FR3078847A1 - Inverter for electric generator and electric generator - Google Patents

Abstract

The present invention relates to an inverter for an electric generator and an inverting electric generator, which belong to the field of electric inverting generators. According to the inverter for electric generator and the inverting electric generator applying the inverter for electric generator proposed by the present invention, the switching of a state switch is directly associated with the switching actions which control a quadruple relay, each unit control unit operates independently, a fixed operating mode is formed without mutual interference, and switching of the output between a single-phase full-power output and a three-phase full-power output is realized. The present invention avoids the use of complex system control and facilitates communication with the control units, so that the reliability of the product is improved. Reference: Figure 1

Description

Description

Title of the invention: Inverter for electric generator and electric generator with inversion The present invention relates to the field of electric generators with inversion, and in particular an inverter for electric generator and an electric generator with inversion.

When using an electric generator with relatively large output power, some loads are three-phase, and some loads are single-phase. For the conventional three-phase electric generator, the single-phase output power is only slightly more than a third of the total three-phase output power, and the nominal output power cannot be reached. The following known patents provide a solution to the problem:

Document 1: JP 2010-206904, and [0004] Document 2: patent application No. 201210154043.6.

In the reversing electric generator proposed by Document 1, an inverter control circuit is described, and the three-phase alternating current or the single-phase alternating current is delivered selectively by operating three groups of single-phase reversing circuits of the reversing electric generator.

In the reversing electric generator proposed by Document 2, it is proposed to improve an operating mode in phase synchronization and an output switching method of the three groups of single-phase reversing circuits of the Document 1.

In the reversing electric generators proposed in the above documents, the output of the inverter requires single-phase / three-phase switching performed by a control circuit and a switch. When they are switched to single-phase, the three groups of inverters produce a parallel output. When they are switched to three-phase, the three groups of inverters produce a phase distribution output by data communication. The solutions presented in the two documents above have the following drawbacks: whether one adopts a single-phase parallel output or a three-phase output, it is necessary to achieve mutual communication and cooperation between the various functional modules to obtain operation with synchronization precise phase, in order to avoid energy consumption between the inverters caused by poor synchronization. In this case, each inverter must be switched between the single-phase operating mode and the three-phase operating mode. As a result, the design of the system is complicated, and reliability is further reduced. In addition, there are too many control circuits for the entire reversing electric generator in the solutions of the documents presented above, which increases the difficulty of designing the entire machine.

In order to solve to a certain extent the problems of the prior art, the present invention provides an inverter for an electric generator and an electric inversion generator.

In order to achieve the above objects, the present invention adopts the following technical solution.

The inverter for an electric generator comprises: a first voltage rectification and stabilization circuit, configured to receive an input from a first winding of an electric generator; a first full-bridge DC-AC conversion circuit, electrically connected to the first voltage rectification and stabilization circuit, a single-phase output terminal, electrically connected to a voltage output end of the first bridge-AC conversion circuit complete; a state switch, configured to switch the operation of single-phase and three-phase electrical outputs; a first control unit, electrically connected respectively to the state switch, to the first voltage rectification and stabilization circuit and to the first AC-to-full-circuit conversion circuit; a quadruple relay having a control terminal, four first working contacts A1, A2, A3 and A4, and four second working contacts B1, B2, B3 and B4; wherein, when the quadruple relay is in a first operating state, the first four working contacts are closed, and the second four working contacts are disconnected; when the quadruple relay is in a second operating state, the first four working contacts are disconnected, and the second four working contacts are closed; and the control terminal of the quadruple relay is electrically connected to the first control unit; a second voltage rectification and stabilization circuit, configured to receive an input from a second winding of an electric generator; a second continuous-alternative conversion circuit into a full bridge; in which two output terminals of the second rectification and voltage stabilization circuit are electrically connected to two input terminals of the second continuous-alternating conversion circuit in full bridge by the first working contacts A1 and A2 of the quadruple relay, and the two output terminals of the second rectification and voltage stabilization circuit are electrically connected to two input terminals of the first DC-AC conversion circuit to full bridge by the second working contacts B1 and B2 of the quadruple relay; a first phase detection circuit, electrically connected to the circuit between the first continuous-alternative conversion circuit to full bridge and the single-phase output terminal; a second control unit, electrically connected respectively to the first phase detection circuit, to the second voltage rectification and stabilization circuit, and to the second DC-AC conversion circuit into full bridge; a third voltage rectification and stabilization circuit, configured to receive an input from a third winding of an electric generator; a third DC-AC to full bridge conversion circuit; in which two output terminals of the third voltage rectification and stabilization circuit are electrically connected to two input terminals of the third DC-AC conversion circuit in full bridge by the first working contacts A3 and A4 of the quadruple relay, and the two output terminals of the third rectification and voltage stabilization circuit are electrically connected to two input terminals of the first DC-AC conversion circuit to full bridge by the second working contacts B3 and B4 of the quadruple relay; a second phase detection circuit, electrically connected to the circuit between the first full-bridge DC-AC conversion circuit and the single-phase output terminal; a third control unit, electrically connected respectively to the second phase detection circuit, to the third voltage rectification and stabilization circuit, and to the third DC-AC conversion circuit into full bridge; and a three-phase output terminal, in which the neutral output ends of the first full-circuit DC-to-AC conversion circuit, of the second full-board DC-to-AC conversion circuit and of the third full-board DC-to-AC conversion circuit them to form a neutral three-phase point; and the phase line output ends of the first full-bridge DC-AC conversion circuit, the second full-bridge DC-AC conversion circuit and the third full-bridge DC-AC conversion circuit are electrically connected to three terminals phase line output of the three-phase output terminal respectively in one-to-one correspondence.

