阅读说明：本技术 功率模块 (Power module ) 是由 蓝琳 张伟强 张全良 于 2019-10-31 设计创作，主要内容包括：本公开涉及电力电子技术领域,提出了一种功率模块,包括：本体件和设置在本体件内的隔离部件、在本体件内由隔离部件隔开的前后贯穿且堆叠的第一风道和第二风道、高压功率单元、低压功率单元；以及变压器,变压器包括高压部和低压部,高压部包括第一磁芯及设置在第一磁芯上的高压线圈；低压部包括第二磁芯及设置在第二磁芯上的低压线圈；其中,高压功率单元和高压部设置在第一风道内,低压功率单元和低压部设置在第二风道内；并且高压线圈与高压功率单元电连接,低压线圈与低压功率单元电连接。功率模块分成独立的两个风道,避免了各功能模块散热相互串联,有效的提高散热能力和功率模块整体的散热效率继而可以提高功率模块的功率密度。(The present disclosure relates to the field of power electronics, and provides a power module, including: the high-voltage power unit comprises a body piece, a separation part arranged in the body piece, a first air duct and a second air duct which are separated by the separation part in the body piece, penetrate through the front and the back and are stacked, a high-voltage power unit and a low-voltage power unit; the transformer comprises a high-voltage part and a low-voltage part, and the high-voltage part comprises a first magnetic core and a high-voltage coil arranged on the first magnetic core; the low-voltage part comprises a second magnetic core and a low-voltage coil arranged on the second magnetic core; the high-voltage power unit and the high-voltage part are arranged in the first air duct, and the low-voltage power unit and the low-voltage part are arranged in the second air duct; and the high-voltage coil is electrically connected with the high-voltage power unit, and the low-voltage coil is electrically connected with the low-voltage power unit. The power module is divided into two independent air channels, so that the mutual series connection of heat dissipation of the functional modules is avoided, the heat dissipation capability and the overall heat dissipation efficiency of the power module are effectively improved, and the power density of the power module can be improved.)

1. A power module, comprising:

a body member (10) and a spacer member (50) disposed within said body member (10);

a first air duct (11) and a second air duct (12) penetrating and stacked in front and rear directions within the body member (10) partitioned by the partition member (50);

a high voltage power unit (20);

a low voltage power unit (30); and

a transformer (40), the transformer (40) including a high voltage part (41) and a low voltage part (42), the high voltage part (41) including a first core (411) and a high voltage coil (412) provided on the first core (411); the low-voltage part (42) comprises a second magnetic core (421) and a low-voltage coil (422) arranged on the second magnetic core (421);

wherein the high voltage power unit (20) and the high voltage part (41) are arranged in the first air duct (11), and the low voltage power unit (30) and the low voltage part (42) are arranged in the second air duct (12); and the high voltage coil (412) is electrically connected with the high voltage power unit (20), and the low voltage coil (422) is electrically connected with the low voltage power unit (30).

2. The power module according to claim 1, wherein the spacer member (50) is an insulator, the power module further comprising:

and a semiconductive layer (60), wherein the semiconductive layer (60) is provided on both sides of the isolation member (50), and the high-voltage portion (41) and the low-voltage portion (42) are in contact with the semiconductive layer (60) on both sides of the isolation member (50), respectively.

3. A power module according to claim 2, characterized in that the semiconducting layer (60) is arranged at the area where the isolation component (50) is in contact with the first magnetic core (411) and the second magnetic core (421), respectively, on both sides.

4. The power module of claim 1, wherein the transformer (40) includes a main transformer (43) and an auxiliary electrical transformer (44), the high voltage portion (41) includes a main high voltage portion (41-A) and an auxiliary electrical high voltage portion (41-B), the low voltage portion (42) includes a main low voltage portion (42-A) and an auxiliary electrical low voltage portion (42-B),

the main high-voltage part (41-A) and the main low-voltage part (42-A) are high-voltage parts and low-voltage parts of a main transformer (43), the auxiliary electric high-voltage part (41-B) and the auxiliary electric low-voltage part (42-B) are high-voltage parts and low-voltage parts of an auxiliary transformer (44), the main high-voltage part (41-A) and the auxiliary electric high-voltage part (41-B) are electrically connected with the high-voltage power unit (20), and the main low-voltage part (42-A) and the auxiliary electric low-voltage part (42-B) are electrically connected with the low-voltage power unit (30).

5. A power module according to claim 4, characterized in that the main transformer (43) is one or more and the auxiliary transformer (44) is one or more.

6. The power module of claim 1, further comprising:

the fan assembly (70) comprises a fan, and an air inlet and an air outlet of the fan are communicated with the front portion of the first air duct (11) and the front portion of the second air duct (12).

7. The power module of claim 6, wherein the fan comprises:

the air inlet and outlet of the first fan (71) are positioned at the front parts of the first air duct (11) and the second air duct (12), and the air inlet and outlet direction of the first fan (71) is parallel to the length direction of the body piece (10).

8. The power module of claim 7, wherein the fan further comprises:

and the second fan (72) is positioned in front of the first air duct (11) and the second air duct (12), and is arranged side by side with the first fan (71).

9. The power module as claimed in claim 8, wherein the air inlet and outlet of the second fan (72) are disposed obliquely with respect to the air inlet and outlet of the first fan (71) and are inclined toward the front of the first air duct (11) and the second air duct (12).

10. The power module of claim 8, wherein the air inlet and outlet of the second fan (72) are arranged in parallel with the air inlet and outlet of the first fan (71), the fan assembly (70) further comprising:

the air deflector (73) is obliquely arranged relative to the air inlet and the air outlet of the second fan (72), so that air exhausted or sucked from the air inlet and the air outlet of the second fan (72) passes through the air deflector (73) and then flows through the first air channel (11) and the second air channel (12).

