JP2005066721A - Boot band fastening tool - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a boot band fastening tool 1 capable of fastening even a boot band different in wound ring diameter. <P>SOLUTION: This boot band fastening tool is provided with a pair of openable/closable clamping claws 13, 14 engaged respectively with a pair of tool claws of the boot band wound in ring shape around a fastened member; a power mechanism 15 provided at a body 12 for holding the pair of clamping claws 13, 14, and driving the clamping claws 13, 14 to close in a boot band fastening direction by the input of power; and a spring member 16 energizing the pair of clamping claws 13, 14 in the closing direction. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to a boot band tightening tool used for tightening a boot band wound around a member to be tightened.

  The boot band is used, for example, to tighten a boot that covers a power transmission portion of an automobile and prevent internal grease or the like from flowing out of the boot, or preventing water or foreign matter from entering the boot. The boot band is ring-shaped and wound around the boot into which the mating member such as a tubular body is inserted, and is tightened in this wound state, thereby pressing the boot against the mating member from the outer peripheral side. This acts to prevent the leakage and intrusion described above.

  The boot band tightening tool is used to tighten such a boot band. When using a manual structure that tightens by hand as the boot band tightening tool, not only is the workability poor, but it is difficult to apply a uniform tightening force. It is used a lot.

  FIGS. 12 and 13 show a conventional boot band tightening tool 1 having a power structure for tightening the boot bands 6 and 7 when power is input, and includes a pair of clamp claws 2 and 3. The pair of clamp claws 2 and 3 are pivoted about the hinge shaft 4 by being connected by the hinge shaft 4, and are opened and closed by this rotation. The clamp claws 2 and 3 are held by a main body (not shown), and when power, fluid pressure, etc. are input to the main body, power is transmitted from the main body and the clamp claws 2 are driven to close.

  The boot bands 6 and 7 to be tightened are tightened by the boot band tightening tool 1 in a state where the boot bands 6 and 7 are wound around the outer periphery of a member to be tightened (not shown). In order to perform this tightening, a pair of tool claws 8a and 8b are formed on the boot bands 6 and 7 so as to protrude outward. Then, the tips of the clamp claws 2 and 3 of the boot band tightening tool 1 are engaged with the respective tool claws 8a and 8b from the outside, and power is input to the tightening tool 1 in this engaged state so that the clamp claws 2 and 3 are engaged. The boot bands 6 and 7 are tightened by driving 3 closed. Tightening is performed until the pair of tool claws 8a and 8b move to a position where they are engaged with each other, and the engagement claws 9 formed on the boot bands 6 and 7 by this movement cause the corresponding engagement of the boot bands. Engage with the joint hole and enter the final tightening state. That is, the linear movement distance until the pair of tool claws 8a and 8b are engaged with each other is the tightening amount (tightening length).

  The amount of tightening is such that the ring-shaped diameter of the boot bands 6 and 7 is set according to the diameter of the member to be tightened, and varies depending on the diameter wound in the ring shape (hereinafter referred to as ring diameter). . That is, since the boot band 6 having a small diameter has a smaller ring diameter than the boot band 7 having a large diameter, the tightening amount (the linear movement distance of the pair of tool claws 8a and 8b) is also set small. Therefore, the linear distance between the tool claws 8a and 8b of the boot band 6 having a small ring diameter, that is, the pitch L1, and the linear distance between the tool claws 8a and 8b in the boot band 7 having a large ring diameter, that is, the pitch L2. Will inevitably be different. In the conventional boot band tightening tool 1, the distance between the pair of clamp claws 2 and 3 is set to match the pitch of the tool claws 8a and 8b.

