JP2016098963A - Wire rope fastening machine - Google Patents

Abstract

PROBLEM TO BE SOLVED: To improve an operating characteristic at a wire rope fastening machine by reducing the total number of operations ranging from a fastening of an item to be fastened to its releasing.SOLUTION: A winding handle H of a wire rope fastening machine A is provided with a resilient contact pin P resiliently contacting toward a rotating axial center Cof a feeding claw Narranged at a resilient contact end surface 20 between a feeding claw part 11 at the feeding claw Nand an inverse rotation preventive releasing protrusion 12 in such a way that it can be fed in or fed out by a compression spring 6. The resilient contact end surface 20 is constituted by an arc-shaped end surface part 21 and a rotation moment generating end surface part 22. Under one state in which the resilient contact pin P is resiliently contacted with the arc-shaped end surface part 21, its resilient contact force F acts to prevent a rotation of the feeding claw Nand under the other state in which the resilient contact pin P is resiliently contacted with the rotation moment generating end surface part 22, its resilient contact force F generates a moment M acting in a direction where the feeding claw Nis engaged with a ratchet R.SELECTED DRAWING: Figure 2

Description

  In the present invention, the engagement of the feed claw with the ratchet is automatically performed by the action of the rotation moment, thereby reducing the total number of operations required for tightening and releasing the wire rope and improving the operability. In particular, in the case of a vehicle transporter that transports a plurality of transported vehicles on a carrier, wire rope tightening used to secure each transported vehicle to the carrier via a wire rope. It is related to the attached machine.

  The wire rope tightening machine tightens the object to be tightened by connecting one end of the wire rope to the object to be tightened in a state where tension is applied to the wire rope wound around the winding drum. One of cargo handling devices, for example, is disclosed in Patent Document 1.

The conventional wire rope tightening machine A ′ and the wire rope tightening machine A according to the present invention differ only in the structure of the feeding claw part, and the other parts have the same structure. Therefore, in the description of the conventional wire rope tightening machine A ′, FIGS. 1 to 3 according to the present invention and FIG. 9 according to the conventional wire rope tightening machine A ′ are used except for the portion of the feed claw. That is, the conventional wire rope tightening machine A ′ is supported by the frame-like main body B in the forward / reverse rotation itself and winds up a wire rope (none of which is shown) for tightening an object to be tightened. D, a ratchet R that is integrally attached to the drum shaft 1 of the winding drum D, and a winding handle H that is rotatably supported around the drum shaft 1 on the outside of the frame-shaped body B; The reversing prevention claw N ₂ that is always engaged with the ratchet R by the urging force of the compression spring 2 and prevents the drum shaft 1 from reversing via the ratchet R, and reversible with respect to the winding handle H. By attaching, the feed claw portion 81 (see FIG. 9) is engaged with the ratchet R, and the reverse rotation prevention claw N ₂ is attached to the compression spring 2 by the reverse rotation prevention release protrusion 82 (see FIG. 9). Rotate against the urging force to prevent the reverse rotation By releasing the engagement between the claw N ₂ and the ratchet R, reverse rotation of the drum shaft 1 is possible, in a state in which the feed pawl 81 against the ratchet R are engaged, the wire of the winding handle H A feed claw N ₁ ′ capable of winding the wire rope on the winding drum D by being rotated in the winding direction of the rope is provided. Regarding the reverse rotation prevention claw N ₂ , although the overall shape is slightly different in the present invention and the conventional wire rope tightening machines A and A ′, the functions are the same, so the same reference numerals are used.

At the time of tightening the wire rope, the feed claw portion 81 of the feed claw N ₁ ′ is engaged with the ratchet R by the biasing force of the compression spring 92 to be described later, while the reverse rotation of the ratchet R is prevented by the reverse rotation prevention claw N ₂ . By pulling down the winding handle H and winding the wire rope around the winding drum D, finally, a predetermined tension is generated on the wire rope and the object to be fastened is tightened. When the take-up handle H is raised, for each tooth of the ratchet R, the feed claw N ₁ ′ is slightly against the take-up handle H against the biasing force in the engaging direction by the compression spring 92. by rotating, the take-up drum D is in a non-rotating state, 'slips, feed pawl N ₁ against the ratchet R' feed pawl N ₁ for each tooth of the ratchet R position of is changed.