Furthermore, the inverter for an electric generator further comprises: a starting circuit, configured to deliver a starting voltage to the first winding of an electric generator; and a DC back-up circuit, configured to receive input from a battery voltage; wherein the DC backup circuit is electrically connected to the starting circuit; and the backup DC circuit and the starting circuit are electrically connected to the first control unit, respectively.

Furthermore, the inverter for an electric generator further comprises: a first filter placed on an output line of the first DC-AC conversion circuit into full bridge, the first filter being electrically connected to the first control unit; a second filter placed on an output line of the second DC-AC conversion circuit in full bridge, the second filter being connected electrically to the second control unit; and a third filter placed on an output line of the third DC-AC conversion circuit in full bridge, the third filter being electrically connected to the third control unit.

In addition, the first control unit detects an operating state of the state switch.

When the state switch is in a three-phase electrical output state, the first control unit controls the quadruple relay to put it in the first operating state, and the first control unit configures an output power of the first DC-AC conversion circuit to full bridge so that it is equal to one third of a nominal output power of the electric generator.

The first phase detection circuit detects an output of the first DC-AC conversion circuit into full bridge. When the first continuous-alternative conversion circuit to full bridge delivers a voltage, the first phase detection circuit obtains a reference phase and transmits it to the second control unit to trigger the second control unit to detect a bus voltage of the second DC-AC conversion circuit into a full bridge. When the DC bus voltage is within the limit of a defined range, the second control unit configures an output power of the second continuous-alternative conversion circuit in full bridge so that it is equal to one third of the power nominal output of the electric generator, and the second control unit configures the phase of an output voltage of the second continuous-alternative conversion circuit in full bridge so that it forms an angle of 120 degrees relative to the reference phase .

The second phase detection circuit detects an output of the first continuous-alternative conversion circuit into a full bridge. When the first continuous-alternative conversion circuit to full bridge delivers a voltage, the second phase detection circuit obtains a reference phase and transmits it to the third control unit to trigger the third control unit to detect a bus voltage of the third continuous-alternative conversion circuit into a full bridge. When the DC bus voltage is within the limit of a defined range, the third control unit configures an output power of the third continuous-alternative conversion circuit to full bridge so that it is equal to one third of the power nominal output of the electric generator, and the third control unit configures the phase of an output voltage of the third continuous-alternative conversion circuit in full bridge so that it forms an angle of 240 degrees relative to the reference phase .

Furthermore, the first control unit interacts with the first continuous-altemative full-circuit conversion circuit to carry out an output control cycle in order to control the output voltage and the output power of the first continuous conversion circuit. -alternative in full bridge.

The second control unit interacts with the second full-bridge DC-AC conversion circuit to perform an output control cycle in order to control the output voltage and the output power of the second DC-AC conversion circuit. full bridge, and to adjust the phase of the output voltage of the second DC-AC conversion circuit to full bridge so that the phase of the output voltage of the second DC-AC conversion circuit to full bridge forms an angle of 120 degrees compared to the reference phase.

The third control unit interacts with the third full-bridge DC-AC conversion circuit to perform an output control cycle to control the output voltage and the output power of the third DC-AC conversion circuit. full bridge, and to adjust the phase of the output voltage of the third DC-AC conversion circuit to full bridge so that the phase of the output voltage of the third DC-AC conversion circuit to full bridge forms an angle of 240 degrees compared to the reference phase.

In addition, the first control unit detects an operating state of the state switch.

When the state switch is in a single-phase electrical output state, the first control unit controls the quadruple relay to put it in a second operating state, and the first control unit configures an output power of the first continuous-alternating conversion circuit to full bridge so that it is equal to a nominal output power of the electric generator.

The first phase detection circuit detects an output from the first DC-to-full-circuit conversion circuit. When the first DC-AC conversion circuit to full bridge delivers a voltage, the first phase detection circuit obtains a reference phase and transmits it to the second control unit to trigger the second control unit to detect a bus voltage of the second DC-AC conversion circuit into a full bridge. When the DC bus voltage is zero, the second control unit does not perform an output control.

When the first DC-AC conversion circuit to full bridge delivers a voltage, the second phase detection circuit obtains a reference phase and transmits it to the third control unit to trigger the third control unit to detect a DC bus voltage from the third DC-AC conversion circuit to full bridge. When the DC bus voltage is zero, the third control unit does not perform an output control.

The inverting electric generator comprises an electric generator provided with a first electric generator winding, a second electric generator winding, and a third electric generator winding.

The reversing electric generator further includes the inverter for electric generator described above.

The first winding of an electric generator is electrically connected to the first rectification and voltage stabilization circuit of the inverter for an electric generator. The second electric generator winding is electrically connected to the second rectifier and voltage stabilization circuit of the inverter for electric generator. The third winding of an electric generator is electrically connected to the third rectification and voltage stabilization circuit of the inverter for an electric generator.

