JP2004350366A - Fixing member for flat cable - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a fixing member for a flat cable capable of enhancing workability when a flat cable is fixed to a fixed body, e.g. a chassis. <P>SOLUTION: A flat cable 2 is provided with a flat cable fixing member having a fixing member body 5 being fixed to a flat cable 2 while surrounding it and the fixing member body 5 is fixed to the flat cable 2 under temporary stopping state where longitudinal movement of the flat cable 2 is allowed. The fixing member for a flat cable comprises a securing means 8 consisting of a first plate 6 and a second plate 7 engaging each other such that they can move from the temporary stopping state to the actual stopping state and securing the fixing member body 5 to the flat cable 2 while pinching the flat cable 2 when the first plate 6 and the second plate 7 are in the actual stopping state. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a flat cable attachment member for fixing a flat cable such as a flat wire harness, a flexible flat cable (FFC), and a flexible printed circuit (FPC) to a fixed body such as a vehicle body.
[0002]
[Prior art]
2. Description of the Related Art A large number of electronic devices and mechanical parts are mounted on an automobile for various controls. These electronic devices and the like are electrically connected by a flexible flat cable such as a flat wire harness, a flexible flat cable (FFC), or a flexible printed circuit (FPC). As described above, a large number of FFCs are routed in the vehicle, and these FFCs are fixed using, for example, a flat cable attachment member so as not to interfere with surrounding components or to be caught by movable components. It is fixed to the vehicle body at each location.
[0003]
Various types of flat cable attachment members have been proposed (for example, see Patent Documents 1 and 2).
For example, a flat cable clamp as a first flat cable attachment member disclosed in Patent Document 1 pulls out a locking member 101 from a locking hole 102 as shown in FIG. The flat cable 104 is inserted from below into the lower side of the overhang member 103, and one side end of the flat cable 104 is inserted into the holding portion 105. Next, after positioning the other side end of the flat cable 104 on the holding portion 106, the locking member 101 is inserted into the locking hole 102. As a result, the flat cable 104 is pressed by the width elastic portions 108 and the ribs 109 and 110 by the spring pieces 107, so that the clamp 100 can be fixed to the flat cable 104. The flat cable 104 can be fixed at a predetermined position by pressing the elastic claw member 111 of the clamp 100 into a locking hole formed at a predetermined position of the vehicle body.
[0004]
Further, as shown in FIG. 8, the clamp as the second flat cable attachment member disclosed in Patent Literature 2 inserts the locking projection 204 of the housing 203 into the insertion locking portion 202 of the flat cable 201. Then, the flat cable 201 is accommodated in the accommodation section 203. After the housing, the other end of the cover body 205 is rotated upward to engage a lock projection (not shown) with the lock arm 206, and the cover body 205 completely closes the opening of the housing portion 203. As a result, the flat cable 201 is pressed against the bottom wall 209 of the housing 203 by the plate portions 207 and 208, so that the clamp 200 can be fixed to the flat cable 201. The flat cable 201 can be fixed at a predetermined position by press-fitting the clip 210 of the clamp 200 into a locking hole formed at a predetermined position on the vehicle body.
[0005]
[Patent Document 1]
JP-A-9-89164 (FIG. 1)
[Patent Document 2]
JP-A-2002-10452 (FIG. 1)
[0006]
[Problems to be solved by the invention]
By the way, since the inside of the vehicle body on which the FFC is routed is narrow, it is difficult to work, and the FFC is hardly routed in a straight line and may be routed in various directions. ) Workability is poor. In addition, when the FFC is routed on the vehicle body, a large number of flat cable mounting members are attached to one FFC, and a large number of FFCs are routed on the vehicle body instead of one. For this reason, instead of arranging FFCs one by one on the vehicle body, a plurality of FFCs are laid out in a shape substantially the same as the shape laid out on the vehicle body, for example, on a wiring table outside the vehicle body, for example, with no obstacles around. I do. A flat cable attachment member or the like is attached in advance to each of the predetermined locations (locations to be fixed to the vehicle body) of each of the arranged FFCs. Then, the FFC to which the flat cable attachment member and the like are attached is positioned as it is at the wiring position of the vehicle body. After the positioning, the flat cable mounting members and the like are fixed to the vehicle body so that the flat cable mounting members and the like are not mounted on the FFC in a narrow vehicle body but on a wide outside of the vehicle body, for example, on a wiring board. Therefore, the workability of arranging the FFC is improved.
