KUC711AE101 3BHB004661R0101 CI854AK01 3BSE030220R1 3BHE039724R0C3D PPD513AOC-100440 PFSK162 3BSE015088R1 Use according to instructions
The security function STO is specifically designed to provide functional security by preventing system restarts. In order to achieve this functional safety, the wiring of the safety circuit must comply with the safety requirements of IEC 60204, ISO 12100, and IEC 62061 SIL CL2, which are ISO 13849-1 PLd, respectively. If STO is automatically activated by the control system, ensure that there is no possible malfunction in the output monitoring control device. 6.9.4 Prohibition of use. If the drive is inactive due to the following reasons, the STO function must not be used
Reason:
--Cleaning, maintenance, and repair operations, prolonged inactivity: In this case, the entire system should be manned and secured (main switch).
--Emergency shutdown situation: The power contactor must be closed (through the emergency shutdown button).
connection
When using STO wiring leads outside the control cabinet, the cables must be laid durable (firmly) to prevent external damage (such as in cable ducts), and separately protected in different sheaths or through grounding connections. The wiring inside the required enclosure must comply with the requirements of IEC 60204-1 standard.PFSK152 3BSE018877R1 PFSK151 3BSE018876R1 PFSA140 3BSE006503R1 PFTL101B 5.0KN 3BSE004191R1 PFEA111-20 3BSE050090R20 PFEA111-65 3BSE050090R65 PFEA113-65 3BSE050092R65 UAC389AE01 HIEE300888R0001 GFD563A102 3BHE046836R0102 PPC905AE101 Electrical Installation Guidelines
Correct wiring is the foundation for reliable operation of servo systems. Arrange power cables and control cables separately. We suggest maintaining a distance of at least 200mm. This improves anti-interference performance. If a motor power cable is used, it includes a core for brake control, which must be individually shielded. Ground both ends of the shield. Ground all shields on a large area (low impedance) and use metalized connector shells or shield connection clips as much as possible. Attention Regarding connection technology, please refer to page 52. The feedback line may not be extended as shielding may be interrupted and signal processing may be disrupted. The line braking resistor between the amplifier and the external must be shielded. Install all power cables with sufficient cross-section according to IEC 60204 (page 28) and use the required cable materials (page 53) to achieve maximum values. Cable length.
Each SM128V occupies a single slot in the VME rack.
1. Carefully open the packaging of the card. Use a grounding wire or release any static electricity before touching the card and remove it from oneself.
2. Place the card welding face down on a uniform, clean, and dry surface to set the DIP switch as required.
3. Turn off the VME bus rack.
4. Use the two sliding elements (handles) between the thumb and index finger to hold each finger of the card.
5. Carefully slide the card into the corresponding slot of the VME system.
6. Before sliding the card into the end, ensure that the two guide pins at the rear are secure3BHE014070R0101 PFVK135 3BSE007135R1 KUC755AE117 3BHB005243R0117 PCD530A102 3BHE041343R0102 SYN5201A-Z,V277 3BHB006714R0277 KUC755AE117 3BHB005243R0117 CMA130 3DDE300410 PCD237A101 3BHE028915R0101 PCD235A101 3BHE032025R0101 PFCA401SF 3BSE024387R4 SYN5201A-Z V217 3BHB006714R0217 V217 3BHB006714R0217 SYN5302-0277 SYN5201A-Z V217 3BHB006714R0217KUC711AE101
3BHB004661R0101 CI854AK01 3BSE030220R1 3BHE039724R0C3D PPD513AOC-100440 PFSK162 3BSE015088R1 PFSK152 3BSE018877R1 PFSK151 3BSE018876R1 PFSA140 3BSE006503R1 PFTL101B 5.0KN 3BSE004191R1 PFEA111–20 3BSE050090R20 PFEA111–65 3BSE050090R65 PFEA113–65 3BSE050092R65 UAC389AE01 HIEE300888R0001 GFD563A102 3BHE046836R0102 PPC905AE101 3BHE014070R0101 PFVK135 3BSE007135R1 KUC755AE117 3BHB005243R0117 PCD530A102 3BHE041343R0102 SYN5201A-Z,V277 3BHB006714R0277 KUC755AE117 3BHB005243R0117 CMA130 3DDE300410 PCD237A101 3BHE028915R0101 PCD235A101 3BHE032025R0101 PFCA401SF 3BSE024387R4 SYN5201A-Z V217 3BHB006714R0217 V217 3BHB006714R0217 SYN5302–0277
Slide the side of the front panel into the dedicated holes on the rack.
