CN107608307A - A kind of Programmable logical controller subsystem - Google Patents

Abstract

The present invention provides a kind of Programmable logical controller subsystem, it includes the first modular converter, the second modular converter and M universal logic module, each universal logic module is connected by the first CAN with the first modular converter, and each universal logic module is connected by the second CAN with the second modular converter, wherein, M is natural number.Compared with prior art, Programmable logical controller subsystem in the present invention is communicated by CAN and modular converter, because CAN communication is faster than the speed of other bus forms transmission data, after data turn NET modules by CAN, computer operation can quickly be sent data to and carry out Centralized Monitoring, there is good interactivity；Communicated using dual CAN bus, the redundancy of data can be accomplished.

Description

A kind of Programmable logical controller subsystem

【Technical field】

The present invention relates to Programmable logical controller technical field, more particularly to a kind of Programmable logical controller subsystem.

【Background technology】

Programmable logic controller (PLC) (Programmable Logic Controller) is kind exclusively in industrial settings Using and design digital operation electronic system.It uses a kind of programmable memory, performs and patrols in its storage inside The instruction of the operations such as computing, sequential control, timing, counting and arithmetical operation is collected, passes through digital or analog input and output To control various types of plant equipment or production process.

Existing universal logic module is free of Switching Power Supply, and the low progress of insulation that can not be to external power supply is effectively former Phragma from；The low chip module that can damage in-line power of exterior insulation.Existing universal logic module individual module is adopted Collection point is few, and the capacity of single substation is small, and cost it is expensive/extension is difficult；The modular converter of prior art can not handle mass data, Expansible receiving module is caused to have quantity limitation.Existing universal logic module is using 485 communications or other buses Formula control (length is less than 1 kilometer), transmission rate is low, can not carry out the quick processing and transmission of big data.It is existing programmable Logic control module is communicated using monobus, the redundancy of no data.The external structure of existing universal logic module is not Facilitate very much the fixation of universal logic module.

Therefore, it is necessary to a kind of improved technical scheme is provided to overcome one or more of above mentioned problem.

【The content of the invention】

It is an object of the invention to provide a kind of Programmable logical controller subsystem, its message transmission rate are high, expansible Universal logic module quantity it is big, and the redundancy of data can be accomplished.

In order to solve the above problems, according to an aspect of the present invention, the present invention provides a kind of Programmable logical controller System, it includes the first modular converter, the second modular converter and M universal logic module.Each FPGA control Molding block is connected by the first CAN with the first modular converter, and each universal logic module is total by the 2nd CAN Line is connected with the second modular converter, wherein, M is natural number, and each universal logic module receives multiple current/voltage letters Number, and multiple current/voltage signals to receiving are handled, to produce simultaneously outputting data signals；The data-signal leads to Cross the first CAN and be transferred to first modular converter, the data-signal that first modular converter is received is by CAN Form is converted to NET forms；The data-signal is transferred to second modular converter by the second CAN, and described second The data-signal that modular converter is received is converted to NET forms by CAN forms.

Further, the universal logic module includes communication module, microprocessor and input/output module, The input/output module includes N number of voltage/current signals interface, and it is used to receiving or sending voltage/current signals, the N For natural number；The communication module includes the first CAN communication module and the second CAN communication module, and the microprocessor and input/ Output module, the first CAN communication module are connected with the second CAN communication module, and the input/output module is received outer Portion's current/voltage signal is supplied to the microprocessor, and foreign current/voltage signal that the microprocessor receives to it enters The data-signal is respectively supplied to the first CAN communication module and the second CAN communication mould by row processing to form data-signal Block, the data-signal that the first CAN communication module is received is converted into the data-signal of CAN forms, then passes through first CAN is transferred to the first modular converter；The data-signal that the second CAN communication module is received is converted into CAN lattice The data-signal of formula, then the second modular converter is transferred to by the second CAN.

Further, the universal logic module also includes power module, and the power module includes switch electricity Source, the input of the Switching Power Supply are connected with external power supply, and its output end is to the device in the universal logic module Power supply, and insulation of the Switching Power Supply to external power supply is low isolates, M≤16, the N is equal to 12.

Further, the power module also includes the first variable-voltage power supply and the second variable-voltage power supply, and described first becomes piezoelectricity The input in source is connected with the output end of the Switching Power Supply, and the output end of first variable-voltage power supply is led to the first CAN The power end of news module is connected, and the voltage that first variable-voltage power supply is used to receive its input carries out transformation to be become Piezoelectricity pressure, and the transformation voltage is exported by its output end；The input of second variable-voltage power supply and the Switching Power Supply Output end is connected, and the output end of second variable-voltage power supply is connected with the power end of the second CAN communication module, and described second The voltage that variable-voltage power supply is used to receive its input carries out transformation, to obtain transformation voltage, and is exported by its output end The transformation voltage.

