User's Manual

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MELSERVO

Servo Amplifiers and Motors

Instruction Manual

MR-J2S-쏔A

INDUSTRIAL AUTOMATION

Art. no.: 138918

2001 02 15

Version C

Summary of content (342 pages)

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MELSERVO Servo Amplifiers and Motors Instruction Manual MR-J2S-쏔A Art. no.
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Safety Instructions (Always read these instructions before using the equipment.) Do not attempt to install, operate, maintain or inspect the servo amplifier and servo motor until you have read through this Instruction Manual, Installation guide, Servo motor Instruction Manual and appended documents carefully and can use the equipment correctly. Do not use the servo amplifier and servo motor until you have a full knowledge of the equipment, safety information and instructions.
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1. To prevent electric shock, note the following: WARNING Before wiring or inspection, switch power off and wait for more than 10 minutes. Then, confirm the voltage is safe with voltage tester. Otherwise, you may get an electric shock. Connect the servo amplifier and servo motor to ground. Any person who is involved in wiring and inspection should be fully competent to do the work. Do not attempt to wire the servo amplifier and servo motor until they have been installed.
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. Additional instructions The following instructions should also be fully noted. Incorrect handling may cause a fault, injury, electric shock, etc. (1) Transportation and installation CAUTION Transport the products correctly according to their weights. Stacking in excess of the specified number of products is not allowed. Do not carry the motor by the cables, shaft or encoder. Do not hold the front cover to transport the controller. The controller may drop.
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CAUTION Securely attach the servo motor to the machine. If attach insecurely, the servo motor may come off during operation. The servo motor with reduction gear must be installed in the specified direction to prevent oil leakage. For safety of personnel, always cover rotating and moving parts. Never hit the servo motor or shaft, especially when coupling the servo motor to the machine. The encoder may become faulty. Do not subject the servo motor shaft to more than the permissible load.
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(4) Usage CAUTION Provide an external emergency stop circuit to ensure that operation can be stopped and power switched off immediately. Any person who is involved in disassembly and repair should be fully competent to do the work. Before resetting an alarm, make sure that the run signal is off to prevent an accident. A sudden restart is made if an alarm is reset with the run signal on. Do not modify the equipment. Use a noise filter, etc.
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(6) Maintenance, inspection and parts replacement CAUTION With age, the electrolytic capacitor will deteriorate. To prevent a secondary accident due to a fault, it is recommended to replace the electrolytic capacitor every 10 years when used in general environment. Please consult our sales representative. (7) Disposal CAUTION Dispose of the product as general industrial waste.
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COMPLIANCE WITH EC DIRECTIVES 1. WHAT ARE EC DIRECTIVES? The EC directives were issued to standardize the regulations of the EU countries and ensure smooth distribution of safety-guaranteed products.
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(4) Power supply (a) Operate the servo amplifier to meet the requirements of the overvoltage category II set forth in IEC664. For this purpose, a reinforced insulating transformer conforming to the IEC or EN Standard should be used in the power input section. (b) When supplying interface power from external, use a 24VDC power supply which has been insulation-reinforced in I/O.
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(7) Auxiliary equipment and options (a) The no-fuse breaker and magnetic contactor used should be the EN or IEC standard-compliant products of the models described in Section 13.2.2. (b) The sizes of the cables described in Section 13.2.1 meet the following requirements. To meet the other requirements, follow Table 5 and Appendix C in EN60204-1. Ambient temperature: 40 (104) [ ( )] Sheath: PVC (polyvinyl chloride) Installed on wall surface or open table tray (c) Use the EMC filter for noise reduction.
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CONFORMANCE WITH UL/C-UL STANDARD (1) Servo amplifiers and servo motors used Use the servo amplifiers and servo motors which comply with the standard model. Servo amplifier Servo motor :MR-J2S-10A to MR-J2S-700A MR-J2S-10A1 to MR-J2S-40A1 :HC-KFS HC-MFS HC-SFS HC-RFS HC-UFS (2) Installation Install a fan of 100CFM air flow 10.16 cm (4 in) above the servo amplifier or provide cooling of at least equivalent capability.
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CONTENTS 1. FUNCTIONS AND CONFIGURATION 1- 1 to 1-18 1.1 Introduction.............................................................................................................................................. 1- 1 1.2 Function block diagram .......................................................................................................................... 1- 2 1.3 Servo amplifier standard specifications ..............................................................................................
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3.8.2 Connection diagram......................................................................................................................... 3-49 3.8.3 I/O terminals .................................................................................................................................... 3-51 3.9 Servo motor with electromagnetic brake ............................................................................................. 3-53 3.10 Grounding ..............................................
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7. GENERAL GAIN ADJUSTMENT 7- 1 to 7-12 7.1 Different adjustment methods ............................................................................................................... 7- 1 7.1.1 Adjustment on a single servo amplifier.......................................................................................... 7- 1 7.1.2 Adjustment using servo configuration software............................................................................ 7- 2 7.2 Auto tuning ...............................
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12. CHARACTERISTICS 12- 1 to 12- 8 12.1 Overload protection characteristics ................................................................................................... 12- 1 12.2 Power supply equipment capacity and generated loss .................................................................... 12- 3 12.3 Dynamic brake characteristics........................................................................................................... 12- 5 12.4 Encoder cable flexing life .................
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14.12 Detailed explanations of commands............................................................................................... 14-14 14.12.1 Data processing.......................................................................................................................... 14-14 14.12.2 Status display ............................................................................................................................ 14-16 14.12.3 Parameter................................................
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Optional Servo Motor Instruction Manual CONTENTS The rough table of contents of the optional MELSERVO Servo Motor Instruction Manual is introduced here for your reference. Note that the contents of the Servo Motor Instruction Manual are not included in the Servo Amplifier Instruction Manual. 1. INTRODUCTION 2. INSTALLATION 3. CONNECTORS USED FOR SERVO MOTOR WIRING 4. INSPECTION 5. SPECIFICATIONS 6. CHARACTERISTICS 7. OUTLINE DIMENSION DRAWINGS 8.
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1. FUNCTIONS AND CONFIGURATION 1. FUNCTIONS AND CONFIGURATION 1.1 Introduction The Mitsubishi MELSERVO-J2-Super series general-purpose AC servo is based on the MELSERVO-J2 series and has further higher performance and higher functions. It has position control, speed control and torque control modes. Further, it can perform operation with the control modes changed, e.g. position/speed control, speed/torque control and torque/position control.
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1. FUNCTIONS AND CONFIGURATION 1.2 Function block diagram The function block diagram of this servo is shown below.
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1. FUNCTIONS AND CONFIGURATION 1.
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1. FUNCTIONS AND CONFIGURATION 1.4 Function list The following table lists the functions of this servo. For details of the functions, refer to the corresponding chapters and sections. Function (Note) Control mode Description Refer to Position control mode This servo is used as position control servo. P Section 3.1.1 Section 3.4.1 Section 4.2.2 Speed control mode This servo is used as speed control servo. S Section 3.1.2 Section 3.4.2 Section 4.2.
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1. FUNCTIONS AND CONFIGURATION Description (Note) Control mode Return converter Used when the regenerative brake option cannot provide enough regenerative power. Can be used with the MR-J2S-500A MR-J2S-700A. P, S, T Section 13.1.3 Alarm history clear Alarm history is cleared. Function Refer to P, S, T Parameter No.
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1. FUNCTIONS AND CONFIGURATION (2) Model MR–J2S– A MR–J2S–100A or less Series MR–J2S–200A 350A Power Supply Symbol Power supply None 3-phase 200 to 230VAC (Note2) 1-phase 230VAC (Note1) 1-phase 100V to 120VAC 1 Rating plate Note:1. Not supplied to the servo amplifier of MR-J2S-60A or more. 2. Not supplied to the servo amplifier of MR-J2S-100A or more.
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1. FUNCTIONS AND CONFIGURATION 1.7 Structure 1.7.1 Parts identification (1) MR-J2S-100A or less Name/Application Refer to Battery holder Section15.3 Contains the battery for absolute position data backup. Battery connector (CON1) Used to connect the battery for absolute position data backup. Display The 5-digit, seven-segment LED shows the servo status and alarm number. Section15.3 Chapter6 Operation section Used to perform status display, diagnostic, alarm and parameter setting operations.
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1. FUNCTIONS AND CONFIGURATION (2) MR-J2S-200A MR-J2S-350A POINT The servo amplifier is shown without the front cover. For removal of the front cover, refer to Section 1.7.2. Name/Application Refer to Battery holder Contains the battery for absolute position data backup. Section15.3 Battery connector (CON1) Used to connect the battery for absolute position data backup. Section15.3 Display The 5-digit, seven-segment LED shows the servo status and alarm number.
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1. FUNCTIONS AND CONFIGURATION (3) MR-J2S-500A POINT The servo amplifier is shown without the front cover. For removal of the front cover, refer to Section 1.7.2. Name/Application Refer to Battery connector (CON1) Used to connect the battery for absolute position data Section15.3 backup. Battery holder Section15.3 Contains the battery for absolute position data backup. Display The 5-digit, seven-segment LED shows the servo status and alarm number.
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1. FUNCTIONS AND CONFIGURATION (4) MR-J2S-700A POINT The servo amplifier is shown without the front cover. For removal of the front cover, refer to next page. Name/Application Battery connector (CON1) Used to connect the battery for absolute position data backup. Section15.3 Battery holder Contains the battery for absolute position data backup. Section15.3 Display The 5-digit, seven-segment LED shows the servo status and alarm number.
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1. FUNCTIONS AND CONFIGURATION 1.7.2 Removal and reinstallation of the front cover To avoid the risk of an electric shock, do not open the front cover while power is on. CAUTION (1) For MR-J2S-200A or more Reinstallation of the front cover Removal of the front cover 1) Front cover hook (2 places) 2) 2) Front cover 1) Front cover socket (2 places) 1) Hold down the removing knob. 2) Pull the front cover toward you. 1) Insert the front cover hooks into the front cover sockets of the servo amplifier.
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1. FUNCTIONS AND CONFIGURATION (3) For MR-J2S-700A Reinstallation of the front cover Removal of the front cover Front cover hook (2 places) A) B) 2) 2) 1) A) 1) Front cover socket (2 places) 1) Push the removing knob A) or B), and put you finger into the front hole of the front cover. 2) Pull the front cover toward you. 1) Insert the two front cover hooks at the bottom into the sockets of the servo amplifier. 2) Press the front cover against the servo amplifier until the removing knob clicks.
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1. FUNCTIONS AND CONFIGURATION 1.8 Servo system with auxiliary equipment WARNING To prevent an electric shock, always connect the protective earth (PE) terminal (terminal marked ) of the servo amplifier to the protective earth (PE) of the control box.
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1. FUNCTIONS AND CONFIGURATION (b) For 1-phase 100V to 120VAC 1-phase 100V to 120VAC power supply Options and auxiliary equipment Refer to Options and auxiliary equipment Refer to No-fuse breaker Section 13.2.2 Regenerative brake option Section 13.1.1 Magnetic contactor Section 13.2.2 Cables Section 13.2.1 Servo configuration software Section 13.1.8 Power factor improving reactor Section 13.2.
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1. FUNCTIONS AND CONFIGURATION (2) MR-J2S-200A MR-J2S-350A or more 3-phase 200V to 230VAC power supply Options and auxiliary equipment Options and auxiliary equipment Refer to Refer to No-fuse breaker Section 13.2.2 Regenerative brake option Magnetic contactor Section 13.2.2 Cables Servo configuration software Section 13.1.8 Power factor improving reactor Section 13.2.3 No-fuse breaker (NFB) or fuse Section 13.1.1 Section 13.2.
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1. FUNCTIONS AND CONFIGURATION (3) MR-J2S-500A 3-phase 200V to 230VAC power supply Options and auxiliary equipment Refer to Options and auxiliary equipment Refer to No-fuse breaker Section 13.2.2 Regenerative brake option Section 13.1.1 Magnetic contactor Section 13.2.2 Cables Section 13.2.1 Servo configuration software Section 13.1.8 Power factor improving reactor Section 13.2.
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1. FUNCTIONS AND CONFIGURATION (4) MR-J2S-700A Options and auxiliary equipment 3-phase 200V to 230VAC power supply Refer to Refer to No-fuse breaker Regenerative brake option Section 13.1.1 Magnetic contactor Section 13.2.2 Cables Section 13.2.1 Servo configuration software Section 13.1.8 Power factor improving reactor Section 13.2.
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1.
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2. INSTALLATION 2. INSTALLATION CAUTION Stacking in excess of the limited number of products is not allowed. Install the equipment to incombustibles. Installing them directly or close to combustibles will led to a fire. Install the equipment in a load-bearing place in accordance with this Instruction Manual. Do not get on or put heavy load on the equipment to prevent injury. Use the equipment within the specified environmental condition range.
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2. INSTALLATION 2.2 Installation direction and clearances CAUTION The equipment must be installed in the specified direction. Otherwise, a fault may occur. Leave specified clearances between the servo amplifier and control box inside walls or other equipment. (1) Installation of one servo amplifier Control box Control box 40mm (1.6 in.) or more Servo amplifier Wiring clearance 70mm (2.8 in.) Top 10mm (0.4 in.) or more 10mm (0.4 in.) or more Bottom 40mm (1.6 in.
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2. INSTALLATION (2) Installation of two or more servo amplifiers Leave a large clearance between the top of the servo amplifier and the internal surface of the control box, and install a fan to prevent the internal temperature of the control box from exceeding the environmental conditions. Control box 100mm (4.0 in.) or more 10mm (0.4 in.) or more Servo amplifier 30mm (1.2 in.) or more 30mm (1.2 in.) or more 40mm (1.6 in.
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2. INSTALLATION 2.4 Cable stress (1) The way of clamping the cable must be fully examined so that flexing stress and cable's own weight stress are not applied to the cable connection. (2) In any application where the servo motor moves, the cables should be free from excessive stress. For use in any application where the servo motor moves run the cables so that their flexing portions fall within the optional encoder cable range. Fix the encoder cable and power cable of the servo motor.
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3. SIGNALS AND WIRING 3. SIGNALS AND WIRING WARNING Any person who is involved in wiring should be fully competent to do the work. Before starting wiring, switch power off, then wait for more than 10 minutes, and after the charge lamp has gone off, make sure that the voltage is safe in the tester or like. Otherwise, you may get an electric shock. Ground the servo amplifier and the servo motor securely. Do not attempt to wire the servo amplifier and servo motor until they have been installed.
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3. SIGNALS AND WIRING 3.1 Standard connection example POINT Refer to Section 3.7.1 for the connection of the power supply system and to Section 3.8 for connection with the servo motor. 3.1.1 Position control mode (1) FX-10GM Positioning module FX-10GM Servo amplifier (Note 4, 9) (Note 4) CN1A CN1B SVRDY COM2 COM2 SVEND COM4 PG0 RD COM INP 1 2 12 11 14 13 19 9 18 P15R 4 OP 14 LG 1 OPC 11 COM 9 7,17 24 8,18 VC 5 FPO 6 FP COM5 9,19 16 RP 15 RP0 3 CLR COM3 4 PP SG NP CR SG SD (Note 10) 2m(6.
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3. SIGNALS AND WIRING Note: 1. To prevent an electric shock, always connect the protective earth (PE) terminal (terminal marked ) of the servo amplifier to the protective earth (PE) of the control box. 2. Connect the diode in the correct direction. If it is connected reversely, the servo amplifier will be faulty and will not output signals, disabling the emergency stop and other protective circuits. 3. The emergency stop switch (normally closed contact) must be installed. 4.
