JPH09255287A - Device generating tensile load on wire rope - Google Patents

Abstract

PROBLEM TO BE SOLVED: To apply large tensile force to a wire rope with the contact friction between the outer periphery of an inner tube and a spiral groove by inserting the inner tube into an outer tube provided with the spiral groove on the inside face and the feed/discharge ports of the wire rope, rotatably supporting the inner tube, and connecting it to a braking means. SOLUTION: A wire rope 3 guided by a wire guide is inserted into a control drum 5 from a feed port, and it is wound on the outer periphery of an inner tube 6 along the spiral groove 12 of an outer tube 7 and extracted from a discharge port. The inner tube 6 of the control drum 5 is braked via a braked body 10, a tensile load is applied to the wire rope 3 when it is wound by the rotating force of a winch, and the initial elongation of the new wire rope 3 is eliminated. The braking action to the wire rope 3 by the control drum 5 is exerted according to the braking capability of the inner tube 6 of the control drum 5, the number of turns, and the contact length of the outer tube 7 with a spiral vane 11, and a large tensile load is applied to the wire rope 3.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a device for generating a tension load on a new wire rope in a winch of a crane or the like.

[0002]

2. Description of the Related Art When a new wire rope is wound or rewound on a winch of a crane or the like, the new wire rope is wound on a drum made of wood or the like, and the end of the wire rope is set on the winch of the crane. The wire rope is wound by the rotating force of the wire rope, but at the time of winding, a tension load is applied to the wire rope, and the initial stretch of the new wire rope is made in order to make the winding of the winch ground winding part stick to the winch drum. It is important to wind while taking. As a result, wire troubles such as interruption of the wire rope during crane work can be prevented. Therefore, it is required to apply a tension load to the wire rope and to wind the wire rope tightly and tightly wound around the winch of the crane in order.

For that purpose, for example, in a wire rope having a large diameter such as 30 mm, the tension load is required to be 10 t or more.

[0004]

According to such a conventional technique, since a large load is applied to the wire rope that is pulled out, the rotation of the wooden drum is controlled with a large braking force. , The wire rope that is pulled out from the upper layer interrupts the lower layer of the wire rope that is wound in a multi-layered state on a drum made of wood, etc., causing a problem of scratching the wire rope. In the worst case, there is a problem that the interrupt is strong and cannot be unrolled.

Further, since a wooden drum is braked by a large braking force and further pulled by a large tension load, the drum such as a wooden body may be broken, which causes a problem that it cannot be unwound. Further, since the winch cannot be wound up with a sufficient tensile force, there is a problem that the winch is not firmly and firmly wound onto the winch and is in a slippery state.

[0006]

Therefore, according to the present invention, a spiral groove is formed on the inner side surface and an inner cylinder is fitted to an outer cylinder provided with a supply port and a discharge port for a wire rope, and the inner cylinder is rotatable. It is characterized in that it is supported and connected to the braking means, and the outer cylinder is fixed to the main body of the apparatus.

[0007]

Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 is an overall explanatory view, FIG. 2 is a sectional view of a main part, FIG. 3 is a perspective view of dismantling a main part, and FIG. 4 is a sectional explanatory view of an outer cylinder. In FIG. It is rotatably set to 2. The rotation table 2 is rotation-controlled by a rotation controller (not shown).

Reference numeral 3 is a wire rope wound around the drum 1 made of wood or the like, and 4 is a rope guide for guiding the wire rope 3 fed from the drum 1 made of wood or the like. 5
Is a control drum, and is composed of an inner cylinder 6 and an outer cylinder 7 as described below. The inner cylinder 6 is a cylinder whose both sides are closed, has a rotary shaft 8 at the center in the axial direction, a flange 9 for engagement is formed on one side, and a brake disc or a brake disk is formed on both sides or one side. A braked object 10 such as a brake shoe is provided.

The outer cylinder 7 has a diameter that fits and covers the inner cylinder 6, and spiral threads 11 are formed a plurality of times on the inner surface to form a spiral groove 12, and the wire rope 3 is formed in the spiral groove 12 on the cylinder body. A supply port 13 and a discharge port 14 for guiding are formed. Inner cylinder 6
Is fitted to the outer cylinder 7 thus configured, and the locking flange 15 is attached to the end of the inner cylinder 6 so that the outer cylinder 7 is positioned between the locking flange 15 and the flange 9 so as not to come off.