The further universal logic module includes buckle, is formed at the universal logic module back of the body The groove in face and the accepting groove on the outside of the groove, the accepting groove from the universal logic module back side one Side extends to the groove, and when the buckle is contained in the accepting groove, the foot of the buckle exposes to the groove It is interior, the universal logic module is fixed on the fixture of the groove.

Further, the accepting groove is included from the lateral groove side at the universal logic module back side The first collecting groove portion to extension, from the end of the described first collecting groove portion continue to extend up to the groove direction it is described recessed The second of groove houses groove portion, the block in the middle part of the accepting groove, wherein, formed with leading in the side wall of second accepting groove Approaching channel；The buckle include buckle body, positioned at the head on buckle body top, the foot positioned at buckle body bottom, be located at The shoulder of the head on both sides of buckle body and positioned at buckle body both sides and the guidance part between the shoulder and foot； The buckle body includes the cavity through the buckle body thickness direction, extends being formed from the buckle body and be located at Elastic clip and finger portion in the cavity；The buckle is contained in the accepting groove, and can conciliate card position fixing position Between move, when the buckle, which is in, fixes position, the shoulder of the buckle is contained in described first and housed in groove portion and institute The bottom for stating the shoulder of buckle is butted on the described second side wall top for housing groove portion；The guidance part is contained in described second and housed In the guide channel of groove portion；The opening of the elastic clip is held on the first side of the widest portion of the block, and the finger portion is remote The block；The foot of the buckle is exposed in the groove, so that the universal logic module is fixed on and is located at On the fixture 600 of the groove, when the buckle is in solution card position, the shoulders of the buckle exit described the Recess the described second side wall top for housing groove portion in the bottom of one collecting groove portion and the shoulder of the buckle；The elastic clip Opening is held on the second side of the widest portion of the block；The finger portion stops close to the block and by the block；Institute The foot for stating buckle is retracted into the second collecting groove portion, to cause the universal logic module to depart from positioned at described The fixture of groove.When the buckle is moved to by solution card position and fixes position, the opening of the elastic clip is by the gear Second side of the widest portion of block is moved to the first side of the widest portion of the block by the widest portion of the block.

Further, the elastic clip from the extension of the side on the head of the close buckle of the cavity of the buckle body and Into from the side of the foot of the close buckle of the cavity of the buckle body, extension forms in the finger portion；The block with it is described The adjacent one end in finger portion is formed with recess, and when the buckle, which is in, fixes position, the finger portion is partially housed in the gear The end in the recess of block and the finger portion and the bottom of the recess of the block maintain a certain distance；At the buckle When card position is solved, the end in the finger portion abuts against the bottom of the recess of the block.

Further, the described first width for housing groove portion is more than the described second collecting well width, the buckle body The thickness of shoulder is more than the thickness of the guide portion；It is located at the side of the groove on the back side of universal logic module, Formed with the accepting groove described in several, universal logic module also includes patrolling from the programmable of opposite side of the groove Several spaced cards that the back portion of control module is extended to above groove are collected, can by described in by the card Programmed logic control module is affiliated on the fixture of the groove, and the buckle also includes being formed at the buckle back side Conduit, the back side of the buckle are to be located at the cavity of the buckle body close to the end face of the collecting trench bottom, the conduit Between the foot of buckle, when the buckle inserts or detaches the accepting groove, the block passes through the conduit.

Compared with prior art, the Programmable logical controller subsystem in the present invention by CAN and modular converter (i.e. CAN turns NET modules) communication, because CAN communication is faster than the speed of other bus forms transmission data, data are turned by CAN After NET modules, it can quickly send data to computer operation and carry out Centralized Monitoring, there is good interactivity；Using double CAN Bus communication, the redundancy of data can be accomplished.

