CN218041202U - Controllable filter circuit and power converter - Google Patents

Abstract

The application discloses a controllable filter circuit and a power converter, and achieves the purpose of power-on buffering. The controllable filter circuit comprises a filter capacitor E and an electrifying buffer circuit 1, and the filter capacitor E is connected with the electrifying buffer circuit 1 in series; the power-on buffer circuit 1 comprises a bypass switch S and a current-limiting resistor R, wherein the bypass switch S is connected with the current-limiting resistor R in parallel.

Description

Controllable filter circuit and power converter

Technical Field

The utility model relates to a power electronic technology field, more specifically say, relate to a controllable filter circuit and power converter.

Background

The power converter usually uses a filter capacitor to filter out the alternating current component contained in the direct current, but because the filter capacitor is free of charge and voltage before the power converter is electrified, the filter capacitor can generate a large charging current at the moment of electrification, and the safe and stable operation of the system is threatened.

Taking the circuit structure of the power converter for rectifying and filtering the grid voltage as an example, the above contents are exemplified: as shown in fig. 1, the rectifier bridge is used to convert the input ac power into dc power, but the output voltage of the rectifier bridge contains ac components, so a filter capacitor E needs to be connected in parallel to the output end of the rectifier bridge to filter out the ac components; since the filter capacitor E is free of charge and voltage before power-on, a large impact current is generated on the filter capacitor E at the moment of power-on.

SUMMERY OF THE UTILITY MODEL

In view of this, the present invention provides a controllable filter circuit and a power converter to achieve the purpose of power-on buffering.

A controllable filter circuit, wherein:

the controllable filter circuit comprises a filter capacitor E and a power-on buffer circuit 1, and the filter capacitor E is connected with the power-on buffer circuit 1 in series;

the power-on buffer circuit 1 comprises a bypass switch S and a current-limiting resistor R, wherein the bypass switch S is connected with the current-limiting resistor R in parallel.

In one embodiment, the filter capacitor E is a separate capacitor element; alternatively, the filter capacitor E is a series combination, a parallel combination, or a series-parallel combination of a plurality of capacitor elements.

In one embodiment, the filter capacitor E includes a first capacitive element E1 and a second capacitive element E2, and the first capacitive element E1 is connected in series or in parallel with the second capacitive element E2.

In one embodiment, when the first capacitive element E1 is connected in series with the second capacitive element E2, the controllable filter circuit further comprises: the capacitor comprises a first voltage-sharing resistor R1 and a second voltage-sharing resistor R2, wherein the first voltage-sharing resistor R1 is connected with a first capacitor element E1 in parallel, and the second voltage-sharing resistor R2 is connected with a second capacitor element E2 in parallel.

In one embodiment, the bypass switch S is a bidirectional controllable electronic switch or a contact switch.

In one embodiment, the bidirectional controllable electronic switch is a triac, wherein: one end of the bidirectional controllable silicon is used as one end of the bidirectional controllable electronic switch, and the other end of the bidirectional controllable silicon is used as the other end of the bidirectional controllable electronic switch;

or, the bidirectional controllable electronic switch comprises a full-bridge rectification circuit and a switching tube Q7, wherein: the full-bridge rectification circuit comprises a first diode D1, a second diode D2, a third diode D3 and a fourth diode D4, the electric energy input end of a switch tube Q7 is electrically connected with the cathode of the first diode D1 and the cathode of the second diode D2, the electric energy output end of the switch tube Q7 is electrically connected with the anode of the third diode D3 and the anode of the fourth diode D4, the anode of the second diode D2 is electrically connected with the cathode of the fourth diode D4 and then serves as one end of the bidirectional controllable electronic switch, and the anode of the first diode D1 is electrically connected with the cathode of the third diode D3 and then serves as the other end of the bidirectional controllable electronic switch;

or, the bidirectional controllable electronic switch includes a first switch tube Q8 and a second switch tube Q9, an electric energy output end of the first switch tube Q8 is electrically connected with an electric energy output end of the second switch tube Q9, an electric energy input end of the first switch tube Q8 serves as one end of the bidirectional controllable electronic switch, and an electric energy input end of the second switch tube Q9 serves as the other end of the bidirectional controllable electronic switch.