11. The power module of claim 6, wherein the fan assembly (70) is disposed on a side of the body member (10) proximate the low voltage power cell (30).

12. The power module of claim 11, wherein the fan assembly (70) is disposed within the body member (10), the power module further comprising:

the first partition plate (80) is arranged on one side, close to the fan assembly (70), in the first air duct (11), and the high-voltage power unit (20) and the high-voltage part (41) are both located on the same side of the first partition plate (80) and located on the other side opposite to the side where the fan assembly (70) is located;

the first partition plate (80) is provided with a first air guide opening communicated with the front part of the first air duct (11).

13. The power module of claim 11, wherein the fan assembly (70) further comprises:

a mounting portion (74), said blower being disposed within said mounting portion (74), said mounting portion (74) being connected to said body member (10);

wherein, the mounting part (74) is provided with a ventilation opening (741) communicated with the first air duct (11) and the second air duct (12).

14. The power module of claim 13, wherein at least a portion of the vent (741) is an opening, the power module further comprising:

a second partition plate (81), the second partition plate (81) being provided on the mounting portion (74) for blocking a portion of the opening;

and a second air guide opening communicated with the front part of the first air duct (11) is formed in the second partition plate (81).

15. The power module according to any one of claims 6 to 14, wherein the first air duct (11) is located below the second air duct (12), or wherein the first air duct (11) is located above the second air duct (12).

16. The power module according to any one of claims 1 to 14, wherein the isolation member (50) is a bent plate, and the high voltage power cell (20) and the low voltage power cell (30) are sequentially disposed along a length direction of the body member (10).

17. The power module according to claim 16, wherein the spacer member (50) comprises:

a first plate (51), wherein the first plate (51) is arranged on the body piece (10) and extends along the length direction of the body piece (10);

a second plate body (52), wherein the second plate body (52) is arranged on the body piece (10) and extends along the length direction of the body piece (10), and the first plate body (51) and the second plate body (52) are sequentially arranged along the height direction of the body piece (10);

a third plate body (53), wherein the third plate body (53) is arranged on the body piece (10) and is used for connecting the first plate body (51) and the second plate body (52), and the third plate body (53) is obliquely arranged relative to the first plate body (51) and the second plate body (52);

wherein the high voltage power unit (20) and the low voltage power unit (30) are respectively located on both sides of the third plate body (53).

18. The power module according to claim 17, wherein the high voltage portion (41) and the low voltage portion (42) are located on both sides of the first plate body (51), respectively; or the high-pressure part (41) and the low-pressure part (42) are respectively positioned at two sides of the second plate body (52); or the high-pressure part (41) and the low-pressure part (42) are respectively positioned on two sides of the third plate body (53).

19. The power module of claim 17, further comprising:

the third partition plate (90) is arranged in the second air duct (12) and used for dividing the second air duct (12) into two parts, and the low-voltage power unit (30) and the low-voltage part (42) are both positioned on the same side of the third partition plate (90);

and a third air guide opening is formed in the third partition plate (90).

20. The power module according to any one of claims 17 to 19, wherein the first board body (51) is located above the second board body (52);

the upper side and the lower side of the first plate body (51), the third plate body (53) and the second plate body (52) are respectively provided with the second air duct (12) and the first air duct (11), the high-voltage power unit (20) is positioned below the first plate body (51), and the low-voltage power unit (30) is positioned above the second plate body (52);

or, the upper and lower both sides of first plate body (51), third plate body (53) and second plate body (52) are first wind channel (11) with second wind channel (12) respectively, low pressure power unit (30) are located the below of first plate body (51), high pressure power unit (20) are located the top of second plate body (52).

21. The power module of claim 20, further comprising:

a high voltage input terminal (21), the high voltage input terminal (21) being disposed on the high voltage power cell (20) and protruding out of a side or rear portion of the body member (10);

a low voltage output terminal (31), the low voltage output terminal (31) being disposed on the low voltage power cell (30) and protruding the top or bottom surface of the body member (10).

22. The power module according to any one of claims 1 to 6, wherein the spacer member (50) is a straight plate, and the high-voltage power cell (20) and the low-voltage power cell (30) are arranged in order in a height direction of the body member (10).

Technical Field

The present disclosure relates to the field of power electronics, and more particularly, to a power module.

Background

At present, the power module mainly comprises a high-voltage power unit, a low-voltage power unit and a transformer, the power module is provided with a high-voltage cavity and a low-voltage cavity which are arranged in parallel, the high-voltage power unit is positioned in the high-voltage cavity, and the low-voltage power unit and the transformer are positioned in the low-voltage cavity. The high-voltage power unit and the transformer are connected through a cable.

The disadvantages of this solution are: (1) the internal structures of the power modules are sequentially arranged, so that the height size is large, and the power modules are difficult to carry; the high-pressure cavity is deep, and the cables and the optical fibers are difficult to connect and fix. (2) The adoption of shielded solid insulation results in large module size, heavy weight and high price. (3) The power module has poor internal heat dissipation capability.

Disclosure of Invention

It is a primary object of the present disclosure to overcome at least one of the above-mentioned deficiencies of the prior art and to provide a power module.

