WO1997004512A1 - Control system for controlling plural electrical devices - Google Patents

Control system for controlling plural electrical devices Download PDF

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Publication number
WO1997004512A1
WO1997004512A1 PCT/AU1996/000456 AU9600456W WO9704512A1 WO 1997004512 A1 WO1997004512 A1 WO 1997004512A1 AU 9600456 W AU9600456 W AU 9600456W WO 9704512 A1 WO9704512 A1 WO 9704512A1
Authority
WO
WIPO (PCT)
Prior art keywords
patch
control system
matrix
devices
motor
Prior art date
Application number
PCT/AU1996/000456
Other languages
French (fr)
Inventor
Michael John Bauer
Edward John Fregon
Original Assignee
Bytecraft Research Pty. Ltd.
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Bytecraft Research Pty. Ltd. filed Critical Bytecraft Research Pty. Ltd.
Priority to JP9506094A priority Critical patent/JPH11509387A/en
Priority to AU64094/96A priority patent/AU709762B2/en
Priority to US08/983,386 priority patent/US6297610B1/en
Priority to EP96923782A priority patent/EP0846359A4/en
Publication of WO1997004512A1 publication Critical patent/WO1997004512A1/en

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Classifications

    • HELECTRICITY
    • H02GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
    • H02PCONTROL OR REGULATION OF ELECTRIC MOTORS, ELECTRIC GENERATORS OR DYNAMO-ELECTRIC CONVERTERS; CONTROLLING TRANSFORMERS, REACTORS OR CHOKE COILS
    • H02P5/00Arrangements specially adapted for regulating or controlling the speed or torque of two or more electric motors
    • GPHYSICS
    • G05CONTROLLING; REGULATING
    • G05BCONTROL OR REGULATING SYSTEMS IN GENERAL; FUNCTIONAL ELEMENTS OF SUCH SYSTEMS; MONITORING OR TESTING ARRANGEMENTS FOR SUCH SYSTEMS OR ELEMENTS
    • G05B11/00Automatic controllers
    • G05B11/01Automatic controllers electric
    • G05B11/32Automatic controllers electric with inputs from more than one sensing element; with outputs to more than one correcting element
    • HELECTRICITY
    • H02GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
    • H02PCONTROL OR REGULATION OF ELECTRIC MOTORS, ELECTRIC GENERATORS OR DYNAMO-ELECTRIC CONVERTERS; CONTROLLING TRANSFORMERS, REACTORS OR CHOKE COILS
    • H02P6/00Arrangements for controlling synchronous motors or other dynamo-electric motors using electronic commutation dependent on the rotor position; Electronic commutators therefor
    • H02P6/04Arrangements for controlling or regulating the speed or torque of more than one motor
    • AHUMAN NECESSITIES
    • A63SPORTS; GAMES; AMUSEMENTS
    • A63JDEVICES FOR THEATRES, CIRCUSES, OR THE LIKE; CONJURING APPLIANCES OR THE LIKE
    • A63J1/00Stage arrangements
    • A63J1/02Scenery; Curtains; Other decorations; Means for moving same