【Brief description of the drawings】

In order to illustrate the technical solution of the embodiments of the present invention more clearly, required use in being described below to embodiment Accompanying drawing be briefly described, it should be apparent that, drawings in the following description are only some embodiments of the present invention, for this For the those of ordinary skill of field, without having to pay creative labor, it can also be obtained according to these accompanying drawings other Accompanying drawing.Wherein：

Fig. 1 is the structural representation of the programmable logic control system of the present invention in one embodiment；

Fig. 2 is the circuit diagram of a universal logic module in one embodiment in Fig. 1；

Fig. 3 is the top view of universal logic module in one embodiment shown in Fig. 2；

Fig. 4 is the recognition methods of the failure universal logic module in the programmable logic control system shown in Fig. 1 Schematic flow sheet；

Fig. 5 is the explosive view of the backside structure of the universal logic module of the present invention in one embodiment；

Fig. 6 is that the universal logic module shown in Fig. 5 is in structural representation when fixing position in buckle；

Fig. 7 is structural representation of the universal logic module when buckle is in solution card position shown in Fig. 5；

Fig. 8 is the structural representation of the back side of the buckle shown in Fig. 1 in one embodiment；

Fig. 9 is the structure schematic diagram that multiple universal logic modules are provided with a fixture；

Figure 10 is the structural representation of the Programmable logical controller frame of the present invention in one embodiment.

【Embodiment】

In order to facilitate the understanding of the purposes, features and advantages of the present invention, it is below in conjunction with the accompanying drawings and specific real Applying mode, the present invention is further detailed explanation.

" one embodiment " or " embodiment " referred to herein refers to may be included at least one implementation of the present invention Special characteristic, structure or characteristic." in one embodiment " that different places occur in this manual not refers both to same Individual embodiment, nor the single or selective embodiment mutually exclusive with other embodiment.Unless stated otherwise, herein In connect, be connected, connecting expression be electrically connected with word represent directly or indirectly to be electrical connected.

(1) using the programmable logic control system and Programmable logical controller subsystem of dual CAN bus communication

It refer to shown in Fig. 1, the structural representation of its programmable logic control system for the present invention in one embodiment Figure.Programmable logic control system shown in Fig. 1 includes first work station 110 (being abbreviated as 1# work stations), second work station 120 (being abbreviated as 2# work stations) and multiple Programmable logical controller subsystems (not marking).

Each Programmable logical controller subsystem include the first modular converter 122 (i.e. CAN turns NET modules 122), second turn Change the mold block 124 (i.e. CAN turns NET modules 124) and M universal logic module 130, M is natural number, and M≤16.First The modular converter 124 of modular converter 122 and second is that CAN (Controller Area Network, controller local area network) turns NET (Ethernet, Ethernet) module.Any one Programmable logical controller mould in each Programmable logical controller subsystem Block 130 turns NET modules 122 with CAN by the first CAN (CNABUS1) and is connected, and CAN turns NET modules 122 and passes through Ethernet It is connected through the first interchanger 142 with first work station 110；Any one universal logic module 130 is total by the 2nd CAN Line (CNABUS2) turns NET modules 124 with CAN and is connected, and CAN turns NET modules 124 by Ethernet through second switch 144 and Two work stations 120 are connected.

Each universal logic module 130 receives multiple current/voltage signals, and multiple electric currents to receiving/ Voltage signal is handled, to produce simultaneously outputting data signals.The data-signal is transferred to CAN by the first CAN and turned NET modules 122, CAN turn the data-signal that NET modules 122 are received and are converted to NET forms, NET forms by CAN forms Data-signal first work station 110 is transferred to by Ethernet again；The data-signal is transferred to by the second CAN CAN turns NET modules 124, and the CAN turns the data-signal that NET modules 124 are received and is converted to NET lattice by CAN forms Formula, the data-signal of NET forms are transferred to second work station 120 by Ethernet again.

In the present invention, universal logic module 130 by CAN (the first CAN, the second CAN) with Modular converter (CAN turns NET modules 122, CAN turns NET modules 124) communicates, because CAN communication is than other bus forms biography The speed of transmission of data is fast, after data turn NET modules 122,124 by CAN, can quickly send data to computer operation progress Centralized Monitoring (modular converter connects interchanger by Ethernet), has good interactivity；Communicated, done using dual CAN bus To the redundancy of data, dual CAN bus communication can turn NET modules by different CAN respectively and enter the first computer operation respectively Stand 110 and second computer work station 120, so redundancy monitoring, the first computer workstation can be carried out to access point respectively 110 and second computer work station 120 can also do effective redundancy, realize safest monitoring.

The present invention uses modularized design circuit, and single universal logic module 130 (is specifically seen below to figure 2 description) 12 curtage signals can be received, using the microprocessor of itself of universal logic module 130 by number It is transmitted according to by dual CAN bus (i.e. the CAN of redundancy), while a substation (subsystem) can accommodate 16 pieces so Universal logic module 130, such a substation can have the access of 192 points, and this 192 points turn NET moulds by CAN Block 122,124 change after to computer workstation Centralized Monitoring, turning NET modules by extending n CAN can have individual 192 points of n defeated Enter, system can reception capacity can be gone down by this extended mode infinite expanding, n here can be the natural number more than 2.

