CN105472839A - Two-path bidirectional switch direct frequency conversion three-phase power supply and communication device and control method thereof - Google Patents

Two-path bidirectional switch direct frequency conversion three-phase power supply and communication device and control method thereof Download PDF

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Publication number
CN105472839A
CN105472839A CN201510704084.1A CN201510704084A CN105472839A CN 105472839 A CN105472839 A CN 105472839A CN 201510704084 A CN201510704084 A CN 201510704084A CN 105472839 A CN105472839 A CN 105472839A
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bidirectional switch
switch cell
cell
phase
bidirectional
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CN105472839B (en
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李建山
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Zhejiang Paiwei Digital Technology Co ltd
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Hangzhou Zhong Hengpai Prestige Electrosource Inc
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    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02BCLIMATE CHANGE MITIGATION TECHNOLOGIES RELATED TO BUILDINGS, e.g. HOUSING, HOUSE APPLIANCES OR RELATED END-USER APPLICATIONS
    • Y02B20/00Energy efficient lighting technologies, e.g. halogen lamps or gas discharge lamps
    • Y02B20/40Control techniques providing energy savings, e.g. smart controller or presence detection

Abstract

The invention provides a two-path bidirectional switch direct frequency conversion three-phase power supply and communication device and a control method thereof. A switch control module is arranged between an alternating current output end and a power supply module. A digital chip is used for transmitting control signals. The switch control module comprises at least one switch control unit, and each switch control unit further comprises a switch controller, a first bidirectional switch unit S1 serially connected to a first phase output end of an alternating current, a second bidirectional switch unit S2 serially connected to a second phase output end of the alternating current. The device has the advantages that: communication is carried out through electric power wires, the signal amplitude is high, the communication is further stable, and extra wire cost is avoided; the device is suitable for transmitting a relatively small amount of data, is applicable to low-frequency communication and is suited to grouping control; only by expanding functions of an internal single-chip microcomputer of a power supply at a lamp side, the device can be realized, and the device is simple and reliable, and is low in cost; in addition, the device is suitable for outdoor lighting reconstruction of a three-phase power supply and secondary energy saving after the reconstruction and is also applicable to the fields such as new program secondary energy saving, and the total cost is the lowest.

Description

Two-way bidirectional switch Direct Conversion three phase supply and communicator and control method thereof
Technical field
The present invention relates to Control on Communication field, particularly relate to distributed power source for electrical domain, particularly adopt a kind of two-way bidirectional switch Direct Conversion three phase supply of two-way bidirectional switch and the common switching controls of earthed switch and communicator and control method thereof.
Background technology
Application of power field and need the electric power system application of simple transmitting control information out of doors, as applications such as LED street lamp, Tunnel Lamp or other conventional lamp, because supply line is comparatively far away and there is many uncertain factors, generally by mains electricity, the power supply in light fixture is powered, and undertaken communicating and controlling by independent communicator or circuit.Such as during LED street lamp application, need to regulate every brightness to street lamp in several hours, i.e. so-called light modulation, which, owing to realizing secondary energy-saving, has great economy and social effect.Brightness adjustment control mode mainly contains four classes: the control mode (as: 0-10V analog voltage control/PWM discrete control/RS-485 digital communication controls) of being carried out analog or digital by independent light modulation line; Light modulation and control mode is carried out, as Zigbee communication and control by radio communication; Do not need independent circuit and carried out the mode that communicates by power line, as PLC power line carrier, PLC; Timing controlled is carried out by the timer of lamp interior; These communication be in fact all to light fixture inside power supply communicate and control.
Realize simple by the control mode technology of independent light modulation line, can realize controlling together a certain group of lamp, namely divide into groups to control, the light modulation line of a such as 0-10V can control the lamp of nearly more than 200, but when engineer applied especially reconstruction of old circuit time to there is construction wiring difficult, wiring distance is far away, the drawback that wire rod cost is high, and the poor ability of the anti-induced lightening interference of light modulation circuit, reliability is not high.PLC power line carrier, PLC mode: at present by each power supply (namely on every bar lamp) install power line carrier, PLC module additional and single-lamp controller realizes communicating and controlling functions, advantage is that transferable semaphore is very large, signal bi-directional, transmission speed is fast, signal is transmitted by Alternating Current Power Supply line, without the need to wiring of again constructing, without unnecessary wire rod cost; But single-lamp controller cost is high and complicated, signal amplitude is too little, is easily disturbed, and communication reliability is low, and when light fixture quantity is more, single-lamp controller quantity is many too, and total cost is very high.If power line carrier, PLC is integrated into inside power supply, not only there is power carrier chip and the high problem of coupling solutions decoding circuit cost, also can there is the problem that power line carrier, PLC frequency overlaps with Switching Power Supply internal operating frequencies height and meeting is disturbed, the EMI electromagnetic compatibility problem brought is difficult to process, design difficulty is high, not yet has the application of actual product batch so far.There is the problem that cost is high, communication is unstable, communication distance is short in radio communication (as Zigbee), also needs additional wireless communication device and antenna on lamp.If radio communication be integrated in power supply, because outdoor power system is with water proof type aluminum hull, an antenna must be stretched out from aluminum hull, waterproof and configuration aspects difficulty are large, cost is also high.The common feature of three is the material or device that all need fringe cost higher.Timing dimming: timer is started working when power supply electrifying, after the time period of setting, namely the electric current of power source internal is adjusted to reach required brightness, advantage is that cost is very low, does not need external wire rod, controller etc., but due to PERCOM peripheral communication cannot be followed, once setting timing strategies, can not change, therefore be not suitable for the larger street lamp application of evening hours difference in length in summer in winter, be also not suitable for the application such as Tunnel Lamp.The most crucial demand of engineer applied is the secondary energy-saving based on light modulation, and this demand only need unify adjustment (grouping controls) to some section or certain group lamp, does not need to control one by one single lamp; During light modulation, semaphore is very little, only need send simple light modulation percentage signal; Dimming interval is long, generally every adjustment in several hours once; Therefore the demand of dimmer application is: semaphore is minimum, signal transmission number of times is few, need just to need communication when adjustment, can customize in advance light modulation Time controlling schema and communication in write-once to power source internal memory, do not need single lamp to control and only need divide into groups to control, avoiding rewiring as far as possible; In above-mentioned four kinds of modes, the Method compare being undertaken controlling by light modulation line meets light modulation demand, and plc communication and radio communication greatly exceed actual demand, and timing dimming can not meet the demand of communication adjustment, and application is few.
