KR100934206B1 - Electric motor chiller - Google Patents

Abstract

The present invention relates to an electric motor cooling device. In the present invention, the coupling hole 21 ′ in which the rotor and the stator are installed inside the frame 21 is formed, and a cooling passage 25 through which the coolant is moved is formed on the outer surface thereof. The frame 21 is pressed into the frame cover 41. The frame 21 or the frame cover 41 is formed such that the flow path inlet 27 and the flow path outlet 29 through which the coolant is introduced and discharged communicate with the cooling flow path 25. Compartment ribs 33 are provided at intervals in the cooling passage 25 to partition the cooling passage 25. Both ends of the partition rib 33 are alternately formed with a flow passage 33 'for communicating between the partitioned cooling passages 25.

According to the motor cooling apparatus according to the present invention having such a configuration, the passage passage is formed in the opposite direction to the passage passage of the neighboring compartment ribs to repeatedly change the moving direction of the coolant, the resulting turbulence can be convection heat transfer There is an advantage that the heat transfer amount of the cooling water increases.

Description

Cooling device for electric motor

The present invention relates to an electric motor cooling apparatus, and more particularly, to an electric motor cooling apparatus for cooling heat generated in a process in which the electric motor converts electrical energy into mechanical energy.

In general, a motor is provided with a rotor coupled with a magnet and a stator wound with a coil, and uses the power of the rotating shaft as the rotor rotates due to the magnetic flux generated by the current applied to the coil of the stator and the electromagnetic induction of the rotor. Device.

In the process of converting electrical energy into mechanical energy, such a motor generates energy loss due to hysteresis of iron, eddy current, mechanical friction, etc., which causes heat to be generated in the motor.

Since this heat loss causes a decrease in the function of the motor, the motor is provided with cooling means for cooling the heat. Cooling means are generally used as the cooling means of the electric motor, and the cooling means includes air cooling using a cooling fan and water cooling using cooling water.

1 is a perspective view of a motor cooling apparatus according to the prior art.

As shown in this figure, a coupling hole 1 ′ in which a stator (not shown) of the electric motor is installed is formed in the frame 1 forming the skeleton of the motor cooling apparatus. Protruding portions 3 and 3 'are provided at the front and rear ends of the frame 1 to protrude around the outer circumferential surface of the frame 1. The protrusions 3 and 3 'are in close contact with the inner circumferential surface of the frame cover 11 to be described below to prevent the outflow of cooling water.

The protrusions 3, 3 ′ are connected to each other by boundary ribs 5. The boundary ribs 5 serve to change the flow direction of the cooling water. In addition, the frame 1 is provided with a plurality of compartment ribs 7 forming the cooling passage 9.

A plurality of partition ribs 7 are provided to surround the outer circumferential surface of the frame 1, and one end and the other end of the partition ribs 7 are alternately connected to the side surfaces of the boundary ribs 5. That is, the partition ribs 7 are provided such that the cooling passages 9 communicate with each other and extend in a zigzag shape.

The frame 1 is press-fitted into the through hole 11 'formed in the frame cover 11 to shield the cooling passage 9 from the outside. The frame cover 11 has a flow path inlet 13 through which the coolant flows in and a flow path outlet 15 through which the coolant flows out. The flow passage inlet 13 communicates with one cooling passage 9 separated by the boundary rib 5, and the flow passage outlet 15 communicates with the other cooling passage 9. The flow path inlet 13 and the flow path outlet 15 are connected to a circulation pump (not shown) for circulation of the cooling water.

In the conventional motor cooling apparatus having such a configuration, cooling water flows into the flow path inlet 13. Cooling water circulates through the cooling passage 9 while the flow direction is repeatedly switched by the boundary ribs 5. The cooling water absorbs heat of the electric motor while circulating the cooling passage 9. The high temperature cooling water circulated through the cooling passage 9 is discharged through the flow passage outlet 15.

However, the motor cooling apparatus according to the prior art as described above has the following problems.

In the related art, since the width of the cooling passage 9 is narrow, there are many sections in which the flow direction is switched, and the flow path is long, a large pressure difference between the flow path inlet 13 and the flow path outlet 15 occurs. If a large pressure drop occurs in the flow path outlet 15, the cooling water is not smoothly moved, thereby lowering the cooling efficiency.

