JP4632420B2 - Power transmission cable and cable terminal assembly and collar member - Google Patents

Description

  The present invention relates to a power transmission cable used as, for example, a vehicle transmission cable, a cable terminal assembly used in the power transmission cable, and a collar member used in the cable terminal assembly.

  FIG. 15 is a combined perspective view of the terminal portion in the shift lever direction of the conventional transmission cable. The transmission cable 100 is interposed between a shift lever (not shown) and the transmission. The operating force of the driver is transmitted to the transmission by the transmission cable 100. The transmission cable 100 includes an inner cable (not shown), an outer tube (not shown), a cable terminal assembly 101, a lever member 102, and a pin member 103. The inner cable can slide in the outer tube in the axial direction. The cable terminal assembly 101 is fixed to both ends of the inner cable (that is, the shift lever direction end and the transmission direction end). The cable terminal assembly 101 and the lever member 102 are connected via a pin member 103 so as to be rotatable and slidable.

FIG. 16 is an exploded perspective view of the cable terminal assembly disposed at the terminal portion of the transmission cable in the shift lever direction. As shown in the figure, the cable terminal assembly 101 includes a metal rod member 101a and a resin collar member 101b. A mounting hole 101c is formed at the tip of the rod member 101a. The collar member 101b is inserted into the attachment hole 101c. A connecting hole 101f is formed in the collar member 101b. Returning to FIG. 15, the lever member 102 has a power transmission hole 102a. The power transmission hole 102a and the connection hole 101f are arranged coaxially and in series. The pin member 103 passes through the power transmission hole 102a and the connection hole 101f. In this manner, the cable terminal assembly 101 and the lever member 102 are connected to each other by the pin member 103 so as to be rotatable and slidable.
Japanese Utility Model Publication No. 60-019814 Japanese Utility Model Publication No. 49-102175

  Incidentally, in the cable terminal assembly 101, it is necessary to regulate the axial displacement and circumferential displacement of the collar member 101b with respect to the mounting hole 101c of the rod member 101a. That is, when the collar member 101b moves in the axial direction, the collar member 101b may fall off from the attachment hole 101c. When the collar member 101b moves in the circumferential direction, a sliding interface at the time of power transmission is developed between the outer peripheral surface of the collar member 101b and the inner peripheral surface of the attachment hole 101c. On the other hand, in terms of design, the sliding interface is set between the inner peripheral surface of the connecting hole 101f of the collar member 101b and the outer peripheral surface of the pin member 103. Therefore, if the collar member 101b moves (that is, rotates) in the circumferential direction with respect to the attachment hole 101c, the operation feeling at the time of shift change may be deteriorated.

  In view of these points, the outer peripheral diameter of the collar member 101b (the outer peripheral diameter before being inserted into the mounting hole 101c) is set larger than the hole diameter of the mounting hole 101c. That is, a margin for fastening the collar member 101b with respect to the attachment hole 101c is set. If the tightening margin is set large, the collar member 101b is difficult to move with respect to the mounting hole 101c. For this reason, the axial displacement and circumferential displacement of the collar member 101b with respect to the mounting hole 101c can be restricted.

  However, if the tightening margin of the collar member 101b with respect to the mounting hole 101c is set large, the diameter of the connecting hole 101f of the collar member 101b may be small when a thermal load is applied to the collar member 101b. That is, the outer peripheral diameter of the collar member 101b before insertion is smaller than the hole diameter of the attachment hole 101c. For this reason, in the hole of the attachment hole 101c, the collar member 101b is held in a state compressed in the diameter reducing direction. Therefore, when a thermal load is applied, there is a possibility that the hole diameter of the connecting hole 101f becomes small due to a combination of thermal creep and thermal contraction. When the hole diameter of the connecting hole 101f is reduced, the allowance for the collar member 101b is reduced. In addition, the sliding resistance between the inner peripheral surface of the connecting hole 101f and the outer peripheral surface of the pin member 103 is increased. For this reason, even if the tightening margin is set large, the collar member 101b may eventually rotate with respect to the mounting hole 101c during power transmission. In other words, the connecting hole 101f, that is, the collar member 101b and the pin member 103 may rotate together.

  On the other hand, even if the tightening margin of the collar member 101b with respect to the mounting hole 101c is set small, the collar member 101b and the pin member 103 may still rotate together as described above. Further, if the tightening margin of the collar member 101b with respect to the attachment hole 101c is set small, the rod member 101a and the collar member 101b may be separated when the cable terminal assembly 101 is conveyed.

  In this regard, Patent Document 1 introduces a cable terminal assembly in which an engagement claw is provided at an end in the insertion direction of the collar member with respect to the attachment hole. FIG. 17 shows an exploded perspective view of the same type of cable terminal assembly. FIG. 18 shows a combined perspective view of the cable terminal assembly. In these drawings, portions corresponding to those in FIG. 16 are denoted by the same reference numerals.

  As shown in the drawing, a plurality of engaging claws 101h are provided around the slit 101g at the insertion direction end of the collar member 101b. The diameter of the imaginary circle connecting the outer peripheral ends of these engaging claws 101h is set larger than the hole diameter of the attachment hole 101c. When the attachment hole 101c passes, the engaging claw 101h is elastically curved toward the inner peripheral side. After passing through the attachment hole 101c, the engagement claw 101h is elastically restored and locked to the hole edge of the attachment hole 101c. According to the cable terminal assembly 101, the axial displacement of the collar member 101b with respect to the attachment hole 101c can be restricted.

  However, even in the case of the cable terminal assembly 101 described in the same document, it is difficult to regulate the circumferential displacement of the collar member 101b with respect to the attachment hole 101c. A slit 101g is formed between the engaging claws 101h. Therefore, the sliding resistance between the inner peripheral surface of the connecting hole 101f of the collar member 101b and the outer peripheral surface of the pin member and the sliding resistance between the outer peripheral surface of the collar member 101b and the inner peripheral surface of the mounting hole 101c during power transmission. Is unstable. Therefore, the operation feeling at the time of shift change may be deteriorated. In addition, if the slit 101g is arranged in the collar member 101b, foreign matter or the like may be accumulated in the slit 101g. For this reason, there exists a possibility that abrasion of a sliding part may be promoted by a foreign material. Therefore, the operation feeling may be further deteriorated.