Definitions

  • the present invention relates to a control system for controlling a plurality of electrical devices.
  • the invention is particularly but not exclusively applicable to the control of electrical devices such as electric motors especially those used for control of stage equipment.
  • VSD variable speed drive
  • the VSD provides output power to the motor to control its speed in a precise way.
  • the motors may for example be DC or AC either single or three phase.
  • the drives must provide the correct control voltage, current or frequency input to the motor to achieve the desired speed.
  • the axis controller generates control signals which are coupled to the VSD and controls such things as the rate of acceleration, maximum speed, duration of maximum speed, rate of deceleration and precise end-point positioning.
  • the central controller provides the highest level control and it usually comprises a computer which is programmed to select which pieces of stage equipment are moved, where they are moved to and when they are moved. The central controller provides appropriate control signals to the axis controllers.
  • an automatic patch can be represented by a rectangular matrix.
  • a "switch” (actually a set of switches, because there are many conductors required to be routed between a winch and its associated drive) would be located at each cross point in the matrix to enable any combination of motors (up to the total number of VSDs) to be connected to a drive each. In practice, this is not economically feasible and would cost more than a system having one VSD per motor.
  • a subset of matrix cross points are populated with switches.
  • the number of switches allocated to each motor, i.e. cross points populated in each row of the matrix, will determine the probability of being able to assign a given motor in a group to an available VSD.
  • the probability decreases, of course, as the group size increases. This probability can be quite high for small group sizes, e.g. up to 100%, but it drops sharply as the group size approaches the number of VSDs.
  • One automatic motor-drive patch system has been proposed but it tended to be over complicated and cumbersome to implement. In this system the central controller is coupled to each of the patch switches so that the central controller acting through the patch switches determines which of the motors are coupled to which of the VSDs.
  • An object of the present invention is to provide a novel control system which is particularly applicable to an automatic motor-drive patch system.
  • the invention herein concerns the architecture of the patch and control logic, i.e. the method by which the patch switches are inter-connected and controlled.
  • control logic is distributed in the network which couples the central controller to the electrical devices to be controlled.
  • a control system for controlling a plurality of electrical devices, a central controller for controlling selected functions of said devices, a plurality of device drivers for providing drive signals to said electrical devices, the number of device drivers being less than the number of devices and a network coupled between said device drivers and said devices, said network including logic elements which determine which devices are coupled to respective device drivers.
  • the logic elements are operable to determine which devices are coupled to respective drivers without direct coupling between the central controller and said logic elements.
  • the central controller comprises a computer which coordinates network activity.
  • a stage apparatus control system including a central controUer, a plurality of motors and a patch network including patch buses for coupling the central controller to the motors characterised in that elements of the patch network are coupled to the central controller through the patch buses and are not independently connected thereto.
  • the invention also provides a stage control system comprising a central computer, a patch network, a plurality of motors characterised in that a satellite processor is provided for each motor.
  • the invention also provides a stage control system comprising a central computer, a patch network, a plurality of motors characterised in that the system includes a plurality of axis controllers and wherein the axis controllers include logic elements which cooperate in the control of the patch network.
  • Figure IA is a schematic block diagram of a control system of the invention.
  • Figure IB shows a signal packet generated by the central controller
  • Figure 2 shows in more detail a typical control system for a theatrical winch motor
  • Figure 3 shows a motor-drive patch matrix of the invention
  • Figure 4 is a block diagram illustrating part of the control system of the invention
  • FIG. 5 is a block diagram showing in more detail an electronic patch switch element
  • Figure 6 is a block diagram schematically showing the matrix switch logic circuitry
  • FIG. 7 is a more detailed diagram of the patch switch logic circuitry
  • Figure 8 is a block diagram of an axis controller
  • Figure 9 is a more detailed diagram showing further details of part of the axis controller
  • Figure 10 is a block diagram of a satellite processor module
  • Figure 11 shows an example of safety switch circuitry
  • Figure 12 is a diagrammatic representation of the power patch interlock circuitry;
  • Figure 13 schematically shows manual switching circuitry;
  • Figure 14 shows a typical front panel of an axis controller
  • Figure 15A is a diagrammatic representation of the power switching matrix of a dual- matrix embodiment of the invention.
  • Figure 15B is a diagrammatic representation of the signal switchmg matrix of a dual- matrix embodiment of the invention.
  • Figure 16 diagrammatically shows a P patch module for the dual-matrix embodiment
  • Figure 17 diagrammatically shows a Q patch module for the dual-matrix embodiment
  • FIG. 18 shows the P and Q patch modules connected together
  • FIG. 19 is an alternative schematic representation of the P and Q patch modules connected together
  • Figure 20 illustrates a modified dual-matrix embodiment in which there is a LAN connection from the central controller to the satellite module;
  • Figure 21 shows an alternative dual-matrix embodiment of the invention in which there is a LAN connection from the central controller to the Q modules;
  • Figure 22 shows an alternative dual-matrix embodiment having a LAN connection to the Q modules but a serial connection from the satellite modules to the P modules; and
  • Figures 23 and 24 show examples of the front panel configurations for the drive switch Q module and motor switch P module for the dual-matrix embodiment.
  • Figure IA shows a block diagram of a control system of the invention, the control system including a central controller 2 coupled by a LAN 3 to a control network 4 which in turn is coupled to a plurality of electric loads such as motors 6.
  • the network 4 includes a number of driver devices which are selectively coupled to control the motors 6.
  • the LAN 3 may be of a normal commercially available type such as an ethernet.
  • Figure 2 illustrates in more detail a complete control path which is established between the central controller 2 and one of the motors 6 in a typical control system where there is a variable speed drive (VSD) 10 and axis controllers 8.
  • VSD variable speed drive
  • axis controllers 8 In the control system of the invention there is no permanently connected control path between the motors 6 and the VSDs 10 but temporary connections are established as required by the control network 4 and controller 2.
  • the temporary control path however has the same or similar control elements as the complete control path shown in Figure 2.
  • the complete control path of Figure 2 includes an axis controller 8 which is coupled to the central controller 2.
  • the axis controller 8 has a termination panel 12 which is coupled to the VSD 10.
  • Output lines 14 from the VSD 10 are coupled to the motor 6 via a switch matrix 28 which forms part of the control network 4 as will be described in more detail below.
  • the matrix 28 may be a single, double or other type of matrix as explained below.
  • Figures 3 to 14 are concerned with a single matrix embodiment and Figures 15 to 22 are concerned with a dual-matrix embodiment.
  • the motor 6 may comprise a three phase motor.
  • the motor 6 includes an encoder or resolver 16 which provides velocity feedback signals to the VSD 10 through the matrix 28.
  • a position (or velocity) encoder 18 is also mounted on the motor shaft so as to provide encoded positional (velocity) signals to the axis controller 8 through the matrix 28 and termination panel 12.
  • Various safety limit switches 20 associated with the motor or the equipment which is moved by the motor are provided to generate safety signals which again are coupled to the axis controller 8 via the termination panel 12.
  • An AC supply 22 is coupled to the VSD 10 via filters 23, fuses 25 and contacts 27.
  • the control system closes the contacts 27.
  • the VSD 10 provides controlled voltages and/or cunents on its output terminals TJ, V and W appropriate for mamtaining a controlled speed and direction of rotation of the motor 6.
  • the axis controller 8 provides input signals to the VSD 10 so as to control such things as the rate of acceleration of rotor speed, maximum constant rotational velocity of the motor, the duration of the period for which constant rotational speed is maintained and the rate of deceleration. These control parameters are important to provide a smooth non-jerky movement of the motor and the equipment coupled thereto.
  • the central controller 2 provides overall control necessary for deterrmning the required sequence of movement of stage equipment such as selecting which motors are to be operated, control of final position of motors, etc.
  • a brake 40 is provided to stop rotational movement of the motor 6. It is preferred that the brake is operated in a fail safe way, that is to say it will be applied by means of a spring when power is lost to the brake.
  • the controller 2 may comprise a Bytecraft .STATE 3.
  • SYSCON Product No. 811-060
  • the axis controller 8 may comprise WINCON 3 (No. 811-046)
  • the VSD 10 may comprise ABB (Model ACS-600) or a SIEMENS drive.
  • the Bytecraft products refe ⁇ ed to above may incorporate software and hardware elements of the LAN 3. It also includes an interface to deal with additional signals for communication with the matrix 28.
  • the present invention is primarily concerned with the architecture of the matrix 28 which operates to establish control paths which include an axis controller 8, VSD 10 and motor 6, in an installation where there are a lesser number of axis controllers 8 and VSDs 10 compared with the number of motors 6.
  • the central controller 2 is a ⁇ anged to generate signal packets 5 of the type illustrated diagrammatically in Figure IB.
  • the signal packets include an address field 7, command type field 9 and command data field 11.
  • the packets 5 are transmitted from the central controller 2 via the LAN 3 and are received by the axis controllers 8, as will be described hereinafter.
  • the axis controllers 8 generate communication packages which are sent via the LAN 3 to the central controller 2 containing information relating to the states of the motors 6 to which connections have been made through the matrix 28.
  • FIG 3 illustrates diagrammatically part of the network 4 and in particular the switch matrix 28 which is an example of a single matrix configuration.
  • the VSDs 10 being for controlling thirty-two winch motors 6 which can be connected together by buses which form part ofthe matrix 28, as will be described below.
  • Each of the axis controllers 8 is coupled to a winch control patch bus 24 represented by columns in the matrix and each of the motors is connected to a motor bus 26 represented by rows in the matrix.
  • the buses 24 and 26 can be regarded as a two dimensional matrix, as shown in Figure 3, with a selected number of patch switches 30, comprising a signal switch element and a power switch element.
  • each patch switch 30 is coupled in one of the winch control patch buses 24.
  • the patch switches 30 are used to provide interconnections between the winch control patch buses 24 and the motor buses 26.
  • the patch switches 30 can be independently controlled and in practice comprise a number of switches, as will be described below. The number of switches in each motor bus 26 or module can be varied in accordance with control requirements.
  • the switches 30 are used to provide the connection between the VSDs 10 and the motors 6, it being noted that there is no direct (i.e. permanently established) communication path needed from the central controller 2 directly to the switches 30. It will be appreciated from the foregoing that when a particular motor needs to be operated, it can be coupled through its motor bus 26 and switches 30 to one of two VSDs 10. If one of those VSDs 10 is available, the appropriate coupling is made so that the motor can be operated as required.
  • Each patch switch 30 itself comprises an electronic patch switch 32 and power patch switch 34, as diagrammatically illustrated in Figure 4.
  • the signal switching elements 32 common to a motor signal bus 26 are incorporated into one .Patch Switch Module..
  • the electronic patch switch 32 is concerned with switching control signals whereas the power patch switch 34 is concerned with switching in the heavy cu ⁇ ent supply lines which are required for the motor 6 and brake 40.
  • the electronic patch switch 32 includes a plurality of electronic switches for switching various control lines and the power patch switch 34 includes a plurality of switches for switching in a number of heavy cu ⁇ ent lines.
  • FIG. 4 illustrates in more detail a selected connection between one of the VSDs 10 and its associated axis controller 8 to the motor 6 through the patch switches 32 and 34.
  • the winch control patch bus 24 and the motor bus 26 include signal buses 36 and power buses 38 which are respectively connected to the switches 32 and 34.
  • the signal bus 36 communicates control signals whereas the power bus 38 handles heavier cunents required for operation of the motor 6 and brake 40 through the power patch switch 34.
  • a satellite processor module 42 is provided for each ofthe motors 6.
  • the satellite module 42 is coupled to monitor the safety switches 20 and the incremental encoder 18 and to provide local storage of data relevant to the motor 6 to which it is coupled. This is important because the axis controllers 8 are shared between the various motors and therefore do not monitor and or store all of this information for the motors to which they could be connected. System security is enhanced by monitoring this data locally at the motor rather than trying to store this information elsewhere for input to the axis controllers 8 when required. Because the functions performed by the satellite module 42 are restricted, it does not need to have powerful processing capabilities.
  • the power patch switch 34 includes a power relay 44 having contacts 46 and relay coil 48. Operation of the relay coil 48 is controlled by the electronic patch switch 32, as will be described below. It is prefe ⁇ ed that the power relay 44 includes seven sets of contacts which are used as follows. Three of the contacts are used for three-phase power to the motor 6, another two are used for single phase power to the brake 40 and two further auxiliary (low current) contacts are used for providing status signals which indicate when the patch switch 30 or patch bus 24 to which the switch 30 is connected is being operated, as will be described in more detail below. Figures 5, 6 and 7 illustrate in more detail the signal patch switch 32, or parts thereof.
  • Each switch element 32 includes an identity comparator 50, a contactor driver logic circuit 52, tri-state buffers 54 and relay contacts which allow signals to be selectively coupled between the winch control patch bus 24 and the motor bus 26.
  • the switch 32 includes a DIP 5 switch 56 which can be set so as to define a unique address for each patch switch 30 on a given winch control bus 24. In the illustrated a ⁇ angement, the address may be a digital number in the range 0 to 31.
  • the axis controller 8 generates the address signal for a motor select bus 58, which forms part ofthe bus 24, when a particular motor is to be activated. More specifically, the central controller 2 defines which of the motors 6 is to be used and the axis
  • controller 8 receives appropriate information from the central controller 2 and operates to translate this into the address signal for inputting to its motor select bus 58.
  • the identity comparator 50 detects a match with the address on the motor select bus 58 it generates on its output 60 a P_SEL signal.
  • the P_SEL signal is coupled to the input of the contactor driver logic circuit 52 and other switch components as will be described below.
  • a serial data link 68 is connected between the axis controller 8 and the satellite processor module 42 associated with the selected motor 6.
  • the status of any motor, bus 24 or 26, electronic patch switch 32 can be monitored by the axis controllers 8 without affecting the state ofthe power patch switches 34.
  • This provides a useful monitoring function which is inherently safe because it can be utilised without changing the state of the 0 switches 34.
  • this a ⁇ angement enables the absolute position of any motor axis to be read or set by virtue of the serial data links 68 established between the satellite processor modules 42 and the axis controllers 8.
  • tri-state buffers 64 are used to interconnect the serial data links 66 and 68 which form part of the buses 24 and 26 respectively.
  • the buffers 64 are coupled to the output 60 of the comparator 50 and are 5 therefore only enabled when the P_SEL signal is present.
  • PGRP_FREE is applied to a patch status bus 62 which forms part of the winch control patch bus 24.
  • the PGRP_FREE status signals indicate to the axis controller 8 that power patch 0 contacts 46 forming part of a group common to a motor 6, is energised, as will be described in more detail below.
  • a patch switch 32 While a patch switch 32 is selected, it will respond to other control signals from the axis controller 8 to which it is coupled. Also, while it is selected, the serial data communications link to the satellite processor allows the axis controller to momtor the status of the motor.
  • the status information can include the absolute position of the axis of the motor, the state of various safety switches and any other sensors which are connected to the motor's satellite processor 42.
  • the contactor driver logic 52 includes a NAND gate 70, one input of which is coupled to the output 60 of the identity comparator 50. Another input of the gate 70 is coupled to a signal line 72 which carries the PGRP_FREE status signal. The final input to the gate 70 is via a signal line 74 which is connected to the bus 24 and canies an engage signal P_ENGAGE which is generated by the axis controller 8 while the patch switch 30 is to be selected.
  • the output of the NAND gate 70 is used to control the base of a relay driver transistor 76, the emitter of which is connected to a control line 78 which in turn is connected to the bus 24.
  • the control line 78 canies status signal PBUS_FREE thereon and is therefore indicative, in the illustrated a ⁇ angement, of whether one or other of the two patch switches 34 in a motor bus 26 has been engaged.
  • the power patch interlocks, PBUS_FREE and PGRP_FREE, will only be active (+24V) if no power patch switches 34 have been engaged on the matrix row and matrix column representing the node (switch element 30) selected.
  • the relay driver transistor 76 Only when the appropriate signal conditions are present on the three inputs to the NAND gate 70 and the co ⁇ ect PBUS_FREE status signal on the line 78 can the relay driver transistor 76 turn on and so activate a relay coil 80.
  • the axis controller 8 also provides a relay hold signal P_HOLD on control line 82 which is connected to the bus 24. Accordingly, the patch relay coil 80 can be activated only when the appropriate PBUS_FREE, PGRP_FREE signals are present on the motor bus 26 and P_HOLD signals are provided on the bus 24 by the axis controller.
  • the axis controller provides a pulsed P_ENGAGE signal on line 74 the transistor 76 will turn on and so activate the coil 80. This closes the contacts 84 which operate to keep the coil 80 activated whilst the P_HOLD signal is maintained on the bus 24 by the axis controller.
  • the patch relay coil 80 includes a second pair of contacts 86 which are used to control the power patch switch 34, as mdicated in Figures 5 and 7.
  • the contacts 86 are used to control the power patch relay 44, as shown in Figure 4.
  • the relay 44 has seven pairs of contacts, three of which are used for controlling three phase power to the motor 6, one of which is used for controlling single phase power to the brake 40 and the remaining contacts used to generate control signals.
  • the switch driver logic 52 also controls tri-state buffers 88 which allow communication of encoder signals from lines 90 and 92 in the buses 24 and 26 respectively.
  • the encoder signals 90 comprise the signals derived from the incremental encoder 18 through the satellite processor module 42, as shown in Figure 4.
  • the buffers 88 are only enabled when a P_SEL signal is present which occurs when the patch switch 30 has been activated.
  • the patch switch 32 also includes a safety switch relay having a coil 94, the contacts of which 96 are provided in four safety switch lines 98.
  • the coil 94 is controlled by the switch driver logic 52 so that it is only closed whilst the switch 30 is activated. More particularly, it will be seen that the coil 94 is coupled to line 93, the anangement being such that the coil
  • the safety switch lines 98 are "hard wired", i.e. relay contacts are employed in the patch switches 30 to connect these signals from the satellite processor module 42 and safety switches 20 to the axis controllers 8. This is inherently safer than a ⁇ angements in which the switch circuits are not “hard wired” i.e.which utilise .solid-state, electronic switching devices.
  • the axis controllers 8 monitor the safety signals independently from processor software and it is essential for the connections to be properly made before operation of the motors can commence. A break in any of these connections will result in the motor being unable to move. Thus the system is fail safe.
  • the safety circuits are therefore independent of all electronic controls (such as those generated by the axis controllers 8) and software in the central controller 2.
  • Figure 8 shows a block diagram of the main circuit components for a typical axis controller 8.
  • Axis controllers are well known in the art and therefore details of this circuit need not be described.
  • known axis controllers can be utilised in the system of the invention with very little modification.
  • the modification requires the addition of interface logic 71 to a microprocessor 69 in the axis controller 8.
  • the axis controller requires additional signal lines in order to provide control signals for the signal matrix 28.
  • Figure 9 diagrammatically shows one implementation for the interface logic 71. The operation ofthe logic 71 is straightforward and need not be described in detail.
  • the axis controller 8 preferably has a number of additional signal lines through the logic 71 in order to control the matrix.
  • the microprocessor 69 After receipt of a system controller command packet by the axis controller the microprocessor 69 checks the command type field 9 and also interprets the command data in the field 11. It then generates the appropriate patch switch 30 control signals in accordance with the instructions in data field 11.
  • FIG 10 diagrammatically illustrates the satellite processor module 42.
  • the satellite processor 42 includes a microcontroller 73 having inputs coupled to the encoder 18 and safety switches 20 (which may include other sensors such as for sensing other parameters such as over travel of a winch to which the motor is connected, a crossed wire on a winch drum or slack winch wire or the like).
