KR102669606B1 - Sealing structure of the cable in the drive motor - Google Patents

Abstract

The present invention relates to a cable airtight structure for a drive motor in which a cable for applying power or a control signal required for operation of the drive motor is airtight in the area where it passes through the housing of the drive motor.
The cable airtight structure of the drive motor according to the present invention includes a housing (10) in which cables (C) are mounted at intervals from each other; A liquid gasket (30) applied between adjacent cables (C) and on top of the cable (C); And it is coupled to the upper part of the housing 10, and while coupled to the housing 10, the liquid gasket 30 is pressed so that the liquid gasket 30 is connected to the outer surface of the cable C and the housing ( 10) includes a cover 20 to fill the space between them, and an application groove 12 for receiving the liquid gasket 30 is formed in the housing 10 in a direction perpendicular to the cable C. The liquid gasket 30 pressurized by the cover 20 fills the application groove 12 and comes into close contact with the circumference of the cable C, making it airtight.

Description

SEALING STRUCTURE OF THE CABLE IN THE DRIVE MOTOR}

The present invention relates to a cable airtight structure for a drive motor that ensures that the cable for applying power or control signals required for operation of the drive motor is airtight in the area where it passes through the housing of the drive motor.

A drive motor for generating driving force by supplying power is provided with a cable (C) for applying power or control signals necessary for operation of the drive motor (M).

Since current flows inside the driving motor (M) when it operates, a seal (140) is applied to airtighten the cable (C) to prevent foreign substances such as moisture and dust from penetrating from the outside. Since the seal 140 made of rubber is an elastic material, it airtightens the space between the housing 110 of the drive motor M and the cable C to prevent moisture or foreign substances from penetrating from the outside. In particular, the diameter of the area where the cable C passes through the seal 140 is reduced to ensure airtightness through elasticity after assembly.

However, since the cable C and the seal 140 must be assembled, a separate assembly process is added, and if the seal 140 is torn during assembly, an airtightness failure occurs.

Additionally, as durability progresses, airtightness failure occurs due to thermal deformation of the seal 140.

KR 10-2020-0085852 A(2020.07.15, Name: Cable seal assembly)

The present invention was invented to solve the above problems, and its purpose is to provide a cable airtight structure for a drive motor in which airtightness can be achieved simply by assembling the cover and housing without applying a seal, which is a separate part.

The cable airtight structure of the drive motor according to the present invention for achieving the above object includes a housing in which cables are mounted at intervals from each other; A liquid gasket applied between adjacent cables and on top of the cables; and a cover coupled to the upper part of the housing and pressing the liquid gasket while coupled to the housing so that the liquid gasket fills the space between the outer surface of the cable and the housing. An application groove for receiving the liquid gasket is formed in a direction perpendicular to the cable, and the liquid gasket pressed by the cover fills the application groove and adheres to the circumference of the cable, making it airtight.

The housing is formed at a predetermined depth from the top of the housing, and a plurality of cable holders are formed to support the lower part of the cable, and the application groove is formed deeper than the cable holder.

The cable holder is characterized in that it is formed in plurality at intervals from each other in a direction perpendicular to the cable.

The application groove in the housing is characterized in that it is formed longer than the section where the cable holder is formed.

The end of the application groove formed at the outermost portion of the cable holder in the application groove is formed in a round shape to have a certain radius.

The cover is characterized in that pressing portions extending downward from the bottom of the cover to pressurize the liquid gasket between the adjacent cables are formed at intervals.

The cable is positioned between the pressing parts adjacent to each other.

The lower outer side of the outermost pressing part among the pressing parts is characterized in that it is formed in a round shape.

The round shapes of the pressing portion and the application groove are characterized in that they have the same radius of curvature.

A gap is formed between the end of the application groove and the outer lower end of the pressing portion.

A flow groove through which the liquid gasket flows is formed on the bottom of the cover.

According to the cable airtight structure of the drive motor of the present invention having the above configuration, airtightness can be achieved without a separate process of assembling a seal by applying a liquid gasket before assembling the cover to the housing.

Additionally, since the liquid gasket is pressurized by the cover and surrounds the entire circumference of the cable, the airtightness process is simplified.

Figure 1 is a perspective view of a drive motor to which a cable airtight structure according to the prior art is applied.
Figure 2 is a plan view showing the airtight structure of a cable according to the prior art.
Figure 3 is a cross-sectional view showing the airtight structure of a cable according to the prior art.
Figure 4 is a perspective view showing a state in which the cover, cable, and housing are assembled according to the cable airtight structure of the drive motor according to the present invention.
Figure 5 is an exploded perspective view showing the state before the cover, cable, and housing are assembled according to the cable airtight structure of the drive motor according to the present invention.
Figure 6 is a cross-sectional view of the cable airtight structure of the drive motor according to the present invention.
Figure 7 is a cross-sectional view taken along line I-I of Figure 6.
Figure 8 is an enlarged cross-sectional view of the main part of the cable airtight structure of the drive motor according to the present invention.
Figure 9 is a plan view, front view, and side view showing the shape of the housing in the cable airtight structure of the drive motor according to the present invention.
Figure 10 is a plan view, front view, and side view showing the shape of the cover in the cable airtight structure of the drive motor according to the present invention.
Figure 11 is a schematic diagram showing the process of assembling the cover, cable, and housing for the cable airtight structure of the drive motor according to the present invention.
Figure 12 is a front cross-sectional view and a side cross-sectional view showing the process of a liquid gasket penetrating between the cable and the housing by the cover in the cable airtight structure of the drive motor according to the present invention.
Figure 13 is a CT (Computed tomography) photograph showing the actual application of the cable airtight structure of the drive motor according to the present invention.

