KR101148846B1 - Device for manufacturing cable-laid, method for manufacturing cable-laid grommet thereof, and cable-laid grommet manufactured by it - Google Patents

Abstract

The apparatus for manufacturing a cable laid according to the present invention and a cable laid grommet using the same, a support provided in the main body, a rotating plate rotating in the front of the support, a bobbin provided to enable free rotation on the rotating plate, the back of the support The drive mechanism for rotating the rotating plate in the main body side sieve is provided, and the separation side sheave for supporting the wire rope connected in a closed loop structure opposed to the body side sheave is configured, thereby continuously rotating the wire rope cable laid grommets It can be produced, by minimizing the bending phenomenon of the wire rope, it is possible to produce a better product, has the effect of contributing to the improvement of productivity.

Wire Rope, Grommet, Sling, Sheave, Ohm

Description

Device for manufacturing cable laid, cable laid grommet manufacturing method using the same, cable laid grommet produced by the same {Device for manufacturing cable-laid, method for manufacturing cable-laid grommet, and cable-laid grommet manufactured by it}

The present invention relates to a cable laid manufacturing apparatus for producing a cable laid grommet (Cable Laid Grommet) used when lifting or lowering heavy goods such as cargo at the time of crane unloading operation, and a cable laid grommet manufacturing method using the same.

In general, cable laid grommets or cable laid slings are used as lifting means for unloading operations that require lifting and unloading of heavy goods such as cargo or machinery.

The cable laid grommets are formed in a single closed loop loop structure, and the cable laid slings are usually formed in a structure having an eye (EYE) at both ends.

These cable laid grommets and slings are made by twisting a wire rope into multiple strands.

The cable laid grommets are usually used with 50-100mm in diameter, and more than 100mm in size. Most of them are manufactured by hand using various tools. The productivity is very low, about two people per day, even when using a conventional mechanical device, the productivity is not significantly increased.

In addition, when the wire rope is manufactured by twisting the wire rope into a plurality of strands in the related art, when the cable laid grommets are manufactured by winding six wire ropes around the core core rope, the wire ropes in the first to third wire ropes enter into the core core rope. When the 4th to 6th wire rope comes out, a so-called 'pigtail phenomenon' appears, and when the load is applied using the cable laid grommets, the load is concentrated on the 1st to 3rd wire wire wound and the breakage occurs. There is a problem that the risk of safety accidents increases as the likelihood of increase.

In addition, when the cable laid grommets are conventionally produced using wire ropes, the wire rope rotates in the opposite direction to the twisting direction due to the inherent properties of the ropes. Thus, when the cable laid grommets are manufactured while winding the wire ropes in multiple strands, Due to the rotation of the rope caused by the production of the cable laid grommet problem is not easy.

The present invention has been made to solve the above problems, it is possible to produce a cable laid grommet while continuously rotating the wire rope to minimize the bending phenomenon of the product, it is possible to produce a better cable laid grommet, and at least It is an object of the present invention to provide a cable laid manufacturing apparatus and a cable laid grommet manufacturing method using the same, which can contribute to the productivity improvement of the personnel.

An apparatus for manufacturing a cable laid according to the present invention for realizing the above object includes: a vertical support stand; A rotating plate disposed in a direction parallel to the support in front of the support and rotating; A bobbin provided to allow free rotation at a position eccentric from a rotation center of the rotation plate, and to be mounted with a drum wound with a wire rope; A driving mechanism provided at the rear of the support to rotate the rotating plate; A rotating shaft for transmitting a driving force of the driving mechanism to the rotating plate; At least one body side sheave provided at a rear of the support to support a wire rope connected in a closed loop structure; And a spaced-side sheave rotatably supported at a distance spaced from the front of the rotating plate to support the wire rope connected in a closed loop structure to face the body-side sheave.

Here, the central part of the component, the rotating shaft and the rotating plate connected to the rotating shaft in the driving mechanism is formed with a hole through which the wire rope connected in a closed loop structure passes, and the rotating plate, the rotating shaft through which the wire rope passes, supports the rotating shaft. The structure of the drive mechanism connected to the structure, the rotating shaft is formed in an open structure from the hole through which the wire rope passes so as to be separated after manufacturing the cable laid grommets, characterized in that configured to be separated.