  Patent Document 2 introduces a connecting rod mounting tool having a bush and a connecting rod gripping portion. The bush has a short-axis cylindrical shape. The bush includes a connecting rod insertion hole, an engaging claw and a slit as shown in FIG. The bush is press-fitted and held in a press-fitting hole of a lever member for power transmission. The connecting rod insertion hole penetrates a predetermined position eccentric with respect to the bush shaft center in the axial direction. The connecting rod gripping part is formed integrally with the bush. The connecting rod gripping portion protrudes in the diameter increasing direction from one end in the bush axis direction. The connecting rod has an L shape. The intermediate portion of the connecting rod is held by the connecting rod holding portion. The refracting tip of the connecting rod penetrates the connecting rod insertion hole. That is, the connecting rod is fixed to the bush by the connecting rod gripping portion and the connecting rod insertion hole.

  During power transmission, the outer peripheral surface of the bush and the inner peripheral surface of the press-fitting hole of the lever member rotate and slide relatively. On the other hand, the inner peripheral surface of the bush (that is, the inner peripheral surface of the connecting rod insertion hole) and the connecting rod do not move relatively. That is, the bush and the connecting rod move together.

  If the connecting rod mounting tool described in Patent Document 2 is diverted to the cable terminal assembly, the collar member and the pin member (corresponding to the bush and connecting rod in Patent Document 2) move together. For this reason, it is difficult to regulate the circumferential displacement of the collar member with respect to the mounting hole.

  Similarly, when the connecting rod attachment described in Patent Document 2 is diverted to the cable terminal assembly, a slit similar to Patent Document 1 is formed between the engaging claws of the collar member. For this reason, the sliding resistance between the collar member outer peripheral surface and the mounting hole inner peripheral surface (corresponding to the bush outer peripheral surface and the press-fitting hole inner peripheral surface of Patent Document 2) during power transmission is still unstable. is there. Therefore, the operation feeling at the time of shift change may be deteriorated. In addition, if a slit is disposed in the collar member, foreign matter or the like may still accumulate in the slit.

  The power transmission cable, cable terminal assembly, and collar member of the present invention have been completed in view of the above problems. Therefore, the present invention provides a power transmission cable, a cable terminal assembly, and a collar member that are capable of regulating at least one of an axial displacement and a circumferential displacement of the collar member with respect to the mounting hole and that have a good operation feeling. Objective.

(1) In order to solve the above-described problem, a cable terminal assembly according to the present invention includes a rod body that is connected to at least one end of a cable body capable of transmitting power , and a ring portion that is connected to one end of the rod body and defines an attachment hole. A rod member that is disposed on the inner circumferential side of the mounting hole, defines a coupling hole that the other member rotates and slidably contacts with, and has a substantially outer peripheral surface having a substantially the same diameter, and the rod body. And a resin-made collar member having a restricting portion that restricts at least one of an axial displacement and a circumferential displacement of the cylindrical portion with respect to the attachment hole.

  Here, the cylindrical part has “circumferential outer circumferential surface of substantially the same diameter” as well as the axial end portion of course when the entire axial direction of the cylindrical part has an outer circumferential surface of substantially the same diameter. In some cases, taper processing, chamfering processing, and the like are performed.

  In the cable terminal assemblies shown in FIGS. 15 and 16, the axial displacement and circumferential displacement of the collar member 101b relative to the mounting hole 101c are restricted by friction between the outer circumferential surface of the collar member 101b and the inner circumferential surface of the mounting hole 101c. I was trying.

  In the cable terminal assemblies shown in FIGS. 17 and 18, the circumferential displacement of the collar member 101b relative to the mounting hole 101c is to be restricted by friction between the outer peripheral surface of the collar member 101b and the inner peripheral surface of the mounting hole 101c. . In addition, the axial displacement of the collar member 101b with respect to the mounting hole 101c is to be restricted by the engagement of the engaging claw 101h with the hole edge of the mounting hole 101c.

In contrast to these conventional cable terminal assemblies, the outer peripheral surface of the cylindrical portion of the collar member of the cable terminal assembly of the present invention has a circumferential shape with substantially the same diameter. That is, the slit is not arrange | positioned at the cylinder part. For this reason, the sliding resistance between the connection hole inner peripheral surface and the counterpart member outer peripheral surface during power transmission is stable. Therefore, the operation feeling at the time of shift change is good. In addition, since the slit is not disposed in the cylindrical body portion, there is no possibility that foreign matter or the like is accumulated in the slit. For this reason, there is no possibility that the wear of the sliding portion is promoted by the foreign matter. Therefore, it is possible to suppress the deterioration of the operation feeling due to wear.

  And the collar member of the cable terminal assembly of this invention is provided with the control part. The restricting portion comes into contact with the rod body, not the attachment hole. According to the cable terminal assembly of the present invention, it is not necessary to regulate axial displacement and circumferential displacement of the collar member with respect to the attachment hole due to friction between the outer peripheral surface of the cylindrical body portion and the inner peripheral surface of the attachment hole. For this reason, unlike the prior art, there is no need to set a large allowance for the collar member with respect to the mounting hole. Therefore, when a thermal load is applied to the collar member, the hole diameter of the connecting hole of the collar member is not easily reduced. That is, even if a thermal load is applied, the sliding resistance between the inner peripheral surface of the connection hole and the outer peripheral surface of the counterpart member is unlikely to increase. For this reason, at the time of power transmission, there is little possibility that the connecting hole, that is, the collar member and the counterpart member rotate together.

  The restricting portion of the cable terminal assembly of the present invention is suitable for restricting the circumferential displacement of the collar member with respect to the mounting hole (of course, restricting only the circumferential displacement and the axial displacement or the axial displacement). May be good). That is, the restricting portion protrudes in the diameter increasing direction with respect to the cylindrical portion. The restricting portion is in contact with the rod body. Here, the rod main body contact portion in the restricting portion is located on the outer peripheral side with respect to the interface between the outer peripheral surface of the cylindrical portion and the inner peripheral surface of the attachment hole. For this reason, according to the cable terminal assembly of the present invention, the circumferential displacement of the collar member with respect to the mounting hole can be regulated with a relatively small force.

  (2) Preferably, it is better that the restricting portion is an external fitting restricting portion that is externally fitted to the rod body. According to this configuration, the restricting portion is pressed against the outer surface of the rod body. For this reason, at least one of the axial displacement and the circumferential displacement of the collar member with respect to the mounting hole can be more strongly regulated.

(3) Preferably, in the configuration of (2), the outer fitting restricting portion is a partial arc-shaped outer fitting restricting portion having an opening in a part in a circumferential direction, and at an arbitrary distance from the axis of the cylindrical body portion. a straight line connecting the arc center and the opening center of the partial circular arc shape-fitting restriction portion, the axis of said cylindrical body portion, is substantially parallel, when inserting the tube body portion in said mounting hole, is opening It is better to have a configuration in which the partial arc-shaped external fitting restricting portion is externally fitted to the rod main body by elastically expanding along the rod main body and performing backward contraction.