Also, when releasing the tension acting on the wire rope (releasing the wire rope), the take-up handle H is caused with the feed claw N ₁ ′ substantially inverted with respect to the take-up handle H. in, by the reverse rotation prevention releasing projection portion 82 of the feed pawl N ₁ ', and the reverse rotation preventing claw N ₂ against reverse rotation preventing claw N ₂ the urging force of the compression spring 2 is rotated in the direction away from the ratchet R, By holding this state, the wire rope wound around the winding drum D is pulled out from the winding drum D by the tension acting on itself, and the tightening of the object to be tightened is released.

As shown in FIG. 9, the conventional wire rope tightening machine A ′ disclosed in Patent Document 1 has a feed claw N ₁ ′ attached to the winding handle H in a fixed state with respect to the winding handle H. , 'a rotation support shaft 91 for supporting the rotatably, the feed pawl N _1' feed pawl N ₁ in a state of being urged by the compression spring 92 on the side of the provided in the rotating support shaft 91 The feed claw N ₁ ′ is provided with the engagement recess 91a engageable with the ratchet R by the engagement sphere 93 provided to be engageable with the engagement recess 91a. Only at the “position”, the winding drum D is rotated by rotating integrally with the winding handle H. Therefore, as shown by a two-dot chain line in FIG. 9, the engagement sphere 93 and the engagement recess 91 a of the rotation support shaft 91 are engaged at a position other than the “specific position in the rotation direction” described above. The feed claw N ₁ ′ is freely rotated with respect to the winding handle H after being released. In FIGS. 1, 2, and 9, C ₀ , C ₁ , and C ₂ indicate the rotation shaft centers of the drum shaft, the feed claw N _1, and the reverse rotation prevention claw N ₂ , respectively.

Therefore, the winding handle H is raised, and the reverse rotation prevention claw N ₂ is separated from the ratchet R by the reverse rotation prevention release protrusion 82 of the feed claw N ₁ ′. To bring the rope into a winding state, as shown in FIGS. 7-C and 7-E, it is necessary to manually wind the rope to the position where the feed claw portion 81 of the feed claw N ₁ ′ can be engaged with the ratchet R. The feed claw N ₁ ′ had to be rotated with respect to the handle H.

In particular, in a wire rope tightening machine used in a vehicle transporter, the driver of the vehicle transporter loads and unloads a plurality of transported vehicles on the loading platform, and tightens a number of wire rope tighteners. Since the driver who wears the leather gloves naturally carries out each operation of the release and the release operation alone, the rotation operation of the feed claw N ₁ ′ is a troublesome work.

Further, in a vehicle transport vehicle, when traveling after the transported vehicle is fastened to the cargo bed using the conventional wire rope tightening machine A ′, turning power is applied to the ratchet due to vibration during travel or the like. 7-F, the winding handle H is lowered to a substantially horizontal position, and in this state, the engagement between the feeding claw N ₁ ′ and the ratchet R is released. The feed claw N ₁ ′ is slightly rotated. However, conventional wire rope tightening device A 'is feed pawl N ₁ described above' in the state of disengagement of, the whole of the nail N ₁ 'feed in a side view may enter the inside of the winding handle H shape Therefore, it is difficult to arrange the posture of the feed claw N ₁ ′ in the rotation direction to the position where the reverse rotation prevention claw N ₂ is rotated backward in preparation for lowering the transported vehicle. It was. Therefore, as shown in FIG. 7-B, after arriving at the destination, the entire feeding claw N ₁ ′ is rotated in a state where there is no restriction around the winding handle H slightly lifted, Since the posture was changed, the total number of operations of the wire rope tightening machine A ′ increased and the operability was poor.

JP 2000-43880 A

  An object of the present invention is to improve operability by reducing the total number of operations required from the tightening of an object to be tightened to the release thereof in the wire rope tightening machine having the above-described configuration.