The present invention provides a power module, comprising:

a body member and a spacer member disposed within the body member;

a first air duct and a second air duct penetrating and stacked in front and rear directions within the body member and partitioned by a partition member;

a high voltage power unit;

a low voltage power unit; and

the transformer comprises a high-voltage part and a low-voltage part, wherein the high-voltage part comprises a first magnetic core and a high-voltage coil arranged on the first magnetic core; the low-voltage part comprises a second magnetic core and a low-voltage coil arranged on the second magnetic core;

the high-voltage power unit and the high-voltage part are arranged in the first air duct, and the low-voltage power unit and the low-voltage part are arranged in the second air duct; and the high-voltage coil is electrically connected with the high-voltage power unit, and the low-voltage coil is electrically connected with the low-voltage power unit.

In one embodiment of the present invention, the isolation member is an insulator, and the power module further includes:

and the high-voltage part and the low-voltage part are respectively contacted with the semi-conducting layers on the two sides of the isolation component.

In one embodiment of the present invention, a transformer includes:

the high-voltage part comprises a main high-voltage part and an auxiliary high-voltage part, the low-voltage part comprises a main low-voltage part and an auxiliary low-voltage part, the main high-voltage part and the main low-voltage part are the high-voltage part and the low-voltage part of the main transformer, the auxiliary high-voltage part and the auxiliary low-voltage part are the high-voltage part and the low-voltage part of the auxiliary transformer, the main high-voltage part and the auxiliary high-voltage part are electrically connected with the high-voltage power unit, and the main low-voltage part and the auxiliary low-voltage part are electrically connected with the low-voltage power unit.

In one embodiment of the invention, the main transformer is one or more and the auxiliary transformer is one or more.

In one embodiment of the invention, the semiconducting layer is arranged on both sides of the separating member in the area where the first magnetic core and the second magnetic core are in contact with each other.

In one embodiment of the invention, the power module further comprises:

the fan assembly comprises a fan, and an air inlet and an air outlet of the fan are communicated with the front portion of the first air channel and the front portion of the second air channel.

In one embodiment of the present invention, a fan includes:

the air inlet and outlet of the first fan are positioned in the front parts of the first air channel and the second air channel, and the air inlet and outlet direction of the first fan is parallel to the length direction of the body piece.

In one embodiment of the present invention, the fan further comprises:

and the second fan is positioned at the front parts of the first air channel and the second air channel and is arranged side by side with the first fan.

In one embodiment of the present invention, the air inlet and outlet of the second fan are disposed obliquely with respect to the air inlet and outlet of the first fan and are inclined toward the front portions of the first air duct and the second air duct.

In an embodiment of the present invention, the air inlet and outlet of the second blower are arranged in parallel with the air inlet and outlet of the first blower, and the blower assembly further includes:

and the air deflector is obliquely arranged relative to the air inlet and the air outlet of the second fan, so that the air discharged or sucked from the air inlet and the air outlet of the second fan passes through the first air channel and the second air channel after passing through the air deflector.

In one embodiment of the invention, the fan assembly is disposed on a side of the body member adjacent the low voltage power cell.

In one embodiment of the present invention, the fan assembly is disposed within the body member, and the power module further comprises:

the first partition plate is arranged on one side, close to the fan assembly, in the first air duct, and the high-voltage power unit and the high-voltage part are both positioned on the same side of the first partition plate and are positioned on the other side opposite to the side where the fan assembly is positioned;

wherein, a first air guide opening communicated with the front part of the first air duct is arranged on the first clapboard.

In one embodiment of the present invention, the fan assembly further comprises:

the fan is arranged in the mounting part, and the mounting part is connected with the body piece;

wherein, be provided with the vent that is used for being linked together with first wind channel and second wind channel on the installation department.

In one embodiment of the invention, at least part of the vent is an opening, the power module further comprising:

the second partition plate is arranged on the mounting part and used for shielding the part of the opening;

and a second air guide opening communicated with the front part of the first air duct is formed in the second partition plate.

In one embodiment of the present invention, the first air duct is located below the second air duct, or the first air duct is located above the second air duct.

In one embodiment of the present invention, the isolation member is a bent plate, and the high voltage power cell and the low voltage power cell are sequentially disposed along a length direction of the body member.

In one embodiment of the present invention, the isolation member comprises:

the first plate body is arranged on the body piece and extends along the length direction of the body piece;

the second plate body is arranged on the body piece and extends along the length direction of the body piece, and the first plate body and the second plate body are sequentially arranged along the height direction of the body piece;

the third plate body is arranged on the body piece and used for connecting the first plate body and the second plate body, and the third plate body is obliquely arranged relative to the first plate body and the second plate body;

wherein, high-voltage power unit and low-voltage power unit are located the both sides of third plate body respectively.

In one embodiment of the present invention, the high-pressure portion and the low-pressure portion are respectively located at both sides of the first plate body; or the high-pressure part and the low-pressure part are respectively positioned at two sides of the second plate body; or the high-pressure part and the low-pressure part are respectively positioned at two sides of the third plate body.

In one embodiment of the invention, the power module further comprises:

the third partition plate is arranged in the second air duct and used for dividing the second air duct into two parts, and the low-voltage power unit and the low-voltage part are both positioned on the same side of the third partition plate;

wherein, a third air guide opening is arranged on the third clapboard.

In one embodiment of the present invention, the first plate is located above the second plate;

the upper side and the lower side of the first plate body, the third plate body and the second plate body are respectively provided with a second air duct and a first air duct, the high-voltage power unit is positioned below the first plate body, and the low-voltage power unit is positioned above the second plate body;

or the upper side and the lower side of the first plate body, the third plate body and the second plate body are respectively provided with a first air duct and a second air duct, the low-voltage power unit is positioned below the first plate body, and the high-voltage power unit is positioned above the second plate body.