  As described above, in the conventional boot band tightening tool 1, the interval between the clamp claws 2 and 3 for tightening is the pitch of the tool claws 8a and 8b of the boot bands 6 and 7 (that is, the ring diameter of the boot bands 6 and 7). When a boot band having a different pitch between the tool claws 8a and 8b is tightened, a boot having a clamp claw interval that matches the pitch of the tool claws 8a and 8b. It is necessary to use the band fastening tool 1. For this reason, every time the pitches of the tool claws 8a and 8b are different, the boot band tightening tool 1 suitable for the pitch must be replaced, and the tightening work is complicated and the workability is lowered. Yes.

  In addition, when the distance between the clamp claws 2 and 3 does not match the pitch of the tool claws 8a and 8b, reliable tightening cannot be performed. For example, when the boot band 6 having a small pitch between the tool claws 8a and 8b is tightened by using the boot band tightening tool 1 matched with the tool claws 8a and 8b having a large pitch, the tool claws of one of the clamp claws 2 and 3 are used. Engagement with 8a and 8b is incomplete. As a result, the clamping claws 2 and 3 slip off from the tool claws 8a and 8b during tightening and cannot be tightened.

  The present invention has been made in consideration of such conventional problems, and even if the pitch of the tool claw in the boot band (that is, the linear distance according to the ring diameter of the boot band) is different, the boot band An object of the present invention is to improve the workability of tightening the boot band by providing a versatile boot band tightening tool capable of securely tightening the boot band.

  In order to achieve the above object, the boot band tightening tool according to the first aspect of the present invention is openable and closable which engages with each of the pair of tool claws of the boot band wound around the tightened member in a ring shape. A pair of clamp claws, a power mechanism that is provided on the body that holds the pair of clamp claws and that drives the clamp claws to close in the tightening direction of the boot band when power is input, and a pair of clamp claws in the closing direction And a spring member for biasing.

  In the boot band tightening tool according to the first aspect of the present invention, when one clamp claw is engaged with one tool claw and the other clamp claw is opened and brought into contact with the other tool claw, the other clamp Since the claw is urged in the closing direction by the urging force of the spring member, the other clamp claw can be reliably engaged with the other tool claw. In this state, the boot band can be securely tightened by inputting power to the power mechanism and driving the clamp claws to close.

  In such an invention of claim 1, even if the pitches of the tool claws are different, the clamp claws can be adjusted in accordance with the pitches. Therefore, the boot bands having different pitches of the tool claws, that is, the ring diameters are different. It can be used as it is for a boot band, and can be versatile without the need to change the boot band tightening tool. Further, since the clamp pawl can be reliably engaged with the tool pawl, the clamp pawl is not detached, and the reliability of the tightening operation can be improved.

  A second aspect of the present invention is the boot band tightening tool according to the first aspect, wherein the spring member is a leaf spring spanned between at least one of the clamp claws and the main body.

  Since the leaf spring is used as the spring member as in the invention of claim 2, the attachment thereof is easy, so that the spring member can be easily replaced or maintained. Moreover, since it does not become bulky, the boot band fastening tool does not increase in size.

  According to the boot band tightening tool of the present invention, since the clamp claws can be adjusted in accordance with the pitch of the tool claws, the boot bands can be securely tightened and the boot bands having different ring diameters can be used. Since it can be used as it is, it is not necessary to replace the boot band tightening tool, and the tightening workability is improved.

  1 to 3 show a boot band tightening tool 11 according to an embodiment of the present invention. The boot band tightening tool 11 of this embodiment includes a main body 12, a pair of clamp claws 13, 14, a power mechanism 15 that drives the clamp claws 13, 14 to close, and a leaf spring 16 as a spring member. ing.

  As shown in FIG. 3, the main body 12 is formed in a cylindrical shape having a predetermined length in which the power mechanism 15 is disposed. The receiving arm portions 17 and 18 of the pair of clamp claws 13 and 14 are inserted into one end side (the left end side in FIG. 3) of the main body 12. Moreover, the other end side (right end side in FIG. 3) of the main body 12 is opened, and the power mechanism 15 is inserted from the other end side.