[0007]
However, since the FFC is long and may bend in various directions, the FFC is actually positioned on the vehicle body even if the mounting member for the flat cable is previously attached to each predetermined location of the FFC installed on the routing board. In this case, the position of the flat cable attachment member may deviate from the position of, for example, the locking hole of the vehicle body (a dimensional error occurs). In this case, the flat cable clamp or the clamp, which is the flat cable mounting member, must be once removed from the FFC and mounted again at a predetermined position. That is, since the flat cable clamp or the clamp is fixed to the FFC, the locking member is pulled out from the locking hole to release the engagement, or the lock projection and the lock arm are released from engagement. However, since it is not usually assumed that these engagements are released, it is difficult to release the engagement. In addition, it is difficult to work when the working place is a narrow place in the vehicle body, and as a result, the workability of wiring (assembling) the FFC to the vehicle body may be reduced.
[0008]
Accordingly, the present invention has been made in view of such circumstances, and an object of the present invention is to provide a flat cable attachment member capable of improving workability in assembling a flat cable to a fixed body such as a vehicle body. It is in.
[0009]
[Means for Solving the Problems]
In order to achieve the above object, a flat cable mounting member of the present invention is a flat cable mounting member having a mounting member main body attached to a flat cable so as to surround the flat cable, wherein the mounting member main body is A first plate attached to the flat cable in a temporarily locked state that allows the flat cable to move in the longitudinal direction, and a first plate that is movably engaged with each other from the temporarily locked state to the fully locked state. And a fixing means for fixing the mounting member body to the flat cable by holding the flat cable when the first plate and the second plate are in the fully locked state.
In this manner, by attaching the attachment member main body to the flat cable, the attachment member for the flat cable is attached in a temporarily locked state, and the movement of the flat cable in the longitudinal direction is allowed. For this reason, when routing a flat cable such as an FFC to which a flat cable mounting member is attached in advance to a fixed body such as a vehicle body, even if the relative position between the flat cable mounting member and the fixed body is shifted (the dimensional error is reduced). Even if it occurs), the position can be easily adjusted by moving the flat cable attachment member in the longitudinal direction of the flat cable. When the attachment position of the attachment member main body to the flat cable is determined, the first plate and the second plate are moved from the temporarily locked state to the fully locked state. When the first plate and the second plate move to the fully locked state, the flat cable is sandwiched by the fixing means, and the mounting member main body is fixed to the flat cable.
Therefore, since the mounting position can be adjusted without removing the mounting member main body from the flat cable, a flat cable mounting member in which the workability of assembling a flat cable such as an FFC to a fixed body such as a vehicle body is improved. become.
The first plate and the second plate are a pair of plates respectively covering the surface of the flat cable, and the first plate and the second plate slide from the temporary locked state to the fully locked state. Preferably, it is movably engaged.
The first plate and the second plate are each formed in a U-shape from a rectangular flat base covering the surface of the flat cable and a pair of side walls provided at both ends of the base. A pair of side walls of the plate and a pair of side walls of the second plate are movably engaged with each other, and the fixing means is provided on each of opposing surfaces of the base of the first plate and the base of the second plate. It is preferable that the first holding portion and the second holding portion are formed.
Preferably, the first plate and the second plate are a pair of separated plates, and these plates are assembled around a flat cable and attached to the flat cable.
Thereby, the attachment member main body can be quickly attached to an arbitrary position of the flat cable.
When the first plate and the second plate are attached to the flat cable, it is preferable that the first plate and the second plate are only movably engaged with each other from the temporarily locked state to the fully locked state.
This makes it easier to move the first plate and the second plate to the final locking state.
[0010]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.
1 to 5 are views showing an example of the flat cable mounting member of the present invention.
[0011]
As shown in FIGS. 1 to 5, the flat cable mounting member of the present invention is mounted on a flat cable 2 and fixed to a fixed body such as a vehicle body 3. In the flat cable mounting member 1, a mounting member main body 5 that surrounds a part (a part of the entire outer periphery) of the flat cable 2 and is mounted on the flat cable 2 allows the flat cable 2 to move in the longitudinal direction. The first plate 6 and the second plate 7 are attached to the flat cable 2 in the locked state, and are movably engaged with each other from the temporary locked state to the final locked state. It is characterized in that fixing means 8 for fixing the mounting member body 5 to the flat cable 2 by holding the flat cable 2 when the flat plate 6 and the second plate 7 are fully locked is provided. Further, it is preferable to provide a lock mechanism 9 for locking the first plate 6 and the second plate 7 in the fully locked state.