In addition, the cooling water that moves the cooling passage 9 has a regular flow of flow, which has a problem that the efficiency of heat transfer is lowered because the mixing does not occur well during the circulation process.

In addition, the partition ribs 7 are provided in the cylindrical frame 1 to form the cooling flow path 9. Thus, welding around the curved surface has a problem in that the productivity of the product is lowered due to the difficulty of work.

The present invention is to solve the problems of the prior art as described above, an object of the present invention is to provide an electric motor cooling apparatus for reducing the pressure drop phenomenon caused by the flow resistance of the cooling water.

Another object of the present invention is to provide an electric motor cooling device in which turbulent flow is formed when the coolant moves.

Still another object of the present invention is to provide an electric motor cooling apparatus in which a cooling passage for guiding the movement of the cooling water is simply formed.

According to a feature of the present invention for achieving the above object, the present invention comprises a frame is formed with a coupling hole in which the rotor and the stator is installed, the cooling flow path is formed on the outer surface; A frame cover into which the frame is press-fitted to shield the cooling flow path from the outside; At least one flow path inlet and a flow path outlet formed in the frame or the frame cover to communicate with the cooling flow path, the cooling water flowing in and out; Partition ribs provided at intervals on the cooling passages to partition the cooling passages and alternately formed at both ends of the passage passages for communicating between the divided cooling passages; And a guide rib provided in the cooling passage communicating with the passage inlet and extending from the passage inlet toward the passage.

The partition ribs are provided at regular intervals along the circumferential direction of the frame.

The length of the partition rib is 600mm, the height of the flow path is formed to 130mm.

The width of the flow path is formed larger than 125mm and smaller than 300mm.

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The guide rib includes a parallel portion formed parallel to the inflow direction of the coolant and a guide portion inclined toward the flow path.

According to the present invention, since the flow resistance according to the movement of the cooling water is minimized by designing the width of the passage passage with respect to the length of the partition ribs, the smooth movement of the cooling water is secured and the cooling efficiency is improved.

Further, in the present invention, the flow path is formed in the opposite direction to the flow path of the adjacent compartment ribs to change the moving direction of the coolant repeatedly. Therefore, the cooling water is turbulent flow, turbulent flow has an effect that the convective heat transfer in the cooling water itself to increase the amount of heat dissipation by the cooling water.

In the present invention, since the partition rib forming the cooling flow path is provided perpendicular to the circumferential direction of the frame, the production and installation are easy, and thus the productivity of the product is improved.

Hereinafter, a preferred embodiment of the motor cooling apparatus according to the present invention having the configuration as described above will be described in detail with reference to the accompanying drawings.

2 is a perspective view showing the configuration of a preferred embodiment of the motor cooling apparatus according to the present invention, FIG. 3 is a front view showing a partition rib constituting the embodiment of the present invention, and FIG. A perspective view is shown schematically showing the flow.

As shown in these figures, the frame 21 is formed with a coupling hole 21 'in which a stator (not shown) of the electric motor is installed. Before describing the frame 21, the configuration of the electric motor will be briefly described.

The rotor shaft is rotatably installed at the inner center of the motor. The rotor shaft is provided with a rotor coupled to the permanent magnet or eastern bar, coil, etc. integrally surrounding the outer peripheral surface of the rotor shaft.

In addition, a stator with a coil wound around the rotor is fixedly installed inside the frame 21 constituting the exterior of the electric motor. When the current is applied to the coil of the stator to generate a magnetic force to rotate the rotor.

At both ends of the frame 21, protrusions 23 and 23 'forming the cooling passage 25 are formed to protrude around the outer circumferential surface of the frame 21. The protrusions 23 and 23 'are in close contact with the inner circumferential surface of the frame cover 41 to be described below. The cooling passage 25 is a path through which cooling water circulates.

The protrusions 23 and 23 ′ are formed to communicate with the cooling passage 25 through the flow passage inlet 27 through which the coolant flows and the flow passage outlet 29 through which the coolant flows. The flow path inlet 27 and the flow path outlet 29 may be formed in the frame cover 41 according to design conditions.