  • the microcontroller 73 commumcates with axis controllers 8 via the serial data links 68 and 66 via an RS-485 asynchronous full duplex protocol type link 75.
  • the main function of the satellite processor module 42 is to continuously maintain data relating to the absolute position of the motor axis to which it is coupled.
  • the satellite processor modules 42 and the sensors connected to them are preferably powered from a battery-backed power supply 100 so as to avoid problems which might occur if power were temporarily lost to the satellite processor modules 42.
  • FIG 11 diagrammatically illustrates one example of the way in which the safety switches 20 are connected to the microcontroller 73.
  • four safety switches 113, 114, 116 and 118 are connected in series via a load 120 to a +24V supply.
  • Safety input lines 122 are coupled as inputs to the microcontroller 73 via buffer amplifiers 123. In the normal anangement, all of the switches are closed and thus all of the logic inputs to the satellite processor are high. If, however, one of the switches opens, the circuit will be broken and the microcontroller 73 will be able to identify which ofthe switches 113, 114, 116 and 118 has opened.
  • the microntroller 73 cannot tell which ones are open but it should always be able to identify which switch opened first. This will enable an operator to rectify the fault which caused the conesponding safety switch being closed. The next switch which remains open can then be identified by the microcontroller 73 and the operator should again be able to rectify the fault.
  • the switch 113 may indicate overload on the winch motor 6, the switch 114 indicates a chain break in a winch, the switch 116 may indicate a "crossed groove" on the winch drum and the switch 118 indicates a slack wire in a winch.
  • the satellite modules 42 may be located in close proximity to their respective motors rather than in say the winch control room where typically the axis controllers 8, VSDs 10 and patch switches 30 would be situated. This has the benefit of reducing the amount of cabling from the control room to the location of the motors.
  • Figure 12 diagrammatically illustrates how two further pairs of auxiliary normally closed contacts 87 and 88 of the power patch relays 44 are used to generate the PBUS_FREE and PGRP_FREE signals on the lines 72 and 78.
  • This can conveniently be effected by arranging for the auxiliary contacts of the power patch relays to be of the normally closed type so that when the relay 44 is activated the contacts 87 and 89 will be open.
  • the signal line 78 of the three patch switches 34 common to a matrix row [in either the motor matrix or the drive matrix of a dual -matrix implementation] are effectively connected in series and, when one ofthe switches ofthe group has been selected, its contacts in the line 78 will be open and this state indicates that the group is not free.
  • the auxiliary contacts in the line 72 of all of the switches 34 common to a matrix column will effectively be connected in series and when one of the switches 30 in the column has been activated, the auxiliary contacts will open and this state indicates that the patch bus 28 is not free.
  • PBUS_FREE is derived from a series connection of auxiliary contacts of all contactors on the matrix column, i.e. all contactors under the control of a particular axis controller 8.
  • PGRP_FREE is derived from a series connection of auxiliary contacts of all contactors on the matrix row, i.e. all contactors associated with a particular winch motor 6.
  • the axis controller must have its P_HOLD signal (24V DC) applied to the bus 24;
  • the axis controller must pulse the P_ENGAGE signal on patch bus for coupling to the line 74.
  • the patch switches may, optionally, be operated manually, i.e. without involving the axis controller logic.
  • Figure 13 diagrammatically illustrates one circuit anangement for connecting the operator control switches 108 and 109 which are used during manual operation.
  • the engage switch 108 is connected in series with interlock contacts 124 which are controlled by an interlock relay 126.
  • the interlock relay 126 is powered from the line 78 which canies the PGRP_FREE signal. This provides a safety interlock because the engage switch 108 will not be operative unless the PGRP_FREE signal on line 78 is present, thereby providing safety interlock even during the manual operation.
  • the a ⁇ angement includes a switch 128 which may comprise a rotary or thumb wheel selector for selection of the desired patch bus to be engaged.
  • Figure 14 diagrammatically illustrates a front pantl 102 for an axis controller 8. It will be seen that the panel includes indicating lamps 104 for indicating the state of various signal parameters. It also includes an ethernet connector 105 for coupling to the LAN 3.
  • Figure 15A diagrammatically illustrates the power switching part of a dual-matrix configuration in which there is a motor switch matrix 127 and a drive switch matrix 129.
  • the dual-matrix configuration can be a ⁇ anged to provide appropriate connections between the axis controllers 8 and the VSDs 10 and the motors 6.
  • the temporary connections between the axis controllers 8 and the VSDs 10 and motor 6 are established by the control network 4.
  • the dual-matrix configuration is established by a ⁇ anging for a motor matrix 127 to be established in the upper rows and a drive matrix 129 for the VSDs 10 to be established in the lower rows.
  • the patch buses 24 comprise the matrix columns which extend from the motor matrix to the drive matrix. Inputs to the rows of the drive switch matrix 129 are derived from VSD's 10. In the drive switch matrix 129, populated patch switches 34 are indicated by means of squares in the matrix. In the drive switch matrix 129 there are four switch elements 34 in each row and three patch switch elements 34 in each column. In the motor switch matrix 127, there are two patch switch elements 34 in each row and three in each column. Outputs from the rows in the matrix 127 are coupled to the motor bus 26 for connection to the motors 6. Each of the patch switches 30 in the matrices 127 and 129 can be similar to the power patch switch 34 of the single matrix embodiment.
  • Figure 15B shows diagrammatically another part of the dual-matrix embodiment.
  • FIG. 15B shows matrices used for switching of signals and the general form is similar to that shown in Figure 15A.
  • Figure 15B includes a drive signal switch matrix 140 and a motor switch matrix 142. Inputs to the rows of the matrix 142 are from axis controllers 8. Outputs from the matrix 142 are to the satellite processor modules 42.
  • the patch switches 30 in the matrices 140 and 142 are analogous to those described previously.
  • the patch switches 30 can be implemented in accordance with the patch switch 132 (Q module switch element) diagrammatically illustrated in Figure 17.
  • Figure 16 is a block diagram showing schematically a signal patch switch element 131 which can be used for the patch switches 32 in the motor signal matrix 142.
  • the switch 131 operates analogously to the switch 32 shown in Figure 5 and need not be described in detail.
  • the selection of the motors to be coupled and the patch switches to be closed in the matrix or matrices is determined by the central controller 2.
  • the central controller 2 preferably also stores the overall state of the matrix, that is to say stores information regarding which patch switches are closed in the matrix.
  • the central controller 2 also operates a routing algorithm in order to select which switches should be closed in order to establish a connection between a VSD and a motor. This information is also stored in the central controller.
  • the central controller also stores information regarding any failed components in the system so that these can be bypassed.
  • the central controller 2 may include stored information relative to the matrix or matrices to which it is coupled. This will enable it to cany out the routing algorithm required in practice. In some circumstances, it may be convenient to instal in the central controller 2 a program which can generate the matrix information tables so that on commissioning the equipment the central controller can be loaded with information which is appropriate for the matrix which has been established. Also this would enable the equipment to be altered if the matrix were changed.
  • the dual-matrix scheme not only raises the probability of finding a route between each motor and a drive for large groups of motors, using fewer switches than a single matrix, but also offers a high degree of fault tolerance due to the ability to assign a drive to one of several buses. This means that any group of motors can be assigned a drive, even when some drives or axis controllers may be out of service.
  • the matrix is largely specified by "R” (the number of patch buses 24), "P” (the number of buses available to each motor) and “Q” (the number of buses available to each drive) and finally, the pattern of population of cross points within the matrix.
  • the optimal configuration of the matrix for a given application is designed with these guidelines and optimised with the computer simulation of thousands of routing attempts.
  • the axis controllers 8 can be similar to known axis controllers but having additional signal processing capabilities for handling communications with the matrix 18 whether single or dual.
  • the additional signals to be handled by the axis controller include:
  • QBUS_FREE Input signal (when high) indicates to axis controller and Q-module that the patch bus for that particular Q-module Switch is in fact free.
  • QGRP_FREE Input signal (when high) indicates to an axis controller 8 that no other Q- switch in that particular Q-module has been selected. That is, axis controller 8 can only select one patch bus at a time. - 21 -
  • Q_ENGAGE Output signal (when pulsed high) commands a particular selected Q-module switch to activate itself fully and also to activate its associated power contactor. This forms the first part of a path through the power contactor matrix.
  • Q_HOLD Output signal that must be high to allow the Q_ENGAGE signal to activate the selected Q-switch element. This signal remains high whilst the particular Q- switch is activated. If this signal goes low then the particular Q-switch and power contactor will be disengaged.
  • PBUS_FREE Has same function as Q-matrix QBUS_FREE but is on a P-module. Signal is routed via Q-module and patch bus to P-module.
  • PGRP_FREE Has same function as Q-matrix QGRP_FREE but is on a P-module. Signal is routed via Q-module and patch bus to P-module.
  • P_ENGAGE Has same function as Q-matrix Q_ENGAGE but is on a P-module. Signal is routed via Q-module and patch bus to P-module.
  • P HOLD Has same function as Q-matrix Q_HOLD but is on a P-module. Signal is routed via Q-module and patch bus to P-module.
  • MSELO-3 Binary nibble output signals routed via Q-module/patch bus to nibble comparators on each P-module. If nibble matches a particular P-module DIP switch setting then that P-module is SELECTED (not ENGAGED as yet however).
  • BUSBUSY Input signal (when high) to axis controller to indicate that a particular signal bus is in fact engaged by another axis controller/Q-module.
  • SELENAB Output signal that allows an axis controller/Q-module to assert a particular bus-busy signal when that Q-module switch is selected. Indicates to other Q- modules on bus that bus is cunently selected.
  • CHA Input encoder signal that originates from winch motor position encoder (First quadrature encoded channel signal). Routed from satellite processor module 42 via P-module-Bus-Q-module.
  • CHB Input encoder signal that originates from winch motor position encoder 18 (second quadrature encoded channel signal) and is routed from satellite processor module 42 via P-module-patch bus-Q- module.
  • ZMARK Input encoder signal that originates from winch motor position encoder 18 (encoder "zero-position” indicator pulse). Router from the satellite processor module via P-module-patch bus-Q-module.
  • TXD Transmitted serial data to the satellite processor module 42. Allows commands and general control of the satellite processor module.
  • RXD Received serial data from the satellite processor module 42. Allows status of satellite process or module to be read also used for handshaking and acknowledgement of commands.
  • FWDOTR Forward overtravel safety signal It is routed from the satellite processor module 42.
  • REVOTR Reverse overtravel safety signal It is routed from the satellite processor module 42.
  • AUXIN1 First auxiliary safety signal. It is routed from the satellite processor module 42. It can also be used as backup safety signal.
  • QSELO-2 3 bit encoded output signal used to select one (or none) of six Q-switches on a Q-module PCB. This is SELECT only, not engage.
  • the axis controller interprets the command types in the command type field 9. Four of these command types are outlined below.
  • the satellite processor module 42 can be down loaded with the motor (batten) number. This command should specify the low-level patch bus address and P-module address to connect to the required winch. Signal patch must be connected via P and Q modules. Signal is communicated via serial TXD and RXD lines.
  • Configure Axis command The satellite processor module 42 will be down loaded with any parameters specific to its winch motor such as the axis absolute position. Signal is sent via patch TXD and RXD lines. Whenever the axis controller 8 establishes a patch route to the satellite processor module 42, it must read the motor number stored in the satellite processor module and verify that the number is the same as that in the command packet.
  • axis controller 8 Requests an axis controller 8 to activate a signal route to a specified satellite processor module 42, without engaging any power patch contactors.
  • the patch bus to be used will be dictated by the central controller 2.
  • the axis controller 8 will check for bus contention and other anomalies. This is done via the BUSBUSY If the route can be made then the bus is selected via SELENAB and QSELO-2 lines.
  • the axis controller will get winch motor position and status from the satellite processor module via TXD/RXD and respond to the central controller 2. The signal route is kept until a subsequent poll command changes it.
  • a pre-move command will instruct the axis controller 8 to engage a patch route to a specified winch, using a specified patch bus. This is done using the Q/P_ENGAGE and Q P_HOLD signals.
  • the patch switch elements should be SELECTED beforehand.
  • the axis controller 8 will check for contention and other anomalies via BUSBUSY and integrity or actual existence of RXD signal. If the route can be made, the axis controller 8 will attempt to engage the two power contactors required and verify the patch (using the interlock monitoring signals Q/P BUS_FREE and GRP_FREE). The axis controller 8 will initialise its winch motor position and status as read from the satellite processor module 42 and respond to the central controller 2.
  • the axis controller 8 normally includes a service port CLI which may be extended to include patch diagnostics and commands to drive the patch manually for fault detection or local control ofthe various winch motors 6 without control signals from the central controller 2.
  • each axis controller 8 is connected directly to one VSD 10 and one Q-Module, each of which comprises six of the patch switches 132, only one of which is shown in Figure 18 for clarity of illustration.
  • a P module is made up from three of the patch switches 131 and again only one is shown in Figure 18.
  • the entire system comprises a plurality of controllers 8, VSDs 10, Q-Modules and P- Modules, all of which are controlled by the central controller 2 via signals sent over the LAN 3. There is no direct connection for control or status signalling to the P-Modules from the axis controllers 8.
  • the ability of the axis controllers 8 to poll winch status by connecting to satellite processor modules 42, without the need to disturb the power patch, is retained in the dual- matrix scheme. However, it is prefe ⁇ ed to include means to prevent two or more axis controllers 8 sharing a common patch bus from addressing the same bus simultaneously. While this eventuality could not result in a fault in the power patch, because of the safety interlocks, it would create contention between two or more satellite processor modules 42 attempting to transmit on the same serial link in the patch signal bus.
  • Figure 19 is an alternative representation of the circuit shown in Figure 18. This representation shows the motor switch matrix 127 and drive switch matrix 129 of Figure 15A together with the drive switch matrix 140 and motor switch matrix 142 of Figure 15B.
  • FIG 20 shows schematically a modified form of dual matrix embodiment.
  • the LAN 3 extends directly from the central controller 2 to the satellite processor module 42 to thereby enable the central controller 2 to establish complete system status based upon information transmitted to it by the LAN from the satellite processor modules 42. It will be appreciated that this system status can be gathered entirely independently of the patch switches in the matrix and therefore can be used to provide additional system reliability checks.
  • the patch switches 131 of the P modules are controlled directly by the satellite processor module 42 via P module control bus 135 rather than via signals from the axis controllers 8 via the matrixes 127 and 129. In this scheme there is a one to one conespondence between the patch switches in the P modules and the satellite processor modules 42.
  • the functions of the switches 131 of the P module and the satellite processor module 42 could be combined into a single module. In this embodiment, the topology is more readily understandable and results in fewer conductors in the signal matrix buses.
  • Figure 21 shows schematically a further modified form of dual-matrix embodiment.
  • Figure 22 shows schematically a further modified form of dual-matrix embodiment.
  • the central controller 2 directly controls the patch switches 132 of the Q modules via the LAN 3.
  • the satellite processor modules 42 control the patch switches in the matrices 127 and 142 from the satellite processor module 42 via the serial data link 68, as in the case of Figure 19.
  • Figures 23 and 24 show examples of the front panel configurations for the drive switch
  • the front panel of the drive switch Q module may include an engage switch 108 and a release switch 109 for manually engaging or disengaging the patch switches 132 therein.
  • the panel may include indicating LEDs 111 and
  • each LED 111 is coupled to contacts 46 of the power patch switch 34 and is thereby illuminated when the selected motor bus 26 is busy.
  • Each LED 112 is effectively
  • Figure 24 diagrammatically illustrates a front panel of a motor switch P module which includes a number of patch switches 131 therein.
  • the panel may include mdicating LEDs for
  • the panel may include a number of engage switches 140 and a release switch 142 for manually engaging or disengaging the patch switches 131 therein.
  • the patch control logic is distributed in the control network 4 rather than being centralised in the central controller 2.
  • Each axis controller 8 in addition to its motion control function, is also responsible for the control and monitoring of a number of patch switches 30.
  • the axis controller is capable of addressing a number of patch switches on its winch control patch bus 24.
  • a single module is dedicated to each motor 6.
  • Each patch switch 30 within the module is controlled and monitored by a different axis controller 8. (In Fig. 3, a patch switch module comprises two switches 30, but the number may vary from system to system).
  • the patch matrix topology can be optimised for each application, i.e. the number of VSDs required and the number of patch switches 30 per motor can be varied to suit each application.
  • the patch switch module inco ⁇ orates novel safety interlocks to prevent abenant switch operation and uncontrolled motor axis motion. More particularly, the signals from critical safety switches are available to the central controller 2 via two paths. They are transmitted in serial format by the serial processor 42 and are also hard wired. This provides enhanced safety.
  • the patch switch module in conjunction with the axis controller interface logic, provides a mechanism whereby the status of any motor (e.g. its absolute position, safety switch and sensor inputs, etc.) can be monitored without the need to activate or change the power patch switch 34 (i.e. connecting the drive power circuits to the motor). Consequently, the status of motors can be determined without disturbing the cu ⁇ ently active power patch 34.
  • any motor e.g. its absolute position, safety switch and sensor inputs, etc.
  • the patch switch module can incorporate independent manual backup controls and indicators on the front panel. This allows manual setting up of the patch switches in the event of failure or unavailability of axis controller processors).
  • the satellite processor module 42 being situated on the axis side of the matrix enables the use of an incremental position encoder 18.
  • the satellite processor module 42 contains circuitry enabling it to remember at all times the position of the axis of the motor 6 to which it is connected. When a route is established through the matrix between an axis controller 8 and a motor, the satellite processor module 42 transmits the motor access position to the controller 8 prior to commencement of any motion. The axis controller 8 then uses this position in its control algorithm. This results in more reliable operation of the system.
  • an absolute encoder may be used.
  • the satellite processor module 42 enables the accuracy of the signal matrix route to be confirmed.
  • PBUS_FREE and PGRP_FREE signals which are used to provide "row” and “column” proving signals.
  • the technique for generating these signals and the manner in which these are used provides additional system reliability.
  • the background status of motors it is possible to monitor the background status of motors. This can be accomplished by a ⁇ anging for the satellite processors 42 to be polled via their serial communications links to gather the status of the motors to which they are coupled. 11.
  • the prefe ⁇ ed embodiments of the invention enable the power matrix contacts 46 to be switched independently from switches within the electronic patch switch 32. This means that the signal matrix routes can be established without operating or affecting the condition of power relays. If this were not the case, then background status monitoring of the motors would not be practical because it would necessitate switching power relays frequently and this would result in excessive wear, noise and low speed of operation.
  • Prefened embodiments of the invention can be used to generate a global emergency stop condition.
  • the satellite processor modules 42 are able in certain circumstances to detect illegal motions of a motor axis. If the motor axis is cu ⁇ ently patched, i.e. connected via the patch switch 30 to an axis controller 8 and drive 10, the satellite processor could signal this condition to the controlling axis controller 8 and the appropriate action could be taken. If, however, illegal motion was detected in a condition in which a motor axis is not properly patched (such as might occur with a malfunction in the power matrix), then the satellite processor module 42 would normally be powerless to intervene. To guard against this possibility, the satellite processor module 42 can be provided with a Global Emergency Stop output which can be connected to a central emergency stop system. Such a signal can be used to a ⁇ est motion of all machinery or all machinery within a defined area. This is diagrammatically represented by the energy stop system 144 shown in Figures 19 to 22.
  • FILE *pFP stdin; #ifhdef unix char *optarg; #endif
  • wQSwitch randO % wQSwitches
  • ⁇ wRippedUpMotor RipUpRoute(wMotor); if (RouteMotor(wMotor)) ⁇ if (RouteMotor(wRippedUpMotor))