Hereinafter, the cable airtight structure of the drive motor according to the present invention will be described in detail with reference to the attached drawings.

The cable airtight structure of the drive motor according to the present invention includes a housing 10 in which cables C are held at intervals from each other, and a liquid gasket applied between adjacent cables C and on top of the cable C. (30) and the upper part of the housing 10, and while being coupled to the housing 10, the liquid gasket 30 is pressed so that the liquid gasket 30 is outside the cable (C). It includes a cover 20 to fill the space between the side and the housing 10, and an application groove for receiving the liquid gasket 30 in the housing 10 in a direction perpendicular to the cable C. 12) is formed, and the liquid gasket 30 pressurized by the cover 20 fills the application groove 12 and comes into close contact with the circumference of the cable C, making it airtight.

The housing 10 is formed on one side of the drive motor (M). A cable (C) is installed through the housing (10) to supply power necessary for operation of the driving motor (M) or to transmit signals necessary for controlling the driving motor (M).

The cables (C) are placed in the housing (10) at intervals from each other.

The cable holder 11 is formed to support the lower part of the cable (C) in order to mount the cable (C) in the housing (10). The cable mounting portions 11 are formed in the housing 10 at intervals from each other. As shown in FIG. 5, the cable holder 11 has an open top and is formed to have a predetermined depth from the top of the housing 10. The lower end of the cable holder 11 is formed in a shape that matches the lower part of the cable (C). The cable (C) is inserted into the cable holder 11 through the open top of the cable holder 11 and is placed in a seated form on the cable holder 11, thereby preventing left and right movement. .

The application groove 12 is formed in the housing 10 in a direction perpendicular to the cable C. That is, the application groove 12 is formed in the arrangement direction of the cable holder 11. In FIG. 5, just as the cable holder 11 is formed from the upper left to the lower right of the drawing, the application groove 12 is also formed from the upper left to the lower right of the drawing.

The application groove 12 is also formed at a predetermined depth to accommodate the liquid gasket 30 therein. At this time, the depth of the application groove 12 is formed deeper than the cable holder 11. The depth of the application groove 12 is formed deeper than the cable holder 11, so that the lowermost end of the application groove 12 is located lower than the bottom of the cable holder 11. The depth of the application groove 12 is formed deeper than the cable holder 11, so that the liquid gasket 30 flows along the application groove 12 at the lower part of the cable C, so that the liquid gasket 30 flows along the application groove 12. (30) is applied around the cable (C) to fill the gap between the circumference of the cable (C) and the housing (10) and the cover (20) to make it airtight.

Meanwhile, the length of the application groove 12 (length from upper left to lower right in FIG. 5) is formed to be longer than the width at which the cable mounting portion 11 is arranged. Accordingly, a certain space is formed between the outer end of the outermost cable holder 11 and the end of the application groove 12. Looking at (a) of Figure 9, a gap 'S' is formed between the outer end of the cable holder 11 and the end of the application groove 12, and the application groove ( 12) is formed longer.

The liquid gasket 30 can be sufficiently injected to the outside of the outermost cable C through the space equal to the interval 'S'.

In addition, the outermost portion of the cable mounting portion 11 in the application groove 12 is formed in a round shape with a certain radius. That is, as indicated by 'R' in (b) of FIG. 9, the end of the application groove 12 is formed in a round shape, and the liquid gasket 30 applied to the end of the application groove 12 is injected. Make this easy.

The liquid gasket 30 is made of silicon, etc., and fills the gap between the outer surface of the cable C, the cover 20, and the housing 10. It can be applied through an injector of the liquid gasket 30, etc., and after application, it has elasticity to enable airtightness.

The cover 20 is coupled to the upper part of the housing 10. The cover 20 is coupled to the upper part of the housing 10, and while coupled to the housing 10, the liquid gasket 30 is pressed so that the liquid gasket 30 is attached to the cable C. Make sure to fill the space between the outer surface and the housing 10.

To this end, the cover 20 includes a pressurizing portion (C) extending downward from the bottom of the cover 20 in order to efficiently pressurize the liquid gasket 30 between the cables C. 21) is formed. The pressing portions 21 are formed at intervals from each other and serve to press downward the liquid gasket 30 between the adjacent cables C.

