JP2020180671A - Seal structure of control cable - Google Patents

Abstract

To inhibit deformation of a seal member with slide resistance of an inner cable reduced and inhibit water from entering into an outer casing.SOLUTION: A seal structure 1 has an inner cable Ca, an outer casing Cb, a guide member 2, and a seal member 3. The guide member 2 has a base part 21, a connection part 22 with which one end Eb1 of the outer casing Cb is connected; a lead-out part 23 from which the inner cable Ca is led out; and a guide part 24 which guides the inner cable Ca while bending the inner cable Ca. In the base part 21, a linear line arrangement part ST in which the inner cable Ca can linearly extend is provided between the lead-out part 23 and the guide part 24. The linear line arrangement part ST is provided forming a distance such that a load applied to the seal member 3 in a substantially vertical direction Y can be reduced.SELECTED DRAWING: Figure 6

Description

The present invention relates to a control cable seal structure.

Control cables used in environments where water can enter, such as throttle cables operated by the throttle grips of motorcycles, prevent water from entering the outer casing of the control cable. Therefore, a sealing member is provided (see, for example, Patent Document 1). The device described in Patent Document 1 is provided between a throttle grip and a throttle valve, and is attached with a throttle cable having an inner cable and an outer casing, a throttle grip having a cable winding portion, and an end portion of the outer casing. It has a slider that guides the inner cable to the cable winding part. The slider is a bent part that guides the cable holding part to which the end of the outer casing is attached and the inner cable led out from the circular opening provided in the cable holding part by bending about 90 degrees toward the cable winding part. And have. A waterproof seal is provided at the end of the outer casing adjacent to the circular opening of the cable holding portion, and the waterproof seal prevents moisture such as rainwater from entering the outer casing.

International Publication No. 2014/188527

In the case of the structure disclosed in Patent Document 1, the inner cable is configured to be guided to the bent portion immediately after being led out from the waterproof seal provided at the end portion of the outer casing.

Therefore, for example, when the other members provided around the waterproof seal rattle due to the vibration of the vehicle or the like, the inner cable may move due to the rattling. For example, the inner cable may move relative to the opening of the waterproof seal in a direction perpendicular to the axis of the inner cable due to the above-mentioned rattling. In this case, the opening of the waterproof seal is repeatedly deformed by the movement of the inner cable, and after long-term use, the opening of the waterproof seal widens and the waterproof effect deteriorates. In addition, since the inner cable slides on the bent portion, the sliding resistance during operation of the inner cable increases.

The purpose of the control cable sealing structure of the present invention is to reduce the sliding resistance of the inner cable, suppress the deformation of the sealing member, and prevent water from entering the outer casing.

The seal structure of the control cable of the present invention includes an inner cable in which one end is connected to the operating portion and the other end is connected to the operated portion, an outer casing through which the inner cable is inserted, and the inner cable extending from one end of the outer casing. The guide member is provided with a guide member for guiding the inner cable to the operation portion and a seal member on which the inner cable slides. The guide member is provided on one side of the base portion and the base portion, and one end of the outer casing is connected. A connection portion, a lead-out portion from which the inner cable inserted into the outer casing connected to the connection portion is led out, and a guide portion provided on the other side of the base portion to guide the inner cable by bending. The guide portion has a curved path for guiding the inner cable, and the base portion has a linear arrangement in which the inner cable can extend linearly between the lead-out portion and the guide portion. A cord portion is provided, and the straight line arrangement portion is provided to the seal member when the guide portion moves between the lead-out portion and the guide portion in a direction perpendicular to the direction in which the inner cable extends. The seal member is provided as a distance capable of reducing the load in the vertical direction, and the seal member is provided at the end of the lead-out portion on the straight line arrangement portion side.

According to the seal structure of the control cable of the present invention, it is possible to suppress the deformation of the seal member and prevent water from entering the outer casing while reducing the sliding resistance of the inner cable.

It is a figure which shows the cable operation mechanism provided with the seal structure of the control cable of this embodiment. It is a top view which shows the operation part provided with the seal structure. It is a side view which shows the operation part provided with the seal structure. It is a figure which shows the connection state between a seal structure and a cable winding part of an operation part. It is a top view of the guide member to which a control cable is connected. FIG. 5 is a sectional view taken along line VV of FIG. It is a perspective view of a guide member. It is a figure which shows the state of the inner cable and the seal member when the guide part moves with respect to a lead-out part in the guide member which is not provided with a straight line arrangement part. It is a figure which shows the state of the inner cable and the seal member when the guide part moves with respect to the lead-out part in the guide member provided with the straight line arrangement part.

