DE3706325A1 - Control and data network - Google Patents

Abstract

A control and data network is described in which a number of access modules (10) having in each case one processor (14) with associated components (15) and in each case at least one input circuit (21) and one output circuit (17) for receiving and outputting data and signals are connected in parallel to a bus (11). The system exhibits a common control computer (12) which calls up the access modules (10) by means of addressed messages via the bus (11) and transmits data and control information and receives responses from the access modules (10). As a special feature, the access modules (10) have a control input (24) which, when a predetermined control signal is present, can bring the access module into a predetermined emergency stop state. The control inputs of the access modules in the network are connected to a common emergency stop control line (25) so that the entire system can be brought in a simple manner into an emergency stop state when disturbances or safety problems occur. <IMAGE>

Description

The invention relates to a control and data network Work according to the preamble of claim 1.

In the industrial sector, it is often necessary a system consisting of several or many components with greater spatial expansion reliably over guard and control. To do this, you first have to build each part, each machine, each sensor, etc. separate Control, monitoring and power lines laid. Especially in the case of larger expansion and also at Later changes and extensions will then be the Effort and space requirements for the multitude of Connection lines too high. in addition, such Wiring confusing and difficult to maintain or is to be repaired in case of flow.

It is therefore already tried in a known manner been, the individual parts of the system for control, monitoring data transmission and data acquisition in parallel to one Switch on bus, for example a symmetrical one Two-wire bus. The individual system parts are for this Interface modules assigned, each with a processor and have associated components. A host computer transmits Telegrams addressed to the individual via the bus Interface modules, so that data and control Information about the interface modules and answers can be taken up by them.

An example of a distributed system in the industrial area with distances between each Components in the range up to several 100 m or more an automated warehouse with a variety of transportation facilities, light barriers, distance sensors, counters, Light switches, drive motors etc. The same applies to  the control of a large crane system, of ships or also on production lines and the like.

In all cases of this kind, it doesn't just happen depends on the effort for the control and data network to keep it as small as possible, but also the operational process as safe as possible even when faults occur shape.

The invention is accordingly based on the object a control and data network according to the generic term of Claim 1 towards high reliability and great To further develop operational safety. The solution to the task is specified in claim 1.

The individual interface modules of a control and Data network can therefore from the outside, for example by the master computer, or also through the individual interface modules yourself or even, for example, through an emergency switch in one Be brought into an emergency stop state, for example Contactors for motors, transport equipment, etc. be made to fall off. Since the emergency stop control line against all or at least certain interface modules are together, the whole plant can be shut down or be brought into a desired state if Malfunctions or security problems occur.

Developments of the invention are the subject of Subclaims. It can be provided that the emergency stop Control line in the normal operating state on a pre given voltage is maintained. Failing or falling off this voltage is then recognized as a control signal and evaluated.

The processor brings the output in an emergency stop state expediently in a predetermined signal state, preferably the switch-off status. If at the exit or one A contactor can be connected to the outputs For example, a motor controlled by the contactor or another electrical device can be switched off.

In addition, in a further embodiment of the invention be provided that at least certain connection module an enable line is looped through to  a locking circuit leads, and that the locks circuit the operation of the network and thus the System only releases if in all certain interface modules a predetermined switching process with respect to the release line is carried out. The switching process can include closing a relay con be tactful. Overall, the system can only in this way then go into operation when all or at least certain Interface modules via which the enable line is looped has released the operation, for example have closed the relay contact. In a similar way can save the entire system with the help of the release line Be put into operation, for example in the emergency stop state brought if in one of the connection modules in relay contact located on the enable line is opened.

Because in rough industrial use the electrical Security is important and appropriate regulations all inputs are advisable the interface modules including the bus connection and of the control input via voltage-proof optocouplers. Furthermore, creep and Clearances according to the respective regulations be respected. In addition, everyone will be expedient Outputs of the interface modules via voltage-proof optocouplers led, which are followed by output drivers, which from a special power supply with a voltage-proof network separation are fed.

To combine the power supply of the interface modules fold, they are appropriately from an industry-standard DC voltage of preferably 24 V over DC voltage converter fed with voltage-proof mains isolation.

The bus can be functional and known per se Way to be a symmetrical two-wire bus, that of the standardized Interface corresponds to RS485. Other common bus versions stanchions can also be used. The same can the connection between the individual interface modules too via fiber optics. Then for every transfer device requires a special optical fiber  Lich, and the transmitted light signals must be in each Interface module in corresponding electrical signals and then be converted back into light signals.