A power converter comprising a main circuit and a control unit, the main circuit comprising any one of the controllable filter circuits as disclosed above; the controllable filter circuit can be electrically connected with a direct current power supply; the output end of the control unit is at least electrically connected with the control end of a bypass switch of the controllable filter circuit;

the control unit is used for keeping the bypass switch disconnected before the controllable filter circuit is connected to the direct-current power supply; and when the state duration of the controllable filter circuit connected to the direct current power supply exceeds a first time, controlling the bypass switch to be conducted.

In one embodiment, the main circuit further comprises a rectifier bridge, and the rectifier bridge is the direct current power supply; the main circuit also comprises an inverter bridge;

one end of the controllable filter circuit is electrically connected with the high-potential output end of the rectifier bridge, the other end of the controllable filter circuit is electrically connected with the low-potential output end of the rectifier bridge, and the input end of the inverter bridge is electrically connected with the output end of the rectifier bridge; the output end of the control unit is also electrically connected with the control end of the inverter bridge and is used for controlling the inverter bridge to work; the inverter bridge can be electrically connected with the input end of the air-conditioning compressor and is used for controlling the air-conditioning compressor to work.

Or, the main circuit further comprises: an inverter bridge; the controllable filter circuit is connected in parallel with the output end of the direct current power supply, and the input end of the inverter bridge is electrically connected with the output end of the direct current power supply.

Or the main circuit comprises a controllable filter circuit and a switching power supply;

the controllable filter circuit is connected in parallel with the output end of the direct current power supply, and the input end of the switching power supply is electrically connected with the output end of the direct current power supply; the output end of the switching power supply is electrically connected with a load circuit or a load.

According to the technical scheme, the utility model provides a controllable filter circuit or power converter keeps bypass switch S to break off at the last electric moment, and direct current output voltage is whole applyed on current-limiting resistor R and begin to charge to filter capacitor E in the twinkling of an eye at this moment, and filter capacitor E goes up the voltage and risees gradually, and filter capacitor E charging current is restricted in the safety range by current-limiting resistor R; after the filter capacitor E basically finishes charging or is fully charged, the bypass switch S is closed to bypass the current-limiting resistor R, and the charging current of the filter capacitor E is still in a safe range after the current-limiting resistor R is bypassed because the filter capacitor E has voltage, so that the purpose of power-on buffering is realized.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to these drawings without creative efforts.

Fig. 1 is a schematic circuit diagram of a prior art circuit for rectifying and filtering a grid voltage;

fig. 2 is a schematic diagram of a controllable filter circuit according to an embodiment of the present invention;

FIG. 3 is a schematic diagram illustrating the charging current flow path of the filter capacitor when the bypass switch is turned off in the embodiment shown in FIG. 2;

fig. 4 is a schematic diagram of another controllable filter circuit disclosed in the embodiment of the present invention;

fig. 5 is a schematic diagram of another controllable filter circuit disclosed in the embodiment of the present invention;

FIG. 6 is a schematic diagram of the controllable filter circuit of FIG. 4 using a triac as a bypass switch;

FIG. 7 is a schematic diagram of the controllable filter circuit with a combination of a full-bridge rectifier circuit and a switch tube as a bypass switch;

FIG. 8 is a schematic diagram of a controllable filter circuit employing a combination of two switching tubes as a bypass switch;

FIG. 9 is a schematic diagram of a power-on buffer circuit connected in series with each of any two-phase AC inputs;

fig. 10 is a schematic diagram of a power converter disclosed in an embodiment of the present invention, and particularly a schematic diagram of a three-phase power supply frequency converter circuit adopting the scheme shown in fig. 5;

fig. 11 is a schematic diagram of another power converter disclosed in an embodiment of the present invention;

fig. 12 is a schematic diagram of another power converter according to an embodiment of the present invention.

Detailed Description

For reference and clarity, the terms, abbreviations or abbreviations used hereinafter are summarized as follows:

MCU: micro Control Unit, micro Control Unit;

PTC: positive Temperature Coefficient, positive Temperature Coefficient;

MOSFET: metal-Oxide-Semiconductor Field-Effect Transistor (MOSFET);

IGBT: an Insulated Gate Bipolar Transistor.