Furthermore, the reversing electric generator further comprises: a motor, the motor and the electric generator being arranged coaxially.

Furthermore, the reversing electric generator further comprises a battery.

The inverter for an electric generator further includes: a starting circuit and a backup DC circuit.

The battery is electrically connected to the DC backup circuit.

The DC backup circuit is electrically connected to the starting circuit.

The starting circuit is electrically connected to the first winding of the electric generator.

The backup DC circuit and the starting circuit are electrically connected to the first control unit, respectively.

Furthermore, the reversing electric generator further comprises an output panel, the state switch being placed on the output panel.

The output panel is further provided with a three-phase socket and a single-phase socket. The single-phase output terminal is electrically connected to the single-phase outlet, and the three-phase output terminal is electrically connected to the three-phase outlet.

The present invention adopts the technical solution presented above, and has at least the following beneficial effects.

According to the inverter for electric generator and the electric reversing generator applying the inverter for electric generator proposed by the present invention, the switching of the state switch is directly associated with the switching actions which control a quadruple relay. , each control unit operates independently, a fixed operating mode is formed without forming mutual interference, and the switching of the output between the single-phase full power output and the three-phase full power output is performed. The present invention avoids the use of complex system control and facilitates communication with the control unit, so that product reliability is improved.

It is understood that the above general description and the following detailed description are given simply by way of example and by way of explanation, without limiting the present invention.

In order to clarify the technical solutions of the embodiments of the present invention or of the prior art, the appended drawings required in the description of the embodiments or of the prior art will be briefly presented. It is obvious that the appended drawings described are only embodiments of the present invention. People with ordinary knowledge of the trade can obtain all the other drawings without inventive work, according to these appended drawings.

[Fig.l] is a block diagram of an embodiment of an inverter for an electric generator of the present invention during a single-phase electrical output.

[Fig.2] is a block diagram of an embodiment of an inverter for an electric generator of the present invention during a three-phase electrical output.

[Fig.3] is a block diagram of another embodiment of an inverter for an electric generator of the present invention during a single-phase electrical output.

[Fig.4] is a block diagram of an electric reversing generator to which the inverter for electric generator of the present invention is applied.

[Fig.5] is a flow diagram of a first control unit of the present invention.

[Fig.6] is a flow diagram of a second control unit and a third control unit of the present invention.

In the figures, the following reference numbers represent the following elements: 1-inverter for electric generator; 2-electric generator; 3-motor; 4-battery; 5-output board; 101-first voltage rectification and stabilization circuit; 102-first DC-AC conversion circuit to full bridge; 103-single phase output terminal; 104-state switch; 105-first control unit; 106-quadruple relay; 107-second rectification and voltage stabilization circuit; 108-second DC-AC conversion circuit to full bridge; 109-first phase detection circuit; 110-second control unit; 111-third rectification and voltage stabilization circuit;

112-third DC-AC conversion circuit to full bridge; 113-second phase detection circuit; 114-third control unit; 115-three-phase output terminal; 116 starting circuit; 117-DC backup circuit; 118-first filter; 119-second filter; 120-third filter; 201-first winding of electric generator; 202-second winding of electric generator; 203-third winding of electric generator; 501-three-phase socket; 501-single-phase socket.

In order to clarify the objects, technical solutions and advantages of the present invention, the technical solutions of the present invention will be presented in detail. It is obvious that the embodiments described are only a part of the embodiments of the present invention. Based on the embodiments presented here, people with ordinary knowledge of the trade can obtain all the other embodiments, without inventive work, which must be within the scope of the present invention.

The embodiments of the present invention provide an inverter for an electric generator and an electric inversion generator. The present invention is illustrated in detail in association with the accompanying drawings below.

