CN217655773U - Novel electrode capacitance and power module - Google Patents

Abstract

A novel electrode capacitor comprising: the capacitor comprises a first capacitor bus, a second capacitor bus, a capacitor group, a first capacitor leading-out electrode main body, a first capacitor leading-out electrode connecting part, a second capacitor leading-out electrode main body and a second capacitor leading-out electrode connecting part; the capacitor group is arranged between the first capacitor bus bar and the second capacitor bus bar, and the first capacitor leading-out electrode main body is led out from the first capacitor bus bar and extends towards the direction of the second capacitor bus bar; the second capacitor leading-out electrode main body is led out of the second capacitor bus bar and extends towards the first capacitor bus bar; the first capacitor extraction electrode main body and the second capacitor extraction electrode main body are arranged in a laminated manner; the first capacitor leading-out electrode connecting part is led out from the first capacitor leading-out electrode main body and extends towards the direction far away from the capacitor group; the second capacitor lead-out electrode connecting portion is led out from the second capacitor lead-out electrode main body and extends in a direction away from the capacitor bank. The structure of the capacitor module can be simplified, the volume is reduced, and the parasitic inductance of the whole power module is reduced.

Description

Novel electrode capacitance and power module

Technical Field

The utility model relates to a power electronics field, concretely relates to novel electrode capacitance and power module.

Background

The power module is a power switch module formed by combining and packaging power electronic power devices such as metal oxide semiconductors (power MOS transistors), insulated gate field effect transistors (IGBT) and Fast Recovery Diodes (FRD) according to certain functions, and is mainly used for power conversion of electric vehicles, wind power generation, industrial frequency conversion and other occasions.

A motor driving circuit of an electric vehicle generally includes three groups of power modules having upper and lower arms, respectively, and fig. 1 is a circuit diagram of a conventional power module, which shows a circuit diagram of a group of power modules having upper and lower arms, and includes: the bridge-type power module comprises an insulated gate type field effect transistor Z1 serving as an upper bridge arm, a fast recovery diode D1 in reverse parallel connection with the insulated gate type field effect transistor Z1, an insulated gate type field effect transistor Z2 serving as a lower bridge arm and a fast recovery diode D2 in reverse parallel connection with the insulated gate type field effect transistor Z2, wherein a collector electrode of the insulated gate type field effect transistor Z1 is connected with an anode p + of the power module, an emitter electrode of the insulated gate type field effect transistor Z2 is connected with a collector electrode of the edge gate type field effect transistor Z2, and an emitter electrode of the insulated gate type field effect transistor Z1 and the collector electrode of the insulated gate type field effect transistor Z2 are commonly connected with an output terminal of the power module. In practical applications, three sets of the power modules are generally used to provide three-phase alternating current for the motor; the operation principle of the power module is illustrated by the circuit schematic diagram of only one group of power modules: when the insulated gate type field effect transistor Z1 is switched on, current is sequentially OUTPUT to the motor through the positive electrode p + of the power module, the collector electrode and the emitter electrode of the insulated gate type field effect transistor Z1 and the OUTPUT terminal OUTPUT of the power module; when the insulated gate field effect transistor Z1 is turned off, since the motor is an inductive load, to ensure that the current flow direction is unchanged, the follow current needs to be OUTPUT to the motor through the other groups of power modules via the negative electrode p-of the power module, the diode D2, and the power module OUTPUT terminal OUTPUT.

In some practical applications, the electronic device in the power module may also adopt a power MOS transistor, and fig. 2 is a schematic circuit diagram of another power MOS transistor module, which includes: the power MOS tube M1 as an upper bridge arm and the power MOS tube M2 as a lower bridge arm are connected, wherein the drain electrode of the power MOS tube M1 is connected with the positive electrode p + of a power module, the source electrode of the power MOS tube M1 is connected with the drain electrode of the power MOS tube M2, the source electrode of the power MOS tube M2 is connected with the negative electrode p-of the power module, the source electrode of the power MOS tube M1 and the drain electrode of the power MOS tube M2 are connected with the output terminal of the power module together, the working principle of the power module is similar to that of a module adopting an insulated gate field effect transistor, and the difference between the power module and the module is mainly that a reverse diode is arranged in the power MOS tube, so that the parallel connection of the reverse diodes is not needed. In addition, the reverse conducting type IGBT has the same structure and function as the power MOS, and because a diode is built in, a reverse parallel diode is not required, and the module design and structure are similar to those of the power MOS, and are not described herein again.