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

As shown in fig. 1, the rectifier bridge is used to convert the input ac power into dc power, but the output voltage of the rectifier bridge contains ac components, so a filter capacitor E needs to be connected in parallel to the output end of the rectifier bridge to filter out the ac components; because the filter capacitor E is free of charge and voltage before power-on, larger impact current can be generated on the filter capacitor E at the power-on moment, and the impact current is theoretically very large, so that not only can a power grid be greatly impacted or tripped, but also a rectifier bridge can be possibly damaged, and a fuse wire or a circuit connection can be mistakenly broken. Based on this, referring to fig. 2, the embodiment of the present invention discloses a controllable filter circuit, wherein:

the controllable filter circuit comprises a filter capacitor E and an electrifying buffer circuit 1, and the filter capacitor E is connected with the electrifying buffer circuit 1 in series;

the power-on buffer circuit 1 comprises a bypass switch S and a current-limiting resistor R, wherein the bypass switch S is connected with the current-limiting resistor R in parallel.

In practical use, the controllable filter circuit is mounted at a certain path of direct-current voltage output end in the power converter, and can be connected to an external voltage source output end, wherein the output end has higher voltage and larger voltage ripple, and a filter capacitor is required to be mounted for filtering; the voltage ripple herein may refer to both an output voltage ripple at the dc voltage output terminal and an input voltage ripple caused by the influence of the load on the dc voltage. The specific output end of the direct-current voltage output end of the circuit needs to be determined according to the circuit structure of the power converter. For example, when the power converter includes a circuit structure for rectifying and filtering the power grid voltage (the direct current output after rectifying and filtering the power grid voltage can be used as a direct current power supply for medium and high power electric appliances such as a variable frequency air conditioner, an electric vehicle charger, a high frequency electric welding machine, an electrolytic plating power supply, a communication power supply, etc.), the controllable filter circuit can be connected in parallel with the output end of the rectifier bridge (i.e., one end, i.e., a high potential end, of the controllable filter circuit is electrically connected with a high potential output end DC + of the rectifier bridge, and the other end, i.e., a low potential end, of the controllable filter circuit is electrically connected with a low potential output end DC-of the rectifier bridge), and the output voltage after the rectifier bridge is often high in voltage and large in voltage ripple. For another example, the controllable filter circuit can also be applied to the direct-current power output occasions where high-voltage storage batteries such as electric vehicles and the like supply the motor frequency converter; for high power loads, the output voltage of the required battery is high and the load may cause input voltage ripple.

The embodiment of the utility model provides a through for filter capacitor E establish ties one go up electric buffer circuit 1 after again parallelly connected access power converter inside a certain DC voltage output of the same kind, this output end voltage is higher, voltage ripple is great, has realized going up the electric buffering purpose, and its theory of operation is as follows:

before power-on, the bypass switch S is kept in a disconnected state, which is equivalent to that the filter capacitor E is connected in series with the current-limiting resistor R and then connected to the direct-current voltage output end of the circuit in parallel, and no charge or voltage exists on the filter capacitor E. In a short time after power-on, such as the first time, the off-state of the bypass switch S is maintained, and almost all of the dc output voltage is instantaneously applied to the current-limiting resistor R and the filter capacitor E and starts to charge the filter capacitor E (the path through which the filter capacitor E charges the current is shown by the dashed line with an arrow in fig. 3); in the first time, along with the accumulation of the charging time, the charge on the filter capacitor E is gradually increased, the voltage on the filter capacitor E is gradually increased, and the voltage on the current-limiting resistor R is gradually reduced; the filter capacitor E charging circuit is buffered by the current limiting resistor R, so that no great charging current is generated, namely the filter capacitor E charging current is limited in a safety range by the current limiting resistor R. After the power is on and the first time is passed, the filter capacitor E is fully charged or basically fully charged, at the moment, the bypass switch S is closed to bypass the current-limiting resistor R, the current-limiting resistor R is bypassed, and then the filter capacitor E is directly connected in parallel with the direct-current voltage output end, but because the voltage is existed on the filter capacitor E at the moment, the charging current of the filter capacitor E is still in a safe range, thereby realizing the purpose of power-on buffering. After the purpose of power-on buffering is achieved, the rear-stage circuit can be started to work, and the current-limiting resistor R is bypassed, so that extra power loss cannot be generated in the working process of the rear-stage circuit. The bypass switch S is a bidirectional controllable switch, the switching state of which is controlled by a control unit, e.g. an MCU. The first time can be in the second level, the specific duration is related to the direct-current voltage, the size of the filter capacitor and the resistance value of the current-limiting resistor, and the direct-current voltage can basically finish or finish charging the filter capacitor only within the first time duration.