As shown in Figures 1 and 2, in one embodiment of the present invention, the present invention provides an inverter 1 for an electric generator, comprising: a first rectification and voltage stabilization circuit 101, configured to receive an input of a first winding of an electric generator 201; a first full-bridge DC-AC conversion circuit 102, electrically connected to the first voltage rectification and stabilization circuit 101, a single-phase output terminal 103 electrically connected to a voltage output end of the first DC-AC conversion circuit in full bridge 102; a state switch 104 configured to switch the operation of the single-phase and three-phase electrical outputs; a first control unit 105 electrically connected respectively to the state switch 104, to the first voltage rectification and stabilization circuit 101 and to the first full-bridge DC-AC conversion circuit 102; a quadruple relay 106 having a control terminal, four first working contacts A1, A2, A3 and A4, and four second working contacts B1, B2, B3 and B4; wherein, when the quadruple relay 106 is in a first operating state, the first four working contacts are closed, and the second four working contacts are disconnected; when the quadruple relay 106 is in a second operating state, the first four working contacts are disconnected, and the second four working contacts are closed; the control terminal of the quadruple relay 106 is electrically connected to the first control unit 105; a second voltage rectification and stabilization circuit 107, configured to receive an input from a second winding of electric generator 202; a second DC-to-full-circuit conversion circuit 108; in which two output terminals of the second rectification and voltage stabilization circuit 107 are electrically connected to two input terminals of the second full-circuit DC-AC conversion circuit 108 by the first working contacts A1 and A2 of the quadruple relay 106, and the two output terminals of the second rectification and voltage stabilization circuit 107 are electrically connected to two input terminals of the first full-circuit DC-AC conversion circuit 102 by the second working contacts B1 and B2 of the quadruple relay 106; a first phase detection circuit 109, electrically connected to the circuit between the first full-bridge DC-AC conversion circuit 102 and the single-phase output terminal 103; a second control unit 110, electrically connected respectively to the first phase detection circuit 109, to the second voltage rectification and stabilization circuit 107, and to the second DC-AC conversion circuit to full bridge 108; a third voltage rectification and stabilization circuit 111, configured to receive an input from a third winding of electric generator 203; a third DC-to-full bridge conversion circuit 112; in which two output terminals of the third rectification and voltage stabilization circuit 111 are electrically connected to two input terminals of the third DC-to-full-circuit conversion circuit 112 by the first working contacts A3 and A4 of the quadruple relay 106, and the two output terminals of the third rectification and voltage stabilization circuit 111 are electrically connected to two input terminals of the first DC-AC conversion circuit to full bridge 102 by the second working contacts B3 and B4 of the quadruple relay 106; a second phase detection circuit 113, electrically connected to the circuit between the first full-bridge DC-AC conversion circuit 102 and the single-phase output terminal 103; a third control unit 114, electrically connected respectively to the second phase detection circuit 113, to the third voltage rectification and stabilization circuit 111, and to the third DC-to-full-bridge conversion circuit 112; and a three-phase output terminal 115, in which the neutral output ends of the first full-bridge DC-AC conversion circuit 102, the second full-bridge DC-AC conversion circuit 108 and the third DC-AC conversion circuit into complete bridge 112 are connected together to form a neutral three-phase point; and the phase line output ends of the first full-bridge DC-AC conversion circuit 102, the second full-bridge DC-AC conversion circuit 108 and the third full-bridge DC-AC conversion circuit 112 are electrically connected to three phase line output terminals of the three-phase output terminal 115 respectively in one-to-one correspondence. An explanation of specific implementation is given concerning the operation of the solution of the inverter 1 for electric generator 1 in association with FIGS. 1 and 2.

In an example of an application, the state switch 104 is configured for the switching operation of single-phase and three-phase electrical outputs. For example, when an on / off switch is chosen as state switch 104, the state of the on / off switch is turned on or off. By a user operation, a status signal from the single-phase electrical output or the three-phase electrical output is transmitted back to the first control unit 105.

The first control unit 105 detects an operating state of the state switch 104.

When the state switch 104 is in a three-phase electrical output state, as shown in Figures 1, 5 and 6, the first control unit 105 controls the quadruple relay 106 to put it in the first state of operation, and the first control unit 105 configures an output power of the first full-circuit DC-AC conversion circuit 102 so that it is equal to one third of a nominal output power of the electric generator.

The first phase detection circuit 109 detects an output of the first DC-AC conversion circuit to full bridge 102. When the first DC-AC conversion circuit to full bridge 102 delivers a voltage, the first detection circuit of phase 109 obtains a reference phase and transmits it to the second control unit 110 to trigger the second control unit 110 to detect a DC bus voltage from the second DC-AC conversion circuit to full bridge 108. When the bus voltage is within the limit of a defined range, the second control unit 110 configures an output power of the second DC-AC conversion circuit into full bridge 108 so that it is equal to one third of the nominal output power of the electric generator, and the second control unit 110 configures the phase of an output voltage of the second conversion circuit cont inu-alternative in full bridge so that it forms an angle of 120 degrees with respect to the reference phase.

The second phase detection circuit 113 detects an output of the first DC-AC conversion circuit to full bridge 102. When the first DC-AC conversion circuit to full bridge 102 delivers a voltage, the second detection circuit of phase 113 obtains a reference phase and transmits it to the third control unit 114 to trigger the third control unit 114 to detect a DC bus voltage from the third AC to full bridge conversion circuit 112. When the DC bus voltage found within the limit of a defined range, the third control unit 114 configures an output power of the third full-circuit DC-AC conversion circuit 112 so that it is equal to one third of the nominal output power of the generator electric, and the third control unit 114 configures the phase of an output voltage of the third conveying circuit full-bridge continuous-alternating connection 112 so that it forms an angle of 240 degrees relative to the reference phase.

Thanks to the example of implementation above, the three-phase alternating current whose three phases differ from each other by 120 degrees is formed.

The first control unit 105 detects an operating state of the state switch 104.

When the state switch 104 is in a single-phase electrical output state, as shown in Figures 2, 5 and 6, the first control unit 105 controls the quadruple relay 106 to put it in a second state of operation, and the first control unit 105 configures an output power of the first full-circuit DC-AC conversion circuit 102 so that it is equal to a nominal output power of the electric generator.

The first phase detection circuit 109 detects an output from the first continuous-altemative full circuit conversion circuit 102.

When the first DC-AC conversion circuit to full bridge 102 delivers a voltage, the first phase detection circuit 109 obtains a reference phase and transmits it to the second control unit 110 to trigger the second control unit 110 for detecting a DC bus voltage from the second DC-AC conversion circuit to full bridge 108. When the DC bus voltage is zero, the second control unit 110 does not carry out output control.