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3. SIGNALS AND WIRING (2) AD75P (A1SD75P ) Positioning module AD75P (A1SD75P ) Servo amplifier (Note 10) 10m(32ft) max.
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3. SIGNALS AND WIRING Note: 1. To prevent an electric shock, always connect the protective earth (PE) terminal (terminal marked ) of the servo amplifier to the protective earth (PE) of the control box. 2. Connect the diode in the correct direction. If it is connected reversely, the servo amplifier will be faulty and will not output signals, disabling the emergency stop and other protective circuits. 3. The emergency stop switch (normally closed contact) must be installed. 4.
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3. SIGNALS AND WIRING 3.1.2 Speed control mode Servo amplifier (Note 4) CN1B (Note 4,9) CN1A Speed selection 1 SP1 8 SG 10 3 VDD 13 COM (Note 12) (Note 7) (Note 2,5) 18 ALM RA1 19 ZSP RA2 6 TLC RA3 Trouble Zero speed Limiting torque 10m(32ft) max.
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3. SIGNALS AND WIRING Note: 1. To prevent an electric shock, always connect the protective earth (PE) terminal (terminal marked ) of the servo amplifier to the protective earth (PE) of the control box. 2. Connect the diode in the correct direction. If it is connected reversely, the servo amplifier will be faulty and will not output signals, disabling the emergency stop and other protective circuits. 3. The emergency stop switch (normally closed contact) must be installed. 4.
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3. SIGNALS AND WIRING 3.1.3 Torque control mode Servo amplifier (Note 4) CN1B (Note 4,8) CN1A Speed selection 1 SP1 8 SG 10 3 VDD 13 COM (Note 10) (Note 6) (Note 2,5) 18 ALM RA1 19 ZSP RA2 6 VLC RA3 Trouble Zero speed Limiting torque 10m(32ft) max.
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3. SIGNALS AND WIRING Note: 1. To prevent an electric shock, always connect the protective earth (PE) terminal of the (terminal marked ) servo amplifier to the protective earth (PE) of the control box. 2. Connect the diode in the correct direction. If it is connected reversely, the servo amplifier will be faulty and will not output signals, disabling the emergency stop and other protective circuits. 3. The emergency stop switch(normally closed contact) must be installed. 4.
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3. SIGNALS AND WIRING 3.2 Internal connection diagram of servo amplifier The following is the internal connection diagram where the signal assignment has been made in the initial status in each control mode. Servo amplifier CN1B VDD 3 COM 13 DC24V (Note) (Note) P S T COM COM COM CN1A CN1A P S 9 18 INP SA RD RD RD S T T Approx. 4.
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3. SIGNALS AND WIRING 3.3 I/O signals 3.3.1 Connectors and signal arrangements POINT The connector pin-outs shown above are viewed from the cable connector wiring section side. Refer to the next page for CN1A and CN1B signal assignment.
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3. SIGNALS AND WIRING (2) CN1A and CN1B signal assignment The signal assignment of connector changes with the control mode as indicated below; For the pins which are given parameter No.s in the related parameter column, their signals can be changed using those parameters. (Note2) Connector (Note1) Pin No.
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3. SIGNALS AND WIRING Note: 1. I : Input signal, O: Output signal 2. P : Position control mode, S: Speed control mode, T: Torque control mode, P/S: Position/speed control change mode, S/T: Speed/torque control change mode, T/P: Torque/position control change mode 3. By setting parameters No. 43 to 48 to make TL available, TLA can be used. 4. The signal of CN1A-18 is always output.
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3. SIGNALS AND WIRING 3.3.2 Signal explanations For the I/O interfaces (symbols in I/O column in the table), refer to Section 3.6.2. In the control mode field of the table P : Position control mode, S: Speed control mode, T: Torque control mode : Denotes that the signal may be used in the initial setting status. : Denotes that the signal may be used by setting the corresponding parameter among parameters 43 to 49. The pin No.s in the connector pin No. column are those in the initial status.
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3. SIGNALS AND WIRING Signal ConnecSymbol tor pin No. Outside torque limit selection TL Internal torque limit selection TL1 Forward rotation start ST1 Reverse rotation start ST2 CN1B 9 CN1B 8 CN1B 9 Functions/Applications I/O division Torque limit selection disconnecting TL-SG makes internal torque limit 1 (parameter No. 28) valid and connecting them makes analog torque limit (TLA) valid. For details, refer to (5), Section 3.4.1.
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3. SIGNALS AND WIRING Signal Symbol Speed selection 1 SP1 Speed selection 2 SP2 Speed selection 3 SP3 ConnecI/O tor pin Functions/Applications division No. CN1A DI-1 8 Used to select the command speed for operation. When using SP3, make it usable by making the setting of parameter No. 43 to 48. DI-1 CN1B (Note) Input Setting of 7 signals parameter Speed command No. 43 to 48 SP3 SP2 SP1 0 0 Analog speed command (VC) DI-1 Internal speed command 1 When speed 0 1 (parameter No.
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3. SIGNALS AND WIRING Signal Proportion control Emergency stop Clear Symbol Connector pin No. Functions/Applications I/O division PC CN1B 8 Connect PC-SG to switch the speed amplifier from the proportional integral type to the proportional type. If the servo motor at a stop is rotated even one pulse due to any external factor, it generates torque to compensate for a position shift.
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3. SIGNALS AND WIRING Signal Control change Symbol LOP Connector pin No. CN1B 7 Functions/Applications Used to select the control mode in the position/speed control change mode. I/O division DI-1 Control mode P S T Refer to Functions/ Applications. (Note) LOP Control mode 0 1 Position Speed Note.0: LOP-SG off (open) 1: LOP-SG on (short) Used to select the control mode in the speed/torque control change mode.
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3. SIGNALS AND WIRING (2) Output signals Signal ConnecSymbol tor pin No. Functions/Applications I/O division ALM CN1B 18 ALM-SG are disconnected when power is switched off or the protective circuit is activated to shut off the base circuit. Without alarm, ALM-SG are connected within 1 after power on. DO-1 Ready RD CN1A 19 RD-SG are connected when the servo is switched on and the servo amplifier is ready to operate.
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3. SIGNALS AND WIRING Signal Alarm code ConnecSymbol tor pin No. ACD 0 ACD 1 ACD 2 CN1A 19 CN1A 18 CN1B 19 I/O division Functions/Applications To use this signal, set " 1 " in parameter No.49. This signal is output when an alarm occurs. When there is no alarm, respective ordinary signals (RD, INP, SA, ZSP) are output.
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3. SIGNALS AND WIRING Connector pin No. Symbol Encoder Z-phase pulse (Open collector) OP CN1A 14 Outputs the zero-point signal of the encoder. One pulse is output per servo motor revolution. OP and LG are connected when the zero-point position is reached. (Negative logic) The minimum pulse width is about 400 s. For home position return using this pulse, set the creep speed to 100r/min. or less.
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3. SIGNALS AND WIRING (4) Power supply Signal ConnecSymbol tor pin No. Functions/Applications I/F internal power supply VDD CN1B 3 Used to output 24V 10% to across VDD-SG. When using this power supply for digital interface, connect it with COM. Permissible current : 80mA Digital I/F power supply input COM CN1A 9 CN1B 13 Used to input 24VDC for input interface. Connect the positive terminal of the 24VDC external power supply.
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3. SIGNALS AND WIRING 3.4 Detailed description of the signals 3.4.1 Position control mode (1) Pulse train input (a) Input pulse waveform selection Encoder pulses may be input in any of three different forms, for which positive or negative logic can be chosen. Set the command pulse train form in parameter No. 21. Arrow or in the table indicates the timing of importing a pulse train. A- and B-phase pulse trains are imported after they have been multiplied by 4.
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3. SIGNALS AND WIRING (b) Connections and waveforms 1) Open collector system Connect as shown below: Servo amplifier VDD OPC PP Approx. 1.2k NP Approx. 1.2k SG SD The explanation assumes that the input waveform has been set to the negative logic and forward and reverse rotation pulse trains (parameter No.21 has been set to 0010). The waveforms in the table in (a), (1) of this section are voltage waveforms of PP and NP based on SG.
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3. SIGNALS AND WIRING 2) Differential line driver system Connect as shown below: Servo amplifier PP PG NP NG SD The explanation assumes that the input waveform has been set to the negative logic and forward and reverse rotation pulse trains (parameter No.21 has been set to 0010). For the differential line driver, the waveforms in the table in (a), (1) of this section are as follows. The waveforms of PP, PG, NP and NG are based on that of the ground of the differential line driver.
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3. SIGNALS AND WIRING (2) In-position (INP) PF-SG are connected when the number of droop pulses in the deviation counter falls within the preset in-position range (parameter No. 5). INP-SG may remain connected when low-speed operation is performed with a large value set as the in-position range.
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3. SIGNALS AND WIRING (5) Torque limit (a) Torque limit and generated torque By setting parameter No. 28 (internal torque limit 1), torque is always limited to the maximum value during operation. A relationship between the limit value and servo motor-generated torque is shown below. Generated torque Max. torque 0 0 100 Torque limit value [%] Torque limit value [%] A relationship between the applied voltage of the analog torque limit (TLA) and the torque limit value of the servo motor is shown below.
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3. SIGNALS AND WIRING 3.4.2 Speed control mode (1) Speed setting (a) Speed command and speed The servo motor is run at the speeds set in the parameters or at the speed set in the applied voltage of the analog speed command (VC). A relationship between the analog speed command (VC) applied voltage and the servo motor speed is shown below: The maximum speed is achieved at 10V. The speed at 10V can be changed using parameter No. 25.
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3. SIGNALS AND WIRING (b) Speed selection 1 (SP1), speed selection 2 (SP2) and speed command value Choose any of the speed settings made by the internal speed commands 1 to 3 using speed selection 1 (SP1) and speed selection 2 (SP2) or the speed setting made by the analog speed command (VC). (Note) External input signals Speed command value SP2 SP1 0 0 Analog speed command (VC) 0 1 Internal speed command 1 (parameter No. 8) 1 0 Internal speed command 2 (parameter No.
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3. SIGNALS AND WIRING 3.4.3 Torque control mode (1) Torque control (a) Torque command and generated torque A relationship between the applied voltage of the analog torque command (TC) and the torque generated by the servo motor is shown below. The maximum torque is generated at 8V. Note that the torque generated at 8V input can be changed with parameter No. 26. CCW direction Max. torque Forward rotation (CCW) Generated torque 8 0.05 0.05 8 TC applied voltage [V] CW direction Max.
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3. SIGNALS AND WIRING (b) Analog torque command offset Using parameter No. 30, the offset voltage of voltage as shown below. 999 to 999mV can be added to the TC applied Generated torque Max. torque Parameter No.30 offset range 999 to 999mV 0 8( 8) TC applied voltage [V] (2) Torque limit By setting parameter No. 28 (internal torque limit 1), torque is always limited to the maximum value during operation. A relationship between limit value and servo motor-generated torque is as in (5) in section 3.4.1.
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3. SIGNALS AND WIRING (b) Speed selection 1(SP1)/speed selection 2(SP2)/speed selection 3(SP3) and speed limit values Choose any of the speed settings made by the internal speed limits 1 to 7 using speed selection 1(SP1), speed selection 2(SP2) and speed selection 3(SP3) or the speed setting made by the speed limit command (VLA), as indicated below. Setting of parameter No.
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3. SIGNALS AND WIRING 3.4.4 Position/speed control change mode Set "0001" in parameter No. 0 to switch to the position/speed control change mode. This function is not available in the absolute position detection system. (1) Control change (LOP) Use control change (LOP) to switch between the position control mode and the speed control mode from an external contact.
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3. SIGNALS AND WIRING (3) Speed setting in speed control mode (a) Speed command and speed The servo motor is run at the speed set in parameter No. 8 (internal speed command 1) or at the speed set in the applied voltage of the analog speed command (VC). A relationship between analog speed command (VC) applied voltage and servo motor speed and the rotation directions determined by the forward rotation start signal (ST1) and reverse rotation start signal (ST2) are as in (a), (1) in section 3.4.2.
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3. SIGNALS AND WIRING 3.4.5 Speed/torque control change mode Set "0003" in parameter No. 0 to switch to the speed/torque control change mode. (1) Control change (LOP) Use control change (LOP) to switch between the speed control mode and the torque control mode from an external contact. Relationships between LOP-SG status and control modes are indicated below: (Note) LOP Servo control mode 0 Speed control mode 1 Torque control mode Note.
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3. SIGNALS AND WIRING (4) Speed limit in torque control mode (a) Speed limit value and speed The speed is limited to the limit value set in parameter No. 8 (internal speed limit 1) or the value set in the applied voltage of the analog speed limit (VLA). A relationship between the analog speed limit (VLA) applied voltage and the servo motor speed is as in (a), (3) in section 3.4.3.
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3. SIGNALS AND WIRING 3.4.6 Torque/position control change mode Set "0005" in parameter No. 0 to switch to the torque/position control change mode. (1) Control change (LOP) Use control change (LOP) to switch between the torque control mode and the position control mode from an external contact. Relationships between LOP-SG status and control modes are indicated below: (Note) LOP Servo control mode 0 Torque control mode 1 Position control mode Note.
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3. SIGNALS AND WIRING 3.5 Alarm occurrence timing chart When an alarm has occurred, remove its cause, make sure that the operation signal is not being input, ensure safety, and reset the alarm before restarting operation. CAUTION When an alarm occurs in the servo amplifier, the base circuit is shut off and the servo motor is coated to a stop. Switch off the main circuit power supply in the external sequence.
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3. SIGNALS AND WIRING 3.6 Interfaces 3.6.1 Common line The following diagram shows the power supply and its common line. CN1A CN1B CN1A CN1B DC24V VDD RA ALM .etc COM DO-1 SON, etc. DI-1 SG (Note) OPC PG NG PP NP SG 15VDC 10% 30mA P15R SG Isolated OP LG LA etc. Analog input ( 10V/max. current) Differential line driver output 35mA max. LAR etc. LG TLA VC etc.
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3. SIGNALS AND WIRING 3.6.2 Detailed description of the interfaces This section gives the details of the I/O signal interfaces (refer to I/O Division in the table) indicated in Sections 3.3.2. Refer to this section and connect the interfaces with the external equipment. (1) Digital input interface DI-1 Give a signal with a relay or open collector transistor. Source input is also possible. Refer to (7) in this section.
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3. SIGNALS AND WIRING (b) Lamp load For use of internal power supply For use of external power supply Servo amplifier 24VDC Servo amplifier VDD 24VDC Do not connect VDD-COM. VDD COM COM R R 24VDC 10% ALM, etc. ALM, etc. SG SG (3) Pulse train input interface DI-2 Provide a pulse train signal in the open collector or differential line driver system.
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3. SIGNALS AND WIRING (b) Differential line driver system 1) Interface Servo amplifier Max. input pulse frequency 500kpps Am26LS31 or equivalent PP(NP) PG(NG) About 100 SD 2) Conditions of the input pulse tHL tc PP PG tLH tHL 0.1 s tc 1 s tF 3 s 0.9 0.1 tc tLH tF NP NG (4) Encoder pulse output DO-2 (a) Open collector system Interface Max.
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3. SIGNALS AND WIRING (b) Differential line driver system 1) Interface Max. output current: 35mA Servo amplifier Servo amplifier LA (LB, LZ) Am26LS32 or equivalent LA (LB, LZ) 100 150 LAR (LBR, LZR) LAR (LBR, LZR) LG SD SD 2) Output pulse Servo motor CCW rotation LA LAR T LB LBR /2 LZ signal varies 3/8T on its leading edge. LZ LZR 400 s or more OP (5) Analog input Input impedance 10 to 12k Servo amplifier 15VDC P15R Upper limit setting 2k 2k VC‚ etc LG Approx.