  As shown in FIGS. 1 and 2, the pair of clamp claws 13 and 14 are held by the main body 12 in a state of being assembled so as to have an X shape. The clamp claws 13 and 14 are formed by receiving arm portions 17 and 18 and clamp portions 19 and 20 that are detachably connected to the distal ends of the receiving arm portions 17 and 18, respectively. 19 and 20 are extracted from one end side of the main body 12 to the outside. The clamp portions 19 and 20 are detachably connected to the receiving arm portions 17 and 18 via the connection plate portions 21 and 22. This connection is performed by tightening a plurality of screws 23.

  The pair of clamp claws 13 and 14 are assembled to the receiving arm portions 17 and 18 by penetrating the hinge shaft 24, and the pair of clamp claws 13 and 14 are opened and closed by rotating about the hinge shaft 24. It is possible. The pair of clamp claws 13 and 14 are held by the main body 12 via the hinge shaft 24.

  In this embodiment, the power mechanism 15 has a structure that operates by pressurized air. The power mechanism 15 includes a piston 26 inserted into the main body 12 along the axial direction, and a wedge block 27 connected to the tip (left end) of the piston 26.

  The inner surface of the wedge block 27 is a wedge surface 27a in which the distance from the pair of clamp claws 13 and 14 gradually decreases, and the receiving arm portions 17 and 18 of the pair of clamp claws 13 and 14 are inserted into the wedge surface 27a. Yes. Therefore, when the wedge block 27 advances in the direction of the clamp claws 13 and 14, the receiving arm portions 17 and 18 are rotated so as to be closed. By this rotation, the pair of clamp claws 13 and 14 (clamp portions 19 and 20) can be closed and closed.

  The advancement of the wedge block 27 is performed by the advancement of the piston 26 by air pressure. In order to supply pressure air for this purpose to the main body 12, an air pressure source (not shown) is provided on the other end side of the main body 12. A connecting pipe 28 to be connected is attached. A seal ring 29 made of an O-ring or the like is fitted on the outer periphery of the piston 26 to prevent air from leaking between the piston 26 and the main body 12. Further, return springs 31 and 32 for urging the piston 26 and the wedge block 27 in a direction away from the pair of clamp claws 13 and 14 are arranged inside the main body 12.

  FIG. 1 shows a state in which the power mechanism 15 is not driven, and the pair of clamp claws 13 and 14 are held by the main body 12 so that the clamp portions 19 and 20 are separated at a constant interval. In this state, by supplying pressurized air from the air pressure source through the connection pipe 28, the piston 26 and the wedge block 27 advance in the direction of the pair of clamp claws 13 and 14 so that the receiving arm portions 17 and 18 are closed. Act on. As a result, the pair of clamp claws 13 and 14 rotate around the hinge shaft 24 and are driven to close. By this closing drive, the boot band is tightened as will be described later.

  The leaf spring 16 as a spring member biases the pair of clamp claws 13 and 14 in the closing direction. In this embodiment, the leaf spring 16 is stretched between one clamp claw 13 and the main body 12. That is, the leaf spring 16 is fixed to the connecting plate portion 21 on the clamp claw 13 side by a fixing screw 35 at the front end side, and the other end side extends in the direction of the main body 12 in this fixed state. Is pressed.

  By disposing the leaf spring 16 in this way, one clamp claw 13 is biased to rotate in the direction of the other clamp claw 14, so that the pair of clamp claws 13, 14 are attached in the closing direction. It is possible to support. Further, by applying a force larger than the urging force of the leaf spring 16, the pair of clamp claws 13 and 14 can be opened.

  Engaging recesses 37 and 38 that engage with the tool claws of the boot band are formed on the opposing surfaces of the clamp portions 19 and 20 on the tip side of the pair of clamp claws 13 and 14.

  Next, an example of the boot band 70 tightened by the above boot band tightening tool 11 will be described with reference to FIGS.