[0012]
The flat cable 2 may be any flat wire having flexibility, such as a flat wire harness, a flexible flat cable (FFC), and a flexible printed circuit (FPC). Can be For example, in the case of FFC as an example, a plurality of conductors made of copper or the like are arranged in parallel at a predetermined interval, and these conductors are sandwiched between two insulating sheets made of vinyl chloride or the like in a parallel state. A part in which two insulating sheets are in contact with each other is welded (heat-bonded) to be integrally fused. The FFC 2 has excellent flexibility and slidability, and is used for wiring of the vehicle body 3.
[0013]
The mounting member main body 5 includes a first plate 6 and a second plate 7, and may be formed in any manner as long as it surrounds the FFC 2 and is mounted on the FFC 2. It is preferable that the attachment member main body 5 be formed in a rectangular cylindrical shape in the fully locked state. Specifically, for example, the mounting member main body 5 is preferably formed in a rectangular cylindrical shape having an inner width slightly longer than the width of the FFC 2 and an inner height equal to or larger than the thickness of the FFC 2.
[0014]
That is, the first plate 6 and the second plate 7 may be formed in any manner as long as the first plate 6 and the second plate 7 are preferably formed in a rectangular cylindrical shape in the final locking state. It is preferable to form them in a U-shape.
[0015]
The first plate 6 and the second plate 7 include rectangular flat bases 10 and 11 that cover the surface of the FFC 2, and a pair of side walls 12, 12, 13 and 13 provided on both side ends of the bases 10 and 11. And are formed in a U-shape. One plate, for example, the second plate 7 is formed in a size to be fitted between the side walls 12, 12 of the first plate 6. That is, the width of the base 11 of the second plate 7 (the length in the direction orthogonal to the surface of the side wall 13) is formed to be the same as or slightly shorter than the length between the inner surfaces of the side walls 12 of the base 10 of the first plate 6. I have. The height of the side wall 13 of the second plate 7 (the length in the direction perpendicular to the surface of the base 11) is the same as or slightly shorter than the length from the inner surface of the base 10 to the tip of the side wall 12 of the first plate 6. Is formed. Since the space between the side walls 13 and 13 of the second plate 7 is inside the mounting member main body 5, the width between the inner surfaces of the side walls 13 of the base 11 of the second plate 7 is equal to or larger than the width of the FFC 2, preferably slightly longer than the width. In addition to the dimensions, the length from the inner surface of the base 11 to the tip of the side wall 13 of the second plate 7 should be greater than the thickness of the FFC 2.
[0016]
The length of the second plate 7 (the length of the base 11 in the extending direction of the side wall 13 (the length of the FFC 2 in the extending direction)) may be formed to be the same as or slightly shorter than the length of the first plate 6. preferable. The length of the base 10 of the first plate 6 and the length of the base 11 of the second plate 7 (the length of the mounting member main body 5) allow the mounting member main body 5 to be fixed to the vehicle body 3 and the mounting member It is set arbitrarily from a range where the main body 5 can be fixed to the FFC 2.
The thickness of the first plate 6 and the thickness of the second plate 7 (thickness of the mounting member main body 5) are determined when the locking portion 20 is locked to the vehicle body 3 and when the fixing member 8 fixes the mounting member main body 5 to the FFC2. When it is fixed to the shape, it is formed so as not to be deformed.
[0017]
The locking portion 20 is provided on one of the first plate 6 and the second plate 7, for example, at a substantially central portion of the outer surface of the base of the first plate 6, and is provided upright along a direction perpendicular to the surface. I have.
The locking portion 20 is inserted (for example, press-fitted) into the locking hole 4 of the vehicle body 3 and locked to fix the flat cable mounting member 1 to the vehicle body 3. For example, a clip portion may be used.
[0018]
The clip portion 20 includes, for example, a pair of support portions 21 protruding from the surface of the base portion 10 and a pair of flexible portions extending from the front end portion of the support portion 21 toward the base portion 10 and having a locking step 22 at the front end portion. It comprises flexible locking portions 23, 23.