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3. SIGNALS AND WIRING (7) Source input interface When using the input interface of source type, all Dl-1 input signals are of source type. Source output cannot be provided. For use of internal power supply For use of external power supply Servo amplifier Servo amplifier SG COM (Note) For a transistor Approx. 5mA SG R: Approx. 4.7 COM SON, etc. Switch Switch SON,etc. 24VDC TR VDD 24VDC 200mA or more VCES 1.0V ICEO 100 A Note: This also applies to the use of the external power supply.
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3. SIGNALS AND WIRING 3.7 Input power supply circuit CAUTION When the servo amplifier has become faulty, switch power off on the servo amplifier power side. Continuous flow of a large current may cause a fire. Use the trouble signal to switch power off. Otherwise, a regenerative brake transistor fault or the like may overheat the regenerative brake resistor, causing a fire. 3.7.
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3. SIGNALS AND WIRING (2) For 1-phase 100 to 120VAC or 1-phase 100 to 120VAC power supply Emergency OFF RA stop ON MC MC SK Power supply 1-phase 100 to 120VAC or 1-phase 230VAC NFB MC L1 Servo amplifier L2 L3 (Note) L11 L21 EMG Emergency stop Servo-on SON SG VDD COM ALM Note : Not provided for 1-phase 100 to 120VAC.
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3. SIGNALS AND WIRING 3.7.2 Terminals The positions and signal arrangements of the terminal blocks change with the capacity of the servo amplifier. Refer to Section 11.1. Symbol Signal Description Supply L1, L2 and L3 with the following power: For 1-phase 230VAC, connect the power supply to L1/L2 and leave L3 open.
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3. SIGNALS AND WIRING 3.7.3 Power-on sequence (1) Power-on procedure 1) Always wire the power supply as shown in above Section 3.7.1 using the magnetic contactor with the main circuit power supply (three-phase 200V: L1, L2, L3, single-phase 230V: L1, L2). Configure up an external sequence to switch off the magnetic contactor as soon as an alarm occurs.
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3. SIGNALS AND WIRING 3.8 Connection of servo amplifier and servo motor 3.8.1 Connection instructions WARNING Insulate the connections of the power supply terminals to prevent an electric shock. CAUTION Connect the wires to the correct phase terminals (U, V, W) of the servo amplifier and servo motor. Otherwise, the servo motor will operate improperly. Do not connect AC power supply directly to the servo motor. Otherwise, a fault may occur.
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3. SIGNALS AND WIRING Servo motor Connection diagram Servo amplifier Servo motor U (Red) U V (White) V W (Black) W Motor (Green) (Note 1) 24VDC HC-KFS053 (B) to 73 (B) HC-MFS053 (B) to 73 (B) HC-UFS13 (B) to 73 (B) B1 (Note2) B2 Electromagnetic brake EMG To be shut off when servo on signal switches off or by alarm signal CN2 Encoder Encoder cable Note:1.
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3. SIGNALS AND WIRING 3.8.3 I/O terminals (1) HC-KFS HC-MFS HC-UFS3000r/min series Encoder connector signal arrangement Power supply lead 4-AWG19 0.3m Encoder cable 0.
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3. SIGNALS AND WIRING (2) HC-SFS HC-RFS HC-UFS2000 r/min series Servo motor side connectors Servo motor Motor plate For power supply For encoder (Opposite side) HC-SFS81(B) HC-SFS121(B) to 301(B) HC-SFS203(B) 17PD-B 353(B) HC-RFS103(B) to 203 (B) HC-RFS353(B) 503(B) Encoder connector Brake connector MS3102A10SL4P CE05-2A32- HC-SFS702(B) HC-UFS72(B) shared.
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3. SIGNALS AND WIRING 3.9 Servo motor with electromagnetic brake Configure the electromagnetic brake operation circuit so that it is activated not only by the servo amplifier signals but also by an external emergency stop signal. Contacts must be open when servo-on signal is off or when an alarm (trouble) is present and when an electromagnetic brake signal. Circuit must be opened during emergency stop signal.
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3. SIGNALS AND WIRING (3) Timing charts (a) Servo-on signal command (from controller) ON/OFF Tb [ms] after the servo-on (SON) signal is switched off, the servo lock is released and the servo motor coasts. If the electromagnetic brake is made valid in the servo lock status, the brake life may be shorter. Therefore, when using the electromagnetic brake in a vertical lift application or the like, set Tb to about the same as the electromagnetic brake operation delay time to prevent a drop.
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3.
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3. SIGNALS AND WIRING 3.10 Grounding WARNING Ground the servo amplifier and servo motor securely. To prevent an electric shock, always connect the protective earth (PE) terminal of the servo amplifier with the protective earth (PE) of the control box. The servo amplifier switches the power transistor on-off to supply power to the servo motor. Depending on the wiring and ground cablerouting, the servo amplifier may be affected by the switching noise (due to di/dt and dv/dt) of the transistor.
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3. SIGNALS AND WIRING 3.11 Servo amplifier terminal block (TE2) wiring method (1) Termination of the cables Solid wire: After the sheath has been stripped, the cable can be used as it is. (Cable size: 0.2 to 2.5mm2) Approx. 10mm Twisted wire: Use the cable after stripping the sheath and twisting the core. At this time, take care to avoid a short caused by the loose wires of the core and the adjacent pole. Do not solder the core as it may cause a contact fault. (Cable size: 0.2 to 2.
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3. SIGNALS AND WIRING (2) Connection Insert the core of the cable into the opening and tighten the screw with a flat-blade screwdriver so that the cable does not come off. (Tightening torque: 0.5 to 0.6N m) Before inserting the cable into the opening, make sure that the screw of the terminal is fully loose. When using a cable of 1.5mm2 or less, two cables may be inserted into one opening. Flat-blade screwdriver Tip thickness 0.4 to 0.6mm Overall width 2.5 to 3.5mm To loosen. To tighten.
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4. OPERATION 4. OPERATION 4.1 When switching power on for the first time Before starting operation, check the following: (1) Wiring (a) A correct power supply is connected to the power input terminals (L1, L2, L3, L11, L21) of the servo amplifier. (b) The servo motor power supply terminals (U, V, W) of the servo amplifier match in phase with the power input terminals (U, V, W) of the servo motor.
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4. OPERATION 4.2 Startup WARNING Do not operate the switches with wet hands. You may get an electric shock. CAUTION Before starting operation, check the parameters. Some machines may perform unexpected operation. During power-on for some after power-off, do not touch or close a parts (cable etc.) to the servo amplifier heat sink, regenerative brake resistor, the servo motor, etc. Their temperatures may be high and you may get burnt or a parts may damaged.
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4. OPERATION (4) Servo-on Switch the servo-on in the following procedure: 1) Switch on main circuit/control power supply. 2) Switch on the servo-on signal (SON). When placed in the servo-on status, the servo amplifier is ready to operate and the servo motor is locked. (5) Command pulse input Entry of a pulse train from the positioning device rotates the servo motor. At first, run it at low speed and check the rotation direction, etc. If it does not run in the intended direction, check the input signal.
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4. OPERATION 4.2.3 Speed control mode (1) Power on 1) Switch off the servo-on (SON) signal. 2) When main circuit power/control circuit power is switched on, the display shows "r (servo motor speed)", and in two second later, shows data. (2) Test operation Using jog operation in the test operation mode, make sure that the servo motor operates. (Refer to Section 6.8.2.) (3) Parameter setting Set the parameters according to the structure and specifications of the machine.
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4. OPERATION (6) Stop In any of the following statuses, the servo amplifier interrupts and stops the operation of the servo motor: Refer to Section 3.9, (2) for the servo motor equipped with electromagnetic brake. Note that simultaneous ON or simultaneous OFF of stroke end (LSP, LSN) OFF and forward rotation start (ST1) or reverse rotation start (ST2) signal has the same stop pattern as described below. (a) Servo-on (SON) OFF The base circuit is shut off and the servo motor coasts.
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4. OPERATION (4) Servo-on Switch the servo-on in the following procedure: 1) Switch on main circuit/control power supply. 2) Switch on the servo-on signal (SON) (short SON-SG). When placed in the servo-on status, the servo amplifier is ready to operate and the servo motor is locked. (5) Start Using speed selection 1 (SP1) and speed selection 2 (SP2), choose the servo motor speed.
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5. PARAMETERS 5. PARAMETERS CAUTION Never adjust or change the parameter values extremely as it will make operation instable. 5.1 Parameter list 5.1.1 Parameter write inhibit POINT After setting the parameter No. 19 value, switch power off, then on to make that setting valid. In the MR-J2S-A servo amplifier, its parameters are classified into the basic parameters (No. 0 to 19), expansion parameters 1 (No. 20 to 49) and expansion parameters 2 (No.
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5. PARAMETERS 5.1.2 Lists POINT For any parameter whose symbol is preceded by *, set the parameter value and switch power off once, then switch it on again to make that parameter setting valid. The symbols in the control mode column of the table indicate the following modes: P : Position control mode S : Speed control mode T : Torque control mode (1) Item list Basic parameters No.
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5. PARAMETERS No.
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5. PARAMETERS No.
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5. PARAMETERS (2) Details list Class No. Symbol 0 *STY Name and function Control mode, regenerative brake option selection Used to select the control mode and regenerative brake option. 0 Initial value 0000 Unit Setting Control range mode Refer to P S T Name and 0 function column. Select the control mode.
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5. PARAMETERS Class No. Symbol 2 ATU Name and function Auto tuning Used to selection the response level, etc. for execution of auto tuning. Refer to Chapter 7. 0 Initial value 0105 Unit Setting Control range mode Refer to P S Name and function 0 column.
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5. PARAMETERS Class No. Symbol 5 INP 6 PG1 7 PST Name and function In-position range Used to set the in-position signal (INP) output range in the command pulse increments prior to electronic gear calculation. For example, when you want to set 10 m in the conditions that the ballscrew is direct coupled, the lead is 10mm, and the feedback pulses are 8192 pulses/rev (parameter No. 6 : 1), set "8" as indicated by the following expression: 10 10 6 10 10 3 8192 8.
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5. PARAMETERS Class No. Symbol 9 SC2 Initial value 500 Name and function Internal speed command 2 Used to set speed 2 of internal speed commands. Internal speed limit 2 Used to set speed 2 of internal speed limits. 10 SC3 Internal speed command 3 Used to set speed 3 of internal speed commands. 1000 Internal speed limit 3 Used to set speed 3 of internal speed limits.
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5. PARAMETERS Class No. Symbol 14 TQC Name and function Torque command time constant Used to set the constant of a low pass filter in response to the torque command. Torque command Torque Setting Control range mode Initial value Unit 0 ms 0 to 20000 T station 0 to 31 P S T Refer to P S T After filtered TQC TQC Time Basic parameters TQC: Torque command time constant 15 *SNO Station number setting Used to specify the station number for serial communication.
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5. PARAMETERS Class No. Symbol 17 MOD Analog monitor output Used to selection the signal provided to the analog monitor output. (Refer to Section 5.3) 0 0100 Unit Setting Control range mode Refer to Name and function 0 Setting column. Analog monitor output selection ch2 Basic parameters Initial value Name and function ch1 0 Servo motor speed ( 8V/max. speed) 1 Torque ( 8V/max. torque) 2 Motor speed ( 8V/max. speed) 3 Torque ( 8V/max. torque) 4 Current command ( 8V/max.
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5. PARAMETERS Class No. Symbol 18 Initial value Name and function *DMD Status display selection Used to select the status display shown at power-on.
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5. PARAMETERS Class No. Symbol 19 *BLK Name and function Parameter block Used to select the reference and write ranges of the parameters. Operation can be performed for the parameters marked . Set value Operation Basic parameters 0000 (Initial value) 000B 000C 000E 100B 100C 100E 20 *OP2 Setting Control range mode Refer to P S T Name and function column. Expansion Expansion parameters 1 parameters 2 No. 20 No. 50 to No. 49 to No. 84 Write No. 19 only No. 19 only No. 19 only No. 19 only No.
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5. PARAMETERS Class No. Symbol 21 *OP3 Initial value Name and function Function selection 3 (Command pulse selection) Used to select the input form of the pulse train input signal. (Refer to Section 3.4.1.) 0000 Unit Setting Control range mode Refer to P Name and function 0 0 column.
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5. PARAMETERS No. Symbol 23 FFC 24 ZSP 25 VCM 26 TLC 27 *ENR Expansion parameters 1 Class Name and function Feed forward gain Used to set the feed forward gain. At the setting of 100%, droop pulses during constant-speed operation will be almost “zero”. Note that sudden acceleration/deceleration will increase overshoot. As a guideline, set 1s or more as the acceleration/deceleration time constant to the rated speed when the feed forward gain is set to 100%.
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5. PARAMETERS Class No. Symbol 29 Expansion parameters 1 30 VCO TLO 31 MO1 32 MO2 33 MBR 34 GD2 35 PG2 36 VG1 37 VG2 38 VIC Name and function Initial value Unit Analog speed command offset Depends mV Used to set the offset voltage of the analog speed command (VC). on servo For example, if CCW rotation is provided by switching on forward amplifier rotation start (ST1) with 0V applied to VC, set a negative value.
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5. PARAMETERS Class No. Symbol 39 VDC 40 41 Name and function Speed differential compensation Used to set the differential compensation. Made valid when the proportion control signal is switched on. For manufacturer setting Must not be changed. *DIA Initial value 980 Unit Setting Control range mode 0 to 1000 P S Refer to P S T 0 Input signal automatic ON selection Used to set automatic ON of SON, LSP and LSN. 0000 Name and 0 function column.
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5. PARAMETERS Class No. Symbol 43 *DI2 Initial value Name and function Input signal selection 2 (CN1B-5) This parameter is unavailable when parameter No.42 is set to assign the control change signal (LOP) to CN1B-pin 5. Allows any input signal to be assigned to CN1B-pin 5. Note that the setting digit and assigned signal differ according to the control mode. 0111 Unit Setting Control range mode Refer to P S T Name and function column.
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5. PARAMETERS Class No. Symbol 45 *DI4 Name and function Input signal selection 4 (CN1A-8) Allows any input signal to be assigned to CN1A-pin 8. The assignable signals and setting method are the same as in input signal selection 2 (parameter No. 43). Initial value 0665 function Input signals of CN1A-pin 8 selected. This parameter is unavailable when parameter No. 42 is set to assign the control change signal (LOP) to CN1 A-pin 8.
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5. PARAMETERS Class No. Symbol 49 *DO1 Initial value Name and function Output signal selection 1 Used to select the connector pins to output the alarm code, warning (WNG) and battery warning (BWNG). Setting range Control mode Refer to P S T Name and function 0 column. Setting of alarm code output Connector pins Set value CN1B-19 CN1A-18 CN1A-19 0 ZSP INP or SA RD Alarm code is output at alarm occurrence.
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5. PARAMETERS Class No. Symbol 50 51 *OP6 Initial value Name and function For manufacturer setting Must not be changed. 0000 Function selection 6 Used to select the operation to be performed when the alarm reset signal switches on. 0000 0 Unit Setting Control range mode Refer to P S T Name and function 0 0 column.
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5. PARAMETERS Class No. Symbol 55 *OPA Initial value Name and function Function selection A Used to select the position command acceleration/deceleration time constant (parameter No. 7) control system. 0 0 Unit 0000 Setting Control range mode Refer to P Name and function 0 column.
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5. PARAMETERS Class No. Symbol 60 LPF Name and function Low-pass filter/adaptive vibration suppression control Used to selection the low-pass filter and adaptive vibration suppression control. (Refer to Chapter 8.) Initial value Unit 0000 Setting Control range mode Refer to P S T Name and function 0 column. Low-pass filter selection 0: Valid (Automatic adjustment) 1: Invalid VG2 setting 10 When you choose "valid", 2 (1 GD2 setting 0.1) [Hz] bandwidth filter is set automatically.