When the first DC-to-full-circuit conversion circuit 108 delivers a voltage, the second phase detection circuit 113 obtains a reference phase and transmits it to the third control unit 114 to trigger the third control unit 114 for detecting a DC bus voltage from the third DC-AC conversion circuit to full bridge 112. When the DC bus voltage is zero, the third control unit 114 does not perform an output control.

Thanks to the illustration of the example of implementation above, the outputs of the first voltage rectification and stabilization circuit 101, of the second voltage rectification and stabilization circuit 107 and of the third rectification circuit and of voltage stabilization 111 converge mutually. The single-phase current is delivered by the first continuous-alternative conversion circuit into a full bridge 102.

With illustration of examples of implementation of the solution presented above, according to the inverter 1 for an electric generator of the present invention, the switching of the state switch 104 is directly associated with the switching actions which control quadruple relay 106. Each control unit operates independently. A fixed operating mode is formed without forming mutual interference, and the switching of the output between the full-power single-phase output and the full-power three-phase output is performed. The reliability of the product is improved. The difficulty of designing the reversing electric generator is greatly reduced while the cost is reduced. Consequently, the following disadvantages of the solutions presented in the two documents mentioned in the background of the present application can be overcome: mutual communication and cooperation between the respective functional modules are necessary to obtain operation with synchronization of precise phase, to avoid energy consumption between inverters caused by poor synchronization. Each inverter must be switched between the single-phase operating mode and the three-phase operating mode. As a result, system design is complicated, and reliability can be further reduced. In addition, there are more control circuits for the entire reversing electric generator in the solutions of the documents presented above, which increases the design difficulty of the whole machine.

In the present invention, the respective functional circuits and the respective functional units can come from related technologies. For example, the first control unit 105, the second control unit 110 and the third control unit 114 can adopt a technology of single-chip microcomputer, programmable integrated circuit (FPGA), pin matrix package (PGA) ), etc. Quadruple relay 106 can be a relay in which the first four working contacts are normally closed contacts, and correspondingly, the second four working contacts are normally open contacts, or in which the first four working contacts are normally open contacts, and correspondingly, the second four working contacts are normally closed contacts.

As shown in Figure 3, in one embodiment of the present invention, the inverter 1 for electric generator further comprises: a starting circuit 116, configured to deliver a starting voltage to the first winding of electric generator 201; and a DC backup circuit 117, configured to receive input from a battery voltage.

The DC backup circuit 117 is electrically connected to the starting circuit 116.

The DC backup circuit 117 and the starting circuit 116 are electrically connected respectively to the first control unit 105.

Conventionally, when the engine drives the electric generator to produce electricity, starting the engine includes an electric start and a manual start. The above solution of the present invention can be applied to the electric start motor. Thanks to the starting circuit 116, using an external DC voltage assistance, the first winding of the electric generator 201 can be supplied to generate an electromagnetic torque intended to drive the rotor of an electric generator with permanent magnet . The motor and the electric generator being arranged coaxially, the motor takes an initial speed, then it gradually enters the operating state.

As shown in Figures 1, 2 and 3, in one embodiment of the present invention, the inverter 1 for an electric generator further comprises: a first filter 118 placed on an output line of the first conversion circuit continuous-alternating in full bridge 102, the first filter 118 being electrically connected to the first control unit 102; a second filter 119, placed on an output line of the second DC-AC conversion circuit to full bridge 108, the second filter 119 being electrically connected to the second control unit 108; and a third filter 120 placed on an output line of the third full-bridge DC-AC conversion circuit 112, the third filter 120 being electrically connected to the third control unit 112.

With the above solution, each DC-AC conversion circuit in full bridge is provided with a corresponding respective filter, which makes it possible to filter the harmonics on the AC current delivered by each DC-conversion circuit. full bridge AC, to eliminate a harmful influence on the AC current delivered.

As shown in Figures 5 and 6, in one embodiment of the present invention, in the case where the present invention is applied to the three-phase electrical output, the first control unit 105 interacts with the first conversion circuit full-bridge DC-AC 102 to perform an output control cycle to control the output voltage and output power of the first full-bridge DC-AC conversion circuit 102.

The second control unit 110 interacts with the second full-bridge DC-AC conversion circuit 108 to perform an output control cycle in order to control the output voltage and the output power of the second continuous conversion circuit. to full bridge 108, and to adjust the phase of the output voltage of the second DC-AC conversion circuit to full bridge 108 so that the phase of the output voltage of the second DC-AC conversion circuit to full bridge 108 forms an angle of 120 degrees from the reference phase.

The third control unit 114 interacts with the third full-bridge DC-AC conversion circuit 112 to carry out an output control cycle in order to control the output voltage and the output power of the third DC conversion circuit. to full bridge 112, and to adjust the phase of the output voltage of the third DC-AC conversion circuit to full bridge 112 so that the phase of the output voltage of the third DC-AC conversion circuit to full bridge 112 forms an angle of 240 degrees from the reference phase.

With the above solution, thanks to the interaction between each control unit and the corresponding DC-AC conversion circuit to full bridge, the output control cycle is carried out, thus ensuring the stability of the output. single-phase electrical or three-phase electrical output.