Hereinafter, the seal structure of the control cable according to the embodiment of the present invention will be described with reference to the drawings. The embodiments shown below are merely examples, and the seal structure of the control cable of the present invention is not limited to the following embodiments.

FIG. 1 is a diagram showing a cable operation mechanism provided with a seal structure (hereinafter, simply referred to as a seal structure) for the control cable of the present embodiment. The application target of the seal structure of the present invention is not limited to the cable operation mechanism. Further, in the following example, the attachment target to which the cable operation mechanism is attached is a motorcycle that operates the control cable by the rotational operation of the throttle grip. However, the attachment target to which the cable operation mechanism is attached is not limited to the motorcycle, and may be a saddle-riding vehicle such as a water bike or a snow bike, or various devices requiring a seal structure.

As shown in FIG. 1, the cable operating mechanism M has an operating portion OP1, an operated portion OP2, and a seal structure 1 described later. The seal structure 1 has an inner cable Ca and an outer casing Cb (hereinafter, the inner cable Ca and the outer casing Cb are collectively referred to as a control cable C), and the operation unit OP1 is an operated portion via the inner cable Ca. It is connected to OP2. Although the details will be described later, in the seal structure 1, as shown in FIGS. 2 and 3, the guide member 2 for guiding the inner cable Ca extending from one end Eb1 of the outer casing Cb to the operation unit OP1 and the inner cable Ca slide together. It includes a moving seal member 3.

As shown in FIG. 1, the inner cable Ca has one end Ea1 connected to the operating portion OP1 and the other end Ea2 connected to the operated portion OP2. The inner cable Ca transmits the operating force applied to the operating unit OP1 to the operated unit OP2, and the operating unit OP1 remotely controls the operated unit OP2. As shown in FIGS. 1 to 3, an inner cable Ca is inserted through the outer casing Cb to guide the inner cable Ca from the vicinity of the operating portion OP1 to the vicinity of the operated portion OP2 along a predetermined routing path. To do. One end Eb1 of the outer casing Cb is attached to the guide member 2, and the other end Eb2 is attached in the vicinity of the operated portion OP2. The routing route of the outer casing Cb is not particularly limited, but in the present embodiment, as shown in FIG. 1, the outer casing Cb extends downward from the operating portion OP1 until it reaches the operated portion OP2. In addition, it is arranged so as to extend upward at at least one place, and is attached to the attachment target (vehicle body B in this embodiment). In the present embodiment, as shown in FIG. 2, the inner cable Ca has two inner cables Ca1 and Ca2, and the outer casing Cb is inserted with the two inner cables Ca1 and Ca2, respectively. It has two outer casings Cb1 and Cb2. However, the number of the inner cable Ca and the outer casing Cb is not particularly limited.

The operation unit OP1 is operated to operate the operated unit OP2. One end Ea1 of the inner cable Ca is connected to the operation unit OP1, and the operating force of the operation unit OP1 is transmitted to the operated unit OP2 via the inner cable Ca.

The operation unit OP1 is not particularly limited as long as it has a structure in which the operated unit OP2 can be operated via the inner cable Ca, and the operated unit OP2 is operated via the inner cable Ca by the operation of the operation unit OP1. The structure is not particularly limited. In the present embodiment, as shown in FIG. 1, the operation unit OP1 is the throttle grip G, and the operated unit OP2 is the throttle valve V. In the present embodiment, the inner cable C1 is operated by the rotation operation of the throttle grip G, the throttle valve V, which is the operated portion OP2, is opened and closed, and the amount of air supplied to the engine is adjusted.

The throttle grip G is rotatably provided with respect to the pipe P shown by the alternate long and short dash line in FIG. The throttle grip G has a grip portion Ga operated by the driver and a cable winding portion W to which one end Ea1 of the inner cable Ca is connected to one end side of the grip portion Ga. A part of the inner cable Ca guided by the guide member 2 is wound around the cable winding portion W, and one end Ea1 of the inner cable Ca is attached. The cable winding portion W rotates around the axis of the throttle grip G together with the throttle grip G. In the present embodiment, two inner cables Ca1 and Ca2 are attached to the cable winding portion W. In the present embodiment, the cable winding portion W includes a winding portion Wa around which the inner cables Ca1 and Ca2 are wound and the inner cables Ca1 and Ca2 extending in the axial direction of the throttle grip G, as shown in FIG. It has a first engaging portion Wb1 and a second engaging portion Wb2 with which one end portion Ea1 of the above is engaged, respectively.