  The boot band 70 includes a band main body 71 formed in a band shape by press punching and bending a metal thin plate, and a member to be tightened (not shown) in a state where the band main body 71 is wound in a ring shape. Tightening is carried out by placing it on the outer peripheral side of the. As shown in FIGS. 7 and 8, the band main body 71 wound in a ring shape is formed with an outer overlapping portion 72 and an inner overlapping portion 73 that overlap each other, and the boot band tightening tool 11 of this embodiment can be used. By using these overlapping portions 72 and 73 in the reduced diameter direction, the member to be tightened is tightened. FIG. 7 shows a temporarily fixed state before tightening.

  As shown in FIGS. 5 and 6, the band main body 71 has two engagement claws 75, 76 (second engagement claws 75, 1st in the direction from the inner overlapping portion 73 toward the outer overlapping portion 72. ), A first tool claw 77, two engagement holes 78 and 79 (second engagement hole 78, first engagement hole 79), and a second tool claw 80 are formed in this order. ing. Then, by tightening in a state of being wound in a ring shape, the engagement claw 75 enters the engagement hole 78 and engages, and the engagement claw 76 enters the engagement hole 79 and engages. By these engagements, the tightening member is tightened by entering the final tightening state. 8 and 9 show this fully tightened state.

  The first tool claw 77 and the second tool claw 80 are pressed so as to stand upward from the band body 71, and the clamp claws 13 of the boot band tightening tool 11 are formed on these tool claws 77, 80. Tightening is performed with 14 engaged. When tightening, the tool claws 77 and 80 are drawn together. When the tool claws 77 and 80 are brought into the engaged state shown in FIGS. 8 and 9, the engagement claws 75 and 76 are associated with each other. It enters into the joint holes 78 and 79 and engages to enter the final tightening state. In this case, holes 77 a and 80 a are formed in the first tool claw 77 and the second tool claw 80. As shown in FIG. 9, the holes 77a and 80a are formed on the side opposite to the tightening direction (the direction in which the tool claws 77 and 80 are drawn).

  With respect to such a boot band 70, as shown in FIGS. 4 (a) and 4 (b), the clamp portions 19 and 20 of the pair of clamp claws 13 and 14 are connected to the corresponding tool claws 77 and 80 in the outer circumferential direction. Engage from. In other words, the tool claws 77 and 80 are engaged with each other by the pair of clamp claws 13 and 14. In this engagement, the engagement concave portions 37 and 38 of the clamp portions 19 and 20 are brought into contact with the tool claws 77 and 80, respectively. Thereafter, by inputting pressurized air to the power mechanism 15, the clamp claws 13 and 14 are closed and driven. Thereby, the tool claws 77 and 80 are attracted and engaged with each other, and the engagement claws 77 and 76 are engaged with and engaged with the engagement holes 78 and 79 to be in a tightened state. In FIG. 4, the main body 12 is omitted.

  In the boot band tightening tool 11 described above, the distance between the pair of clamp claws 13 and 14 is set according to the ring diameter of the boot band to be tightened, as shown in FIGS. 4 (a) and 4 (b). The boot band having the corresponding ring diameter is tightened. In the boot band tightening tool 11 of this embodiment, the boot band having a different ring diameter (that is, the boot band having the different pitches of the tool claws 77 and 80) is used. Can be applied.

  For example, a boot band having a large ring diameter L2 shown in FIG. 4 (b) using a boot tightening tool 11 (FIG. 4 (a)) in which the distance between the clamp claws 13 and 14 is set in accordance with the small ring diameter L1. When one of the clamping claws (for example, the other clamping claw 14) is engaged with the corresponding tool claw (first tool claw 77), the clamping claws 13 and 14 are used with the engagement site as a fulcrum. And the other clamp claw (one clamp claw 13) is moved in the direction of the opposed tool claw (second tool claw 80). In this operation, since the pair of clamp claws 13 and 14 are urged in the closing direction by the leaf spring 16, the moved clamp claws (one clamp claw 13) are tool claws (second tool claws). After overcoming, the return operation is performed to engage with the tool pawl. Thereby, since a pair of clamp nail | claws 13 and 14 engage with the corresponding tool nail | claws 77 and 80 reliably, even if it is a boot band with a large ring diameter, the clamping | tightening can be performed.