Summary of the invention
For the shortcoming of such scheme, the present invention proposes a kind of two-way bidirectional switch Direct Conversion three phase supply and communicator and control method thereof, feature can be communicated by power line, signal amplitude is large and then communication is stable, without redundant wire cost, be applicable to transmitting less data volume, be applicable to low frequency communication, be applicable to grouping to control, the function that the power supply of light fixture side only need expand inner single-chip microcomputer can realize, simple and reliable, cost is low, be applicable to three phase supply outdoor lighting transformation and transformation after secondary energy-saving, also new projects' secondary energy-saving application and other field application is applicable to, overall cost is minimum, economic benefit highly significant.
A kind of two-way bidirectional switch Direct Conversion three phase supply of the present invention and communicator, comprise alternating current output and the power module being connected to described alternating current output, described power module comprises some power supplys, between described alternating current output and described power module, switch control module is set, described switch control module and power module adopt digit chip transfer control signal, described switch control module comprises on-off controller, be serially connected in the first bidirectional switch cell S 1 of alternating current first-phase output, be serially connected in the second bidirectional switch cell S 2 of alternating current second-phase output, the first described bidirectional switch cell S 1 is connected power module one end with the second bidirectional switch cell S 2 is intersected, the output of described on-off controller respectively with the first described bidirectional switch cell S 1, the control end of the second bidirectional switch cell S 2 is connected, described arbitrary switch control unit at least connects a power supply.
Further, described switch control module also comprises the first bidirectional switch cell S 3 being connected to alternating current the 3rd output.
Further, described switch control module also comprises the 11 two-way switch element S11 being connected to alternating current first-phase output.
Further, described switch control unit comprises the 4th bidirectional switch cell S 4; The control end of the 4th described bidirectional switch cell S 4 is connected with the output of described on-off controller, the residue two ends of the 4th described bidirectional switch cell S 4, one end is connected to the node that the first described bidirectional switch cell S 1, second bidirectional switch cell S 2 intersects, and the other end is connected with the input of the power supply on the first-phase of described power module.
Further, described switch control unit comprises the 5th bidirectional switch cell S 5, and the control end of the 5th described bidirectional switch cell S 5 is connected with the output of described on-off controller; The residue two ends of the 5th described bidirectional switch cell S 5, one end is connected to the node that the first described bidirectional switch cell S 1, second bidirectional switch cell S 2 intersects, and the other end is connected with the input of the power supply on the second-phase of described power module.
Further, described switch control unit comprises the 4th bidirectional switch cell S 4 and the 5th bidirectional switch cell S 5, and the 4th described bidirectional switch cell S 4, the control end of the 5th bidirectional switch cell S 5 are connected with the output of described on-off controller; The 4th described bidirectional switch cell S 4, the residue two ends of the 5th bidirectional switch cell S 5, one end is connected to the node that the first described bidirectional switch cell S 1, second bidirectional switch cell S 2 intersects, and the other end is connected with the input of the power supply on the second-phase, the 3rd of described power module respectively; Described switch control unit comprises the 6th bidirectional switch cell S 6; The control end of the 6th described bidirectional switch cell S 6 is connected with the output of described on-off controller, the residue two ends of the 6th described bidirectional switch cell S 6, one end is connected to the node that the described two-way switch element S11 of the 3rd bidirectional switch cell S the 3, the 11 intersects, and the input of the power supply on the other end and the 3rd of described power module the is connected.
Further, described switch control unit comprises the 13 bidirectional switch cell S 13; The control end of the 13 described bidirectional switch cell S 13 is connected with the output of described on-off controller, the residue two ends of the 13 described bidirectional switch cell S 13, one end is connected to the node that the described two-way switch element S11 of the 3rd bidirectional switch cell S the 3, the 11 intersects, and the other end is connected with the input of the power supply on the first-phase of described power module.
Further, described switch control unit comprises the 7th bidirectional switch cell S 7, and the control end of the 7th described bidirectional switch cell S 7 is connected with the output of described on-off controller; The circuit of the first described bidirectional switch cell S 1 and the 4th bidirectional switch cell S 4 serial connection is in parallel with the 7th described bidirectional switch cell S 7.
Further, described switch control unit comprises the 8th bidirectional switch cell S 8, and the control end of the 8th described bidirectional switch cell S 8 is connected with the output of described on-off controller; The circuit of the second described bidirectional switch cell S 2 and the 5th bidirectional switch cell S 5 serial connection is in parallel with the 8th described bidirectional switch cell S 8.
Further, described switch control unit comprises the 9th bidirectional switch cell S 9, and the control end of the 9th described bidirectional switch cell S 9 is connected with the output of described on-off controller; The circuit of the 3rd described bidirectional switch cell S 3 and the 6th bidirectional switch cell S 6 serial connection is in parallel with the 9th described bidirectional switch cell S 9.
Further, described switch control unit comprises the tenth bidirectional switch cell S 10, and the control end of the tenth described bidirectional switch cell S 10 is connected with the output of described on-off controller; The residue two ends of the tenth described bidirectional switch cell S 10, one end is connected to the node that the first described bidirectional switch cell S 1, second bidirectional switch cell S 2 intersects, other end ground connection.
Further, described switch control unit comprises the 12 bidirectional switch cell S 12, and the control end of the 12 described bidirectional switch cell S 12 is connected with the output of described on-off controller; The residue two ends of the 12 described bidirectional switch cell S 12, one end is connected to the node that the described two-way switch element S11 of the 3rd bidirectional switch cell S the 3, the 11 intersects, other end ground connection.
Further, MOSFET or IGBT that be that the first described bidirectional switch cell S 1, second bidirectional switch cell S 2, the 3rd bidirectional switch cell S 3 comprise at least two Opposite direction connections respectively or that form two-way admittance form or thyristor.
Further, MOSFET or IGBT that be that the tenth described bidirectional switch cell S 10 comprises at least two Opposite direction connections or that form two-way admittance form or thyristor.
Further, MOSFET or IGBT that be that the 12 described bidirectional switch cell S 12 comprises at least two Opposite direction connections or that form two-way admittance form or thyristor.
The control method of a kind of two-way bidirectional switch Direct Conversion three phase supply and communicator
S1, to be controlled by the Control timing sequence of the on-off controller described in controlling described in switch control unit in the conducting state of switch;
The waveform of array output of the conducting state of the switch in S2, switch control unit described in definition is control command, and control command becomes digital signal by the decoding of described digit chip and conveys to power module.
The invention has the beneficial effects as follows: the present invention, by adding switch control module in ac power supply line, reaches the object of simple communication by the short time wave form varies controlling alternating current.Described switch control module controls to switch module the control command transmitting simulation or digital signal by on-off controller, and power module side can be undertaken sampling and decoding or store by built-in digit chip, response limiting instruction.Adopt said method, each power supply can arrange grouping or set address separately, realizes grouping and controls even point-to-point control.The digit chip of power source internal realizes simple, and cost is low; Simultaneously because the present invention adopts large-signal transmission of information, antijamming capability is strong, and communication reliability is high.The invention belongs to one-way communication, in LED power field, control mode and function and to carry out the mode of brightness adjustment control similar by simulating light modulation line, but without unnecessary Construction Cost and wire rod cost, increase the cost of power supply hardly, without thunderbolt interference hidden danger, achieve grouping and control, and absorb the advantage of timing dimming, meet actual requirement of engineering to greatest extent.This kind of mode is adopted to carry out digital signal transfers, ensure that on the one hand the power supply of arbitrary power supply is maintained the form of interchange and then power supply still can normally work, amount of information less (as light modulation percentage signal) on the other hand owing to transmitting, communication speed can meet instructions for use, and communication reliability is very high, and supply line provides balancing waveform in short-term simultaneously, duration is very short, can complete in several power frequency period, after filtering, can ignore the interference of electrical network.For street light modulating application, once communication can set the timing dimming strategy of coming few months, and the communication frequency is lower.
Accompanying drawing explanation
Fig. 1 is the circuit theory diagrams of the embodiment of the present invention one
Fig. 2 is the embodiment of the present invention one switch control time sequence figure.
Fig. 3 is the oscillogram of Fig. 2 of the present invention.
Fig. 4 is the simplified pinciple figure of Fig. 1 of the present invention.
Fig. 5 is the circuit theory diagrams of the embodiment of the present invention two.
Fig. 6 is the schematic diagram that switch control unit of the present invention is extended to three-phase.
Fig. 7 is the schematic diagram of the parallel form of Fig. 6 topology of the present invention.
Fig. 8 is the first kind replacement form of the bidirectional switch unit in the present invention.
Fig. 9 is the Equations of The Second Kind replacement form of the bidirectional switch unit in the present invention.
Embodiment
Below in conjunction with accompanying drawing, technical scheme of the present invention is further described, but the present invention is not limited to these embodiments.
As shown in figs. 1-7, a kind of two-way bidirectional switch Direct Conversion three phase supply of the present invention and communicator, comprise alternating current output and the power module being connected to described alternating current output, described power module comprises some power supplys, between described alternating current output and described power module, switch control module is set, described switch control module and power module adopt digit chip transfer control signal, described switch control module comprises on-off controller, be serially connected in the first bidirectional switch cell S 1 of alternating current first-phase output, be serially connected in the second bidirectional switch cell S 2 of alternating current second-phase output, the first described bidirectional switch cell S 1 is connected power module one end with the second bidirectional switch cell S 2 is intersected, the output of described on-off controller respectively with the first described bidirectional switch cell S 1, the control end of the second bidirectional switch cell S 2 is connected, described arbitrary switch control unit at least connects a power supply.
Described switch control module also comprises the first bidirectional switch cell S 3 being connected to alternating current the 3rd output.
Described switch control module also comprises the 11 two-way switch element S11 being connected to alternating current first-phase output.
Described switch control unit comprises the 4th bidirectional switch cell S 4; The control end of the 4th described bidirectional switch cell S 4 is connected with the output of described on-off controller, the residue two ends of the 4th described bidirectional switch cell S 4, one end is connected to the node that the first described bidirectional switch cell S 1, second bidirectional switch cell S 2 intersects, and the other end is connected with the input of the power supply on the first-phase of described power module.
Described switch control unit comprises the 5th bidirectional switch cell S 5, and the control end of the 5th described bidirectional switch cell S 5 is connected with the output of described on-off controller; The residue two ends of the 5th described bidirectional switch cell S 5, one end is connected to the node that the first described bidirectional switch cell S 1, second bidirectional switch cell S 2 intersects, and the other end is connected with the input of the power supply on the second-phase of described power module.
Described switch control unit comprises the 4th bidirectional switch cell S 4 and the 5th bidirectional switch cell S 5, and the 4th described bidirectional switch cell S 4, the control end of the 5th bidirectional switch cell S 5 are connected with the output of described on-off controller; The 4th described bidirectional switch cell S 4, the residue two ends of the 5th bidirectional switch cell S 5, one end is connected to the node that the first described bidirectional switch cell S 1, second bidirectional switch cell S 2 intersects, and the other end is connected with the input of the power supply on the second-phase, the 3rd of described power module respectively; Described switch control unit comprises the 6th bidirectional switch cell S 6; The control end of the 6th described bidirectional switch cell S 6 is connected with the output of described on-off controller, the residue two ends of the 6th described bidirectional switch cell S 6, one end is connected to the node that the described two-way switch element S11 of the 3rd bidirectional switch cell S the 3, the 11 intersects, and the input of the power supply on the other end and the 3rd of described power module the is connected.
Described switch control unit comprises the 13 bidirectional switch cell S 13; The control end of the 13 described bidirectional switch cell S 13 is connected with the output of described on-off controller, the residue two ends of the 13 described bidirectional switch cell S 13, one end is connected to the node that the described two-way switch element S11 of the 3rd bidirectional switch cell S the 3, the 11 intersects, and the other end is connected with the input of the power supply on the first-phase of described power module.
Described switch control unit comprises the 7th bidirectional switch cell S 7, and the control end of the 7th described bidirectional switch cell S 7 is connected with the output of described on-off controller; The circuit of the first described bidirectional switch cell S 1 and the 4th bidirectional switch cell S 4 serial connection is in parallel with the 7th described bidirectional switch cell S 7.
Described switch control unit comprises the 8th bidirectional switch cell S 8, and the control end of the 8th described bidirectional switch cell S 8 is connected with the output of described on-off controller; The circuit of the second described bidirectional switch cell S 2 and the 5th bidirectional switch cell S 5 serial connection is in parallel with the 8th described bidirectional switch cell S 8.
Described switch control unit comprises the 9th bidirectional switch cell S 9, and the control end of the 9th described bidirectional switch cell S 9 is connected with the output of described on-off controller; The circuit of the 3rd described bidirectional switch cell S 3 and the 6th bidirectional switch cell S 6 serial connection is in parallel with the 9th described bidirectional switch cell S 9.
Described switch control unit comprises the tenth bidirectional switch cell S 10, and the control end of the tenth described bidirectional switch cell S 10 is connected with the output of described on-off controller; The residue two ends of the tenth described bidirectional switch cell S 10, one end is connected to the node that the first described bidirectional switch cell S 1, second bidirectional switch cell S 2 intersects, other end ground connection.
Described switch control unit comprises the 12 bidirectional switch cell S 12, and the control end of the 12 described bidirectional switch cell S 12 is connected with the output of described on-off controller; The residue two ends of the 12 described bidirectional switch cell S 12, one end is connected to the node that the described two-way switch element S11 of the 3rd bidirectional switch cell S the 3, the 11 intersects, other end ground connection.
MOSFET or IGBT that be that the first described bidirectional switch cell S 1, second bidirectional switch cell S 2, the two-way switch element S11 of the 3rd bidirectional switch cell S the 3 and the 11 comprise at least two Opposite direction connections respectively or that form two-way admittance form or thyristor.
MOSFET or IGBT that be that the tenth described bidirectional switch cell S 10 comprises at least two Opposite direction connections or that form two-way admittance form or thyristor.
Further, MOSFET or IGBT that be that the 12 described bidirectional switch cell S 12 comprises at least two Opposite direction connections or that form two-way admittance form or thyristor.
A control method for two-way bidirectional switch Direct Conversion three phase supply and communicator,
S1, to be controlled by the Control timing sequence of the on-off controller described in controlling described in switch control unit in the conducting state of switch;
The waveform of array output of the conducting state of the switch in S2, switch control unit described in definition is control command, and control command becomes digital signal by the decoding of described digit chip and conveys to power module.
It should be noted that, the bidirectional switch unit described in the present invention all can embody with the form of serial or parallel connection switch combination.
First with single phase power supply form, the present invention is illustrated, so that the understanding of the present invention.As shown in Figure 4, Fig. 4 is the schematic diagram of bidirectional switch unit on single-phase alternating current is powered be arranged on three-phase alternating current, is the reduced form on a kind of basis of the present invention.When not needing communication, a conducting the 7th bidirectional switch cell S 7, keeps normal power supply; When needs communicate, close the 7th bidirectional switch cell S 7, and the first bidirectional switch cell S 1, the second bidirectional switch cell S 2 is switched according to certain sequential.Tenth bidirectional switch cell S 10 is for the function such as clamper and current limliting.
Be further elaborated with regard to embodiment a pair the present invention below, only in order to illustrate but not limit as this kind of form.
Embodiment one; as shown in Figure 1; the first described bidirectional switch cell S 1; second bidirectional switch cell S 2; 3rd bidirectional switch cell S 3 and the tenth bidirectional switch cell S 10 comprise respectively two differential concatenations switching device and for the protection of protection switch; described switching device represents with Q1-Q6 in the drawings, and protection switch is S101-S103 in the drawings.Protection switch S101-S103 is generally relay, the switching device Q1-Q6 in figure can being made to separate completely with power supply circuits when not needing work, affecting line powering under avoiding switching device Q1-Q6 to there is the failure conditions such as short circuit in inside.The switching device herein selected is metal-oxide-semiconductor, also can adopt other forms.Herein, general the 7th described bidirectional switch cell S 7 is the switch two-way switch element that the reliabilities such as contactor, air switch, thyristor, contactor are high, withstanding current capability strong, rate request is not high.In Fig. 1, the tenth bidirectional switch cell S 10(of ground connection comprises S103, Q5, Q6), under some switching sequence, due to the demand of afterflow and control voltage aspect, the tenth bidirectional switch cell S 10 can make control mode more flexible, plays the effect such as afterflow, clamper when practical application.This switch combination form can be used as canonical form in actual applications.
When only needing power supply normally to work when not needing to communicate, conducting the 7th bidirectional switch cell S 7,4th bidirectional switch cell S 4, the tenth bidirectional switch cell S 10(comprise S103, Q5, Q6) and switching device Q1-Q4 be all in off state, thus the connection of roof-cut resistence control module and power supply side.Due to a conducting the 7th bidirectional switch cell S 7 in this case, this state known and common normal power supply as broad as long.When needs Control on Communication, the 7th bidirectional switch cell S 7 is turned off, the 4th bidirectional switch cell S 4 conducting, and according to certain Control timing sequence conducting Q1-Q4, as shown in Figure 2, switch device conductive when defining high level inside sequential chart, low level switching device turns off.According to conducting sequential, the supply lines of first-phase can be formed waveform as shown in Figure 3.Switching device Q1-Q4 has certain control method preventing leading directly to when switching, ensure can not when work by one, two, three-phase voltage short circuit leads directly to, avoid occurring integrity problem.Three-phase alternating current is through the switching over of switching device Q1-Q4, and setting is just arrived negative level and is being changed to numeral 1, bears positive level and is changed to numeral 0, according to Fig. 3, can form the numeral 1 as figure definition and numeral 0.Like this, the digital quantity that the communication information comprises can according to the transmission of certain communication protocol one one.Because power source internal is provided with digit chip and the memory of decoding, by decoding to the coding of input line, the digital signal of transmission just can be known.The definition of the switching mode of switching device Q1 to Q4 defined above and numeral 0 and 1 just wherein a kind of mode, the present invention is not limited to above-mentioned definition mode.
Owing to introducing bidirectional switch unit, in conjunction with different Control timing sequence, the definition of multiple communication form and numeral 0,1 can be had.