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5. PARAMETERS Class No. Symbol 65 *CDP Name and function Gain changing selection Used to select the gain changing condition. (Refer to Section 8.3.) Initial value Unit 0000 Setting Control range mode Refer to P S Name and 0 0 0 function column. Expansion parameters 2 Gain changing selection Gains are changed in accordance with the settings of parameters No.
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5. PARAMETERS Class No. Symbol 73 SC5 Name and function Internal speed command 5 Used to set speed 5 of internal speed commands. Initial value 300 Internal speed limit 5 Used to set speed 5 of internal speed limits. 74 SC6 Internal speed command 6 Used to set speed 6 of internal speed commands. 500 Internal speed limit 6 Used to set speed 6 of internal speed limits. Expansion parameters 2 75 SC7 Internal speed command 7 Used to set speed 7 of internal speed commands.
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5. PARAMETERS 5.2 Detailed description 5.2.1 Electronic gear CAUTION Wrong setting can lead to unexpected fast rotation, causing injury. POINT 1 CMX 500. 50 CDV If the set value is outside this range, noise may be generated during acceleration/ deceleration or operation may not be performed at the preset speed and/or acceleration/deceleration time constants. The following specification symbols are required to calculate the electronic gear.
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5. PARAMETERS (b) Conveyor setting example For rotation in increments of 0.01 per pulse Servo motor 131072 [pulse/rev] Machine specifications Table Table : 360 /rev Reduction ratio: n 4/64 Servo motor resolution: Pt Pt CMX CDV 0.01 131072 [pulses/rev] 131072 4/64 360 Timing belt : 4/64 65536 ................................................................................. (5.2) 1125 Since CMX is not within the setting range in this status, it must be reduced to the lowest term.
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5. PARAMETERS (3) Setting for use of AD75P The AD75P also has the following electronic gear parameters. Normally, the servo amplifier side electronic gear must also be set due to the restriction on the command pulse frequency (differential 400kpulse/s, open collector 200kpulse/s).
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5. PARAMETERS To rotate the servo motor at 3000r/min in the open collector system (200kpulse/s), set the electronic gear as follows f CMX CDV f : N0 : Pt : 200 N0 60 pt Input pulses [pulse/s] Servo motor speed [r/min] Servo motor resolution [pulse/rev] CMX CDV 3000 131072 60 CMX CDV 3000 60 131072 200 3000 131072 60 200000 4096 125 The following table indicates the electronic gear setting example (ballscrew lead AD75P is used in this way.
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5. PARAMETERS 5.2.2 Analog output The servo status can be output to two channels in terms of voltage. Use this function when using an ammeter to monitor the servo status or synchronizing the torque/speed with the other servo. (1) Setting Change the following digits of parameter No.17: Parameter No. 17 0 0 Analog monitor ch1 output selection (Signal output to across MO1-LG) Analog monitor ch2 output selection (Signal output to across MO2-LG) Parameters No.
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5. PARAMETERS (2) Set content The servo amplifier is factory-set to output the motor speed to ch1 and the torque to ch2. The setting can be changed as listed below by changing the parameter No.17 value: Refer to Appendix 2 for the measurement point. Setting 0 Output item Motor speed Description Setting 6 CCW direction 8[V] Output item Droop pulses ( 10V/128pulse) Description 10[V] CCW direction 128[pulse] Max. speed 0 0 Max.
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Command pulse Command pulse frequency Droop pulse Position control Speed command Differential Motor speed Speed control Current command Torque Current control 5 - 31 Encoder M Servo Motor Position feedback Current feedback PWM Current encoder Bus voltage 5.
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5. PARAMETERS 5.2.3 Using forward/reverse rotation stroke end to change the stopping pattern The stopping pattern is factory-set to make a sudden stop when the forward/reverse rotation stroke end is made valid. A slow stop can be made by changing the parameter No. 22 value. Parameter No.22 Setting 0 (initial value) Stopping method Sudden stop Position control mode : Motor stops with droop pulses cleared. Speed control mode : Motor stops at deceleration time constant of zero.
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5. PARAMETERS 5.2.5 Position smoothing By setting the position command acceleration/deceleration time constant (parameter No.7), you can run the servo motor smoothly in response to a sudden position command. The following diagrams show the operation patterns of the servo motor in response to a position command when you have set the position command acceleration/deceleration time constant. Choose the primary delay or linear acceleration/deceleration in parameter No. 55 according to the machine used.
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5.
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6. DISPLAY AND OPERATION 6. DISPLAY AND OPERATION 6.1 Display flowchart Use the display (5-digit, 7-segment LED) on the front panel of the servo amplifier for status display, parameter setting, etc. Set the parameters before operation, diagnose an alarm, confirm external sequences, and/or confirm the operation status. Press the "MODE" "UP" or "DOWN" button once to move to the next screen. To refer to or set the expansion parameters, make them valid with parameter No. 19 (parameter write disable).
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6. DISPLAY AND OPERATION 6.2 Status display The servo status during operation is shown on the 5-digit, 7-segment LED display. Press the "UP" or "DOWN" button to change display data as desired. When the required data is selected, the corresponding symbol appears. Press the "SET" button to display its data. At only power-on, however, data appears after the symbol of the status display selected in parameter No. 18 has been shown for 2[s].
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6. DISPLAY AND OPERATION 6.2.2 Status display list The following table lists the servo statuses that may be shown: Refer to Appendix 2 for the measurement point. Name Symbol Unit Description Cumulative feedback pulses C pulse Servo motor speed r r/min Feedback pulses from the servo motor encoder are counted and displayed. The value in excess of 99999 is counted, bus since the servo amplifier display is five digits, it shows the lower five digits of the actual value.
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6. DISPLAY AND OPERATION Display range Name Symbol Unit Description Within one-revolution position high Cy2 100 pulse The within one-revolution position is displayed in 100 pulse increments of the encoder. The value returns to 0 when it exceeds the maximum number of pulses. The value is incremented in the CCW direction of rotation.
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6. DISPLAY AND OPERATION 6.3 Diagnostic mode Name Display Description Not ready. Indicates that the servo amplifier is being initialized or an alarm has occurred. Sequence Ready. Indicates that the servo was switched on after completion of initialization and the servo amplifier is ready to operate. External I/O signal display Indicates the ON-OFF states of the external I/O signals. The upper segments correspond to the input signals and the lower segments to the output signals.
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6. DISPLAY AND OPERATION Name Display Description Motor series Press the "SET" button to show the motor series ID of the servo motor currently connected. For indication details, refer to the optional MELSERVO Servo Motor Instruction Manual. Motor type Press the "SET" button to show the motor type ID of the servo motor currently connected. For indication details, refer to the optional MELSERVO Servo Motor Instruction Manual.
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6. DISPLAY AND OPERATION 6.4 Alarm mode The current alarm, past alarm history and parameter error are displayed. The lower 2 digits on the display indicate the alarm number that has occurred or the parameter number in error. Display examples are shown below. Name Display Description Indicates no occurrence of an alarm. Current alarm Indicates the occurrence of overvoltage (AL.33). Flickers at occurrence of the alarm. Indicates that the last alarm is overload 1 (AL.50).
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6. DISPLAY AND OPERATION 6.5 Parameter mode The parameters whose abbreviations are marked* are made valid by changing the setting and then switching power off once and switching it on again. Refer to Section 5.1.2. (1) Operation example The following example shows the operation procedure performed after power-on to change the control mode (parameter No. 0) to the speed control mode. Using the "MODE" button, show the basic parameter screen. The parameter number is displayed.
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6. DISPLAY AND OPERATION 6.6 External I/O signal display The ON/OFF states of the digital I/O signals connected to the servo amplifier can be confirmed. (1) Operation Call the display screen shown after power-on. Using the "MODE" button, show the diagnostic screen. Press UP once.
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6. DISPLAY AND OPERATION (a) Control modes and I/O signals Connector (Note 2) Symbols of I/O signals in control modes Signal input/output (Note 1) I/O Pin No. P P/S S S/T T T/P Related parameter CR CR/SP1 SP1 SP1 SP1 SP1/CR No.43 to 48 OP OP OP /INP No.49 RD RD No.49 8 I 14 O OP OP OP 18 O INP INP/SA SA 19 O RD RD RD (Note 3) 4 O DO1 DO1 DO1 DO1 DO1 DO1 5 I SON SON SON SON SON SON 6 O TLC 7 I 8 I 9 I 14 CN1A CN1B SA/ RD No.
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6.
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6. DISPLAY AND OPERATION 6.7 Output signal (DO) forced output POINT When the servo system is used in a vertical lift application, turning on the electromagnetic brake interlock signal after assigning it to pin CN1B-19 will release the electromagnetic brake, causing a drop. Take drop preventive measures on the machine side. The output signal can be forced on/off independently of the servo status. This function is used for output signal wiring check, etc.
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6. DISPLAY AND OPERATION 6.8 Test operation mode CAUTION The test operation mode is designed to confirm servo operation and not to confirm machine operation. In this mode, do not use the servo motor with the machine. Always use the servo motor alone. If any operational fault has occurred, stop operation using the forced stop (EMG) signal. POINT The test operation mode cannot be used in the absolute position detection system. Use it after choosing "Incremental system" in parameter No. 1.
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6. DISPLAY AND OPERATION 6.8.2 Jog operation Jog operation can be performed when there is no command from the external command device. (1) Operation Connect EMG-SG to start jog operation and connect VDD-COM to use the internal power supply. Hold down the "UP" or "DOWN" button to run the servo motor. Release it to stop. When using the servo configuration software, you can change the operation conditions.
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6. DISPLAY AND OPERATION 6.8.3 Positioning operation POINT The servo configuration software is required to perform positioning operation. Positioning operation can be performed once when there is no command from the external command device. (1) Operation Connect EMG-SG to start positioning operation and connect VDD-COM to use the internal power supply.
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6. DISPLAY AND OPERATION 6.8.4 Motor-less operation Without connecting the servo motor, you can provide output signals or monitor the status display as if the servo motor is running in response to external input signals. This operation can be used to check the sequence of a host programmable controller or the like. (1) Operation After turning off the signal across SON-SG, choose motor-less operation. After that, perform external operation as in ordinary operation.
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7. GENERAL GAIN ADJUSTMENT 7. GENERAL GAIN ADJUSTMENT POINT For use in the torque control mode, you need not make gain adjustment. 7.1 Different adjustment methods 7.1.1 Adjustment on a single servo amplifier The gain adjustment in this section can be made on a single servo amplifier. For gain adjustment, first execute auto tuning mode 1. If you are not satisfied with the results, execute auto tuning mode 2, manual mode 1 and manual mode 2 in this order.
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7. GENERAL GAIN ADJUSTMENT (2) Adjustment sequence and mode usage START Usage Interpolation made for 2 or more axes? Yes Interpolation mode No Operation Allows adjustment by merely changing the response level setting. First use this mode to make adjustment. Auto tuning mode 1 Operation Yes No OK? No Operation OK? Used when the conditions of auto tuning mode 1 are not met and the load inertia moment ratio could not be estimated properly, for example.
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7. GENERAL GAIN ADJUSTMENT 7.2 Auto tuning 7.2.1 Auto tuning mode The servo amplifier has a real-time auto tuning function which estimates the machine characteristic (load inertia moment ratio) in real time and automatically sets the optimum gains according to that value. This function permits ease of gain adjustment of the servo amplifier. (1) Auto tuning mode 1 The servo amplifier is factory-set to the auto tuning mode 1.
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7. GENERAL GAIN ADJUSTMENT 7.2.2 Auto tuning mode operation The block diagram of real-time auto tuning is shown below. Load inertia moment Automatic setting Command Encoder Control gains PG1,VG1 PG2,VG2,VIC Current control Servo motor Current feedback Set 0 or 1 to turn on. Gain table Parameter No. 2 0 1 0 7 Real-time auto tuning section Switch Load inertia moment ratio estimation section Position/speed feedback Speed feedback Parameter No.
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7. GENERAL GAIN ADJUSTMENT 7.2.3 Adjustment procedure by auto tuning Since auto tuning is made valid before shipment from the factory, simply running the servo motor automatically sets the optimum gains that match the machine. Merely changing the response level setting value as required completes the adjustment. The adjustment procedure is as follows.
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7. GENERAL GAIN ADJUSTMENT 7.2.4 Response level setting in auto tuning mode Set the response (The first digit of parameter No.2) of the whole servo system. As the response level setting is increased, the trackability and settling time for a command decreases, but a too high response level will generate vibration. Hence, make setting until desired response is obtained within the vibrationfree range.
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7. GENERAL GAIN ADJUSTMENT 7.3 Manual mode 1 (simple manual adjustment) If you are not satisfied with the adjustment of auto tuning, you can make simple manual adjustment with three parameters. 7.3.1 Operation of manual mode 1 In this mode, setting the three gains of position control gain 1 (PG1), speed control gain 2 (VG2) and speed integral compensation (VIC) automatically sets the other gains to the optimum values according to these gains.
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7. GENERAL GAIN ADJUSTMENT (c)Adjustment description 1) Speed control gain 2 (parameter No. 37) This parameter determines the response level of the speed control loop. Increasing this value enhances response but a too high value will make the mechanical system liable to vibrate.
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7. GENERAL GAIN ADJUSTMENT (c) Adjustment description 1) Position control gain 1 (parameter No. 6) This parameter determines the response level of the position control loop. Increasing position control gain 1 improves trackability to a position command but a too high value will make overshooting liable to occur at the time of settling.
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7. GENERAL GAIN ADJUSTMENT 7.4 Interpolation mode The interpolation mode is used to match the position control gains of the axes when performing the interpolation operation of servo motors of two or more axes for an X-Y table or the like. In this mode, the position control gain 2 and speed control gain 2 which determine command trackability are set manually and the other parameter for gain adjustment are set automatically.
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7. GENERAL GAIN ADJUSTMENT 7.5 Differences in auto tuning between MELSERVO-J2 and MELSERVO-J2-Super 7.5.1 Response level setting To meet higher response demands, the MELSERVO-J2-Super series has been changed in response level setting range from the MELSERVO-J2 series. The following table lists comparison of the response level setting. Parameter No.
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7.
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8. SPECIAL ADJUSTMENT FUNCTIONS 8. SPECIAL ADJUSTMENT FUNCTIONS POINT The functions given in this chapter need not be used generally. Use them if you are not satisfied with the machine status after making adjustment in the methods in Chapter 7. If a mechanical system has a natural resonance point, increasing the servo system response may cause the mechanical system to produce resonance (vibration or unusual noise) at that resonance frequency.
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8. SPECIAL ADJUSTMENT FUNCTIONS You can use the machine resonance suppression filter 1 (parameter No. 58) and machine resonance suppression filter 2 (parameter No. 59) to suppress the vibration of two resonance frequencies. Note that if adaptive vibration suppression control is made valid, the machine resonance suppression filter 1 (parameter No. 58) is made invalid. Machine resonance point Mechanical system response Frequency Notch depth Frequency Parameter No. 58 Parameter No.
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8. SPECIAL ADJUSTMENT FUNCTIONS POINT If the frequency of machine resonance is unknown, decrease the notch frequency from higher to lower ones in order. The optimum notch frequency is set at the point where vibration is minimal. A deeper notch has a higher effect on machine resonance suppression but increases a phase delay and may increase vibration. The machine characteristic can be grasped beforehand by the machine analyzer on the servo configuration software.
