JPH09267689A - Waterproofing structure of door mirror driving unit - Google Patents

Abstract

PROBLEM TO BE SOLVED: To improve the reliability of a waterproofing function by preventing the dislocation of a seal protrusion against a seal groove. SOLUTION: A seal protrusion 24 is formed at an upper case 20 to form ribs 26, 27 on both sides of the seal protrusion 24. A stepped seal groove 46 whose upper width is wide is provided at a lower case 40. After sealing agent is poured in the seal groove 46, the upper case 20 is overlapped on it to push out the sealing agent 30 around the seal protrusion 24. The outer sides 26b, 27b of the ribs 26, 27 are brought into sliding contact with the groove surface 46x of the seal groove 46. In the course of jointing a case and after jointing the case, therefore, the seal protrusion 24 is always maintained in the middle position of the seal groove 46, thus preventing dislocation from occurring.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a waterproof structure for a drive unit for a door mirror.

[0002]

2. Description of the Related Art Generally, a drive unit is arranged inside a door mirror of an automobile. That is, the mirror drive unit that houses the electric mechanism for adjusting the mirror angle and the electric storage drive unit that houses the electric storage device for tilting the door mirror are arranged. These drive units mainly have a waterproof structure so that the motor housed therein does not rust.

Conventionally, as such a waterproof structure, for example, as shown in FIG. 1, case portions 2 and 4 each having a seal projection 3 and a seal groove 5 formed on a joint surface are joined together,
There is a system in which a sealant 6 is filled between the seal protrusion 3 and the seal groove 5. That is, in this type of waterproof structure, as shown in FIG. 1 (I), after pouring the sealing agent 6 into the seal groove 5, as shown in FIG. 1 (II), both case portions 2 and 4 are overlapped. The seal projection 3 is inserted into the seal groove 5.
At this time, the seal projection 3 is inserted into the seal groove 5 so as to push out the sealant 6, and the seal groove 5 and the seal projection 3 are inserted.
A sealant 6 is filled in a space between and between the case parts 2 and 4, and the case parts 2 and 4 are sealed. Such a waterproof structure,
Higher sealing performance than the waterproof structure that has a step on the joint surface and abuts against each other, and is easier on complex joint surfaces than a waterproof structure that inserts an O-ring or a special shape seal member into the joint surface. There is an advantage that can correspond to.

However, such a waterproof structure is shown in FIG.
As shown in (I), when the seal projection 3 is inserted in the center of the seal groove 5, a regular seal length 7 is secured and sufficient sealing performance is exhibited, but there are variations in processing of the case portions 2 and 4. If the seal projection 3 is biased to one side of the seal groove 5 and the seal length 8 is shortened due to deformation at the time of joining, as shown in FIG. In addition, the seal protrusion 3 is inserted in the center of the seal groove 5 so that both covers 2, 4
Cases 4 due to subsequent thermal expansion etc.
The deformation may cause the seal projection 3 to be biased with respect to the seal groove 5, and the sealing performance may be deteriorated. However, in the past, it was sufficient to have a certain degree of sealing property, and thus such a reduction in sealing property was not a problem.
Therefore, no particular measures have been taken against such a decrease in sealing performance.

However, recently, due to the popularization of so-called coin car washing, intrusion of water into the drive unit for door mirrors, which has not been a problem in the past when car washing with high pressure washing water, has become a problem. Therefore, it has become necessary to prevent the seal projection 3 from being biased with respect to the seal groove 5 and improve the reliability of the waterproof function.

[0006]

SUMMARY OF THE INVENTION Therefore, the technical problem to be solved by the present invention is to provide a waterproof structure for a drive unit for a door mirror, which prevents displacement of the seal projection with respect to the seal groove and improves reliability of the waterproof function. It is to be.

[0007]

In order to solve the above technical problems, the present invention provides a waterproof structure for a drive unit for a door mirror having the following configuration.