The pressing portion 21 is formed so that the cable C is positioned between the pressing portions 21 adjacent to each other. In particular, the outermost pressing part 21 among the pressing parts 21 has a round shape at the lower end. At this time, the radius of curvature of the round shape formed on the outside of the lower end of the pressing portion 21 and the round shape formed at the end of the application groove 12 are formed to be the same, but the liquid gasket 30 is formed in between. A gap is formed to position (see Figure 8)

A flow groove 22 is formed on the bottom of the cover 20. The flow groove 22 allows the liquid gasket 30 to flow along the longitudinal direction of the cover 20 on the bottom of the cover 20.

Figure 11 shows the assembly sequence of the cable airtight structure of the drive motor of the present invention.

As shown in (a) of FIG. 11, the housing 10, the cable C, and the cover 20 are prepared, and the cable C is attached to the cable holder 11 of the housing 10. ) is mounted on. Each cable (C) is mounted on each of the cable mounting portions (11).

Afterwards, a liquid gasket 30 is applied on top of the cable C and between adjacent cables C (see Figure 11 (b)). At this time, the liquid gasket 30 is first applied between the cable C and the housing 10, and later the area where the cover 20 and the housing 10 come into contact, that is, the cable C is placed at the top. Apply the liquid gasket (30) to. Here, the amount of the liquid gasket 30 applied is set to be about 150% or more than the volume of the space to be filled with the liquid gasket 30. When assembling the cover 20, it is applied in an amount of 150% or more compared to the space, reflecting the loss flowing out of the cover 20 and the housing 10.

When application of the liquid gasket 30 is completed, the cover 20 is assembled to the housing 10 (see (d) of FIG. 11). As the cover 20 is slowly lowered, the pressing portion 21 of the cover 20 presses the liquid gasket 30, allowing the liquid gasket 30 to penetrate around the cable C. As the cover 20 is coupled to the housing 10, the pressing portion 21 presses the applied liquid gasket 30. When the liquid gasket 30 is pressurized by the pressurizing part 21, the liquid gasket 30 applied on top of the cable C or between the cables C adjacent to each other is shown in FIG. 12. As shown, it is pushed by the pressing part 21 and injected into the lower part of the cable (C). The liquid gasket 30, while applied to the top and side of the cable C, is pushed by the pressing part 21 and is injected into the lower part of the cable C.

In this way, when the assembly of the cover 20 and the housing 10 is completed (see (d) of FIG. 11), the liquid gasket 30 surrounds the entire outer circumference of the cable C, Airtightness is achieved by the liquid gasket (30).

Meanwhile, a CT photograph of the cable airtight structure of the drive motor according to the present invention is shown in FIG. 13. Looking at FIG. 13, it can be seen that the liquid gasket 30 wraps around the cable C and fills the space between the cover 20 and the housing 10, thereby completing airtightness. Some bubbles (b) are present, but this is not related to airtightness.

10: housing
11: Cable holder
12: Applicator
20: cover
21: pressurizing part
22: floating groove
30: Liquid gasket
110: housing
140: thread
M: Drive motor
C: cable
b: air bubbles

Claims (11)

A housing in which cables are placed at intervals from each other;
A liquid gasket applied between adjacent cables and on top of the cables; and
A cover coupled to the upper part of the housing and pressurizing the liquid gasket while coupled to the housing so that the liquid gasket fills the space between the outer surface of the cable and the housing;
Including,
An application groove for receiving the liquid gasket is formed in the housing in a direction perpendicular to the cable,
The liquid gasket pressurized by the cover fills the application groove and adheres closely to the circumference of the cable, making it airtight,
The housing is formed at a predetermined depth from the top of the housing, and a plurality of cable holders are formed to support the lower part of the cable,
The cable holder is open at the top.
Cable airtight structure of the drive motor characterized by . According to paragraph 1,
In the housing, the application groove is formed deeper than the cable holder.
Cable airtight structure of the drive motor characterized by . According to paragraph 2,
The cable holder is formed in plurality at intervals from each other in a direction perpendicular to the cable.
Cable airtight structure of the drive motor characterized by . According to paragraph 3,
In the housing, the application groove is formed longer than the section where the cable holder is formed.
Cable airtight structure of the drive motor characterized by . According to clause 4,
The end of the application groove formed in the application groove at the outermost portion of the cable holder is formed in a round shape to have a certain radius.
Cable airtight structure of the drive motor characterized by . According to clause 5,
The cover extends downward from the bottom of the cover and has pressurizing portions formed at intervals to pressurize the liquid gasket between the adjacent cables.
Cable airtight structure of the drive motor characterized by . According to clause 6,
The cable is located between the pressing parts adjacent to each other.
Cable airtight structure of the drive motor characterized by . According to clause 6,
The lower outer side of the outermost pressing part among the pressing parts is formed in a round shape.
Cable airtight structure of the drive motor characterized by . According to clause 8,
The round shape of the pressing part and the application groove have the same radius of curvature.
Cable airtight structure of the drive motor characterized by . According to clause 8,
A gap is formed between the end of the application groove and the lower outer side of the pressing portion.
Cable airtight structure of the drive motor characterized by . According to clause 6,
A flow groove through which the liquid gasket flows is formed on the bottom of the cover.
Cable airtight structure of the drive motor characterized by .

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