The inner cable Ca opens the throttle valve V when the throttle grip G and the cable winding portion W rotate in one direction, and closes the throttle valve V when the throttle grip G and the cable winding portion W rotate in the other direction. Works like this. For example, when the driver rotates the throttle grip G toward you and the cable winding portion W rotates counterclockwise in FIG. 4, one inner cable Ca1 becomes the winding portion Wa of the cable winding portion W. The throttle valve V is opened by the other end Ea2 of one inner cable Ca1 after being wound and pulled. At this time, the other inner cable Ca2 is unwound from the winding portion Wa of the cable winding portion W and operates in the direction opposite to that of the one inner cable Ca1. Further, when the driver rotates the throttle grip G on the opposite side to the side when accelerating, such as when decelerating a motorcycle, and the cable winding portion W rotates clockwise in FIG. 4, the other inner cable Ca2 is moved. The throttle valve V is closed by the other end Ea2 of the other inner cable Ca2 after being wound around the winding portion Wa of the cable winding portion W and pulled. At this time, one inner cable Ca1 is unwound from the winding portion Wa of the cable winding portion W and operates in the opposite direction to the other inner cable Ca2. The shape and structure of the cable winding portion W are not particularly limited as long as the inner cable Ca can be operated by operating the operating portion OP1 such as the throttle grip G to operate the operated portion OP2 such as the throttle valve V. ..

In the present embodiment, the operation unit OP1 is provided so as to be movable relative to the housing H accommodating the guide member 2. Specifically, the throttle grip G, which is the operation unit OP1, is rotatably attached to the housing H. In the present embodiment, the cable winding portion W and the guide member 2 provided at the end of the throttle grip G are housed in the housing H, and the grip portion Ga and the cable winding portion W rotate with respect to the housing H. In the present embodiment, as shown in FIG. 4, the housing H is composed of a pair of half-split housing members Ha and Hb, and the pair of housing members Ha and Hb form a guide member 2 and a cable winding portion W. It is sandwiched (see FIG. 2).

As described above, the seal structure 1 has an inner cable Ca, an outer casing Cb, a guide member 2, and a seal member 3. The seal structure 1 prevents water from entering the outer casing Cb through the inner cable Ca led out from the outer casing Cb. In the present embodiment, the seal structure 1 suppresses the intrusion of water from one end Eb1 on the operation unit OP1 side of both ends Eb1 and Eb2 of the outer casing Cb. More specifically, the seal structure 1 is provided on the outer casing Cb in a structure having a gap that is difficult to seal, such as a structure in which the operation unit OP1 moves relative to the mounting target, such as the housing H and the throttle grip G. It suppresses the ingress of water. In the present embodiment, since the seal structure 1 is provided in the vicinity of the operation unit OP1, it is effective that the moisture entering from the gap between the mounting target and the operation unit OP1 penetrates into the outer casing Cb. It is suppressed.

As shown in FIGS. 2, 3, 5 and 6, the guide member 2 is attached with one end Eb1 of the outer casing Cb, and the inner cable Ca derived from one end Eb1 of the outer casing Cb is attached to the operation unit OP1. I will guide you towards. In the present embodiment, the guide member 2 supports one end Eb1 of the pair of outer casings Cb1 and Cb2, and guides the pair of inner cables Ca1 and Ca2 to the winding portion Wa of the cable winding portion W. In the present embodiment, the guide member 2 is arranged adjacent to the operation unit OP1 as shown in FIGS. 2 and 3. Specifically, it is arranged adjacent to the cable winding portion W in the housing H. The guide member 2 is held in the space inside the housing H, and is held at a predetermined position by mounting the housing H at a predetermined position to be mounted (a position near the throttle grip G of the vehicle body B of the motorcycle). To. The material of the guide member 2 is not particularly limited, but may be, for example, a hard resin.

As shown in FIGS. 5 and 7, the guide member 2 is provided on one side of the base 21 and the base 21, and is connected to the connecting portion 22 to which one end Eb1 of the outer casing Cb is connected and the connecting portion 22. It has a lead-out portion 23 from which the inner cable Ca inserted into the outer casing Cb is led out, and a guide portion 24 provided on the other side of the base portion 21 to guide the inner cable Ca by bending.

The base portion 21 is a portion serving as a base of a guide member 2 provided with a connecting portion 22 on one side and a guide portion 24 on the other side. The overall shape of the base portion 21 is not particularly limited, but in the present embodiment, the base portion 21 has a linear routing portion ST (see FIGS. 5 and 6) between the lead-out portion 23 and the guide portion 24. In the present embodiment, the straight line arrangement portion ST has a space portion SP formed in the base portion 21. The base portion 21 has an opening A1 opened on the lower side of the base portion 21 and a second opening A2 opened on the upper side of the base portion 21, and is formed in a rectangular frame shape penetrating in the vertical direction. In the present specification, the terms "upper" and "lower" mean up and down in the vertical direction when the seal structure 1 is attached to the attachment target. Further, the shape of the guide member 2 including the base portion 21 shown in the figure is merely an example, and the shape of the guide member is not limited to the shape shown in the figure. Details of the base 21 will be described later.

As shown in FIGS. 2, 3 and 5, the connecting portion 22 is a portion to which one end Eb1 of the outer casing Cb is connected. As shown in FIG. 5, the connecting portion 22 has an internal space 22a in which one end Eb1 of the outer casing Cb is arranged, and the internal space 22a of the connecting portion 22 is an insertion hole 231 of the lead-out portion 23 described later. It communicates with. The number of outer casings Cb connected to the connecting portion 22 is not particularly limited, but in the present embodiment, the two outer casings Cb1 and Cb2 are connected to the connecting portion 22. The method of connecting the outer casing Cb in the connecting portion 22 is not particularly limited, and the outer casing Cb can be fixed by a known fixing method such as fitting joint, caulking, or adhesive.

The lead-out portion 23 is a portion where the inner cable Ca protruding from one end Eb1 of the outer casing Cb is led out to the seal member 3 side. The lead-out unit 23 has an insertion hole 231 through which the inner cable Ca is inserted. The insertion hole 231 extends along the axis X direction of the outer casing Cb, as shown in FIGS. 5 and 6. One end of the insertion hole 231 in the axis X direction communicates with the internal space 22a of the connecting portion 22, and the other end of the insertion hole 231 communicates with the through hole 31 of the seal member 3. Further, in the present embodiment, as shown in FIGS. 3, 5 and 6, a seal member 3 is attached to the lead-out portion 23, and the lead-out portion is transmitted from the seal member 3 along the inner cable Ca on the guide portion 24 side. Moisture infiltration to the 23 side is suppressed. In the present embodiment, the lead-out portion 23 has a seal member attachment portion 232 to which the seal member 3 is attached.

The seal member mounting portion 232 is a portion to which the seal member 3 is mounted. In the present embodiment, the seal member mounting portion 232 is provided at the end of the lead-out portion 23 in the axis X direction. In the present embodiment, the seal member mounting portion 232 can be attached to and detached from the seal member 3, and the seal member 3 can be attached to the guide member 2 via the seal member mounting portion 232. Further, the seal member 3 can be removed from the guide member 2 and replaced with another seal member 3, such as being replaced with the inner cable Ca after being used for a predetermined period of time.

The shape and structure of the seal member mounting portion 232 are not particularly limited as long as the seal member 3 can be attached and detached. In the present embodiment, the seal member mounting portion 232 has an engaging portion 232a capable of engaging the seal member 3 in the axis X direction of the outer casing Cb. The engaging portion 232a of the sealing member mounting portion 232 engages with the engaged portion 32 of the sealing member 3 described later. As a result, when the inner cable Ca slides with respect to the seal member 3 in the axis X direction, the seal member 3 is prevented from coming off from the lead-out portion 23.

The shape of the engaging portion 232a is particularly high as long as the engaging portion 232a can engage with the engaged portion 32 of the seal member 3 and the disengagement of the seal member 3 from the seal member mounting portion 232 can be suppressed. Not limited. In the present embodiment, a part of the lead-out portion 23 forms a protruding portion PR protruding in the axis X direction from the wall portion 21a (see FIG. 7) on the connecting portion 22 side of the base portion 21, and the shaft X is formed on the protruding portion PR. An engaging portion 232a extending vertically in the direction is formed. More specifically, the engaging portion 232a is formed in the axis X direction between the small diameter portion PR1 and the large diameter portion PR2 of the protruding portion PR composed of the small diameter portion PR1 and the large diameter portion PR2. It is formed as a stepped portion.

The guide unit 24 guides the inner cable Ca led out from the lead-out unit 23 and the seal member 3 toward the operation unit OP1. In the present embodiment, as shown in FIG. 4, the guide portion 24 guides each of the pair of inner cables Ca1 and Ca2 toward the cable winding portion W. In the present embodiment, the guide portion 24 guides the inner cables Ca1 and Ca2 in a predetermined direction so that the pair of inner cables Ca1 and Ca2 are wound around the cable winding portion W in opposite directions. As a result, as described above, when the cable winding portion W rotates in one direction, one inner cable Ca1 is wound around the cable winding portion W, and the other inner cable Ca2 is wound from the cable winding portion W. The throttle valve V can be opened by being fed out.