  As described above, in such an embodiment, even if the pitches of the tool claws 77 and 80 are different, the clamp claws 13 and 14 can be adjusted in accordance with the pitches. It can be used as it is for a boot band having a different pitch, that is, a boot band having a different ring diameter. For this reason, it becomes versatile that it is not necessary to replace the boot band tightening tool. Further, since the clamp claws can be reliably engaged with the tool claws, the clamp claws 13 and 14 are not detached from the tool claws 77 and 80, and the reliability of the tightening operation can be improved.

  FIG. 10 shows another embodiment of the present invention. In this embodiment, fitting claws 37a and 38a are formed on the clamp parts 19 and 20 of the pair of clamp claws 13 and 14, respectively. The fitting claw portions 37a and 38a are formed so as to be positioned in the engagement concave portions 37 and 38 of the clamp portions 19 and 20. These fitting claws 37 a and 38 a enter and fit into the holes 77 a and 80 a formed in the tool claws 77 and 80 of the boot band 70. In the present invention, as described above, the clamp claws 13 and 14 reliably engage with the tool claws 77 and 80 even with respect to boot bands having different ring diameters. The holes 77a and 80a of 77 and 80 can be securely fitted. By such fitting, the clamp claws 13 and 14 are not detached from the tool claws 77 and 80, so that the boot band can be more securely tightened.

  FIG. 11 shows still another embodiment of the present invention. In this embodiment, a coil spring 41 is used as the spring member. As the coil spring 41, a tension spring is used, and this spring is stretched over the connection plates 21 and 22 of the pair of clamp claws 13 and 14. Thereby, the clamp claws 13 and 14 are urged in the closing direction, and can act in the same manner as the leaf spring 16 described above.

  The present invention can be variously modified without being limited to the above embodiments. For example, a leaf spring 16 as a spring member may be disposed for each of the clamp claws 13 and 14. Further, the leaf spring 16 may be a metal or a resin. Furthermore, as the power mechanism 15 for closing and driving the pair of clamp claws 13 and 14, a mechanism using an electric motor or a fluid pressure motor as a drive source, or other mechanisms can be used.

It is sectional drawing which shows the clamp nail | claw part in one embodiment of this invention. It is sectional drawing which shows the closed state of a clamp nail | claw. It is sectional drawing which shows the inside of the boot clamping tool of one Embodiment. (A), (b) is a side view which shows the fastening state of a boot band. It is a top view of an example of a boot band. It is a side view of an example of a boot band. It is a side view which shows the temporary fix | stop state of a boot band. It is a side view which shows the final fastening state of a boot band. It is sectional drawing which shows partially the final fastening state of a boot band. It is sectional drawing which shows another embodiment of this invention. It is sectional drawing which shows another embodiment of this invention. It is a side view which shows the state which clamps with the conventional boot band clamping tool. It is a side view which shows the state which clamps with the conventional boot band clamping tool.

Explanation of symbols

DESCRIPTION OF SYMBOLS 11 Boot tightening tool 12 Main body 13,14 Clamp claw 15 Power mechanism 16 Leaf spring 70 Boot band 77 1st tool nail 80 2nd tool nail

Claims (2)

A pair of openable and closable clamp claws that engage with each of the pair of tool claws of the boot band wound in a ring shape around the tightened member;
A power mechanism that is provided in a main body that holds a pair of clamp claws and that drives the clamp claws to close in the tightening direction of the boot band when power is input;
A boot band tightening tool comprising: a spring member that biases the pair of clamp claws in the closing direction.   2. The boot band tightening tool according to claim 1, wherein the spring member is a leaf spring that is stretched between at least one of the clamp claws and the main body.

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