KR102496628B1 - Dynamic waterproofing test device for dust cap assembly - Google Patents

Abstract

The present invention relates to a dynamic waterproofing test device for a dust cap assembly, which tests a waterproofing performance of a dust cap assembly shielding moisture flowing into a rack housing along a pinion shaft of a vehicle. The purpose of the present invention is to provide the dynamic waterproofing test device for a dust cap assembly, capable of accurately testing the waterproofing test in a severe dynamic condition by repeatedly applying vibration to the dust cap assembly. According to the present invention, the dynamic waterproofing test device for a dust cap assembly includes: a bed having a waterproofing test space; a movable support unit fixing the dust cap assembly by being arranged on one side of the test space of the bed and arranging the dust cap assembly in the waterproofing test space in a horizontal longitudinal direction; a fixed support unit arranged on the other side of the waterproofing test space formed in the bed and supporting a dust packing of the dust cap assembly by attaching the dust packing to a contact support piece; and a spray nozzle spraying water to the surface of the dust cap assembly arranged in the longitudinal direction in the test space at a high pressure. The movable support unit includes: a movable support body arranged on the other side of the bed as a horizontal movement structure; a clamp unit arranged on the inner side of the movable support body and fixing the dust cap assembly by inserting the dust cap assembly; and a vibration generating unit providing a moving force to the movable support body so that the movable support body reciprocates in the horizontal longitudinal direction, wherein the vibration generating unit vibrates the dust cap assembly while the dust cap assembly moves in the horizontal longitudinal direction.

Description

Dynamic waterproofing test device for dust cap assembly}

The present invention relates to a dynamic watertight inspection device for a dust cap assembly, and more particularly, to a dynamic watertightness inspection device for inspecting the watertight performance of the dust cap assembly for shielding moisture flowing into a rack housing along a pinion shaft of a vehicle. It's about inspection equipment.

In general, a steering device of a vehicle includes a rack bar that receives rotational motion from a steering shaft, has a pinion gear formed under the steering shaft, and is engaged with the pinion gear to convert rotational motion input from the steering shaft into linear motion.

In addition, the steering device of the vehicle includes a rack housing surrounding the rack bar and the pinion gear, a bearing provided inside the rack housing and formed to surround the outer circumferential surface of the steering shaft to support the steering shaft, the upper side of which is seated on the outer circumferential surface of the steering shaft, and the other side of the bearing A stop ring supporting the bearing by being seated on the upper side and press-fitting, a plug coupled to the upper inner circumferential surface of the rack housing but provided on the upper part of the bearing and through which the steering shaft passes, and a dust seal provided on the upper inner circumferential surface of the plug to surround the steering shaft , and an O-ring provided between the plug and the rack housing to prevent oil leakage.

At this time, a dust packing supporting a dust cap and a dash panel is provided on an upper portion of the rack housing to prevent foreign matter such as dust or water from penetrating into the rack housing from the outside during driving or stopping.

However, in the steering device of a vehicle, the dust packing contacts the dash panel of the vehicle to perform a watertight function, the dust cap supports the middle, and the O-ring is assembled with the steering gear to perform a watertight function.

On the other hand, the dust cap assembly in which the dust packing is assembled at the assembly end of the dust cap requires stable sealing performance to block the inflow of foreign substances or moisture. However, in the related art, it is difficult to secure reliability according to the watertight test because the watertight performance is tested under static conditions in which vibration or shock is not applied.

KR 10-2020-0070751

An object of the present invention, which has been devised to solve the above problems, is to repeatedly provide variable vibration to the dust cap assembly, thereby verifying the watertight performance of the dust cap assembly under severe dynamic conditions in which various vibrations are continuously provided. It is to provide a dynamic watertight inspection device of an assembly.

The above object is achieved by the following structure provided by the present invention.

The dynamic watertight inspection device of the dust cap assembly according to the present invention,

a bed in which a watertight inspection space is formed; a movable support part disposed on one side of the inspection space of the bed to fix the dust cap assembly and disposing the dust cap assembly in the left and right longitudinal directions within the watertight inspection space; a fixing support portion disposed on the other side of the watertight inspection space formed in the bed and supporting the dust packing of the dust cap assembly in close contact with the close support piece; and a spray nozzle for spraying water at high pressure to the surface of the dust cap assembly disposed in the longitudinal direction within the inspection space,

The movable support unit, and a movable support disposed on the other side of the bed in a left and right forward and backward structure; a clamping unit disposed on an inner surface of the movable support to insert and fix the dust cap assembly; and a vibration generating unit that reciprocates and provides forward and backward forces to the movable support in the left and right longitudinal directions so that the dust cap assembly vibrates while advancing and retreating in the left and right longitudinal directions.