  That is, in this configuration, the direction of the opening of the partial arc-shaped outer fitting restricting portion and the axis of the cylindrical portion are substantially matched. According to this configuration, the partial arc-shaped external fitting restricting portion can be externally fitted to the rod body at the same time when the cylindrical body portion is inserted into the attachment hole. That is, the collar member and the rod member can be assembled in one motion. Thus, the cable terminal assembly of this structure is excellent in assembling workability.

  (4) Preferably, the hole diameter of the attachment hole should be larger than the outer diameter of the cylindrical body. According to this structure, the fastening allowance of the cylinder part with respect to an attachment hole does not generate | occur | produce. For this reason, even if it is a case where a thermal load is added to a cylinder part, there is no possibility that the hole diameter of a connection hole becomes small. Therefore, there is no possibility that the sliding resistance between the inner peripheral surface of the connecting hole and the outer peripheral surface of the counterpart member will increase. That is, there is no possibility that the connecting hole, that is, the collar member and the counterpart member rotate together during power transmission.

  (5) Preferably, in the configuration of (4), the difference between the hole diameter and the outer peripheral diameter is 0 mm or more and 0.1 mm or less. The difference between the hole diameter of the mounting hole and the outer peripheral diameter of the cylindrical body portion is set to 0 mm or more. When the diameter is less than 0 mm, the outer peripheral diameter of the cylindrical body portion> the hole diameter of the mounting hole. It will occur.

  The difference between the hole diameter of the mounting hole and the outer peripheral diameter of the cylindrical body portion is set to 0.1 mm or less. If the diameter exceeds 0.1 mm, rattling of the cylindrical body portion in the hole of the mounting hole increases, and the operation feeling This is because there is a risk that it will worsen.

  Preferably, the hole diameter of the mounting hole is set to 100%, and the outer peripheral diameter of the cylindrical body portion is set to 99.3% or more and 100% or less. The reason why the outer peripheral diameter of the cylindrical body portion is set to 100% or less is that when the outer peripheral diameter exceeds 100%, the outer peripheral diameter of the cylindrical body portion> the hole diameter of the mounting hole, and the tightening margin of the cylindrical body portion with respect to the mounting hole occurs. is there.

  The reason why the outer peripheral diameter of the cylindrical part is 99.3% or more is that if it is less than 99.3%, the cylindrical part in the mounting hole becomes more loose and the operation feeling may be worsened. Because there is.

  (6) Preferably, the hole diameter of the attachment hole is less than the outer peripheral diameter of the cylindrical body portion, and the difference between the outer peripheral diameter and the hole diameter is preferably greater than 0 mm and 0.1 mm or less.

  FIG. 1 shows the relationship between the tightening allowance of the cylindrical body portion with respect to the mounting hole and the hole diameter contraction amount of the connecting hole. As shown in the figure, if the tightening margin (that is, the difference between the outer diameter and the hole diameter when the hole diameter of the mounting hole is equal to or smaller than the outer diameter of the cylindrical body) is 0.1 mm or less, the hole diameter shrinkage of the connecting hole is compared. Small. For this reason, the sliding resistance between the connecting hole inner peripheral surface and the mating member outer peripheral surface is also relatively small.

  In addition, the slope of the straight line is different between the case where the tightening margin is greater than 0 mm and 0.1 mm or less, and the case where it exceeds 0.1 mm. That is, when the tightening allowance of the cylindrical portion with respect to the mounting hole is more than 0 mm and 0.1 mm or less, the tightening allowance on the horizontal axis is x, and the shrinkage amount of the hole diameter on the vertical axis is y, (x, y) = (0, 0. 03), (0.05, 0.05), and (0.1, 0.07), an approximate expression (least square method) of y = 0.4x + 0.03 can be derived (straight line L in the figure). .

  On the other hand, when the tightening margin of the cylindrical body portion with respect to the mounting hole exceeds 0.1 mm, (x, y) = (0.1, 0.07), (0.15, 0.15), (0 .2, 0.25), (0.25, 0.31), and (0.3, 0.38), an approximate expression (least square method) of y = 1.56x−0.08 is derived. Yes (straight line L ′ in the figure).

  As described above, the slope of the straight line L ′ is at least twice (specifically, 3.9 times) the slope of the straight line L. Therefore, when the tightening allowance of the cylindrical body portion with respect to the attachment hole exceeds 0.1 mm, the response of the hole diameter contraction amount of the connecting hole to the change in the tightening allowance becomes sensitive. In other words, when there is variation in the setting of the tightening allowance among the plurality of cable terminal assemblies, the variation in sliding resistance between the inner peripheral surface of the connecting hole and the outer peripheral surface of the mating member becomes excessively large.

  On the other hand, when the tightening allowance of the cylindrical body portion with respect to the mounting hole is 0.1 mm or less, the response of the hole diameter contraction amount of the connecting hole to the change in the tightening allowance is slow. For this reason, even if there is variation in the setting of the tightening allowance, variation in sliding resistance between the inner peripheral surface of the coupling hole and the outer peripheral surface of the mating member is relatively small.

  As described above, the sliding resistance between the inner peripheral surface of the connecting hole and the outer peripheral surface of the mating member is relatively small, and the variation in the sliding resistance among the plurality of cable terminal assemblies is relatively small. Set the tightening margin to 0 mm and 0.1 mm or less.

(7) Moreover, in order to solve the said subject, the power transmission cable of this invention is a cable main body which can transmit power by operation | movement of at least one direction among a push direction and a pull direction, and said (1)-(6) a cable terminal assembly according to any one of out, a lever member for transmitting the operation of the cable terminal assembly as a power, is formed in the lever member integrally or separately, of the coupling hole of the collar member And a pin member arranged on the circumferential side, connecting the cable terminal assembly and the lever member, and rotating and slidingly contacting the connection hole.

  The power transmission cable of the present invention includes a cable body, a cable terminal assembly, a lever member, and a pin member. The cable terminal assembly includes a rod member and a collar member. As described in (1) above, the collar member includes a restricting portion. The restricting portion comes into contact with the rod body, not the attachment hole. For this reason, it is not necessary to regulate the axial displacement and the circumferential displacement of the collar member with respect to the mounting hole due to the friction between the outer peripheral surface of the cylindrical portion and the inner peripheral surface of the mounting hole. That is, unlike the prior art, it is not necessary to set a large allowance for the collar member with respect to the mounting hole. Therefore, when a thermal load is applied to the collar member, the hole diameter of the connecting hole of the collar member is not easily reduced. That is, even if a thermal load is applied, the sliding resistance between the inner peripheral surface of the connection hole and the outer peripheral surface of the pin member is unlikely to increase. For this reason, at the time of power transmission, there is little possibility that the connecting hole, that is, the collar member and the pin member will rotate together.