(2) internal structure of universal logic module

It refer to shown in Fig. 2, its circuit for a universal logic module in Fig. 1 in one embodiment shows It is intended to.Universal logic module shown in Fig. 2 includes input/output module 210, communication module (not marking) and microprocessor Device (CPU, also referred to as central processing unit).

The input/output module 210 includes N number of current/voltage signaling interface IN, its be used to receive or send electric current/ Voltage signal, the N is natural number, and in the specific embodiment shown in Fig. 2, the input/output module 210 includes 12 electricity Stream/voltage signal interface IN, and it is 4~20mA or, 0~10V that it, which receives the scope of current/voltage signal,.The communication module Including the first CAN communication module 222, the second CAN communication module 224, the microprocessor and input/output module 210, first CAN communication module 222 is connected with the second CAN communication module 224.

Foreign current/voltage signal that the input/output module 210 is received is supplied to the microprocessor, Foreign current/voltage signal that the microprocessor receives to it is handled to form data-signal, and by the data Signal is respectively supplied to the first CAN communication module 222 and the second CAN communication module 224.The first CAN communication module 222 will Its data-signal received is converted into the data-signal of CAN forms, then the number of the CAN forms is transmitted by the first CAN It is believed that number giving the first modular converter 122；The data-signal that the second CAN communication module 224 is received is converted into CAN lattice The data-signal of formula, then the data-signal of the CAN forms is transmitted to the second modular converter 124 by the second CAN.So, Universal logic module can shown in Fig. 2 is realized double between the first modular converter 122 and the second modular converter 124 CAN communicates.

In the specific embodiment shown in Fig. 2, the first CAN communication module 222 includes the first communication input interface 1# The communication output interface 1#CAN OUT of CAN IN and first, and the first communication input interface 1#CAN IN and the second communication output connect Mouth 1#CAN OUT are connected by the first CAN with the first modular converter 122；The second CAN communication module 224 includes the Two communication input interface 2#CAN IN and the second communication output interface 2#CAN OUT, and the second communication input interface 2#CAN IN It is connected with the second communication output interface 2#CAN OUT by the first CAN with the second modular converter 124.

Please continue to refer to shown in Fig. 2, the universal logic module shown in Fig. 2 (is not marked also including the power module Note), the power module includes Switching Power Supply 232, and the input of the Switching Power Supply 232 is connected with external power supply, and it is exported Hold to the device power supply in the universal logic module, and the low progress of insulation of the Switching Power Supply 232 to external power supply Isolation, so as to carry out transformation with a Switching Power Supply to reach the low effective Fault Isolation of progress of insulation to external power supply.One In individual embodiment, by the turn-on and turn-off of controlling switch pipe, the voltage received to its input enters the Switching Power Supply 232 Row transformation, to export stable output voltage by its output end.

Please continue to refer to shown in Fig. 2, the power module in the universal logic module shown in Fig. 2 also includes the One variable-voltage power supply 234 and the second variable-voltage power supply 236.

The input of first variable-voltage power supply 234 is connected with the output end of the Switching Power Supply 232, first transformation The output end of power supply 234 is connected with the power end of the first CAN communication module 222, first variable-voltage power supply 234 be used for pair The voltage that its input receives carries out transformation, to obtain transformation voltage, and exports the transformation voltage by its output end.It is described The input of second variable-voltage power supply 236 is connected with the output end of the Switching Power Supply 232, second variable-voltage power supply 236 it is defeated Go out end with the power end of the second CAN communication module 224 to be connected, second variable-voltage power supply 236 is used to input it termination The voltage received carries out transformation, to obtain transformation voltage, and exports the transformation voltage by its output end.

Wherein, Switching Power Supply 232, the first variable-voltage power supply 234 and the second variable-voltage power supply 236 can use existing power supply electricity Road and the technology of transforming circuit, therefore will not be repeated here.

In a specific embodiment, the external power supply is 24V dc source；The Switching Power Supply 232 is 24V Turn 3V Switching Power Supply；The variable-voltage power supply 236 of first variable-voltage power supply 234 and second is the variable-voltage power supply that 3V turns 5V.