[0019]
The distal end portion of the support portion 21 and the root portion of the flexible locking portion 23 are formed in a size and a shape that can be inserted into the locking hole 4 of the vehicle body 3, and are, for example, substantially semi-spherical, substantially semi-elliptical. And the like.
[0020]
The flexible locking portion 23 is formed so as to be inclined in a direction away from the support portion 21 as the outer surface goes to the distal end portion in a natural state where no external force is applied.
Only the base of the flexible locking portion 23 is provided integrally with the distal end of the supporting portion 21, and a space is formed between the flexible locking portion 23 and the other supporting portions 21. Accordingly, when the flexible locking portion 23 is pressed in the space direction (when an external force is applied), the flexible locking portion 23 is flexed into the space (inward) against the urging force, and the vehicle body is bent. 3 can be penetrated.
[0021]
The locking step portion 22 is formed such that the flexible locking portion 23 is flexible against the urging force and penetrates the locking hole 4 of the vehicle body 3 to return to the original shape by the urging force or to return to the original shape. When it moves to return to the position, it is locked to the periphery of the vehicle body 3 forming the locking hole 4. At this time, it is preferable to set the length of the support portion 21 of the clip portion 20 so that the outer surface of the base portion 10 makes surface contact with the surface of the vehicle body 3.
[0022]
The first plate 6 and the second plate 7 may be configured in any manner as long as they are attached to the FFC 2 in a temporarily locked state. However, after the FFC 2 is positioned in one of the plates 7, It is preferable that the FFC 2 can be attached to the FFC 2 in a temporarily locked state by attaching (engaging) the other plate 6. Further, the first plate 6 and the second plate 7 may have any configuration as long as their positions are movably engaged with each other from the provisionally locked state to the fully locked state. May be varied, but is preferably configured to be moved to a fully locked state by sliding movement.
[0023]
For example, the first plate 6 is provided with an engagement groove 30, a slide groove 31, and a first lock 32, and the second plate 7 is provided with an engagement protrusion 40, a slide protrusion 41, and a second lock 42. Thus, while being attached to the FFC 2 in the provisionally locked state, it may be moved from the provisionally locked state to the fully locked state by sliding.
[0024]
The engagement grooves 30 are provided along the surface of the base 10 at the roots (places in contact with the base 10) at one side ends of the inner surfaces of both side walls 12, 12 of the first plate 6. The engaging groove 30 is formed to have a concave cross section, and its length and width are not particularly limited.
[0025]
The slide groove portion 31 includes a slide groove 33 provided along the surface of the base 10 at a root portion of the other side end of the inner surface of both sides 12, 12 of the first plate 6, and a side wall of the first plate 6. Attachment grooves 34 are provided at the other end of the inner surface of the inner surface 12 along the side end. The slide groove 33 and the mounting groove 34 form an L-shaped groove.
[0026]
The slide groove 33 is formed in a concave shape in cross section, the length thereof is formed to be longer than the length of the engagement groove portion 30, and the width thereof is not particularly limited. It is preferable that the bottom surface of the slide groove 33 is inclined according to the inclined surface 41a so that the bottom surface of the slide groove 33 can make surface contact with the inclined surface 41a of the slide protrusion 41 described later.
The mounting groove 34 is formed by cutting out the side end of the side wall 12 of the first plate 6 in an L-shape. The width of the mounting groove 34 is formed such that the length from the position of the groove wall forming the mounting groove 34 to the innermost part of the slide groove 33 is slightly shorter than the length of the slide groove 31.
At the end of the mounting groove 34 in contact with the slide groove 31, a right triangular mounting engagement portion 35 having a vertical surface 35 a whose slide groove 31 side extends along a direction orthogonal to the surface of the side wall 12 is provided. Have been.
[0027]
The first lock portion 32 is a lock protrusion protruding substantially at the center of the inner end surface of each of the side walls 12, 12 of the first plate 6. The lock projection 32 has a vertical surface 32a in which the engagement groove 30 side extends along a direction orthogonal to the surface of the side wall 12 and an inclined surface 32b inclined from the top of the vertical surface 32a to the slide groove 31 side. It is formed in the shape of a right triangle.
[0028]
The engagement protrusions 40 are provided near the one end side wall of the outer surfaces of both side walls 13, 13 of the second plate 7 along the direction perpendicular to the outer surface of the side wall 13. The engagement protrusion 40 is formed, for example, in a columnar shape. The height of the engagement protrusion 40 is formed to be the same as or slightly shorter than the depth of the engagement groove 30. The width (diameter) of the engaging projection 40 is formed to be the same as or slightly shorter than the width of the engaging groove 30.