The support is provided with a base positioned in the horizontal direction, a vertical support vertically mounted on the base, on which the rotating plate and the rotating shaft are mounted, and between the base and the vertical support at the rear of the vertical support, to which the main body side sheave is mounted. It is preferable to include the sheave support to be.

Preferably, the rotating plate is provided with a weight mounting portion having a weight mounted thereon to adjust the balance from the center of rotation in the opposite position where the bobbin is installed.

The drive mechanism includes a motor supported by the support and a drive gear that is rotated by the motor, and a driven gear that is rotated by the drive gear in a state of being connected to the rotating shaft at the rear of the support, wherein the driven gear is It is preferable that a part is detachably constituted and assembled by the connecting plate.

The rotating shaft is rotatably supported by the support through the bushing, the rotating shaft, the bushing, the support is preferably formed to have an open structure to be separated after manufacturing the cable laid grommets.

The method for manufacturing a cable laid grommets using the cable laid manufacturing apparatus, the wire rope wound around the drum is released from the drum through the hole in the center of the separation side sheave, the main body side sheave, the rotating shaft, the rotating plate. A first step of producing a central core rope connected to the middle of the wire rope and continuing the closed loop structure; After the first step, while moving the central core rope in the direction of the separation side sheave on the rotating plate, while rotating the rotating plate, while unwinding the wire rope wound on the drum and wound around the core core rope to move toward the separation side sheave, A second step of giving a predetermined distance to the wire rope when supplying the wire rope to the core core rope; A third step of winding the wire rope into a plurality of strands while giving an ohmic to the core core rope through the second step, and then using an ohmic remover to even out the pitch of the cable laid grommets; After the third step, a fourth step of installing a first reinforcing member around the cable laid gromm of the portion where the front end and the end of the wire rope are located; After the fourth step, a portion of the cable laid grommets, which is not the portion where the first reinforcing member is installed, is set at both ends of the cable laid grommets, and after aging is performed at both ends by using a sizing rope, sizing And a fifth step of installing a second reinforcing member so as not to loosen the treated both ends.

After the third step, characterized in that it comprises a fourth step of sizing the front end and the end of the wire rope, respectively.

Here, in the second step, the rotation direction of the rotating plate is preferably rotated to be wound around the central core rope in a direction opposite to the twisting direction of the wire rope wound on the drum.

Between the second step and the third step, the position of the wire rope from the leading end to the predetermined length of the center core rope and the wire rope from the middle portion to the end of the wire rope of the strand wound last on the core core rope It is preferable to further include the step of proceeding with the replacement.

In addition, the cable laid grommets according to the present invention for achieving the above object is manufactured by the above-described cable laid grommets manufacturing method, 25% point and 75% point from either end of the cable laid grommet The first reinforcing member is installed, the first reinforcing member is characterized in that made of a synthetic resin material containing a general synthetic resin material or a fluorescent material so that the position can be easily identified with the naked eye.

The main problem solving means of the present invention as described above, will be described in more detail and clearly through examples such as 'details for the implementation of the invention', or the accompanying 'drawings' to be described below, wherein In addition to the main problem solving means as described above, various problem solving means according to the present invention will be further presented and described.

The apparatus for manufacturing cable laid according to the present invention and the method for manufacturing cable laid gromm using the same are manufactured to produce the cable laid grommets while continuously rotating the wire rope, thereby minimizing the bending phenomenon of the product and producing a better cable laid grommets. This makes it possible to produce a large amount with a minimum number of people, thereby providing an effect that can contribute to productivity improvement.

Hereinafter, exemplary embodiments of the present invention will be described with reference to the accompanying drawings.

1 is a side view showing the overall configuration of a cable laid manufacturing apparatus according to the present invention, Figures 2 and 3 are perspective views of the main body of the device according to the invention seen from the front and rear. 4 and 5 is a schematic view showing the separation state of the rotating shaft and the driven gear according to the invention, Figure 6 is a side view showing the wire rope is wound on the device of the present invention, Figure 7 using an ohm remover A perspective view showing a state in which ohms are removed. 8 is a view showing a cable laid in accordance with the present invention.

As illustrated in these drawings, the cable laid manufacturing apparatus according to the present invention includes a main body 10 and a spaced-side sheave 100 spaced apart from the main body 10.