To sum up, the embodiment of the present invention keeps the bypass switch S off at the moment of power-on, and at this moment, the dc output voltage is almost completely applied to the current-limiting resistor R and starts to charge the filter capacitor E; in the first time, the voltage on the filter capacitor E is gradually increased, and the charging current of the filter capacitor E is limited in a safety range by the current limiting resistor R. The bypass switch S is closed to bypass the current-limiting resistor R after the first time or the capacitor E to be filtered is fully charged, and the charging current of the filter capacitor E after the current-limiting resistor R is bypassed is still in a safe range due to the voltage on the filter capacitor E at the moment, so that the purpose of power-on buffering is achieved. And after the first time or the filter capacitor E is fully charged, the average voltage on the filter capacitor E is kept in a relatively stable range, and the charge and the discharge charge are kept relatively balanced in the filtering process, namely, the current flowing through the bypass switch S is only the alternating current ripple current component of the capacitor E but not all the current on the main circuit, so that the requirement on the type selection of the bypass switch S can be reduced, and the cost can be further reduced.

In any of the embodiments disclosed above, the filter capacitor E may be an independent capacitor element, or may be a series combination, a parallel combination, or a series-parallel combination of a plurality of capacitor elements. In fig. 2, the filter capacitor E is merely an example of a series combination of two capacitor elements E1 and E2, and for example, when three-phase AC380V supply rectification is performed, two electrolytic capacitors having a withstand voltage of about 400V may be selected to operate in series. Fig. 4 only exemplifies a parallel combination of two capacitor elements E1 and E2 as a filter capacitor E, and for example, when single-phase AC220V power supply is rectified and a dc bus voltage required by a subsequent circuit is 300 volts, two electrolytic capacitors with withstand voltages of 400 to 450V may be selected to operate in parallel.

When the filter capacitor E is a series combination or a series-parallel combination of a plurality of capacitor elements, a voltage-sharing resistor may be further disposed on the filter capacitor E. For example, as shown in fig. 5, the filter capacitor E is a series combination of two capacitor elements E1 and E2, a voltage-sharing resistor R1 is connected in parallel to the capacitor element E1, and a voltage-sharing resistor R2 is connected in parallel to the capacitor element E2. The voltage-sharing resistor is used for realizing the voltage equality of each capacitor element connected in series, thereby avoiding overvoltage damage of the capacitor elements caused by the fact that voltages on the individual capacitor elements bear overhigh voltages.

In any of the embodiments disclosed above, the current limiting resistor R may be a single resistor element, or may be a series combination, a parallel combination, or a series-parallel combination of a plurality of resistor elements. Fig. 2 to 5 illustrate the current limiting resistor R as a single resistor element. In addition, the current limiting resistor R is preferably of a type using a power resistor or a PTC resistor, but is not limited thereto.

In any of the above disclosed embodiments, the bypass switch S may be a bidirectional controllable electronic switch or a contact switch, etc., without limitation. The contact switch is, for example, a relay.

The bidirectional controllable electronic switch is, for example, a bidirectional thyristor, as shown in fig. 6: one end of the bidirectional controllable silicon is used as one end of the bidirectional controllable electronic switch, and the other end of the bidirectional controllable silicon is used as the other end of the bidirectional controllable electronic switch.

Alternatively, the bidirectional controllable electronic switch can also be obtained by combining a full-bridge rectification circuit with a switching tube Q7, for example, as shown in fig. 7: the full-bridge rectification circuit comprises a first diode D1, a second diode D2, a third diode D3 and a fourth diode D4, the electric energy input end of a switch tube Q7 is electrically connected with the cathode of the first diode D1 and the cathode of the second diode D2, the electric energy output end of the switch tube Q7 is electrically connected with the anode of the third diode D3 and the anode of the fourth diode D4, the anode of the second diode D2 is electrically connected with the cathode of the fourth diode D4 and then serves as one end of the bidirectional controllable electronic switch, and the anode of the first diode D1 is electrically connected with the cathode of the third diode D3 and then serves as the other end of the bidirectional controllable electronic switch; fig. 7 is a diagram showing that the unidirectional switching tube Q7 is switched on and off bidirectionally by the full-bridge rectification circuit; when the switching tube Q7 is switched on, the bypass switch S is switched on; when the switching tube Q7 is turned off, the bypass switch S is turned off.