The gap between the outer peripheral surface of the inner cylinder 6 and the spiral blade 11 of the outer cylinder 7 is set so that the wire rope 3 does not pass therethrough. In this state, the inner cylinder 6 and the outer cylinder 7 are combined with each other, and the rotation shaft 8 of the inner cylinder 6 is supported by the bearing stand 16 so as to be rotatable.
0, and the outer cylinder 7 is fixed to the apparatus main body by the locking portion 17.

In the control drum 5 assembled in this way, the wire rope 3 guided by the wire guide 18 from the drum 1 made of wood or the like is inserted through the supply port 13 thereof, and the outer cylinder 7 is attached to the outer peripheral surface of the inner cylinder 6. It is wound along the spiral groove 12 and taken out from the discharge port 14, and its tip is set on a winch of a crane (not shown). The wire rope 3 set in this way is wound around the winch of a crane. At that time, the drum 1 made of wood or the like is braked and the inner cylinder 6 of the control drum 5 is braked via the braked body 10. In addition, the tensile force A applied to the wire rope 3 from the drum 1 made of wood or the like is smaller than the tensile force B applied to the wire rope 3 from the control drum 5, and the control drum 5 receives the pulling force of the winch. The tensile force is not directly transmitted to the drum 1 made of wood or the like.

This is because by applying proper braking to the inner cylinder 6 of the control drum 5, the wire rope 3 wound around the inner cylinder 6 several times with respect to the pulling force of the winch, the outer peripheral surface of the inner cylinder 6 The primary friction is generated by the contact friction with.
Further, the wire rope 3 has a spiral groove 12 of the outer cylinder 7.
According to the principle of the screw, the inner cylinder 6 is smoothly fed in accordance with the rotation of the inner cylinder 6, and at that time, the fixed spiral blade 1 is fixed.
Secondary tension is generated by the contact friction with 1.

Due to the primary and secondary contact friction, a large tension is applied to the pulling force of the winch, so that the winch can be wound tightly in close contact with the winch in order. Moreover, since the pulling force of the winch is not transmitted to the drum 1 made of wood or the like by the control drum 5, the wire rope 3 is not interrupted by the lower layer wound around the multi-layered drum 1 made of wood or the like.

Therefore, regarding the braking action of the wire rope 3 by the control drum 5, the braking ability of the inner cylinder 6 of the control drum 5 is of course the number of windings of the inner cylinder 6 of the control drum 5 and the spiral blade 11 of the outer cylinder 7. The contact length is a major factor in the braking action. In order to bring the wire rope 3 into close contact with the inner cylinder 6 immediately if necessary, a wire pressing roller 19 is provided in the spiral groove 12 of the supply port 13 of the outer cylinder 7 as shown in FIGS. 1 and 5. As a result, the pressing roller 19 makes the wire rope 3 closely contact with the outer peripheral surface of the inner cylinder 6, and even if the supply speed from the drum 1 such as wood changes, the pressing roller 19 keeps the inner cylinder constant. 6 Can be closely attached to the outer peripheral surface.

The pressing roller 19 is installed by providing an opening 20 in the outer cylinder 7 as shown in FIG.
In the structure in which a part of the pressing roller 19 is projected into the spiral groove 12, one end of the support member 21 to which the pressing roller 19 is attached is rotatably attached to the outer cylinder 7, and the other end is locked to the outer cylinder 7. It is preferable to make it possible to lock by means of 22 and to make it possible to adjust the pressing force of the pressing roller 19 by pressing the end portion of the support member 21 by means of this locking tool 22.

The inner cylinder 6 and the outer cylinder 7 of the control drum 5 described above are cylindrical bodies having the same size up to both ends, but they are not necessarily such cylindrical bodies, and are, for example, the outer cylinder shown in FIG. The shape of the inner cylinder may be a truncated cone, and the shape of the inner cylinder may be adjusted accordingly. Further, as in the case of the outer cylinder shown in FIG. 7, a shape of a truncated cone may be used. do it.