  In addition, the outer peripheral surface of the cylindrical portion of the collar member has a circumferential shape with substantially the same diameter. That is, the slit is not arrange | positioned at the cylinder part. For this reason, the sliding resistance between the connection hole inner peripheral surface and the pin member outer peripheral surface during power transmission is stable. Therefore, the operation feeling at the time of shift change is good. In addition, since the slit is not disposed in the cylindrical body portion, there is no possibility that foreign matter or the like is accumulated in the slit. For this reason, there is no possibility that the wear of the sliding portion is promoted by the foreign matter. Therefore, it is possible to suppress the deterioration of the operation feeling due to wear.

  The restricting portion of the collar member is suitable for restricting the circumferential displacement of the collar member with respect to the mounting hole (of course, only the circumferential displacement and the axial displacement, or only the axial displacement may be regulated). The restricting portion protrudes in the diameter increasing direction with respect to the cylindrical portion, and is in contact with the rod body. The rod main body contact portion in the restricting portion is located on the outer peripheral side with respect to the interface between the outer peripheral surface of the cylindrical portion and the inner peripheral surface of the attachment hole. For this reason, the circumferential displacement of the collar member with respect to the mounting hole can be regulated with a relatively small force.

(8) Moreover, in order to solve the said subject, the collar member of this invention has a rod main body connected with at least one end of the cable main body which can transmit power , and a ring part which is connected with one end of this rod main body and divides an attachment hole. A resin-made collar member interposed between a rod member and a mating member that is rotatably inserted into the mounting hole, and is disposed on an inner peripheral side of the mounting hole, and the mating member And a cylindrical body portion that has a circumferential outer surface having a substantially same diameter and a circumference, and an axial displacement and a circumferential displacement of the cylindrical portion relative to the mounting hole by contacting the rod body And a restricting portion for restricting at least one of the above.

  Here, the cylindrical part has “circumferential outer circumferential surface of substantially the same diameter” as well as the axial end portion of course when the entire axial direction of the cylindrical part has an outer circumferential surface of substantially the same diameter. In some cases, taper processing, chamfering processing, and the like are performed.

As described in the above (1), the collar member of the present invention is provided with a regulating portion. The restricting portion contacts the rod body of the rod member . For this reason, it is not necessary to regulate the axial displacement and the circumferential displacement of the collar member with respect to the mounting hole due to the friction between the outer peripheral surface of the cylindrical portion and the inner peripheral surface of the mounting hole. That is, unlike the prior art, it is not necessary to set a large allowance for the collar member with respect to the mounting hole. Therefore, when a thermal load is applied to the collar member, the hole diameter of the connecting hole of the collar member is not easily reduced. That is, even if a thermal load is applied, the sliding resistance between the inner peripheral surface of the connection hole and the outer peripheral surface of the counterpart member is unlikely to increase. For this reason, at the time of power transmission, there is little possibility that the collar member and the counterpart member rotate together.

In addition, the outer peripheral surface of the cylindrical portion of the collar member has a circumferential shape with substantially the same diameter. That is, the slit is not arrange | positioned at the cylinder part. For this reason, the sliding resistance between the connection hole inner peripheral surface and the counterpart member outer peripheral surface during power transmission is stable. Therefore, the operation feeling at the time of shift change is good. In addition, since the slit is not disposed in the cylindrical body portion, there is no possibility that foreign matter or the like is accumulated in the slit. For this reason, there is no possibility that the wear of the sliding portion is promoted by the foreign matter. Therefore, it is possible to suppress the deterioration of the operation feeling due to wear.

The restricting portion of the collar member is suitable for restricting the circumferential displacement of the collar member with respect to the mounting hole (of course, only the circumferential displacement and the axial displacement, or only the axial displacement may be regulated). The restricting portion protrudes in the diameter increasing direction with respect to the cylindrical portion, and is in contact with the rod body of the rod member . The rod main body contact portion in the restricting portion is located on the outer peripheral side with respect to the interface between the outer peripheral surface of the cylindrical portion and the inner peripheral surface of the attachment hole. For this reason, the circumferential displacement of the collar member with respect to the mounting hole can be regulated with a relatively small force.

  According to the present invention, it is possible to provide a power transmission cable, a cable terminal assembly, and a collar member that can regulate at least one of an axial displacement and a circumferential displacement of the collar member with respect to the mounting hole and that have good operation feeling. .

  Hereinafter, an embodiment in which the power transmission cable of the present invention is embodied as a vehicle transmission cable will be described. In addition, the following description serves as description about embodiment of the cable terminal assembly and collar member of this invention.

<First embodiment>
First, the configuration of the transmission cable of this embodiment will be described. FIG. 2 is a combined perspective view of the terminal portion in the shift lever direction of the transmission cable of the present embodiment. FIG. 3 shows a combined perspective view of the cable terminal assembly disposed at the terminal portion in the shift lever direction of the transmission cable. FIG. 4 shows an exploded perspective view of the terminal portion of the transmission cable in the shift lever direction.

  The transmission cable 1 is interposed between a shift lever (not shown) and the transmission. The operating force of the driver is transmitted to the transmission by the transmission cable 1. The transmission cable 1 includes an inner cable 90, an outer tube 91, a sleeve 92, a mounting flange 93, a cable terminal assembly 2, a lever member 3, and a pin member 4. The inner cable 90 is included in the cable body of the present invention.

  The attachment flange 93 is made of metal and has a cylindrical shape. The attachment flange 93 is fixed to a vehicle side member (not shown). An outer tube 91 to be described later is fixed to one end in the axial direction of the mounting flange 93. The sleeve 92 is made of metal and has a cylindrical shape. The sleeve 92 is inserted into the other axial end of the mounting flange 93 so as to be swingable. The mounting flange 93 and the sleeve 92 are disposed at both axial ends of the outer tube 91 (that is, the shift lever direction end and the transmission direction end).

  The outer tube 91 has a three-layer structure in which a liner, a shield, and an outer coat (not shown) are stacked from the inner peripheral side toward the outer peripheral side. The liner is made of resin and has a tube shape. The shield is made of a number of steel wires and is wound around the outer peripheral surface of the liner. The outer coat is made of resin and covers the outer peripheral surface of the liner.