In the present embodiment, the guide portion 24 has a curved path 241 for guiding the inner cable Ca, as shown in FIGS. 5 to 7. As a result, the inner cable Ca is curved and guided toward the operation unit OP1. In the present embodiment, the guide portion 24 has an introduction portion 242 located on an extension line of the shaft (coaxial with the shaft X of the outer casing Cb) of the insertion hole 231 of the lead-out portion 23. The inner cable Ca that extends linearly to the introduction portion 242 is curved and guided toward the operation portion OP1 along the curved path 241. In the present embodiment, the guide portion 24 has a pair of curved paths 241a and 241b that guide the pair of inner cables Ca1 and Ca2, respectively. As shown in FIGS. 5 to 7, the curved paths 241a and 241b change the extending direction of the inner cables Ca1 and Ca2 by approximately 90 ° with respect to the axis X, and the pair of inner cables Ca1 and Ca2. The inner cables Ca1 and Ca2 are guided so that they are separated from each other as they approach the cable winding portion W. The introduction unit 242 and the lead-out unit 23 regulate the inner cable Ca so as to be linear at the base portion 21. Further, the inner cable Ca reaching from the lead-out unit 23 to the introduction unit 242 is guided by the guide unit 24 in the direction including the direction component perpendicular to the direction in which the inner cable Ca extends linearly from the lead-out unit 23 to the introduction unit 242. Therefore, the inner cable Ca can come into contact with the inner peripheral surface of the introduction portion 242 and maintain the linear state of the inner cable Ca at the base portion 21.

The seal member 3 suppresses the infiltration of moisture into the outer casing Cb along the inner cable Ca. As shown in FIGS. 5 and 6, the seal member 3 has a through hole 31 configured so that the inner cable Ca slides. In the seal member 3, in a state where the inner cable Ca can slide in the through hole 31, the moisture transmitted through the inner cable Ca flows from the opening provided at one end Eb1 of the outer casing Cb to the inner cavity of the outer casing Cb. It suppresses intrusion. As shown in FIGS. 5 and 6, the through hole 31 is a guide that opens into the lead-out portion side opening 31a that communicates with the insertion hole 231 of the lead-out portion 23 and the space portion SP (straight line arrangement portion ST) of the base portion 21. It has a portion side opening 31b. As shown in FIGS. 5 and 6, the through hole 31 is formed with a portion that is in close contact with the outer circumference of the inner cable Ca and a portion that is not in contact with the outer circumference alternately in the axis X direction. As a result, the inner cable Ca can be easily slid in the axis X direction, and the portion in close contact with the outer circumference of the inner cable Ca can be easily deformed, so that the sealing performance can be improved. The material of the seal member 3 is not particularly limited, but in the present embodiment, the seal member 3 is made of an elastic material such as rubber. As a result, the seal member 3 can follow the operation of the inner cable Ca, and the sealability is improved.

As described above, the seal member 3 is provided at the end of the lead-out portion 23 on the straight line arrangement portion ST side, which will be described later. Specifically, as shown in FIGS. 5 and 6, the seal member 3 is detachably attached to the seal member attachment portion 232 provided at the end of the lead-out portion 23. The seal member has an engaged portion 32 that engages with the engaging portion 232a of the seal member mounting portion 232 in the axis X direction. As a result, when the inner cable Ca slides with respect to the seal member 3, the seal member 3 is prevented from being detached from the seal member attachment portion 232.

The structure of the seal member 3 is not particularly limited, but in the present embodiment, as shown in FIGS. 5 and 6, the seal member 3 is provided with a large engaged portion 32 that engages with the engaging portion 232a. It has a diameter portion 3a, a large diameter portion 3a, and a small diameter portion 3b continuous with the axis X direction and having a through hole 31 formed therein.

Next, the details of the base 21 will be described. In the present embodiment, as shown in FIGS. 5 and 6, the base portion 21 has a straight line arrangement portion ST in which the inner cable Ca can extend linearly between the lead-out portion 23 and the guide portion 24. It is provided. More specifically, as shown in FIGS. 5 and 6, the straight line arrangement portion ST is an introduction portion of the guide portion 24 from the opening edge of the guide portion side opening 31b of the seal member 3 attached to the lead-out portion 23. Up to 242, it is a predetermined region of the base 21 in which the inner cable Ca extends linearly.

In the straight line arrangement portion ST, the inner cable Ca is not guided by another member, and the outer circumference of the inner cable Ca extends linearly in a non-contact state with the other member. In the present embodiment, the straight line arrangement portion ST has a space portion SP, and the outer circumference of the inner cable Ca is not in contact with other members in the space portion SP in which a predetermined distance is secured on the radial outer side of the inner cable Ca. It extends linearly in the state. In the present embodiment, the space portion SP of the straight line arrangement portion ST has openings A1 and a second opening A2 above and below the base portion 21, but the straight line arrangement portion ST is not necessarily on the upper side or the lower side. It is not necessary to have an opening.

When the guide portion 24 moves between the lead-out portion 23 and the guide portion 24 in the direction Y (see FIG. 6) substantially perpendicular to the direction in which the inner cable Ca extends (axis X direction). , The distance is provided as a distance capable of reducing the load in the direction Y substantially perpendicular to the seal member 3. The "distance that can reduce the load in the substantially vertical direction Y to the seal member 3" is a predetermined distance in the axis X direction of the linear wiring unit ST that can exert the effect of the linear wiring unit ST described later. Is the distance. This distance can be changed according to the mounting target of the seal structure 1, and a specific numerical value is not particularly limited. When the attachment target of the seal structure 1 is a motorcycle, the distance of the straight line arrangement portion ST in the axis X direction can be, for example, 2 mm or more, preferably 5 mm or more. Further, the upper limit of this distance is not particularly limited, and the distance of the straight line arrangement portion ST in the axis X direction can be, for example, 15 mm or less, preferably 10 mm or less. The direction Y substantially perpendicular to the direction in which the inner cable Ca extends is shown as a vertical direction in FIG. 5, but it may be a direction including a direction perpendicular to the direction in which the inner cable Ca extends (axis X direction) as a component. For example, it is not limited to the vertical direction. For example, the substantially vertical direction Y may be the paper depth direction in FIG.

When the straight line arrangement portion ST is provided in the seal structure 1, the load applied in the direction Y substantially perpendicular to the inner cable Ca to the seal member 3 is reduced, and the deformation of the seal member 3 is suppressed. As a result, it is possible to prevent water from entering the outer casing Cb due to the deformation of the seal member 3 and shorten the life of the seal member 3 due to repeated deformation of the seal member 3.

More specifically, for example, the guide portion 24 is displaced in a direction Y substantially perpendicular to the connection portion 22 due to play between the guide member 2 and the surrounding members, vibration applied to the mounting target, and the like. The guide portion 24 may move in the direction Y substantially perpendicular to the lead-out portion 23 (or the seal member 3). In this case, the portion guided by the guide portion 24 of the inner cable Ca moves in a substantially vertical direction Y together with the guide portion 24 (see, for example, FIGS. 8 and 9. Note that FIGS. 8 and 9 are easy to understand. The amount of deformation is emphasized in order to do this). At this time, when the straight line arrangement portion ST is not provided, as shown in FIG. 8, when the guide portion 24 moves in the direction Y substantially perpendicular to the seal member 3, the inner cable Ca moves to the seal member 3. It bends when entering the introduction unit 242 of the guide unit 24 from the side. In this case, as shown in FIG. 8, the opening edge of the guide portion side opening 31b of the seal member 3 expands in the direction in which the inner cable Ca is bent, and a gap is provided between the outer periphery of the inner cable Ca and the seal member 3. Is generated, and water easily infiltrates into the outer casing Cb side. Further, if the opening edge of the guide portion side opening 31b of the seal member 3 is repeatedly deformed due to long-term use, the seal member 3 is worn out and the seal member 3 is deteriorated at an early stage.

On the other hand, when the straight line arrangement portion ST is provided as in the present embodiment, even if the guide portion 24 is displaced in the substantially vertical direction Y by the same amount as the state shown in FIG. 8, it is shown in FIG. As described above, by having the straight line arrangement portion ST, it is suppressed that the inner cable Ca is suddenly bent as shown in FIG. Therefore, the amount of deformation of the seal member 3 at the opening edge of the guide portion side opening 31b of the seal member 3 can be reduced. Therefore, it is possible to suppress the formation of a gap between the outer circumference of the inner cable Ca and the seal member 3, and it is possible to suppress the intrusion of water into the outer casing Cb side. Further, since the amount of deformation of the opening edge of the guide portion side opening 31b of the seal member 3 can be reduced when the object to be attached vibrates, the life of the seal member 3 can be extended. Similarly, even if the opening edge of the guide portion side opening 31b of the seal member 3 and the position of the introduction portion 242 of the guide portion 24 are displaced in a substantially vertical direction Y due to a manufacturing error of the guide member 2 or the seal member 3, a straight line is formed. By providing the wiring portion ST, the amount of deformation of the opening edge of the guide portion side opening 31b of the seal member 3 can be reduced, and the life of the seal member 3 can be extended. Further, in the present embodiment, in the straight line arrangement portion ST, since the outer circumference of the inner cable Ca is not in contact with other members, an increase in sliding resistance is suppressed.