In practical applications, the parasitic inductance has been a major problem to be overcome in power electronic device applications, especially in high-frequency and high-power applications of power MOS transistors. Parasitic inductance inside the module can cause overvoltage in the turn-off process, and the parasitic inductance can cause voltage spike and waveform oscillation in the switching process of the power module, so that electromagnetic interference and switching loss are increased, and even the module is damaged.

Disclosure of Invention

The utility model discloses a solve the problem that exists among the prior art, provide a novel electrode electric capacity, include: the capacitor comprises a first capacitor bus, a second capacitor bus, a capacitor group, a first capacitor leading-out electrode main body, a first capacitor leading-out electrode connecting part, a third capacitor leading-out electrode connecting part, a second capacitor leading-out electrode main body, a second capacitor leading-out electrode connecting part and a fourth capacitor leading-out electrode connecting part; the capacitor group is arranged between the first capacitor bus bar and the second capacitor bus bar, and the first capacitor leading-out electrode main body is flaky, is led out from the end part of the first capacitor bus bar and extends towards the direction of the second capacitor bus bar; the second capacitor leading-out electrode main body is flaky, is led out from the end part of the second capacitor bus bar and extends towards the direction of the first capacitor bus bar; the first capacitor extraction electrode main body and the second capacitor extraction electrode main body are arranged in a laminated and separated mode; the first capacitor leading-out electrode connecting part is led out from the end part of the first capacitor leading-out electrode main body close to the second capacitor bus bar and extends towards the direction far away from the capacitor bank; the second capacitor leading-out electrode connecting part is led out from the second capacitor leading-out electrode main body, crosses the first capacitor leading-out electrode main body and extends in the direction away from the capacitor bank, and the first capacitor leading-out electrode connecting part and the second capacitor leading-out electrode connecting part are adjacently arranged side by side.

Further, an insulating layer is arranged between the first capacitor lead-out electrode main body and the second capacitor lead-out electrode main body.

Further, an insulating layer is provided between the second capacitor extraction electrode connecting portion and the first capacitor extraction electrode main body.

Further, the second capacitor lead-out electrode connecting portion is formed by punching and bending the second capacitor lead-out electrode main body according to a predetermined shape.

Furthermore, a single first capacitor leading-out electrode connecting part and a single second capacitor leading-out electrode connecting part which are adjacently arranged side by side form a capacitor leading-out electrode connecting group, and the number of the capacitor leading-out electrode connecting groups is three.

Furthermore, the third capacitor leading-out electrode connecting part is led out from one side of the first capacitor leading-out electrode main body and extends towards the direction far away from the capacitor bank, the fourth capacitor leading-out electrode connecting part is led out from one side of the second capacitor leading-out electrode main body and extends towards the direction far away from the capacitor bank, and the third capacitor leading-out electrode connecting part and the fourth capacitor leading-out electrode connecting part are adjacently arranged side by side.

Furthermore, the first capacitor leading-out electrode connecting part and the second capacitor leading-out electrode connecting part are both provided with nuts used for being connected with an external power module.

The utility model also provides a power module, including the novel electrode electric capacity that provides among the above-mentioned technical scheme, power module includes first power electrode, second power electrode, and electrode connecting portion fixed connection is drawn forth with first electric capacity to first power electrode, and electrode connecting portion fixed connection is drawn forth with second electric capacity to second power electrode.

Furthermore, the number of the power modules is three, and the first power electrode and the second power electrode of each power module are fixedly connected with the corresponding capacitor extraction electrode connection group. The parasitic inductance of the whole power module can be effectively reduced.

Drawings

Fig. 1 is a schematic circuit diagram of a conventional power module;

FIG. 2 is a circuit schematic of another prior art power module;

fig. 3 is a three-dimensional structure diagram of a novel electrode capacitor provided by the present invention;

fig. 4 is a partial structural view of a novel electrode capacitor provided by the present invention;

fig. 5 is a partial structural view of a novel electrode capacitor provided by the present invention;

fig. 6 is a partial structural view of a novel electrode capacitor provided by the present invention;

fig. 7 is a structural diagram of a power module according to the present invention.