  The invention of claim 1 for solving the above-described problems is a winding drum for winding a wire rope that is supported by a frame-shaped main body in forward and reverse rotation itself and fastens an object to be fastened, and the winding drum. A ratchet integrally attached to the drum shaft, a winding handle rotatably supported around the drum shaft on the outside of the frame-shaped main body, and the ratchet always engaged with the ratchet by an urging force. The reversing prevention claw for preventing the rewinding of the winding drum via the reversing and the reversing attachment to the winding handle, the feed claw portion is engaged with the ratchet, and the reversal prevention release By rotating the anti-reverse rotation pawl against the urging force by the protrusion and releasing the engagement between the reverse rotation prevention pawl and the ratchet, the drum shaft can be reversed, and the feed pawl is fed to the ratchet. Department is in charge In this state, the wire rope clamping machine includes a feed claw that enables the wire rope to be wound around the winding drum by rotating the winding handle in the winding direction of the wire rope. The winding handle has an elastic contact pin that elastically contacts the pin elastic contact end surface of the feed claw between the feed claw portion and the reverse rotation prevention release projection portion toward the rotation axis of the feed claw. Is provided so as to be able to enter and exit in the longitudinal direction of the elastic contact pin, and the pin elastic contact end surface is concentric with the rotation axis of the feed claw and is an arcuate end surface portion present on the feed claw portion side. The rotational moment that is connected to the arcuate end surface portion and gradually decreases from the arcuate radius of the arcuate end surface portion as the distance from the pivot axis of the feed pawl becomes smaller toward the reverse rotation prevention release protrusion. And the elastic contact pin In the state of elastic contact with the arcuate end surface portion, the elastic contact force acts so as to prevent rotation of the feed claw, and in the state where the elastic contact pin is elastically contacted with the rotational moment generation end surface portion, The elastic contact force is characterized by generating a moment in a direction in which the feed claw and the ratchet are engaged to rotate the feed claw.

  According to the first aspect of the invention, the winding handle is rotated to the maximum toward the reverse rotation prevention pawl side, and the reverse rotation prevention claw is rotated against the urging force by the reverse rotation prevention release protrusion of the feed claw. After releasing the engagement with the ratchet and releasing the tightening of the wire rope, the elastic contact pin rotates the feed claw when the winding handle is rotated to the side opposite to the reverse rotation prevention claw. The feed pawl is rotated in a direction to engage with the ratchet by the rotational moment generated by elastic contact with the moment generating end surface portion, and is automatically engaged with the ratchet. Therefore, after releasing the tightening of the wire rope by releasing the engagement of the reverse rotation prevention claw, the wire handle is returned to the side opposite to the reverse rotation prevention claw without manually rotating the feed claw. The rope can be wound up.

  Thus, after releasing the wire rope tightening, the engagement of the feed claw with the ratchet is automatically performed, so that the total number of operations required for tightening the wire rope and releasing it is reduced. The operability as a tightening machine is improved.

  Further, when the feed claw is rotated in a direction in which the engagement between the feed claw and the ratchet is released, the elastic contact pin elastically contacts the arcuate end surface portion of the feed claw, so that the rotational moment with respect to the feed claw is Without generating, the elastic contact force of the elastic contact pin acts only to prevent the feed pawl from rotating. Therefore, the feed pawl is reliably stopped at the position where the disengagement state with the ratchet is maintained.

  The invention of claim 2 is characterized in that, in the invention of claim 1, the connecting portion between the arcuate end surface portion of the feed claw and the rotational moment generating end surface portion is a continuous surface.

  In the invention of claim 2, since the connecting portion between the arcuate end surface portion of the feed claw and the rotational moment generating end surface portion is a continuous surface, the elastic contact pin provided on the take-up handle It can slide smoothly, and the feed pawl can be rotated manually.

  The invention of claim 3 is the invention of claim 1 or 2, wherein the wire rope take-up device secures the vehicle to be transported to the loading platform via the wire rope in the vehicle transport vehicle, In a state where the feeding claw and the ratchet are engaged and the winding handle is pulled down, the tip of the reverse rotation preventing claw protrudes upward from the winding handle.

  In a vehicle transporter, when the transported vehicle is secured with a wire rope and traveled, the engagement between the feed claw and the ratchet constituting the wire rope tightening machine is released. According to the invention of No. 3, in a state where the take-up handle is pulled down, a part of the feed claw protrudes upward from the take-up handle. By causing the elastic contact pin to elastically contact the arcuate end surface portion of the feed claw, the feed claw is kept in a non-engaged state with respect to the ratchet.

  According to a fourth aspect of the present invention, in any one of the first to third aspects, the tip of the elastic contact pin is formed in a hemispherical shape.

  According to the invention of claim 4, when winding the wire rope, the tip of the elastic contact pin is in elastic contact with the elastic contact end surface of the supply nail by the urging force of the urging means. However, since the tip of the elastic contact pin is hemispherical, the sliding resistance is reduced and the sliding is smooth.