The main body 10 includes a support 11 that is vertically erected, a rotation plate 20 disposed in front of the support 11 to rotate, a bobbin 30 provided on the rotation plate 20, and a support 11. The main body for supporting the wire rope (R) is provided at the rear of the support shaft 11, the rotating shaft 50 for transmitting the driving force of the driving mechanism 60, the driving mechanism 60 provided on the back of the support plate 11 It consists of a side sheave 70.

The spaced side sheave 100 is configured to support the wire rope R connected in an endless structure, that is, a closed loop structure, to face the body side sheave 70 at a position away from the body 10. .

As described above, in the cable laid manufacturing apparatus according to the present invention, the wire rope R wound around the drum 40 is separated from the drum 40 by the side sheave 100, the main body side sheave 70, and the rotation shaft 50. The cable laid while continuously winding the wire rope Rd provided from the drum 40 to the wire rope Rc connected in the closed loop structure while penetrating through the rotating plate 20 and connected in the closed loop structure. It is configured to produce a grommets and the like.

More specific operation of the device and the method of manufacturing the cable laid grommets will be described in detail below, and each component part constituting the device of the present invention described above will be described first.

First, the main body 10 will be described with reference to FIG. 1 and the like.

The support base 11 is a component for supporting the main body 10 in a specific space, and can be configured by changing its structure as appropriate depending on the implementation conditions.

The support 11 illustrated in the drawings of the present embodiment has a base 12 having a substantially circular structure positioned in a horizontal direction, and is vertically erected from the upper portion of the base 12 so that the rotating plate 20 and the rotating shaft ( 50 and a sheave support 15 provided between the base 12 and the vertical support 13 at the rear of the vertical support 13 to which the main body side sheave 70 is mounted. )

Here, the sheave support 15 is composed of a plate disposed in the front and rear direction, the bottom surface is fixed to the base 12 by welding or the like, the front surface is fixed to the vertical support 13 by welding or the like. In particular, the sieve support 15 is inclined when viewed from the front side, which is vertical when two main body side sieves 71 and 73 are installed in the sieve support 15, as shown in FIGS. 2 and 3. This is to support the wire rope passing through the outside of the support 13 and the wire rope passing through the center of the main body 10.

Rotating plate 20 is arranged in the direction parallel to the vertical support 13 in front of the vertical support 13 is configured to be supported by the vertical support 13 through the rotation shaft (50).

The rotating plate 20 may be formed in an approximately rhombic shape, as illustrated in the drawing, and a central portion thereof is formed with a hole 22 through which the wire rope R passes, and in one direction from the hole 22. Open openings 24 are formed to separate the cable laid grommets are manufactured.

In addition, the rotation plate 20 is provided with a weight mounting portion 26 on which the weight is mounted on the opposite side on which the bobbin 30 is installed to adjust the balance from the rotation center. In the drawing of the present embodiment, the weight mounting part 26 illustrates a structure consisting of a hole, and according to the load of the drum 40 mounted on the bobbin 30, the weight 28 is fitted to the hole to rotate the entire rotating plate ( 20) to adjust the balance.

The bobbin 30 is configured such that the drum 40 on which the wire rope Rd is wound may be mounted, so that the bobbin 30 may be freely rotated at an eccentric position in the rotation center of the rotation plate 20.

That is, the bobbin 30 has a bobbin shaft 33 which is freely rotated on the rotating plate 20, a bobbin frame 31 connected to the bobbin shaft 33 in a 'c' shape, and the bobbin frame 31. The drum mounting shaft 35 is installed to penetrate the drum 40. Here, the bobbin shaft 33 may be rotatably installed on the rotating plate 20 through a bearing or the like, and the drum mounting shaft 35 may be mounted to the bobbin frame 31 to mount or detach the drum 40. And may be configured to be detachable.

The bobbin 30 is configured to revolve around the rotation shaft 50 when the rotating plate 20 rotates, and also to rotate about the bobbin shaft 33.

The drive mechanism 60 is configured to be connected to the rotation shaft 50 at the rear of the support 11 to drive the rotation plate 20, this embodiment, referring to Figures 1 and 3, the support ( 11 by the motor 61 supported by the motor 61 and the drive gear 63 which rotates by this motor 61, and the said drive gear 63 in the state connected with the said rotating shaft 50 in the back of the support 11 The structure which consists of the following driven gear 65 is illustrated.

