KR102641122B1 - Cable connecting device - Google Patents

Abstract

The present invention relates to a cable connection device that can be miniaturized and improves construction quality. It has a hollow portion through which a first cable is inserted on one side and a second cable can be inserted on the other side, and is penetrated in a direction perpendicular to the hollow portion to form a female thread. A cable connection member provided with a screw groove having a mountain formed thereon, a fastening member screwed into the screw groove of the cable connection material to fasten and secure the first cable and the second cable to the cable connection material, and the fastening member to be fastened to the screw groove. Includes a fastening tool that rotates the member. With this configuration, it can be miniaturized and no construction debris is generated, thereby improving construction quality.

Description

Cable connecting device {CABLE CONNECTING DEVICE}

The present invention relates to a cable connection device, and more specifically, to a cable connection device that can be miniaturized and improve construction quality.

In general, the underground distribution lines that make up the distribution lines are impossible to produce, package, and transport the wires that can make up the entire line, so generally, the cable length required for connection is ordered and the cables are connected to the required length to form the distribution line. , Wire connection connects two cut wires using a straight connecting material.

Figure 1 is a diagram schematically showing a configuration for connecting conventional electric wires.

Referring to Figure 1, conventionally, after inserting the wires (C) that need to be connected into both ends of the straight connecting material (10), bolts (20) are fastened to the straight connecting material (10) to connect the two wires (C). The ends are connected physically and electrically.

In this way, when connecting wires in the conventional method, the head 21 of the bolt 20 of the straight connecting material 10 is rotated using a wrench 30 to connect the wire C to the straight connecting material 10. In the process of rotating the head 21 of the bolt 20 using the wrench 30, the head 21 of the bolt 20 is worn and metal powder falls, creating construction debris. There is a problem that arises.

In addition, since the head 21 of the bolt 20 must be rotated while inserted into the wrench 30, the gap between the bolts 20 can secure space for driving the wrench 30. There is a problem in that it takes up a lot of space because it has to be formed at regular intervals.

In addition, there is a problem in that the head 21 of the bolt 20 protrudes outside the straight connecting member 10 and takes up a lot of space.

Accordingly, for miniaturization, a bolt 20 in which only the head 21 falls off when the head 21 of the bolt 20 is rotated above a certain torque has been developed. In other words, when the bolt 20 is rotated to fasten the wire C to the straight connecting member 10 and then further rotated, only the head 21 is removed, preventing the part from taking up space.

However, in this case, there is a problem in that as the head 21 falls off, more metal powder falls and a lot of construction debris is generated.

The present invention was created to solve the above problems, and its purpose is to provide a cable connection device that can be miniaturized and improves construction quality by not generating construction debris.

In order to achieve the above object, a cable connection device according to a preferred embodiment of the present invention has a hollow portion through which a first cable is inserted on one side and a second cable is inserted on the other side, and penetrates in a direction perpendicular to the hollow portion. A cable connection material provided with a screw groove formed with a female thread; a fastening member screwed into a screw groove of the cable connection member to fasten and secure the first cable and the second cable to the cable connection member; and a fastening tool that rotates the fastening member so that it fastens to the screw groove.

As an example, the cable connection material includes a straight connection material body; a first hollow portion inserted inward from one end of the connecting material body; a second hollow portion inserted inward from the other end of the connecting member body; a blocking wall blocking between the first hollow part and the second hollow part; At least one first screw groove is formed to penetrate the first hollow portion on the outer peripheral surface of the connection material body and has a female thread formed on the inner peripheral surface; And at least one second screw groove is formed, which is formed to penetrate the second hollow portion on the outer peripheral surface of the connection material body, and has a female thread formed on the inner peripheral surface.

Also, when the fastening member is rotated by the fastening tool, the entire body can be positioned inside the cable connection member.

To this end, the fastening member includes: a fastening member body formed in a cylindrical shape; a male thread formed on an outer peripheral surface of one side of the fastening member body and screwed to a thread formed in the thread groove; and a fastening groove formed in the shape of a polygonal groove inward from the other end surface of the fastening member body, and through which the fastening tool is fastened to receive rotational force.