In the present embodiment, the straight line arrangement portion ST has a space portion SP to which the seal member 3 can be attached and detached. Since the straight line arrangement portion ST has a space portion SP to which the seal member 3 can be attached and detached, the seal member 3 can be easily attached to the lead-out portion 23. When the seal member 3 is attached to the lead-out portion 23, the seal member 3 is inserted into the space portion SP so that the shaft of the through hole 31 of the seal member 3 and the shaft of the insertion hole 231 of the lead-out portion 23 are aligned in the axis X direction. .. Then, by moving the seal member 3 toward the seal member attachment portion 232 in the axis X direction, the seal member 3 can be easily attached to the lead-out portion 23. The length of the space portion SP in the axis X direction is not particularly limited as long as the seal member 3 can be attached to the lead-out portion 23. For example, when the length in the axis X direction from the tip of the lead-out unit 23 on the guide portion 24 side to the introduction portion 242 of the guide portion 24 is longer than the length in the axis X direction of the seal member 3, the seal member 3 is led out. It becomes easier to attach to the portion 23. The length of the space portion SP in the substantially vertical direction Y (the length from the opening A1 to the second opening A2) is not particularly limited, but for example, the outer diameter of the seal member 3 (the outer diameter of the large diameter portion 3a). ) Can be longer.

Further, in the present embodiment, the space portion SP of the base portion 21 has an opening (opening A1 or second opening A2) in a direction Y substantially perpendicular to the axis X direction of the outer casing Cb, and is a sealing member. 3 is formed in an opening that can be introduced into the straight line arrangement portion ST. As a result, when the seal member 3 is attached to the lead-out portion 23, the seal member 3 can be moved toward the space portion SP via the opening, so that the seal member 3 is attached to the lead-out portion 23. It becomes easy to introduce the member 3 into the space SP.

Further, in the present embodiment, the base portion 21 has a second opening portion A2 different from the opening portion A1. In this case, since the base portion 21 is formed with two openings, the opening A1 and the second opening A2, the seal member 3 is gripped from two directions so as to be sandwiched between fingers or the like and attached to the lead-out portion 23. Further, the sealing member 3 can be easily attached. When the opening A1 and the second opening A2 are formed so as to face each other in a substantially vertical direction Y (vertical direction), the seal member 3 is gripped so as to be sandwiched in a substantially vertical direction Y (vertical direction). This makes it easier to attach the seal member 3. The position where the second opening A2 is provided is not limited to the position facing the opening A1, and the second opening A2 may be formed on the side of the base 21.

As described above, in the present embodiment, as shown in FIG. 6, the base portion 21 has a space portion SP that forms a space between the seal member 3 and the guide portion 24, and the space portion SP is a seal. It has an opening A1 between the member 3 and the guide portion 24 capable of discharging water. The size of the opening A1 is not particularly limited as long as it can discharge the water that has entered between the seal member 3 and the guide portion 24.

As described above, when the space SP has an opening A1 capable of discharging water, water is discharged from the opening A1 even if water enters between the seal member 3 and the guide portion 24. .. Therefore, water is prevented from accumulating at the opening edge of the guide portion side opening 31b of the seal member 3. For example, as shown in FIG. 8, when the member is provided directly under the inner cable Ca in the region R near the opening edge of the guide portion side opening 31b of the seal member 3, there is no escape place for water and the accumulated water. However, due to the repeated sliding of the inner cable Ca, water easily moves toward the lead-out portion 23. On the other hand, in the present embodiment, at the opening edge of the guide portion side opening 31b of the seal member 3, as shown in FIG. 6, there is an escape place for water by the opening A1. Therefore, the accumulation of water at the opening edge of the guide portion side opening 31b of the seal member 3 is suppressed, and the infiltration of water toward one end Eb1 of the outer casing Cb is suppressed.