As shown in Figure 2, this kind of mode is adopted to carry out numeral or analog signal transmission, ensure that the power supply of some load power sources is maintained the form of interchange on the one hand, because power source internal has rectification circuit or circuit of power factor correction, these power supplys still can normally work under above-mentioned supply power mode, reach the object of transmission of information on the other hand.By adopting the form of bidirectional switch, simplify hardware configuration, save hardware number, what is more important substantially increases the flexibility of control, can realize the switching of transient process easily, and ensure the integrality of handoff procedure.
Being illustrated in figure 4 a kind of simplified pinciple figure of the embodiment of the present invention one, is a kind of common form of bidirectional switch unit form switching controls topology.4th bidirectional switch cell S 4 and the 7th bidirectional switch cell S 7 are generally the forms such as relay, contactor, air switch, and the first bidirectional switch cell S 1 and the second bidirectional switch cell S 2 are power electronic device, as MOSFET, IGBT, SCR etc., can reliability be improved like this, and ensure that the time switched is very fast.This form is comparatively general when practical application.
With three phase supply form, the present invention is illustrated again below, is just further elaborated with embodiment two couples of the present invention below.
Embodiment two, as shown in Figure 5, wherein the first bidirectional switch cell S 1, second bidirectional switch cell S 2, the first bidirectional switch cell S 1, the second bidirectional switch cell S 2 in the effect of the two-way switch element S11 of the 3rd bidirectional switch cell S the 3, the 11 and single phase power supply form is consistent; 4th bidirectional switch cell S 4,5th bidirectional switch cell S 5,6th bidirectional switch cell S 6,13 bidirectional switch cell S 13 is for by the first bidirectional switch cell S 1, second bidirectional switch cell S 2,3rd bidirectional switch cell S the 3, the 11 two-way switch element S11 timesharing is linked into first, second and third phase of three-phase alternating current when being linked into three-phase separate.7th bidirectional switch cell S the 7, eight bidirectional switch cell S the 8, nine bidirectional switch cell S 9 is the same with the 7th bidirectional switch cell S 7 in embodiment one, respectively in order to switch power supply state and the state of a control of supply line.When real work, 7th bidirectional switch cell S 7 and the 4th bidirectional switch cell S the 4, the 13 bidirectional switch cell S 13,8th bidirectional switch cell S 8 and the 5th bidirectional switch cell S 5,9th bidirectional switch cell S 9 and the 6th bidirectional switch cell S 6 carry out supporting switching respectively, as second-phase need communication time, 8th bidirectional switch cell S 8 is turned off, 5th bidirectional switch cell S 5 conducting, first bidirectional switch cell S 1, second bidirectional switch cell S 2, according to certain sequence switch, can form signal of communication and be transferred to the power supply of second-phase.Now the 7th bidirectional switch cell S 7, the 9th bidirectional switch cell S 9 keep conducting, and the 4th bidirectional switch cell S 4, the 6th bidirectional switch cell S the 6, the 13 bidirectional switch cell S 13 keep turning off.Threephase switch in Fig. 5, the 7th bidirectional switch cell S 7 can also be made when switching, 8th bidirectional switch cell S 8 or the 7th bidirectional switch cell S 7, 9th bidirectional switch cell S 9 turns off and the 4th bidirectional switch cell S 4 simultaneously, 5th bidirectional switch cell S 5 or the 6th bidirectional switch cell S 6, 13 bidirectional switch cell S 13 conducting simultaneously (the 4th bidirectional switch cell S 4, the conducting of the 5th bidirectional switch cell S 5 turns off and the 7th bidirectional switch cell S 7, 8th bidirectional switch cell S 8 is supporting), namely communication control unit exports identical signal of communication to some power supplys of the two-phase in three-phase simultaneously, it is now another kind of mode of operation.
Alternatively, also can connect the tenth bidirectional switch cell S the 10, the 12 bidirectional switch cell S 12 in embodiment two and play the effect such as afterflow, clamper.
The present invention also can provide the situation of two or more switch control unit parallel operation, and this situation is suitable for relatively high power expansion, is also applicable to backing up individual module, promotes reliability.Due to two communicator parallel connections, coordinate different Control timing sequence, can form communication mode more flexibly, such as the two can alternation, some a part of circuit of work, another work another part circuit etc.Therefore might not be simple relation in parallel.Threephase switch in Fig. 5,7th bidirectional switch cell S 7, the 8th bidirectional switch cell S 8, the 9th bidirectional switch cell S 9 can also be turned off and the 4th bidirectional switch cell S 4 simultaneously when switching, 5th bidirectional switch cell S 5, the conducting simultaneously of 6th bidirectional switch cell S 6, namely communication control unit exports identical signal of communication to each power supply in first, second and third phase simultaneously, is now another kind of mode of operation.
Fig. 5 is the form that the topology shown in Fig. 4 is expanded into three-phase.
Fig. 6 gives the schematic diagram that topology is expanded into three-phase.And each switch control unit can be completely the same in Fig. 6, also can be different.Fig. 7 gives the situation of every two identical or different device parallel connections mutually, in conjunction with different control modes, can realize high-power expansion and produce new control method and communication waveforms.