The fastening tool includes a wrench part fastened to the fastening member; and a rotating part to which the wrench part is fastened and to rotate the wrench part.

And, the fastening tool includes a sensor unit that measures a torque at which the wrench unit rotates by the rotating unit; and a display unit that displays the torque measured by the sensor unit.

In addition, the fastening tool may include an operation unit provided on the display unit and capable of setting a target torque value; and a notification unit that notifies the user to recognize when the rotation unit rotates the wrench unit and reaches the target torque value.

Alternatively, the fastening tool may include a torque transmission unit that is provided between the wrench unit and the rotating unit and transmits rotational force up to a set maximum torque value, and does not transmit rotational force when the set maximum torque value is exceeded. .

As an example, the torque transmission unit may include a first rotating unit that is fastened to the wrench unit and rotates together; and a second rotating part that is fastened to the rotating part and rotates together, and is disposed around the first rotating part and is in contact with the first rotating part to have a predetermined frictional force.

For example, the torque transmitting unit may be configured to set the maximum static friction force between the first rotating unit and the second rotating unit to a value corresponding to the set maximum torque value.

According to the cable connection device according to the present invention, it is possible to achieve the effect of improving construction quality by enabling miniaturization and not generating construction debris.

Figure 1 is a diagram schematically showing a configuration for connecting conventional wires.
Figure 2 is a diagram schematically showing a cable connection device according to an embodiment of the present invention;
Figure 3 is a perspective view schematically showing a fastening tool extracted from a cable connection device according to an embodiment of the present invention;
Figure 4 is a diagram schematically showing a state in which a cable is connected using a cable connection device according to an embodiment of the present invention;
Figure 5 is a cross-sectional view schematically showing another embodiment of a fastening tool in a cable connection device according to an embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the attached drawings.

Since the present invention can make various changes and have various embodiments, specific embodiments will be illustrated in the drawings and described in detail in the detailed description. This is not intended to limit the present invention to specific embodiments, and should be interpreted as including all changes, equivalents, and substitutes included in the spirit and technical scope of the present invention.

The terms used in this application are only used to describe specific embodiments and are not intended to limit the invention. Singular expressions may include plural expressions, unless the context clearly indicates otherwise.

Unless otherwise defined, all terms used herein, including technical or scientific terms, may have the same meaning as commonly understood by a person of ordinary skill in the technical field to which the present invention pertains. Terms defined in commonly used dictionaries can be interpreted as having meanings consistent with the meanings they have in the context of related technologies, and unless clearly defined in this application, are interpreted as having an ideal or excessively formal meaning. It may not work.

Hereinafter, specific embodiments of the present invention will be described with reference to the attached drawings.

Figure 2 is a diagram schematically showing a cable connection device according to an embodiment of the present invention, Figure 3 is a perspective view schematically showing a fastening tool extracted from the cable connection device, and Figure 4 is a diagram showing the cable connection device. This is a diagram schematically showing a state in which a cable is connected using , and Figure 5 is a cross-sectional view schematically showing another embodiment of the fastening tool.

Referring to Figures 2 to 5, the cable connection device 100 according to an embodiment of the present invention includes a cable connection member 110 into which a cable is inserted, and a fastening member for fastening and fixing the cable to the cable connection material 110 ( 120), and a fastening tool 130 for fastening the fastening member 120 to the cable connection material 110.

The cable connector 110 has hollow parts 112 and 113 into which the first cable C1 is inserted on one side and the second cable C2 is inserted on the other side, and is perpendicular to the hollow parts 112 and 113. Screw grooves 115 and 116 penetrating in one direction and forming female threads are provided.