The position of the opening A1 is not particularly limited as long as it is opened so as to prevent water from accumulating at the opening edge of the guide portion side opening 31b of the seal member 3. In the present embodiment, the opening A1 of the base 21 is provided below the base 21 so that the water that has entered the space SP can be discharged from the opening A1 by gravity. By opening the opening A1 in the direction of gravity in this way, the water that has entered the base 21 can be smoothly discharged.

Further, as shown in FIG. 6, the opening A1 is provided on the bottom surface of the base 21 from below the lead-out portion 23 toward the guide portion 24. As described above, since the opening A1 is formed as an opening that is widely opened from below the lead-out portion 23 to the guide portion 24, water can be discharged smoothly, and the seal member 3 can be attached to the lead-out portion 23. It will be easy. In the present embodiment, the opening A1 is formed in a size that allows the seal member 3 to be introduced into the straight line arrangement portion ST as described above, so that the seal member 3 can be easily attached and the amount of water that has entered is At most, it can be easily discharged.

Further, in the present embodiment, the opening A1 is provided on the lower side of the base 21, and the second opening A2 is provided on the upper side of the base 21. As a result, the opening A1 and the second opening A2 cause an air flow in the space SP where the inner cable Ca extends. This further promotes the drainage of water from the opening A1. In the present embodiment, since the second opening A2 is covered with the housing H, it is suppressed that water directly enters from the second opening A2. Further, in the present embodiment, as described above, the seal structure 1 has the linear wiring portion ST between the seal member 3 and the guide portion 24, so that water transmitted from the guide portion 24 side to the inner cable Ca. Is hard to reach the seal member 3, so that it is possible to further suppress the intrusion of water into the outer casing Cb.

1 Seal structure 2 Guide member 21 Base 21a Wall on the connection side of the base 22 Connection 22a Internal space 23 Derivation part 231 Insertion hole 232 Seal member mounting part 232a Engagement part 24 Guide part 241, 241a, 241b Curved path 242 Introduction Part 3 Seal member 3a Large diameter part 3b Small diameter part 31 Through hole 31a Outlet side opening 31b Guide part side opening 32 Engagement part A1 Opening A2 Second opening B Body C Control cable Ca, Ca1, Ca2 Inner cable Cb , Cb1, Cb2 Outer casing Ea1 One end of the inner cable Ea2 The other end of the inner cable Eb1 One end of the outer casing Eb2 The other end of the outer casing G Throttle grip Ga Grip part H Housing Ha, Hb Housing member M Cable operation mechanism OP1 Operation part OP2 Operation part P Pipe PR Protruding part PR1 Small diameter part PR2 Large diameter part R Area near the opening edge of the guide part side opening SP Space part ST Straight line arrangement part V Throttle valve W Cable winding part Wa Winding part Wb1 1st engagement Joint part Wb2 Second engaging part X Outer casing axis Approximately perpendicular to the Y-axis direction

Claims (4)

An inner cable having one end connected to the operating portion and the other end connected to the operated portion, an outer casing through which the inner cable is inserted, and a guide member for guiding the inner cable extending from one end of the outer casing to the operating portion. A seal member on which the inner cable slides is provided.
The guide member
At the base,
A connection portion provided on one side of the base portion and to which one end of the outer casing is connected,
A lead-out unit from which the inner cable inserted into the outer casing connected to the connection unit is led out,
It has a guide portion provided on the other side of the base portion and guides the inner cable in a curved manner.
The guide portion has a curved path for guiding the inner cable.
The base portion is provided with a straight line arrangement portion in which the inner cable can extend linearly between the lead-out portion and the guide portion.
When the guide portion moves in a direction perpendicular to the direction in which the inner cable extends between the lead-out portion and the guide portion, the straight line arrangement portion moves in the direction perpendicular to the seal member. It is provided as a distance that can reduce the load,
The seal member is provided at the end of the lead-out portion on the straight line arrangement portion side.
Control cable seal structure. The seal structure for a control cable according to claim 1, wherein the seal member is made of an elastic material that can follow the operation of the inner cable. The lead-out portion has a seal member mounting portion at the end to which the seal member can be attached and detached.
The seal member mounting portion has an engaging portion capable of engaging the seal member in the axial direction of the outer casing.
The straight line arrangement portion has a space portion to which the seal member can be attached and detached.
The seal structure for a control cable according to claim 1 or 2, wherein the seal member has an engaged portion that engages with the engaging portion of the seal member mounting portion in the axial direction. 3. The space portion of the base portion has an opening in a direction perpendicular to the axial direction of the outer casing, and forms an opening into which the seal member can be introduced into the straight line arrangement portion. Seal structure of the control cable described in.

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