KR810000458B1 - Pulling eye assembly - Google Patents

Abstract

A pulling eye assembly for attachment to an end of the cable is composed of an elongated metal sleeve (12) open at one end to accommodate the cable and closed at the other end. A spigot(20), having a plurality of barbs(24) spaced throughout its length, secures to the block and is positioned concentrically within the sleeve. A pulling eye(32) is interconnected with the spigot.

Description

Tow Ring Assembly

1 is a perspective view of a tow ring assembly with a portion cut away.

2 is a perspective view of a traction ring assembly similar to that of FIG. 1 showing an annular recess in the position between the protrusions of the spigot.

3 is a perspective view showing a part of the incision of a different type of pulling eye (pulling eye).

4 is a cross-sectional view of the tow ring shown in FIG. 3 connected to a sleeve.

FIG. 5 is a perspective view of a ready state for connecting the cable of the tow ring communication cable of FIG. 1 to pull the cable linearly; FIG.

The present invention relates to a pulling eye assembly for pulling a cable after connecting to a large end of the communication cable of the present invention (hereinafter referred to as a cable end). In particular, it relates to a towing ring assembly which allows a quick fixation at the end of a communication cable and then the cable can be towed linearly in the air underground or on a pole.

Devices for connecting cables are already known but commercially available devices do not satisfactorily fulfill the functions described above, an example of which can be found in cave US Pat. No. 3,522,961.

It is an object of the present invention to provide a cable traction ring assembly, which is relatively inexpensive and can be easily fixed to the end of the cable as well as having a very high strength with respect to the cable end. It can be applied in the middle. The use of the tow hook assembly of the present invention eliminates the need for frequent cable connections because it is able to tow very long and heavy cables, and as a result, the need for time, labor and winding work can be reduced. Will be. Also provided is a means for sealing the cable ends during underground cabling of the present invention.

In the broadest aspect of the invention, this relates to a traction ring assembly that is secured to the final end of the communication cable. The assembly consists of an elongated metal sleeve with one end open and the other end sealed to secure it to the cable end. The block member is mounted to the sealing end of the sleeve, and the center rod, which forms a plurality of annular protrusions at regular intervals over the entire length, is fixed to the block and positioned at the center of the sleeve.

The towing ring is connected to the center bar and is located outside the sealing end of the sleeve, which allows the sleeve to be looped between the ridges formed in the center bar when the center bar is inserted into the cable end. It is positioned annularly between and the wall.

The present invention will be described in detail with reference to the accompanying drawings.

The traction ring assembly shown in FIG. 1 has a sleeve 12, which is preferably formed of a thin walled steel tubing with a constant diameter and of sufficient length to make the necessary connection with the cable end.

For example, the inside diameter of this sleeve is about 1 3/8 inch. As also shown in FIG. 1, one end of the sleeve is open so that one end of the communication cable can be inserted and the other end is sealed.

The diameter of the sleeve sealing end may be equal to the diameter of the open end, but preferably this sealing end is inclined as shown by reference numeral 16, and the block member 18 is fixed to this sealing end 16. The screw member is formed in the block member 18 to be screwed together with the screw 22 formed at one end of the metal rod or the center rod 20, and the outer end thereof is extended to the outside of the sealing end. The central rod 20 is located at the center of the sleeve and extends substantially the same as the entire inner length of the sleeve. As shown in FIG. 1, the central rod 20 has a plurality of protrusions 24 protruding over the battlefield. This protrusion can be formed integrally with the center bar or can be fixed to the center bar by a method such as welding. Moreover, the protrusions 24 are the inclined surface 26 which faces the direction of a cable end part, and the plane 28 which is the same as the direction to pull. A sharply inclined tip 30 was formed at the end of the central rod far from the sealing end of the sleeve. The other end of the center rod 20 which extends through the sleeve sealing end and the blocking pin is fixed to the traction ring 32 of a suitable structure, and the traction ring 32 is threaded at the end of the center rod 20. And a gap formed by forming a screw in the block member 18 as necessary, and a sealant 34 and a washer made of silicon rubber between the sealing end of the sleeve 12 and the traction ring 32. 36) or other equivalent materials thereof. As another example of another method not shown, a lock nut may be screwed into the space between the sealing end of the sleeve 12 and the traction ring 32.

As shown in FIG. 1, the end 30 of the center rod 20 is inserted into the end of the communication cable. It should be noted here that no lead at the center of the cable is removed and only the position is shifted by the end of the center rod.

After the cable end is inserted into the sleeve and the center rod, the cable end is connected to the block member 18 as shown in FIG. 2, and then the sleeve 12 is indicated by the number 38 in FIG. Likewise, throughout the entire length of the traction ring assembly, an annular recess is inserted between the block member and the first protrusion and also between all of these protrusions. This recessed part compresses the cable C made of the conductive wire and the insulation coating around the center bar 20 to deform the communication wire. Therefore, the depth of this recess is determined by the overall cross-sectional area of the communication cable, where the compressive force on the wire must remain at the tensile strength level of pure copper, which theoretically did not cause deformation of the wire itself, and of course the copper tensile strength is a complete tow ring assembly. Must be greater than the compression force so that it does not disconnect from the communication cable (C).

3 and 4, the preferred form of the traction ring is shown where the traction ring 40 is formed integrally with the block member 42. As shown in FIG. As an example, the sleeve 44 is welded to the block member 42 at an angled edge 46, and the block member 42 constitutes a sealing end of the sleeve. In the block member 42, a screw hole is drilled at the position of the number 48 so that the screw thread is screwed with the screw of the center rod 50, and the center rod 50 forms an air passage 52 in the entire length of the block member 42. Communication with the air passage 54 is made.

The air valve 56 and passage 54 shown in FIGS. 3 and 4 may also be applied to the assembly shown in FIGS. It is often necessary to press the ends of the cable to keep the lines in the sleeve in a uniform form without breaking. In addition, pressurization prevents moisture from penetrating the cable ends, and it is very important to pressurize it especially when the cable is submerged during underground work. This pressurization method is to put air through the valve 56 and the injected air is diffused throughout the center bar and then put through the cable end.

The tow ring assembly shown in FIG. 1 is shown in FIG. 5 as a completed form, which is fixed to the cable C and can be towed.

Claims (1)

As shown and described in detail herein, in forming a traction ring assembly for fixing to one end of the communication cable, one end of the elongated sleeve 44 is opened so that one end of the communication cable C can be inserted. The other end is sealed by welding the block member 42, but the center rod 50, which protrudes several annular protrusions 24, is screwed to the block member 42 to be positioned on the inner center line of the sleeve 44. Traction ring assembly by forming a traction ring 40 on the outside of the block member (42).

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