[0029]
The slide protrusions 41 are provided along the base 11 on the other end side walls of the outer surfaces of both side walls 13, 13 of the second plate 7. The slide projection 41 has a trapezoidal shape having a vertical surface 41b whose base portion extends along a direction orthogonal to the surface of the side wall 13 and an inclined surface 41a inclined from the top of the vertical surface 41b to the tip end side. It is formed in a triangular shape.
The width of the slide projection 41 is formed to be the same as or slightly shorter than the width of the slide groove 31.
The length of the slide projection 41 is the same as or slightly shorter than the length of the slide groove 31.
[0030]
As a result, the first plate 6 and the second plate 7 are opposed to each other on the inner surfaces as shown in FIG. 3, and the second plate 7 is tilted with respect to the first plate 6. Is engaged with the engagement groove 30 of the first plate 6. After the engagement protrusion 40 is brought into contact with the innermost portion of the engagement groove 30, the slide protrusion 41 is rotated around the engagement protrusion 40 in a direction in which the slide protrusion 41 contacts the first plate 6, and FIG. When the slide projection 41 is located in the slide groove 33 from the mounting groove 34 via the mounting engagement part 35 as shown in FIG. 5, the first plate 6 and the second plate 7 are parallel and the first plate 6 and the second plate 7 are slidably engaged with each other at a position where the opposing positions of the plates are substantially the same from a stepped state.
[0031]
As shown in FIG. 6, the second lock portion 42 engages with the movement groove 45 provided substantially at the center of the outer surface of both side walls 13, 13 of the second plate 7 and the lock projection 32 to make the first plate A temporary locking lock recess 46 for engaging the first plate 6 and the second plate 7 in a temporary locking state; a final locking lock recess 47 for locking the first plate 6 and the second plate 7 in the final locking position; Consists of
[0032]
The movement groove 45 is used when the slide protrusion 41 is positioned in the slide groove 33 from the mounting groove 34 through the mounting engagement part 35 in a state where the engagement protrusion 40 is in contact with the innermost part of the engagement groove 30. The groove through which the lock projection 32 passes.
[0033]
The temporary locking lock concave portion 46 is configured such that the opposing positions of the plates 6 and 7 are substantially the same from the state in which the slide protrusion 41 is positioned in the slide groove 33 from the mounting groove 34 via the mounting engagement portion 35 (stepped state). The lock projection 32 is engaged during the sliding movement. The temporary locking lock concave portion 46 is formed by a vertical surface 46a where the vertical surface 32a of the lock projection 32 makes surface contact and an inclined surface 46b where the inclined surface 32b of the lock projection 32 makes surface contact. The locking lock recess 46 does not move over the vertical surface 46a.
The wall on the side of the engaging projection 40 that forms the temporary locking lock recess 46 is formed as an inclined surface 48 so that the lock projection 32 gets over and engages with the temporary locking lock recess 46.
[0034]
The final locking lock recess 47 locks the lock projection 32 when the plates 6 and 7 slide and move so that the opposing positions of the plates 6 and 7 become substantially the same from the temporary engagement state. The final locking lock concave portion 47 is formed by a vertical surface 47a where the vertical surface 32a of the lock projection 32 comes into surface contact and an inclined surface 47b where the inclined surface 32b of the lock projection 32 comes into surface contact. The locking lock recess 47 does not move over the vertical surface 47a. In this state, since the slide protrusion 41 is in contact with the innermost portion of the slide groove 33, the lock protrusion 32 does not climb over the inclined surface 47b of the final locking lock recess 47, and the lock protrusion 32 The stop lock recess 47 locks. The lock mechanism 9 is configured by the lock protrusion 32, the final locking lock recess 47, the slide protrusion 41, and the slide groove 33.
[0035]
The fixing means 8 has moved the first plate 6 and the second plate 7 from the temporarily locked state (temporarily locked state) to the fully locked state (full locking position), as shown in FIGS. At this time, any configuration may be used as long as the mounting member main body 5 can be fixed to the FFC 2 while sandwiching the FFC 2. The fixing means 8 includes, for example, a first holding portion 51 provided on the inner surface of the base 10 of the first plate 6 and a second holding portion 52 provided on the inner surface of the base 11 of the second plate 7.