Detailed Description

The embodiments of the present invention will be described in detail below with reference to the drawings, and it should be understood that the specific embodiments described herein are merely illustrative of the present invention and are not intended to limit the present invention.

A novel electrode capacitor as provided in fig. 3 and 4, comprising: the capacitor comprises a first capacitor bus bar 10, a second capacitor bus bar 20, a capacitor group 30, a first capacitor leading-out electrode main body 11, a first capacitor leading-out electrode connecting part 12, a third capacitor leading-out electrode connecting part 13, a second capacitor leading-out electrode main body 21, a second capacitor leading-out electrode connecting part 22 and a fourth capacitor leading-out electrode connecting part 23; the capacitor group 30 is arranged between the first capacitor bus bar 10 and the second capacitor bus bar 20, and the first capacitor leading-out electrode main body 11 is flaky, is led out from the end part of the first capacitor bus bar 10 and extends towards the direction of the second capacitor bus bar 20; the second capacitor leading-out electrode main body 21 is in a sheet shape, is led out from the end part of the second capacitor bus bar 20 and extends towards the direction of the first capacitor bus bar 10; the first capacitance extraction electrode main body 11 and the second capacitance extraction electrode main body 21 are arranged in a laminated and separated mode; the first capacitor leading-out electrode connecting part 12 is led out from the end part of the first capacitor leading-out electrode main body 11 close to the second capacitor busbar 20 and extends towards the direction far away from the capacitor group 30; the second capacitor leading-out electrode connecting portion 22 is led out from the second capacitor leading-out electrode main body 21, crosses over the first capacitor leading-out electrode main body 11, and extends in a direction away from the capacitor bank 30, specifically, in practical application, the second capacitor leading-out electrode connecting portion 22 can cross over from one side of the first capacitor leading-out electrode main body 11, and can cross over from the first capacitor leading-out electrode main body 11 according to practical requirements, it is required to ensure that the second capacitor leading-out electrode connecting portion 22 and the first capacitor leading-out electrode main body 11 are mutually insulated, and the first capacitor leading-out electrode connecting portion 12 and the second capacitor leading-out electrode connecting portion 22 are adjacently arranged side by side.

Specifically, as a further improvement of the above technical solution, an insulating layer is disposed between the first capacitor leading electrode main body 11 and the second capacitor leading electrode main body 21 to enhance the stability of mutual insulation between the first capacitor leading electrode main body 11 and the second capacitor leading electrode main body 21.

Specifically, as a further improvement of the above technical solution, an insulating layer is disposed between the second capacitor leading electrode connecting portion 22 and the first capacitor leading electrode main body 11, so as to enhance the stability of mutual insulation between the second capacitor leading electrode connecting portion 22 and the first capacitor leading electrode main body 11.

Specifically, as a further improvement of the above technical solution, as shown in fig. 5, the second capacitor leading electrode connecting portion 22 is formed by pressing and bending the second capacitor leading electrode main body 21 in a predetermined shape. The purposes of simplifying the processing technology, simplifying the structure, reducing the volume and saving materials are achieved.

Specifically, as a further improvement of the above technical solution, as shown in fig. 3 and 7, a single first capacitor extraction electrode connection portion 12 and a single second capacitor extraction electrode connection portion 22, which are adjacently arranged side by side, constitute a capacitor extraction electrode connection group, and there are three capacitor extraction electrode connection groups; specifically, in practical application, the number of the capacitor leading-out electrode connection groups is not limited to three, and one or more capacitor leading-out electrode connection groups can be freely arranged according to actual requirements.

Specifically, as a further improvement of the above-described technical solution, as shown in fig. 3 to 5, the third capacitor leading electrode connecting portion 13 is led out from one side of the first capacitor leading electrode main body 11 and extends in a direction away from the capacitor group 30, the fourth capacitor leading electrode connecting portion 23 is led out from one side of the second capacitor leading electrode main body 21 and extends in a direction away from the capacitor group 30, and the third capacitor leading electrode connecting portion 13 and the fourth capacitor leading electrode connecting portion 23 are disposed adjacent to each other and in parallel.

Specifically, as a further improvement of the above technical solution, as shown in fig. 3, the first capacitor lead-out electrode connecting portion 12 and the second capacitor lead-out electrode connecting portion 22 are each provided with a nut for connecting with an external power module.