It should be noted that, when the switch control unit described in the present invention is parallel with one another, the inside of described each switch control unit can be kept to connect completely the same, also can adopt the switch control unit that inner connecting way is different.Fig. 5 and Fig. 4 show only the extend type of identical switch control unit, does not show the extend type of different switch control unit, and arbitrary switch control unit inside all can adopt different topologys.
Bidirectional switch unit mentioned by the present invention, bidirectional switch unit in topology as shown in figs. 1-7, can substitute by the concrete switch form shown in " A-D " in " A-L, the a-z; α-γ " in Fig. 8 and Fig. 9, and can substitute with switch series, parallel any in Fig. 8-9, connection in series-parallel form.Switch two-way switch element in Fig. 8-9 can be MOSFET(mos field effect transistor), Diode(diode), JFET(technotron), IGBT(igbt), GTO(turn-off thyristor), BJT(bipolar junction transistor), Thyristor(thyristor), IGCT(integrated gate commutated thyristor), TRIAC(three terminal bidirectional alternating-current switch), bidirectional thyristor, relay(relay), Contactor(contactor), air switch, solid-state relay etc.
In addition, it should be noted that, especially increase inductance, capacitor filter, lightning protection circuit etc. in circuit of the present invention between bidirectional switch unit node to power supply lines also within right; Communication code, switching sequence are not limited to the form shown in embodiment one.
Specific embodiment described herein is only to the explanation for example of the present invention's spirit.Those skilled in the art can make various amendment or supplement or adopt similar mode to substitute to described specific embodiment, but can't depart from spirit of the present invention or surmount the scope that appended claims defines.

Claims (17)

1. a two-way bidirectional switch Direct Conversion three phase supply and communicator, comprise alternating current output and the power module being connected to described alternating current output, described power module comprises some power supplys, it is characterized in that: between described alternating current output and described power module, switch control module is set, described switch control module and power module adopt digit chip transfer control signal, described switch control module comprises at least one switch control unit, described switch control unit comprises on-off controller, be serially connected in the first bidirectional switch cell S 1 of alternating current first-phase output, be serially connected in the second bidirectional switch cell S 2 of alternating current second-phase output, the first described bidirectional switch cell S 1 is connected power module one end with the second bidirectional switch cell S 2 is intersected, the output of described on-off controller respectively with the first described bidirectional switch cell S 1, the control end of the second bidirectional switch cell S 2 is connected, described arbitrary switch control unit at least connects a power supply.
2. two-way bidirectional switch Direct Conversion three phase supply according to claim 1 and communicator, is characterized in that: described switch control module comprises a switch control unit; Or described switch control module comprises at least two switch control units, described switch control unit is connected to alternating current output parallel with one another.
3. two-way bidirectional switch Direct Conversion three phase supply according to claim 2 and communicator, is characterized in that: described switch control unit also comprises the first bidirectional switch cell S 3 being connected to alternating current third phase output.
4. two-way bidirectional switch Direct Conversion three phase supply according to claim 3 and communicator, is characterized in that: described switch control unit also comprises the 11 two-way switch element S11 being connected to alternating current first-phase output.
5. the two-way bidirectional switch Direct Conversion three phase supply according to any one of claim 2-4 and communicator, is characterized in that: described switch control unit comprises the 4th bidirectional switch cell S 4; The control end of the 4th described bidirectional switch cell S 4 is connected with the output of described on-off controller, the residue two ends of the 4th described bidirectional switch cell S 4, one end is connected to the node that the first described bidirectional switch cell S 1, second bidirectional switch cell S 2 intersects, and the other end is connected with the input of the power supply on the first-phase of described power module.
6. two-way bidirectional switch Direct Conversion three phase supply according to claim 5 and communicator, it is characterized in that: described switch control unit comprises the 5th bidirectional switch cell S 5, the control end of the 5th described bidirectional switch cell S 5 is connected with the output of described on-off controller; The residue two ends of the 5th described bidirectional switch cell S 5, one end is connected to the node that the first described bidirectional switch cell S 1, second bidirectional switch cell S 2 intersects, and the other end is connected with the input of the power supply on the second-phase of described power module.
7. the two-way bidirectional switch Direct Conversion three phase supply according to any one of claim 4 and communicator, it is characterized in that: described switch control unit comprises the 4th bidirectional switch cell S 4 and the 5th bidirectional switch cell S 5, the 4th described bidirectional switch cell S 4, the control end of the 5th bidirectional switch cell S 5 are connected with the output of described on-off controller; The 4th described bidirectional switch cell S 4, the residue two ends of the 5th bidirectional switch cell S 5, one end is connected to the node that described first bidirectional switch cell S 1, second bidirectional switch cell S 2 intersects, and the other end is connected with the input of the power supply on the second-phase of described power module, third phase respectively; Described switch control unit comprises the 6th bidirectional switch cell S 6; The control end of the 6th described bidirectional switch cell S 6 is connected with the output of described on-off controller, the residue two ends of the 6th described bidirectional switch cell S 6, one end is connected to the node that the described two-way switch element S11 of the 3rd bidirectional switch cell S the 3, the 11 intersects, and the other end is connected with the input of the power supply on the third phase of described power module.