[0036]
The first sandwiching portion 51 is, for example, a sandwiching projecting portion that extends along the width direction and protrudes substantially at the center of the inner surface of the base 10 of the first plate 6 in the length direction. The shape of the holding projection 51 is not particularly limited, and is formed into a curved surface such as a semicircular cross-section or a semi-elliptical cross-section. The length of the holding projection 51 (the length of the base 10 in the width direction) is not particularly limited as long as the slide movement of the plates 6 and 7 is not hindered, and the side walls 13 and 13 of the base 11 of the second plate 7 are not limited. The dimension may be slightly shorter than the length between the inner surfaces or shorter.
[0037]
The second holding portion 52 is, for example, a flexible holding member projecting along the width direction at a position from the engagement protrusion 40 from a substantially central portion in the length direction of the inner surface of the base 11 of the second plate 7. Is a piece. The flexible holding piece 52 is formed in, for example, a rectangular plate having flexibility, and is provided on the base 11 so as to be inclined toward the slide protrusion 41. The length of the flexible holding piece 52 (the length of the base 11 in the width direction) may be formed in accordance with the length of the holding protrusion 51, or may be formed longer or shorter than that length. May be.
[0038]
When the first plate 6 and the second plate 7 are in the temporarily locked state, the interval between the flexible holding piece 52 and the first plate 6 such as the holding protrusion 51 is set in the mounting member body 5. However, when the plate is moved to the final locking position, a portion of the outer surface closer to the front end than the front end thereof abuts against the holding projection 51 and is flexed against the urging force. And is formed so as to come into contact with the holding projection 51. That is, when the FFC 2 is located between the holding projection 51 and the flexible holding piece 52 and the plates 6 and 7 are moved to the final locking position, the biasing force of the flexible holding piece 52 causes the FFC 2 to come into contact with the flexible holding piece 52. The mounting member main body is fixed to the FFC 2 by being held by the holding projection 51.
[0039]
Although the holding projection is provided on the first plate 6 and the flexible holding piece is provided on the second plate 7, the provided plates may be reversed, and the pair of holding projections and the flexible holding piece may be provided. A plurality of sets may be provided. As described above, when a plurality of sets of a pair of holding protrusions and flexible holding pieces are provided, the plates provided with the holding protrusions may be the same plate or alternately different plates. Further, a pair of holding protrusions and a flexible holding piece may be provided in a zigzag shape.
[0040]
Now, in order to fix the FFC 2 to the vehicle body 3 using the flat cable attachment member 1, first, for example, one surface of a predetermined portion of the FFC 2 is covered with the first plate 6. This allows the FFC 2 to be inserted between the pair of side walls 12 of the first plate 6 so that the inner surface of the base 10 and one surface of the FFC 2 face each other, as shown in FIG. At this time, the holding projection 51 is covered with one surface of the FFC 2.
[0041]
The FFC 2 makes the inner surfaces of the first plate 6 and the second plate 7 located between the pair of side walls 12, 12 face each other. Both engagement projections 40 of the second plate 7 are engaged with the engagement grooves 30 of the first plate 6 with the second plate 7 inclined with respect to the first plate 6. The second plate 7 is moved along the direction in which the first plate 6 extends, and the engagement protrusion 40 is brought into contact with the innermost portion of the engagement groove 30.
[0042]
After the contact, the second plate 7 is rotated about the engagement protrusion 40 in the direction in which the slide protrusion 41 comes into contact with the first plate 6, and the slide protrusion 41 is attached as shown in FIG. It is positioned (engaged) in the slide groove 33 from the groove 34 via the mounting engagement portion 35. Thus, the first plate 6 and the second plate 7 are stepped, but the second plate 7 is fitted into the first plate 6. That is, the first plate 6 and the second plate 7 form a rectangular cylindrical attachment member body. Further, since the vertical surface 41b of the slide protrusion 41 is in surface contact with the vertical surface 35a of the mounting engagement portion 35, the second plate 7 does not rotate around the engagement protrusion 40. That is, the first plate 6 and the second plate 7 are brought into contact with each other by the engagement between the engagement groove 30 and the engagement protrusion 40 and the engagement between the slide groove 33 and the slide protrusion 41. Are engaged so that only sliding movement is possible. As a result, the first plate 6 and the second plate 7 can be easily moved between the first plate 6 and the second plate 7 because the other movement cannot be performed only by the slide movement. [0043]
Then, for example, the second plate 7 is slid along the direction from the slide protrusion 41 to the engagement protrusion 40 so that the step between the first plate 6 and the second plate 7 is eliminated. Then, when the lock projection 32 gets over the inclined surface 48 and engages with the temporary locking lock concave portion 46, the sliding movement of the second plate 7 is stopped. Thereby, the flat cable mounting member 1 can be mounted on the FFC 2 in a temporarily locked state.