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8. SPECIAL ADJUSTMENT FUNCTIONS (2) Parameters The operation of adaptive vibration suppression control selection (parameter No.60). Parameter No. 60 0 0 Adaptive vibration suppression control selection Choosing "valid" or "held" in adaptive vibration suppression control selection makes the machine resonance suppression filter 1 (parameter No. 58) invalid. 0: Invalid 1: Valid Machine resonance frequency is always detected to generate the filter in response to resonance, suppressing machine vibration.
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8. SPECIAL ADJUSTMENT FUNCTIONS 8.5 Gain changing function This function can change the gains. You can change between gains during rotation and gains during stop or can use an external signal to change gains during operation. 8.5.1 Applications This function is used when: (1) You want to increase the gains during servo lock but decrease the gains to reduce noise during rotation. (2) You want to increase the gains during settling to shorten the stop settling time.
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8. SPECIAL ADJUSTMENT FUNCTIONS 8.5.3 Parameters When using the gain changing function, always set " 4 " in parameter No.2 (auto tuning) to choose the manual mode of the gain adjustment modes. The gain changing function cannot be used in the auto tuning mode. Parameter Abbrevi No. ation Name Unit Description Position and speed gains of a model used to set the response level to a command. Always valid.
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8. SPECIAL ADJUSTMENT FUNCTIONS (1) Parameters No. 6, 34 to 38 These parameters are the same as in ordinary manual adjustment. Gain changing allows the values of ratio of load inertia moment to servo motor inertia moment, position control gain 2, speed control gain 2 and speed integral compensation to be changed. (2) Ratio of load inertia moment to servo motor inertia moment 2 (GD2B: parameter No. 61) Set the ratio of load inertia moment to servo motor inertia moment after changing.
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8. SPECIAL ADJUSTMENT FUNCTIONS 8.5.4 Gain changing operation This operation will be described by way of setting examples. (1) When you choose changing by external input (a) Setting Parameter No. Abbreviation Name Setting Unit 6 PG1 Position control gain 1 100 rad/s 36 VG1 Speed control gain 1 1000 rad/s 34 GD2 Ratio of load inertia moment to servo motor inertia moment 4 0.
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8. SPECIAL ADJUSTMENT FUNCTIONS (2) When you choose changing by droop pulses (a) Setting Parameter No. Abbreviation Setting Unit 6 PG1 Position control gain 1 Name 100 rad/s 36 VG1 Speed control gain 1 1000 rad/s 34 GD2 Ratio of load inertia moment to servo motor inertia moment 40 0.1 times 35 PG2 Position control gain 2 120 rad/s 37 VG2 Speed control gain 2 3000 rad/s 38 VIC Speed integral compensation 20 ms 100 0.
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8.
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9. INSPECTION 9. INSPECTION WARNING Before starting maintenance and/or inspection, make sure that the charge lamp is off more than 10 minutes after power-off. Then, confirm that the voltage is safe in the tester or the like. Otherwise, you may get an electric shock. Any person who is involved in inspection should be fully competent to do the work. Otherwise, you may get an electric shock. For repair and parts replacement, contact your safes representative.
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9.
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10. TROUBLESHOOTING 10. TROUBLESHOOTING 10.1 Trouble at start-up CAUTION Excessive adjustment or change of parameter setting must not be made as it will make operation instable. POINT Using the optional servo configuration software, you can refer to unrotated servo motor reasons, etc. The following faults may occur at start-up. If any of such faults occurs, take the corresponding action. 10.1.1 Position control mode (1) Troubleshooting No. 1 2 3 Start-up sequence Power on Fault LED is not lit.
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10. TROUBLESHOOTING No. 4 5 Start-up sequence Gain adjustment Cyclic operation Fault Investigation Possible cause Refer to Rotation ripples (speed fluctuations) are large at low speed. Make gain adjustment in the Gain adjustment fault following procedure: 1. Increase the auto tuning response level. 2. Repeat acceleration and deceleration several times to complete auto tuning. Chapter 7 Large load inertia moment causes the servo motor shaft to oscillate side to side.
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10. TROUBLESHOOTING (2) How to find the cause of position shift Positioning unit Servo amplifier (a) Output pulse counter Electronic gear (parameters No.
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10. TROUBLESHOOTING 10.1.2 Speed control mode No. 1 2 3 4 Start-up sequence Power on Fault LED is not lit. LED flickers. Investigation Possible cause Refer to 1. Power supply voltage fault Not improved if connectors CN1A, CN1B, CN2 and CN3 2. Servo amplifier is faulty. are disconnected. Improved when connectors CN1A and CN1B are disconnected. Power supply of CN1 cabling is shorted. Improved when connector CN2 is disconnected. 1. Power supply of encoder cabling is shorted. 2. Encoder is faulty.
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10. TROUBLESHOOTING 10.1.3 Torque control mode No. 1 2 3 Start-up sequence Power on Fault LED is not lit. LED flickers. Investigation Possible cause Refer to 1. Power supply voltage fault Not improved if connectors CN1A, CN1B, CN2 and CN3 2. Servo amplifier is faulty. are disconnected. Improved when connectors CN1A and CN1B are disconnected. Power supply of CN1 cabling is shorted. Improved when connector CN2 is disconnected. 1. Power supply of encoder cabling is shorted. 2. Encoder is faulty.
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10. TROUBLESHOOTING 10.2 When alarm or warning has occurred POINT Configure up a circuit which will detect the trouble (ALM) signal and turn off the servo-on (SON) signal at occurrence of an alarm. 10.2.1 Alarms and warning list When a fault occurs during operation, the corresponding alarm or warning is displayed. If any alarm or warning has occurred, refer to Section 10.2.2 or 10.2.3 and take the appropriate action. 1" in parameter No.
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10. TROUBLESHOOTING 10.2.2 Remedies for alarms CAUTION When any alarm has occurred, eliminate its cause, ensure safety, then reset the alarm, and restart operation. Otherwise, injury may occur. If an absolute position erase alarm (AL.25) occurred, always make home position setting again. Otherwise, misoperation may occur. POINT When any of the following alarms has occurred, always remove its cause and allow about 30 minutes for cooling before resuming operation.
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10. TROUBLESHOOTING Display Name Definition Cause AL.17 AL.19 Board error 2 CPU/parts fault Faulty parts in the servo amplifier Memory error 3 ROM memory fault Checking method Alarm (AL.17 or AL.19) occurs if power is switched on after CN1A, CN1B and CN3 connectors are disconnected. AL.1A Motor combination error Encoder error 2 AL.20 AL.24 Main circuit error AL.25 Absolute position erase AL.30 Regenerative alarm Wrong combination of servo anplifier and servo motor.
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10. TROUBLESHOOTING Display AL.31 Name Overspeed Definition Cause Speed has exceeded 1. Input command pulse frequency the instantaneous exceeded the permissible permissible speed. instantaneous speed frequency. Action Set command pulses correctly. Increase acceleration/deceleration time 2. Small acceleration/deceleration time constant caused overshoot to constant. be large. AL.32 AL.33 Overcurrent Overvoltage 3. Servo system is instable to cause overshoot. 1. Re-set servo gain to proper value.
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10. TROUBLESHOOTING Display AL.35 AL.37 AL.45 AL.46 AL.50 Name Definition Input pulse Command pulse frequency frequency of the command pulse is error too high. Parameter error Overload 1 Action Change the command pulse frequency to a proper value. 2. Noise entered command pulses. Take action against noise. 3. Command device failure Change the command device. Parameter setting is 1. Servo amplifier fault caused the Change the servo amplifier. wrong. parameter setting to be rewritten.
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10. TROUBLESHOOTING Display AL.51 Name Overload 2 Definition Cause Machine collision or 1. Machine struck something. the like caused max. output current to 2. Wrong connection of servo motor. flow successively for Servo amplifier's output terminals several seconds. U, V, W do not match servo Servo motor locked: motor's input terminals U, V, W. 1s or more 3. Servo system is instable and hunting. 4. Encoder faulty. Action 1. Review operation pattern. 2. Install limit switches. Connect correctly. 1.
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10. TROUBLESHOOTING Display 88888 Name Watchdog Definition CPU, parts faulty Cause Action Fault of parts in servo amplifier Change servo amplifier. Checking method Alarm (88888) occurs if power is switched on after CN1A, CN1B and CN3 connectors are disconnected. 10.2.3 Remedies for warnings If AL.E6 or AL.EA occurs, the servo off status is established. If any other warning occurs, operation can be continued but an alarm may take place or proper operation may not be performed.
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11. OUTLINE DIMENSION DRAWINGS 11. OUTLINE DIMENSION DRAWINGS 11.1 Servo amplifiers (1) MR-J2S-10A to MR-J2S-60A MR-J2S-10A1 to MR-J2S-40A1 [Unit: mm] 6 ( 0.24) mounting hole 70 (2.76) 20 B 6 (0.24) ([Unit: in]) 135 (5.32) Terminal layout (Terminal cover open) (0.79) A MITSUBISHI MITSUBISHI 168 (6.61) 156 (6.14) OPEN OPEN C N 1 A C N 1 B C N 2 E N C C N 3 TE1 L1 L2 C N 1 B C N 2 E N C C N 3 L3 (Note) 6 (0.24) 7 (0.28) Name plate C N 1 A U V W TE2 PE terminal 6 (0.
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11. OUTLINE DIMENSION DRAWINGS (2) MR-J2S-70A MR-J2S-100A [Unit: mm] 70(2.76) ([Unit: in]) 190(7.48) 20 6 (0.24) 70(2.76) 22 (0.87) Terminal layout (Terminal cover open) (0.79) 6 ( 0.24) mounting hole MITSUBISHI MITSUBISHI 7 (0.28) 6(0.24) 168(6.61) 156(6.14) OPEN OPEN C N 1 A C N 1 B C N 2 E N C C N 3 L1 L2 L3 U V W 6(0.24) 22 42 (0.87) (1.65) Name plate PE terminal TE2 TE1 6(0.24) 6(0.24) Weight [kg]([lb]) Servo amplifier MR-J2S-70A 1.7 (3.
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11. OUTLINE DIMENSION DRAWINGS (3) MR-J2S-200A MR-J2S-350A [Unit: mm] ([Unit: in]) 6 (0.24) 6 ( 0.24) mounting hole 6 (0.24) 70(2.76) 90(3.54) 78(3.07) 195(7.68) Terminal layout MITSUBISHI 168(6.61) 156(6.14) MITSUBISHI TE2 TE1 PE terminal Fan air orientation Weight [kg]([lb]) Servo amplifier MR-J2S-200A 2.0 (4.41) MR-J2S-350A PE terminals TE1 L1 L2 L3 U V W Terminal screw: M4 Tightening torque: 1.24 [N m] (175.6 [oz in]) Terminal screw: M4 Tightening torque: 1.24 [N m] (175.
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11. OUTLINE DIMENSION DRAWINGS (4) MR-J2S-500A [Unit: mm] ([Unit: in]) OPEN (0.79) (0.24) 130(5.12) (0.24) 70 6 6 (2.76) 118(4.65) 20 7.5 (0.5) 2- 6( 0.24) mounting hole 200(7.87) (0.19) 5 Terminal layout MITSUBISHI MITSUBISHI 235(9.25) 250(9.84) OPEN C N 1 B C N 1 A C N 1 B C N 2 C N 3 C N 2 C N 3 TE2 N.P. N.P. Fan 7.5 (0.5) OPEN TE1 C N 1 A Fan 6(0.24) Fan air orientation Servo amplifier Weight [kg]([lb]) MR-J2S-500A 4.9(10.
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11. OUTLINE DIMENSION DRAWINGS (5) MR-J2S-700A 70 10 (2.76) 180(7.09) 160(6.23) 7.5 (0.5) (0.39) 10 20 (0.39) 200(7.87) 138(5.43) 62 (0.79) 2- 6( 0.24) mounting hole (2.44) [Unit: mm] ([Unit: in]) 6(0.24) Terminal layout MITSUBISHI MITSUBISHI OPEN OPEN C N 1 A C N 1 B C N 1 A C N 1 B C N 2 C N 3 C N 2 C N 3 350(13.8) 335(13.2) TE2 OPEN TE1 Fan 7.5 (0.5) 6 (0.24) Fan air orientation Servo amplifier Weight [kg]([lb]) MR-J2S-700A 7.2(15.
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11. OUTLINE DIMENSION DRAWINGS 11.2 Connectors (1) Servo amplifier side <3M > (a) Soldered type Model Connector Shell kit [Unit: mm] ([Unit: in]) : 10120-3000VE : 10320-52F0-008 10.0(0.39) 12.0(0.47) 14.0 (0.55) 22.0 (0.87) 39.0 (1.54) 23.8 (0.94) Logo, etc. are indicated here. 33.3 (1.31) 12.7(0.50) (b) Threaded type 33.3 (1.31) 12.7 (0.50) 10.0 14.0 (0.55) 12.0 (0.47) 27.4 (1.08) 5.7 (0.22) 39.0 (1.54) 23.8 (0.94) 22.0 (0.87) [Unit: mm] ([Unit: in]) (0.
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11. OUTLINE DIMENSION DRAWINGS (2) Bus cable connector PCR-LS20LA1 PCR-LS20LA1W 10.4 (0.409) 13.0 (0.512) 20.6 (0.811) 14.2 (0.559) 38.5 (1.516) HONDA 38.5 (1.516) HONDA 1 12.2 1 (0.039) (0.48) (0.039) 23.0 (0.906) RS RS 27.4 (1.079) 32.0 (0.906) 1 1.9 (0.039) 12.2 27.4 (1.079) 32.0 (0.906) (0.075) 1 (0.039) (0.
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11.
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12. CHARACTERISTICS 12. CHARACTERISTICS 12.1 Overload protection characteristics An electronic thermal relay is built in the servo amplifier to protect the servo motor and servo amplifier from overloads. The operation characteristics of the electronic thermal relay are shown below. Overload 1 alarm (AL.50) occurs if overload operation performed is above the electronic thermal relay protection curve shown below. Overload 2 alarm (AL.
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12. CHARACTERISTICS (3) MR-J2S-500A MR-J2S-700A HC-SFS series HC-RFS series HC-UFS series 10000 Operation time[s] 1000 During servo lock During rotation 100 10 1 0 50 100 150 200 250 Load ratio [%] Fig 12.
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12. CHARACTERISTICS 12.2 Power supply equipment capacity and generated loss (1) Amount of heat generated by the servo amplifier Table 12.1 indicates servo amplifiers' power supply capacities and losses generated under rated load. For thermal design of an enclosure, use the values in Table 12.1 in consideration for the worst operating conditions. The actual amount of generated heat will be intermediate between values at rated torque and zero torque according to the duty used during operation.
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12. CHARACTERISTICS (2) Heat dissipation area for enclosed servo amplifier The enclosed control box (hereafter called the control box) which will contain the servo amplifier should be designed to ensure that its temperature rise is within 10 at the ambient temperature of 40 . (With a 5 (41 ) safety margin, the system should operate within a maximum 55 (131 ) limit.) The necessary enclosure heat dissipation area can be calculated by Equation 12.1: P .........................................................
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12. CHARACTERISTICS 12.3 Dynamic brake characteristics Fig. 12.4 shows the pattern in which the servo motor comes to a stop when the dynamic brake is operated. Use Equation 12.2 to calculate an approximate coasting distance to a stop. The dynamic brake time constant varies with the servo motor and machine operation speeds. (Refer to Fig. 12.5) Emergency stop(EMG) ON OFF Time constant V0 Machine speed te Time Fig. 12.5 Dynamic brake operation diagram Lmax Lmax Vo JM JL te JL V0 te 1 .................