  According to the present invention, the pin elastic contact end surface of the upper end surface of the feed claw is composed of an arcuate end surface portion that does not generate a rotation moment in the feed claw and a rotation moment generation end surface portion that generates a rotation moment, The direction of the elastic contact force of the elastic contact pin that comes into elastic contact with the contact end surface is set so as to pass through the rotation axis of the feed claw. When the take-up handle is pulled down after releasing the wire rope, the elastic contact pin is in elastic contact with the rotational moment generating end surface, so that the supply claw is connected to the ratchet. A rotational moment acts in the direction of engagement, the feed claw and the ratchet are automatically engaged, and the feed claw of the feed claw is slightly separated from the ratchet to release the engagement between them. Then, the elastic contact By down is elastic contact with the arcuate end surface portions, the separated state is maintained.

  As a result, the operability of the wire rope tightening machine can be improved by reducing the total number of operations required for tightening and releasing the wire rope. In particular, when a wire rope tightening machine is used for tightening a transported vehicle of a vehicle transporter, a single driver can tighten and release a number of wire rope tightening machines within a limited time. Because of the need to do so, improving operability by reducing the total number of operations has a significant effect in the vehicle transport industry.

It is a perspective view of the wire rope clamping machine A which concerns on this invention. It is a side view similarly. It is also a plan view. It is a front view of the feed pawl N ₁ constituting the wire rope tightening device A. By elastically contacting the arcuate end surface 21 of the upper end surface of the feed claw N ₁ of the elastic contact pin P, the rotation claw N _{1 is} not caused to generate a rotational moment M, and the feed claw N ₁ is rotated. FIG. FIG. 4 is a principle diagram showing that a rotational moment M is generated with respect to the feed claw N ₁ by elastic contact with the arcuate end surface portion 21 of the upper end surface of the feed claw N ₁ of the elastic contact pin P. It is a figure which shows the state of this invention and each conventional wire rope clamping machine A, A 'during driving | running | working of the vehicle transporter carrying the to-be-transported vehicle. And vehicle transporters loaded with the transportation vehicle arrives at the destination is a diagram showing an inversion operation of the 'required feed pawl N ₁ only in' conventional wire rope tightening device A. It is a figure which shows the release preparation operation of wire rope in each wire rope clamp | tightening machine A, A ', and its release operation. It is a diagram showing a winding preparation operation wire rope by reversing the conventional 'feed pawl N ₁ necessary only in' attached wire rope tightening machine A. It is a figure which shows winding operation of the wire rope in each wire rope clamping machine A, A '. It is a figure which shows the starting preparation operation in each wire rope clamping machine A and A '. (A), (b), the rotation of the separate shapes moment generating end surface 22 'is a front view of the feed pawl N ₁ equipped with a 22 ". It is the side view which fractured | ruptured a part which shows the winding principle of the conventional wire rope clamping machine A '.

Hereinafter, the present invention will be described in more detail with reference to examples. In the present invention, the elastic contact pin P that elastically contacts the elastic contact end surface 20 of the feed claw N ₁ is attached to the winding handle H by being biased in the protruding direction by the compression spring 6, and the elastic contact pin P Is characterized by two points in the shape of the elastic contact end face 20 of the feed claw N ₁ , and the other configuration is the same as or equivalent to the conventional wire rope clamping machine A ′ as described above.

That is, as shown in FIGS. 1 and 2, the take-up handle H includes a U-shaped handle frame body portion 3 integrally attached to the drum shaft 1 outside the frame-shaped main body B, and The handle frame body portion 3 includes an operation handle portion 4 that is integrally attached to the opposite side of the drum shaft 1. A pin insertion cylinder 5 is provided on the inner side of the opposing plate body portion 3 a of the handle frame body portion 3. And the elastic contact pin P is accommodated in the pin insertion cylinder 5 with only the tip projecting toward the feed claw N ₁ and accommodated in the pin insertion cylinder 5. The elastic contact pin P is urged in the protruding direction by the compression spring 6 so as to elastically contact the elastic contact end surface 20 of the feed claw N ₁ . The elastic contact portion at the tip of the elastic contact pin P is formed in a hemispherical shape so that it can slide smoothly with respect to the elastic contact end surface 20 of the feed claw N ₁ .

The following configuration is the same as that of the conventional wire rope tightening machine A ′, but the ratchet R attached integrally to the drum shaft 1 has a handle frame body portion 3 at one end of the drum shaft 1. The feed claw N ₁ is disposed between one plate body portion 3a and the take-up drum D, and the feed claw N ₁ is disposed inside one plate body portion 3a of the handle frame body portion 3 of the take-up handle H. It is supported so as to be rotatable with respect to a rotation support shaft 7 integrally attached to the body portion 3a. Further, the reverse rotation preventing claw N ₂ is integrally attached to one end portion of a claw support shaft 9 that is rotatably supported by both side plate portions 8 (see FIG. 3) of the frame-shaped main body B.