The waterproof structure of the drive unit for the door mirror is
The first case portion having the seal protrusion and the second case portion having the seal groove are joined to each other, and the seal agent is filled between the seal protrusion and the seal groove in a substantially U-shaped cross section. The first case has positioning ribs on both sides adjacent to the seal protrusion. The positioning rib slides in contact with the seal groove of the second case when joining the cases, and guides the seal protrusion of the first case so as to come to the center of the seal groove of the second case.

In the above structure, after the sealing agent is poured into the seal groove of the second case portion, both cases are joined.
Since the positioning rib is in sliding contact with the seal groove during joining of the cases, the seal projection is inserted into the seal groove while being kept in the center of the seal groove. for that reason,
It is possible that the sealing agent is evenly extruded on both sides of the seal protrusion so as to be evenly filled between the seal protrusion and the seal groove. After the case is joined, even if the case is deformed due to thermal expansion or the like, the relative position between the seal protrusion and the seal groove is kept constant by the positioning rib. Therefore, the gap between the seal protrusions and the seal groove in the seal agent filled portion does not change, and it is possible to maintain the state in which the seal agent is evenly filled.

Therefore, with the above construction, it is possible to prevent the displacement of the seal projection with respect to the seal groove and improve the reliability of the waterproof function.

Preferably, the seal groove of the other case has a relatively wide first groove portion on the opening side and the first groove portion.
The second groove portion has a relatively narrow width on the bottom side and is continuous with the groove portion. The first groove portion is configured as an escape portion for accommodating the sealing agent which is inserted into the seal protrusion of the first case when the case is joined and overflows from the second groove portion.

In the above structure, when a predetermined amount of the sealing agent is poured into the seal groove of the second case portion and the two cases are joined together, the seal protrusion is formed only in the second groove portion of the seal groove of the second case portion. It is possible that the sealant is filled in between. On the other hand, when a sealant in excess of a predetermined amount is poured and the two cases are joined together, the sealant overflows from the second groove portion of the seal groove of the second case portion and reaches the first groove portion. The first groove portion of the seal groove serves as a relief portion for accumulating an excess amount of sealing agent exceeding a predetermined amount. Since the width of the first groove portion is wider than that of the second groove portion, a large amount of sealing agent can be stored even if the first groove portion is shallow. Therefore, it is possible to prevent the sealing agent from overflowing from the sealing groove.

Preferably, the other case has a discharge groove for communicating the opening side of the seal groove with the outside.

In the above structure, when the amount of the sealing agent is further large, the sealing agent overflows from the first groove portion of the sealing groove to the outside before the case joining or during the case joining. Therefore, it is possible to avoid the worst situation in which the sealant overflows inside the door mirror drive unit and adheres to the internal mechanisms.

[0015]

BEST MODE FOR CARRYING OUT THE INVENTION The waterproof structure of a door mirror drive unit according to an embodiment of the present invention shown in FIGS. 2 and 3 will be described in detail below. FIG. 2 is a sectional view of a main part of the case before joining, and FIG. 3 is a sectional view of a main part of the case at the time of joining.

In this door mirror drive unit 10, as shown in FIG. 3, the upper case 20 is superposed on the lower case 40, and both cases 20 and 20 are fitted by a snap fit (not shown).
40 is fixed in a joined state, and the inside 12 and the outside 14 of the unit 10 are blocked by the sealing agent 30 filled in the joined portions of the cases 20 and 40, so that the inside 12 of the unit 10 is sealed. There is.

More specifically, as shown in FIG. 2, the lower case 4
In No. 0, the seal groove 46 is continuously formed on the joint surface 42 that joins with the upper case 20, and the seal groove 46 makes one round.
The seal groove 46 includes a first groove portion 46a on the opening side, that is, the joint surface 42 side, and a second groove portion 46b on the bottom side that is continuous with the first groove portion 46a. First and second groove portions 46a, 46b
Extend in a direction perpendicular to the joint surface 42, and
The width of the groove 46a is wider than the width of the second groove 46b. In addition, in the joint surface 42 of the lower case 40, a seal groove 46 is formed on a part or all of the outside of the seal groove 46.
A discharge groove 44 is formed so as to communicate with the outside 14.