(3) indicating lamp structure of universal logic module

It refer to shown in Fig. 2, which show the internal structure of the indicator lamp of the universal logic module in the present invention, Refer to shown in Fig. 3, it is the top view of universal logic module in one embodiment shown in Fig. 2, which show The external structure of the indicator lamp of universal logic module.

With reference to shown in Fig. 2 and Fig. 3, the indicator lamp of the universal logic module in the present invention includes the first light-emitting diodes Pipe D1, the second light emitting diode D2, the 3rd light emitting diode D3, the 4th light emitting diode D4 and the 5th light emitting diode D5, with And 2N light emitting diode corresponding with N number of current/voltage signaling interface of the input/output module 210.

Wherein, the first CAN communication module 222 and the first light emitting diode D1 (Tx represents hair data) and second are luminous Diode D2 (Rx represents to receive data) is connected, and the first light emitting diode D1 is used to show that the first CAN communication module 222 is sent out Send data whether faulty；Second light emitting diode D2 is used to show that the first CAN communication module 222 receives whether data have Failure.Similarly, the second CAN communication module 224 and the 3rd light emitting diode D3 (Tx) and the 4th light emitting diode D4 (Rx) It is connected, the 3rd light emitting diode D3 is used to show whether the second CAN communication module 224 sends data faulty；4th hair Optical diode D4 is used to show whether the second CAN communication module 224 receives data faulty.In one embodiment, institute The first light emitting diode D1 to the 4th light emitting diode D4 is stated by whether flashing to show that corresponding CAN communication module receives number According to or receive data it is whether faulty, such as, when the first light emitting diode D1 flash, expression the first CAN communication module 222 have Data are sent, and when the first light emitting diode D1 does not flash, it is faulty to represent that the first CAN communication module 222 sends data；When When two light emitting diode D2 flash, represent that the first CAN communication module 222 has data receiver, when the second light emitting diode D2 does not dodge When bright, it is faulty to represent that the first CAN communication module 222 receives data.

The microprocessor is connected with the 5th light emitting diode D5, and the 5th light emitting diode D5 is used to show microprocessor Device whether normal work.In one embodiment, the 5th light emitting diode D5 passes through bright or go out to show that microprocessor is No normal work, such as, when the microprocessor normal work, the 5th light emitting diode D5 Chang Liang, when the microprocessor During failure, the 5th light emitting diode D5 often goes out；For another example, when the microprocessor normal work, the 5th light-emitting diodes Pipe D5 often goes out, when the microprocessor breaks down, the 5th light emitting diode D5 Chang Liang.

Each current/voltage signaling interface of the input/output module 210 passes through two light emitting diodes and microprocessor Device is connected, and described two light emitting diodes are respectively used to show the transmission signal and reception signal of the current/voltage signaling interface It is whether normal.For example the interface of a current/voltage signal in the left side of the input/output module 210 includes the He of pin 1 2, wherein pin 2 passes sequentially through light emitting diode D6, resistance R1 and optocoupler 1 and is connected with microprocessor；The input/output module The interface of one current/voltage signal on 210 right side includes pin 1 and 2, wherein pin 2 pass sequentially through light emitting diode D7, Resistance R2 and optocoupler 2 are connected with microprocessor.

(4) in programmable logic control system failure universal logic module recognition methods

It refer to shown in Fig. 4, it is the failure Programmable logical controller mould in the programmable logic control system shown in Fig. 1 The schematic flow sheet of the recognition methods of block.Below in conjunction with Fig. 1, the failure universal logic module shown in Fig. 4 is specifically introduced Recognition methods.

Step 410, modular converter 122,124 gives its corresponding universal logic module with predetermined period of time 130 send random heartbeat signal；

Step 420, the corresponding universal logic module 130 receives the modular converter 122,124 and sent Heartbeat signal after, send the data-signal of specified format includes address to the modular converter 122,124, the data-signal The heartbeat signal that signal, current/voltage signal and the corresponding universal logic module 130 receive, wherein, it is described The external signal that current/voltage signal receives for the corresponding universal logic module；The address signal is institute The signal (similar gateway 1-255) that microprocessor in universal logic module corresponding to stating obtains after self detecting. In one specific embodiment, the universal logic module 130 changes the current/voltage signal of the outside received The data signal that can recognize that into computer, then again by the data signal, address signal and corresponding Programmable logical controller mould The heartbeat signal that block 130 receives is integrated into the data-signal of specified format, then again by CAN bus transfer to corresponding The modular converter 122,124.

Step 430, the modular converter 122,124 receives the number that corresponding universal logic module 130 is sent It is believed that number after, whether the heartbeat signal detected in the data-signal received correct.