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Time constant [ms] 16 14 12 10 8 6 4 2 0 0 Time constant [s] 12. CHARACTERISTICS 23 43 13 500 1000 1500 2000 2500 3000 Speed [r/min] 0.02 0.018 0.016 0.014 0.012 0.01 0.008 0.006 0.004 0.002 0 0 23 73 053 43 13 500 1000 1500 2000 2500 3000 Speed [r/min] a. HC-KFS series b. HC-MFS series 0.045 0.04 121 0.03 Time constant [s] Time constant [s] 0.035 201 0.025 0.02 301 0.015 0.01 81 0.005 0 0 50 500 Speed [r/min] 1000 0.04 0.035 Time constant [s] 0.06 353 103 0.02 0 0 50 52 502 0.
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12. CHARACTERISTICS Use the dynamic brake at the load inertia moment indicated in the following table. If the load inertia moment is higher than this value, the built-in dynamic brake may burn. If there is a possibility that the load inertia moment may exceed the value, contact Mitsubishi. Servo amplifier Load inertia moment ratio [times] MR-J2S-10A to MR-J2S-200A MR-J2S-10A1 to MR-J2S-40A1 30 MR-J2S-350A 16 MR-J2S-500A MR-J2S-700A 15 12.
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12.
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13. OPTIONS AND AUXILIARY EQUIPMENT 13. OPTIONS AND AUXILIARY EQUIPMENT WARNING Before connecting any option or auxiliary equipment, make sure that the charge lamp is off more than 10 minutes after power-off, then confirm the voltage with a tester or the like. Otherwise, you may get an electric shock. CAUTION Use the specified auxiliary equipment and options. Unspecified ones may lead to a fault or fire. 13.1 Options 13.1.
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13. OPTIONS AND AUXILIARY EQUIPMENT Unbalance torque Servo motor speed (b) To make selection according to regenerative energy Use the following method when regeneration occurs continuously in vertical motion applications or when it is desired to make an in-depth selection of the regenerative brake option: a. Regenerative energy calculation Use the following table to calculate the regenerative energy.
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13. OPTIONS AND AUXILIARY EQUIPMENT Subtract the capacitor charging from the result of multiplying the sum total of regenerative energies by the inverse efficiency to calculate the energy consumed by the regenerative brake option. ER [J] Es Ec Calculate the power consumption of the regenerative brake option on the basis of single-cycle operation period tf [s] to select the necessary regenerative brake option. PR [W] ER/tf .....................................................................................
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13. OPTIONS AND AUXILIARY EQUIPMENT (4) Connection of the regenerative brake option The regenerative brake option will generate heat of about 100 . Fully examine heat dissipation, installation position, used cables, etc. before installing the option. For wiring, use flame-resistant cables and keep them clear of the regenerative brake option body. Always use twisted cables of max. 5m(16.4ft) length for connection with the servo amplifier.
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13. OPTIONS AND AUXILIARY EQUIPMENT When using the regenerative brake resistor option, remove the servo amplifier's built-in regenerative brake resistor terminals (across P-C), fit them back to back, and secure them to the frame with the accessory screw as shown below. Mounting method Accessory screw For MR-J2S-500A For MR-J2S-700A Accessory screw Accessory screw For the MR-RB51 install the cooling fan as shown.
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13. OPTIONS AND AUXILIARY EQUIPMENT (5) Outline drawing (a) MR-RB032 MR-RB12 [Unit: mm (in)] LA 12 (0.47) 6 (0.23) 6 (0.24) mounting hole LB 144 (5.67) 5 (0.20) 6 (0.23) 12 (0.47) G3 G4 P C 6 (0.23) TE1 168 (6.61) 156 (6.14) MR-RB 1.6 (0.06) 20 (0.79) LD LC Regenerative Regenerative Resistance brake option power[W] [ ] MR-RB032 30 40 MR-RB12 100 40 (b) MR-RB32 MR-RB30 MR-RB31 Variable dimensions LA LB LC LD 30 15 119 99 (1.18) (0.59) (4.69) (3.9) 40 15 169 149 (1.57) (0.59) (6.
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13. OPTIONS AND AUXILIARY EQUIPMENT 13.1.2 Brake unit POINT The brake unit and resistor unit of other than 200V class are not applicable to the servo amplifier. The brake unit and resistor unit of the same capacity must be combined. The units of different capacities may result in damage. The brake unit and resistor unit must be installed on a vertical surface in the vertical direction. If they are installed in the horizontal direction or on a horizontal surface, a heat dissipation effect reduces.
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13. OPTIONS AND AUXILIARY EQUIPMENT The cables between the servo amplifier and brake unit and between the resistor unit and brake unit should be as short as possible. The cables longer than 5m(16.404ft) should be twisted. If twisted, the cables must not be longer than 10m(32.808ft). The cable size should be equal to or larger than the recommended size. See the brake unit instruction manual. You cannot connect one set of brake unit to two servo amplifiers or two sets of brake units to one servo amplifier.
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13. OPTIONS AND AUXILIARY EQUIPMENT (b) Resistor unit (FR-BR) EE (E) 204 Eye bolt (8.031) 33 (1.299) C 5 (0.197) AA 5 (0.197) FR-BR-55K Two eye bolts are provided (as shown below). 40 (1.575) EE (E) (Note) (F) Control circuit terminals Main circuit terminals BB 3 (0.118) B 5 (0.197) BA 1 (0.039) K 2- D (F) [Unit : mm(in)] A 5 (0.197) Note: Ventilation ports are provided in both side faces and top face. The bottom face is open. Resistor Unit Model A AA FR-BR15K 170 (6.693) 100 (3.
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13. OPTIONS AND AUXILIARY EQUIPMENT (2) Connection example Servo amplifier L11 L21 NFB Power factor improving reactor MC FR-BAL L1 Power supply 3-phase 200V or 230VAC L2 L3 VDD COM ALM RA2 EM1 SG SG Always remove wiring across P-C. N N/ P C P/ 5m(16.
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13. OPTIONS AND AUXILIARY EQUIPMENT (3) Outside dimensions of the power return converters [Unit : mm(in)] Mounting foot (removable) Mounting foot movable E 2- D hole Rating plate Display panel window BA B Front cover Cooling fan K F EE D AA C A Heat generation area outside mounting dimension Power return converter A AA B BA C D E EE K F Approx. Weight [kg(Ib)] FR-RC-15K 270 200 450 432 195 (10.630) (7.874) (17.717) (17.008) (7.677) 10 (0.394) 10 (0.394) 8 (0.315) 3.2 (0.
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13. OPTIONS AND AUXILIARY EQUIPMENT 13.1.4 Cables and connectors (1) Cable make-up The following cables are used for connection with the servo motor and other models. Those indicated by broken lines in the figure are not options.
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13. OPTIONS AND AUXILIARY EQUIPMENT No. Product Model Description Connector: 10120-3000VE Shell kit: 10320-52F0-008 (3M or equivalent) Housing : 1-172161-9 Connector pin : 170359-1 (AMP or equivalent) Application Standard flexing life IP20 1) Standard encoder MR-JCCBL M-L cable Refer to (2) in this section. 2) Long flexing life encoder cable 3) Standard encoder MR-JHSCBL M-L Connector: 10120-3000VE cable Refer to (2) in this Shell kit: 10320-52F0-008 (3M or equivalent) section.
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13. OPTIONS AND AUXILIARY EQUIPMENT No. 9) 10) 11) Product 16) 17) 18) 19) Application Connector: 10120-3000VE Shell kit: 10320-52F0-008 (3M or equivalent) Junction terminal block cable MR-J2TBL M Refer to Section13.1.5. Connector: HIF3BA-20D-2.54R (Hirose Electric) Junction terminal block MR-TB20 Refer to Section 13.1.5. Bus cable MR-J2HBUS M Refer to section13.1.6.
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13. OPTIONS AND AUXILIARY EQUIPMENT (2) Encoder cable CAUTION If you have fabricated the encoder cable, connect it correctly. Otherwise, misoperation or explosion may occur. POINT The encoder cable is not oil resistant. Refer to Section 12.4 for the flexing life of the encoder cable. Generally use the encoder cable available as our options. If the required length is not found in the options, fabricate the cable on the customer side.
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13.
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13. OPTIONS AND AUXILIARY EQUIPMENT (b) MR-JHSCBL M-L MR-JHSCBL M-H MR-ENCBL M-H These encoder cables are used with the HC-SFS HC-RFS HC-UFS2000r/min series servo motors. 1) Model explanation Model: MR-JHSCBL MSymbol Specifications L Standard flexing life H Long flexing life Symbol Cable length [m(ft)] 2 5 10 20 30 40 50 2 (6.56) 5 (16.4) 10 (32.8) 20 (65.6) 30 (98.4) 40 (131.2) 50 (164.0) Note: MR-JHSCBL M-L has no 40(131.2) and 50m(164.0ft) sizes.
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13.
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13. OPTIONS AND AUXILIARY EQUIPMENT (3) Communication cable POINT This cable may not be used with some personal computers. After fully examining the signals of the RS-232C connector, refer to this section and fabricate the cable.
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13. OPTIONS AND AUXILIARY EQUIPMENT 13.1.5 Junction terminal block (MR-TB20) POINT When using the junction terminal block, you cannot use SG of CN1A-20 and CN1B-20. Use SG of CN1A-4 and CN1B-4. (1) How to use the junction terminal block Always use the junction terminal block (MR-TB20) with the junction terminal block cable (MRJ2TBL M) as a set.
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13. OPTIONS AND AUXILIARY EQUIPMENT (4) Junction terminal block cable (MR-J2TBL M) Model : MR-J2TBL M Symbol Cable length[m(ft)] 05 0.5 (1.64) 1 1 (3.28) Junction terminal block side connector (Hirose Electric) HIF3BA-20D-2.54R (connector) Servo amplifier side (CN1A CN1B) connector (3M) 10120-6000EL (connector) 10320-3210-000 (shell kit) (Note) Symbol Junction terminal Position control mode Speed control mode Torque control mode block terminal No.
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13. OPTIONS AND AUXILIARY EQUIPMENT 13.1.6 Maintenance junction card (MR-J2CN3TM) (1) Usage The maintenance junction card (MR-J2CN3TM) is designed for use when a personal computer and analog monitor outputs are used at the same time.
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13. OPTIONS AND AUXILIARY EQUIPMENT (4) Bus cable (MR-J2HBUS M) Model: MR-J2HBUS M Symbol Cable length [m(ft)] 05 1 5 0.5 (1.64) 1 (3.28) 5 (16.4) MR-J2HBUS05M MR-J2HBUS1M MR-J2HBUS5M 10120-6000EL (connector) 10320-3210-000 (shell kit) 1 11 2 12 3 13 4 14 5 15 6 16 7 17 8 18 9 19 10 20 1 11 2 12 3 13 4 TD 14 TD* 5 LG 15 LG 6 16 EMG 7 EMG* 17 8 18 BAT 9 19 10 20 LG LG RD RD* SD 10120-6000EL (connector) 10320-3210-000 (shell kit) Plate Plate 13.1.
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13. OPTIONS AND AUXILIARY EQUIPMENT 13.1.8 Servo configurations software The servo configuration software uses the communication function of the servo amplifier to perform parameter setting changes, graph display, test operation, etc. on a personal computer. (1) Specifications Item Description Communication signal Baudrate [bps] Conforms to RS-232C. 57600, 38400, 19200, 9600 Batch display, high-speed display, graph display (Minimum resolution changes with the processing speed of the personal computer.
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13. OPTIONS AND AUXILIARY EQUIPMENT (b) Configuration diagram 1) When using RS-232C Servo amplifier Personal computer Communication cable CN3 CN2 Servo motor To RS-232C connector 2) When using RS-422 You can make multidrop connection of up to 32 axes.
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13. OPTIONS AND AUXILIARY EQUIPMENT 13.2 Auxiliary equipment Always use the devices indicated in this section or equivalent. To comply with the EN Standard or UL/CUL Standard, use the products which conform to the corresponding standard. 13.2.1 Recommended wires (1) Wires for power supply wiring The following diagram shows the wires used for wiring. Use the wires given in this section or equivalent.
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13. OPTIONS AND AUXILIARY EQUIPMENT Use wires 6) of the following sizes with the brake unit (FR-BU) and power return converter (FR-RC). Model Wires[mm2] FR-BU-15K FR-BU-30K FR-BU-55K FR-RC-15K 3.5(AWG12) 5.5(AWG10) 14(AWG6) 14(AWG6) Table 13.
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13. OPTIONS AND AUXILIARY EQUIPMENT 13.2.2 No-fuse breakers, fuses, magnetic contactors Always use one no-fuse breaker and one magnetic contactor with one servo amplifier. When using a fuse instead of the no-fuse breaker, use the one having the specifications given in this section.
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13. OPTIONS AND AUXILIARY EQUIPMENT 13.2.4 Relays The following relays should be used with the interfaces: Interface Selection example Relay used especially for switching on-off analog input To prevent defective contacts , use a relay for small signal command and input command (interface DI-1) signals (twin contacts). (Ex.) Omron : type G2A , MY Relay used for digital output signals (interface DO-1) Small relay with 12VDC or 24VDC of 40mA or less (Ex.) Omron : type MY 13.2.
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13. OPTIONS AND AUXILIARY EQUIPMENT (b) Reduction techniques for external noises that cause the servo amplifier to malfunction If there are noise sources (such as a magnetic contactor, an electromagnetic brake, and many relays which make a large amount of noise) near the servo amplifier and the servo amplifier may malfunction, the following countermeasures are required. Provide surge absorbers on the noise sources to suppress noises. Attach data line filters to the signal cables.
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13. OPTIONS AND AUXILIARY EQUIPMENT Noise transmission route Suppression techniques 1) 2) 3) When measuring instruments, receivers, sensors, etc. which handle weak signals and may malfunction due to noise and/or their signal cables are contained in a control box together with the servo amplifier or run near the servo amplifier, such devices may malfunction due to noises transmitted through the air. The following techniques are required.
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13. OPTIONS AND AUXILIARY EQUIPMENT (b) Surge suppressor The recommended surge suppressor for installation to an AC relay, AC valve, AC electromagnetic brake or the like near the servo amplifier is shown below. Use this product or equivalent. MS Relay Surge suppressor Surge suppressor Surge suppressor This distance should be short (within 20cm(0.79 in.)). (Ex.) 972A.2003 50411 (Matsuo Electric Co.,Ltd. 200VAC rating) Outline drawing [Unit: mm] ([Unit: in.
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13. OPTIONS AND AUXILIARY EQUIPMENT Outline drawing [Unit: mm] ([Unit: in.]) Earth plate Clamp section diagram 2- 5(0.20) hole installation hole 6 (0.24) 10(0.39) 0.3 0 24 22(0.87) 35(1.38) Note: Screw hole for grounding. Connect it to the earth plate of the control box. Type A B C Accessory fittings Clamp fitting L AERSBAN-DSET 100 (3.94) 86 (3.39) 30 (1.18) clamp A: 2pcs. A 70 (2.76) AERSBAN-ESET 70 (2.76) 56 (2.20) clamp B: 1pc. B 45 (1.77) 13 - 33 (0.940) A C 35 (1.
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13. OPTIONS AND AUXILIARY EQUIPMENT (d) Line noise filter (FR-BLF, FR-BSF01) This filter is effective in suppressing noises radiated from the power supply side and output side of the servo amplifier and also in suppressing high-frequency leakage current (zero-phase current) especially within 0.5MHz to 5MHz band. Connection diagram Outline drawing [Unit: mm] ([Unit: in.
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13. OPTIONS AND AUXILIARY EQUIPMENT 13.2.7 Leakage current breaker (1) Selection method High-frequency chopper currents controlled by pulse width modulation flow in the AC servo circuits. Leakage currents containing harmonic contents are larger than those of the motor which is run with a commercial power supply. Select a leakage current breaker according to the following formula, and ground the servo amplifier, servo motor, etc. securely.