As shown in FIG. 4, the feed claw N ₁ is a thick plate-like member, and the phase in the rotation direction around the rotation axis C ₁ in the main body plate portion 10 is the elastic contact described later. A feed claw portion 11 and a reverse rotation prevention release projection portion 12 project from a portion shifted by 180 ° or more along the direction including the end surface 20, and between the feed claw portion 11 and the reverse rotation prevention release projection portion 12. In addition, a rotating operation unit 13 is provided at a portion close to the feeding claw portion 11 so as to project the rotating claw N ₁ for holding the feeding claw N ₁ by hand.

An upper end surface of the main body plate portion 10 between the reverse rotation prevention release protrusion 12 and the rotation operation portion 13 is a resilient contact end surface 20 with which the resilient contact pin P is resiliently contacted. The elastic contact end face 20 is connected to the turning operation part 13 and has an arcuate end face part 21 having a central angle (θ ₁ ) equal to the radius (r) from the turning axis C ₁ of the feed claw N _1. And a rotational moment generation end face portion 22 provided in connection with the arcuate end face portion 21. Distance from the rotation axis C ₁ of the feed pawl N ₁ of rotational moment generating end surface portion 22, smaller than the radius (r) of the arc-shaped end surface 21 in all parts, the intersection of the two ends faces 21 and 22 It gradually decreases from Q toward the reverse rotation prevention release protrusion 12. The central angle of the feed claw N ₁ of the rotational moment generating end face portion 22 is (θ ₂ ), and the position at each position shifted from the intersection Q by an angle (θ ₂ a) and an angle (θ ₂ a + θ ₂ b). The distances from the rotation axis C ₁ are (J ₁ ) and (J ₂ ), respectively (r> J ₁ > J ₂ ). The rotational moment generation end surface portion 22 is a non-arc-shaped curved surface, and at the intersection Q, the end surfaces 21 and 22 of the circular arc shape and the generation of rotational moment are continuous.

Here, as shown in the front view of the feed claw N ₁ in FIG. 4, the intersection point Q of the end surfaces 21 and 22 where the arc and the rotational moment are generated and the rotation axis C ₁ of the feed claw N ₁ are By defining the connecting straight line as the boundary straight line K and illustrating the boundary straight line K everywhere, the elastic contact pin P rotates with the arcuate end surface portion 21 in the operation explanatory view of the wire rope tightening machine A described later. It is possible to visually understand at which position the moment generation end face portion 22 exists.

Therefore, as shown in FIGS. 1 and 2, the elastic contact pin P attached to the winding handle H side is always applied to the elastic contact end surface 20 of the feed claw N _{1 by} the urging force of the compression spring 6. It is elastically contacted and elastically contacts either the arcuate end surface 21 or the rotational moment generating end surface 22 depending on the rotation position of the feed claw N ₁ with respect to the elastic contact pin P.

Then, as shown in FIG. 7A described later, during the traveling of the vehicle transporter loaded with the transported vehicle, the engagement between the ratchet R and the feed pawl N ₁ is released, and this state is maintained. If desired, the elastic contact pin P is brought into elastic contact with the arcuate end surface portion 21 of the feed claw N ₁ as shown in the principle diagram of FIG. Thus, elastic contact force F acts perpendicular to the tangent L ₀₁ of the point S _1, elastic contact force F of the elastic contact pins P for arcuate end surface 21 of the feed pawl N ₁ is the feed pawl N ₁ since the only acts toward the pivot axis C _1, the rotation moment without any effect on feeding claw N _1, the elastic contact force F is feed pawl N ₁ relative rotation supporting shaft 7 It only acts to press the main body plate portion 10 and cannot rotate. As a result, the position of the feed claw N ₁ with respect to the rotation support shaft 7 is maintained unchanged. Hereinafter, this state is referred to as a “feed claw unrotatable state”.

On the other hand, as shown in FIGS. 1 and 2, the feed claw portion 11 of the feed claw N ₁ is engaged with the ratchet R, causing the take-up handle H to rotate the take-up drum D to a predetermined length. After winding the wire rope, the winding handle H is pulled down to wind up the next predetermined length of wire rope. As shown in the principle diagram of FIG. Is elastically contacted with the rotational moment generating end surface portion 22 of the elastic contact end surface 20 of the feed claw N ₁ , and the rotational moment generating end surface portion 22 is in contact with the elastic contact force F toward the rotational axis C ₁ of the feed claw N _1. Is working.