In one embodiment of the invention, the power module further comprises:

the high-voltage input terminal is arranged on the high-voltage power unit and protrudes out of the side surface or the rear part of the body piece;

and the low-voltage output terminal is arranged on the low-voltage power unit and protrudes out of the top surface or the bottom surface of the body member.

In one embodiment of the present invention, the isolation member is a straight plate, and the high voltage power cell and the low voltage power cell are sequentially disposed in a height direction of the body member.

According to the power module, the interior of the body piece is divided into the first air channel and the second air channel which penetrate through and are stacked front and back, the high-voltage power unit and the high-voltage part are arranged in the first air channel, the low-voltage power unit and the low-voltage part are arranged in the second air channel, namely the high-voltage power unit and the high-voltage part as well as the low-voltage power unit and the low-voltage part are respectively arranged in two different air channels which are separated by the separation part, and the independent first air channel and the independent second air channel can not only prevent heat from being mutually transmitted, but also ensure the circulation of air flow, so that the heat dissipation capacity in the body piece is accelerated.

Drawings

Various objects, features and advantages of the present disclosure will become more apparent from the following detailed description of preferred embodiments thereof, when considered in conjunction with the accompanying drawings. The drawings are merely exemplary illustrations of the disclosure and are not necessarily drawn to scale. In the drawings, like reference characters designate the same or similar parts throughout the different views. Wherein:

FIG. 1 is a schematic diagram illustrating an internal structure of a power module according to an exemplary embodiment;

FIG. 2 is a schematic cross-sectional view of a power module according to an exemplary embodiment;

FIG. 3 is a schematic diagram illustrating a power module according to an exemplary embodiment;

FIG. 4 is a schematic diagram illustrating an internal structure of a power module according to another exemplary embodiment;

FIG. 5 is a schematic cross-sectional view of a power module according to another exemplary embodiment;

FIG. 6 is a schematic diagram of a power module according to another exemplary embodiment;

FIG. 7 is a schematic diagram illustrating a fan assembly according to an exemplary embodiment;

FIG. 8 is a schematic illustration of an internal construction of a fan assembly according to an exemplary embodiment;

FIG. 9 is a schematic structural diagram illustrating a fan assembly according to another exemplary embodiment;

FIG. 10 is a schematic illustration of an internal construction of a fan assembly according to another exemplary embodiment;

FIG. 11 is a partial schematic diagram of a power module according to an exemplary embodiment;

FIG. 12 is a schematic diagram of a main transformer of a power module according to an exemplary embodiment;

fig. 13 is a schematic diagram of the construction of an auxiliary electrical transformer according to one of the power modules shown in fig. 11;

FIG. 14 is a schematic diagram illustrating a configuration of a partition of a power module according to an exemplary embodiment.

The reference numerals are explained below:

10. a body member; 11. a first air duct; 12. a second air duct; 20. a high voltage power unit; 21. a high voltage input terminal; 30. a low voltage power unit; 31. a low voltage output terminal; 40. a transformer; 41. a high-voltage part; 41-A, a main high-voltage part; 41-B, an auxiliary electric high-voltage part; 411. a first magnetic core; 411-A, a first main magnetic core; 411-B, a first auxiliary electromagnet core; 412. a high-voltage coil; 412-A, a primary high voltage coil; 412-B, an auxiliary electrical high voltage coil; 42. a low-pressure portion; 42-A, a main low-pressure part; 42-B, an auxiliary low-voltage part; 421. a second magnetic core; 421-A, a second main magnetic core; 421-B, a second auxiliary electromagnetic core; 422. a low-voltage coil; 422-A, a main low-voltage coil; 422-B, an auxiliary electric low-voltage coil; 43. a main transformer; 44. an auxiliary electrical transformer; 50. an isolation member; 51. a first plate body; 52. a second plate body; 53. a third plate body; 60. a semiconducting layer; 70. a fan assembly; 71. a first fan; 72. a second fan; 73. an air deflector; 74. an installation part; 741. a vent; 80. a first separator; 81. a second separator; 90. and a third partition plate.

Detailed Description

Exemplary embodiments that embody features and advantages of the present disclosure are described in detail below in the specification. It is to be understood that the disclosure is capable of various modifications in various embodiments without departing from the scope of the disclosure, and that the description and drawings are to be regarded as illustrative in nature, and not as restrictive.

In the following description of various exemplary embodiments of the disclosure, reference is made to the accompanying drawings, which form a part hereof, and in which are shown by way of illustration various exemplary structures, systems, and steps in which aspects of the disclosure may be practiced. It is to be understood that other specific arrangements of parts, structures, example devices, systems, and steps may be utilized and structural and functional modifications may be made without departing from the scope of the present disclosure. Moreover, although the terms "over," "between," "within," and the like may be used in this specification to describe various example features and elements of the disclosure, these terms are used herein for convenience only, e.g., in accordance with the orientation of the examples in the figures. Nothing in this specification should be construed as requiring a specific three dimensional orientation of structures in order to fall within the scope of this disclosure.

An embodiment of the present invention provides a power module, please refer to fig. 1 to 14, the power module includes: body member 10 and spacer member 50 disposed within body member 10; a first air duct 11 and a second air duct 12 penetrating and stacked in front and rear directions within the body member 10 partitioned by a partition member 50; a high voltage power unit 20; a low-voltage power unit 30; and a transformer 40, the transformer 40 including a high voltage part 41 and a low voltage part 42, the high voltage part 41 including a first core 411 and a high voltage coil 412 disposed on the first core 411; the low voltage part 42 includes a second core 421 and a low voltage coil 422 provided on the second core 421; wherein, the high-voltage power unit 20 and the high-voltage part 41 are arranged in the first air duct 11, and the low-voltage power unit 30 and the low-voltage part 42 are arranged in the second air duct 12; and the high voltage coil 412 is electrically connected to the high voltage power unit 20 and the low voltage coil 422 is electrically connected to the low voltage power unit 30.