The drive mechanism 60 can be configured in various ways using a well-known driving device capable of rotationally driving the rotation shaft 50 in addition to the configuration illustrated in the drawings.

In FIG. 3, reference numeral 17 denotes a motor support for supporting the motor 61.

On the other hand, the driven gear 65 has a rope hole 66 (see Fig. 3) is formed so that the wire rope (Rc) passes through the center portion, the portion 65a of the gear is configured to be detachable and coupled. That is, in the driven gear 65 as a whole, the wire rope R in a state where the portion 65a is divided around the rope hole 66 and assembled together to the driven gear 65 by the connecting plate 67. When pulling out, the part 65a of the gear is separated by disassembling the connecting plate 67, so that the wire rope can be pulled out.

The rotary shaft 50 is formed in a cylindrical structure and is rotatably supported in the cylindrical bushing 55 provided in the vertical support 13.

Here, as shown in FIG. 4, the opening shafts 51 and 56 are formed to extend in the axial direction so that the wire rope R can be pulled out as shown in FIG. 4. And the vertical support 13 is also formed on one side, preferably the upper surface side 13a is formed.

Therefore, after completing the cable laid grommets using the wire rope (R), in order to remove the cable laid grommets, as shown in Figure 4, the opening 24 of the rotating plate 20 and the rotating shaft 50 After the 51 is set upward, the opening 51 of the rotation shaft 50, the opening 56 of the bushing 55, the opening 24 of the rotating plate 20 and the vertical support 13 ( Through 13a). Of course, the portion of the driven gear 65 (65a) is also removed as shown in Figure 5 the cable laid grommet pulled out.

1 to 3, the main body side sheave 70 is rotatably installed on the sheave support 15 to support one side of the wire rope Rc connected in a closed loop structure.

In the drawing of this embodiment, the figure which comprised two main body side sheaves 70 was illustrated. The lower sheave 71 is installed to change the direction of movement upward while supporting the wire rope R moving in the spaced sheave 100, and the upper sheave 73 is moved via the lower sheave 71. It is installed to move the wire rope in the direction of the spaced sheave 100 again. At this time, the wire rope R via the lower sheave 71 passes through the central gears of the driven gear 65, the rotation shaft 50, and the rotation plate 20 of the drive mechanism 60.

Here, the lower sheave 71 is supported by the sheave support 15 in a state that is further protruded to the side of the vertical support 13, the upper sheave 73 is a wire rope (R) to the hole in the center of the rotation shaft 50, etc. It is configured to be supported by the sheave support 15 in a position that has entered further than the lower sheave 71 for delivery. Therefore, the sheave support 15 supporting the lower sheave 71 and the upper sheave 73 is disposed to be inclined with respect to the vertical direction as described above.

Next, referring to FIG. 1, the spaced-side sheave 100 is installed to support the other side of the wire rope R moving in a closed loop structure. Although only one is illustrated, two or more may be configured depending on the implementation conditions.

The spaced side sheave 100 may be configured to be structurally separated from the main body 10, so that the wire rope R may continuously rotate in a closed loop structure in a state supported by the support structure 110. Support.

The spaced-side sheave 100 is installed on the rail / fixed structure 115 which can move the support structure 110 and fix the position thereof, and is configured to adjust a distance (separation distance) away from the main body 10. It is preferred to produce the cable laid grommets with their positions properly adjusted according to the overall length of the cable laid grommets to be produced. Of course, it is also possible to configure so that the separation distance can be adjusted by moving the main body 10, not the separation side sheave 100.

In addition, the separation sheave 100 may be provided with a driving mechanism to rotate the wire rope (R) connected in a closed loop structure. As shown in FIG. 1, the driving mechanism may have a structure in which the belt 121 is connected between the spaced side sheaves 100 in the driving motor 120. Of course, it is also possible to configure the wire rope R to rotate by moving any one of the main body side sheaves 71 and 73 instead of the method of driving the spaced side sheave 100.

The cable laid grommets manufacturing method according to the present invention using the cable laid manufacturing apparatus of the present invention configured as described above will be described.

First, the wire rope R is wound around the drum 40 by calculating the total usage amount of the wire rope R necessary for manufacturing the cable laid grommets.