The elastic contact force F does not act perpendicularly to the tangent L _{02 at the} point of application S ₂ of the elastic contact force F on the rotational moment generation end face portion 22. Therefore, when the elastic contact force F is decomposed into a component force F ₁ perpendicular to the tangent line L ₀₁ and a component force F ₂ parallel to the tangent line L ₀₁ , the action line of the component force F ₁ perpendicular to the tangent line L ₀ is since the deviation from the rotation axis C ₁ of the feeding claws N _1, the component force F ₁ is to generate a rotational moment which rotates the feed pawl N _1, the other component force F ₂ is the elastic contact force F Since it acts in the tangential direction at the action point S ₂ , it does not act on the feed claw N ₁ as a force or a rotational moment. Then, the action line L ₁ of the component force F _1, the distance between the action line L ₁ parallel to the imaginary line L ₂ passing through the pivot axis C ₁ of the feeding claws N ₁ When (E), feed against nail N ₁ acts rotational moment M is (F ₁ × E), the rotational moment M is, in the direction of feed pawl portion 11 of the feed pawl N ₁ is engaged with the ratchet R, the feed pawl N ₁ Energize to rotate. Hereinafter, this state is referred to as a “feed claw rotation urging state”.

As a result, even feed pawl N ₁ against the ratchet R is in any arrangement, as long as the rotation moment generated end surface portion 22 in elastic contact pin P of the feed pawl N ₁ is in elastic contact, by the rotation moment M, the feed pawl N ₁ is urged in a direction in which the feed claw portion 11 is engaged with the ratchet R, and tries to engage with the ratchet R.

According to the present invention, according to the above principle, the rotational moment M is applied to the feed claw N ₁ by the elastic contact force F of the elastic contact pin P according to the arrangement position of the feed claw N ₁ with respect to the ratchet R. the arrangement region of the feed pawl N ₁ to engage the feed pawl N _1, by pressing the feed claw N ₁ relative rotation supporting shaft 7 is divided into a placement area to disable the rotation of the feed pawl N ₁ There is a special feature.

Next, using FIG. 7-A and FIG. 7-F, the above-described wire rope tightening machine A is fixed to the loading platform of the vehicle transport vehicle and used for securing the transported vehicle loaded on the loading platform. The case where it does is demonstrated. The wire rope tightening machine A is fixed to the loading platform of the vehicle transporter, and the wire rope wound around the winding drum D is secured to the frame of the transported vehicle. FIGS. 7A and 7F illustrate the operations of the present invention and the conventional wire rope tightening machines A and A ′ in comparison with the upper and lower stages, respectively. The blank portion indicates that the operation required in the conventional wire rope tightening machine A ′ is unnecessary. As described above, the feature of the present invention is that the “feed claw rotation urging state” and “feed claw rotation state” are determined by the position of the elastic contact force F of the elastic contact pin P on the elastic contact end surface 20 of the feed claw N _1. It is that two different states of “impossible state” occur, and the winding of the wire rope with respect to the winding drum D itself has no characteristics. Therefore, the wire rope is not illustrated throughout the drawings.

FIG. 7-A is a diagram showing the state of each wire rope tightening machine A, A ′ when the vehicle transporter is “running”, and as shown in FIG. 7-F, the transported vehicle at the destination. In both cases, the winding handle H is pulled down to the maximum and the feed claws 11 and 81 of the feed claws N ₁ and N ₁ ′ are ratchet. It is separated from R and is in a disengaged state. That is, in the wire rope tightening machine A according to the present invention, the feed claw N ₁ is pressed against the rotation support shaft 7 by the elastic contact force F of the elastic contact pin P, and the “feed claw rotation impossible state” is established. Therefore, there is no fear that the feeding claw N ₁ is rotated by the vibration during transportation and engages with the ratchet R. However, in the conventional wire rope tightening machine A ′, the feeding claw N ₁ ′ This is a state that can be rotated in any direction, which is different from the possibility that the feed claw N ₁ ′ may be rotated and engaged with the ratchet R due to vibration or the like.