Preferably, the vibration generating unit includes a drive motor generating rotational force; an eccentric link arm for converting the rotational force of the driving motor into reciprocating force by connecting the rotating shaft of the driving motor and the movable support with an eccentric rotational structure; a driving wheel which is fixed to the rotating shaft of the driving motor and rotates in one direction; It includes an eccentric connector fixed to the eccentric part of the driving wheel and connecting the end of the eccentric link arm to the driving wheel in an eccentric rotation structure,

an adjustment rail formed on the driving wheel and fixing the eccentric coupler in a forward and backward structure; It is fastened between the driving wheel and the eccentric connector and is configured to further include an eccentric adjustment bolt for adjusting the formation position of the eccentric connector disposed on the control rail by adjusting the amount of fastening.

More preferably, the clamping unit includes a ball cage formed on an inner surface of the movable support; A clamp member assembled to the ball cage in a ball joint structure and tilting the ball cage to form a required clamping angle,

The clamp member has a ball head inserted into the ball cage at an outer end and assembled in a ball joint structure, and a clamping socket for clamping by inserting the dust cap assembly in the longitudinal direction is integrally formed at an inner end.

As described above, the present invention provides a dynamic inspection device for a dust cap assembly that accurately inspects watertight performance under severe dynamic conditions in which vibration is repeatedly applied to the dust cap assembly.

In particular, when the watertightness test of the dust cap assembly is performed through the present invention, the watertightness test is performed on the dustcap assembly under a condition more similar to the driving condition of an actual vehicle by vibration provided in the left and right longitudinal directions and twist provided in the forward and reverse directions. Therefore, higher reliability according to the watertight inspection can be secured.

1 to 3 show the overall configuration of a dynamic inspection device for a dust cap assembly proposed as a preferred embodiment of the present invention,
3 to 5 show detailed configurations of a movable support unit in a dynamic inspection device for a dust cap assembly proposed as a preferred embodiment of the present invention,
6 shows the watertightness inspection state of the dust cap assembly through the dynamic inspection device of the dust cap assembly proposed as a preferred embodiment in the present invention,
7 shows a dust cap assembly inspected for watertightness by a dynamic inspection device for a dust cap assembly proposed as a preferred embodiment of the present invention.

Hereinafter, a dynamic inspection device for a dust cap assembly proposed as a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 to 3 show the overall configuration of a dynamic inspection device for a dust cap assembly proposed as a preferred embodiment in the present invention, and FIGS. 3 to 5 show a dust cap assembly proposed as a preferred embodiment in the present invention. In the dynamic inspection device, the detailed configuration of the movable support is shown, and FIG. 6 shows the watertight inspection state of the dust cap assembly through the dynamic inspection device of the dust cap assembly proposed as a preferred embodiment in the present invention. FIG. shows the dust cap assembly inspected for watertightness by the dynamic inspection device for the dust cap assembly proposed as a preferred embodiment of the present invention.

As shown in FIG. 7, in the dust cap assembly 100 whose watertight performance is tested by the dynamic watertight inspection device proposed in the present invention, the dust packing 120 is installed at the assembled end of the dust cap body 110 made of a hollow body. It is composed of stacked and assembled forms and is an automobile part that blocks moisture flowing into the rack housing along the pinion shaft of the automobile.

In the dynamic watertight inspection device 1 according to the present invention, water is continuously applied to the dust packing 120 in a state where the dust packing 120 of the dust cap assembly 100 is in close contact with the close support piece 132. By spraying at high pressure, the watertight performance of the dust cap assembly 100 is inspected.

In particular, the dynamic watertightness inspection apparatus 1 according to the present invention performs a watertightness inspection under a dynamic condition in which vibration similar to that generated during driving of a vehicle is continuously applied during the watertightness inspection process, thereby checking the watertightness of the dust cap assembly 100. Improved reliability according to inspection is ensured.