On the other hand, in the upper case 20, a seal projection 24 protruding in a direction perpendicular to the joint surface 22 is continuously formed on the joint surface 22 joined to the lower case 40 so as to make a circuit. The width of the seal protrusion 24 is equal to that of the lower case 40.
The width is smaller than the width of the second groove portion 46b of the seal groove 46. Further, the protruding length of the seal protrusion 24 is smaller than the depth of the seal groove 46 of the lower case 40. Ribs 26 and 27 are provided on both sides of the seal projection 24 at appropriate intervals. Each rib 26, 27 has a first side 26 a, 27 a extending obliquely with respect to the seal protrusion 24 and a second side 26 b, 27 b parallel to the seal protrusion 24.
The outer width of both ribs 26, 27, that is, the distance between the second sides 26b, 27b is determined by the first groove portion 46a of the seal groove 46 of the lower case 40.
The width of the ribs 26, 27 is equal to that of the first groove portion 46a of the seal groove 46.

The sealant 30 contains, for example, an anaerobic component such as silicon and is of a hot melt type having a relatively soft characteristic even after cooling. It is preferable to use a urethane-based water-swellable sealant known as a building sealant, because the sealing property can be more surely maintained.

Next, regarding the joining of both cases 20 and 40,
explain. At the time of joining, first, as shown in FIG. 2, a predetermined amount of the sealing agent 30 is poured into the sealing groove 46 of the lower case 40. At this time, the upper surface 30a of the sealant 30 reaches the middle of the second groove portion 46b of the seal groove 46.

Next, as shown in FIG. 3, the upper case 20 is overlaid on the lower case 40, and the seal projection 24 and the ribs 26, 27 of the upper case 20 are inserted into the seal groove 46 of the lower case 40. When a predetermined amount of the sealing agent 30 is poured into the seal groove 46 of the lower case 40, as shown by the chain line in FIG.
6b and 27b are the first groove portions 4 of the seal groove 46 of the lower case 40.
When the sliding contact with the groove surface 46x of 6a begins, the tip 24a of the sealing protrusion 24 of the upper case 20 comes into contact with the upper surface 30a of the sealing agent 30. From this chain line state, the upper case 20 is further lowered, and the seal projection 24 of the upper case 20 is pushed into the sealant 30. At this time, the second sides 26b, 27b of the ribs 26, 27 of the upper case 20 are in sliding contact with the groove surface 46x of the first groove portion 46a of the seal groove 46 of the lower case 40, and the groove surface 46
Since it is guided by x, the seal projection 24 of the upper case 20 is inserted into the seal groove 46 of the lower case 40 while being held at the central position. Therefore, the outer peripheral surface 24x of the seal protrusion 24 is formed on the groove surface 46y of the second groove portion 46b of the seal groove 46.
The gap between and is kept constant, and the sealant 30 is pushed up to both sides of the seal protrusion 24.

When the joint surfaces 22 and 42 of the two cases 20 and 40 overlap each other, a snap fit (not shown) is fitted into the two cases 20 and 40 to maintain the joined state. Then, as shown in FIG. 3, between the outer peripheral surface 24x of the seal projection 24 and the groove surface 46y of the second groove portion 46b of the seal groove 46, the sealant 3
0 is evenly filled. After the case is joined, even if the cases 20 and 40 are deformed due to thermal expansion or the like, the seal protrusion 24
The relative position between the seal groove 46 and the second seal groove 46b is
Since the ribs 26 and 27 are fitted in the first groove portion 46a of the seal groove 46, they are kept constant. That is, the seal protrusion 24
Since the gap of the seal agent filled portion between the seal groove 46 and the second groove portion 46b of the seal groove 46 does not change, the state in which the seal agent 30 is evenly filled is maintained and the sealability is maintained.

Therefore, the unit 10 having the above structure is
By fitting the ribs 26 and 27 into the seal groove 46, the displacement of the seal protrusion 24 with respect to the seal groove 46 is prevented, and therefore the reliability of the waterproof function is high.