  The inner cable 90 includes a core wire, a main side line, and a sub side line (not shown). The core wire is made of steel wire. The main side wire and the sub side wire are wound around the core wire. The inner cable 90 can slide in the outer tube 91 in the axial direction. Further, both ends of the inner cable 90 in the axial direction are inserted into the mounting flange 93 and the sleeve 92.

  The cable terminal assembly 2 includes a rod member 20 and a collar member 21. The cable terminal assembly 2 is disposed at both axial ends of the inner cable 90. The rod member 20 is made of carbon steel wire for cold heading (SWCH), and includes a rod body 200 and a ring portion 201. The rod body 200 has a round bar shape. One end of the rod body 200 in the axial direction is caulked and fixed to one end of the inner cable 90 in the axial direction. The ring part 201 is disposed at the other axial end of the rod body 200. A mounting hole 201a is formed in the ring portion 201.

  The color member 21 is made of glass fiber-containing polyamide (PA), and includes a color main body portion 210 and a partial arc-shaped outer fitting restriction portion 211. The color main body 210 includes a flange portion 210a, a cylindrical body portion 210b, and a connection hole 210c. The cylinder part 210b has a short-axis cylindrical shape. The cylindrical portion 210b is inserted into the mounting hole 201a of the rod member 20. The outer peripheral surface of the cylindrical part 210b has the same-diameter circumferential shape. A taper process is applied to one end of the cylindrical portion 210b in the axial direction in order to improve the insertability into the mounting hole 201a. The flange portion 210a has a disk shape and is disposed at the other axial end of the cylindrical portion 210b. The connecting hole 210c passes through the flange portion 210a axis and the cylindrical portion 210b axis in the axial direction.

  The partial arc-shaped outer fitting restricting portion 211 includes a connecting portion 211a and a main body portion 211b. The main body 211b has a partial arc shape, that is, a c-shape. An opening 211c is defined between the c-shaped ends of the main body 211b. The main body 211b is externally fitted to the rod main body 200 of the rod member. The connecting portion 211 a connects the main body portion 211 b and the flange portion 210 a of the collar main body portion 210.

  The lever member 3 is made of metal and has a thin plate shape. At one end of the lever member 3 in the longitudinal direction, a rectangular tube-shaped connecting boss 30 is disposed. The operating force of the driver is transmitted to the connecting boss 30 via the shift lever. Power transmission tabs 31 a and 31 b are disposed at the other longitudinal end of the lever member 3. A power transmission hole 310a is formed in the power transmission tab 31a. A power transmission hole 310b is formed in the power transmission tab 31b. The two power transmission tabs 31a and 31b are arranged in a positional relationship such that the power transmission holes 310a and 310b are arranged coaxially and in series. The two power transmission tabs 31 a and 31 b are connected by a tab connecting portion 32. The cable terminal assembly 2 is interposed between the two power transmission tabs 31a and 31b. The power transmission hole 310a, the connection hole 210c of the cable terminal assembly 2, and the power transmission hole 310b are arranged coaxially and in series.

  The pin member 4 is made of metal and includes a head portion 40 and a shaft portion 41. The pin member 4 passes through the power transmission hole 310a, the connection hole 210c of the cable terminal assembly 2, and the power transmission hole 310b. The shaft portion 41 has a round bar shape. A pin hole 410 is formed in the outer peripheral surface on one end side of the shaft portion 41. The pin hole 410 is disposed outside the power transmission tab 31a. The pin hole 410 penetrates the outer peripheral surface of the shaft portion 41 in a diameter shape. A metal beta pin 410 a is fixed to the pin hole 410. The head 40 has a disk shape. The head 40 is disposed at the other end of the shaft portion 41. The head 40 is disposed outside the power transmission tab 31b. The head 40 and the beta pin 410a prevent the pin member 4 from dropping from the power transmission hole 310a, the coupling hole 210c, and the power transmission hole 310b.

  Next, a method for assembling the transmission cable according to the present embodiment will be described. First, the outer tube 91, the attachment flange 93, and the inner cable 90 after passing through the sleeve 92 are fixed to the rod body 200 of the rod member 20 (see FIG. 2 above).

  Secondly, the cable terminal assembly 2 is assembled. FIG. 5 shows a VV cross-sectional view of FIG. FIG. 6 is a cross-sectional view taken along the line VI-VI in FIG. As shown in FIG. 5, the cylindrical body part 210 b of the collar main body part 210 is inserted into the attachment hole 201 a of the ring part 201. Here, the outer peripheral diameter D1 of the cylindrical portion 210b is equal to the hole diameter D2 of the attachment hole 201a. For this reason, the fastening allowance of the cylinder part 210b with respect to the attachment hole 201a is zero.

  As shown in FIG. 6, the partial arc-shaped external fitting restricting portion 211 is externally fitted to the rod body 200. Here, a straight line L2 connecting the arc center C1 of the partial arc-shaped outer fitting restricting portion 211 and the opening center C2 of the opening 211c is parallel to the axis L1 of the cylindrical portion 210b in FIG. FIG. 7 is a cross-sectional view showing a state in which the partial arc-shaped outer fitting restricting portion of the cable terminal assembly of the transmission cable according to this embodiment is in contact with the rod body. As shown in the drawing, when the opening 211c abuts on the outer peripheral surface of the rod main body 200, the opening 211c elastically expands along the shape of the outer peripheral surface of the rod main body 200, as indicated by a white arrow in the figure. Subsequently, when the opening 211c gets over the rod body 200 diameter D4, the opening 211c elastically shrinks and returns along the shape of the outer peripheral surface of the rod body 200. By the series of movements described above, the rod main body 200 is housed in the main body 211b as if swallowed.

  FIG. 8 is a cross-sectional view of the transmission cable according to the present embodiment after assembling in the vicinity of the collar main body of the cable terminal assembly. As shown in the drawing, the outer peripheral surface of the cylindrical portion 210b and the inner peripheral surface of the attachment hole 201a are in contact with each other. The flange portion 210a is in contact with the hole edge of the attachment hole 201a.

