JP5052431B2 - Tightening band - Google Patents

Description

  The present invention relates to a tightening band, and more particularly to a tightening band that is attached to a boot that covers a constant velocity joint for a vehicle and performs tightening.

  2. Description of the Related Art Conventionally, a so-called one-touch type tightening band is used as a tightening band for tightening a member to be tightened such as a cover (boots) or a hose of a joint portion of an automobile drive shaft. This is a tightening band in which both ends of a metal band member are joined to form a ring shape, and a lever is joined to the joint by spot welding. In such a tightening band, by inserting the tightening band into the member to be tightened in the axial direction and bending the lever so that the handle side end is along the peripheral surface of the band member with the fulcrum side end as a fulcrum, The band member is reduced in diameter to tighten the member to be tightened.

  When fixing boots for constant velocity joints of automobile drive shafts, omega type clamps with gate-type fastening ears cannot be used because the outermost diameter is greatly increased and it is difficult to secure a gap with other parts. Yes, it is necessary to use one-touch type tightening bands. Technologies relating to conventional one-touch type tightening bands are disclosed in, for example, Patent Documents 1 to 3.

  FIG. 5 is a schematic side view showing a configuration of a conventional one-touch type tightening band. As shown in FIG. 5, a one-touch type tightening band 101 (also called a one-touch boot clamp when used to fix a boot) includes a metal band portion 102. The band portion 102 is formed in a ring shape by being overlapped so that both ends thereof are in a palm. The lever portion 104 is fixed to the joint portion 102a of the band portion 102 by spot welding. The lever portion 104 includes one end 111 that is one end, the other end 112 that is the other end, a midway portion 113 joined to the palm portion 102a, and one end side portion closer to the one end 111 than the midway portion 113. 115 and the other end portion 114 closer to the other end 112 than the midway portion 113.

  The lever portion 104 is formed in an arc shape so as to be in close contact with the outer peripheral surface of the band portion 102 when bent. The one end side portion 115 and the other end side portion 114 are formed in a single arc shape that shares the center of curvature and equalizes the curvature. The lever portion 104 is joined to the palm portion 102 a on the curved arcuate projecting surface side in the midway portion 113. At one end 111 that serves as a fulcrum at the time of bending, the lever portion 104 is provided substantially along the radial direction of the ring shape of the band portion 102. Lever stops 103 are formed standing on both sides of the band portion 102 in the width direction.

  The inner peripheral surface of the plate 108 having a U-shaped cross section is joined to one inner peripheral surface where the end portions of the band portion 102 are joined to each other by spot welding. The plate 108 is provided so as to cover the gap formed on the inner peripheral surface side by joining both ends of the band portion 102, and absorbs a step (gap) with the member to be fastened to improve the sealing performance. The lever portion 104 is provided to receive and reinforce the load applied to the fulcrum when the lever portion 104 is tilted with the one end 111 being abutted against the band portion 102.

When tightening a member to be tightened using a conventional tightening band, the other end portion 114 is bent in the direction of arrow A101 shown in FIG. Defeat. At this time, the band portion 102 spot-welded to the lever portion 104 is pulled in the direction of arrow A102 shown in FIG. Thereby, the band part 102 formed in the ring shape can be reduced in diameter, and the member to be fastened can be tightened.
JP-A-9-291912 JP 2006-161869 A JP-A-10-26108

  When the member to be fastened is tightened using the conventional one-touch type tightening band 101, the pressing load generated along with the generation of the tensile load pulling the band portion 102 acts on the fulcrum portion where the one end 111 of the lever portion 104 abuts. To do. There is a peak of the tensile load of the band portion 102 while the lever portion 104 is lowered to the lever stop 103, and the pressing load to the fulcrum portion is also maximized. As shown in FIG. 5, when the lever portion 104 formed in a single arc shape is tilted, the fulcrum portion is always tightened due to the effect of the lever portion 104 extending in the radial direction of the tightened member at the fulcrum portion. A pressing load in a direction close to the center direction of the attaching member (that is, the direction of arrow A103 shown in FIG. 5) is received.