In the power module according to an embodiment of the present invention, the interior of the body member 10 is divided into the first air duct 11 and the second air duct 12 which are penetrated through and stacked front and back, the high-voltage power unit 20 and the high-voltage portion 41 are disposed in the first air duct 11, and the low-voltage power unit 30 and the low-voltage portion 42 are disposed in the second air duct 12, that is, the high-voltage power unit 20 and the high-voltage portion 41, and the low-voltage power unit 30 and the low-voltage portion 42 are disposed in two different air ducts, respectively, and the two air ducts are separated by the separating member 50, so that the independent first air duct 11 and the independent second air duct 12 can not only prevent heat from being mutually transferred, but also ensure air flow circulation, thereby accelerating heat dissipation. The power module is divided into two independent air channels, so that the mutual series connection of heat dissipation of the functional modules is avoided, the heat dissipation capability and the overall heat dissipation efficiency of the power module are effectively improved, and the power density of the power module can be improved.

In one embodiment, the first air duct 11 and the second air duct 12 are both penetrated in the front and back directions, i.e. the front and back portions of the body member 10 are provided with ventilation openings to ensure reliable circulation of air flow. The first air duct 11 and the second air duct 12 are arranged in a stacked manner, and may be stacked up and down, but are not limited to the stacked manner.

As shown in fig. 2, the isolation member 50 is an insulating member, and the power module further includes: the semiconductive layer 60 and the semiconductive layer 60 are provided on both sides of the insulating member 50, and the high-voltage part 41 and the low-voltage part 42 are in contact with the semiconductive layers 60 on both sides of the insulating member 50, respectively.

In one embodiment, the isolation member 50 and the semi-conductive layer 60 are used to electrically isolate the high-voltage part 41 from the low-voltage part 42, and the isolation member 50 is also used to adjust a gap between the high-voltage part 41 and the low-voltage part 42, thereby performing a function of adjusting a magnitude of leakage inductance of the transformer 40; by providing the semiconductive layer 60, the electric fields in the high-voltage portion 41 and the low-voltage portion 42 can be uniformly distributed in the insulating member 50, and thus, not only the partial discharge phenomenon can be prevented, but also the uniform distribution of the electric fields can be ensured.

In one embodiment, the isolation component 50 made of an insulating member can isolate high voltage and low voltage, which enables the transformer 40 to be free of solid shielding insulation and insulation layer wrapping, and the cooling air can directly dissipate heat of the first magnetic core 411, the high voltage coil 412, the second magnetic core 421 and the low voltage coil 422, thereby avoiding a heat dissipation bottleneck of solid insulation. The high-voltage power unit 20 does not need to be wrapped by a solid insulation shielding shell, so that the size, the weight and the structural member cost are greatly reduced, and the power density is greatly improved.

In a specific embodiment of the semiconductive layer 60, the semiconductive layer 60 is provided at least in a region where both sides of the insulating member 50 are in contact with the first magnetic core 411 and the second magnetic core 421.

In one embodiment, a semiconductive layer 60 is disposed between the isolation member 50 and the first magnetic core 411, that is, the first magnetic core 411 is in contact with the isolation member 50 through the semiconductive layer 60, the first magnetic core 411 has an end portion, the semiconductive layer 60 is sandwiched between the end portion of the first magnetic core 411 and the isolation member 50, and a projection of the end portion on the isolation member 50 is located on the semiconductive layer 60, that is, an area of the semiconductive layer 60 may be greater than or equal to an area of the end portion of the first magnetic core 411, the end portion of the first magnetic core 411 may be multiple, and the corresponding semiconductive layer 60 may be multiple to fit therewith, but may also be an integral body. Accordingly, the semiconductive layer 60 is disposed between the isolation member 50 and the second magnetic core 421, that is, the second magnetic core 421 is in contact with the isolation member 50 through the semiconductive layer 60, the second magnetic core 421 has an end portion, the semiconductive layer 60 is sandwiched between the end portion of the second magnetic core 421 and the isolation member 50, and the projection of the end portion on the isolation member 50 is located on the semiconductive layer 60, that is, the area of the semiconductive layer 60 may be greater than or equal to the end portion of the second magnetic core 421, the end portion of the second magnetic core 421 may be multiple, and the corresponding semiconductive layer 60 may be multiple to the corresponding end portion, but may also be one integral.

In one embodiment, as shown in FIG. 12, transformer 40 comprises a main transformer 43 located within body member 10, main transformer 43 comprising a main high voltage section 41-A and a main low voltage section 42-A, main high voltage section 41-A comprising a first main core 411-A and a main high voltage coil 412-A disposed on first main core 411-A; the main low voltage part 42-a comprises a second main core 421-a and a main low voltage coil 422-a arranged on the second main core 421-a, and the main high voltage coil 412-a is electrically connected with the high voltage power unit 20, in particular, with a main power circuit in the high voltage power unit 20; the primary low voltage coil 422-a is electrically connected to the low voltage power unit 30, and in particular, to the primary power circuit of the low voltage power unit 30.