  FIG. 9 shows a cross-sectional view of the transmission cable according to this embodiment after the assembly in the vicinity of the partial arc-shaped outer fitting restricting portion of the cable terminal assembly. As shown in the drawing, the outer peripheral surface of the rod main body 200 and the inner peripheral surface of the main body portion 211b are in contact with each other. Here, as shown in FIG. 6, the inner peripheral diameter D5 of the main body 211b before assembly is smaller than the diameter D4 of the rod main body 200. For this reason, even after the assembly, the elastic return force of the main body portion 211b remains. Due to the elastic return force, the rod body 200 receives a regulating force in the direction of diameter reduction from the body portion 211b on the entire circumference. Further, the opening width D3 of the opening 211c after assembly is smaller than the rod body 200 diameter D4. For this reason, the rod body 200 does not fall off from the opening 211c.

  Thirdly, as shown in FIG. 4, the assembled cable terminal assembly 2, the lever member 3, and the pin member 4 are assembled. First, the cable terminal assembly 2 is interposed between the power transmission tab 31 a and the power transmission tab 31 b of the lever member 3. Subsequently, the power transmission hole 310a of the power transmission tab 31a, the connection hole 210c of the cable terminal assembly 2, and the power transmission hole 310b of the power transmission tab 31b are arranged in series. Thereafter, the pin member 4 is inserted into the power transmission hole 310a, the coupling hole 210c, and the power transmission hole 310b from the power transmission hole 310b side. Then, the beta pin 410a shown in FIG. 2 is attached to the pin hole 410 protruding to the power transmission tab 31a side. In this way, the transmission cable 1 of the present embodiment is assembled.

  Next, the movement of the transmission cable of this embodiment will be briefly described. In FIG. 10, the schematic diagram of the terminal part of the shift lever direction of the transmission cable of this embodiment is shown. When the driver switches the shift lever in the room, the lever member 3 swings clockwise or counterclockwise as shown by the dotted line in FIG. For this reason, the cable terminal assembly 2 moves leftward or rightward in the drawing. At this time, the outer peripheral surface of the pin member 4 and the inner peripheral surface of the connection hole 210c slide relatively. The rod body 200 is gripped by the partial arc-shaped outer fitting restricting portion 211. For this reason, the collar member 21 does not move relative to the rod member 20. That is, the collar member 21 is not displaced relative to the rod member 20 in the axial direction or the radial direction.

  The cable terminal assembly 2 is connected to an inner cable (not shown). For this reason, the inner cable slides in the outer tube. As described above, the cable terminal assembly 2, the lever member 3, and the pin member 4 are also disposed on the transmission side of the inner cable. Accordingly, the cable end assembly 2 on the transmission side follows the movement of the inner cable. The movement of the cable terminal assembly 2 causes the transmission-side lever member 3 to swing. For this reason, the transmission is switched to a predetermined shift position.

  Next, the effect of the transmission cable of this embodiment is demonstrated. The collar member 21 of the cable terminal assembly 2 of the transmission cable 1 according to the present embodiment includes a partial arc-shaped outer fitting restricting portion 211. The partial arc-shaped outer fitting restricting portion 211 is fitted on the rod main body 200. For this reason, the axial displacement and circumferential displacement of the collar member 21 with respect to the mounting hole 201a can be strongly restricted. Therefore, there is no possibility that the rod member 20 and the collar member 21 are separated not only when the power is transmitted but also when the cable terminal assembly 2 is transported until the vehicle is assembled.

  Further, as shown in FIGS. 5 and 6, the straight line L2 connecting the arc center C1 and the opening center C2 of the partial arc-shaped outer fitting restricting portion 211 and the axis L1 of the cylindrical portion 210b are set in parallel. Has been. For this reason, the partial arc-shaped external fitting restricting portion 211 can be externally fitted to the rod body 200 at the same time when the cylindrical body portion 210b is inserted into the attachment hole 201a. That is, the collar member 21 and the rod member 20 can be assembled in one motion. Thus, the cable terminal assembly 2 of the transmission cable 1 of this embodiment is excellent in assembling workability.

  Moreover, the outer peripheral surface of the cylindrical part 210b is exhibiting the same-diameter circumference shape. That is, the slit is not arrange | positioned at the cylinder part 210b. For this reason, the sliding resistance between the inner peripheral surface of the connection hole 210c of the collar main body 210 and the outer peripheral surface of the pin member 4 during power transmission is stable. Therefore, the operation feeling at the time of shift change is good. In addition, since no slit is arranged in the cylindrical body part 210b, there is no possibility that foreign matter or the like is accumulated in the slit. For this reason, there is no possibility that the wear of the sliding portion is promoted by the foreign matter. Therefore, it is possible to suppress the deterioration of the operation feeling due to wear.

  Further, the partial arc-shaped outer fitting restricting portion 211 protrudes in the diameter increasing direction with respect to the cylindrical portion 210 b and is in contact with the rod main body 200. The contact portion of the rod main body 200 in the partial arc-shaped outer fitting restricting portion 211 is located on the outer peripheral side with respect to the interface between the outer peripheral surface of the cylindrical portion 210b and the inner peripheral surface of the attachment hole 201a. For this reason, the circumferential displacement of the collar member 21 with respect to the mounting hole 201a can be regulated with a relatively small force.

  Further, as shown in FIG. 5, the outer diameter D1 of the cylindrical portion 210b and the hole diameter D2 of the attachment hole 201a are set equal. For this reason, the fastening allowance of the cylinder part 210b with respect to the attachment hole 201a does not generate | occur | produce. Therefore, even when a thermal load is applied to the cylindrical body part 210b, there is no possibility that the hole diameter of the connecting hole 210c becomes small. That is, there is no possibility that the sliding resistance between the inner peripheral surface of the connecting hole 210c and the outer peripheral surface of the pin member 4 will increase. That is, there is no possibility that the connecting hole 210c, that is, the cylindrical body part 210b and the pin member 4 rotate together during power transmission.

  The color member 21 is made of glass fiber-containing polyamide (PA). For this reason, the collar member 21 is not easily deformed by thermal creep and thermal contraction. Also in this respect, there is no possibility that the sliding resistance between the inner peripheral surface of the coupling hole 210c and the outer peripheral surface of the pin member 4 is increased.

<Second embodiment>
The difference between the present embodiment and the first embodiment is that the rod member of the cable terminal assembly has a two-part configuration. In addition, a ring restricting portion is arranged instead of the partial arc-shaped outer fit restricting portion. Therefore, only the differences will be described here.

  FIG. 11 is an exploded perspective view of the cable terminal assembly of the transmission cable according to the present embodiment. In addition, about the site | part corresponding to FIG. 4, it shows with the same code | symbol. As shown in the figure, the rod body 200 and the ring portion 201 of the rod member 20 are formed separately. A main body side screw portion 200 b is formed at the tip of the rod main body 200. On the other hand, a rod body screwing hole 201b penetrating the inner and outer peripheral surfaces is formed in the ring portion 201. A ring-side screw portion 201c is formed on the inner peripheral surface of the rod main body screw hole 201b.