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Abstract

A control system for controlling a plurality of electrical devices (6) the system including a central controller (2) for controlling functions of the devices, a network (4) coupled between the central controller (2) and the devices, the network including a plurality of device drivers (10) for providing drive signals to the electrical devices, the number of drivers being less than the number of devices characterised in that the network includes intelligent devices (8) which enable communication through the network from the central controller (2) to the devices (6).

Description

CONTROL SYSTEM FOR CONTROLLING PLURAL ELECTRICAL DEVICES
The present invention relates to a control system for controlling a plurality of electrical devices.
The invention is particularly but not exclusively applicable to the control of electrical devices such as electric motors especially those used for control of stage equipment.
In the control of stage equipment in a theatre there is a need for precise and synchronised control of a plurality of motors which may be used for moving and/or winching stage equipment. In these applications safety considerations are paramount because any fault may result in serious injuries to equipment or personnel. Typically the motors required to drive winches and the like are coupled to a variable speed drive (VSD) which in turn is coupled to a central computer usually via an axis controller. The VSD provides output power to the motor to control its speed in a precise way. The motors may for example be DC or AC either single or three phase. The drives must provide the correct control voltage, current or frequency input to the motor to achieve the desired speed. The axis controller generates control signals which are coupled to the VSD and controls such things as the rate of acceleration, maximum speed, duration of maximum speed, rate of deceleration and precise end-point positioning. The central controller on the other hand provides the highest level control and it usually comprises a computer which is programmed to select which pieces of stage equipment are moved, where they are moved to and when they are moved. The central controller provides appropriate control signals to the axis controllers.
In an ideal system, there would be an axis controller and VSD for each motor. In this way the central controller can effectively control all of the motors so that all of the motors can be simultaneously operated. Whilst this may be appropriate for relatively small theatres it is not usually appropriate for large theatres where there may be more than 60 motors to be controlled. It is not appropriate in the larger systems because of the substantial expense involved in providing separate axis controllers and VSDs for each motor. Further, there would be a substantial amount of cabling required to couple the components together.
Economies can be realised if the number of motors required to run simultaneously is lower or substantially lower than the total number of motors and this is frequently the case. In this case, the number of VSDs can be reduced to the number of motors required to run at the same time. However, a mechamsm needs to be put in place which can variously connect a group of motors required at any given time to available VSDs.
In the theatre flying system application area, the connection of a group of motors to their designated VSDs must be made quickly, i.e. in less than half of one second. This precludes the use of a "manual patch" in which an operator plugs a cable from each required motor into an available VSD. Some form of "automatic patch" is needed, where the connections of all power and signal routes between motors and VSDs can be made using controlled switches such as relays, contactors, solid-state switches, etc.
Conceptually, an automatic patch can be represented by a rectangular matrix. Ideally, a "switch" (actually a set of switches, because there are many conductors required to be routed between a winch and its associated drive) would be located at each cross point in the matrix to enable any combination of motors (up to the total number of VSDs) to be connected to a drive each. In practice, this is not economically feasible and would cost more than a system having one VSD per motor.
As an acceptable compromise, a subset of matrix cross points are populated with switches. The number of switches allocated to each motor, i.e. cross points populated in each row of the matrix, will determine the probability of being able to assign a given motor in a group to an available VSD. The probability decreases, of course, as the group size increases. This probability can be quite high for small group sizes, e.g. up to 100%, but it drops sharply as the group size approaches the number of VSDs. One automatic motor-drive patch system has been proposed but it tended to be over complicated and cumbersome to implement. In this system the central controller is coupled to each of the patch switches so that the central controller acting through the patch switches determines which of the motors are coupled to which of the VSDs. This of course requires considerable cabling and also reliability is not optimised. An example of such a system is the scenery flying system implemented at The Olivier Theatre, London and reference is made to a paper entitled The National Theatre 's Scenery Hoist Matrix Scheme by S.K Das and R.H. Keenan.
An object of the present invention is to provide a novel control system which is particularly applicable to an automatic motor-drive patch system.
The invention herein concerns the architecture of the patch and control logic, i.e. the method by which the patch switches are inter-connected and controlled.
In the system of the invention, the control logic is distributed in the network which couples the central controller to the electrical devices to be controlled.
According to the present invention there is also provided a control system for controlling a plurality of electrical devices, a central controller for controlling selected functions of said devices, a plurality of device drivers for providing drive signals to said electrical devices, the number of device drivers being less than the number of devices and a network coupled between said device drivers and said devices, said network including logic elements which determine which devices are coupled to respective device drivers.
Preferably the logic elements are operable to determine which devices are coupled to respective drivers without direct coupling between the central controller and said logic elements. Preferably, the central controller comprises a computer which coordinates network activity.
According to a further aspect of the invention there is provided a stage apparatus control system including a central controUer, a plurality of motors and a patch network including patch buses for coupling the central controller to the motors characterised in that elements of the patch network are coupled to the central controller through the patch buses and are not independently connected thereto.
The invention also provides a stage control system comprising a central computer, a patch network, a plurality of motors characterised in that a satellite processor is provided for each motor.
The invention also provides a stage control system comprising a central computer, a patch network, a plurality of motors characterised in that the system includes a plurality of axis controllers and wherein the axis controllers include logic elements which cooperate in the control of the patch network.
Examples of the invention will now be further described with reference to the accompanying drawings, in which:
Figure IA is a schematic block diagram of a control system of the invention;
Figure IB shows a signal packet generated by the central controller;
Figure 2 shows in more detail a typical control system for a theatrical winch motor;
Figure 3 shows a motor-drive patch matrix of the invention; Figure 4 is a block diagram illustrating part of the control system of the invention;
Figure 5 is a block diagram showing in more detail an electronic patch switch element;
Figure 6 is a block diagram schematically showing the matrix switch logic circuitry;
Figure 7 is a more detailed diagram of the patch switch logic circuitry;
Figure 8 is a block diagram of an axis controller; Figure 9 is a more detailed diagram showing further details of part of the axis controller;
Figure 10 is a block diagram of a satellite processor module;
Figure 11 shows an example of safety switch circuitry;
Figure 12 is a diagrammatic representation of the power patch interlock circuitry; Figure 13 schematically shows manual switching circuitry;
Figure 14 shows a typical front panel of an axis controller;
Figure 15A is a diagrammatic representation of the power switching matrix of a dual- matrix embodiment of the invention;
Figure 15B is a diagrammatic representation of the signal switchmg matrix of a dual- matrix embodiment of the invention;
Figure 16 diagrammatically shows a P patch module for the dual-matrix embodiment;
Figure 17 diagrammatically shows a Q patch module for the dual-matrix embodiment;
Figure 18 shows the P and Q patch modules connected together;
Figure 19 is an alternative schematic representation of the P and Q patch modules connected together,
Figure 20 illustrates a modified dual-matrix embodiment in which there is a LAN connection from the central controller to the satellite module;
Figure 21 shows an alternative dual-matrix embodiment of the invention in which there is a LAN connection from the central controller to the Q modules; Figure 22 shows an alternative dual-matrix embodiment having a LAN connection to the Q modules but a serial connection from the satellite modules to the P modules; and
Figures 23 and 24 show examples of the front panel configurations for the drive switch Q module and motor switch P module for the dual-matrix embodiment.
Figure IA shows a block diagram of a control system of the invention, the control system including a central controller 2 coupled by a LAN 3 to a control network 4 which in turn is coupled to a plurality of electric loads such as motors 6. As will be explained below, the network 4 includes a number of driver devices which are selectively coupled to control the motors 6. The LAN 3 may be of a normal commercially available type such as an ethernet. Figure 2 illustrates in more detail a complete control path which is established between the central controller 2 and one of the motors 6 in a typical control system where there is a variable speed drive (VSD) 10 and axis controllers 8. In the control system of the invention there is no permanently connected control path between the motors 6 and the VSDs 10 but temporary connections are established as required by the control network 4 and controller 2. The temporary control path however has the same or similar control elements as the complete control path shown in Figure 2.
The complete control path of Figure 2 includes an axis controller 8 which is coupled to the central controller 2. The axis controller 8 has a termination panel 12 which is coupled to the VSD 10. Output lines 14 from the VSD 10 are coupled to the motor 6 via a switch matrix 28 which forms part of the control network 4 as will be described in more detail below.
In the ideal system described above the matrix 28 would not be necessary.
The matrix 28 may be a single, double or other type of matrix as explained below.
Figures 3 to 14 are concerned with a single matrix embodiment and Figures 15 to 22 are concerned with a dual-matrix embodiment.
The motor 6 may comprise a three phase motor. The motor 6 includes an encoder or resolver 16 which provides velocity feedback signals to the VSD 10 through the matrix 28. A position (or velocity) encoder 18 is also mounted on the motor shaft so as to provide encoded positional (velocity) signals to the axis controller 8 through the matrix 28 and termination panel 12. Various safety limit switches 20 associated with the motor or the equipment which is moved by the motor are provided to generate safety signals which again are coupled to the axis controller 8 via the termination panel 12.
An AC supply 22 is coupled to the VSD 10 via filters 23, fuses 25 and contacts 27.
When the motor 6 is to be operated, the control system closes the contacts 27. The VSD 10 provides controlled voltages and/or cunents on its output terminals TJ, V and W appropriate for mamtaining a controlled speed and direction of rotation of the motor 6. The axis controller 8 provides input signals to the VSD 10 so as to control such things as the rate of acceleration of rotor speed, maximum constant rotational velocity of the motor, the duration of the period for which constant rotational speed is maintained and the rate of deceleration. These control parameters are important to provide a smooth non-jerky movement of the motor and the equipment coupled thereto. The central controller 2 provides overall control necessary for deterrmning the required sequence of movement of stage equipment such as selecting which motors are to be operated, control of final position of motors, etc. In the illustrated arrangement, a brake 40 is provided to stop rotational movement of the motor 6. It is preferred that the brake is operated in a fail safe way, that is to say it will be applied by means of a spring when power is lost to the brake.
Generally speaking control systems of the type shown in Figure 2 are well known and commercially available and therefore need not be described in detail. For instance, the controller 2 may comprise a Bytecraft .STATE 3. SYSCON (Product No. 811-060), the axis controller 8 may comprise WINCON 3 (No. 811-046) and the VSD 10 may comprise ABB (Model ACS-600) or a SIEMENS drive. The Bytecraft products refeπed to above may incorporate software and hardware elements of the LAN 3. It also includes an interface to deal with additional signals for communication with the matrix 28. The present invention is primarily concerned with the architecture of the matrix 28 which operates to establish control paths which include an axis controller 8, VSD 10 and motor 6, in an installation where there are a lesser number of axis controllers 8 and VSDs 10 compared with the number of motors 6. The central controller 2 is aπanged to generate signal packets 5 of the type illustrated diagrammatically in Figure IB. The signal packets include an address field 7, command type field 9 and command data field 11. The packets 5 are transmitted from the central controller 2 via the LAN 3 and are received by the axis controllers 8, as will be described hereinafter. The axis controllers 8 generate communication packages which are sent via the LAN 3 to the central controller 2 containing information relating to the states of the motors 6 to which connections have been made through the matrix 28.
Figure 3 illustrates diagrammatically part of the network 4 and in particular the switch matrix 28 which is an example of a single matrix configuration. In this aπangement, there are twelve axis controllers 8 each coupled to a respective VSD 10, the VSDs 10 being for controlling thirty-two winch motors 6 which can be connected together by buses which form part ofthe matrix 28, as will be described below. Each of the axis controllers 8 is coupled to a winch control patch bus 24 represented by columns in the matrix and each of the motors is connected to a motor bus 26 represented by rows in the matrix. The buses 24 and 26 can be regarded as a two dimensional matrix, as shown in Figure 3, with a selected number of patch switches 30, comprising a signal switch element and a power switch element. In the illustrated example there are two patch switches 30 in each patch module in the motor buses 26. As shown in Figure 3, each patch switch 30 is coupled in one of the winch control patch buses 24. In the illustrated arrangement, there are five or six of the patch switches 30 provided on each patch bus 24. The patch switches 30 are used to provide interconnections between the winch control patch buses 24 and the motor buses 26. The patch switches 30 can be independently controlled and in practice comprise a number of switches, as will be described below. The number of switches in each motor bus 26 or module can be varied in accordance with control requirements.
The switches 30 are used to provide the connection between the VSDs 10 and the motors 6, it being noted that there is no direct (i.e. permanently established) communication path needed from the central controller 2 directly to the switches 30. It will be appreciated from the foregoing that when a particular motor needs to be operated, it can be coupled through its motor bus 26 and switches 30 to one of two VSDs 10. If one of those VSDs 10 is available, the appropriate coupling is made so that the motor can be operated as required.
Each patch switch 30 itself comprises an electronic patch switch 32 and power patch switch 34, as diagrammatically illustrated in Figure 4. Preferably, the signal switching elements 32 common to a motor signal bus 26 are incorporated into one .Patch Switch Module.. In the example matrix of Figure 3, there are two (2) switch elements per patch module. The electronic patch switch 32 is concerned with switching control signals whereas the power patch switch 34 is concerned with switching in the heavy cuπent supply lines which are required for the motor 6 and brake 40. The electronic patch switch 32 includes a plurality of electronic switches for switching various control lines and the power patch switch 34 includes a plurality of switches for switching in a number of heavy cuπent lines.
Figure 4 illustrates in more detail a selected connection between one of the VSDs 10 and its associated axis controller 8 to the motor 6 through the patch switches 32 and 34. The winch control patch bus 24 and the motor bus 26 include signal buses 36 and power buses 38 which are respectively connected to the switches 32 and 34. The signal bus 36 communicates control signals whereas the power bus 38 handles heavier cunents required for operation of the motor 6 and brake 40 through the power patch switch 34.
It will also be seen from Figure 4 that a satellite processor module 42 is provided for each ofthe motors 6. The satellite module 42 is coupled to monitor the safety switches 20 and the incremental encoder 18 and to provide local storage of data relevant to the motor 6 to which it is coupled. This is important because the axis controllers 8 are shared between the various motors and therefore do not monitor and or store all of this information for the motors to which they could be connected. System security is enhanced by monitoring this data locally at the motor rather than trying to store this information elsewhere for input to the axis controllers 8 when required. Because the functions performed by the satellite module 42 are restricted, it does not need to have powerful processing capabilities.
The power patch switch 34 includes a power relay 44 having contacts 46 and relay coil 48. Operation of the relay coil 48 is controlled by the electronic patch switch 32, as will be described below. It is prefeπed that the power relay 44 includes seven sets of contacts which are used as follows. Three of the contacts are used for three-phase power to the motor 6, another two are used for single phase power to the brake 40 and two further auxiliary (low current) contacts are used for providing status signals which indicate when the patch switch 30 or patch bus 24 to which the switch 30 is connected is being operated, as will be described in more detail below. Figures 5, 6 and 7 illustrate in more detail the signal patch switch 32, or parts thereof. Each switch element 32 includes an identity comparator 50, a contactor driver logic circuit 52, tri-state buffers 54 and relay contacts which allow signals to be selectively coupled between the winch control patch bus 24 and the motor bus 26. The switch 32 includes a DIP 5 switch 56 which can be set so as to define a unique address for each patch switch 30 on a given winch control bus 24. In the illustrated aπangement, the address may be a digital number in the range 0 to 31. The axis controller 8 generates the address signal for a motor select bus 58, which forms part ofthe bus 24, when a particular motor is to be activated. More specifically, the central controller 2 defines which of the motors 6 is to be used and the axis
10 controller 8 receives appropriate information from the central controller 2 and operates to translate this into the address signal for inputting to its motor select bus 58. When the identity comparator 50 detects a match with the address on the motor select bus 58 it generates on its output 60 a P_SEL signal. The P_SEL signal is coupled to the input of the contactor driver logic circuit 52 and other switch components as will be described below. When a patch switch
15 32 is selected, a serial data link 68 is connected between the axis controller 8 and the satellite processor module 42 associated with the selected motor 6. In this way, the status of any motor, bus 24 or 26, electronic patch switch 32, can be monitored by the axis controllers 8 without affecting the state ofthe power patch switches 34. This provides a useful monitoring function which is inherently safe because it can be utilised without changing the state of the 0 switches 34. Moreover, this aπangement enables the absolute position of any motor axis to be read or set by virtue of the serial data links 68 established between the satellite processor modules 42 and the axis controllers 8. As shown in Figure 5, tri-state buffers 64 are used to interconnect the serial data links 66 and 68 which form part of the buses 24 and 26 respectively. The buffers 64 are coupled to the output 60 of the comparator 50 and are 5 therefore only enabled when the P_SEL signal is present.
During the period when a patch switch 32 is selected, a patch status signal