In one embodiment, as shown in FIGS. 11-13, transformer 40 includes a main transformer 43 and an auxiliary electrical transformer 44 located within body member 10, and high voltage section 41 includes a main high voltage section 41-A and an auxiliary electrical high voltage section 41-B, and low voltage section 42 includes a main low voltage section 42-A and an auxiliary electrical low voltage section 42-B, main high voltage section 41-A and main low voltage section 42-A being respectively a high voltage section and a low voltage section corresponding to main transformer 43, and auxiliary electrical high voltage section 41-B and auxiliary electrical low voltage section 42-B being respectively a high voltage section and a low voltage section corresponding to auxiliary electrical transformer 44, and auxiliary electrical high voltage section 41-B including a first auxiliary electrical core 411-B and an auxiliary electrical high voltage coil 412-B, and auxiliary electrical low voltage section 42-B including a second auxiliary electrical core 421-B and an auxiliary electrical low voltage coil 422-B, wherein main high voltage coil 412-A and main low voltage coil 422-A are respectively associated with high voltage power unit 20 and low voltage unit The main power circuit in the voltage power unit 30 is electrically connected to realize power transmission of the main power circuit; the auxiliary electric high-voltage coil 412-B and the auxiliary electric low-voltage coil 422-B are electrically connected with the auxiliary power supply circuits in the high-voltage power unit 20 and the low-voltage power unit 30, respectively, so as to realize power transmission of the auxiliary power supply circuits, and further realize power supply for control driving and the like of the high-voltage power unit 20 and the low-voltage power unit 30.

In one embodiment, the transformer 40 includes only the main transformers 43, and the number of the main transformers 43 is one or more; in one embodiment, the transformer 40 includes both the main transformers 43 and the auxiliary electrical transformers 44, and the number of the main transformers 43 is 1 or more and the number of the auxiliary electrical transformers 44 is 1 or more. Also, the main transformer 43 may be arranged in parallel and electrically connected to a plurality of main circuits in the high/low voltage power unit, or a plurality of main transformers may be arranged in parallel and electrically connected to one main circuit in the high/low voltage power unit at the same time; the auxiliary power transformers 44 may be arranged in parallel and electrically connected to a plurality of auxiliary power circuits in the high/low voltage power unit, or a plurality of auxiliary power transformers may be arranged in parallel and electrically connected to the same auxiliary power circuit in the high/low voltage power unit at the same time.

In one embodiment, main transformer 43 and auxiliary electrical transformer 44 multiplex isolation members 50, and are arranged side-by-side, such that auxiliary electrical transformer 44 is integrated inside the power module, resulting in a more modular system; on the other hand, the auxiliary power transformer 44 and the main transformer 43 share insulation, so that a power cable of auxiliary power is shortened, the occupied space of the system is reduced, and the power density of the system is further improved.

As shown in fig. 1 and 4, the power module further includes: the fan assembly 70, the fan assembly 70 includes a fan, and the air inlet and the air outlet of the fan are communicated with the front part of the first air duct 11 and the front part of the second air duct 12.

In one embodiment, the fan is used to send cold air into the first air duct 11 and the second air duct 12 or suck hot air out of the first air duct and the second air duct 12, that is, the air inlet and the air outlet of the fan can be used for blowing air or sucking air, which depends on the environment with heat dissipation and the heat dissipation time, and only the air circulation inside the first air duct 11 and the second air duct 12 needs to be ensured.

In one embodiment, the two ends of the air duct are defined as the front and the rear with respect to the length direction of the air duct, i.e., the front and the rear of the first air duct 11 and the front and the rear of the second air duct 12.

As shown in fig. 2 and 5, the blower includes: the air inlet and outlet of the first fan 71 are located at the front parts of the first air duct 11 and the second air duct 12, and the air inlet and outlet direction of the first fan 71 is parallel to the length direction of the body member 10, i.e. parallel to the front and rear parts of the first air duct 11 and the second air duct 12.

In one embodiment, the air inlet and outlet of the first fan 71 directly blows air or sucks air to the first air duct 11 and the second air duct 12. The front and rear directions of the first duct 11 and the second duct 12 are the directions of inflow and outflow of air currents.

In one embodiment, the fan further comprises: and a second fan 72, wherein the second fan 72 is positioned at the front part of the first air duct 11 and the second air duct 12 and is arranged side by side with the first fan 71. The first fan 71 and the second fan 72 are arranged to ensure that sufficient cold air can be fed into the first air duct 11 and the second air duct 12, or sufficient hot air can be sucked out, i.e. air circulation inside the air ducts is ensured.

Regarding the installation position of the second fan 72, as shown in fig. 8, the air inlet and outlet of the second fan 72 is obliquely arranged with respect to the air inlet and outlet of the first fan 71 and is obliquely inclined toward the front portions of the first air duct 11 and the second air duct 12. The air inlet and outlet of the second fan 72 are inclined to ensure that the air inlet and outlet of the second fan 72 can flow through the first air duct 11 and the second air duct 12 more easily.

As shown in fig. 10, the air inlet and outlet of the second blower 72 are arranged in parallel with the air inlet and outlet of the first blower 71, and the blower assembly 70 further includes: the air deflector 73 is obliquely arranged relative to the air inlet and outlet of the second fan 72, so that cold air blown in from the air inlet and outlet of the second fan 72 passes through the air deflector 73 and then blows to the first air duct 11 and the second air duct 12 or hot air generated in the first air duct 11 and the second air duct 12 passes through the air deflector 73 and then is sucked out from the air inlet and outlet of the second fan 72.

In one embodiment, the second fan 72 is disposed in the same manner as the first fan 71, and the air inlet and the air outlet of the second fan 72 face an air duct, so that the air discharged or sucked from the air inlet and the air outlet of the second fan 72 can easily flow through the first air duct 11 and the second air duct 12 at the same time, an inclined air deflector 73 is disposed for guiding the air. Wherein the angle of the air deflector 73 is adjustably set.