The drum 40 wound with the necessary wire rope R is mounted on the bobbin 30 of the main body 10. At this time, the drum 40 is inserted into the bobbin frame 31 while the drum mounting shaft 35 of the bobbin 30 is removed, and then the drum mounting shaft 35 is coupled to the bobbin frame 31 and the drum 40. The drum 40 is mounted on the bobbin 30.

Next, referring to FIG. 1, the wire rope R wound around the drum 40 is released to turn the first starting portion (hereinafter referred to as “tip portion”) from the spaced side sheave 100 and the lower sheave 71. After passing through the upper sheave 73 one after another, in the middle of the wire rope R released from the drum 40 through the driven gear 65, the rotating shaft 50, and the center hole of the rotating plate 20 Connect the center core rope (Rc) to connect the closed loop structure.

At this time, the separation distance between the separation side sheave 100 and the main body 10 is set by the total length of the cable laid grommets to be manufactured. In addition, by connecting the front end portion and the middle portion of the wire rope (R) with a clip (C) to connect the wire rope (R) in a closed loop structure. It is preferable to fasten two or more clips C or more.

Alternatively, the wire rope R is released from the drum 40 by twice the total length of the cable laid grommets, and the tip is fixed with a clip C in the middle of the wire rope R, so that the core core rope has a closed loop structure. After producing Rc, it is also possible to mount the center core rope Rc on the side sheave 100 and the main body 10 side after marking the pitch distance to the center core rope Rc.

As described above, when the center core rope Rc of the closed loop structure is connected to the separation side sheave 100 and the main body 10 side, the rotating plate of the main body 10 while rotating driving the separation side sheave 100 ( When the center core rope Rc is moved in the direction of the spaced sheave 100 at 20, and the motor 61 of the drive mechanism is rotated to rotate the rotating plate 20, the wire wound on the drum 40 As the rope Rd is released, the rope Rd is wound around the core core rope Rc and moved toward the spaced side sheave 100.

At this time, the rotation direction of the rotating plate 20 is preferably rotated so as to be wound around the central core rope (Rc) in the direction opposite to the twisting direction of the wire rope (Rd) wound on the drum (40). This is because the inherent property of the wire rope rotates in the opposite direction of the twisting direction, when the wire rope Rd is twisted additionally while being twisted by the central core rope Rc, the direction opposite to the twisting direction of the wire rope Rd This is to prevent the rotation from occurring while the ropes are all twisted.

In addition, while the wire rope Rd is additionally supplied to the core core rope Rc, it is preferable to give the additional wire rope R a certain degree, that is, ohm, wherein the size of the ohm is approximately an additional wire rope ( It is preferable to give an extra length twice the pitch that Rd is wound on the central core rope Rc.

6 shows a state in which the wire rope Rd is wound in addition to the center core rope Rc.

Through the above process, a total of six wire ropes (R) are wound around the core core rope (Rc) to produce a single cable (hereinafter also referred to as '1 + 6 cable'). That is, referring to the drawings, the wire rope provided from the drum 40 while moving (rotating) the central core rope Rc connected in a closed loop structure between the spaced-side sheave 100 and the main body 10 in a counterclockwise direction ( The wire rope Rd is wound while R is continuously rotated so as to be wound six times in total through the same process as in FIG. 6 around the center core rope Rc.

At this time, while winding a total of six wire rope (Rd) Ohm in the order of winding to the core core rope (Rc), it is preferable to give only the first wire rope (Rd) to the fifth wire rope (Rd).

At this time, when the unit rope is opened while the wire rope Rd provided from the drum 40 is wound around the center core rope Rc, the wire rope is formed around the bobbin shaft 33 by the drum 40 and the bobbin 30. It is preferable to wind one turn in the twisting direction of the wire rope in the opposite direction to be opened. That is, in FIG. 6, the wire rope Rd is wound around the center core rope Rc while the drum 40 is rotated (idle) counterclockwise. When the state of the wire rope Rd is opened, the drum 40 and The bobbin 30 is rotated (rotated) in the opposite direction to produce a 1 + 6 cable to eliminate the spread of the wire rope. At this time, if the total length of the wire rope (R) is 21m it can be rotated about eight times. This is to counteract the occurrence of + kink or -kink by rotating in one direction when the wire ropes R are all twisted. This solves the cable rotation.