PGRP_FREE is applied to a patch status bus 62 which forms part of the winch control patch bus 24. The PGRP_FREE status signals indicate to the axis controller 8 that power patch 0 contacts 46 forming part of a group common to a motor 6, is energised, as will be described in more detail below.
While a patch switch 32 is selected, it will respond to other control signals from the axis controller 8 to which it is coupled. Also, while it is selected, the serial data communications link to the satellite processor allows the axis controller to momtor the status of the motor. The status information can include the absolute position of the axis of the motor, the state of various safety switches and any other sensors which are connected to the motor's satellite processor 42.
Figure 7 shows the electronic patch switch 32 in more detail. In the illustrated circuit, the contactor driver logic 52 includes a NAND gate 70, one input of which is coupled to the output 60 of the identity comparator 50. Another input of the gate 70 is coupled to a signal line 72 which carries the PGRP_FREE status signal. The final input to the gate 70 is via a signal line 74 which is connected to the bus 24 and canies an engage signal P_ENGAGE which is generated by the axis controller 8 while the patch switch 30 is to be selected. The output of the NAND gate 70 is used to control the base of a relay driver transistor 76, the emitter of which is connected to a control line 78 which in turn is connected to the bus 24. The control line 78 canies status signal PBUS_FREE thereon and is therefore indicative, in the illustrated aπangement, of whether one or other of the two patch switches 34 in a motor bus 26 has been engaged. The power patch interlocks, PBUS_FREE and PGRP_FREE, will only be active (+24V) if no power patch switches 34 have been engaged on the matrix row and matrix column representing the node (switch element 30) selected.
Only when the appropriate signal conditions are present on the three inputs to the NAND gate 70 and the coπect PBUS_FREE status signal on the line 78 can the relay driver transistor 76 turn on and so activate a relay coil 80. The axis controller 8 also provides a relay hold signal P_HOLD on control line 82 which is connected to the bus 24. Accordingly, the patch relay coil 80 can be activated only when the appropriate PBUS_FREE, PGRP_FREE signals are present on the motor bus 26 and P_HOLD signals are provided on the bus 24 by the axis controller. When the axis controller provides a pulsed P_ENGAGE signal on line 74 the transistor 76 will turn on and so activate the coil 80. This closes the contacts 84 which operate to keep the coil 80 activated whilst the P_HOLD signal is maintained on the bus 24 by the axis controller.
The patch relay coil 80 includes a second pair of contacts 86 which are used to control the power patch switch 34, as mdicated in Figures 5 and 7. The contacts 86 are used to control the power patch relay 44, as shown in Figure 4. As mentioned above, in one convenient circuit realisation, the relay 44 has seven pairs of contacts, three of which are used for controlling three phase power to the motor 6, one of which is used for controlling single phase power to the brake 40 and the remaining contacts used to generate control signals.
As seen in Figure 7, the switch driver logic 52 also controls tri-state buffers 88 which allow communication of encoder signals from lines 90 and 92 in the buses 24 and 26 respectively. The encoder signals 90 comprise the signals derived from the incremental encoder 18 through the satellite processor module 42, as shown in Figure 4. The buffers 88 are only enabled when a P_SEL signal is present which occurs when the patch switch 30 has been activated.
The patch switch 32 also includes a safety switch relay having a coil 94, the contacts of which 96 are provided in four safety switch lines 98. The coil 94 is controlled by the switch driver logic 52 so that it is only closed whilst the switch 30 is activated. More particularly, it will be seen that the coil 94 is coupled to line 93, the anangement being such that the coil
94 will only operate to close the contacts 96 when the P_ACTIVE signal is present on line 93.
When the coil 94 is operated it enables transmission of signals on the safety switch lines 98. The safety switch lines 98 are "hard wired", i.e. relay contacts are employed in the patch switches 30 to connect these signals from the satellite processor module 42 and safety switches 20 to the axis controllers 8. This is inherently safer than aπangements in which the switch circuits are not "hard wired" i.e.which utilise .solid-state, electronic switching devices.
The axis controllers 8 monitor the safety signals independently from processor software and it is essential for the connections to be properly made before operation of the motors can commence. A break in any of these connections will result in the motor being unable to move. Thus the system is fail safe. The safety circuits are therefore independent of all electronic controls (such as those generated by the axis controllers 8) and software in the central controller 2.
Figure 8 shows a block diagram of the main circuit components for a typical axis controller 8. Axis controllers are well known in the art and therefore details of this circuit need not be described. Generally speaking, known axis controllers can be utilised in the system of the invention with very little modification. Essentially, the modification requires the addition of interface logic 71 to a microprocessor 69 in the axis controller 8. The axis controller requires additional signal lines in order to provide control signals for the signal matrix 28. Figure 9 diagrammatically shows one implementation for the interface logic 71. The operation ofthe logic 71 is straightforward and need not be described in detail. The axis controller 8 preferably has a number of additional signal lines through the logic 71 in order to control the matrix. The additional signals will be described later with reference to an example of a dual-matrix embodiment. After receipt of a system controller command packet by the axis controller the microprocessor 69 checks the command type field 9 and also interprets the command data in the field 11. It then generates the appropriate patch switch 30 control signals in accordance with the instructions in data field 11.
Figure 10 diagrammatically illustrates the satellite processor module 42. The satellite processor 42 includes a microcontroller 73 having inputs coupled to the encoder 18 and safety switches 20 (which may include other sensors such as for sensing other parameters such as over travel of a winch to which the motor is connected, a crossed wire on a winch drum or slack winch wire or the like). The microcontroller 73 commumcates with axis controllers 8 via the serial data links 68 and 66 via an RS-485 asynchronous full duplex protocol type link 75. The main function of the satellite processor module 42 is to continuously maintain data relating to the absolute position of the motor axis to which it is coupled. It also monitors safety switches and other sensors fitted to each of the motors and/or winches, independently of the axis controllers 8. The satellite processor modules 42 and the sensors connected to them are preferably powered from a battery-backed power supply 100 so as to avoid problems which might occur if power were temporarily lost to the satellite processor modules 42.
Figure 11 diagrammatically illustrates one example of the way in which the safety switches 20 are connected to the microcontroller 73. In this arrangement, four safety switches 113, 114, 116 and 118 are connected in series via a load 120 to a +24V supply. Safety input lines 122 are coupled as inputs to the microcontroller 73 via buffer amplifiers 123. In the normal anangement, all of the switches are closed and thus all of the logic inputs to the satellite processor are high. If, however, one of the switches opens, the circuit will be broken and the microcontroller 73 will be able to identify which ofthe switches 113, 114, 116 and 118 has opened. If two or more switches go open at the same time, the microntroller 73 cannot tell which ones are open but it should always be able to identify which switch opened first. This will enable an operator to rectify the fault which caused the conesponding safety switch being closed. The next switch which remains open can then be identified by the microcontroller 73 and the operator should again be able to rectify the fault. In a typical aπangement, the switch 113 may indicate overload on the winch motor 6, the switch 114 indicates a chain break in a winch, the switch 116 may indicate a "crossed groove" on the winch drum and the switch 118 indicates a slack wire in a winch.
Optionally, the satellite modules 42 may be located in close proximity to their respective motors rather than in say the winch control room where typically the axis controllers 8, VSDs 10 and patch switches 30 would be situated. This has the benefit of reducing the amount of cabling from the control room to the location of the motors.
Figure 12 diagrammatically illustrates how two further pairs of auxiliary normally closed contacts 87 and 88 of the power patch relays 44 are used to generate the PBUS_FREE and PGRP_FREE signals on the lines 72 and 78. This can conveniently be effected by arranging for the auxiliary contacts of the power patch relays to be of the normally closed type so that when the relay 44 is activated the contacts 87 and 89 will be open. The signal line 78 of the three patch switches 34 common to a matrix row [in either the motor matrix or the drive matrix of a dual -matrix implementation] are effectively connected in series and, when one ofthe switches ofthe group has been selected, its contacts in the line 78 will be open and this state indicates that the group is not free. Similarly, the auxiliary contacts in the line 72 of all of the switches 34 common to a matrix column will effectively be connected in series and when one of the switches 30 in the column has been activated, the auxiliary contacts will open and this state indicates that the patch bus 28 is not free.
Thus, the power patch interlocks, PBUSJFREE and PGRP_FREE, will only be true if no power patch contactors are engaged on the matrix row and matrix column representing the node (switch element) selected. As diagrammatically shown in Figure 12, PBUS_FREE is derived from a series connection of auxiliary contacts of all contactors on the matrix column, i.e. all contactors under the control of a particular axis controller 8. PGRP_FREE is derived from a series connection of auxiliary contacts of all contactors on the matrix row, i.e. all contactors associated with a particular winch motor 6.
In summary, a combination of conditions needs to be satisfied before a power patch switch 30 can be engaged:
(a) The control system power supply (24V DC) must be operating; (b) The axis controller power supplies (5V and 24V DC) must be operating;
(c) The axis controller must have its P_HOLD signal (24V DC) applied to the bus 24;
(d) The patch switch 32 must be selected via the motor select bus 58;
(e) The coπect safety interlock status signals PBUS_FREE, and PGRP_FREE must both be present on the lines 78 and 72; and
(f) The axis controller must pulse the P_ENGAGE signal on patch bus for coupling to the line 74.
The patch switches may, optionally, be operated manually, i.e. without involving the axis controller logic. Figure 13 diagrammatically illustrates one circuit anangement for connecting the operator control switches 108 and 109 which are used during manual operation. It will be noted that the engage switch 108 is connected in series with interlock contacts 124 which are controlled by an interlock relay 126. The interlock relay 126 is powered from the line 78 which canies the PGRP_FREE signal. This provides a safety interlock because the engage switch 108 will not be operative unless the PGRP_FREE signal on line 78 is present, thereby providing safety interlock even during the manual operation. The aπangement includes a switch 128 which may comprise a rotary or thumb wheel selector for selection of the desired patch bus to be engaged.
Figure 14 diagrammatically illustrates a front pantl 102 for an axis controller 8. It will be seen that the panel includes indicating lamps 104 for indicating the state of various signal parameters. It also includes an ethernet connector 105 for coupling to the LAN 3.
The principles of the invention are applicable to dual-matrix systems. Examples of the dual-matrix systems will now be described with reference to Figures 15 to 22. In the single matrix example described above, a patch single switch closure on a matrix node will connect a winch motor to a VSD 10. The performance/cost ratio of a patch system can be dramatically improved by extending the concept to the dual-matrix configuration.
Figure 15A diagrammatically illustrates the power switching part of a dual-matrix configuration in which there is a motor switch matrix 127 and a drive switch matrix 129. The dual-matrix configuration can be aπanged to provide appropriate connections between the axis controllers 8 and the VSDs 10 and the motors 6. As in the case of a single matrix configuration, in the dual-matrix configuration, the temporary connections between the axis controllers 8 and the VSDs 10 and motor 6 are established by the control network 4. In order to achieve this, the dual-matrix configuration is established by aπanging for a motor matrix 127 to be established in the upper rows and a drive matrix 129 for the VSDs 10 to be established in the lower rows. The patch buses 24 comprise the matrix columns which extend from the motor matrix to the drive matrix. Inputs to the rows of the drive switch matrix 129 are derived from VSD's 10. In the drive switch matrix 129, populated patch switches 34 are indicated by means of squares in the matrix. In the drive switch matrix 129 there are four switch elements 34 in each row and three patch switch elements 34 in each column. In the motor switch matrix 127, there are two patch switch elements 34 in each row and three in each column. Outputs from the rows in the matrix 127 are coupled to the motor bus 26 for connection to the motors 6. Each of the patch switches 30 in the matrices 127 and 129 can be similar to the power patch switch 34 of the single matrix embodiment.
Figure 15B shows diagrammatically another part of the dual-matrix embodiment.
More particularly, this drawing shows matrices used for switching of signals and the general form is similar to that shown in Figure 15A. Figure 15B includes a drive signal switch matrix 140 and a motor switch matrix 142. Inputs to the rows of the matrix 142 are from axis controllers 8. Outputs from the matrix 142 are to the satellite processor modules 42. The patch switches 30 in the matrices 140 and 142 are analogous to those described previously. In the matrices 140 and 142, the patch switches 30 can be implemented in accordance with the patch switch 132 (Q module switch element) diagrammatically illustrated in Figure 17. Figure 16 is a block diagram showing schematically a signal patch switch element 131 which can be used for the patch switches 32 in the motor signal matrix 142. The switch 131 operates analogously to the switch 32 shown in Figure 5 and need not be described in detail.
It will be appreciated by those skilled in the art that the operation of the dual-matrix configuration is analogous to that of the single matrix example refened to above, assuming that appropriate control signals are provided by the axis controllers 8 for selecting both the motors 6 and VSDs 10. In order to effect a power path between a selected motor 6 and VSD 10, one of the patch switches 34 in each of the motor matrix 127 and drive matrix 129 would need to be closed on the same bus 24.
Various algorithms could be adopted for selecting the motors and VSDs to be coupled for a particular control function. In the system of the invention, the selection of the motors to be coupled and the patch switches to be closed in the matrix or matrices is determined by the central controller 2. The central controller 2 preferably also stores the overall state of the matrix, that is to say stores information regarding which patch switches are closed in the matrix. The central controller 2 also operates a routing algorithm in order to select which switches should be closed in order to establish a connection between a VSD and a motor. This information is also stored in the central controller. The central controller also stores information regarding any failed components in the system so that these can be bypassed. Set out below is a simple routing algorithm for a dual-matrix scheme:
Finding a set of paths through the dual-matrix for a group of machines.
Start:
For each motor in the group.
Find the first available bus which could be connected to the motor (populated matrix node).
If there is an available bus for the motor.
Try a limited number of times to find an available drive for bus. If a drive can be found for the bus.
Mark the motor, bus and drive as allocated, "busy" (not free).
If no bus or drive were allocated.
Pick a random bus which is associated with the cuπent motor. Pick a random drive which is associated with the selected bus. Deallocate the bus connected to the selected drive. Deallocate the drive connected to the selected bus.
Try again to allocate a bus and drive to the cunent motor.
If there were any motors which were deallocated
Go back to start and repeat for the motors without a connection. Repeat a finite number of times before deciding there is no path. The central controller 2 may include stored information relative to the matrix or matrices to which it is coupled. This will enable it to cany out the routing algorithm required in practice. In some circumstances, it may be convenient to instal in the central controller 2 a program which can generate the matrix information tables so that on commissioning the equipment the central controller can be loaded with information which is appropriate for the matrix which has been established. Also this would enable the equipment to be altered if the matrix were changed.
A computer program listing in the programming language C is given in Appendix I. This routine implements a patch "routing algorithm" based on the foregoing outline. This program would refer to matrix tables stored in the central controller or generated by software in the central controller.
The dual-matrix scheme not only raises the probability of finding a route between each motor and a drive for large groups of motors, using fewer switches than a single matrix, but also offers a high degree of fault tolerance due to the ability to assign a drive to one of several buses. This means that any group of motors can be assigned a drive, even when some drives or axis controllers may be out of service.
In the illustrated example (Figure 15), up to seven motors chosen at random can be assigned a VSD 10, with a 100% probability of finding a patch route for each. The probability drops to 99.7% for groups of eight motors and to 85.6% for twelve motors.
It can be shown that the probability of successfully finding a path through the matrix is influenced by several inter-related features of the design of the matrix. The matrix is largely specified by "R" (the number of patch buses 24), "P" (the number of buses available to each motor) and "Q" (the number of buses available to each drive) and finally, the pattern of population of cross points within the matrix.
Since "P" is the number of switches per motor, then it must be an integer value and it should also be equal for each motor in order that the matrix be regular. It can be shown that the probability of success is improved greatly when "P" is 3 when compared with when "P" is 2. Increasing P beyond 3 yields marginal benefit when contrasted with the additional cost and complexity of constructing the matrix. For the example shown in Figure 15, extending the configuration to twenty-four buses and three switches per motor (P=3), the probability increases to 100% for eleven motors and 99.5% for twelve motors.
Similarly, "Q" must also be integer. Since there are many more motors than drives, then increasing "Q" does not have the same cost impact on the matrix and thus "Q" is typically larger than "P". Because "P" and "Q" share common buses, then "P" and "Q" must be factors of "R", the number of buses. Further, "R" must be larger than the minimum number of motors which must be able to be patched in at any one time. Finally, the cross point population of the matrix is selected so that where possible, no two motors share the same combination of bus connections.
The optimal configuration of the matrix for a given application is designed with these guidelines and optimised with the computer simulation of thousands of routing attempts.
As mentioned previously, the axis controllers 8 can be similar to known axis controllers but having additional signal processing capabilities for handling communications with the matrix 18 whether single or dual. For a dual-matrix system of the type shown in Figures 15A and 15B, the additional signals to be handled by the axis controller include:
QBUS_FREE Input signal (when high) indicates to axis controller and Q-module that the patch bus for that particular Q-module Switch is in fact free.
QGRP_FREE Input signal (when high) indicates to an axis controller 8 that no other Q- switch in that particular Q-module has been selected. That is, axis controller 8 can only select one patch bus at a time. - 21 -
Q_ENGAGE Output signal (when pulsed high) commands a particular selected Q-module switch to activate itself fully and also to activate its associated power contactor. This forms the first part of a path through the power contactor matrix.
Q_HOLD Output signal that must be high to allow the Q_ENGAGE signal to activate the selected Q-switch element. This signal remains high whilst the particular Q- switch is activated. If this signal goes low then the particular Q-switch and power contactor will be disengaged.