As shown in Figure 4, the present invention provides an embodiment of the inverting electric generator. With reference to FIG. 4, the reversing electric generator comprises an electric generator 2. The electric generator comprises a first winding of electric generator 201, a second winding of electric generator 202, and a third winding of electric generator 203.

The inverting electric generator further comprises the inverter 1 for an electric generator shown in FIG. 1.

The first electric generator winding 201 is electrically connected to the first voltage rectification and stabilization circuit 101 of the inverter 1 for an electric generator. The second winding of electric generator 202 is electrically connected to the second voltage rectification and stabilization circuit 107 of the inverter 1 for electric generator. The third winding of electric generator 203 is electrically connected to the third voltage rectification and stabilization circuit 111 of the inverter 1 for electric generator.

Regarding the device of the above embodiment, the specific mode of operation of each unit has been described in detail in the embodiments concerned set out above, and will not be explained in detail here.

In a specific application of the present invention, the electric generator 2 can employ an electric generator with a permanent magnet.

As shown in Figure 4, in one embodiment of the present invention, the reversing electric generator further comprises a motor 3, and the motor 3 and the electric generator 2 are arranged coaxially.

As shown in FIGS. 3 and 4, in an embodiment of the present invention, the electric reversing generator further comprises a battery 4.

The inverter 1 for an electric generator further comprises a starting circuit

116 and a DC backup circuit 117.

The battery 4 is electrically connected to the DC backup circuit 117.

The DC backup circuit 117 is electrically connected to the starting circuit 116.

The starting circuit 116 is electrically connected to the first winding of the electric generator 201.

The DC backup circuit 117 and the starting circuit 116 are electrically connected respectively to the first control unit 105.

With this solution, the electric generator according to the present invention can be applied to the electric start engine. The respective functional units of the present invention can be integrated into a processing module, or respective units physically exist separately, or two or more units are integrated into a single module. For example, as shown in FIG. 3, the start-up circuit 116 and the first voltage rectification and stabilization circuit 101 are integrated in a module.

As shown in Figure 4, in one embodiment of the present invention, the reversing electric generator further comprises an output panel 5. The state switch 4 is placed on the output panel 105.

The output panel 5 is further provided with a three-phase outlet 501 and a single-phase outlet 502. The single-phase outlet terminal 103 is electrically connected to the single-phase outlet 502, and the three-phase outlet terminal 115 is connected electrically to the three-phase socket 501.

In a specific application, the ON / OFF state of the state switch

104 can represent respectively and correspondingly two states of full-power single-phase output and full-power three-phase output. No selection switch is placed between the output of inverter 1 for electric generator and the switchboard. When the status switch 104 on the output panel 5 is in a three-phase output position, the three-phase output of the inverter 1 for electric generator is effective, and the total three-phase output power is the nominal power of the electric generator inversion. Furthermore, since the single-phase output terminal 103 and a phase of the three-phase output of the inverter are connected, the single-phase socket 502 can also deliver a single-phase voltage, but the output power of this is worth a third of the nominal power of the reversing electric generator. When the status switch 104 on the output panel 5 is in a single-phase output position, the three-phase output of the inverter 1 for electric generator is not effective, and the maximum output power of the single-phase output socket is equal to the nominal power of the electric generator.

It is understood that identical or similar parts in the respective embodiments above can be designated, and the content not described in detail in certain embodiments can relate to identical or similar content of other embodiments.

Note that in the description of the present invention, the terms "first", "second", etc. are used for description purposes only, and should not be considered to indicate or imply materiality. Furthermore, in the description of the present invention, the expression "a plurality of" means at least two, unless otherwise stated.

Any description of process or process in the flowcharts or otherwise described herein must be understood as representing the module, segment or part of a code which includes one or more executable instruction (s) for setting implements the steps of a particular logical function or a particular process. The scope of the preferred embodiments of the present invention includes additional implementations, and the functions can be performed substantially simultaneously or in reverse order, rather than in the order shown or described, depending on the functions involved, this which must be understood by those skilled in the art to which the embodiments of the present invention belong.

It is understood that the respective parts of the present invention may be implemented in the form of hardware, software, firmware, or one of their combinations. In the above embodiments, several steps or methods can be implemented in software or firmware stored in a memory and executed by an appropriate instruction execution system. For example, in the case of hardware implementation, as is the case in another embodiment, they can be implemented by any one or a combination of the following well known technologies: a discrete logic circuit comprising a logic gate circuit for implementing a logic function on data signals, an integrated circuit developed for a customer comprising an appropriate combinational logic gate circuit, a pin matrix housing (PGA), a programmable pre-broadcast integrated circuit (LPGA ), etc.

A person with ordinary knowledge of the trade can understand that all or part of the steps involved in the process implementing the above embodiments can be completed by a program intended to send instructions to associated equipment, and this program can be stored on a computer storage medium. When the program is executed, a step or a combination of the steps of the embodiments of the method is included.

In addition, the respective functional units in the respective embodiments of the present invention can be integrated into a single processing module, or each unit can exist physically and separately, or else two or more units can be integrated into a single module. These integrated modules can be implemented in the form of hardware or in the form of software functional modules. If implemented in the form of software functional modules and sold or used as independent products, the integrated modules can also be stored on a computer storage medium.