As shown in FIGS. 1 to 3, the dynamic watertight inspection device 1 of the dust cap assembly 100 includes a bed 10 having a watertight inspection space 11 formed thereon; A movable support portion disposed on one side of the watertight inspection space 11 of the bed 10 to fix the rear end of the dust cap assembly 100 and disposing the dust cap assembly 100 in the left and right longitudinal directions in the watertight inspection space 11 ( 20) and; It is disposed on the other side of the watertight inspection space 11 formed in the bed 10, faces the movable support part 20, and supports the dust packing 120 of the dust cap assembly 100 in close contact with the support piece 32 a fixed support 30 having a fixed support 31; and a spray nozzle unit 40 for spraying water at a high pressure to the dust cap assembly 100 disposed in the longitudinal direction within the watertight inspection space 11 .

The spray nozzle unit 40 sprays water supplied at high pressure through a water supply pump (not shown) through a plurality of spray nozzles 41 at various angles to the dust packing 120 requiring a watertightness inspection, Watertightness between the dust packing 120 and the dust cap body 110 and between the dust packing 120 and the close support piece 32 is inspected.

In addition, a water collection tank 50 is provided at the bottom of the watertight inspection space 11 where the spray nozzle unit 40 is disposed, and the water sprayed to the dust cap assembly 100 through the spray nozzle unit 40 falls under its own weight. So that the water is collected through the water collection tank 50.

In addition, on the other side of the watertight inspection space 11, a transfer rail 33 is formed in the left and right longitudinal directions, and a fixed support 31 having a close contact support piece 32 formed on the inside of the transfer rail 33 moves left and right forward and backward. placed in the structure.

At this time, between the fixed support 31 and the bed 10, the fixed support 31 is moved left and right along the transfer rail 33 according to the amount of fastening, and the spacing adjustment bolt 34 is fixed to one point of the transfer rail 33. ) is formed, so that the distance between the fixed support 31 and the movable support 21 is adjusted by moving the fixed support 31 left and right through the tightening amount of the distance adjusting bolt 34 as shown in FIG. 3a.

Therefore, the manager moves the fixing support 31 left and right through the gap adjusting bolt 34 according to the length of the dust cap assembly 100 requiring watertightness inspection at the time of initial setting, and moves the fixing support 31 facing each other. By adjusting the distance between the supports 21, a watertightness test is performed in common of dust cap assemblies 100 having various lengths.

In particular, as shown in FIGS. 1 to 5 , the movable support part 20 is disposed on one side of the watertight inspection space 11 of the bed 10 in a left and right forward and backward structure, and the dust cap assembly 100 is inserted into the inner surface. a movable support 21 on which a clamping unit 22 is fixed by being fixed; and a vibration generating unit 23 that reciprocates and provides forward and backward forces to the movable support 21 in the left and right longitudinal directions so that the dust cap assembly 100 moves forward and backward in the left and right longitudinal directions.

Here, the clamping unit 22 for clamping the dust cap assembly 100 requiring the watertight inspection includes, as shown in FIG. 3, a ball cage 23a formed on an inner surface of the movable support 21; It is assembled to the ball cage 23a in a ball joint structure, and includes a clamp member 23b that tilts around the ball cage 23a to form a required clamping angle.

Preferably, a ball head 23b-a inserted into the ball cage 23a and assembled into a ball joint structure is formed at an outer end of the clamp member 23b, and an end of the dust cap assembly 100 is formed at an inner end. A clamping socket 23b-b for clamping by inserting in the longitudinal direction is integrally formed.

At this time, the clamp member 23b tilted at a set angle within the ball cage 23a is pressed by the fixing bolt 23c entered into the ball cage 23a, fixed at a set angle, and dust cap assembly ( 100) is placed in the longitudinal direction in the watertight inspection space at a set angle.

Therefore, the clamp member 23b is tilted at a required angle within the ball cage 23a according to the shape or length of the dust cap assembly 100, thereby fixing the dust packing 120 of the dust cap assembly 100. It is fixed in close contact with the support piece 32 of the support part 30 .

In addition, advance and retreat rails 21a are formed on one side of the watertight inspection space 11 of the bed 10 in the left and right longitudinal directions, and movable supports 21 are disposed on the advance and retreat rails 21a in a left and right forward and backward structure.

And, the vibration generating unit 23 includes a driving motor 23a generating rotational force; An eccentric link arm 23b is connected between the rotation shaft of the drive motor 23a and the movable support 21 in an eccentric rotation structure to convert the rotational force of the drive motor 23a into a reciprocating forward and backward force.