Alternatively, the bidirectional controllable electronic switch may also be a series combination of a first switching tube Q8 and a second switching tube Q9, for example, as shown in fig. 8: the electric energy output end of the first switching tube Q8 is electrically connected with the electric energy output end of the second switching tube Q9, the electric energy input end of the first switching tube Q8 is used as one end of the bidirectional controllable electronic switch, and the electric energy input end of the second switching tube Q9 is used as the other end of the bidirectional controllable electronic switch; when Q8 and Q9 are both switched on, the bypass switch S is switched on; when Q8 and Q9 are both off, the bypass switch S is off.

The switch tube in any of the embodiments disclosed above may be a MOSFET, an IGBT with an anti-parallel diode, or the like, where the anti-parallel diode may be a self-contained IGBT or an external IGBT, and is not limited. When the switch tube is an MOSFET, the electric energy input end of the switch tube is the drain electrode of the MOSFET, and the electric energy output end of the switch tube is the source electrode of the MOSFET; when the switch tube is an IGBT with an anti-parallel diode, the electric energy input end of the switch tube is a collector of the IGBT with the anti-parallel diode, and the electric energy output end of the switch tube is an emitter of the IGBT with the anti-parallel diode.

In any of the embodiments disclosed above, the dc voltage output terminal with higher voltage and larger voltage ripple may be an output terminal of a rectifier bridge, specifically, the rectifier bridge may be a three-phase rectifier bridge or a single-phase rectifier bridge, and the corresponding input power source is a three-phase ac power source or a single-phase ac power source; the dc voltage output terminal may also be an output terminal of a dc power supply, such as an output terminal of a storage battery, a photovoltaic power supply, and the like, without limitation. It should be noted that, when any of the embodiments disclosed above is connected to the output end of the three-phase rectifier bridge, the advantages are more obvious, because the dc component after three-phase rectification is very high, and the charging and discharging current flowing through the filter capacitor is much smaller than the main loop current, so the bypass switch S with the same current capacity can drive a high-power electrical appliance with several times of the main loop current. Of course, when the circuit is applied to a direct current power supply input end, the circuit also has the advantages that: the charging and discharging current flowing through the filter capacitor is much smaller than the main loop current, so the bypass switch S with the same current capacity can drive a high-power electric appliance with the main loop current multiplied by several times.

FIG. 9 is a schematic diagram of a power-up buffer circuit connected in series with each of any two-phase AC inputs. Different from any of the embodiments disclosed above, the power-on buffer circuit in fig. 9 includes a switch K1, a resistor R1, and a switch K2, where the switch K1 is connected in series with the resistor R1 and then connected in parallel with the switch K2, at the power-on instant, K1 is turned on and K2 is turned off, and after the filter capacitor E is fully charged or substantially fully charged, K1 is turned off and K2 is turned on, thereby achieving the purpose of power-on buffering. The power-on buffer circuit in fig. 9 is connected in series to the main circuit, and the current of the main circuit is much larger than the current of the branch of the filter capacitor E, so that compared with the case where any of the above-mentioned embodiments is connected to the output end of the three-phase rectifier bridge, the power-on buffer circuit in fig. 9 has higher requirement on the capacity specification of each device and higher cost. In addition, compared with any of the embodiments disclosed above, when the three-phase rectifier bridge is connected to the output end, the number of the power-on buffer circuits used in fig. 9 is larger, and the circuit structure is also more complex, which further increases the cost. It can be seen that any of the embodiments disclosed above has at least the following advantages over the circuit shown in fig. 9: the power-on buffer circuit is small in quantity, simple in circuit and low in cost.

Furthermore, the embodiment of the utility model provides a power converter is still disclosed, include: a main circuit comprising any one of the controllable filter circuits disclosed above (except for fig. 9) and a control unit (e.g. MCU).