  When the inner diameter after tightening of the member to be tightened is adjusted to increase the tightening allowance of the member to be tightened, the tensile load of the band portion 102 increases and the pressing load on the fulcrum portion also increases. When the pressing load in the direction of arrow A103 increases, deformation of the lever portion 104, deformation of the plate 108, or breakage of the band portion 102 at the fulcrum portion is likely to occur during tightening, and when such deformation or breakage occurs, There was a problem that tightening was not achieved.

  When a relatively elastic material such as a chloroprene rubber boot or a rubber hose is fastened as a member to be fastened, high sealing performance can be maintained by returning the material to be fastened even when tightened with a low tightening force. However, when tightening a material having relatively low elasticity as a member to be tightened, for example, a resin boot such as a thermoplastic elastomer, it is necessary to tighten the band portion 102 with a high tightening force in consideration of sealing properties. The problem that the above-mentioned deformation and breakage are likely to occur.

  The present invention has been made in view of the above problems, and its main purpose is to suppress the deformation of the lever portion, the deformation of the plate, and the breakage of the band portion of the fulcrum portion even when the band portion is tightened with a high tightening force. It is to provide a tightening band with improved durability and reliability.

  The tightening band according to the present invention includes a band portion and a lever portion. The band portion is formed in a ring shape by joining both end portions of the band-shaped member. The lever portion has one end that is one end and the other end that is the end opposite to the one end. One end of the lever portion comes into contact with the outer peripheral surface of the band portion. The lever part is joined to the band part in the middle part between one end and the other end. The fastening band fastens a member to be fastened disposed on the inner peripheral side of the band portion by tilting the lever portion toward the outer peripheral surface of the band portion with one end of the lever portion serving as a fulcrum. The lever portion includes one end side portion on one end side from the midway portion and the other end side portion on the other end side from the midway portion. The outer peripheral surface of the band portion includes a facing portion that faces the lever portion when the lever portion is tilted. The one end side part is formed in the curved surface shape which becomes convex toward the opposing part. The other end side part is formed in the curved surface shape which becomes concave toward the opposing part.

  When the tightening band is viewed from the side, the extension length of the other end portion may be larger than the extension length of the one end portion.

  The curved surface shape that forms the one end side portion and the curved shape that forms the other end side portion may be in contact with each other at the midway portion.

  According to the tightening band of the present invention, the one end side portion of the lever portion is bent in a direction opposite to the direction in which the other end portion bends, and the entire shape of the lever portion is an S-shape. Therefore, the load direction acting on the fulcrum when the band portion is reduced in diameter and the member to be fastened is tightened can be directed from the conventional radial direction to the circumferential direction. Therefore, since the load applied in the radial direction of the conventional band part can be released in the circumferential direction, the deformation of the lever part, the deformation of the plate, and the occurrence of the band part breakage of the fulcrum part can be suppressed. Tightening ability can be improved.

  Embodiments of the present invention will be described below with reference to the drawings. In the following drawings, the same or corresponding parts are denoted by the same reference numerals, and description thereof will not be repeated.

  In the embodiments described below, each component is not necessarily essential for the present invention unless otherwise specified. In the following embodiments, when referring to the number, amount, etc., unless otherwise specified, the above number is an example, and the scope of the present invention is not necessarily limited to the number, amount, etc.

  FIG. 1 is a schematic perspective view showing the configuration of the fastening band of the present embodiment. FIG. 2 is a schematic side view of the fastening band as seen from the II direction shown in FIG. FIG. 3 is a schematic diagram for explaining the shape of the lever portion. FIG. 4 is a schematic diagram for explaining a load acting on a fulcrum portion. The fastening band of the present embodiment will be described with reference to FIGS.