FIG. 7B to FIG. 7-F are operation explanatory diagrams when the vehicle transport vehicle arrives at the destination and “when the vehicle is unloaded”. FIG. 7-B shows that the feed claw N ₁ ′ is almost reversed only in the conventional wire rope tightening machine A ′ before the transported vehicle is lowered, and the reverse rotation prevention release protrusion of the feed claw N ₁ ′ is shown. 82 is the state in which the reverse rotation preventing claw N ₂ is rotated in the direction away from the ratchet R to prepare for releasing the tension acting on the wire rope. However, in the wire rope tightening machine A according to the present invention, the engagement between the reverse rotation prevention claw N ₂ and the ratchet R is released in the final operation after loading the transported vehicle at the destination shown in FIG. Since the feed claw N ₁ is inverted to a possible posture and is in a “feed claw rotation disabled state”, in the wire rope tightening machine A of the present invention, the feed claw N ₁ before the transported vehicle is lowered. No reversing operation is required.

FIG. 7-C shows that the reverse rotation prevention claw N _{2 is} caused by the reverse rotation prevention release protrusions 12 and 82 of the feed claws N ₁ and N ₁ ′ when the take-up handle H is raised before the transported vehicle is lowered at the destination. By rotating the wire rope in a direction away from the ratchet R, by releasing the tension of the wire rope, the winding drum D is rotated in the direction opposite to that during winding by the tension of the wire rope itself, By pulling out the wire rope of a predetermined length, the tension of the wire rope is released and loosened. Then, as shown in the portion of the operation explanatory diagram according to the upper of the invention of FIG. 7-C, before and after the reversal preventing claw N ₂ by a feeding claw N ₁ is rotated, the feed pawl N ₁ is The “feed claw rotation impermissible state” is changed to the “feed claw rotation urging state”.

  As described above, after all the transported vehicles loaded on the loading platform of the vehicle transport vehicle are released from the wire rope, the transported vehicle is dropped from the loading platform, and another plurality of transported vehicles are mounted. Carrying the “vehicle loading / unloading” work on the loading platform.

After loading the transported vehicle at the destination, as shown in FIG. 7-D, in the conventional wire rope tightening machine A ′, the feed claw N ₁ ′ is almost reversed and the feed claw portion 81 is reversed. Must be engaged with the ratchet R. However, in the present invention, in a state that releases the tension of the wire rope is the last operation before Kudasu to be carrier vehicle of FIG. 7-C, the feed pawl N ₁ is "feed pawl pivot biasing state since a "by the rotation moment M acting on the feed pawl N _1, when separating the feed pawl N ₁ against backstop claws N _2, the feed pawl N ₁ automatically, It is rotated in a direction to engage with the ratchet R and engages with the ratchet R. Therefore, in the present invention, the manual turning operation of the feed claw N ₁ is not necessary.

Next, as shown in FIG. 7E, when the take-up handle H is pulled down while the feed claws N ₁ (N ₁ ′) and the ratchet R are engaged, the take-up drum D rotates. When the wire rope is wound around the winding drum D by being moved and the winding handle H is raised, the winding claw N ₁ (N ₁ ') Slips and is triggered. By repeating this operation, a wire rope having a required length is wound around the winding drum D, thereby applying tension to the wire rope. Here, in the present invention, in a state where the feed claw portion 11 of the feed claw N ₁ and the ratchet R are engaged, the feed claw N ₁ maintains the “feed claw turning biased state”. Therefore, the engaged state between the feed claw N ₁ and the ratchet R is always maintained.

After applying the necessary tension to the wire rope and securing the transported vehicle loaded on the loading platform, “preparation for departure” for another destination is performed. That is, as shown in FIG. 7-F, the feed claws N ₁ , N ₁ with the take-up handle H slightly raised in order to facilitate the rotation of the feed claws N ₁ , N _{1 ′.} In the state where the engagement between the feed claws N ₁ , N ₁ ′ and the ratchet R is released by slightly rotating the feed claws 11, 81 in the direction away from the ratchet R, Let it run. Finally, when the winding handle H is lowered to the lowest position, “departure preparation” is completed. As shown in the upper part of FIG. 7-F, in the wire rope tightening machine A of the present invention, the take-up handle H is pulled down and the feed claw N ₁ and the ratchet R are engaged. In this state, the tip of the reverse rotation preventing release protrusion 12 of the feed claw N ₁ protrudes upward from the upper surface of the handle frame body 3 of the winding handle H, so that the feed claw N ₁ Can be easily rotated.

As shown in the operation explanatory diagram according to the present invention in the upper part of FIG. 7 -F, when the feed claw N ₁ is engaged with the ratchet R, the feed claw rotation biased state is set. However, when the feed claw N ₁ is separated from the ratchet R by a necessary amount, the “feed claw rotation impossible state” is established, and the separated state of the feed claw N ₁ with respect to the ratchet R is maintained.