In the frame 21, boundary ribs 31 connected to inner surfaces of each of the protrusions 23 and 23 'are formed perpendicular to the protrusions 23 and 23'. The boundary rib 31 blocks the cooling flow path 25 between the flow path inlet 27 and the flow path outlet 29 so that the coolant flowing into the flow path inlet 27 is not discharged directly to the flow path outlet 29. do. That is, the boundary ribs 31 allow the coolant to move in only one direction along the cooling passage 25 of the frame 21.

The frame 21 is provided with a plurality of compartment ribs 33 in parallel with the boundary ribs 31. That is, the partition rib 33 is provided perpendicular to the circumferential direction of the frame 21.

The compartment rib 33 is provided at intervals in the cooling passage 25 to partition the cooling passage 25, and the passage passage 33 ′ communicating between the divided cooling passages 25 is the compartment. It is formed alternately at both ends of the rib (33). That is, the flow path 33 'is alternately formed at one end of the compartment rib 33 and the other end of the neighboring compartment rib 33.

When the flow passage 33 'is alternately formed at both ends of the partition rib 33, the flow of the cooling water in the cooling passage 25 is zigzag.

Width (a) and height (b) of the passage passage (33 ') has a close relationship with the flow resistance and turbulence formation of the cooling water, in particular, the passage passage (33) for the length of the partition rib (33) The thermal analysis simulation confirmed that the ratio of width a is a significant factor in the pressure drop phenomenon.

For example, while the length of the partition rib 33 is fixed to 600 mm and the height B of the flow path 33 'is 130 mm, the width A of the flow path 33' is 125 mm. When formed, a pressure loss of approximately 3,500 Pa (pascal) occurred, whereas a pressure loss of approximately 700 Pa occurred when the width A was formed at 250 mm.

When the length of the partition rib 33 is fixed to 600 mm and the height B of the flow passage 33 'is 130 mm, the width A of the flow passage 33' is 125 mm <a <300 mm. Is optimized for flow resistance and heat transfer, and preferably, the width A of the flow path 33 'is formed to be 250 mm.

If the width A of the passage passage 33 'is formed to be 125 mm or less, the flow resistance becomes large and the movement of the cooling water does not occur smoothly. In addition, when the width A of the passage passage 33 'is formed to be 300 mm or more, the formation of turbulence due to the movement of the cooling water is insufficient, resulting in low heat transfer efficiency.

On the other hand, the plurality of partition ribs 33 are formed at regular intervals along the circumferential direction of the frame 21. For example, a total of seven partition ribs 33 may be provided at 45 degree intervals along the circumferential direction of the frame 21.

At least one guide rib 35 is provided in the cooling passage 25 communicating with the passage inlet 27. The guide rib 35 includes a parallel portion 35a formed parallel to the inflow direction of the coolant and a guide portion 35b inclined toward the flow passage 33 '.

The parallel part 35a serves to guide the coolant flowing through the flow path inlet 27 to the guide part 35b. In addition, the guide part 35b guides the moving direction so that the coolant moving through the parallel part 35a faces the flow path 33 '.

In FIG. 2, the guide part 35b is provided perpendicular to the parallel part 35a, but is not necessarily the case, and may be provided in various shapes for guiding a flow direction of the coolant.

For example, the parallel portion 35a and the guide portion 35b may be formed in a curved surface so that the coolant flowing into the flow path inlet 27 faces the flow path 33 'without being clearly distinguished. In addition, when the flow path inlet 27 is formed to face the flow path 33 ', the guide rib 35 for guiding the movement of the cooling water may be omitted.

On the other hand, the frame 21 is coupled to the frame cover 41. The frame cover 41 is formed with a through hole 41 ′ into which the frame 21 is inserted. The inner diameter of the frame cover 41 is formed to be the same as the outer diameter of the protrusions 23 and 23 'so that the frame 21 is press-fitted into the through hole 41'. Therefore, the cooling passage 25 is shielded by the frame cover 41, and the cooling water does not flow out.

Hereinafter, the operation of the motor cooling apparatus according to the present invention having the configuration as described above will be described in detail.