Step 440, if the modular converter 122,124 detects the heartbeat signal disappearance or wrong returned with data-signal By mistake, then universal logic module 130 corresponding to judging there may be failure.

To sum up shown, the recognition methods of the failure universal logic module in the present invention can be to FPGA control Universal logic module in system processed is monitored, and can be quickly found out out of order universal logic module.

(5) external structure of universal logic module

In order to facilitate the fixation of universal logic module, external structure of the present invention to universal logic module Improved.

It refer to shown in Fig. 5, the backside structure of its universal logic module for the present invention in one embodiment Explosive view；It refer to shown in Fig. 6, it is in when fixing position for the universal logic module shown in Fig. 5 in buckle Structural representation；It refer to shown in Fig. 7, it is the universal logic module shown in Fig. 5 when buckle is in solution card position Structural representation.

Universal logic module 500 shown in Fig. 5-7 includes buckle 520, is formed at the Programmable logical controller The groove 510 at the back side of module 500 and the accepting groove 530 positioned at the outside of groove 510, the accepting groove 530 can be compiled described in The side at the journey Logic control module back side extends to the groove 510.When the buckle 520 is contained in the accepting groove 530 When, the foot 521 of the buckle 520 is exposed in the groove 510, and the universal logic module 500 is fixed In on the fixture 600 at the groove 510.

In specific embodiment shown in Fig. 5-7, the accepting groove 530 is included from the universal logic module 500 The first of the one lateral direction of groove 510 extension at the back side houses groove portion 532, from the described first end for housing groove portion 532 Continue to extend up to the second collecting groove portion 534 of the groove 510, in the accepting groove 530 to the direction of groove 510 The block 536 in portion, wherein, second accepting groove, formed with guide channel 5342 in 534 side wall；The buckle 520 includes card Detain body 525, positioned at the head 522 on the top of buckle body 525, the foot 521 positioned at the bottom of buckle body 525, positioned at buckle The shoulder 523 of the both sides of head 522 of body 525 and positioned at the both sides of buckle body 525 and it is located at the shoulder 523 and foot Guidance part 524 between 521；The buckle body 525 include through the thickness direction of buckle body 525 cavity 5252, Being formed from the buckle body 525 extension and the elastic clip 5256 in the cavity 5252 and finger portion 5254；The card Button 520 can be contained in the accepting groove 530, and is moved between can conciliating card position fixing position.

(Fig. 6 is specifically referred to when the buckle 520, which is in, fixes position), and the shoulder 523 of the buckle 520 is contained in In the first collecting groove portion 532 and bottom of the shoulder 523 of the buckle 520 is butted on the described second side for housing groove portion 534 Wall top；The guidance part 524 is contained in the described second guide channel 5342 for housing groove portion 534；The elastic clip 5256 Opening is held on the first side of the widest portion of the block 536, and the finger portion 5254 is away from the block 536；The buckle 520 foot 521 is exposed in the groove 510, so that the universal logic module 500 is fixed on positioned at described recessed On fixture 600 at groove 510.

(Fig. 7 is specifically referred to when the buckle 520 is in solution card position), and the shoulders 523 of the buckle 520 move back Recess the described second side for housing groove portion 534 in the bottom for going out the first collecting groove portion 532 and the shoulder 523 of the buckle 520 Wall top；The opening of the elastic clip 5256 is held on the second side of the widest portion of the block；The finger portion 5254 is close The block 536 is simultaneously stopped by the block 536；The foot of the buckle 520 is retracted into described second and housed in groove portion 534, with So that the universal logic module 500 departs from the fixture 600 at the groove 510.In the buckle 520 Be moved to by solution card position when fixing position, the opening of the elastic clip 5256 by the block 536 widest portion second Side is moved to the first side of the widest portion of the block 536 by the widest portion of the block 536.

In the specific embodiment shown in Fig. 5-7, the elastic clip 5256 is from the cavity 5252 of the buckle body 525 Close to the side on the head 522 of buckle 520, extension forms, and the finger portion 5254 is from the cavity 5252 of the buckle body 525 Side extension close to the foot 521 of buckle 520 forms；The block 536 one end adjacent with the finger portion 5254 formed with Recess 5362, when the buckle 520, which is in, fixes position, the finger portion 5254 is partially housed in the recessed of the block 536 In the mouth 5362 and end in the finger portions 5254 and the bottom of the recess 5362 of the block 536 maintain a certain distance；When When the buckle 520 is in solution card position, the end in the finger portion 5254 abuts against the bottom of the recess 5362 of the block 536 Portion.