In one embodiment, the front portion of the first air duct 11 is smaller than the front portion of the second air duct 12, the air inlet and outlet of the first fan 71 face to the front portion of the first air duct 11 and the front portion of the second air duct 12 simultaneously, and the second fan 72 and the first fan 71 are disposed side by side up and down, so that in order to enable the air discharged or sucked from the air inlet and outlet of the second fan 72 to flow through the first air duct 11 and the second air duct 12 simultaneously, the second fan 72 may be disposed obliquely, or may be provided with an air deflector 73 for guiding the air.

In one embodiment, the fan assembly 70 is disposed on a side of the body member 10 adjacent to the low voltage power cell 30. The fan assembly 70 is disposed at a position on one hand in consideration of safety, and on the other hand, the fan assembly 70 is beneficial to reducing the size of the power module in the length direction, that is, the fan assembly 70 is disposed at a side close to the low-voltage power unit 30, and compared with the fan assembly disposed at a side close to the high-voltage power unit 20, the electrical clearance and the creepage distance required to be reserved are smaller, and the size of the power module in the length direction can be reduced.

In one embodiment, the number of fans of the fan assembly 70 may be increased or decreased according to different power levels.

As shown in fig. 1 and 2, the fan assembly 70 is disposed within the body member 10, and the power module further includes: the first partition plate 80 is arranged at one side, close to the fan assembly 70, in the first air duct 11, and the high-voltage power unit 20 and the high-voltage part 41 are both positioned at the same side of the first partition plate 80 and at the other side opposite to the side where the fan assembly 70 is positioned; the first partition 80 is provided with a first air guiding opening communicated with the front portion of the first air duct 11.

In one embodiment, although the first air duct 11 and the second air duct 12 are two independent air ducts, since they are in a communication state with the outside, that is, air circulation needs to be ensured, there is a problem that the high voltage power unit 20 and the high voltage portion 41 are discharged and connected in series to the low voltage power unit 30 and the low voltage portion 42 and the inside of the fan assembly 70 during actual use, thereby affecting normal operation of the low voltage power unit 30 and the low voltage portion 42 and the fan assembly 70, and the first partition 80 can further prevent the problem, that is, further dividing the high voltage region (including the high voltage power unit 20 and the high voltage portion 41) and the low voltage region (including the low voltage power unit 30 and the low voltage portion 42).

In one embodiment, the first baffle 80 is provided with a plurality of first air guiding openings.

As for the specific structure of the fan assembly 70, as shown in fig. 7 to 10, the fan assembly 70 further includes: a mounting part 74, in which the blower fan is disposed, the mounting part 74 being connected with the body member 10; the mounting portion 74 is provided with a vent 741 for communicating with the first air duct 11 and the second air duct 12.

In one embodiment, the fan assembly 70 and the body member 10 are independent of each other, that is, the fan assembly 70 is connected to the body member 10 through a mounting portion 74, and can be detached at any time when in use, and the first fan 71 and the second fan 72 are both disposed on the mounting portion 74.

In one embodiment, when the first fan 71 is disposed in parallel with the air inlet and outlet of the second fan 72, the air deflector 73 of the fan assembly 70 is also disposed on the mounting portion 74.

In one embodiment, the first fan 71 and the second fan 72 are both fans.

In one embodiment, at least a portion of the vent 741 is an opening, the power module further comprising: a second partition plate 81, the second partition plate 81 being provided on the mounting portion 74 for blocking a portion of the opening; wherein, the second partition 81 is provided with a second air guiding opening communicated with the front portion of the first air duct 11. The second partition 81 is provided to isolate the first air duct 11 from the ventilation hole 741, i.e., to prevent the discharge in the high-pressure region from being connected in series to the low-pressure region and the fan assembly 70, thereby reducing the safety of the power module.

In one embodiment, a plurality of second air guiding openings are disposed on the second partition 81.

For the arrangement of the first air duct 11 and the second air duct 12, the first air duct 11 is located below the second air duct 12, or the first air duct 11 is located above the second air duct 12. The upper and lower portions herein may also represent the arrangement relationship of the partial structures, and do not exclude that the portions of the first air duct 11 and the second air duct 12 are located in the same horizontal plane.

Regarding the specific structure of the isolation member 50, the isolation member 50 is a bent plate, and the high voltage power unit 20 and the low voltage power unit 30 are sequentially disposed along the length direction of the body member 10. This arrangement can reduce the volume of the power module as a whole.

As shown in fig. 2 and 5, the spacer member 50 includes: a first plate 51, the first plate 51 being disposed on the body member 10 and extending along a length direction of the body member 10; a second plate 52, the second plate 52 being disposed on the body member 10 and extending along the length direction of the body member 10, the first plate 51 and the second plate 52 being sequentially disposed along the height direction of the body member 10; a third plate 53, the third plate 53 being provided on the body member 10 for connecting the first plate 51 and the second plate 52, the third plate 53 being disposed obliquely with respect to the first plate 51 and the second plate 52; wherein, the high voltage power unit 20 and the low voltage power unit 30 are respectively located at both sides of the third plate body 53.

In one embodiment, the isolation member 50 is composed of a first plate 51, a second plate 52 and a third plate 53, wherein the first plate 51 and the second plate 52 are horizontally disposed but not in the same horizontal plane, and the third plate 53 for connecting the first plate 51 and the second plate 52 is disposed obliquely to the horizontal plane, i.e., the isolation member 50 divides the body member 10 into upper and lower portions. In this case, the first air duct 11 may be located below the second air duct 12, or may be located above the second air duct 12.