For example, as shown in fig. 10, the main circuit A1 includes a controllable filter circuit and an inverter bridge, the dc power supply A2 includes a rectifier bridge, and the main circuit is electrically connected to an output terminal of the rectifier bridge; specifically, the controllable filter circuit is connected in parallel to the output end of the rectifier bridge, and the input end of the inverter bridge is electrically connected to the output end of the rectifier bridge. The power converter can then act as a three-phase supply frequency converter.

Fig. 10 is a schematic diagram of a three-phase power supply frequency converter adopting the scheme shown in fig. 5. Six IGBTs Q1-Q6 in the figure 10 form a three-phase inverter bridge, and output U, V and W three-phase SPWM or SVPWM to drive a variable frequency alternating current or permanent magnet direct current motor to realize stepless speed regulation. Current sampling and three-phase L1 ~ L3 input AC voltage signal, zero crossing signal, phase place phase sequence signal provide MCU integrated processing together, MCU realizes the intelligent frequency conversion control to bypass switch S and the three half-bridge drive of three-phase inverter bridge, and concrete MCU can be to bypass switch S' S processing procedure: before the controllable filter circuit is connected to the direct current power supply, the bypass switch is kept disconnected; and when the state duration of the controllable filter circuit connected to the direct current power supply exceeds a first time, controlling the bypass switch to be conducted. In this embodiment, the controllable filter circuit is connected to the dc power supply, specifically, the whole power converter is connected to a three-phase input power supply to be powered on, when the power converter is powered on, the rectifier bridge outputs a high voltage with ripples, and the filtering and the power-on buffering can be realized by using the controllable filter circuit. The output end of the inverter bridge can be connected with an air conditioner compressor and used for driving the air conditioner compressor, and the filter capacitor E1 can be a film capacitor with a small capacitance value (relative to an electrolytic capacitor).

Alternatively, as shown in fig. 11, the main circuit includes a controllable filter circuit and an inverter bridge; the main circuit can be electrically connected with a direct current power supply (such as a photovoltaic cell panel, a storage battery, a rectifier bridge and the like); specifically, the controllable filter circuit is connected in parallel to the output end of the dc power supply, and the input end of the inverter bridge is electrically connected to the output end of the dc power supply. At the moment, the controllable filter circuit is used for filtering alternating current components in the input voltage of the inverter bridge.

Alternatively, as shown in fig. 12, the main circuit includes a controllable filter circuit and a switching power supply; the main circuit can be electrically connected with a direct current power supply (such as a photovoltaic cell panel, a storage battery or a rectifier bridge); specifically, the controllable filter circuit is connected in parallel to the output end of the dc power supply, and the input end of the switching power supply is electrically connected to the output end of the dc power supply; the load or load circuit is connected behind the switching power supply. The load circuit may include a load driving circuit, specifically, a motor driving circuit (such as an inverter bridge), an electric vehicle heating circuit, and the like, and is suitable for the fields of air conditioner compressor driving, trolley bus driving, electric vehicle heating technology, electric vehicle driving, and the like. The rear of the switching power supply can also be directly connected with a load, such as a direct current motor and the like, which is not limited in the application. At this time, the power converter is equivalent to a DC/DC transformer additionally provided with a controllable filter circuit for filtering an alternating current component in the input voltage of the switching power supply. When the power converter is used for energy storage power supplies such as storage batteries and the like, the influence of input ripples caused by the fact that an overlong power line (which can generate equivalent inductance) is connected can be compensated, and the stability of the power converter is improved.

In the present specification, the embodiments are described in a progressive manner, each embodiment focuses on differences from other embodiments, and the same and similar parts among the embodiments are referred to each other.

The previous description of the disclosed embodiments is provided to enable any person skilled in the art to make or use the present invention. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the spirit or scope of the embodiments of the invention. Thus, the present embodiments are not intended to be limited to the embodiments shown herein but are to be accorded the widest scope consistent with the principles and novel features disclosed herein.

Claims (10)

1. A controllable filter circuit, comprising:

the controllable filter circuit comprises a filter capacitor (E) and a power-on buffer circuit (1), and the filter capacitor (E) is connected with the power-on buffer circuit (1) in series;

the power-on buffer circuit (1) comprises a bypass switch (S) and a current-limiting resistor (R), wherein the bypass switch (S) is connected with the current-limiting resistor (R) in parallel.