Therefore, as shown in FIGS. 3A and 6 , the movable support 21 fixing the dust cap assembly 100 in the longitudinal direction through the clamp member 23b converts the rotational force of the driving motor 23a to the eccentric link arm 23b. It converts into a reciprocating forward and backward force through a reciprocating force and forms a dynamic support state in which it vibrates repeatedly in the left and right longitudinal directions by the provided reciprocating vibration.

In this embodiment, while the dust cap assembly 100 is repeatedly vibrated 600,000 times or more in the left and right longitudinal direction through the movable support part 20, the dust cap formed a dynamic support state for water through the spray nozzle part 40. By spraying the dust packing 120 of the assembly 100 at high pressure, the dust cap assembly 100 is configured to be repeatedly watertightly inspected in a dynamic vibration state.

Preferably, the vibration generating unit 23 includes a drive wheel 23c which is fixed to the rotation shaft of the drive motor 23a and rotates in one direction; An eccentric connector 23d is fixed to the eccentric part of the driving wheel 23c and connects the end of the eccentric link arm 23b to the driving wheel 23c in an eccentric rotation structure.

In particular, in this embodiment, an eccentric adjustment structure is provided to adjust the eccentric amount of the eccentric coupler 23d by adjusting the fixing position of the eccentric coupler 23d to the drive wheel 23c, thereby increasing the eccentricity of the eccentric coupler 23d. Through the adjustment, the amount of vibration applied to the dust cap assembly 100 can be adjusted.

As shown in FIGS. 2 and 4, the eccentric adjustment structure provided in this embodiment includes an adjustment rail 23c-a formed on the driving wheel 23c and fixing the eccentric connector 23d in a forward and backward structure; An eccentric adjusting bolt 23c-b fastened between the drive wheel 23c and the eccentric connector 23d and adjusting the formation position of the eccentric connector 23d disposed on the control rail 23c-a by adjusting the tightening amount. ).

Therefore, when the eccentricity of the eccentric coupler 23d is reduced by the eccentric adjustment bolts 23c-b, the advance and retreat distance of the movable support 21 is shortened and the amount of vibration is reduced, and conversely, the eccentricity of the eccentric coupler 23d is increased. When the movable support 21 advances and retreats, the amount of vibration increases.

Thus, the operator appropriately adjusts the amount of vibration according to the standard of the dust cap assembly 100 that requires the water tightness inspection, and precisely performs the dynamic watertight inspection of the dust cap assembly 100.

In addition, in the present invention, a torsion generating unit for repeatedly twisting the dust cap assembly 100 in the forward and reverse directions is applied to the movable support part 20 for repeatedly dynamically vibrating the dust cap assembly 100 in the left and right longitudinal directions. By adding (24), the dust cap assembly 100 allows the watertightness inspection to be performed under a condition more similar to the driving condition of an actual vehicle by vibration provided in the left and right longitudinal directions and twist provided in the forward and reverse directions.

In particular, the torsion generating unit 24 proposed as a preferred embodiment in the present invention uses the vibration force provided in the left and right longitudinal directions through the vibration generating unit 23 without a separate driving means to form the dust cap assembly 100. ) to twist the clamping member 23b in the forward and reverse directions.

As shown in FIG. 5, the torsion generating unit 24 proposed in this embodiment is arranged to face each other between the movable support 21 and the clamping unit 23, which are mutually separated and face each other, so that the vibration generating unit 23 a pair of oblique plane support rims 24a and 24b which allow the clamping unit 22 to twist forward and backward by interfering with each other by the advancing and retreating action of the movable support body 21 advancing and retreating in the left and right longitudinal directions; A torsion spring 24c providing elastic torsional force between the movable support 21 and the clamping unit 22 is included.

Preferably, the inclined surface support protrusions 24a-a and 24b-a are formed in a radial structure on the inclined surface support rims 24a and 24b, so that the inclined surface support rims 24a and 24b are close to each other and the inclined surface support protrusions ( Through 24a-a and 24b-a), the oblique planes interfere with each other in one direction to twist in one direction, and when spaced apart from each other, they are twisted in the opposite direction by the torsion spring 24c.