The above storage medium can be a read-only memory, a magnetic disc, an optical disc or other similar element.

In the description of the present invention, the description referring to the expressions "an embodiment", "embodiments", "example", "specific example" or "examples" and similar expressions means that the specific parts, structures, materials or features described in conjunction with the embodiment or example are included in at least one embodiment or example of the present invention. In the present description, the schematic representation of the above terms does not necessarily mean that it is the same embodiment or example. In addition, the specific parts, structures, materials or features described can be suitably combined in any one or more of the embodiments or examples.

[0099] Although embodiments of the present invention have been shown and described in the foregoing, it is understood that these embodiments are illustrative and should not be understood as limiting the present invention. Persons with ordinary knowledge of the trade can make variations, modifications, substitutions and variants to the above embodiments while remaining within the scope of the present invention.

Claims (1)

claims Inverter (1) for an electric generator, comprising: a first voltage rectification and stabilization circuit (101), configured to receive an input from a first winding of an electric generator (201); a first DC-to-full-circuit conversion circuit (102), electrically connected to the first voltage rectification and stabilization circuit; a single phase output terminal (103) electrically connected to a voltage output end of the first AC to full bridge conversion circuit; a state switch (104) configured to switch the operation of single-phase and three-phase electrical outputs; a first control unit (105) electrically connected respectively to the state switch, to the first voltage rectification and stabilization circuit and to the first AC to full bridge conversion circuit; a quadruple relay (106) having a control terminal, four first working contacts A1, A2, A3 and A4, and four second working contacts B1, B2, B3 and B4; in which : when the quadruple relay is in a first operating state, the first four working contacts are closed, and the second four working contacts are disconnected; when the quadruple relay is in a second operating state, the first four working contacts are disconnected, and the second four working contacts are closed; and the control terminal of the quadruple relay is electrically connected to the first control unit; a second voltage rectification and stabilization circuit (107), configured to receive an input from a second winding of an electric generator (202); a second DC-to-full bridge conversion circuit (108); in which : two output terminals of the second rectification and voltage stabilization circuit (107) are electrically connected to two input terminals of the second DC-to-full-circuit conversion circuit (108) by the first working contacts A1 and A2 of the quadruple relay, and the two output terminals of the second voltage rectification and stabilization circuit (107) are electrically connected to two input terminals of the first DC-AC conversion circuit to full bridge (102) by the second contacts of work B1 and B2 of the quadruple relay; a first phase detection circuit (109), electrically connected to the circuit between the first continuous-alternative conversion circuit into a full bridge and the single-phase output terminal; a second control unit (110), electrically connected respectively to the first phase detection circuit, to the second voltage rectification and stabilization circuit, and to the second DC-AC conversion circuit into full bridge; a third voltage rectification and stabilization circuit (111), configured to receive an input from a third winding of an electric generator (203); a third DC-to-full bridge conversion circuit (112); in which : two output terminals of the third rectification and voltage stabilization circuit are electrically connected to two input terminals of the third DC-AC conversion circuit in full bridge by the first working contacts A3 and A4 of the quadruple relay, and the two output terminals of the third rectification and voltage stabilization circuit are electrically connected to two input terminals of the first DC-AC conversion circuit to full bridge by the second working contacts B3 and B4 of the quadruple relay; a second phase detection circuit (113), electrically connected to the circuit between the first DC-AC conversion circuit to full bridge and the single-phase output terminal; a third control unit (114), electrically connected respectively to the second phase detection circuit, to the third voltage rectification and stabilization circuit, and to the third DC-AC conversion circuit to full bridge; and a three-phase output terminal (115), in which: the neutral output ends of the first continuous-alternative conversion circuit to full bridge, of the second conversion circuit [Claim 2] [Claim 3] [Claim 4] continuous-alternating to full bridge and of the third continuous-alternating conversion circuit to complete bridge are connected together to form a neutral three-phase point; and the phase line output ends of the first full-bridge DC-AC conversion circuit, the second full-bridge DC-AC conversion circuit and the third full-bridge DC-AC conversion circuit are electrically connected to three terminals phase line output of the three-phase output terminal respectively in one-to-one correspondence. An inverter for an electric generator according to claim 1, wherein the inverter for an electric generator further comprises: a starting circuit (116), configured to supply a starting voltage to the first winding of an electric generator; and a DC backup circuit (117), configured to receive input of a battery voltage; in which: the backup DC circuit is electrically connected to the starting circuit; and the backup DC circuit and the starting circuit are electrically connected to the first control unit, respectively. An inverter for an electric generator according to claim 1 or 2, wherein the inverter for an electric generator further comprises: a first filter (118) placed on an output line of the first DC-AC conversion circuit to full bridge, the first filter being electrically connected to the first control unit; a second filter (119), placed on an output line of the second DC-AC conversion circuit in full bridge, the second filter being electrically connected to the second control unit; and a third filter (120) placed on an output line of the third DC-AC conversion circuit in full bridge, the third filter being electrically connected to the third control unit. The inverter for an electric generator according to claim 1 or 2, wherein the first control unit detects an operating state of the state switch; when the state switch is in a