  A ring restricting portion 212 is disposed on the collar member 21. The ring restricting portion 212 has a short-axis cylindrical shape. That is, the rod restricting portion 212 is formed with a rod through hole 212a. The hole diameter of the rod through hole 212a and the outer diameter of the rod main body 200 are set equal.

  When the cable terminal assembly 2 is assembled, the collar member 21 is first attached to the ring portion 201. Specifically, the cylindrical part 210b is inserted into the attachment hole 201a. At this time, as shown by a dotted line in the figure, the rod main body screwing hole 201b and the rod through hole 212a of the ring restricting portion 212 are arranged in series. Next, the rod body 200 is inserted into the rod through hole 212a. And the rod main body 200 and the ring part 201 are assembled | attached by screwing the main body side screw part 200b to the ring side screw part 201c. In this way, the cable terminal assembly 2 of the transmission cable of the present embodiment is assembled.

  The transmission cable of the present embodiment has the same effects as the transmission cable of the first embodiment. Further, according to the transmission cable of the present embodiment, the rod body 200 is surrounded by the ring restricting portion 212 on the entire circumference. For this reason, at the time of power transmission, there is no possibility that the rod body 200 falls off the ring restricting portion 212. Therefore, there is no possibility that the collar member 21 and the rod member 20 are separated.

<Third embodiment>
The difference between this embodiment and 1st embodiment is a point by which the outer cylindrical external fitting control part is arrange | positioned instead of the partial circular arc external fitting control part. Therefore, only the differences will be described here.

  FIG. 12 is an exploded perspective view of the cable terminal assembly of the transmission cable according to the present embodiment. In addition, about the site | part corresponding to FIG. 4, it shows with the same code | symbol. As shown in the figure, the collar member 21 is provided with an outer tubular outer fitting restricting portion 213. The outer tubular outer fitting restricting portion 213 is disposed coaxially and on the outer peripheral side with respect to the tubular portion 210b. A C-shaped recess 213a is formed in the outer tubular outer fitting restricting portion 213. When the cable terminal assembly 2 is assembled, the C-shaped concave portion 213a is fitted onto the rod body 200 at the same time as the cylindrical portion 210b is inserted into the mounting hole 201a. The transmission cable of the present embodiment has the same effects as the transmission cable of the first embodiment.

<Fourth embodiment>
The difference between this embodiment and 1st embodiment is a point by which the circumferential direction displacement control part is arrange | positioned instead of the partial arc-shaped external fitting control part. Therefore, only the differences will be described here.

  FIG. 13 is an exploded perspective view of the cable terminal assembly of the transmission cable according to the present embodiment. In addition, about the site | part corresponding to FIG. 4, it shows with the same code | symbol. As shown in the figure, a circumferential direction displacement restricting portion 214 is disposed on the collar member 21. The circumferential displacement restricting portion 214 is formed with a U-shaped recess 214a. When the cable terminal assembly 2 is assembled, the rod main body 200 is relatively accommodated in the U-shaped recess 214a at the same time as the cylindrical portion 210b is inserted into the attachment hole 201a. According to the transmission cable of this embodiment, the circumferential displacement of the collar member 21 relative to the rod member 20 can be restricted. Further, the opening width of the U-shaped recess 214a and the diameter of the rod body 200 are set equal. For this reason, it is not necessary to press-fit the rod body 200 into the U-shaped recess 214a at the time of assembly. Therefore, the cable terminal assembly 2 of the transmission cable of this embodiment is excellent in assembling workability.

<Fifth embodiment>
The difference between the present embodiment and the first embodiment is that the pin member is fixed to the lever member. Therefore, only the differences will be described here.

  In FIG. 14, the disassembled perspective view of the terminal part of the shift lever direction of the transmission cable of this embodiment is shown. In addition, about the site | part corresponding to FIG. 4, it shows with the same code | symbol. As shown in the figure, the pin member 4 is fixed to the lever member 3. That is, the pin member 4 protrudes from the power transmission tab 31 b of the lever member 3. The transmission cable 1 of the present embodiment has the same effects as the transmission cable of the first embodiment. Moreover, according to the transmission cable 1 of this embodiment, the man-hour of an assembly work can be reduced.

<Others>
The embodiments of the power transmission cable, the cable terminal assembly, and the collar member of the present invention have been described above. However, the embodiment is not particularly limited to the above embodiment. Various modifications and improvements that can be made by those skilled in the art are also possible.

  For example, in the above embodiment, the outer peripheral diameter D1 of the cylindrical portion 210b and the hole diameter D2 of the attachment hole 201a are set equal (see FIG. 5 above). However, the relative relationship between the outer peripheral diameter D1 and the hole diameter D2 is not particularly limited. For example, the hole diameter D2 may be set to be less than the outer diameter D1. In this case, the difference between the outer peripheral diameter D1 and the hole diameter D2 may be set to be greater than 0 mm and not greater than 0.1 mm.

  When the cylindrical portion 210b is thermally contracted, the outer peripheral diameter D1 and the inner peripheral diameter (that is, the hole diameter of the connecting hole 210c) of the cylindrical portion 210b are reduced. For this reason, there exists a possibility that a clearance gap may generate | occur | produce between the attachment hole 201a inner peripheral surface and the cylinder part 210b outer peripheral surface. It is preferable that the gap amount be within 1/10 of the allowable backlash amount (± 0.8 mm) in the layout around the lever member 3. That is, the gap amount is preferably within ± 0.08 mm.

  In this regard, as shown in FIG. 1, when the difference between the outer peripheral diameter D1 and the hole diameter D2 (that is, the tightening allowance of the cylindrical portion 210b with respect to the mounting hole 201a) is set to be more than 0 mm and 0.1 mm or less, the connecting hole 210c The amount of shrinkage of the hole diameter exceeds 0.03 mm and is 0.07 mm or less. For this reason, the outer peripheral diameter D1 of the cylindrical portion 210b shown in FIG. 5 is also contracted by more than 0.03 mm and not more than 0.07 mm.

  Thus, when the difference between the outer peripheral diameter D1 and the hole diameter D2 is set to more than 0 mm and 0.1 mm or less, the gap amount between the inner peripheral surface of the mounting hole 201a and the outer peripheral surface of the cylindrical portion 210b is set within a preferable range (± Within 0.08 mm).