In the specific embodiment shown in Fig. 5-7, the width of the first collecting groove portion 532 is more than second accepting groove The width of portion 534, the thickness of the shoulder 523 of the buckle body 525 are more than the thickness of the guide portion 524；FPGA control It is located at the side of the groove 510 on the back side of molding block 500, formed with the accepting groove 530 described in several, FPGA The back portion that control module 500 also includes the universal logic module 500 of the opposite side from the groove 510 extends to Several spaced cards 540 of the top of groove 510, can be first by the Programmable logical controller by the card 540 Module 500 is affiliated on the fixture 600 at the groove 510, then again by buckle 520 by the Programmable logical controller Module 500 is fixed on the fixture 600 at the groove 510.

The head 522 of the buckle body 525 can use as push-and-pull portion, pass through the head of buckle body 525 described in push-and-pull Portion 522 is so that the buckle 520 moves between conciliating card position in the fixing position of the accepting groove 530.The buckle body 525 head 522 is formed through the through hole 5222 of the thickness direction of head 522, can be auxiliary in the interior insertion of through hole 5222 at this Assistant engineer has, to drive the buckle 520 to be moved between conciliating card position in the fixing position of the accepting groove 530.

It refer to shown in Fig. 8, it is the structural representation of the back side of the buckle shown in Fig. 1 in one embodiment, shown Buckle 520 also include being formed at the conduit 550 at the back side of buckle 520, the back side of the buckle 520 is close to the collecting The end face of the bottom of groove 530, the conduit 550 be located at the buckle body 525 cavity 5252 and buckle 520 foot 521 it Between, when the buckle 520 inserts or detaches the accepting groove 530, the block 536 passes through the conduit 550.

It refer to shown in Figure 10, the structural representation of its Programmable logical controller frame for the present invention in one embodiment Figure.Programmable logical controller frame shown in Figure 10 include installing plate 700, multiple fixtures 600 and it is multiple as illustrated in figs. 5-7 can Programmed logic control module 500.

Wherein, multiple fixtures 600 are sequentially fixed on the end face of the installing plate 700, wherein on each fixture 600 Multiple universal logic modules 500 are all fixed with successively.It refer to described in Fig. 9, it is a fixture 600 in Figure 10 On the structure schematic diagrams of multiple universal logic modules 500 is installed.In the embodiment shown in Fig. 5 and Figure 10, The fixture 600 is strip board.

It is pointed out that any change that one skilled in the art is done to the embodiment of the present invention All without departing from the scope of claims of the present invention.Correspondingly, the scope of claim of the invention is also not merely limited to In previous embodiment.

Claims (8)

1. a kind of Programmable logical controller subsystem, it is characterised in that it includes the first modular converter, the second modular converter and M Individual universal logic module,

Each universal logic module is connected by the first CAN with the first modular converter, and each FPGA Control module is connected by the second CAN with the second modular converter, wherein, M is natural number,

Each universal logic module receives multiple current/voltage signals, and multiple current/voltage signals to receiving Handled, to produce simultaneously outputting data signals；The data-signal is transferred to first modulus of conversion by the first CAN Block, the data-signal that first modular converter is received are converted to NET forms by CAN forms；The data-signal leads to Cross the second CAN and be transferred to second modular converter, the data-signal that second modular converter is received is by CAN Form is converted to NET forms.

2. Programmable logical controller subsystem according to claim 1, it is characterised in that the Programmable logical controller mould Block includes communication module, microprocessor and input/output module,

The input/output module includes N number of voltage/current signals interface, and it is used to receiving or sending voltage/current signals, The N is natural number；

The communication module includes the first CAN communication module and the second CAN communication module, the microprocessor and input/output Module, the first CAN communication module are connected with the second CAN communication module,

Foreign current/voltage signal that the input/output module is received is supplied to the microprocessor, micro- place Foreign current/voltage signal that reason device receives to it is handled to form data-signal, and the data-signal is distinguished The first CAN communication module and the second CAN communication module are supplied to, the data letter that the first CAN communication module is received Number the data-signal of CAN forms is converted into, then the first modular converter is transferred to by the first CAN；Second CAN communication The data-signal that module is received is converted into the data-signal of CAN forms, then is transferred to second turn by the second CAN Change the mold block.