After the above process, a total of six wire ropes Rd are wound around the core core rope Rc to produce a 1 + 6 cable, and the wire rope Rd provided by the drum 40 is cut. At this time, the wire rope (Rd) is preferably cut to leave the amount necessary for the center replacement operation to be described below. Subsequently, an operation of leveling the pitch of the cable laid gromm is performed by using the ohmic remover 210 as illustrated in FIG. 7.

That is, when the ohm eliminator 210 is installed around the 1 + 6 cable and the cable of the closed loop structure is rotated while driving the separation side sheave 100, the wire rope wound around the center core rope Rc ( R) is gradually pushed backwards and shunts to the last sixth wire rope (R) to remove ohms. Rotating a 1 + 6 cable in this manner about three full turns eliminates ohms, resulting in a uniform pitch throughout the 1 + 6 cable.

Here, referring to FIG. 7, the ohmic remover 210 processes a urethane roller or a round bar into two parts so that a 1 + 6 cable can pass through the inside thereof, and inserts a cable therein and fastens with bolts 215 on both sides. Is made of. When removing the ohmic of the cable using the ohmic remover 210, it is preferable to use in the state supported by the support 220 so as not to be pushed.

Thereafter, the clip C is dismantled and the center replacement operation is performed. Referring to FIG. 6, the clip C of the leading end is released, the leading end of the central core rope Rc is pulled out from the center, and the sixth connected at the same time. Insert the wire rope (R) into the part from which the core core rope (Rc) is removed, and the rope replacement work is performed in some sections of the entire 1 + 6 cable. Therefore, one cable is manufactured in a state where the position of each other is changed from the front end portion of the center core rope Rc to a predetermined length and from the middle portion to the end portion of the last sixth wire rope R.

At this time, the work of removing the tip of the center core rope (Rc) from the center is performed manually, and the work of inserting the center of the sixth wire rope at the same time while continuously rotating the entire 1 + 6 cable while driving the separation side sheave (100) It is preferable to proceed.

The cable laid grommets having the annular structure as described above are manufactured, and then separated from the cable laid manufacturing apparatus. Referring to FIG. 8, the first reinforcing member 2 is installed around the cable laid gromm at the portion where the front end and the end of the wire rope constituting the cable laid grommette G are positioned. At this time, the first reinforcing member (2) can be processed by wrapping with a wire rope or a plastic processing method that is injected to wrap the cable with a synthetic resin or the like. Preferably, the method of processing the plasmon is good, in which the plasmcom is preferably formed of synthetic resin such as red or yellow so that the installation position of the first reinforcing member 2 can be easily identified with the naked eye. It is preferably composed of a synthetic resin material containing a fluorescent (glow) material. This is to enable the operator to avoid the part where the tip and the end of the wire rope are located when using the cable laid grommets (G). The purpose of the present invention is to allow the display portion to be retained for a long time, rather than painting with paint or the like, by a plasma treatment.

In addition, a sizing treatment operation is performed on both ends of the cable laid grommets G (both ends when the loop is folded as shown in FIG. 8). At this time, the aging position is performed at the optimum position for lifting the cable laid grommets (G), which is the position where the front end and the end of the unit wire rope, that is, the position where the first reinforcing member 2 is installed Are positions at both ends with 25% points (25% and 75% from one end) at both ends of the cable laid grommet (G), respectively.

In the aging treatment operation, after winding the saging rope 3 in a predetermined section at both ends of the cable laid grommets G, the second reinforcing member 5 is placed at both ends of the sizing rope 3 so that the sizing rope is not loosened. Install. It is preferable that the second reinforcing member 5 is also subjected to a plasmo treatment like the first reinforcing member 2.

As described above, the technical ideas described in the embodiments of the present invention may be implemented independently, or may be implemented in combination with each other. While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is evident that many alternatives, modifications, and variations will be apparent to those skilled in the art. It is possible. Accordingly, the technical scope of the present invention should be determined by the appended claims.

1 is a side view showing the overall configuration of a cable laid manufacturing apparatus according to the present invention,

Figure 2 is a perspective view of the main body of the cable laid manufacturing apparatus according to the present invention from the front,

Figure 3 is a perspective view of the main body of the cable laid manufacturing apparatus according to the present invention,

Figure 4 is a schematic view showing a structure that can separate the wire rope (cable) from the rotary shaft, etc. according to the present invention,

5 is a schematic view showing a structure capable of separating a wire rope (cable) from a driven gear according to the present invention,

Figure 6 is a side view showing a state in which the wire rope is further wound on the core core rope using the device according to the invention,

7 is a perspective view of an essential part showing a state in which the wire rope is removed using an ohmic remover in the present invention;

8 is a diagram illustrating a cable laid grommets according to the present invention.