To further improve security and Each interface module expediently has operational safety a monitoring circuit on if a fault occurs Operation of the processor returns it to the initial state and informs the host computer of this. A such monitoring circuit is also because of its function referred to as "watchdog". When the monitoring responds circuit can then be in the release line Relay contact can be opened.

The invention is based on a the drawing schematically illustrated embodiment described.

The control and data network shown in the drawing has a number of interface modules 10 , of which the second module is shown more precisely and the first, third and nth modules are only shown schematically. The dashed line between the third and n- th module indicates that any number of additional interface modules 10 can be provided. All modules 10 are connected in parallel to a bus 11 , which in the present exemplary embodiment is a symmetrical two-wire bus of a known type. The bus 11 leads to a master computer 12 which controls and monitors the entire system. As a host computer 12 , for example, a so-called personal computer with an additional adapter can be used to connect to the bus 11 .

The master computer 12 connects to the interface modules 10 by transmitting telegrams or data packets via the bus 11 . The telegrams are transmitted in the form of serial bits. For example, in addition to a start flag and a stop flag, each with a plurality of bits, a telegram contains 21 bytes of data, including an address, which is each separately assigned to an interface module 10 . The addresses at a certain point in the telegrams are decoded in the individual interface modules 10 , and the respective interface module only responds to the telegram when it recognizes its own address. In response to the telegram, at least one confirmation telegram is then transmitted back to the host computer 12 by the respective module, optionally with additional or requested data or other information. All modules are queried regularly by the host computer by transmission of telegrams to ensure that waiting data can only be evaluated by the host computer 12 with a certain maximum delay. In addition, the individual interface modules can detect a fault condition if there is no regular query.

Each interface module 10 contains, as the second module shown in greater detail, a processor 14 as a central component. The processor 14 is assigned a memory 15 with additional components in the usual way, which contains the respective control programs including an operating system in addition to data. In the exemplary embodiment, a dual processor of the type INTEL 8044 is advantageously used. A subprocessor creates a serial bus protocol with speeds of up to 375 KBd for the telegrams to be transmitted back to the master computer 12 via the bus 11 , which can be transmitted up to 300 m without an additional repeater. The other subprocessor takes over the further processing operations in the connection module 10 and is hardly burdened by the complex bus protocol. The traffic between the two subprocessors takes place via the memory 15 .

The telegrams arriving from the master computer 12 via the bus 11 pass through the serial interface circuit 16 which contains an optocoupler with a dielectric strength of 3.5 kV for safe electrical isolation in accordance with the schematic illustration. If the processor 14, after decoding the address, determines that the telegram is intended for its own interface module 10 , the data and commands contained in the telegram are recorded and the respective data processing operations are carried out. For example, one of the output lines 18 of the output circuit 17 can be switched on and thus a contactor (not shown) controlled by the connection module 2 can be actuated. Also in the case of the output circuit 17 is connected between the output lines 19 of the processor 14 and the driver contained in the output circuit 17 for the output lines 18, a voltage-stable optocoupler connected. The grid separation is completed by a voltage-proof power supply 20 for the drivers of the output circuit 17th

As another example, the processor may also be transferred to a contained in the telegram from the master computer 12 to the host computer 12 command, data 14, the input circuit example (not shown) via input lines 21 from a sensor 22 Example received. The input circuit 21 in turn contains voltage-proof optocouplers in the direction of the input lines 23 of the processor 14 for all input lines 22 .

As a special feature, the connection modules 10 each have an emergency stop circuit 24 , which is connected to the processor 14 on the output side and is connected to a special wire 25 on the input side via a voltage-proof optocoupler. All connection modules 10 can be brought into a predetermined emergency stop state via this wire 25 , in which the processor 14 preferably switches off all output lines 18 . In the exemplary embodiment, the wire is, as shown schematically, via a resistor 26 in the host computer 12 on a positive potential. If the wire 25 is then grounded at any point, that is to say in the control computer 12 , in the interface modules or on the connecting links, the respective emergency stop circuit 24 recognizes this as an emergency stop command and carries out the corresponding operations via the processor 14 . In this way it can be ensured that the system can be brought into an idle or switched-off state in a defined manner even in the event of cable errors or other faults.