In the above structure, as described above, when a predetermined amount of the sealing agent 30 is poured into the sealing groove 46 of the lower case 40, the sealing agent 30 is filled only in the second groove portion 46b of the sealing groove 46. On the other hand, when more than a predetermined amount of the sealing agent 30 is poured into the sealing groove 46 of the lower case 40, when the two cases 20 and 40 are joined, the sealing agent 30 will be the first of the sealing grooves 46 of the lower case 40. 4 in the groove
It will be filled up to 6a. Since the sealing groove 46 having the above structure is small and the amount of the sealing agent 30 to be poured is small, it is very difficult to control the pouring amount of the sealing agent 30. However, the fluctuation amount of the pouring amount is absorbed by the first groove portion 46a of the sealing groove 46. It is possible. Therefore, it becomes easy to manage the pouring amount of the sealing agent 30.

When a larger amount of the sealing agent 30 is poured, part of the sealing agent 30 overflows from the sealing groove 46 of the lower case 40 and is discharged before or during the joining of the cases 20 and 40. It flows out to the outside 14 of the unit 10 via the groove 44. Both cases 20,40 when joining the cases
Since the joint surfaces 22 and 42 on the inside of the unit are in close contact with each other, the sealing agent 30 does not flow into the inside 12 of the unit 10. Therefore, even if the sealing agent 30 far exceeding the permissible range is poured into the sealing groove 46 of the lower case 40, the sealing agent 30 will flow into the inside 12 of the unit 10 and the sealing agent will be applied to the mechanisms of the inside 12. The worst case of sticking is avoided.

The present invention is not limited to the above embodiment, but can be implemented in various other modes. For example, the first groove portion 46a of the seal groove 46 may be provided continuously or intermittently. Also, the positioning rib 2
The reference numerals 6 and 27 may reach the second groove portion 46b of the seal groove 46, and further may be in sliding contact with the groove surface 46y of the second groove portion 46b.

[Brief description of drawings]

FIG. 1 is a sectional view of a main part of a conventional waterproof structure.

FIG. 2 is a cross-sectional view of the main parts of the case before joining of the waterproof structure of the door mirror drive unit of the present invention.

FIG. 3 is a cross-sectional view of a main part when the cases of FIG. 1 are joined.

[Explanation of symbols]

 10 unit 12 inside 14 outside 20 upper case (first case part) 22 joining surface 24 sealing protrusion 24a tip 24x outer peripheral surface 26 rib (positioning rib) 26a first side 26b second side 27 rib (positioning rib) 27a first side 27b Second edge 30 Sealant 30a Upper surface 40 Lower case (second case part) 42 Joining surface 44 Discharge groove 46 Seal groove 46a First groove part 46b Second groove part 46x, 46y Groove surface

Claims (3)

[Claims] 1. A first case part (20) having a seal protrusion (24) and a second case part having a seal groove (46).
(40) is joined, and the waterproof structure of the door mirror drive unit (10) in which the sealing agent (30) is filled between the sealing protrusion (24) and the sealing groove (46) in a substantially U-shaped cross section. In the above, the first case (20) has positioning ribs (26, 27) on both sides adjacent to the seal protrusion (24), and the positioning ribs (26, 27) are connected to the first case (20) when the case is joined. The seal projection (24) of the first case (20) is slidably contacted with the seal groove (46) of the second case (40) and the second case (4).
0) A waterproof structure for a drive unit for a door mirror, characterized in that it is guided so as to come to the center of the seal groove (46). 2. The seal groove of the second case (40)
(46) is a relatively wide first groove portion (46a) on the opening side
And a relatively narrow second groove portion (46b) on the bottom side which is continuous with the first groove portion (46a), the first groove portion (46a)
Is configured as a relief portion for accommodating the sealing agent overflowing from the second groove portion (46b) by inserting the seal protrusion (24) of the first case (20) at the time of joining the cases. Waterproof structure of the drive unit for door mirrors described. 3. The second case (40) has the seal groove.
In order to connect the opening side of (46) and the outside (14), the discharge groove (4
4) The waterproof structure for a drive unit for a door mirror according to claim 1 or 2, further comprising: