KR20200052605A - Inverter power module cooling structure - Google Patents

Abstract

The present invention relates to an inverter power module cooling structure. A plurality of power modules are arranged at intervals, and each of the power modules is equipped with a cooling unit. The power module and the cooling unit are arranged and connected in a parallel structure and cooled through cooling water. According to the present invention, the inverter power module cooling structure is arranged on a lateral side of a capacitor and can constitute a parallel channel as well as ensure the uniform cooling performance of the power module.

Description

Inverter power module cooling structure

The present invention relates to an inverter power module cooling structure, and more particularly, to an inverter power module cooling structure configured to allow cooling water to flow in parallel to ensure uniform cooling performance of the power module.

In the case of a hybrid vehicle or an electric vehicle, parts that enable electric driving such as a motor, an inverter, and a battery are mounted.

These parts can improve and drive the fuel efficiency of the vehicle by converting, storing, and releasing energy, but the loss occurs because the efficiency is not 100%, and the loss dissipates noise and heat.

In addition, three power modules are mounted on the inverter, and the power modules are cooled through a double-sided cooling device that cools both the top and bottom surfaces.

Here, the two-sided cooling type cooler that cools the power module flows through the input unit to sequentially cool the power modules one by one and then discharges them to the output unit.

However, since the conventional two-sided cooling type cooler sequentially cools three power modules, there is a problem in that the cooling performance of the power module to be cooled last is lowered and a differential pressure is generated as the length of the water channel becomes longer.

That is, when the cooling of the power module is unbalanced, the vehicle must be driven in accordance with the performance of the power module having the lowest cooling performance, so the performance of the vehicle decreases, and the capacity of the cooling pump must be increased to compensate for the differential pressure caused by the long waterway. There was a problem of falling fuel economy.

Republic of Korea Patent Publication No. 10-2013-021570 (2013.03.06) Republic of Korea Patent Publication No. 10-2014-084590 (2014.07.07)

The present invention has been proposed in view of the above circumstances, and an object of the present invention is to provide an inverter power module cooling structure that is disposed on the side of an open capacitor and can constitute a parallel channel.

In addition, the object of the present invention is to provide an inverter power module cooling structure capable of managing sub-parts with a cooler by replacing the connection nipple with a block-type cooling water connection passage structure.

Inverter power module cooling structure according to an embodiment of the present invention, a plurality of power modules are arranged at intervals, and the power modules are respectively equipped with cooling means, while the power modules and cooling means are arranged and connected in a parallel structure. Cooled through coolant.

In addition, a connection block may be mounted between the main block and the main block constituting the cooling means in which the power module is mounted.

Next, the cooling means is an inner and outer cooler mounted on both sides of the power module; An inlet pipe and an outlet pipe which are respectively installed at the same end of the inner and outer coolers and that coolant flows in or out; And the inlet pipe and the outlet pipe are respectively coupled to the block inlet coupler and the block outlet coupler, and one side is equipped with a nipple for internal / external connection for introducing or discharging cooling water, and the inside is supplied through the internal / external connection nipple. It may include; a main block in which a cooling water storage space in which cooling water is stored is formed.

Here, the inlet pipe and the outlet pipe may be formed with a diameter larger than the width of the inner and outer coolers.

In addition, the inlet pipe and the outlet pipe may be located on different lines.

In addition, at least one or more O-rings may be mounted to the inlet pipe and the outlet pipe combined with the block inlet and block outlet couplers of the main block.

In addition, the block outlet coupler of the main block may be formed lower than the block inlet coupler with respect to the upper surface.

And the main block and the connection block can be fitted.

The cooling structure of the inverter power module according to the present invention is arranged on the side of the open capacitor and can constitute a parallel channel, and has an effect of ensuring equal cooling performance of the power module.

In addition, the inverter power module cooling structure according to the present invention can replace the nipple for connection with a block-type cooling water connection passage structure to manage sub-parts together with a cooler, and also share parts by applying a block-type cooling water connection passage structure. It works.

1 is a perspective view showing an inverter power module cooling structure according to the present invention.
Figure 2 is an exploded perspective view showing the cooling structure of the inverter power module according to the present invention.
3 is a plan view showing an inverter power module cooling structure according to the present invention.
Figure 4 is a view showing a separation state of the main block and the connecting block constituting the cooling structure of the inverter power module according to the present invention.

Advantages and features of the present invention, and methods for achieving them will be clarified with reference to embodiments described below in detail together with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but will be implemented in various different forms, and only the embodiments allow the disclosure of the present invention to be complete, and the ordinary knowledge in the technical field to which the present invention pertains. It is provided to fully inform the holder of the scope of the invention, and the invention is defined by the claims. Meanwhile, the terms used in the present specification are for explaining the embodiments and are not intended to limit the present invention. In the present specification, the singular form also includes the plural form unless otherwise specified in the phrase. As used herein, "comprises" or "comprising" means the presence of one or more other components, steps, operations and / or elements other than the components, steps, operations and / or elements mentioned, or Addition is not excluded.

Hereinafter, a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings. FIG. 1 is a perspective view showing an inverter power module cooling structure according to the present invention, and FIG. 2 shows an inverter power module cooling structure according to the present invention. 3 is a perspective view showing a cooling structure of an inverter power module according to the present invention, and FIG. 4 is a view showing a separation state of a main block and a connection block constituting the inverter power module cooling structure according to the present invention.

Inverter power module cooling structure 100, which is the present invention, is equipped with cooling means 200 on a plurality of power modules 10, which are arranged at intervals, to cool power module 10 through cooling water.

At this time, the power module 10 and the cooling means 200 are arranged and connected in a parallel structure for uniform cooling performance and high differential pressure.

In addition, the cooling means 200 reveals that a known power module can be cooled in addition to the illustrated power module 10.

The cooling means 200 is mounted on the side of the capacitor to cool the power module 10.

And the cooling means 200 is mounted on the inner and outer coolers 210a and 210b mounted on both sides of the power module 10 and the inner and outer coolers 210a and 210b, respectively, and cooling water flows in or out. The inlet pipe 220 and the outlet pipe 230 are respectively coupled to the discharged inlet pipe 220, the outlet pipe 230, the block inlet coupler 241 and the block outlet coupler 242, and cooling water is introduced at one side. Alternatively, a connecting nipple 243 for discharging is mounted, and there is a main block 240 in which a cooling water storage space 244 in which cooling water supplied through the inner and outer connecting nipples 243 is stored is formed. .

That is, the cooling means 200, after mounting the inlet pipe 220 and the outlet pipe 230 to the same line ends of the inner and outer coolers 210a, 210b mounted on both sides of the power module 10, respectively, A main block 240 having a nipple 243 for connection and a cooling water storage space 244 is installed in the inlet pipe 220 and the outlet pipe 230.

In addition, the cooling of the cooling means 200 is after the cooling water stored in the cooling water storage space 244 through the inner and outer connecting nipples 243 constituting the main block 240 flows through the inlet pipe 220 , Cooling the power module 10 through the flow paths formed inside and outside the coolers 210a and 210b, and then stored in the cooling water storage space 244 of the main block 240 through the discharge pipe 230.

Here, the inlet pipe 220 and the outlet pipe 230 have a larger diameter than the width of the inner and outer coolers 210a and 210b to smoothly move and discharge cooling water to the inner and outer coolers 210a and 210b. It is formed with.

That is, the inlet pipe 220 smoothly supplies cooling water flowing through the cooling water storage space 244 to the external cooler 210b, and the discharge pipe 230 loads cooling water discharged through the inner cooler 210a. Without it.

In addition, at least one O-ring 400 is mounted on the inlet pipe 220 and the outlet pipe 230 coupled to the block inlet coupler 241 and the block outlet coupler 242 of the main block 240.

That is, the inlet pipe 220 and the outlet pipe 230 is equipped with an O-ring 400 on the outer surface, while blocking the cooling water from flowing out while being in close contact with the block inlet coupler 241 and the block outlet coupler 242 Is done.

In addition, the inlet pipe 220 and the outlet pipe 230 are positioned on different lines to minimize interference during operation.

That is, the inlet pipe 220 and the outlet pipe 230 are mounted on different lines of the inner and outer coolers 210a and 210b so as to avoid interference with each other when the coolant is introduced or discharged.

Next, the block outlet coupler 242 of the main block 240 to which the inlet pipe 220 and the outlet pipe 230 are combined is formed lower than the block inlet coupler 241 based on the upper surface.

That is, the main block 240, the block inlet coupler (241) is to smoothly flow the cooling water while receiving less of the influence of the cooling water discharged through the block outlet coupler 242, the block outlet coupler (242) ) And the block inlet coupler 241 with a difference in height.

Next, the inverter power module cooling structure 100 is provided with a connection block 300 between cooling means 200 in which the power modules 10 arranged in a parallel structure are mounted.

As a supplementary description, the main block 240 and the main block 240 constituting the cooling means 200 may be directly connected as well as coupled through the connection block 300.

At this time, the size and shape of the connection block 300 is not limited to the illustrated drawings and may be variously modified according to the environment and purpose.

In addition, the main block 240 and the connection block 300 are combined or separated by a fitting coupling structure.

Specifically, the connecting block 300 is formed with a fitting coupling hole 320 on one side and a fitting coupling protrusion 340 on the other side, and a block fitting coupling protrusion 250 is formed on the corresponding main block 240 And a block fitting hole 260 is formed.

As a supplementary description, the main block 240 and the connection block 300 are connected to the cooling block supplied to the main block 240 on one side through the block fitting projection 250 and the fitting coupling hole 320. ) Is accommodated in the storage space 360, the cooling water accommodated in the storage space 360 is moved to the other side of the main block 240 through the block fitting hole 260 and the fitting protrusion 340.

At this time, the fitting engagement protrusion 340 and the block fitting engagement protrusion 260 are equipped with an O-ring 400 for maintaining airtightness and improving engagement force.

Looking at an embodiment of the inverter power module cooling structure configured as described above are as follows.

First, after preparing a plurality of power modules 10, the inner and outer coolers 210a and 210b are mounted on both sides of the power module 10.

In addition, the inner and outer coolers 210a and 210b mounted on both sides of the power module 10, and the inlet pipes 220 respectively mounted on the same end of the inner and outer coolers 210a and 210b and in which cooling water flows in or out ) And the discharge pipe 230, the block inlet coupler 241 and the block outlet coupler 242, the inlet pipe 220 and the outlet pipe 230 are respectively coupled, one side of the nipple for connecting or inlet cooling water A pair of cooling means including a main block 240 in which a cooling water storage space 244 in which cooling water supplied through the inner and outer connecting nipples 243 is stored is formed is mounted (243). 200).

Next, after arranging the cooling means 200 at intervals, a fitting hole 320 is formed on one side between the main block 240 and the main block 240 constituting the cooling means 200. , When the coupling block 300 is formed on the other side and the storage space 360 for storing cooling water is formed, the installation work of the inverter power module cooling structure 100 is completed. .

Here, it is revealed that the assembly order of the cooling structure of the inverter power module may be different from the above.

Next, the cooling of the power module 10 through the inverter power module cooling structure 100 is as follows.

First, when cooling water is supplied to the nipple 243 for connection of the cooling means 200 mounted on one side, the cooling water is accommodated in the cooling water storage space 244 while passing through the inlet pipe 220 to the outer cooler 210b and It is accommodated in the cooling water storage space 244 through the discharge pipe 230 through the inner cooler 210a or moved to the connection block 300.

Then, the cooling water moved to the connection block 300 is accommodated in the cooling water storage space 244 of the cooling means 200 mounted on the other side and passes through the inlet pipe 220 to the outer cooler 210b and the inner cooler 210a. Through the discharge pipe 230 is accommodated in the cooling water storage space 244 or discharged to the outside through the connecting nipple 243.

The above description is merely illustrative of the technical idea of the present invention, and those skilled in the art to which the present invention pertains, various modifications and variations are possible without departing from the essential characteristics of the present invention.

Therefore, the embodiments expressed in the present invention are not intended to limit the technical spirit of the present invention, but to illustrate, and the scope of the present invention is not limited by these embodiments. The scope of protection of the present invention should be interpreted by the claims below, and all technical spirits equivalent to or within the equivalent ranges should be interpreted as being included in the scope of the present invention.

100: inverter power module cooling structure
200: cooling means 210a: inner cooler
210b: outer cooler 220: inlet pipe
230: discharge pipe 240: main block
241: block inlet joint 242: block outlet joint
243: connection nipple 244: coolant storage space
250: fitting engagement protrusion 260: block fitting engagement protrusion
300: connecting block 320: fitting coupling hole
340: fitting projection 360: storage space
400: O-ring

Claims (8)

A plurality of power modules are arranged at intervals, and cooling means are respectively installed in the power modules,
The power module and the cooling means are arranged and connected in a parallel structure, the inverter power module cooling structure is cooled through the cooling water.
According to claim 1,
An inverter power module cooling structure in which a connecting block is mounted between the main block and the main block constituting the cooling means in which the power module is mounted.
According to claim 1 or claim 2, The cooling means,
Internal and external coolers mounted on both sides of the power module;
An inlet pipe and an outlet pipe which are respectively installed at the same end of the inner and outer coolers and that coolant flows in or out; And
The inlet pipe and the outlet pipe are respectively coupled to the block inlet and block outlet couplers, and one side is equipped with a nipple for internal or external connection for introducing or discharging cooling water, and the inside is supplied through the internal and external connection nipple. Inverter power module cooling structure comprising a; main block is formed cooling water storage space is stored cooling water.
According to claim 3,
The inlet pipe and the outlet pipe are formed with a larger diameter than the width of the inner and outer cooler inverter power module cooling structure.
According to claim 3,
The inlet pipe and the outlet pipe are inverter power module cooling structure that is located on a different line.
According to claim 3,
Inverter power module cooling structure in which at least one O-ring is mounted on the inlet pipe and the outlet pipe combined with the block inlet and outlet of the main block.
According to claim 3,
The block outlet coupling hole of the main block is formed to be lower than the block inlet coupling block based on the upper surface of the inverter power module cooling structure.
According to claim 2,
The main block and the connection block is an inverter power module cooling structure that is fitted.

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