More specifically, the cable connection material 110 includes a straight connection material body 111, a first hollow portion 112 inserted inward from one end of the connection material body 111, and the connection material body 111. At least one second hollow part 113 is inserted inward from the other end of the and a blocking wall 114 is formed to block between the first hollow part 112 and the second hollow part 113. A first screw groove 115 formed on the outer peripheral surface of the connecting material body 111 to penetrate the first hollow portion 112 and having a female thread formed on the inner peripheral surface, and at least one first screw groove 115 formed on the outer peripheral surface of the connecting material body 111 It may be formed to penetrate the second hollow portion 113 and include a second screw groove 116 having a female thread formed on the inner peripheral surface.

With this configuration, the first cable (C1) among the pair of cables to be connected to each other is inserted into the first hollow portion 112 and then the fastening member 120 is fastened to the first screw groove 115. The fastening member 120 may fasten the first cable C1 by tightly fixing it to the connecting material body 111.

Then, among the pair of cables to be connected to each other, a second cable (C2) is inserted into the second hollow portion 113, and then the fastening member 120 is fastened to the second screw groove 116 to secure the fastening member 120. (120) can be fastened by tightly fixing the second cable (C2) to the connection material body (111).

Through this, the first cable (C1) and the second cable (C2) can be electrically and mechanically connected.

In addition, the blocking wall 114 is formed to block the first hollow part 112 and the second hollow part 113 without communicating with them.

Through this, the first cable C1 inserted through the first hollow part 112 is inserted to the inner end of the first hollow part 112, and the end of the first cable C1 is the blocking wall ( 114), it can be seen that it is no longer moving.

In addition, the second cable C2 inserted through the second hollow part 113 is also inserted to the inner end of the second hollow part 113, and the end of the second cable C2 is connected to the blocking wall 114. ), it can be seen that it is no longer moving.

In addition, each of the first screw groove 115 and the second screw groove 116 is formed along the longitudinal direction of the connection material body 111, and at least one or more may be formed.

That is, in order to improve the fastening force of the first cable (C1) and the second cable (C2) inserted into the first hollow portion 112 and the second hollow portion, respectively, a plurality of cables may be formed.

In the drawing, the first screw groove 115 and the second screw groove 116 are shown to be formed in two each, but this is not limited to this, and the first screw groove may be adjusted depending on the installation location and the thickness and material of the cable to be installed. It can be manufactured to form one or two or more grooves 115 and the second screw grooves 116, respectively.

The fastening member 120 is screwed into the screw grooves 115 and 116 of the cable connection material 110 to fasten and secure the first cable (C1) and the second cable (C2) to the cable connection material 110. It is a composition that does.

The fastening member 120 is formed in a cylindrical shape with the same diameter, so that when rotated by the fastening tool 130, the entire body is inside the cable connection material 110, as shown in FIG. 4. It can be formed to be positioned.

That is, the fastening member 120 is located inside the cable connection material 110 when the cable is fastened to the cable connection material 110, and is formed so that no part protrudes to the outside of the cable connection material 110. It is designed to occupy minimal space.

For this purpose, the fastening member 120 includes a fastening member body 121 formed in a cylindrical shape having the same diameter, a fastening member body 121 formed on one outer peripheral surface of the fastening member body 121, and a screw groove 115 and 116. A male thread 122 screwed to the screw thread, and a fastening groove 123 formed in the form of a polygonal groove inward from the other end surface of the fastening member body 121 and through which the fastening tool 130 is fastened to transmit the rotational force. ) can be achieved including.

That is, conventionally, as shown in FIG. 1, the head 21 of the bolt 20 is formed to have a large diameter, so that even when the wire C is fastened to the straight connecting member 10, the head 21 of the bolt 20 There was a problem in that the portion (21) protruded to the outside of the straight connecting member (10) and took up a lot of space.

Accordingly, in the present invention, unlike the prior art, even in the state where the cable is fastened to the cable connection member 110 by providing the fastening member 120, there is no part protruding outside of the cable connection member 110, so that it takes up minimal space. It was configured to do so.

The fastening tool 130 is configured to rotate the fastening member so that it fastens to the screw groove.