Claims (9)

Vertically supported supports; A rotating plate disposed in a direction parallel to the support in front of the support and rotating; A bobbin provided to allow free rotation at a position eccentric from a rotation center of the rotation plate, and to be mounted with a drum wound with a wire rope; A driving mechanism provided at the rear of the support to rotate the rotating plate; A rotating shaft for transmitting a driving force of the driving mechanism to the rotating plate; At least one body side sheave provided at a rear of the support to support a wire rope connected in a closed loop structure; It comprises a spaced side sheave rotatably supported at a position spaced from the front of the rotating plate to support a wire rope connected in a closed loop structure to face the body side sheave, The drive mechanism includes a motor supported by the support, a drive gear rotated by the motor, and a driven gear rotated by the drive gear in a state connected to the rotation shaft at the rear of the support. The center of the driven gear, the rotating shaft, the rotating plate connected to the rotating shaft is formed with a hole for the wire rope connected in a closed loop structure to pass through, The rotating plate through which the wire rope passes, the rotating shaft, the structure supporting the rotating shaft, and the driven gear of the drive mechanism connected to the rotating shaft are open from the hole through which the wire rope passes so as to be separated after the cable laid grommets are manufactured. Cable laid manufacturing apparatus, characterized in that formed or configured to be separated. The method according to claim 1, The support is provided with a base positioned in the horizontal direction, a vertical support vertically mounted on the base, on which the rotating plate and the rotating shaft are mounted, and between the base and the vertical support at the rear of the vertical support, to which the main body side sheave is mounted. Cable laid manufacturing apparatus characterized in that it comprises a sheave support. The method according to claim 1, The rotating plate, the cable laid manufacturing apparatus, characterized in that the weight mounting portion is provided with a weight (weight) to be able to adjust the balance from the center of rotation in the opposite position where the bobbin is installed. The method according to claim 1, The driven gear is a cable laid manufacturing apparatus, characterized in that the part is detachably configured, assembled by a connecting plate. The method according to claim 1, The rotating shaft is rotatably supported through the bushing to the support, The rotating shaft, the bushing, the support is a cable laid manufacturing apparatus, characterized in that it is formed to have an open structure to be separated after manufacturing the cable laid grommets. In the method of manufacturing a cable laid grommets using the cable laid manufacturing apparatus according to any one of claims 1 to 5, Unwinding the wire rope wound on the drum to connect to the middle of the wire rope released from the drum through the hole in the center of the separation side sheave, the main body side sheave, the rotating shaft, the rotating plate to produce a central core rope connected to the closed loop structure A first step; After the first step, while moving the central core rope in the direction of the separation side sheave on the rotating plate, while rotating the rotating plate, while unwinding the wire rope wound on the drum and wound around the core core rope to move toward the separation side sheave, A second step of giving a predetermined distance to the wire rope when supplying the wire rope to the core core rope; A third step of winding the wire rope into a plurality of strands while giving an ohmic to the core core rope through the second step, and then using an ohmic remover to even out the pitch of the cable laid grommets; After the third step, a fourth step of installing a first reinforcing member around the cable laid gromm of the portion where the front end and the end of the wire rope are located; A fifth reinforcing member to set both ends of the cable laid grommets after the fourth step, and to provide a second reinforcing member so as not to loosen the both ends of the sintered ends after the aging treatment is performed using a sizing rope at both ends. Cable laid grommets manufacturing method comprising the steps. The method of claim 6, In the second step, the rotation direction of the rotating plate, the cable laid grommets manufacturing method characterized in that the rotating so as to be wound around the core core rope in a direction opposite to the twisting direction of the wire rope wound on the drum. delete Manufactured by the cable laid grommet manufacturing method according to claim 6, wherein the first reinforcing member is installed at 25% and 75% from either end of the cable laid grommet, the first reinforcing member is easily visible Cable laid grommets comprising a synthetic resin material or a synthetic resin material containing a fluorescent material so as to determine the position.

Images