  As shown in FIGS. 1 and 2, the fastening band 1 includes a metal band portion 2. The band portion 2 is formed in a substantially ring shape as a whole by joining both end portions of the band-shaped member. Both end portions of the band-shaped member forming the band portion 2 are overlapped and joined so as to be joined by bending to form a joined portion 2a. Lever stops (buckles) 3 as metal stoppers are formed standing on both sides of the band portion 2 in the width direction.

  A lever portion 4 is fixed to the palm portion 2a, which is an overlapping portion of both ends of the band portion 2, by spot welding. The lever part 4 has one end 11 which is one end, the other end 12 which is the other end opposite to the one end 11, a midway part 13 joined to the palm part 2 a, and one end than the midway part 13. 11 includes one end portion 15 on the 11th side and the other end portion 14 on the other end 12 side of the midway portion 13. The lever portion 4 is joined to the palm portion 2 a of the band portion 2 at a midway portion 13 between the one end 11 and the other end 12. The outer peripheral surface of the band portion 2 includes a facing portion 2b that faces the lever portion 4 when the lever portion 4 is bent.

  The inner circumferential surface of the plate 8 having a U-shaped cross section is joined to one inner circumferential surface where the ends of the band portion 2 are joined to each other by spot welding. Flange 8 a that reinforces plate 8 is provided on both side edges of plate 8. The plate 8 is provided so as to cover the gap formed on the inner peripheral surface side by joining both ends of the band portion 2, and absorbs a step (gap) with the member to be tightened to improve the sealing performance. The lever portion is provided to receive and reinforce the load applied to the fulcrum when the lever portion is pushed down with the end portion 11 abutting against the band portion 2.

  Both the one end side portion 15 and the other end side portion 14 of the lever portion 4 are formed in a partial shape of a cylindrical surface. FIG. 3 schematically shows the shape of the lever portion 4 when the tightening band 1 shown in FIG. 2 is viewed from the side as a combination of curved shapes. As shown in FIG. 3, when the lever portion 4 is viewed from the side, both the one end side portion 15 and the other end side portion 14 form an arc shape. The arc forming the other end side portion 14 has the center of curvature at the point CTR1 and has a curvature radius R1. The arc forming the one end side portion 15 has the center of curvature at the point CTR2 and has a curvature radius R2.

  In FIG. 3, the point CTR1 which is the center of curvature of the other end side portion 14 is on the lower right side of the lever portion 4 in the figure, whereas the point CTR2 which is the center of curvature of the one end side portion 15 is the lever portion in the figure. 4 on the upper left side. The points CTR1 and CTR2 are located on both sides of the side surface shape of the lever portion 4 so as to sandwich the side surface shape of the lever portion 4. When the lever portion 4 is viewed from the side, one of the points CTR1 and CTR2 exists on one side with respect to the extending direction of the lever portion 4, and the other extends in the extending direction of the lever portion 4 on the opposite side to the one-way side. It exists in the other direction side.

  The one end side portion 15 is formed in a reverse R shape that bends in the opposite direction to the R shape formed by the other end side portion 14. When the lever portion 4 is viewed from the point CTR1 which is the center of curvature of the other end side portion 14, the other end side portion 14 becomes concave toward the point CTR1, and the one end side portion 15 becomes convex toward the point CTR1. . When the lever portion 4 is viewed from the point CTR2 that is the center of curvature of the one end side portion 15, the other end side portion 14 has a convex shape toward the point CTR2, and the one end side portion 15 has a concave shape toward the point CTR2. Become. The overall shape of the side surface of the lever portion 4 is formed in an S shape in which arc shapes are combined.

  1 and FIG. 2, when the lever portion 4 is assembled as a part of the tightening band 1, the outer peripheral surface of the band portion 2 is when the lever portion 4 is tilted to reduce the diameter of the band portion 2. Has a facing portion 2 b that faces the lever portion 4. The one end side part 15 is formed in the curved surface shape which becomes convex toward the opposing part 2b. The other end portion 14 is formed in a curved surface shape that becomes concave toward the facing portion 2b. Compared to the conventional tightening band 101 shown in FIG. 5, the other end side portion 14 forms a curved surface shape bent in the same direction as the arc shape of the conventional lever portion 104, and the one end side portion 15 corresponds to the lever portion 104. A curved surface shape bent in the opposite direction to the arc shape is formed.