three-phase electrical output state, the first control unit (105) controls the quadruple relay to put it in the first operating state, and the first [Claim 5] control unit configures a output power of the first continuous-alternative conversion circuit to full bridge so that it is equal to one third of a nominal output power of the electric generator; the first phase detection circuit detects an output of the first continuous-alternative conversion circuit into a full bridge; when the first DC-AC conversion circuit to full bridge delivers a voltage, the first phase detection circuit obtains a reference phase and transmits it to the second control unit to trigger the second control unit to detect a bus voltage DC from the second DC-AC conversion circuit to full bridge; when the DC bus voltage is within the limit of a defined range, the second control unit configures an output power of the second continuous-alternative conversion circuit in full bridge so that it is equal to one third of the power nominal output of the electric generator, and the second control unit configures the phase of an output voltage of the second DC-AC conversion circuit in full bridge so that it forms an angle of 120 degrees relative to the reference phase ; and the second phase detection circuit detects an output of the first full-bridge to DC conversion circuit; when the first DC-AC conversion circuit to full bridge delivers a voltage, the second phase detection circuit obtains a reference phase and transmits it to the third control unit to trigger the third control unit to detect a bus voltage continuous of the third continuous-alternative conversion circuit into full bridge; when the DC bus voltage is within the limit of a defined range, the third control unit configures an output power of the third DC-AC conversion circuit in full bridge so that it is equal to one third of the power nominal output of the electric generator, and the third control unit configures the phase of an output voltage of the third DC-AC conversion circuit in full bridge so that it forms an angle of 240 degrees relative to the reference phase . An inverter for an electric generator according to claim 4, in which: the first control unit interacts with the first full-bridge DC-AC conversion circuit to perform an output control cycle to control the output voltage and the [Claim 6] output power of the first DC-AC conversion circuit in full deck; the second control unit interacts with the second DC-AC conversion circuit to complete bridge to carry out an output control cycle in order to control the output voltage and the output power of the second DC-AC conversion circuit to full bridge, and to adjust the phase of the output voltage of the second full-circuit DC-AC conversion circuit so that the phase of the output voltage of the second full-bridge DC-AC conversion circuit forms an angle of 120 degrees relative to the reference phase; and the third control unit interacts with the third full-bridge DC-AC conversion circuit to perform an output control cycle to control the output voltage and output power of the third full-bridge DC-AC conversion circuit , and to adjust the phase of the output voltage of the third DC-AC conversion circuit to full bridge so that the phase of the output voltage of the third DC-AC conversion circuit to full bridge forms an angle of 240 degrees relative to at the reference phase. An inverter for an electric generator according to claim 1 or 2, in which: the first control unit (105) detects an operating state of the state switch; when the state switch is in a single phase electrical output state, the first control unit (105) controls the quadruple relay to put it in a second operating state, and the first control unit configures an output power of the first DC-AC conversion circuit to full bridge so that it is equal to a nominal output power of the electric generator; the first phase detection circuit detects an output of the first full-bridge DC-AC conversion circuit, when the first full-bridge DC-AC conversion circuit supplies a voltage, the first phase detection circuit obtains a reference phase and transmits it to the second control unit to trigger the second control unit (110) to detect a DC bus voltage of the second conversion circuit [Claim 7] [Claim 8] [Claim 9] DC-AC to full bridge, and when the DC bus voltage is zero, the second control unit does not perform an output control; and when the first DC-AC conversion circuit to full bridge delivers a voltage, the second phase detection circuit obtains a reference phase and transmits it to the third control unit (114) to trigger the third control unit to detect a DC bus voltage from the third DC-AC conversion circuit to full bridge, and when the DC bus voltage is zero, the third control unit does not perform an output control. An inverting electric generator, comprising an electric generator provided with a first electric generator winding (201), a second electric generator winding (202), and a third electric generator winding (203); wherein the reversing electric generator further comprises the inverter (1) for electric generator according to claim 1; the first electric generator winding is electrically connected to the first rectifier and voltage stabilization circuit of the inverter for electric generator, the second electric generator winding is electrically connected to the second rectifier and voltage stabilization circuit of the inverter for electric generator, and the third winding of electric generator is electrically connected to the third rectification and voltage stabilization circuit of the inverter for electric generator. The reverse electric generator of claim 7, wherein the reverse electric generator further comprises: a motor, the motor and the electric generator being arranged coaxially. The reverse electric generator according to claim 7, wherein the reverse electric generator further comprises a battery (4); the inverter for an electric generator further comprises: a starting circuit (116) and a backup DC circuit (117); the battery is electrically connected to the DC backup circuit; the backup DC circuit is electrically connected to the starting circuit; the starting circuit is electrically connected to the first en24 [Claim 10] electric generator bearing; and the backup DC circuit and the starting circuit are electrically connected to the first control unit, respectively. A reversing electric generator according to any of claims 7 to 9, wherein the reversing electric generator further comprises an output panel (5), wherein the state switch is placed on the output panel; and the output panel is further provided with a three-phase socket (501) and a single-phase socket (502), the single-phase output terminal (103) is electrically connected to the single-phase socket, and the three-phase output terminal ( 115) is electrically connected to the three-phase socket.