Therefore, as shown in FIG. 6, the dust cap assembly 100 is twisted forward and backward through the vibration generating unit 23 in the left and right longitudinal directions and the torsion generating unit 24, so as to correspond to the driving condition of the actual vehicle. Since the watertightness inspection is performed under more similar conditions, a more precise watertightness inspection of the dust cap assembly is performed.

1. Dynamic watertight inspection device of dust cap assembly
10. Bed 11. Watertight inspection space
20. Movable support 21. Movable support
21a. back and forth rail
22. Clamping unit 23a. ball cage
23 b. clamp member 23b-a. ball head
23b-b. clamping socket 23c. fixing bolt
23. Vibration generating unit 23a. drive motor
23 b. Eccentric link arm 23c. drive wheel
23c-a. Control rail 23c-b. Eccentric Adjustment Bolt
23d. eccentric connector
24. Torsion generating unit 24a. Beveled support rim
24a-a. Oblique support protrusion 24b. Beveled support rim
24b-a. Oblique support protrusion 24c. torsion spring
30. fixed support 31. fixed support
32. Close support piece 33. Transfer rail
34. Gap adjustment bolt
40. Spray nozzle part 41. Spray nozzle
50. Water tank 60. Shatterproof cover
100. Dust cap assembly
110. Dust cap body 120. Dust packing

Claims (4)

a bed in which a watertight inspection space is formed; a movable support part disposed on one side of the inspection space of the bed to fix the dust cap assembly and disposing the dust cap assembly in the left and right longitudinal directions within the watertight inspection space; a fixing support portion disposed on the other side of the watertight inspection space formed in the bed and supporting the dust packing of the dust cap assembly in close contact with the close support piece; and a spray nozzle for spraying water at high pressure to the surface of the dust cap assembly disposed in the longitudinal direction within the inspection space,
The movable support,
A movable support disposed on the other side of the bed in a left and right forward and backward structure;
a clamping unit disposed on an inner surface of the movable support and inserting and fixing the dust cap assembly;
a vibration generating unit that reciprocates and provides forward and backward forces to the movable support in the left and right longitudinal directions so that the dust cap assembly vibrates while moving forward and backward in the left and right longitudinal directions; and
a twist generating unit configured to repeatedly twist the dust cap assembly in forward and reverse directions;
The torsion generating unit is configured to be separated from each other and disposed to face each other between the opposing movable support and the clamping unit, and the vibration generating unit interferes with the oblique plane by the advancing and retreating action of the movable support in the left and right longitudinal directions, thereby interfering with the clamping unit. a pair of oblique support rims to twist in this normal region; A torsion spring providing an elastic torsional force between the movable support and the clamping unit;
Beveled support protrusions are formed on the inclined surface support rim in a radial structure, and as the inclined surface support rims approach each other, the oblique surface interferes with each other in one direction through the inclined surface support protrusions to twist in one direction, and when spaced apart from each other, they are twisted in the opposite direction by the torsion spring. A dynamic watertight inspection device for a dust cap assembly, characterized in that it is configured to do so. The method of claim 1, wherein the vibration generating unit comprises: a driving motor generating rotational force; an eccentric link arm for converting the rotational force of the driving motor into reciprocating force by connecting the rotating shaft of the driving motor and the movable support with an eccentric rotational structure; a driving wheel which is fixed to the rotating shaft of the driving motor and rotates in one direction; The dynamic watertight inspection device of the dust cap assembly, characterized in that it comprises an eccentric connector fixed to the eccentric part of the driving wheel and connecting the end of the eccentric link arm to the driving wheel in an eccentric rotation structure. According to claim 2, An adjustment rail formed on the driving wheel and fixing the eccentric connector in a forward and backward structure; The dynamic watertight inspection device of the dust cap assembly, characterized in that it is configured to further include an eccentric adjustment bolt fastened between the drive wheel and the eccentric connector and adjusting the formation position of the eccentric connector disposed on the control rail by adjusting the tightening amount. According to claim 1, wherein the clamping unit and a ball cage formed on the inner surface of the movable support; A clamp member assembled to the ball cage in a ball joint structure and tilting the ball cage to form a required clamping angle,
The clamp member has a ball head inserted into a ball cage at an outer end and assembled in a ball joint structure, and a clamping socket for clamping by inserting the dust cap assembly in a longitudinal direction at an inner end is formed integrally with the dust cap. Dynamic water tightness inspection device for assemblies.

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