  Since the lever portion 4 is formed in an S shape, the lever portion 4 is inclined with respect to the radial direction of the ring shape formed by the band portion 2 at the fulcrum portion where the one end 11 contacts the band portion 2. The one end side portion 15 on the one end 11 side serving as a fulcrum at the time of bending in the lever portion 4 is the other end side portion 14 on the other end 12 side which is the handle side gripped at the time of bending in the ring-shaped circumferential direction of the band portion 2. It is bent to face the opposite side. The one end side portion 15 near the fulcrum is warped in the opposite direction to the other end side portion 14.

  As shown in FIG. 3, the length L1 of the arc formed by the side shape of the other end side portion 14 is larger than the length L2 of the arc formed by the side shape of the one end side portion 15. The lever portion 4 is provided so that the length from the midway portion 13 to the other end 12 is larger than the length from the one end 11 to the midway portion 13. When the tightening band 1 is viewed from the side, the extension length of the other end portion 14 is larger than the extension length of the one end portion 15.

  Further, as shown in FIG. 3, the arc formed by the one end side portion 15 and the arc formed by the other end side portion 14 are in contact with each other at the midway portion 13. The one end side portion 15 and the other end side portion 14 have a midway portion 13 as a common point, and share a tangent line in the midway portion 13. The curved surface shape forming the one end side portion 15 and the curved surface shape forming the other end side portion 14 are in contact with each other at the midway portion 13. The midway part 13 is an inflection point of a curve formed by the entire shape of the side surface of the lever part 4, and the unevenness state smoothly changes in the midway part 13 between the one end side part 15 and the other end side part 14. Yes.

  Hereinafter, a method for tightening a member to be tightened using the tightening band 1 of the present embodiment will be described. When the tightening member is tightened using the tightening band 1, the end 11 of the lever portion 4 is placed on the outer peripheral surface of the band portion 2 in a state where the tightening member is disposed on the inner peripheral side of the band portion 2 of the tightening band 1. The lever portion 4 is tilted toward the outer peripheral surface of the band portion 2 as a fulcrum for contact. The band portion 2 is bent in the direction of the arrow A1 by tilting the lever portion 4 in the direction of the arrow A1 shown in FIG. At this time, the flanges 8 a provided on both side edges of the plate 8 function as a guide for the lever portion 4 so that the other end 12 of the lever portion 4 is positioned between the lever stops 3. Then, the lever portion 4 is tilted along the outer peripheral surface of the band portion 2, and the lever portion 4 is opposed to the outer peripheral surface of the band portion 2.

  At this time, the band portion 2 spot-welded to the lever portion 4 is pulled in the direction of the arrow A2 shown in FIG. Thereby, the band part 2 formed in the ring shape is reduced in diameter, and the member to be tightened is tightened. The tilted lever portion 4 is bent at the other end 12 side by bending the lever stopper 3 fixed to the band portion 2 toward the outer peripheral surface of the band portion 2 so as to stand on both sides in the width direction of the band portion 2. Is locked and fixed so as to be pressed from the outer peripheral side. The fastening and fastening of the member to be fastened by the fastening band 1 is performed by the operation of tilting the lever portion 4, so that the member to be fastened such as a boot covering the constant velocity joint for the vehicle can be fastened and fixed by a simple operation.

  Here, as described above, the one end side portion 15 of the lever portion 4 has an inverted R shape with respect to the other end side portion 14, and the lever portion 4 is formed so as to be S-shaped as a whole. Therefore, when the lever portion 4 is bent, the load direction acting on the bending fulcrum portion of the lever portion 4 with which the one end 11 abuts is changed with respect to the conventional fastening band 101. Specifically, when the tensile load of the band portion 2 is maximized, the pressing load generated at the fulcrum portion is such that the load direction approaches the circumferential direction of the member to be tightened, as indicated by an arrow A3 in FIG. It has been. The pressing direction with respect to the pressed portion pressed against the one end 11 of the lever portion 4 at the time of tightening is inclined with respect to the conventional radial direction, and is directed in the circumferential direction of the tightened member.