The high pressure part 41 and the low pressure part 42 are respectively positioned at both sides of the first plate body 51 with respect to the arrangement positions of the high pressure part 41 and the low pressure part 42; or the high pressure part 41 and the low pressure part 42 are respectively positioned at both sides of the second plate body 52; or the high pressure part 41 and the low pressure part 42 are respectively located at both sides of the third plate body 53.

In one embodiment, as shown in fig. 4 and 5, the high pressure part 41 and the low pressure part 42 are respectively located at both sides of the first plate body 51, i.e., both the high pressure part 41 and the low pressure part 42 are also arranged in a horizontal direction. At this time, the high voltage power unit 20 is stacked with the high voltage part 41 and the low voltage part 42 of the transformer 40. The high-voltage power unit 20 and the high-voltage part 41 dissipate heat in the first air duct 11; the low-voltage power unit 30 and the low-voltage portion 42 dissipate heat in the second air duct 12.

In one embodiment, the high voltage part 41 and the low voltage part 42 are respectively located at both sides of the second board body 52, i.e., the low voltage power unit 30 may also be stacked with the low voltage part 42 and the high voltage part 41 of the transformer 40.

In one embodiment, the high pressure portion 41 and the low pressure portion 42 are more easily fixed when they are horizontally placed.

In one embodiment, as shown in fig. 1 and 2, the high-pressure portion 41 and the low-pressure portion 42 are respectively located at two sides of the third plate 53, that is, the high-pressure portion 41 and the low-pressure portion 42 are arranged obliquely with respect to the horizontal plane, and at this time, the high-pressure portion 41 and the low-pressure portion 42 can effectively utilize the inner space of the air duct, and meet the requirement of creepage distance, so that the overall volume of the body member 10 can be reduced.

As shown in fig. 2 and 5, the power module further includes: the third partition plate 90 is arranged in the second air duct 12, and is used for dividing the second air duct 12 into two parts, and the low-voltage power unit 30 and the low-voltage part 42 are both positioned on the same side of the third partition plate 90; wherein, a third air guiding opening is arranged on the third partition plate 90.

In one embodiment, the third partition 90 is provided to prevent the high-pressure discharge from being connected in series to the low-pressure region, thereby affecting the normal operation of the interior of the low-pressure region, i.e., the high-pressure region is further divided, which functions similarly to the first partition 80 or the second partition 81.

In one embodiment, a plurality of third air guiding openings are formed on the third partition 90.

In one embodiment, the third partition 90 is located at a position of the second air duct 12 close to the low voltage power unit 30, and the metal case (body member 10) surrounding the low voltage power unit 30, the fan fixing case (mounting portion 74) and the first partition 80 (or the second partition 81) divide the inside of the body member 10 into a low voltage region and a high voltage region. The first partition 80 (or the second partition 81) and the third partition 90 are made of metal materials, and the partitions are of open-hole structures, so that the high-pressure units, such as louver holes, cannot be seen from the low-pressure units. The power module is isolated from high voltage and low voltage, a partition plate is added, the safety of the power module is improved, and the high voltage area is prevented from being discharged to be connected in series to the low voltage area. The opening of the shutter of the partition board ensures the heat dissipation and safety requirements of the power module.

In one embodiment, first plate 51 is positioned above second plate 52; the upper and lower sides of the first plate 51, the third plate 53 and the second plate 52 are respectively a second air duct 12 and a first air duct 11, the high-voltage power unit 20 is located below the first plate 51, and the low-voltage power unit 30 is located above the second plate 52; or, the upper and lower sides of the first plate 51, the third plate 53 and the second plate 52 are respectively the first air duct 11 and the second air duct 12, the low voltage power unit 30 is located below the first plate 51, and the high voltage power unit 20 is located above the second plate 52. Wherein the fan assembly 70 is disposed on a side of the body member 10 adjacent to the low voltage power unit 30.

As shown in fig. 3 and 6, the power module further includes: a high voltage input terminal 21, the high voltage input terminal 21 being disposed on the high voltage power unit 20 and protruding out of the side or rear of the body member 10; a low voltage output terminal 31, the low voltage output terminal 31 being provided on the low voltage power cell 30 and protruding from the top or bottom surface of the body member 10.

In one embodiment, when the second air duct 12 is located above the first air duct 11, the low voltage output terminal 31 may be disposed on the top surface; when the second air duct 12 is located below the first air duct 11, the low voltage output terminal 31 may be disposed on the bottom surface. However, in actual use, the adjustment may be made as long as the interconnection of the low-voltage output terminals 31 of the plurality of power modules and the insertion and extraction of the power modules are facilitated.

In one embodiment, the high voltage input terminals 21 are located at both sides or the rear of the high voltage power unit 20, which may facilitate interconnection of the high voltage input terminals 21 of a plurality of power modules and insertion and extraction of the power modules.

In one embodiment, the isolation member 50 is a straight plate, and the high voltage power unit 20 and the low voltage power unit 30 are sequentially disposed in a height direction of the body member 10. I.e., the high voltage power unit 20 and the low voltage power unit 30 are directly stacked in the vertical direction.

Other embodiments of the invention will be apparent to those skilled in the art from consideration of the specification and practice of the invention disclosed herein. This invention is intended to cover any variations, uses, or adaptations of the invention following, in general, the principles of the invention and including such departures from the present disclosure as come within known or customary practice within the art to which the invention pertains. It is intended that the specification and exemplary embodiments be considered as exemplary only, with a true scope and spirit of the invention being indicated by the following claims.

It will be understood that the invention is not limited to the precise arrangements described above and shown in the drawings and that various modifications and changes may be made without departing from the scope thereof. The scope of the invention is limited only by the appended claims.