Further, the rotational moment generating end face portion 22 of the feed claw N ₁ is connected to the arcuate end face portion 21, and from the rotation axis C ₁ of the feed claw N ₁ toward the reverse rotation prevention release projection portion 12. distance is, if the shape becomes gradually smaller than the arc radius (r) of the arcuate end surface 21 is not limited to the shape described above, even any shape, the rotation moment M to the feed pawl N ₁ Be generated. For example, the rotational moment generation end face portion 22 ′ in FIG. 9A has a radius (r ′) larger than the arc radius (r) of the arc-shaped end face portion 21 and satisfies the above-described conditions. FIG. 9B shows an example in which the rotational moment generation end face 22 ′ is a flat surface. The arc center (C ₁₁ ) is provided at the position.

  Moreover, although the said Example is an example which used the wire rope clamping machine which concerns on this invention with respect to the lashing of the to-be-transported vehicle loaded on the loading platform of a vehicle transport vehicle, this invention is covered with a wire rope. It can be used for any application other than the above as long as it fastens the fastener.

A: Wire rope tightening machine
B: Frame body
C _1: feeding claws of the rotation axis
D: Winding drum
F: Elastic contact force of elastic contact pin
H: Winding handle
K: Boundary straight line of the elastic contact end surface connecting the intersection of the arc-shaped end surface portion and the rotational moment generation end surface portion and the rotation axis of the feed claw
N ₁ : Feeding claw
N _2: anti-reverse claw
P: Elastic contact pin
Q: Intersection of the arcuate end surface and the rotational moment generation end surface
R: Ratchet
6: Compression spring (biasing means) of elastic contact pin
7: Rotating bearing shaft of feed claw
11: Feeding claw part of feeding claw
12: Protrusion for preventing reverse rotation of feed claw
20: Elastic contact end face
21: Arc-shaped end surface portion of the elastic contact end surface
22: End surface portion of rotational moment generation of elastic contact end surface

Claims (4)

A winding drum for winding a wire rope that is supported by the frame-like main body in forward and reverse rotation itself and fastens the object to be tightened;
A ratchet integrally attached to the drum shaft of the winding drum;
A winding handle that is rotatably supported around the drum shaft on the outside of the frame-shaped main body;
A reverse rotation preventing claw that is always engaged with the ratchet by an urging force and prevents reverse rotation of the winding drum via the ratchet;
By being reversibly attached to the winding handle, the feed claw portion is engaged with the ratchet, and the reverse rotation prevention claw is rotated against the urging force by the reverse rotation prevention release protrusion. The drum shaft can be reversed by releasing the engagement between the reverse rotation prevention pawl and the ratchet, and the winding handle is attached to the wire rope in a state where the feed pawl is engaged with the ratchet. A feed claw that enables the wire rope to be wound around the winding drum by rotating in the winding direction;
A wire rope tightening machine equipped with
The winding handle has an elastic contact pin that elastically contacts the pin elastic contact end surface between the feed claw portion and the reverse rotation prevention release projection portion of the feed claw with a biasing means toward the rotation center of the feed claw. Provided in the longitudinal direction of the elastic contact pin,
The pin elastic contact end surface is concentric with the rotation center of the feed claw, and is connected to the arcuate end surface portion existing on the feed claw portion side and the arcuate end surface portion, and the reverse rotation prevention release protrusion The distance from the rotation center of the feed claw as it goes to the part is composed of a rotational moment generation end face part that gradually becomes smaller than the arc radius of the arcuate end face part,
In a state where the elastic contact pin is in elastic contact with the arcuate end surface portion, the elastic contact force acts so as to prevent the feed pawl from rotating, and the elastic contact pin is elastically applied to the rotational moment generation end surface portion. In the contacted state, the elastic contact force generates a moment in a direction in which the feed claw and the ratchet are engaged, and acts to rotate the feed claw.   The wire rope tightening machine according to claim 1, wherein a connecting portion between the arcuate end surface portion of the feed claw and the rotational moment generation end surface portion is a continuous surface. The wire rope take-up device secures the transported vehicle to the cargo bed via the wire rope in the vehicle transport vehicle,
The tip of the reverse rotation preventing claw protrudes upward from the winding handle in a state where the feeding claw portion of the feeding claw and the ratchet are engaged and the winding handle is pulled down. The wire rope fastening machine according to claim 1 or 2.   The wire rope tightening machine according to any one of claims 1 to 3, wherein a tip portion of the elastic contact pin is formed in a hemispherical shape.

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