Specifically, as the further application of above-mentioned technical scheme, as shown in fig. 7, the utility model provides a power module still, including novel electrode electric capacity 100, the power module 200 that provide among the above-mentioned technical scheme, the power module includes first power electrode 201, second power electrode 202, and first power electrode 201 draws electrode connecting portion 12 fixed connection, second power electrode 202 and second electric capacity and draws electrode connecting portion 22 fixed connection.

Specifically, the number of the power modules 200 is three, and the first power electrode 201 and the second power electrode 202 of each power module are fixedly connected to the corresponding capacitor leading-out electrode connection group. The parasitic inductance of the whole power module can be effectively reduced; specifically, in practical applications, the number of the power modules 200 is not limited to three, and one or more power modules may be freely arranged corresponding to the capacitor extraction electrode connection group according to actual requirements.

The above only is the preferred embodiment of the present invention, not limiting the scope of the present invention, all the equivalent structures or equivalent flow changes made by the contents of the specification and the drawings, or directly or indirectly applied to other related technical fields, are included in the same way in the protection scope of the present invention.

Claims (9)

1. A novel electrode capacitor, comprising: the capacitor comprises a first capacitor bus, a second capacitor bus, a capacitor group, a first capacitor leading-out electrode main body, a first capacitor leading-out electrode connecting part, a third capacitor leading-out electrode connecting part, a second capacitor leading-out electrode main body, a second capacitor leading-out electrode connecting part and a fourth capacitor leading-out electrode connecting part; the capacitor group is arranged between the first capacitor bus bar and the second capacitor bus bar, and the first capacitor leading-out electrode main body is flaky, is led out from the end part of the first capacitor bus bar and extends towards the direction of the second capacitor bus bar; the second capacitor leading-out electrode main body is flaky, is led out from the end part of the second capacitor bus bar and extends towards the first capacitor bus bar; the first capacitor extraction electrode main body and the second capacitor extraction electrode main body are arranged in a laminated and separated mode; the first capacitor leading-out electrode connecting part is led out from the end part of the first capacitor leading-out electrode main body close to the second capacitor busbar and extends towards the direction far away from the capacitor bank; the second capacitor leading-out electrode connecting part is led out from the second capacitor leading-out electrode main body, crosses the first capacitor leading-out electrode main body and extends in the direction away from the capacitor bank, and the first capacitor leading-out electrode connecting part and the second capacitor leading-out electrode connecting part are adjacently arranged side by side.

2. The novel electrode capacitor as claimed in claim 1, wherein: an insulating layer is arranged between the first capacitor extraction electrode main body and the second capacitor extraction electrode main body.

3. The novel electrode capacitor of claim 1, wherein: an insulating layer is arranged between the second capacitor leading-out electrode connecting part and the first capacitor leading-out electrode main body.

4. The novel electrode capacitor as claimed in claim 1, wherein: the second capacitor extraction electrode connecting part is formed by punching and bending the second capacitor extraction electrode main body according to a preset shape.

5. The novel electrode capacitor of claim 1, wherein: and the three capacitor leading-out electrode connecting groups are formed by a single first capacitor leading-out electrode connecting part and a single second capacitor leading-out electrode connecting part which are adjacently arranged side by side.

6. The novel electrode capacitor of claim 1, wherein: the third capacitor leading-out electrode connecting part is led out from one side of the first capacitor leading-out electrode main body and extends towards the direction far away from the capacitor bank, the fourth capacitor leading-out electrode connecting part is led out from one side of the second capacitor leading-out electrode main body and extends towards the direction far away from the capacitor bank, and the third capacitor leading-out electrode connecting part and the fourth capacitor leading-out electrode connecting part are adjacently arranged side by side.

7. The novel electrode capacitor as claimed in claim 1, wherein: and the first capacitor leading-out electrode connecting part and the second capacitor leading-out electrode connecting part are both provided with nuts used for being connected with an external power module.

8. A power module, comprising the novel electrode capacitor and power module as claimed in any one of claims 1 to 7, wherein the power module comprises a first power electrode and a second power electrode, the first power electrode is fixedly connected with the first capacitor leading-out electrode connecting part, and the second power electrode is fixedly connected with the second capacitor leading-out electrode connecting part.

9. The power module of claim 8, wherein the number of the power modules is three, and the first power electrode and the second power electrode of each power module are fixedly connected to the corresponding capacitor extraction electrode connection set.

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