[0044]
As described above, the first plate 6 and the second plate 7 are a pair of separated plates, and these plates 6 and 7 are assembled on the outer periphery of the FFC 2 to become the mounting member main body 5 and are mounted on the FFC 2. The attachment member main body 5 can be quickly attached to any part of the FFC 2.
[0045]
In this state, since the distance between the flexible holding piece 52 and the first plate 6 such as the holding protrusion 51 is formed to be longer than the thickness of the FFC 2 in the mounting member main body 5, the flat cable mounting member is used. 1 is allowed to move the FFC 2 in the longitudinal direction. For this reason, when the FFC 2 is positioned on the vehicle body 3 after the flat cable mounting member 1 is mounted on the FFC 2 in advance, the relative position between the clip portion 20 of the flat cable mounting member 1 and the locking hole 4 of the vehicle body 3 is determined. Even if there is a deviation (even if a dimensional error occurs), the flat cable mounting member 1 can be easily moved along the longitudinal direction of the FFC 2 without removing the flat cable mounting member 1 from the FFC 2, The mounting position of the flat cable mounting member 1 can be easily adjusted.
[0046]
Then, the clip portion 20 of the flat cable mounting member 1 is abutted against the locking hole 4 of the vehicle body 3 as shown in FIG. 1, and the flat cable mounting member 1 is brought into contact with the vehicle body 3 in this state. That is, the flat cable mounting member 1 is moved in the direction of the vehicle body 3 so that the clip portion 20 is inserted into the locking hole 4.
[0047]
Then, the distal end portion of the support portion 21 of the clip portion 20 and the root portion of the flexible locking portion 23 enter the locking hole 4. Further, when the flat cable mounting member 1 approaches the vehicle body 3, the flexible locking portion 23 comes into contact with the vehicle body 3 forming the locking hole 4 and flexes against the support portion 21 against the urging force. And enters the locking hole 4. When the flexible locking portion 23 excluding the locking step portion 22 passes through the locking hole 4, the flexible locking portion 23 moves to return to the original shape by the urging force, and Locks on the periphery of the vehicle body 3 forming the locking hole 4. At this time, the outer surface of the base 10 contacts the surface of the vehicle body 3, and the flat cable attachment member 1 is fixed to the vehicle body 3.
[0048]
After the fixation, the second plate 7 is slid along the direction from the slide projection 41 to the engagement projection 40 so that the step between the first plate 6 and the second plate 7 is eliminated. Then, the lock projection 32 climbs over the inclined surface 46b of the temporary locking lock concave portion 46 and engages with the final locking lock concave portion 47, as shown in FIGS. The step between the second plate 6 and the second plate 7 is eliminated, the first plate 6 and the second plate 7 overlap, and the cylindrical attachment member main body 5 with no protrusion is obtained.
[0049]
At this time, the slide plate 41 does not abut on the wall forming the innermost groove of the slide groove 33, and the second plate 7 does not move forward in the slide movement. In addition, since the vertical surface 32a of the lock projection 32 and the vertical surface 47a of the final locking lock recess 47 are in surface contact, the second plate 7 does not move backward in the sliding movement. Thereby, as shown in the figure, the first plate 6 and the second plate 7 are locked in the fully locked state.
As described above, when the first plate 6 and the second plate 7 are slid and moved to the final locking position, the vicinity of the outer end of the flexible holding piece 52 near the front end portion of the flexible holding piece 52 holds the FFC 2 in the mounting member body 5 to the holding projection 51. Press against it. The flexible holding piece 52 is flexible against the urging force by the pressing force. That is, the FFC 2 is held between the flexible holding piece 52 and the holding protrusion 51 by the urging force of the flexible holding piece 52, and the mounting member main body is fixed to the FFC 2.