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13. OPTIONS AND AUXILIARY EQUIPMENT (2) Selection example Indicated below is an example of selecting a leakage current breaker under the following conditions: 2mm2 5m 2mm2 5m NV Servo amplifier MR-J2S-60A Ig1 Iga SM Ig2 Servo motor HC-MFS73 Igm Use a leakage current breaker generally available. Find the terms of Equation (13.2) from the diagram: Ig1 20 5 1000 0.1 [mA] Ig2 20 5 1000 0.1 [mA] Ign 0 (not used) Iga 0.1 [mA] Igm 0.1 [mA] Insert these values in Equation (13.2): Ig 10 {0.
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13. OPTIONS AND AUXILIARY EQUIPMENT 13.2.8 EMC filter For compliance with the EMC Directive of the EN Standard, it is recommended to use the following filter: (1) Combination with the servo amplifier Recommended filter Servo amplifier MR-J2S-10A to MR-J2S-100A MR-J2S-10A1 to MR-J2S-40A1 MR-J2S-200A MR-J2S-350A Model Leakage current [mA] SF1252 38 Weight [kg]([lb]) 0.75 (1.65) SF1253 57 1.37 (1.65) MR-J2S-500A (Note) HF-3040A-TM 1.5 5.5 (12.13) MR-J2S-700A (Note) HF-3050A-TM 1.5 6.7 (14.
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13. OPTIONS AND AUXILIARY EQUIPMENT HF3040-TM HF-3050A-TM K L G F E D L M C J C H B A Model Dimensions [mm(in)] A B C D E F G H J HF3040A-TM 260 (10.23) 210 (8.27) 85 (3.35) 155 (6.10) 140 (5.51) 125 (4.92) 44 (1.73) 140 (5.51) 70 (2.76) HF3050A-TM 290 (11.42) 240 (9.45) 100 (3.94) 190 (7.48) 175 (6.89) 160 (6.30) 44 (1.73) 170 (5.51) 100 (3.94) 13 - 38 K R3.
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14. COMMUNICATION FUNCTIONS 14. COMMUNICATION FUNCTIONS This servo amplifier has the RS-422 and RS-232C serial communication functions. These functions can be used to perform servo operation, parameter changing, monitor function, etc. However, the RS-422 and RS-232C communication functions cannot be used together. Select between RS422 and RS-232C with parameter No.16. (Refer to Section 14.2.2.) 14.1 Configuration 14.1.
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14. COMMUNICATION FUNCTIONS 14.1.2 RS-232C configuration (1) Outline A single axis of servo amplifier is operated. Servo amplifier MITSUBISHI CHARGE To CN3 RS-232C Controller such as personal computer (2) Cable connection diagram Wire as shown below. The communication cable for connection with the personal computer (MRCPCATCBL3M) is available. (Refer to Section 13.1.4.) Personal computer connector D-SUB25 (socket) (Note 3) (Note 2) 15m(49.2ft) max.
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14. COMMUNICATION FUNCTIONS 14.2 Communication specifications 14.2.1 Communication overview This servo amplifier is designed to send a reply on receipt of an instruction. The device which gives this instruction (e.g. personal computer) is called a master station and the device which sends a reply in response to the instruction (servo amplifier) is called a slave station. When fetching data successively, the master station repeatedly commands the slave station to send data.
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14. COMMUNICATION FUNCTIONS 14.2.2 Parameter setting When the RS-422/RS-232C communication function is used to operate the servo, set the communication specifications of the servo amplifier in the corresponding parameters. After setting the values of these parameters, they are made valid by switching power off once, then on again. (1) Serial communication baudrate Choose the communication speed. Match this value to the communication speed of the sending end (master station). Parameter No.
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14. COMMUNICATION FUNCTIONS 14.3 Protocol POINT Whether station number setting will be made or not must be selected if the RS-232C communication function is used. Note that choosing "no station numbers" in parameter No. 53 will make the communication protocol free of station numbers as in the MR-J2-A servo amplifiers. Since up to 32 axes may be connected to the bus, add a station number or group to the command, data No., etc. to determine the destination servo amplifier of data communication.
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14. COMMUNICATION FUNCTIONS (2) Transmission of data request from the controller to the servo S O H S T X Data No. E T X Check sum Station number or group S T X Station number or group Servo side (Slave station) Error code Controller side (Master station) Command 10 frames Data* 6 frames (data) (3) Recovery of communication status by time-out Controller side (Master station) EOT causes the servo to return to the receive neutral status.
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14. COMMUNICATION FUNCTIONS 14.4 Character codes (1) Control codes Code name Hexadecimal Personal computer terminal key operation Description (ASCII code) (General) SOH 01H start of head ctrl A STX 02H start of text ctrl B ETX 03H end of text ctrl C EOT 04H end of transmission ctrl D (2) Codes for data JIS8 unit codes are used.
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14. COMMUNICATION FUNCTIONS 14.5 Error codes Error codes are used in the following cases and an error code of single-code length is transmitted. On receipt of data from the master station, the slave station sends the error code corresponding to that data to the master station. The error code sent in upper case indicates that the servo is normal and the one in lower case indicates that an alarm occurred.
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14. COMMUNICATION FUNCTIONS 14.7 Time-out operation The master station transmits EOT when the slave station does not start reply operation (STX is not received) 300[ms] after the master station has ended communication operation. 100[ms] after that, the master station retransmits the message. Time-out occurs if the slave station does not answer after the master station has performed the above operation three times.
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14. COMMUNICATION FUNCTIONS 14.9 Initialization After the slave station is switched on, it cannot reply to communication until the internal initialization processing terminates. Hence, at power-on, ordinary communication should be started after: (1) 1s or more time has elapsed after the slave station is switched on; and (2) Making sure that normal communication can be made by reading the parameter or other data which does not pose any safety problems. 14.
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14. COMMUNICATION FUNCTIONS 14.11 Command and data No. list 14.11.1 Read commands (1) Status display (Command [0][1]) Command Data No.
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14. COMMUNICATION FUNCTIONS (5) Current alarm (Command [0][2] [3][5]) Command [0][2] Data No. [0][0] Current alarm number Command Data No.
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14. COMMUNICATION FUNCTIONS (5) Operation mode selection (Command [8][B]) Command Data No. [8][B] [0][0] Description Operation mode changing Setting range Frame length 0000 to 0004 4 Setting range Frame length 0000: Exit from test operation mode 0001: Jog operation 0002: Positioning operation 0003: Motor-less operation 0004: Output signal (DO) forced output (6) External input signal disable (Command [9][0]) Command Data No.
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14. COMMUNICATION FUNCTIONS 14.12 Detailed explanations of commands 14.12.1 Data processing When the master station transmits a command data No. or a command data No. data to a slave station, the servo amplifier returns a reply or data according to the purpose. When numerical values are represented in these send data and receive data, they are represented in decimal, hexadecimal, etc. Therefore, data must be processed according to the application.
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14. COMMUNICATION FUNCTIONS (2) Writing the processed data When the data to be written is handled as decimal, the decimal point position must be specified. If it is not specified, the data cannot be written. When the data is handled as hexadecimal, specify "0" as the decimal point position. The data to be sent is the following value. 0 Data is transferred in hexadecimal.
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14. COMMUNICATION FUNCTIONS 14.12.2 Status display (1) Status display data read When the master station transmits the data No. (refer to the following table for assignment) to the slave station, the slave station sends back the data value and data processing information. 1) Transmission Transmit command [0][1] and the data No. corresponding to the status display item to be read. Refer to Section 14.11.1. 2) Reply The slave station sends back the status display data requested.
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14. COMMUNICATION FUNCTIONS 14.12.3 Parameter (1) Parameter read Read the parameter setting. 1) Transmission Transmit command [0][5] and the data No. corresponding to the parameter No. The data No. is expressed in hexadecimal equivalent of the data No. value corresponds to the parameter number. Command Data No. [0][5] [0][0] to [5][4] 2) Reply The slave station sends back the data and processing information of the requested parameter No. Data is transferred in hexadecimal.
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14. COMMUNICATION FUNCTIONS (2) Parameter write POINT The number of parameter write times is restricted to 1,000,000 times. Write the parameter setting. Write the value within the setting range. Refer to Section 5.1 for the setting range. Transmit command [8][4], the data No., and the set data. The data No. is expressed in hexadecimal. The decimal equivalent of the data No. value corresponds to the parameter number.
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14. COMMUNICATION FUNCTIONS 14.12.4 External I/O pin statuses (DIO diagnosis) (1) External input pin status read Read the ON/OFF statuses of the external input pins. (a) Transmission Transmit command [1][2] and data No. [4][0]. Command Data No. [1][2] [4][0] (b) Reply The ON/OFF statuses of the input pins are sent back. b31 b1 b0 1: ON 0: OFF Command of each bit is transmitted to the master station as hexadecimal data.
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14. COMMUNICATION FUNCTIONS 14.12.5 Disable/enable of external I/O signals (DIO) Inputs can be disabled independently of the external I/O signal ON/OFF. When inputs are disabled, the input signals are recognized as follows. Among the external input signals, EMG, LSP and LSN cannot be disabled.
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14. COMMUNICATION FUNCTIONS 14.12.6 External input signal ON/OFF (test operation) Each input signal can be turned on/off for test operation. Turn off the external input signals. Send command [9] [2], data No. [0] [0] and data. Command Data No. [9][2] [0][0] Set data See below b31 b1 b0 1: ON 0: OFF Command of each bit is transmitted to the slave station as hexadecimal data.
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14. COMMUNICATION FUNCTIONS 14.12.7 Test operation mode (1) Instructions for test operation mode The test operation mode must be executed in the following procedure. If communication is interrupted for longer than 0.5s during test operation, the servo amplifier causes the motor to be decelerated to a stop and servo-locked. To prevent this, continue communication without a break, e.g. monitor the status display. (a) Execution of test operation 1) Turn off all external input signals.
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14. COMMUNICATION FUNCTIONS (2) Jog operation Transmit the following communication commands: (a) Setting of jog operation data Item Command Data No. Data Speed Acceleration/decelerati on time constant [A][0] [A][0] [1][0] [1][1] Write the speed [r/min] in hexadecimal. Write the acceleration/deceleration time constant [ms] in hexadecimal. (b) Start Turn on the external input signals SON and ST1/ST2 by using command [9][2] Item Command Data No.
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14. COMMUNICATION FUNCTIONS 14.12.8 Output signal pin ON/OFF output signal (DO) forced output In the test operation mode, the output signal pins can be turned on/off independently of the servo status. Using command [9][0], disable the output signals in advance. (1) Choosing DO forced output in test operation mode Transmit command [8][B] data No. [0][0] data "0004" to choose DO forced output.
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14. COMMUNICATION FUNCTIONS 14.12.9 Alarm history (1) Alarm No. read Read the alarm No. which occurred in the past. The alarm numbers and occurrence times of No. 0 (last alarm) to No. 5 (sixth alarm in the past) are read. (a) Transmission Send command [3][3] and data No. [1][0] to [1][5]. Refer to Section 14.11.1. (b) Reply The alarm No. corresponding to the data No. is provided. 0 0 Alarm No. is transferred in decimal. For example, “0032” means AL.32 and “00FF” means AL._ (no alarm).
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14. COMMUNICATION FUNCTIONS 14.12.10 Current alarm (1) Current alarm read Read the alarm No. which is occurring currently. (a) Transmission Send command [0][2] and data No. [0][0]. Command Data No. [0][2] [0][0] (b) Reply The slave station sends back the alarm currently occurring. 0 0 Alarm No. is transferred in decimal. For example, “0032” means AL.32 and “00FF” means AL._ (no alarm). (2) Read of the status display at alarm occurrence Read the status display data at alarm occurrence.
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14. COMMUNICATION FUNCTIONS 14.12.11 Other commands (1) Servo motor end pulse unit absolute position Read the absolute position in the servo motor end pulse unit. Note that overflow will occur in the position of 16384 or more revolutions from the home position. (a) Transmission Send command [0][2] and data No. [9][0]. Command Data No. [0][2] [9][0] (b) Reply The slave station sends back the requested servo motor end pulses. Absolute value is sent back in hexadecimal in the servo motor end pulse unit.
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15. ABSOLUTE POSITION DETECTION SYSTEM 15. ABSOLUTE POSITION DETECTION SYSTEM CAUTION If an absolute position erase alarm (AL.25) has occurred, always perform home position setting again. Not doing so can cause runaway. 15.1 Outline 15.1.1 Features For normal operation, as shown below, the encoder consists of a detector designed to detect a position within one revolution and a cumulative revolution counter designed to detect the number of revolutions.
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15. ABSOLUTE POSITION DETECTION SYSTEM 15.2 Specifications (1) Specification list Item Description System Electronic battery backup system 1 piece of lithium battery ( primary battery, nominal Battery 3.6V) Type: MR-BAT or A6BAT Maximum revolution range Home position (Note 1) Maximum speed at power failure 500r/min (Note 2) Battery backup time Approx. 10,000 hours (battery life with power off) (Note 3) Data holding time during battery 32767 rev.
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15. ABSOLUTE POSITION DETECTION SYSTEM 15.3 Battery installation procedure Before starting battery installation procedure, make sure that the charge lamp is off more than 10 minutes after power-off. Then, confirm that the voltage is safe in the tester or the like. Otherwise, you may get an electric shock. WARNING POINT The internal circuits of the servo amplifier may be damaged by static electricity. Always take the following precautions: Ground human body and work bench.
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15. ABSOLUTE POSITION DETECTION SYSTEM 15.
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15. ABSOLUTE POSITION DETECTION SYSTEM 15.5 Signal explanation When the absolute position data is transferred, the signals of connector CN1 change as described in this section. They return to the previous status on completion of data transfer. The other signals are as described in Section 3.3.2. For the I/O interfaces (symbols in the I/O Category column in the table), refer to Section 3.6. Signal name ABS transfer mode ABS request Code ABSM ABSR Pin No.
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15. ABSOLUTE POSITION DETECTION SYSTEM 15.6 Startup procedure (1) Battery installation. Refer to Section 15.3 installation of absolute position backup battery. (2) Parameter setting Set "1 "in parameter No. 1 of the servo amplifier and switch power off, then on. (3) Resetting of absolute position erase alarm (AL.25) After connecting the encoder cable, the absolute position erase alarm (AL.25) occurs at first power-on.
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15. ABSOLUTE POSITION DETECTION SYSTEM 15.7 Absolute position data transfer protocol POINT After switching on the ABS transfer mode (ABSM), turn on the servo-on signal (SON). When the ABS transfer mode is off, turning on the servo-on signal (SON) does not switch on the base circuit. 15.7.1 Data transfer procedure Each time the SON signal is turned ON (when the power is switched ON for example), the programmable controller reads the position data (present position) of the servo amplifier.
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15. ABSOLUTE POSITION DETECTION SYSTEM 15.7.2 Transfer method The sequence in which the base circuit is turned ON (servo-on) when it is in the OFF state due to the servo-on signal (SON) going OFF, an emergency stop, or alarm, is explained below. In the absolute position detection system, every time the servo-on (SON) signal is turned on, the ABS transfer mode (ABSM) signal should always be turned on to read the current position in the servo amplifier to the controller.
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15. ABSOLUTE POSITION DETECTION SYSTEM 1) The ready signal (RD) is turned ON when the ABS transfer mode signal (ABSM) is turned OFF after transmission of the ABS data. While the ready signal (RD) is ON, the ABS transfer mode signal (ABSM) input is not accepted. 2) Even if the servo-on (SON) signal is turned ON before the ABS transfer mode signal (ABSM) is turned ON, the base circuit is not turned ON until the ABS transfer mode signal (ABSM) is turned ON.