8. two-way bidirectional switch Direct Conversion three phase supply according to claim 7 and communicator, is characterized in that: described switch control unit comprises the 13 bidirectional switch cell S 13; The control end of the 13 described bidirectional switch cell S 13 is connected with the output of described on-off controller, the residue two ends of the 13 described bidirectional switch cell S 13, one end is connected to the node that the described two-way switch element S11 of the 3rd bidirectional switch cell S the 3, the 11 intersects, and the other end is connected with the input of the power supply on the first-phase of described power module.
9. two-way bidirectional switch Direct Conversion three phase supply according to claim 5 and communicator, it is characterized in that: described switch control unit comprises the 7th bidirectional switch cell S 7, the control end of the 7th described bidirectional switch cell S 7 is connected with the output of described on-off controller; The circuit of the first described bidirectional switch cell S 1 and the 4th bidirectional switch cell S 4 serial connection is in parallel with the 7th described bidirectional switch cell S 7.
10. two-way bidirectional switch Direct Conversion three phase supply according to claim 6 and communicator, it is characterized in that: described switch control unit comprises the 8th bidirectional switch cell S 8, the control end of the 8th described bidirectional switch cell S 8 is connected with the output of described on-off controller; The circuit of the second described bidirectional switch cell S 2 and the 5th bidirectional switch cell S 5 serial connection is in parallel with the 8th described bidirectional switch cell S 8.
11. two-way bidirectional switch Direct Conversion three phase supply according to claim 7 and communicators, it is characterized in that: described switch control unit comprises the 9th bidirectional switch cell S 9, the control end of the 9th described bidirectional switch cell S 9 is connected with the output of described on-off controller; The circuit of the 3rd described bidirectional switch cell S 3 and the 6th bidirectional switch cell S 6 serial connection is in parallel with the 9th described bidirectional switch cell S 9.
12. two-way bidirectional switch Direct Conversion three phase supplies according to Claims 2 or 3 or 4 or 6 and communicator, it is characterized in that: described switch control unit comprises the tenth bidirectional switch cell S 10, the control end of the tenth described bidirectional switch cell S 10 is connected with the output of described on-off controller; The residue two ends of the tenth described bidirectional switch cell S 10, one end is connected to the node that the first described bidirectional switch cell S 1, second bidirectional switch cell S 2 intersects, other end ground connection.
13. two-way bidirectional switch Direct Conversion three phase supplies according to claim 4 or 7 or 8 and communicator, it is characterized in that: described switch control unit comprises the 12 bidirectional switch cell S 12, the control end of the 12 described bidirectional switch cell S 12 is connected with the output of described on-off controller; The residue two ends of the 12 described bidirectional switch cell S 12, one end is connected to the node that the described two-way switch element S11 of the 3rd bidirectional switch cell S the 3, the 11 intersects, other end ground connection.
14. two-way bidirectional switch Direct Conversion three phase supplies according to Claims 2 or 3 and communicator, is characterized in that: MOSFET or IGBT that be that the first described bidirectional switch cell S 1, second bidirectional switch cell S 2, the 3rd bidirectional switch cell S 3 comprise at least two Opposite direction connections respectively or that form two-way admittance form or thyristor.
15. two-way bidirectional switch Direct Conversion three phase supply according to claim 12 and communicators, is characterized in that: MOSFET or IGBT that be that the tenth described bidirectional switch cell S 10 comprises at least two Opposite direction connections or that form two-way admittance form or thyristor.
16. two-way bidirectional switch Direct Conversion three phase supply according to claim 13 and communicators, is characterized in that: MOSFET or IGBT that be that the 12 described bidirectional switch cell S 12 comprises at least two Opposite direction connections or that form two-way admittance form or thyristor.
The control method of 17. 1 kinds of two-way bidirectional switch Direct Conversion three phase supplies according to claim 1 and communicator, is characterized in that:
S1, to be controlled by the Control timing sequence of the on-off controller described in controlling described in switch control unit in the conducting state of switch;
The waveform of array output of the conducting state of the switch in S2, switch control unit described in definition is control command, and control command becomes digital signal by the decoding of described digit chip and conveys to power module.
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CN109375556A (en) * 2018-12-10 2019-02-22 广东新宝电器股份有限公司 A kind of control circuit and control method
WO2022174623A1 (en) * 2021-02-20 2022-08-25 阳光电源股份有限公司 Series-type inverter system and protection method therefor
CN115420159A (en) * 2022-09-05 2022-12-02 天津津航计算技术研究所 Current-limiting protection initiation circuit applied to insensitive electric initiator

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CN104917547A (en) * 2015-06-25 2015-09-16 威胜集团有限公司 TPLC based power line power frequency communication system

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CN104917547A (en) * 2015-06-25 2015-09-16 威胜集团有限公司 TPLC based power line power frequency communication system

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* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN109375556A (en) * 2018-12-10 2019-02-22 广东新宝电器股份有限公司 A kind of control circuit and control method
WO2022174623A1 (en) * 2021-02-20 2022-08-25 阳光电源股份有限公司 Series-type inverter system and protection method therefor
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