  As shown in FIG. 4, a pressing load acts on the fulcrum in the direction of arrow A3. In FIG. 4, a part of the circular shape formed by the band portion 2 and the plate 8 is schematically shown as a circle C. The pressing load acting on the fulcrum portion can be decomposed in the radial direction and the circumferential direction of the circle C. An arrow A31 indicates a component of the pressing load decomposed in the radial direction of the circle C, and an arrow A32 indicates a component of the pressing load decomposed in the circumferential direction of the circle C.

  Since the direction of the pressing load applied to the fulcrum is directed in the circumferential direction of the circle C, the pressing load is distributed in the radial direction and the circumferential direction of the circle C. Therefore, the radial component of the pressing load indicated by the arrow A31 is smaller than that of the conventional tightening band 101. When tightening using the tightening band 1 of the present embodiment, the pressing load acting in the radial direction of the member to be tightened is reduced compared to the case where the conventional tightening band 101 is used. Since the pressing load conventionally applied in the radial direction of the member to be tightened is released in the circumferential direction, the tightening and fixing of the member to be tightened by the tightening band 1 is facilitated. Therefore, it is possible to suppress the occurrence of problems such as deformation of the lever portion 4 during tightening, deformation of the plate 8, or damage to the band portion 2 at the fulcrum portion, which has been a problem in the past.

  Since deformation and breakage at the time of tightening can be avoided, the tightening ability of the tightening band 1 is improved, and a higher tightening force than that of the conventional tightening band 101 can be obtained. Since the tightening capacity can be afforded, the diameter of the band portion 2 after the tightening of the tightening band 1 can be made smaller than the conventional tightening band 101 having the same diameter of the band portion 102 before tightening. It becomes. That is, it is possible to provide the tightening band 1 having an increased tightening margin (difference in inner diameter of the band portion 2 before and after tightening).

  Further, the lever portion 4 is provided so that the extension length L1 of the other end portion 14 when the tightening band 1 shown in FIG. 3 is viewed from the side is larger than the extension length L2 of the one end portion 15. ing. By forming the lever portion 4 in this way, the lever ratio is increased, and the force of pushing the lever portion 4 when the band portion 2 is reduced in diameter can be reduced, so that the tightening member can be more easily tightened. Fixing can be performed. The lever ratio refers to the ratio between the distance between the fulcrum and the force point and the distance between the fulcrum and the action point. In the case of the present embodiment, it corresponds to the ratio between the length L1 and the length L2 shown in FIG. .

  Further, the arc forming the side shape of the one end side portion 15 and the arc forming the side shape of the other end side portion 14 are in contact with each other at the midway portion 13. Therefore, when a load is applied to the lever portion 4 in order to reduce the diameter of the band portion 2, it is possible to avoid the formation of a singular point on the lever portion 4 where stress concentration occurs and deformation is likely to occur. Therefore, it is possible to further suppress the deformation of the lever portion 4 during tightening.

  As described above, the tightening band 1 of the present embodiment includes the band portion 2 and the lever portion 4. The band portion 2 is formed in a ring shape by joining both end portions of the band-shaped member. The lever part 4 has one end 11 that is one end and the other end 12 that is the end opposite to the one end 11. One end 11 of the lever portion 4 contacts the outer peripheral surface of the band portion 2. The lever portion 4 is joined to the band portion 2 at a midway portion 13 between the one end 11 and the other end 12. The fastening band 1 fastens a member to be fastened disposed on the inner peripheral side of the band portion 2 by tilting the lever portion 4 toward the outer peripheral surface of the band portion 2 with the one end 11 of the lever portion 4 as a fulcrum.