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15. ABSOLUTE POSITION DETECTION SYSTEM (c) Checksum The check sum is the code which is used by the programmable controller to check for errors in the received ABS data. The 6-bit check sum is transmitted following the 32-bit ABS data. At the programmable controller, calculate the sum of the received ABS data using the ladder program and compare it with the check sum code sent from the servo. The method of calculating the check sum is shown.
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15. ABSOLUTE POSITION DETECTION SYSTEM (2) Transmission error (a) Time-out warning(AL.E5) In the ABS transfer mode, the time-out processing shown below is executed at the servo. If a timeout error occurs, an ABS time-out warning (AL.E5) is output. The ABS time-out warning (AL.E5) is cleared when the ABS transfer mode (ABSM) changes from OFF to ON.
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15. ABSOLUTE POSITION DETECTION SYSTEM 3) ABS transfer mode finish-time time-out check If the ABS transfer mode signal is not turned OFF within 5s after the last ready to send signal (19th signal for ABS data transmission) is turned ON, it is regarded as the transmission error and the ABS time-out warning (AL.E5) is output. 5s ON ABS transfer mode OFF Signal is not turned OFF 1 ON 2 3 4 18 19 ABS request OFF ON Send data ready 1 OFF 2 3 4 18 19 Yes AL.
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15. ABSOLUTE POSITION DETECTION SYSTEM (3) At the time of alarm reset If an alarm occurs, turn OFF the servo-on (SON) signal by detecting the alarm output (ALM). If an alarm has occurred, the ABS transfer mode signal (ABSM) cannot be accepted. In the reset state, the ABS transfer mode signal (ABSM) can be input.
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15. ABSOLUTE POSITION DETECTION SYSTEM (4) At the time of emergency stop reset (a) If the power is switched ON in the emergency stop state The emergency stop state can be reset while the ABS data is being transferred. If the emergency stop state is reset while the ABS data is transmitted, the base circuit is turned ON 80[ms] after resetting. If the ABS transfer mode signal (ABSM) is OFF when the base circuit is turned ON, the ready signal (RD) is turned ON 20[ms] after the turning ON of the base circuit.
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15. ABSOLUTE POSITION DETECTION SYSTEM (b) If emergency stop is activated during servo-on The ABS transfer mode signal (ABSM) is permissible while in the emergency stop state. In this case, the base circuit and the ready signal (RD) are turned ON after the emergency stop state is reset.
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15. ABSOLUTE POSITION DETECTION SYSTEM 15.7.3 Home position setting (1) Dog type home position return Preset a home position return creep speed at which the machine will not be given impact. On detection of a zero pulse, the home position setting signal (CR) is turned from off to on. At the same time, the servo amplifier clears the droop pulses, comes to a sudden stop, and stores the stop position into the non-volatile memory as the home position ABS data.
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15. ABSOLUTE POSITION DETECTION SYSTEM (2) Data set type home position return Move the machine to the position where the home position is to be set by performing manual operation such as jog operation to turn the motor shaft more than one revolution. When the home position setting signal (CR) is on for longer than 20ms, the stop position is stored into the non-volatile memory as the home position ABS data.
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15. ABSOLUTE POSITION DETECTION SYSTEM 15.7.4 Use of servo motor with electromagnetic brake The timing charts at power on/off and servo-on (SON) on/off are given below. Preset " 1 " in parameter No. 1 to make the electromagnetic brake interlock signal (MBR) usable. When the ABS transfer mode is ON, the electromagnetic brake interlock (MBR) is used as the ABS data bit 1.
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15. ABSOLUTE POSITION DETECTION SYSTEM 15.7.5 How to process the absolute position data at detection of stroke end The servo amplifier stops the acceptance of the command pulse when stroke end (LSP LSN) is detected, clears the droop pulses to 0 at the same time, and stops the servo motor rapidly. At this time, the programmable controller keeps outputting the command pulse.
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15. ABSOLUTE POSITION DETECTION SYSTEM 15.8 Examples of use 15.8.1 MELSEC-A1S (A1SD71) (1) Instructions The absolute coordinate system (programmable controller coordinate system) of the A1SD71 (AD71) only covers the range in which the address increases (positive coordinate values) on moving away from the machine home position (the position reached in the home position return operation).
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15. ABSOLUTE POSITION DETECTION SYSTEM If the address of the machine home position is changed to any coordinate value other than "0", the programmable controller coordinate system will be as illustrated below. The power should be turned ON/OFF in the range in which the address increases on moving away from the home position.
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15. ABSOLUTE POSITION DETECTION SYSTEM (d) Slot arrangement The sequence programs presented in this section show I/O numbers (X, Y) assuming the arrangement of modules on the main base unit is as illustrated below. A1SD71 is mounted at I/O slots 0 and 1, a 16-point input module at slot 2, and 16-point output module at slot 3. If the actual arrangement of the modules differs from this arrangement, change the X and Y numbers accordingly. The numbers of the devices (M, D, T, etc.
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15. ABSOLUTE POSITION DETECTION SYSTEM (3) Sequence program example (a) Conditions This sample program is an ABS sequence program example for a single axis (X axis). To transmit the ABS data using the OFF-to-ON change of the servo-on signal as the trigger. 1) When the servo-ON signal and the GND of the power supply are shorted, the ABS data is transmitted when the power to the servo amplifier power is turned ON, or at the leading edge of the RUN signal after a PC reset operation (PC-RESET).
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15. ABSOLUTE POSITION DETECTION SYSTEM (c) ABS data transfer program for X axis This sequence program example assumes the following conditions: Parameters of the A1SD71-S2 (AD71) positioning module 1) Unit setting : 3 pulse (PLS) 2) Travel per pulse : 1 1 pulse To select the unit other than the pulse, conversion into the unit of the feed command value per pulse is required. Hence, add the following program to the area marked Note in the sequence program.
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15. ABSOLUTE POSITION DETECTION SYSTEM (d) X-axis control program This precludes execution of the X-axis start program while M3 (ready to send the ABS data) is OFF. Positioning X-axis start mode command M3 X-axis start program Ready to send the ABS date When M3 (ready to send the ABS data) is turned ON, the X-axis start command executes the X-axis start program.
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15. ABSOLUTE POSITION DETECTION SYSTEM (g) Electromagnetic brake output During ABS data transfer (for several seconds after the servo-on signal is turned on), the servo motor must be at a stop. Set "1 1 "in parameter No. 1 of the servo amplifier to choose the electromagnetic brake interlock signal. Y41 X31 Y44 Electromagnetic brake output ABS Brake (MBR) transfer mode (h) Positioning completion To create the status information for servo positioning completion.
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15. ABSOLUTE POSITION DETECTION SYSTEM (4) Sequence program - 2-axis control The following program is a reference example for creation of an ABS sequence program for the second axis (Y axis) using a single A1SD71 module. Create a program for the third axis in a similar manner. (a) Y-axis program Refer to the X-axis ABS sequence program and create the Y-axis program.
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15. ABSOLUTE POSITION DETECTION SYSTEM 15.8.2 MELSEC FX(2N)-32MT (FX(2N)-1PG) (1) Connection diagram (a) FX-32MT (FX-1PG) Servo amplifier FX-32MT L 24V COM RUN 3.
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15. ABSOLUTE POSITION DETECTION SYSTEM (b) FX2N-32MT (FX2N-1PG) Servo amplifier FX2N-32MT L 24V Power supply N SG COM 3.
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15. ABSOLUTE POSITION DETECTION SYSTEM (2) Sequence program example (a) Conditions 1) Operation pattern ABS data transfer is made as soon as the servo-on pushbutton is turned on. After that, positioning operation is performed as shown below: Home position 3) 300000 1) 300000 0 address 2) After the completion of ABS data transmission, JOG operation is possible using the JOG or JOG pushbutton switch.
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15. ABSOLUTE POSITION DETECTION SYSTEM (c) ABS data transfer program for X-axis M8002 DMOV K0 D24 Setting home position address to 0 K1 Setting 1PG pulse command unit Initial pulse 1 TO K0 K3 K0 DTO K0 K4 K100000 K1 1PG max.
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15. ABSOLUTE POSITION DETECTION SYSTEM 6 (Continued from preceding page) 6 M8000 K0 K25 K4M100 K1 FX2 1PG Transmission of control signals FROM K0 K28 K3M200 K1 1PG FX2 Transmission of status DFROMK0 K26 D106 K1 RST M108 1PG FX2 Transmission of present position D106, D107 1PG Resetting start command TO Normally ON M200 END (d) Data set type home position return After jogging the machine to the position where the home position (e.g.
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15. ABSOLUTE POSITION DETECTION SYSTEM (e) Electromagnetic brake output During ABS data transfer (for several seconds after the servo-on signal is turned on), the servo motor must be at a stop. Set "1 1 " in parameter No. 1 of the servo amplifier to choose the electromagnetic brake interlock signal. Y1 X1 Y4 Electromagnetic brake output ABS transfer Brake (MBR) mode (f) Positioning completion To create the status information for servo positioning completion.
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15. ABSOLUTE POSITION DETECTION SYSTEM 15.8.
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15. ABSOLUTE POSITION DETECTION SYSTEM Note 1: For the dog type home position return. Need not be connected for the data set type home position return. 2: If the servo motor provided with the zero point signal is started, the A1SD75(AD75) will output the deviation counter clear signal. Therefore, do not connect the clear signal of the MR-J2-A to the A1SD75(AD75) but connect it to the output module of the programmable controller. 3: This circuit is provided for your reference.
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15. ABSOLUTE POSITION DETECTION SYSTEM (2) Sequence program example (a) Conditions 1) When the servo-on signal and power supply GND are shorted, the ABS data is transmitted at power-on of the servo amplifier or on the leading edge of the RUN signal after a PC reset operation (PC-RESET). The ABS data is also transmitted when an alarm is reset or when an emergency stop is reset. 2) If a checksum mismatch is detected in the transmitted data, data transmission is retried up to three times.
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15. ABSOLUTE POSITION DETECTION SYSTEM (c) ABS data transfer program for X axis This sequence program example assumes the following conditions: Parameters of the A1SD75-P1 (AD75-P1) positioning module 1) Unit setting :3 pulse (PLS) 2) Travel per pulse :1 1 pulse To select the unit other than the pulse, conversion into the unit of the feed value per pulse is required.
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15. ABSOLUTE POSITION DETECTION SYSTEM (d) X-axis program Do not execute the X-axis program while the ABS ready (M8) is off. Positioning X-axis start mode command (Note) M8 X-axis start program Ready to send ABS data When "M8" (ready to send ABS data) switches on, the X-axis start program is executed by the X-axis start command. (e) Dog type home position return Refer to the home position return program in the A1SD75 User’s Manual.
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15. ABSOLUTE POSITION DETECTION SYSTEM (f) Data set type home position return After jogging the machine to the position where the home position (e.g. 500) is to be set, choose the home position return mode and set the home position with the home position return start (PBON). After switching power on, rotate the servo motor more than 1 revolution before starting home position return. Do not turn ON the clear signal (Y35) for an operation other than home position return.
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15. ABSOLUTE POSITION DETECTION SYSTEM (g) Electromagnetic brake output During ABS data transfer (for several seconds after the servo-on signal is turned on), the servo motor must be at a stop. Set "1 1 " in parameter No. 1 of the servo amplifier to choose the electromagnetic brake interlock signal. Y31 X21 Y34 Electromagnetic brake output ABS transfer Brake (MBR) mode (h) Positioning completion To create the status information for servo positioning completion.
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15. ABSOLUTE POSITION DETECTION SYSTEM (3) Sequence program - 2-axis control The following program is a reference example for creation of an ABS sequence program for the second axis (Y axis) using a single A1SD75 module. Create a program for the third axis in a similar manner. (a) Y-axis program Refer to the X-axis ABS sequence program and create the Y-axis program.
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15. ABSOLUTE POSITION DETECTION SYSTEM (4) Differences between A1SD75 (AD75) and A1SD71 (AD71) The sequence programs shown in (2) of this section differ from those for the A1SD71 (AD71) in the following portions. 1) to 20) in the following sentences indicate the numbers in the programs given in (2) of this section.
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15. ABSOLUTE POSITION DETECTION SYSTEM 6) Writing absolute position data to A1SD75 The slot number and buffer address of the X-axis current value changing area are changed from [DTOP H0001 K41 D3 K1] to [DTOP H0000 K1154 D3 K1] 14). When the current value is changed in the A1SD75, the current feed value is changed at the start of positioning data No.9003. Therefore, the starting program for positioning data No.9003 15) is added.
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15. ABSOLUTE POSITION DETECTION SYSTEM 15.9 Confirmation of absolute position detection data You can confirm the absolute position data with servo configuration software (MRZJW3-SETUP121E). Choose "Diagnostics" and "Absolute Encoder Data" to open the absolute position data display screen. (1) Choosing "Diagnostics" in the menu opens the sub-menu as shown below: (2) By choosing "Absolute Encoder Data" in the sub-menu, the absolute encoder data display window appears.
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15. ABSOLUTE POSITION DETECTION SYSTEM 15.10 Absolute position data transfer errors 15.10.1 Corrective actions (1) Error list The number within parentheses in the table indicates the output coil or input contact number of the A1SD71 (AD71). Name (Note) ABS communication error ABS data check sum error ABS coordinate error Servo alarm Output coil AD71 1PG Y49 Y4A Cause Y11 1. The ABS data transfer mode signal (Y41) is not completed within 5s. 2.
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15. ABSOLUTE POSITION DETECTION SYSTEM (2) ABS communication error (a) The OFF period of the send data ready signal output from the servo amplifier is checked. If the OFF period is 1s or longer, this is regarded as a transfer fault and the ABS communication error is generated. The ABS communication error occurs if the ABS time-out warning (AL.E5) is generated at the servo amplifier due to an ABS request ON time time-out.
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15. ABSOLUTE POSITION DETECTION SYSTEM (c) To detect the ABS time-out warning (AL.E5) at the servo amplifier, the time required for the ABS request signal to go OFF after it has been turned ON (ABS request time) is checked. If the ABS request remains ON for longer than 1s, it is regarded that an fault relating to the ABS request signal or the send data ready signal has occurred, and the ABS communication error is generated. The ABS communication error occurs if the ABS time-out warning (AL.
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Appendix App 1.
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Command pulse PP, NP Command pulse frequency App - 2 Cumulative feedback pulse CMX CDV Electronic gear Cumulative command pulses Position control Load inertia moment ratio Auto tuning section Droop pulse Differential M Within one-revolution ABS counter ABS counter PWM Peak hold Effective value calculation Absolute position detection encoder Servo motor Bus voltage Peak load ratio Effective load ratio Current control low Within onerevolution position high Speed control Present posi
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REVISIONS *The manual number is given on the bottom left of the back cover. Print data *Manual number Revision Nov.,1999 SH(NA)030006-A First edition Sep.,2000 SH(NA)030006-B Addition of single-phase 100VAC specifications Compatible Servo Configuration software model name change Compliance with EC Directives 1: Review of sentence Section 1.2: Review of function block diagram Section 1.
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Print data *Manual number Sep.,2000 SH(NA)030006-B Feb.,2001 SH(NA)030006-C Revision Section 10.2.2: Addition of description to AL.30 Addition of Cause to AL.33 Chapter 11: Changed to only outline dimensional drawing Section 11.2 (2): Addition Section 12.2 (1): Review of Note for Table 12.1 Section 12.3: Correction of dynamic brake time constant graph Chapter 13: Deletion of MR-CPC98CBL3M communication cable Section 13.1.1 (4)(c): Review of outline drawing Section 13.1.
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