Further, in the above description, the outer cylinder has been described as an integral cylinder, but it may have a divided structure divided into two in the axial direction (a combined structure as shown in FIG. 4),
When divided, both ends are firmly locked, but the locked state is, for example, a structure in which the connecting part on one side is rotatably connected by a hinge and the other side is locked and connected to each other. It suffices if both connecting portions are locked and connected. With such a divided structure, the outer cylinder can be opened, so that the wire rope can be easily attached to the control drum 5.
In addition, the outer cylinder can be attached even to the inner cylinder having a drum-like shape with a narrow center.

In the above description, the wire rope is wound around the winch of the crane. However, the present invention is not limited to the winch of the crane. It is as effective as above in any case of winding on a winch.

[0019]

According to the present invention described in detail above, the inner cylinder is fitted to the outer cylinder having the spiral groove formed on the inner surface and the wire rope supply port and the discharge port, and the inner cylinder is rotatable. The wire rope, which is supplied from the supply port and wound around the inner cylinder, is supported by the outer cylinder and the outer cylinder of the inner cylinder whose rotation is controlled. A large pulling force can be obtained by both the contact friction of the contact friction and the contact friction with the spiral groove, which allows to remove the initial elongation of the wire rope and wind it tightly and tightly in order to form a tight winch. Have an effect.

Since the wire rope can be wound tightly around the winch, the wire rope does not cut into the layer overlaid on the winch even if a large tension is applied to the wire rope unwound from the winch. Becomes In addition, since the pulling force on the winding side is not transmitted to the wooden drum around which the wire rope is wound, the wire rope is interrupted between the wire ropes that are wound in multiple layers to create an irregular winding state or to become stuck. It has the effect of not becoming a state.

[Brief description of drawings]

FIG. 1 is an overall explanatory diagram showing a form example

FIG. 2 is a sectional view of a main part.

FIG. 3 is a perspective view of dismantling of essential parts

FIG. 4 is an explanatory sectional view of an outer cylinder.

FIG. 5 is an explanatory view of a state in which the wire pressing roller is attached.

FIG. 6 is an explanatory cross-sectional view when the outer cylinder has a truncated cone shape.

FIG. 7 is an explanatory cross-sectional view when the outer cylinder has a truncated cone shape.

[Explanation of symbols]

 1 Wooden Drum 2 Rotating Table 3 Wire Rope 5 Control Drum 6 Inner Cylinder 7 Outer Cylinder 10 Braked Object 11 Spiral Blade 12 Spiral Groove 13 Supply Port 14 Discharge Port 19 Presser Roller

─────────────────────────────────────────────────── ───

[Procedure amendment]

[Submission date] July 26, 1996

[Procedure amendment 1]

[Document name to be amended] Statement

[Correction target item name] 0001

[Correction method] Change

[Correction contents]

[0001]

The present invention relates to relates to a device for applying tension load to the new wire rope wound into device Wynn <br/> switch or the like crane.

[Procedure amendment 2]

[Document name to be amended] Statement

[Correction target item name] 0008

[Correction method] Change

[Correction contents]

[0008] 3 is a wire rope wound around the drum 1 of this wooden like. Reference numeral 5 is a control drum, which is composed of an inner cylinder 6 and an outer cylinder 7, as described below. The inner cylinder 6 is a cylinder whose both sides are closed, has a rotary shaft 8 at the center in the axial direction, a flange 9 for engagement is formed on one side, and a brake disc or a brake disk is formed on both sides or one side. A braked object 10 such as a brake shoe is provided.

Claims (4)

[Claims] 1. An inner cylinder is fitted to an outer cylinder having a spiral groove formed on the inner side surface and provided with a supply port and a discharge port for a wire rope,
A device for generating a tension load on a wire rope, characterized in that the inner cylinder is rotatably supported and connected to a braking means, and the outer cylinder is fixed to the apparatus main body. 2. The device for generating a tension load on a wire rope according to claim 1, wherein a spiral blade is provided a plurality of times on the inner surface of the outer cylinder to form a spiral groove. 3. A device for generating a tension load on a wire rope according to claim 1, wherein the outer cylinder is axially divided and engaged in a cylindrical shape. 4. The device for generating a tension load on a wire rope according to claim 1, wherein a wire pressing roller is provided in the spiral groove of the supply port of the outer cylinder.