PBUS_FREE Has same function as Q-matrix QBUS_FREE but is on a P-module. Signal is routed via Q-module and patch bus to P-module.
PGRP_FREE Has same function as Q-matrix QGRP_FREE but is on a P-module. Signal is routed via Q-module and patch bus to P-module.
P_ENGAGE Has same function as Q-matrix Q_ENGAGE but is on a P-module. Signal is routed via Q-module and patch bus to P-module.
P HOLD Has same function as Q-matrix Q_HOLD but is on a P-module. Signal is routed via Q-module and patch bus to P-module.
MSELO-3 Binary nibble output signals routed via Q-module/patch bus to nibble comparators on each P-module. If nibble matches a particular P-module DIP switch setting then that P-module is SELECTED (not ENGAGED as yet however).
BUSBUSY Input signal (when high) to axis controller to indicate that a particular signal bus is in fact engaged by another axis controller/Q-module. SELENAB Output signal that allows an axis controller/Q-module to assert a particular bus-busy signal when that Q-module switch is selected. Indicates to other Q- modules on bus that bus is cunently selected.
CHA Input encoder signal that originates from winch motor position encoder (First quadrature encoded channel signal). Routed from satellite processor module 42 via P-module-Bus-Q-module.
CHB Input encoder signal that originates from winch motor position encoder 18 (second quadrature encoded channel signal) and is routed from satellite processor module 42 via P-module-patch bus-Q- module.
ZMARK Input encoder signal that originates from winch motor position encoder 18 (encoder "zero-position" indicator pulse). Router from the satellite processor module via P-module-patch bus-Q-module.
TXD Transmitted serial data to the satellite processor module 42. Allows commands and general control of the satellite processor module.
RXD Received serial data from the satellite processor module 42. Allows status of satellite process or module to be read also used for handshaking and acknowledgement of commands.
FWDOTR Forward overtravel safety signal. It is routed from the satellite processor module 42.
REVOTR Reverse overtravel safety signal. It is routed from the satellite processor module 42.
AUXIN1 First auxiliary safety signal. It is routed from the satellite processor module 42. It can also be used as backup safety signal.
AUXIN2 Second auxiliary safety signal. It is routed from the satellite processor module
42. It can be used as backup safety signal.
QSELO-2 3 bit encoded output signal used to select one (or none) of six Q-switches on a Q-module PCB. This is SELECT only, not engage.
Some additional processing is carried out by the microprocessor 69 which is included in the axis controller 8. The axis controller interprets the command types in the command type field 9. Four of these command types are outlined below.
1. Set Motor ID command:
The satellite processor module 42 can be down loaded with the motor (batten) number. This command should specify the low-level patch bus address and P-module address to connect to the required winch. Signal patch must be connected via P and Q modules. Signal is communicated via serial TXD and RXD lines.
2. Configure Axis command: The satellite processor module 42 will be down loaded with any parameters specific to its winch motor such as the axis absolute position. Signal is sent via patch TXD and RXD lines. Whenever the axis controller 8 establishes a patch route to the satellite processor module 42, it must read the motor number stored in the satellite processor module and verify that the number is the same as that in the command packet.
3. Matrix Poll command:
Requests an axis controller 8 to activate a signal route to a specified satellite processor module 42, without engaging any power patch contactors. The patch bus to be used will be dictated by the central controller 2. The axis controller 8 will check for bus contention and other anomalies. This is done via the BUSBUSY
Figure imgf000025_0001
If the route can be made then the bus is selected via SELENAB and QSELO-2 lines. The axis controller will get winch motor position and status from the satellite processor module via TXD/RXD and respond to the central controller 2. The signal route is kept until a subsequent poll command changes it.
4. Matrix Pre-move command:
A pre-move command will instruct the axis controller 8 to engage a patch route to a specified winch, using a specified patch bus. This is done using the Q/P_ENGAGE and Q P_HOLD signals. The patch switch elements should be SELECTED beforehand. The axis controller 8 will check for contention and other anomalies via BUSBUSY and integrity or actual existence of RXD signal. If the route can be made, the axis controller 8 will attempt to engage the two power contactors required and verify the patch (using the interlock monitoring signals Q/P BUS_FREE and GRP_FREE). The axis controller 8 will initialise its winch motor position and status as read from the satellite processor module 42 and respond to the central controller 2.
The axis controller 8 normally includes a service port CLI which may be extended to include patch diagnostics and commands to drive the patch manually for fault detection or local control ofthe various winch motors 6 without control signals from the central controller 2.
Refeπing now to Figure 18, each axis controller 8 is connected directly to one VSD 10 and one Q-Module, each of which comprises six of the patch switches 132, only one of which is shown in Figure 18 for clarity of illustration. Similarly, a P module is made up from three of the patch switches 131 and again only one is shown in Figure 18. The entire system comprises a plurality of controllers 8, VSDs 10, Q-Modules and P- Modules, all of which are controlled by the central controller 2 via signals sent over the LAN 3. There is no direct connection for control or status signalling to the P-Modules from the axis controllers 8. These signals are themselves routed to the selected P-Module from the axis controller 8 via its attached Q-Module using the patch switches of the patch buses. The control and status signals from the VSDs 10 to the P Modules are switched onto the patch signal buses by the Q Modules. Once a patch switch 132 (Q module) is closed in the drive matrix, one of sixteen modules in the motor matrix can be selected. The actual number depends on the detailed patch design. This is effected by the MOTOR SELECT signal bus 133 (4 lines). The axis controller 8 having addressed the desired motor switch element 131 (P-Module), then engages the motor switch thereby completing the patch route. Separate interlocks from the motor contactor matrix and drive contactor matrix prevent more than one switch from being energised in any row or column in each matrix.
The ability of the axis controllers 8 to poll winch status by connecting to satellite processor modules 42, without the need to disturb the power patch, is retained in the dual- matrix scheme. However, it is prefeπed to include means to prevent two or more axis controllers 8 sharing a common patch bus from addressing the same bus simultaneously. While this eventuality could not result in a fault in the power patch, because of the safety interlocks, it would create contention between two or more satellite processor modules 42 attempting to transmit on the same serial link in the patch signal bus.
Figure 19 is an alternative representation of the circuit shown in Figure 18. This representation shows the motor switch matrix 127 and drive switch matrix 129 of Figure 15A together with the drive switch matrix 140 and motor switch matrix 142 of Figure 15B.
Figure 20 shows schematically a modified form of dual matrix embodiment. In this embodiment, the LAN 3 extends directly from the central controller 2 to the satellite processor module 42 to thereby enable the central controller 2 to establish complete system status based upon information transmitted to it by the LAN from the satellite processor modules 42. It will be appreciated that this system status can be gathered entirely independently of the patch switches in the matrix and therefore can be used to provide additional system reliability checks. Also in this embodiment, the patch switches 131 of the P modules are controlled directly by the satellite processor module 42 via P module control bus 135 rather than via signals from the axis controllers 8 via the matrixes 127 and 129. In this scheme there is a one to one conespondence between the patch switches in the P modules and the satellite processor modules 42. The functions of the switches 131 of the P module and the satellite processor module 42 could be combined into a single module. In this embodiment, the topology is more readily understandable and results in fewer conductors in the signal matrix buses.
5 Figure 21 shows schematically a further modified form of dual-matrix embodiment.
This aπangement is essentially similar to Figure 20 except that the LAN 3 is extended so as to provide direct control from the central controller 2 to the Q modules.
Figure 22 shows schematically a further modified form of dual-matrix embodiment.
10 In this embodiment, the central controller 2 directly controls the patch switches 132 of the Q modules via the LAN 3. The satellite processor modules 42 control the patch switches in the matrices 127 and 142 from the satellite processor module 42 via the serial data link 68, as in the case of Figure 19.
15 Figures 23 and 24 show examples of the front panel configurations for the drive switch
Q module and motor switch P module comprising groups of the patch switches 132 and 131 respectively. As diagrammatically shown in Figure 23, the front panel of the drive switch Q module may include an engage switch 108 and a release switch 109 for manually engaging or disengaging the patch switches 132 therein. The panel may include indicating LEDs 111 and
20 112 for indicating the states of the patch switches 132. As described previously, the circuit diagram of Figure 6 illustrates the manner in which indicating LEDs 111 and 112 are connected in or to be illuminated to indicate the states of the patch switches 132. More particularly, each LED 111 is coupled to contacts 46 of the power patch switch 34 and is thereby illuminated when the selected motor bus 26 is busy. Each LED 112 is effectively
25 connected in parallel with a relay coil 80 and will be illuminated when a switch element within the module has been engaged which coπesponds to when the P_ACTIVE signal is present.
Figure 24 diagrammatically illustrates a front panel of a motor switch P module which includes a number of patch switches 131 therein. The panel may include mdicating LEDs for
30 indicating the states of the switches therein. The panel may include a number of engage switches 140 and a release switch 142 for manually engaging or disengaging the patch switches 131 therein.
It will be appreciated by those skilled in the art that the control system of the invention has many advantages which can be summarised as follows:
1. The patch control logic is distributed in the control network 4 rather than being centralised in the central controller 2.
2. Each axis controller 8, in addition to its motion control function, is also responsible for the control and monitoring of a number of patch switches 30. The axis controller is capable of addressing a number of patch switches on its winch control patch bus 24.
3. A single module is dedicated to each motor 6. Each patch switch 30 within the module is controlled and monitored by a different axis controller 8. (In Fig. 3, a patch switch module comprises two switches 30, but the number may vary from system to system).
4. The patch matrix topology can be optimised for each application, i.e. the number of VSDs required and the number of patch switches 30 per motor can be varied to suit each application.
5. The patch switch module incoφorates novel safety interlocks to prevent abenant switch operation and uncontrolled motor axis motion. More particularly, the signals from critical safety switches are available to the central controller 2 via two paths. They are transmitted in serial format by the serial processor 42 and are also hard wired. This provides enhanced safety.
6. The patch switch module, in conjunction with the axis controller interface logic, provides a mechanism whereby the status of any motor (e.g. its absolute position, safety switch and sensor inputs, etc.) can be monitored without the need to activate or change the power patch switch 34 (i.e. connecting the drive power circuits to the motor). Consequently, the status of motors can be determined without disturbing the cuπently active power patch 34.
7. The patch switch module can incorporate independent manual backup controls and indicators on the front panel. This allows manual setting up of the patch switches in the event of failure or unavailability of axis controller processors).
8. The satellite processor module 42 being situated on the axis side of the matrix enables the use of an incremental position encoder 18. The satellite processor module 42 contains circuitry enabling it to remember at all times the position of the axis of the motor 6 to which it is connected. When a route is established through the matrix between an axis controller 8 and a motor, the satellite processor module 42 transmits the motor access position to the controller 8 prior to commencement of any motion. The axis controller 8 then uses this position in its control algorithm. This results in more reliable operation of the system. In place of the incremental encoder 18 an absolute encoder may be used.
9. The satellite processor module 42 enables the accuracy of the signal matrix route to be confirmed. In prefened embodiments of the invention, auxiliary contacts 87 and
89 in each power patch contactor are used to generate PBUS_FREE and PGRP_FREE signals which are used to provide "row" and "column" proving signals. The technique for generating these signals and the manner in which these are used provides additional system reliability.
10. In preferred embodiments of the invention, it is possible to monitor the background status of motors. This can be accomplished by aπanging for the satellite processors 42 to be polled via their serial communications links to gather the status of the motors to which they are coupled. 11. The prefeπed embodiments of the invention enable the power matrix contacts 46 to be switched independently from switches within the electronic patch switch 32. This means that the signal matrix routes can be established without operating or affecting the condition of power relays. If this were not the case, then background status monitoring of the motors would not be practical because it would necessitate switching power relays frequently and this would result in excessive wear, noise and low speed of operation.
12. Prefened embodiments of the invention can be used to generate a global emergency stop condition. The satellite processor modules 42 are able in certain circumstances to detect illegal motions of a motor axis. If the motor axis is cuπently patched, i.e. connected via the patch switch 30 to an axis controller 8 and drive 10, the satellite processor could signal this condition to the controlling axis controller 8 and the appropriate action could be taken. If, however, illegal motion was detected in a condition in which a motor axis is not properly patched (such as might occur with a malfunction in the power matrix), then the satellite processor module 42 would normally be powerless to intervene. To guard against this possibility, the satellite processor module 42 can be provided with a Global Emergency Stop output which can be connected to a central emergency stop system. Such a signal can be used to aπest motion of all machinery or all machinery within a defined area. This is diagrammatically represented by the energy stop system 144 shown in Figures 19 to 22.
It will also be appreciated by those skilled in the art that the principles of the invention can be applied in situations other than the control of motors associated with stage equipment.
Many modifications will be apparent to those skilled in the art without departing from the spirit and scope of the invention. APPENDK I
SIMULATED ROUTING ALGORITHM
#include <stdio.h>
#include <sys/types.h>
#ifhdef unix
#iπclude <time.h> ttnclude <mem.h>
#endif
#include "defs.1T
#include "readfile.h"
/*
* DEFINES
V
#define FREE -1
#define USAGE " s: [-f <filename>] [-t N] [-d N] [-F N] [-S] [-R] [-Dgrfesdt]\π"
/*
* STRUCTURES
*/
/
* FILE GLOBALS
*/
static intlό awGroup[MAX_GROUP]; static intlό awMotorCount[MAX_MOTORS]; static intβ abFailedDrives[MAX_DRIVES]; static struct
{ intlό wMotor; intlό wDrive; } asRoute[MAX_BUSES];
static intlό wNumberTests = 1000; static intlό wMaxRouteDepth = 500; static int8 bSortGroup = FALSE; static int8 bRevSort = FALSE; static int8 bDebugPrintGroup = FALSE; static int8 bDebugRouting = FALSE; static int8 bDebugFinalRoute = FALSE; static int8 bDebugFailedRoute = FALSE; static int8 bDebugSort = FALSE; static int8 bDebugRunningDisplay = FALSE; static intlό wMaxRoutedDepth; static intlό wNumberOfFails = 0;
/*
* EXTERNALS
*/ extern intlό awPSwitchMatrix[MAX_MOTORS][MAX_P]; extern intlό awQSwitchMatrix[MAX_DRIVES][MAX_Q]; extern intlό wMotors; extern intlό wNDrives; extern intlό PSwitches; extern intlό wQSwitches; extern intlό wRBuses; #ifdef unix extern char *optarg; extern int32 optind;
#endif I*
* FUNCTION PROTOTYPES
*/ static void TestRoute(intlό wGroupSize); #if def unix char getopts(char *, int, char *[], char **); #endif
/* * CODE V void main(int lArgc, char *pachArgv[])
{ int32 IC; intlό wGrpSize;
FILE *pFP = stdin; #ifhdef unix char *optarg; #endif
#ifdef unix while ((IC = getopt(lArgc, pachArgv, "f:t:d:D:F:RSh?")) != -1) #else while ((IC = getopts("ftdDFRSh?π, lArgc, pachArgv, &optarg)) > 0)
#endif
{ switch(lC)
{ case : if ((pFP = fopen(optarg, V)) == NULL)
{ fprintf(stderr, "Open failure on %s\n", optarg); exit(l);
SHEET Rule 26 } break;
case 't': wNumberTests = (intlό)atoi(optarg); break;
case 'd': wMaxRouteDepth = (intl6)atoi(optarg); break;
case 'F: wNumberOfFails = (intlό)atoi(optarg); break;
case 'S': bSortGroup = TRUE; break;
case 'R': bRevSort = TRUE; bSortGroup = TRUE; break;
case T>': switch (*optarg)
{ case 'g': bDebugPrintGroup = TRUE; break;
case *r': bDebugRouting = TRUE; break; case 'f: bDebugFinalRoute = TRUE; break;
case 'e': bDebugFailedRoute = TRUE; break;
bDebugSort = TRUE; break;
case 'd': bDebugRunningDisplay = TRUE; break;
} break;
case '?': case 'h': fprintf(stderr, USAGE, pachArgv[0]); exit(l); break; }
}
ReadMatrices(pFP); if (pFP != stdin) { fclose(pFP); }
for (wGφSize = wNDrives - wNumberOfFails; wGφSize > 0; wGφSize — ) {
TestRoute(wGφSize);
}
exit(0);
}
/*
* Create the group
static void
CreateGroup(intl6 wGroupSize)
{ intlό wGφMember, wTemp;
wGφMember = 0;
for (wGφMember = 0; wGφMember < wGroupSize;)
{ awGroup[wGφMember] = randi % wMotors; for (wTemp = 0; wTemp < wGφMember; wTemp++)
{ if (awGroup[wTemp] == awGroupfwGφMember])
{ break;
}
} if (wTemp == wGφMember)
{ wGφMember++;
} } if (bDebugPrintGroup)
{ printf("\nGroup "); for (wGφMember = 0; wGφMember < wGroupSize; wGφMember++)
{ printf("%4d", awGroup[wGφMember] + 1); } printf(B\n"); fllush(stdout); }
}
/*
* Rip-up a Route to make the routing of the motor possible
V static intlό RipUpRoute(int 16 wMotor)
{ intlό wBus, wRippedUpMotor; intlό wDrive, wQSwitch;
for (;;)
{ wBus = awPSwitchMatrix[wMotor][rand() % wPSwitches]; if (asRoute[wBus].wMotor != FREE)
{ if (bDebugRouting)
{ printf("Rip up %3d for %3d Bus %2d Drive %2d\n", asRoute[wBus].wMotor + 1, wMotor + 1, asRoute[wBus].wMotor + 1, asRoute[wBus].wDrive + 1); } wRippedUpMotor = asRoute[wBus].wMotor; asRoute[wBus].wMotor = FREE; asRoute[wBus].wDrive = FREE; break; } else
{ intlό wTempBus;
do
{ wDrive = randO % wNDrives; wQSwitch = randO % wQSwitches; } while (awQSwitchMatrix[wDrive][wQSwitch] != wBus);
do
{ wQSwitch = randO % wQSwitches; wTempBus = awQSwitchMatrix[wDrive][wQSwitch]; } while (wTempBus == wBus);
if (asRoute[wTempBus].wDrive != FREE)
{ if (bDebugRouting)
{ printf("Rip up %3d for %3d Bus % 2d Drive %2d\n", asRoute[wTempBus] .wMotor + 1, wMotor + 1, asRoute[wTempBus] .wMotor + 1, asRoute[wTempBus].wDrive + 1);
} wRippedUpMotor = asRoute[wTempBus] .wMotor; asRoute[wTempBus].wMotor = FREE; asRoute[wTempBus].wDrive = FREE; break; } return(wRippedUpMotor); }
static intδ RouteMotor(intlό wMotor)
{ static intlό wRouteDepth = 0; intlό wPSwitch, wQSwitch, wDrive, wBus; intlό wRippedUpMotor, wTemp;
if (bDebugRouting)
{ printf("Route depth %d\n", wRouteDepth);
}
if (++wRouteDepth > wMaxRoutedDepth)
{ wMaxRoutedDepth = wRouteDepth;
}
for (wPSwitch = 0; wPSwitch < wPSwitches; wPSwitch++)
{ wBus = awPSwitchMatrix[wMotor][wPSwitch]; if (asRoute[wBus]. wMotor == FREE) { for (wDrive = 0; wDrive < wNDrives; wDrive++)
{ if (abFailedDrives[wDrive] == TRUE)
{ continue;
} for (wQSwitch = 0; wQSwitch < wQSwitches; wQSwitch++)
{ if (awQSwitchMatrix[wDrive][wQSwitch] == wBus) { for (wTemp = 0; wTemp < wRBuses; wTemp++)
{ if (asRoute[wTemp].wDrive == wDrive) { break;
} } if (wTemp == wRBuses) { if (bDebugRouting)
{ printf("Route %3d thru %2d to %2d\n", wMotor + 1, wBus + 1, wDrive + 1); } asRoute[wBus].wMotor = wMotor; asRoute[wBus].wDrive = wDrive; wRouteDepth — ; return(TRUE); }
}
}
/* * No free routes so need to make one
V if (wRouteDepth < wMaxRouteDepth)
{ wRippedUpMotor = RipUpRoute(wMotor); if (RouteMotor(wMotor)) { if (RouteMotor(wRippedUpMotor))
{ wRouteDepth — ; return(TRUE); }
} } wRouteDepth — ; return(FALSE); }
/*
* Route the group
*/ static int8
RouteGroup(intl6 wGroupSize)
{ intlό wMemb, wBus; intlό wCount;
/*
* Clear all route information V for (wBus = 0; wBus < wRBuses; wBus++) { asRoutejwBus] .wMotor = FREE; asRoute[wBus].wDrive = FREE; }
/*
* Fail the required number of drives V for (wCount = 0; wCount < wNDrives; wCount++)
{ abFailedDrives[wCount] = FALSE;
} for (wCount = 0; wCount < wNumberOfFails;)
{ intlό wDrive = randO % wNDrives;
if (abFailedDrives[wDrive] != TRUE)
{ abFailedDrives[wDrive] = TRUE; wCount++;
} }
/* * Route the group V for (wMemb = 0; wMemb < wGroupSize; wMemb++)
{ if (!RouteMotor(awGroup[wMemb])) { return(FALSE);
} } return(TRUE);