  The lever portion 4 includes one end side portion 15 closer to the one end 11 than the midway portion 13 and the other end side portion 14 closer to the other end 12 than the midway portion 13. The outer peripheral surface of the band portion 2 includes a facing portion 2b that faces the lever portion 4 when the lever portion 4 is tilted. The one end side part 15 is formed in the curved surface shape which becomes convex toward the opposing part 2b. The other end portion 14 is formed in a curved surface shape that becomes concave toward the facing portion 2b.

  If it does in this way, the one end side site | part 15 of the lever part 4 is bent in the reverse direction to the direction where the other end side site | part 14 bends, and the whole shape of the lever part 4 is made into S shape. Therefore, when the band portion 2 is reduced in diameter and the member to be fastened is tightened, the load direction A3 acting on the fulcrum can be directed from the conventional radial direction to the circumferential direction. Therefore, since the load applied in the radial direction can be released in the circumferential direction, the deformation of the lever portion 4, the deformation of the plate 8, and the occurrence of damage to the band portion 2 of the fulcrum portion are suppressed, and the durability of the tightening band 1 is achieved. The reliability can be improved, and in addition, the tightening ability of the tightening band 1 can be improved.

  In the description so far, the lever portion 4 formed so that the side surfaces of the one end side portion 15 and the other end side portion 14 have an arc shape has been described as an example. The radius of curvature of these arcs is shown in FIG. Of course, it is not limited to the example shown in FIG. Moreover, the side surface shape of the one end side portion 15 and the other end side portion 14 may not be an arc shape. For example, the one end side portion 15 and the other end side portion 14 may be formed so that the side surface has another curved shape such as an elliptical arc shape or a parabolic shape. However, if the side surface shape of the other end side portion 14 is an arc shape that is a part of a circle formed by the band portion 2, the other end side portion 14 when the lever portion 4 is tilted and the opposing portion 2b are interposed. It is preferable because it is advantageous in that the size of the generated gap can be reduced and the outer diameter of the tightening band 1 after tightening can be further reduced.

  Although the embodiment of the present invention has been described as above, the embodiment disclosed this time should be considered as illustrative in all points and not restrictive. The scope of the present invention is defined by the terms of the claims, rather than the description above, and is intended to include any modifications within the scope and meaning equivalent to the terms of the claims.

It is a schematic perspective view which shows the structure of the fastening band of this Embodiment. FIG. 2 is a schematic side view of the tightening band viewed from the II direction shown in FIG. It is a schematic diagram for demonstrating the shape of a lever part. It is a schematic diagram explaining the load which acts on a fulcrum part. It is a schematic side view which shows the structure of the conventional one-touch type clamping band.

Explanation of symbols

  1 tightening band, 2 band part, 2a palm part, 2b facing part, 3 lever stopper, 4 lever part, 8 plate, 8a flange, 11 one end, 12 other end, 13 middle part, 14 other end part, 15 one end side Site.

Claims (3)

A band portion formed in a ring shape by joining both end portions of the band-shaped member;
One end abuts on the outer peripheral surface of the band part, and a lever part joined to the band part in the middle part between the one end and the other end,
In a tightening band for tightening a tightening member disposed on the inner peripheral side of the band portion by tilting the lever portion toward the outer peripheral surface of the band portion with the one end as a fulcrum,
The lever portion includes one end side portion on the one end side with respect to the midway portion, and the other end side portion on the other end side with respect to the midway portion,
The outer peripheral surface of the band portion includes a facing portion that faces the lever portion when the lever portion is tilted,
The one end side portion is formed in a curved shape that is convex toward the facing portion,
The said other end side site | part is a fastening band currently formed in the curved surface shape which becomes concave toward the said opposing part.   The tightening band according to claim 1, wherein when the tightening band is viewed from the side, an extension length of the other end side portion is larger than an extension length of the one end side portion.   The tightening band according to claim 1 or 2, wherein the curved surface shape forming the one end side portion and the curved shape forming the other end side portion are in contact with each other in the midway portion.

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