When power is applied to the motor, current flows through the coil of the stator, and the rotor rotates by the magnetic force generated in the stator.

When the rotor rotates at a high speed, energy loss occurs due to mechanical friction in the energy conversion process, and the energy loss is generally converted into heat.

The heat generated in this way causes a decrease in the function of the electric motor, so that the coolant flows into the flow path inlet 27 to cool the heat generated in the electric motor. The cooling water is guided in the flow direction by the guide ribs 35 and circulates through the cooling flow path 25 through the flow path path 33 ′ formed in the partition rib 33.

The width A of the passage passage 33 'is designed under optimum conditions with respect to the length of the compartment rib 33 to minimize the flow resistance of the cooling water. That is, the pressure drop phenomenon of the cooling water is reduced, and the circulation of the cooling water occurs smoothly.

Cooling water is initially introduced in a state similar to a laminar flow having a substantially regular flow. The flow passage 33 'alternately formed at both ends of the compartment rib 33 is a movement of the cooling water, as shown in FIG. Change direction repeatedly

In this process, the coolant in a laminar-like state with a smooth and regular flow changes into a turbulent state mixed with each other with irregular movement. Since the turbulence formed in the cooling passage 25 has a relatively high heat transfer rate, convective heat transfer due to the movement of the fluid as well as heat conduction between the solid and the fluid occurs actively. Cooling efficiency is improved.

That is, when the coolant flows into the cooling flow path 25 to have a laminar flow, the heat is generated only by the heat conduction of the cooling water flowing through the surface of the frame 21, whereas the cooling water passes through the flow path 33 '. Is converted to turbulence so that convective heat transfer occurs in the radial direction of the frame 21, so that heat transfer increases rapidly.

As described above, the cooling water converted into the turbulent state by moving the cooling flow path 25 absorbs the heat generated by the electric motor and is discharged to the flow path outlet 29.

On the other hand, since the partition rib 33 is provided perpendicular to the circumferential direction of the frame 21, it is easier to manufacture and assemble than that provided on the curved surface along the circumferential direction of the frame 21.

The scope of the present invention is not limited to the embodiments described above, but is defined by the claims, and various changes and modifications can be made by those skilled in the art within the scope of the claims. It is self-evident.

1 is a perspective view showing the configuration of a motor cooling apparatus according to the prior art.

Figure 2 is a perspective view showing the configuration of a preferred embodiment of the motor cooling apparatus according to the present invention.

3 is a front view showing a compartment rib constituting an embodiment of the present invention.

Figure 4 is a perspective view schematically showing the flow of cooling water in the embodiment of the present invention.

Explanation of symbols on the main parts of the drawings

21: frame 21 ': coupling hole

23,23 ': protrusion 25: cooling passage

27: Euro exit 29: Euro exit

31: boundary rib 33: compartment rib

33 ': Europath 35: Guide rib

35a: parallel part 35b: guide part

41: frame cover 41 ': through hole

Claims (6)

A frame having a coupling hole in which a rotor and a stator are installed therein, and a cooling flow path through which coolant is moved, formed at an outer surface thereof; A frame cover into which the frame is press-fitted to shield the cooling flow path from the outside; At least one flow path inlet and a flow path outlet formed in the frame or the frame cover to communicate with the cooling flow path, the cooling water flowing in and out; Partition ribs provided at intervals on the cooling passages to partition the cooling passages and alternately formed at both ends of the passage passages for communicating between the divided cooling passages; And a guide rib provided in the cooling passage communicating with the passage inlet and extending from the passage inlet toward the passage. The motor cooling apparatus according to claim 1, wherein the compartment ribs are provided at regular intervals along the circumferential direction of the frame. 3. The motor cooling apparatus according to claim 2, wherein the length of the partition rib is 600 mm and the height of the flow path is 130 mm. 4. The motor cooling apparatus according to claim 3, wherein a width of the flow path is larger than 125 mm and smaller than 300 mm. delete 5. The motor cooling apparatus according to any one of claims 1 to 4, wherein the guide rib includes a parallel portion formed in parallel with the inflow direction of the coolant and a guide portion inclined toward the flow path.

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