Claims

CLAIMS:
1. A control system for controlling a plurality of electrical devices (6) said system including a central controller (2) for controlling functions of said devices, a network (4) coupled between the central controller (2) and said devices, said network including a plurality of device drivers (10) for providing drive signals to said electrical devices, the number of drivers being less than the number of devices characterised in that the network includes intelligent devices (8) which enable communication through the network from the central controller (2) to the devices (6).
2. A control system as claimed in claim 1 wherein the network (4) includes a matrix (28;127J29;140J42) defined by control patch buses (24), device buses (26) and said logic elements (30) which are distributed in said matrix and are operable to couple selected buses together to thereby determine, subject to control from said intelligent devices (8), which devices (6) are coupled to respective device drivers (10).
3. A control system as claimed in claim 2 wherein the network includes patch switches which are selectively provided at nodes in the matrix.
4. A control system as claimed in claim 3 wherein the electrical devices comprises an electrical motor (6).
5. A control system as claimed in claim 4 wherein remote processing means (42) is associated with each motor.
6. A control system as claimed in claim 5 wherein sensors are coupled to the motor and outputs from the sensors (18,20) are inputted to the remote processing means (42) of the associated motor.
7. A control system as claimed in claim 6 wherein said processing means includes memory for storing data from the sensors independently of said central controller.
8. A control system as claimed in any one of claims 3 to 7 wherein the central controller 5 is coupled to said intelligent devices by means of a local area network (3) and the central controller is aπanged to generate signal packets (5).
9. A control system as claimed in claim 8 wherein each command packet includes an address field (7) for the intelligent device, a command field (9) and a data field (11).
10
10. A control system as claimed in claim 9 wherein the intelligent device comprises an axis controller (8) having processing means (69) therein and wherein the processing means (69) is operable to receive said command packets (5), check for address matches, to interpret a command type from said command fields and to interpret an instruction from said data field.
15
11. A control system as claimed in claim 10 wherein the central controller inputs data instructions in said data field for the selection of a particular electrical device (6) to be coupled to one of said device drivers (10).
20 12. A control system as claimed in claim 10 wherein the data instructions in said data field (11) further include instructions for closure of selected patch switches (30) to establish a route from said one device driver (10) to said particular electrical device (6).
13. A control system as claimed in claim 12 wherein the processing means (69) in the axis 25 controller, in response to said instructions for closure of selected patch switches (30), generates patch control signals which are transmitted to the selected patch switches (30).
14. A control system as claimed in claim 13 wherein the axis controller (8) checks the status of the selected patch switches (30).
30
15. A control system as claimed in claim 14 wherein after said selected patch switches have been closed, a communications link (66,68) is established therethrough between the remote processing means (42) and the axis controller (8) and wherein the axis controller generates a status signal packet for communication to the central controller containing
5 information relating to the selected electrical device (6).
16. A control system as claimed in any one of claims 3 to 15 wherein the matrix comprises a single matrix (28).
10 17. A control system as claimed in any one of claims 3 to 15 wherein the matrix comprises a dual-matrix (127J29;140J42).
18. A control system as claimed in claim 16 or 17 wherein each patch switch (30) comprises electronic switch means (32) and power switch means (34).
15
19. A control system as claimed in claim 18 wherein the electronic switch means and the power switch means can be independently operated whereby the central controller (2) can monitor said devices (6) without changing the states of said power switch means.
20 20. A control system as claimed in claim 18 or 19 wherein the power switch means includes power contacts (46) for controlling power to said devices (6) and control contacts (87,89) for generating control signals (PGRP_FREE, QGRP_FREE, PBUS_FREE, QBUS_FREE) indicative of whether a patch switch (30) has been engaged or is in a control patch bus (24) which has been engaged.
25
21. A control system as claimed in any one of claims 3 to 15 as appended directly or indirectly to claim 5 wherein the LAN (3) is coupled to said remote processing means (42).
22. A control system as claimed in any one of claims 3 to 15 as appended directly or 30 indirectly to claim 5 wherein the LAN is coupled to at least some of said patch switches.
TUTE SHEET (Rule 26)
23. A control system as claimed in claim 21 or 22 wherein a control bus (135) is coupled between at least some of said patch switches (30) and said remote processing means (42).
24. A control system for controlling a plurality of electrical devices (6) said system including a central controller (2) for controlling functions of said devices, a network (4) coupled between the central controller (2) and said devices, said network including a plurality of device drivers (10) for providing drive signals to said electrical devices, the number of drivers being less than the number of devices characterised in that each of the devices (6) includes a satellite processor (42) which stores and provides signals indicative of the state of the device (6) to which it is coupled.
PCT/AU1996/000456 1995-07-18 1996-07-18 Control system for controlling plural electrical devices WO1997004512A1 (en)

Priority Applications (4)

Application Number Priority Date Filing Date Title
JP9506094A JPH11509387A (en) 1995-07-18 1996-07-18 Control system for controlling multiple electrical devices
AU64094/96A AU709762B2 (en) 1995-07-18 1996-07-18 Control system for controlling plural electrical devices
US08/983,386 US6297610B1 (en) 1995-07-18 1996-07-18 Control system for controlling plural electrical devices
EP96923782A EP0846359A4 (en) 1995-07-18 1996-07-18 Control system for controlling plural electrical devices

Applications Claiming Priority (2)

Application Number Priority Date Filing Date Title
AUPN4222 1995-07-18
AUPN4222A AUPN422295A0 (en) 1995-07-18 1995-07-18 Control system

Publications (1)

Publication Number Publication Date
WO1997004512A1 true WO1997004512A1 (en) 1997-02-06

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Country Status (6)

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US (1) US6297610B1 (en)
EP (1) EP0846359A4 (en)
JP (1) JPH11509387A (en)
AU (1) AUPN422295A0 (en)
PL (1) PL324523A1 (en)
WO (1) WO1997004512A1 (en)

Cited By (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
WO1998045764A1 (en) * 1997-04-07 1998-10-15 Euchner Gmbh & Co. Safety switch
US7024257B2 (en) 2001-02-09 2006-04-04 Motion Engineering, Inc. System for motion control, method of using the system for motion control, and computer-readable instructions for use with the system for motion control
CN109633305A (en) * 2018-12-12 2019-04-16 盐田国际集装箱码头有限公司 A kind of frequency converter failure processing method and frequency converter failure processing platform