2. Controllable filter circuit according to claim 1, characterized in that the filter capacitor (E) is a separate capacitive element; alternatively, the filter capacitor (E) is a series combination, a parallel combination, or a series-parallel combination of a plurality of capacitive elements.

3. Controllable filter circuit according to claim 2, wherein the filter capacitance (E) comprises a first capacitive element (E1) and a second capacitive element (E2), the first capacitive element (E1) being connected in series or in parallel with the second capacitive element (E2).

4. Controllable filter circuit according to claim 3, characterized in that when the first capacitive element (E1) is connected in series with a second capacitive element (E2), the controllable filter circuit further comprises: the capacitor comprises a first voltage-sharing resistor (R1) and a second voltage-sharing resistor (R2), wherein the first voltage-sharing resistor (R1) is connected with a first capacitor element (E1) in parallel, and the second voltage-sharing resistor (R2) is connected with a second capacitor element (E2) in parallel.

5. Controllable filter circuit according to any of claims 1-4, characterized in that the bypass switch (S) is a bidirectional controllable electronic switch or a contact switch.

6. The controllable filter circuit of claim 5, wherein said bidirectional controllable electronic switch is a triac, wherein: one end of the bidirectional controllable silicon is used as one end of the bidirectional controllable electronic switch, and the other end of the bidirectional controllable silicon is used as the other end of the bidirectional controllable electronic switch;

or, the bidirectional controllable electronic switch comprises a full-bridge rectification circuit and a switching tube (Q7), wherein: the full-bridge rectification circuit comprises a first diode (D1), a second diode (D2), a third diode (D3) and a fourth diode (D4), wherein the electric energy input end of a switch tube (Q7) is electrically connected with the cathode of the first diode (D1) and the cathode of the second diode (D2), the electric energy output end of the switch tube (Q7) is electrically connected with the anode of the third diode (D3) and the anode of the fourth diode (D4), the anode of the second diode (D2) is electrically connected with the cathode of the fourth diode (D4) and then serves as one end of the bidirectional controllable electronic switch, and the anode of the first diode (D1) is electrically connected with the cathode of the third diode (D3) and then serves as the other end of the bidirectional controllable electronic switch;

or, two-way controllable electronic switch includes first switch tube (Q8) and second switch tube (Q9), and the electric energy output of first switch tube (Q8) is connected with the electric energy output of second switch tube (Q9) electricity, and the electric energy input of first switch tube (Q8) is regarded as two-way controllable electronic switch's one end, the electric energy input of second switch tube (Q9) is regarded as two-way controllable electronic switch's the other end.

7. A power converter, characterized by comprising a main circuit and a control unit, the main circuit comprising a controllable filter circuit according to any one of claims 1 to 6; the controllable filter circuit can be electrically connected with a direct current power supply; the output end of the control unit is at least electrically connected with the control end of a bypass switch of the controllable filter circuit;

the control unit is used for keeping the bypass switch disconnected before the controllable filter circuit is connected to the direct-current power supply; and when the state duration of the controllable filter circuit connected to the direct current power supply exceeds a first time, controlling the bypass switch to be conducted.

8. The power converter according to claim 7, wherein the main circuit further comprises a rectifier bridge, the rectifier bridge being the DC power source; the main circuit also comprises an inverter bridge;

one end of the controllable filter circuit is electrically connected with the high-potential output end of the rectifier bridge, the other end of the controllable filter circuit is electrically connected with the low-potential output end of the rectifier bridge, and the input end of the inverter bridge is electrically connected with the output end of the rectifier bridge; the output end of the control unit is also electrically connected with the control end of the inverter bridge and is used for controlling the inverter bridge to work; the inverter bridge can be electrically connected with the input end of the air-conditioning compressor and is used for controlling the air-conditioning compressor to work.

9. The power converter of claim 7, wherein the main circuit further comprises: an inverter bridge; the controllable filter circuit is connected in parallel with the output end of the direct current power supply, and the input end of the inverter bridge is electrically connected with the output end of the direct current power supply.

10. The power converter according to claim 7, wherein the main circuit comprises a controllable filter circuit and a switching power supply;

the controllable filter circuit is connected in parallel with the output end of the direct current power supply, and the input end of the switching power supply is electrically connected with the output end of the direct current power supply; the output end of the switching power supply is electrically connected with a load circuit or a load.

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