3. Programmable logical controller subsystem according to claim 2, it is characterised in that the Programmable logical controller mould Block also includes power module, and the power module includes Switching Power Supply, and the input of the Switching Power Supply is connected with external power supply, Its output end to the device power supply in the universal logic module, and insulation of the Switching Power Supply to external power supply it is low enter Row isolation,

M≤16, the N are equal to 12.

4. Programmable logical controller subsystem according to claim 3, it is characterised in that the power module also includes the One variable-voltage power supply and the second variable-voltage power supply,

The input of first variable-voltage power supply is connected with the output end of the Switching Power Supply, the output of first variable-voltage power supply End is connected with the power end of the first CAN communication module, and first variable-voltage power supply is used for the electricity received to its input Pressure carries out transformation to obtain transformation voltage, and exports the transformation voltage by its output end；

The input of second variable-voltage power supply is connected with the output end of the Switching Power Supply, the output of second variable-voltage power supply End is connected with the power end of the second CAN communication module, and second variable-voltage power supply is used for the electricity received to its input Pressure carries out transformation, to obtain transformation voltage, and exports the transformation voltage by its output end.

5. Programmable logical controller subsystem according to claim 1, it is characterised in that

The universal logic module includes buckle, the groove for being formed at the universal logic module back side and position Accepting groove on the outside of the groove, the accepting groove extend to described from the side at the universal logic module back side Groove,

When the buckle is contained in the accepting groove, the foot of the buckle is exposed in the groove, can by described in Programmed logic control module is fixed on the fixture of the groove.

6. Programmable logical controller subsystem according to claim 5, it is characterised in that

The accepting groove includes first of the lateral groove direction extension from the universal logic module back side House groove portion, continue to extend up to the second collecting of the groove to the groove direction from the end of the described first collecting groove portion Groove portion, the block in the middle part of the accepting groove, wherein, formed with guide channel in the side wall of second accepting groove；

The buckle include buckle body, positioned at the head on buckle body top, the foot positioned at buckle body bottom, positioned at card Detain the shoulder of the head on both sides of body and positioned at buckle body both sides and the guidance part between the shoulder and foot；Institute Stating buckle body includes the cavity through the buckle body thickness direction, extends being formed from the buckle body and be located at institute State the elastic clip in cavity and finger portion；

The buckle is contained in the accepting groove, and is moved between can conciliating card position fixing position,

When the buckle, which is in, fixes position, the shoulder of the buckle is contained in the first collecting groove portion and the card The bottom of the shoulder of button is butted on the described second side wall top for housing groove portion；The guidance part is contained in described second and houses groove portion Guide channel in；The opening of the elastic clip is held on the first side of the widest portion of the block, and the finger portion is away from described Block；The foot of the buckle is exposed in the groove, so that the universal logic module is fixed on positioned at described On the fixture 600 of groove,

When the buckle is in solution card position, the shoulders of the buckle exit described first and house groove portion and the card Recess the described second side wall top for housing groove portion in the bottom of the shoulder of button；The opening of the elastic clip is held on the block Second side of widest portion；The finger portion stops close to the block and by the block；The foot of the buckle is retracted into described Second houses in groove portion, to cause the universal logic module to depart from the fixture positioned at the groove,

When the buckle is moved to by solution card position and fixes position, the opening of the elastic clip by the block widest portion The second side by the block widest portion be moved to the block widest portion the first side.

7. Programmable logical controller subsystem according to claim 6, it is characterised in that

From the side on the head of the close buckle of the cavity of the buckle body, extension forms the elastic clip, and the finger portion is from institute The side extension for stating the foot of the close buckle of the cavity of buckle body forms；

Block one end adjacent with the finger portion is formed with recess, when the buckle, which is in, fixes position, the finger portion The recess for being partially housed in the block and the recess of end and the block in the finger portion bottom maintain it is certain Distance；When the buckle is in solution card position, the end in the finger portion abuts against the bottom of the recess of the block.

8. Programmable logical controller subsystem according to claim 7, it is characterised in that

Described first width for housing groove portion is more than described second and houses well width, and the thickness of the shoulder of the buckle body is more than The thickness of the guide portion；

It is located at the side of the groove on the back side of universal logic module, can formed with the accepting groove described in several The back portion that programmed logic control module also includes the universal logic module of the opposite side from the groove extends to Several spaced cards above groove, the universal logic module is affiliated in described by the card On the fixture of groove,

The buckle also includes the conduit for being formed at the buckle back side, and the back side of the buckle is close to the collecting trench bottom End face, the conduit inserts in the buckle between the cavity of the buckle body and the foot of buckle or detaches institute When stating accepting groove, the block passes through the conduit.