A further special feature of the interface modules 10 is an enable circuit 27 , which is connected on the input side to the processor 14 . On the output side, a special wire 28 is looped through all enable circuits 27 of the interface modules 10 , which leads in the enable circuits via a relay contact 29 . In the last connection module 10 , the relay contact 29 leads to a positive potential as an example. When the system is started up, the relay contact 29 is closed in the respective connection module by a command from the processor 14 when the respective connection module 14 works properly after being checked by the processor 14 . The entire system can then only be put into operation by the host computer 12 when the wire 28 at the input of the host computer 12 carries the positive potential from the last connection module 10 and, accordingly, all relay contacts 29 connected in series have closed.

The interface modules also each have a monitoring circuit (“watchdog”) 30 , which monitors the processor 14, for example by counting regularly emitted pulses and periodically resetting the counter, and can carry out further checks, for example, also monitors the operating voltages. If errors occur, the interface module 10 can then be brought into a defined state, for example the processor 14 can be reset.

The interface modules 10 used in a system can be designed differently. For example, the number of output and input circuits can vary. Combined input and output circuits can also be used, which are switched by processor commands for the respective function. Further versions of interface modules can instead of the digital input and output circuits 21 and 17 contain analog input and output circuits which convert analog voltages supplied to the input circuits into digital signals for the processor and, in the case of the output circuits, deliver defined analog voltages depending on the command supplied. Furthermore, a connection module can also contain an AC input circuit to which AC voltages of, for example, 220 V can be fed directly.

Claims (11)

1. Control and data network with a number of interface modules ( 10 ), each having at least one processor ( 14 ) with associated components ( 15 ) and at least one input circuit ( 21 ) and one output circuit ( 17 ) for receiving or delivering data and have signals,
with a bus ( 11 ) to which the interface modules ( 10 ) are connected in parallel via a bus connection ( 16 ),
and with a master computer ( 12 ) which calls up the interface modules ( 10 ) via the bus ( 11 ) by means of addressed telegrams and transmits data and control information to them and records responses from the interface modules ( 10 ), characterized in that
that the interface modules ( 10 ) have a control input ( 14 ) which, when a predetermined control signal is present, causes the processor ( 14 ) to bring the interface module ( 10 ) into a predetermined emergency stop state,
and that the control inputs ( 16 ) of at least certain connection modules ( 10 ) are connected to a common emergency stop control line ( 25 ). 2. Control and data network according to claim 1, characterized in that the emergency stop control line ( 25 ) is kept in the normal operating state at a predetermined voltage and that a failure or drop in this voltage is detected as a control signal. 3. Control and data network according to claim 1 or 2, characterized in that the processor ( 14 ) brings the output circuit ( 17 ) into a predetermined signal state, preferably the off state, in the emergency stop state. 4. Control and data network according to one of claims 1 to 3, characterized in that via at least certain connection modules ( 10 ) a release line ( 28 ) is looped through, which leads to a locking circuit ( 12 ), and that the locking circuit Operation of the network is only released when a predetermined switching operation with respect to the release line ( 28 ) is carried out in all specific connection modules ( 10 ). 5. Control and data network according to claim 4, characterized in that the switching operation is the closing of a relay contact ( 29 ) lying in series in the release line ( 28 ). 6. Control and data network according to one of claims 1 to 5, characterized in that all inputs of the interface modules ( 10 ) including the bus connection ( 16 ) and the control input ( 24 ) are guided via voltage-proof optocouplers. 7. Control and data network according to one of claims 1 to 6, characterized in that all outputs ( 16, 17 ) of the interface modules ( 10 ) are guided via voltage-proof optocouplers, which are fed from a special power supply unit ( 20 ) with voltage-proof network separation Output drivers are connected downstream. 8. Control and data network according to one of claims 1 to 7, characterized in that the power supply of the interface modules ( 10 ) from an industry standard DC voltage (24 V) via DC voltage converter with voltage-proof mains separation. 9. Control and data network according to one of claims 1 to 8, characterized in that the bus ( 11 ) is a symmetrical two-wire bus. 10. Control and data network according to one of claims 1 to 9, characterized in that each interface module ( 10 ) contains a monitoring circuit ( 30 ) which, in the event of faulty operation of the processor ( 14 ), resets it to the initial state and the master computer ( 12 ) notifies you of this. 11. Control and data network according to claim 5 and 10, characterized in that when the monitoring circuit ( 30 ) responds, the relay contact ( 29 ) lying in the release line ( 28 ) is opened.