7. Unless already completed, lift the lower and upper sliding elements (handles) separately until they click.
8. Press your thumb on the front panel and push the card firmly to the back.
9. Use the two screws at the top and bottom of the front to secure the card to the upper panel of the rack. The GE90/70 system rack does not have an opening for the SM128V board card guide pin. If this fact is not taken into account when ordering the card, the guide pin must be removed before installing the card.
To remove a board from a VME rack, perform the following steps:
1. Turn off the power to the VME rack.
2. Loosen the screws on the front panel.
3. Press the two sliding elements (handles) apart. This will release
Card in the backplane connector.
4. Pull the card out of the slot.
Fiber optic connectors TX and RX (5) (6)
Channel 1 communicates bi-directional with compatible devices through TX and RX interface ports. Both ports use standard ST connectors. TX realizes fiber optic transmitter, while RX realizes fiber optic receiver.
The fiber optic connector TX (10) channel 2 communicates unidirectionally with compatible devices through the TX interface. This port uses standard ST type connectors. TX achieves fiber optic transmission for channel 2.KUC711AE101 3BHB004661R0101 CI854AK01 3BSE030220R1KUC711AE101 3BHB004661R0101 CI854AK01 3BSE030220R1 3BHE039724R0C3D PPD513AOC-100440 PFSK162 3BSE015088R1 PFSK152 3BSE018877R1 PFSK151 3BSE018876R1 PFSA140 3BSE006503R1 PFTL101B 5.0KN 3BSE004191R1 PFEA111-20 3BSE050090R20 PFEA111-65 3BSE050090R65 PFEA113-65 3BSE050092R65 UAC389AE01 HIEE300888R0001 GFD563A102 3BHE046836R0102 PPC905AE101 3BHE014070R0101 RJ11 connector channel 1 (11)
Channel 1 can send data unidirectionally to a single ibaPCMCIA-F device. This port uses the dedicated serial cable included with PCMCIA-F. Synchronize data transmission with optical channel 1. RJ11 connector channel 2 (12) channel 2 can send data unidirectionally to a single ibaPCMCIA-F device. This port uses the dedicated serial cable included with PCMCIA-F. Synchronize data transmission with optical channel 2.
The DIP switch on the board is located at the bottom of the board. They are used to set interrupts, data formats, and memory addresses. The service interface (D-sub 9) for loading firmware is also located in this area.
ALSPA CP80/A800 (AEG Logidyn D) settings ALSPA CP80/A800 is a high-performance name control system compatible with Alstom, CP80/A800, and Logidyn D from AEG. It is a VME based system for rapid control and regulation, developed by Alstom Power Conversion GmbH, Berlin, Germany, formerly known as AEG, AEG Daimler Benz, and AEG Cegelec. In order to use the ibaLink-SM-128V-i-2O board in this system, a modified version with a 16 bit VME backplane connector is required. The backplane of the lower system has a PMB bus in the rack. The engineering instructions for SM128V and ALSPA CP80/A800 (Logidyn D) can be found on the next page. You will find a 24 bit card setting example mode and an integer value for transmitting analog signals. The corresponding memory access can be managed in the LogiCAD program through subroutines (UP). These subroutines need to map the signal to be measured to the memory address of the board. Unable to provide a request solution for selecting the data to be measured through ibaPDA. This signal must be wired in the application. Allow the use of multiple cards in the rack. Setting of ALSPA C80 HPC (Logidyn D2)
PFVK135 3BSE007135R1 KUC755AE117 3BHB005243R0117 PCD530A102 3BHE041343R0102 SYN5201A-Z,V277 3BHB006714R0277 KUC755AE117 3BHB005243R0117 CMA130 3DDE300410 PCD237A101 3BHE028915R0101 PCD235A101 3BHE032025R0101 PFCA401SF 3BSE024387R4 SYN5201A-Z V217 3BHB006714R0217 V217 3BHB006714R0217 SYN5302-0277 SYN5201A-Z V217 3BHB006714R0217