  Further, for example, in the above-described embodiment, the rod member 20 is formed of a carbon steel wire for cold heading (SWCH), but may be formed of a carbon steel material for machine structure (S10C material) or the like. The color member 21 is formed of polyamide (PA) containing glass fiber, but is formed of polyoxymethylene (POM, also known as polyacetal), polybutylene terephthalate (PBT), polyethylene (PE), polyethylene terephthalate (PET), or the like. Also good.

  Moreover, in the said embodiment, the power transmission cable of this invention was embodied as the transmission cable 1. FIG. However, the power transmission cable of the present invention may be embodied as a control cable for opening and closing a vehicle door, for example, a control cable for operating a special vehicle such as a crane truck or a shovel car. Moreover, you may implement as a control cable which adjusts the angle of the wind direction adjustment fin of the air conditioning register | resistor of a vehicle.

It is a graph which shows the relationship between the interference of the cylinder part with respect to an attachment hole, and the hole diameter shrinkage | contraction amount of a connection hole. It is a united perspective view of the terminal portion in the shift lever direction of the transmission cable of the first embodiment. It is a united perspective view of the cable terminal assembly arrange | positioned at the terminal part of the shift lever direction of the transmission cable. It is a disassembled perspective view of the terminal part of a shift lever direction of the transmission cable. It is VV sectional drawing of FIG. It is VI-VI sectional drawing of FIG. It is sectional drawing of the state in which the partial arc-shaped external fitting control part of the cable terminal assembly of the transmission cable contact | abutted to the rod main body. It is sectional drawing after the assembly | attachment of the color body part vicinity of the cable terminal assembly of the transmission cable. It is sectional drawing after the assembly | attachment of the cable terminal assembly of the transmission cable near the partial arc-shaped external fitting control part vicinity. It is a schematic diagram of the terminal part of the transmission cable in the shift lever direction. It is a disassembled perspective view of the cable terminal assembly of the transmission cable of 2nd embodiment. It is a disassembled perspective view of the cable terminal assembly of the transmission cable of 3rd embodiment. It is a disassembled perspective view of the cable terminal assembly of the transmission cable of 4th embodiment. It is a disassembled perspective view of the terminal part of the shift cable direction of the transmission cable of 5th embodiment. The united perspective view of the terminal part of the shift lever direction of the conventional transmission cable is shown. It is a disassembled perspective view of the cable terminal assembly arrange | positioned at the terminal part of the shift lever direction of the transmission cable. It is a disassembled perspective view of the cable terminal assembly which provided the engaging claw in the insertion direction end of the conventional collar member. It is a united perspective view of the cable terminal assembly.

Explanation of symbols

  1: Transmission cable (power transmission cable), 2: Cable terminal assembly, 20: Rod member, 200: Rod main body, 200b: Main body side screw portion, 201: Ring portion, 201a: Mounting hole, 201b: Rod main body screwing hole , 201c: ring side thread portion, 21: collar member, 210: collar main body portion, 210a: flange portion, 210b: cylindrical body portion, 210c: connecting hole, 211: partial arc-shaped outer fitting restricting portion, 211a: connecting portion, 211b: body portion, 211c: opening, 212: ring restricting portion, 212a: rod through hole, 213: outer cylindrical outer fitting restricting portion, 213a: C-shaped recess, 214: circumferential displacement restricting portion, 214a: U-shaped recess 3: lever member, 30: connecting boss, 31a: power transmission tab, 31b: power transmission tab, 310a: power transmission hole, 310b: motion Transmission hole, 32: Tab connecting part, 4: Pin member, 40: Head, 41: Shaft part, 410: Pin hole, 410a: Beta pin, 90: Inner cable (cable body), 91: Outer tube, 92: Sleeve , 93: mounting flange.

Claims (8)

A rod member having a rod main body connected to at least one end of a cable main body capable of transmitting power , and a ring portion connecting to one end of the rod main body and defining an attachment hole;
A cylindrical body portion that is disposed on the inner peripheral side of the mounting hole and defines a connecting hole where the mating member rotates and slidably contacts, and has an outer peripheral surface having a substantially same diameter and a circumferential shape, and the mounting by contacting the rod body A resin-made color member having a restricting portion that restricts at least one of the axial displacement and the circumferential displacement of the cylindrical portion with respect to the hole;
A cable terminal assembly comprising:   The cable terminal assembly according to claim 1, wherein the restriction portion is an external fitting restriction portion that is fitted onto the rod body. The outer fitting restricting portion is a partial arc-shaped outer fitting restricting portion having an opening in a part in the circumferential direction,
A straight line connecting the arc center and the opening center of the partial circular arc shape-fitting restriction portion at any distance from the axis of the cylindrical body portion, the axis of said cylindrical body portion, is substantially parallel,
When the cylindrical body portion is inserted into the mounting hole, the opening is elastically expanded along the rod main body and is retracted backward, so that the partial arc-shaped outer fitting restricting portion is fitted on the rod main body. The cable terminal assembly according to claim 2. The cable terminal assembly according to any one of claims 1 to 3 , wherein a diameter of the attachment hole is equal to or greater than an outer peripheral diameter of the cylindrical body portion.   The cable terminal assembly according to claim 4, wherein a difference between the hole diameter and the outer peripheral diameter is 0 mm or more and 0.1 mm or less. The hole diameter of the mounting hole is less than the outer diameter of the cylindrical body part,
The cable terminal assembly according to any one of claims 1 to 3 , wherein a difference between the outer peripheral diameter and the hole diameter is more than 0 mm and 0.1 mm or less. A cable body capable of transmitting power by operation in at least one of the push direction and the pull direction;
A cable terminal assembly according to any one of claims 1 to 6 ;
A lever member for transmitting the operation of the cable terminal assembly as power;
A pin member formed integrally with or separately from the lever member, disposed on the inner peripheral side of the connecting hole of the collar member, connecting the cable end assembly and the lever member, and rotating and slidingly contacting the connecting hole; ,
A power transmission cable comprising: A rod member having a rod main body connected to at least one end of the cable main body capable of transmitting power, a ring portion connecting to one end of the rod main body and defining an attachment hole, and a mating member rotatably inserted into the attachment hole; A resin-made color member interposed between
A cylindrical body portion that is disposed on the inner peripheral side of the mounting hole and defines a connecting hole with which the mating member rotates and slidably contacts and has an outer circumferential surface having a substantially same diameter and a circumferential shape, and by contacting the rod body, A collar member comprising: a restricting portion that restricts at least one of an axial displacement and a circumferential displacement of the cylindrical portion with respect to the mounting hole.

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