[0050]
Although the flat cable mounting member 1 is fixed to the vehicle body 3 via the clip portion 20 earlier, the position adjustment of the clip portion 20 of the flat cable mounting member 1 to the locking hole 4 of the vehicle body 3 in the vehicle body 3. After that, the first plate 6 and the second plate 7 are slid and fixed to the flat cable mounting member 1 to the FFC 2, and then the flat cable mounting member 1 is fixed to the vehicle body 3 via the clip portion 20. You may make it.
[0051]
Therefore, the position of the flat cable mounting member 1 of the present invention can be easily adjusted after the flat cable mounting member 1 is mounted on the FFC 2, so that the workability of assembling the FFC 2 to the vehicle body 3 can be improved. .
[0052]
Further, after the attachment member main body 5 is locked and fixed to the vehicle body 3 by the clip portion 20, the attachment member main body 5 is fixed to the FFC 2 so that the attachment member main body 5 is fixed even after the attachment member main body 5 is fixed to the vehicle body 3. Can be adjusted at the position at which is fixed to FFC2. When the mounting member main body 5 is fixed to the vehicle body 3, the mounting member main body 5 and the FFC 2 are not in a fixed state, so that the fixing member main body 5 is fixed to the vehicle body 3 at low cost. Therefore, the workability of assembling the FFC 2 to the vehicle body 3 is further improved.
[0053]
【The invention's effect】
As described above, a flat cable attachment member that improves the workability of assembling the flat cable to the fixed body is obtained.
[Brief description of the drawings]
FIG. 1 is a perspective view showing an example of a flat cable mounting member of the present invention.
FIG. 2 is a perspective view showing a state where the flat cable mounting member of the present invention is fixed to a vehicle body.
FIG. 3 is a side view showing a state where the flat cable mounting member of the present invention is fixed to a vehicle body.
FIG. 4 is a perspective view showing a state where the flat cable mounting member of the present invention is fixed to a vehicle body.
FIG. 5 is a side view showing a state where the flat cable mounting member of the present invention is fixed to a vehicle body.
FIG. 6 is a plan view showing an example of the lock mechanism of the present invention.
FIG. 7 is a perspective view showing a conventional flat cable mounting member.
FIG. 8 is a perspective view showing a conventional flat cable mounting member.
[Explanation of symbols]
1 Mounting member for flat cable 2 FFC (flat cable)
Reference Signs List 3 vehicle body 4 locking hole 5 mounting member main body 6 first plate 7 second plate 8 fixing means 9 locking mechanism 10 base 11 base 12 side wall 13 side wall 20 clip portion (lock portion)
21 Supporting part 22 Locking step part 23 Flexible locking part 30 Engagement groove part 31 Slide groove part 32 Lock projection (first lock part)
33 slide groove 34 mounting groove 35 mounting engaging part 40 engaging projection 41 slide projection 42 second locking part 45 moving groove 46 temporary locking lock concave part 47 final locking lock concave part 51 clamping projection (first clamping part)
52 Flexible holding piece (second holding section)

Claims (5)

A flat cable mounting member having a mounting member main body attached to a flat cable so as to surround the flat cable, wherein the mounting member main body is in a temporarily locked state allowing movement of the flat cable in a longitudinal direction. A first plate and a second plate which are attached to the flat cable and whose positions are movably engaged with each other from the provisionally locked state to the fully locked state are provided. A fixing member for a flat cable, comprising: fixing means for fixing the main body of the mounting member to the flat cable by holding the flat cable in the locked state. The first plate and the second plate are a pair of plates respectively covering the surface of the flat cable, and the first plate and the second plate slide from the temporary locked state to the fully locked state. The flat cable mounting member according to claim 1 movably engaged. The first plate and the second plate are each formed in a U-shape from a rectangular flat base covering the surface of the flat cable and a pair of side walls provided at both ends of the base. A pair of side walls of the plate and a pair of side walls of the second plate are movably engaged with each other, and the fixing means is provided on each of opposing surfaces of the base of the first plate and the base of the second plate. The flat cable mounting member according to claim 1 or 2, comprising a first holding portion and a second holding portion. The said 1st plate and the said 2nd plate are a pair of separated plates, These plates are assembled in the outer periphery of a flat cable, and are attached to a flat cable. Mounting member for flat cable. 5. The device according to claim 1, wherein the first plate and the second plate are movably engaged with each other only when the first plate and the second plate are attached to the flat cable from the temporarily locked state to the fully locked state. The mounting member for a flat cable according to claim 1.

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