Families Citing this family (58)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US7170241B1 (en) 1998-02-26 2007-01-30 Anorad Corporation Path module for a linear motor, modular linear motor system and method to control same
KR100371587B1 (en) * 2000-12-15 2003-02-11 한국과학기술연구원 A Flexible/Compact Motor Control Module Based on the CAN Communication Network
US6774600B2 (en) * 2001-11-05 2004-08-10 Richard L. Weinbrenner Matrix connected driver for multiple two phase motors
DE10251763B3 (en) * 2002-11-07 2004-08-05 Daimlerchrysler Ag Device for controlling a plurality of electric motors
JP4891521B2 (en) * 2003-03-28 2012-03-07 三洋電機株式会社 Data input / output method, and storage device and host device capable of using the method
US7145300B2 (en) * 2003-05-05 2006-12-05 International Rectifier Corporation Multi-axis AC servo control system and method
DE10341717A1 (en) * 2003-09-10 2005-05-25 Applied Films Gmbh & Co. Kg Arrangement for n consumers of electrical energy, from which m consumers are supplied with energy at the same time
US7180253B2 (en) * 2003-09-30 2007-02-20 Rockwell Automation Technologies, Inc. Method and system for generating multi-dimensional motion profiles
US7146242B2 (en) * 2003-09-30 2006-12-05 Rockwell Automation Technologies, Inc. Method and system for generating multi-dimensional motion profiles
KR100675891B1 (en) * 2005-05-04 2007-02-02 주식회사 하이닉스반도체 Apparatus and method of implanting ions partially
US20070191966A1 (en) * 2005-10-20 2007-08-16 Fisher Scott M Theatrical Objects Automated Motion Control System, Program Product, And Method
US8085009B2 (en) * 2007-08-13 2011-12-27 The Powerwise Group, Inc. IGBT/FET-based energy savings device for reducing a predetermined amount of voltage using pulse width modulation
US8619443B2 (en) 2010-09-29 2013-12-31 The Powerwise Group, Inc. System and method to boost voltage
US8085010B2 (en) * 2007-08-24 2011-12-27 The Powerwise Group, Inc. TRIAC/SCR-based energy savings device for reducing a predetermined amount of voltage using pulse width modulation
WO2009029162A1 (en) * 2007-08-24 2009-03-05 The Powerwise Group, Inc., A Delaware Corporation System and method for providing constant loading in ac power applications
US8120307B2 (en) * 2007-08-24 2012-02-21 The Powerwise Group, Inc. System and method for providing constant loading in AC power applications
US8810190B2 (en) 2007-09-14 2014-08-19 The Powerwise Group, Inc. Motor controller system and method for maximizing energy savings
US8698447B2 (en) 2007-09-14 2014-04-15 The Powerwise Group, Inc. Energy saving system and method for devices with rotating or reciprocating masses
NO20075383A (en) 2007-10-22 2008-10-13 In Motion As Adjustment of heavier machines
GB0801450D0 (en) * 2008-01-28 2008-03-05 Johnson Electric Sa Method and apparatus for controlling a plurality of motors
US20090261599A1 (en) * 2008-04-21 2009-10-22 Glacier Bay, Inc. Power generation system
US8080966B2 (en) * 2008-07-03 2011-12-20 Honeywell International Inc. Motor control architecture for simultaneously controlling multiple motors
US8004255B2 (en) 2008-08-07 2011-08-23 The Powerwise Group, Inc. Power supply for IGBT/FET drivers
US7920053B2 (en) * 2008-08-08 2011-04-05 Gentex Corporation Notification system and method thereof
US9032880B2 (en) 2009-01-23 2015-05-19 Magnemotion, Inc. Transport system powered by short block linear synchronous motors and switching mechanism
US8616134B2 (en) 2009-01-23 2013-12-31 Magnemotion, Inc. Transport system powered by short block linear synchronous motors
IL203642A (en) 2010-02-01 2014-01-30 Yesaiahu Redler Apparatus and method for optimizinmg current use during control of multiple motors and a projectile device containing the same
US8232884B2 (en) * 2009-04-24 2012-07-31 Gentex Corporation Carbon monoxide and smoke detectors having distinct alarm indications and a test button that indicates improper operation
KR20100130383A (en) * 2009-06-03 2010-12-13 삼성전자주식회사 Image forming apparatus and method for controlling motor thereof
US8483864B2 (en) * 2009-06-20 2013-07-09 Production Resource Group Llc Stage effects console for stage controlling system
US8836532B2 (en) * 2009-07-16 2014-09-16 Gentex Corporation Notification appliance and method thereof
BR112012005097A2 (en) 2009-09-08 2016-05-03 Powerwise Group Inc energy saving system and method for alternating or rotating mass devices
US8698446B2 (en) 2009-09-08 2014-04-15 The Powerwise Group, Inc. Method to save energy for devices with rotating or reciprocating masses
US8710704B2 (en) * 2010-05-03 2014-04-29 Electronic Theatre Controls, Inc. Performance venue with dynamic mechanical load management system and method
US8569987B2 (en) * 2010-09-21 2013-10-29 Rockwell Automation Technologies, Inc. Configurable multi-axis electric drive system concept
US8896989B2 (en) 2011-01-12 2014-11-25 Tait Towers Manufacturing, LLC System for providing power and control signals to devices
US9071169B2 (en) * 2011-02-18 2015-06-30 Ge Hybrid Technologies, Llc Programmable gate controller system and method
KR101137722B1 (en) * 2011-03-29 2012-04-24 한국생산기술연구원 Three dimensional wire flying system
CN103891114B (en) 2011-10-27 2018-01-02 不列颠哥伦比亚大学 Gearshift and its manufacture, use and control method
US8905380B2 (en) 2011-11-08 2014-12-09 Tait Towers Manufacturing, LLC Chain drive control system
US8909379B2 (en) 2012-03-07 2014-12-09 Tait Towers Manufacturing, LLC Winch control system
US8768492B2 (en) 2012-05-21 2014-07-01 Tait Towers Manufacturing Llc Automation and motion control system
US9211741B2 (en) * 2012-07-17 2015-12-15 Hewlett-Packard Development Company, L.P. Position encoder systems
JP6373992B2 (en) 2013-08-06 2018-08-15 ザ・ユニバーシティ・オブ・ブリティッシュ・コロンビア Displacement device and method and apparatus for detecting and estimating motion associated therewith
JP6633516B2 (en) 2013-09-21 2020-01-22 マグネモーション インコーポレイテッド Linear motor transport for packaging and other applications
CA2889410C (en) 2014-04-25 2022-08-30 Harnischfeger Technologies, Inc. Controlling crowd runaway of an industrial machine
US9429926B2 (en) 2014-05-16 2016-08-30 Tait Towers Manufacturing, LLC Automation and motion control system
EP3152822B1 (en) 2014-06-07 2019-08-07 The University Of British Columbia Methods and systems for controllably moving multiple moveable stages in a displacement device
CN105148544B (en) * 2014-06-13 2018-01-23 阮小青 Solar energy light infrared remote control sound senses three-phase micro machine stage curtain drawing machine
WO2015199933A1 (en) * 2014-06-28 2015-12-30 Intel Corporation Sensor bus interface for electronic devices
US10207905B2 (en) 2015-02-05 2019-02-19 Schlumberger Technology Corporation Control system for winch and capstan
EP3320606B1 (en) * 2015-07-06 2023-06-07 The University Of British Columbia Method and system for controllably moving one or more moveable stages in a displacement device
AU2017254937B2 (en) 2016-11-09 2023-08-10 Joy Global Surface Mining Inc Systems and methods of preventing a run-away state in an industrial machine
KR101707565B1 (en) * 2016-11-28 2017-02-16 (주)하온아텍 Interlock system of the stage dedicated, the interlock system using of control methods
US10754320B2 (en) * 2017-11-14 2020-08-25 Rockwell Automation Technologies, Inc. Method and apparatus for integrating an external motion planner with an industrial controller
US11233469B2 (en) * 2019-04-19 2022-01-25 Eaton Intelligent Power Limited Variable frequency drive motor connection module
US11537705B2 (en) * 2020-10-27 2022-12-27 Dell Products L.P. Device access control system
CN117148137B (en) * 2023-10-31 2024-01-19 广东正超电气有限公司 Automatic running-in testing device of permanent magnet circuit breaker of switch cabinet

Citations (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3894244A (en) * 1973-10-03 1975-07-08 Ross K Hill Power limit and control system
GB2071438A (en) * 1980-03-11 1981-09-16 Fiat Ricerche Electric power distribution system
DE3103708A1 (en) * 1981-02-04 1982-08-12 Bayerische Bühnenbau GmbH, 8480 Weiden Apparatus for operating theatre pull mechanisms of a theatre stage
EP0415441A2 (en) * 1989-08-31 1991-03-06 Mita Industrial Co. Ltd. A power supply control subsystem for an image forming apparatus

Family Cites Families (37)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3755686A (en) * 1972-05-31 1973-08-28 Nasa Powerplexer
US4047003A (en) * 1975-04-22 1977-09-06 Continental Can Company, Inc. Communication control system
DE2630993C3 (en) * 1976-07-09 1979-12-06 Siemens Ag, 1000 Berlin Und 8000 Muenchen Switching matrix with connection modules
US4257103A (en) * 1977-11-16 1981-03-17 Heian Iron Works, Ltd. Apparatus for controlling position of a plurality of machining shafts each including a machine tool fitted thereto
US4195236A (en) * 1978-03-23 1980-03-25 Vsesojuzny Nauchno-Issledovatelsky Institut Vagonostroenia Device for discrete control of thyristor-pulse converters
US4371921A (en) * 1978-07-10 1983-02-01 Northrop Corporation Inertial instrument with a temporally digitized rebalance network
US4422027A (en) * 1981-03-16 1983-12-20 The United States Of America As Represented By The Secretary Of The Army Linear motor controller
DE3360779D1 (en) * 1982-06-30 1985-10-17 Bbc Brown Boveri & Cie INSTALLATION DE COMMUTATION
DE3233468A1 (en) * 1982-09-09 1984-03-15 Trepel Ag, 6200 Wiesbaden Control system for the loft machinery of stages
JPS5989592A (en) * 1982-11-13 1984-05-23 Fanuc Ltd Switching control system for plural motors
JPS60113694A (en) * 1983-11-25 1985-06-20 Sumitomo Heavy Ind Ltd Drive device of servo motor and its drive controller
US5769527A (en) * 1986-07-17 1998-06-23 Vari-Lite, Inc. Computer controlled lighting system with distributed control resources
US4827195A (en) * 1988-01-13 1989-05-02 Micro Research, Inc. Motor control system for directing multiple devices
US4962687A (en) * 1988-09-06 1990-10-16 Belliveau Richard S Variable color lighting system
US4908822A (en) * 1988-12-07 1990-03-13 Chrysler Motors Corporation Electrical devices command system, single wire bus and smart dual controller arrangement therefor
US4931712A (en) * 1988-12-28 1990-06-05 Pitney Bowes Inc. Multiple channel servo configuration
JPH02220103A (en) * 1989-02-22 1990-09-03 Fanuc Ltd Spindle control command system
US5621650A (en) * 1989-10-30 1997-04-15 Advanced Micro Devices, Inc. Programmable logic device with internal time-constant multiplexing of signals from external interconnect buses
DE4011598A1 (en) * 1990-04-10 1991-10-17 Rieter Ag Maschf TEXTILE MACHINE, PARTICULAR RING SPINNING MACHINE
DE59008369D1 (en) * 1990-05-22 1995-03-09 Siemens Ag Control for a machine tool or a robot.
FR2664544B1 (en) * 1990-07-12 1993-12-17 Faure Automobile Bertrand CENTRALIZED CONTROL BLOCK FOR VEHICLE SEAT.
WO1992009176A1 (en) * 1990-11-15 1992-05-29 Nvision, Inc. Switch composed of identical switch modules
US5222017A (en) * 1990-11-23 1993-06-22 The University Of British Columbia Control system to synchronize slave computers
US5198809A (en) * 1991-02-22 1993-03-30 James L. Day Co. Inc. Hard wired programmable controller especially for heating ventilating and air conditioning (HVAC systems)
JPH04290102A (en) * 1991-03-19 1992-10-14 Mitsubishi Electric Corp Device for information transmission to servomechanism
LU88009A1 (en) * 1991-09-27 1992-06-01 Jean Marie Schiltz METHOD FOR MOVING, WITH AT LEAST THREE DEGREES OF FREEDOM, IN PARTICULAR IN THE THEATER AREA, MADE BY THREE-DIMENSIONAL
US5237250A (en) * 1991-11-01 1993-08-17 Zeile Kim A Multiplexed stepper motor control apparatus
US5274311A (en) * 1991-11-13 1993-12-28 Quest Technologies, Inc. Control system network structure
US5347270A (en) * 1991-12-27 1994-09-13 Mitsubishi Denki Kabushiki Kaisha Method of testing switches and switching circuit
US5371495A (en) * 1992-01-24 1994-12-06 Intel Corporation Deterministic routing method for minimal switch circuits
US5502627A (en) * 1992-09-25 1996-03-26 Light & Sound Design Limited Stage lighting lamp unit and stage lighting system including such unit
US5574343A (en) * 1992-12-02 1996-11-12 Vdo Adolf Schindling Ag Control of activators in motor vehicle doors
US5491831A (en) * 1993-05-10 1996-02-13 Motorola Cellular motor control network
JPH06350294A (en) * 1993-06-03 1994-12-22 Matsushita Electric Ind Co Ltd Rail width adjuster for automatic electronic parts mounter
US5406176A (en) * 1994-01-12 1995-04-11 Aurora Robotics Limited Computer controlled stage lighting system
US5619111A (en) * 1995-01-20 1997-04-08 Kabushiki Kaisha Sankyo Seiki Seisakusho Motor control system for controlling the operations of a plurality of servo motors
US6031709A (en) * 1998-07-17 2000-02-29 Hewlett-Packard Co Switching multiplexor arrangement of relays for balancing thermal offset

Patent Citations (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3894244A (en) * 1973-10-03 1975-07-08 Ross K Hill Power limit and control system
GB2071438A (en) * 1980-03-11 1981-09-16 Fiat Ricerche Electric power distribution system
DE3103708A1 (en) * 1981-02-04 1982-08-12 Bayerische Bühnenbau GmbH, 8480 Weiden Apparatus for operating theatre pull mechanisms of a theatre stage
EP0415441A2 (en) * 1989-08-31 1991-03-06 Mita Industrial Co. Ltd. A power supply control subsystem for an image forming apparatus

Non-Patent Citations (1)

* Cited by examiner, † Cited by third party
Title
See also references of EP0846359A4 *

Cited By (6)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
WO1998045764A1 (en) * 1997-04-07 1998-10-15 Euchner Gmbh & Co. Safety switch
US7024257B2 (en) 2001-02-09 2006-04-04 Motion Engineering, Inc. System for motion control, method of using the system for motion control, and computer-readable instructions for use with the system for motion control
US7143301B2 (en) 2001-02-09 2006-11-28 Motion Engineering, Inc. System for motion control, method of using the system for motion control, and computer readable instructions for use with the system for motion control
US7406354B2 (en) 2001-02-09 2008-07-29 Motion Engineering, Inc. System for motion control, method of using the system for motion control, and computer readable instructions for use with the system for motion control
US7460471B2 (en) 2001-02-09 2008-12-02 Motion Engineering, Inc. System for motion control, method of using the system for motion control, and computer readable instructions for use with the system for motion control
CN109633305A (en) * 2018-12-12 2019-04-16 盐田国际集装箱码头有限公司 A kind of frequency converter failure processing method and frequency converter failure processing platform

Also Published As

Publication number Publication date
EP0846359A1 (en) 1998-06-10
EP0846359A4 (en) 1999-04-21
PL324523A1 (en) 1998-06-08
US6297610B1 (en) 2001-10-02
JPH11509387A (en) 1999-08-17
AUPN422295A0 (en) 1995-08-10

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