For this purpose, the fastening tool 130 includes a wrench part 131 fastened to the fastening member 120, and a rotating part 132 to which the wrench part 131 is fastened and which rotates the wrench part 131. This is done.

The wrench part 131 is formed in a shape to be inserted into the fastening groove 123 of the fastening member 120, and rotates the fastening member 120 while being inserted into the fastening groove 123 to fasten the fastening. The member 120 may be inserted and fastened to the cable connection material 110.

For example, the fastening groove 123 and the wrench portion 131 may be formed in a hexagonal shape.

In addition, the fastening tool 130 may be configured to rotate the fastening member 120 so that the fastening member 120 presses the cable and provides only the torque required to fasten it to the cable connection material 110.

To this end, the fastening tool 130 includes a sensor unit 133 that measures the torque with which the wrench unit 131 rotates by the rotating unit 132, and a user's current torque measured by the sensor unit 133. It may be configured to include a display unit 134 that displays torque so that the value can be checked.

With this configuration, when the fastening member 120 is rotated with the fastening tool 130 and the fastening member 120 presses the cable, the torque value applied to the rotating part 132 increases. When the user confirms the torque value through the display unit 134, the fastening member 120 can fasten and secure the cable with the optimal torque value for fastening the cable to the cable connection member 110.

In other words, if the fastening member 120 is fastened to a torque value smaller than the torque value for stably fastening and fixing the cable to the cable connecting member 110, a problem may occur in which the cable is easily separated from the cable connecting member 110.

In addition, if the fastening member 120 is fastened to the cable connecting material 110 with a torque value greater than the torque value for stably fastening and fixing the cable, the cable may be disconnected or unnecessary metal metal may be removed due to high friction between the cable and the fastening member 120. Problems with powder generation may occur.

Therefore, the fastening tool 130 according to an embodiment of the present invention can check the torque value at which the fastening member 120 is fastened through the sensor unit 133 and the display unit 134, so that the cable can be adjusted with optimal torque. Can be fastened to the cable connection material 110.

In addition, as shown in FIG. 4, a first cable (C1) inserted into the first hollow portion 112 of the cable connection material 110 and a second cable (C2) inserted into the second hollow portion 113. When the cables have different diameters, the torque values to be applied to each of the first cable (C1) and the second cable (C2) also vary, so they can be fastened at an optimal torque value by considering the diameters of these cables.

In addition, even when the first cable (C1) and the second cable (C2) are made of different materials such as copper and aluminum, the torque values to be applied to the first cable (C1) and the second cable (C2), respectively. Also, since it varies, it is possible to fasten at the optimal torque value by considering the material of the cable.

Therefore, the cable can be optimally fastened and fixed with the optimal torque value considering the size and material of the cable. Here, the optimal torque value can be applied after testing in advance according to the diameter and material of the cable and building a separate database.

In addition, the fastening tool 130 may further include a configuration that notifies the user visually or audibly when the target torque value is reached so that the user can easily recognize it.

To this end, the fastening tool 130 is provided on the display unit 134 and includes a manipulation unit 135 capable of setting a target torque value, and the rotation unit 132 rotates the wrench unit 131 to set the target torque. It may include a notification unit 136 that notifies the user when the value is reached so that the user can recognize it.

Here, the notification unit 136 may be provided as a lamp that can be visually recognized by the user, or may be provided as a speaker that can be recognized audibly by the user. Of course, the notification unit 136 may be equipped with both a lamp and a speaker so that the user can recognize it both visually and audibly.

Alternatively, the fastening tool 130 may be configured to transmit rotational force up to a desired torque without having a separate electronic device such as a sensor unit and a display unit.

For this purpose, the fastening tool 130 is provided between the wrench part 131 and the rotating part 132, and transmits rotational force up to a set maximum torque value, and does not transmit rotational force when it exceeds the set maximum torque value. It may be configured to include a transmission unit 140.

That is, the torque transmitting unit 140 is connected so that the wrench unit 131 and the rotating unit 132 rotate together up to a set maximum torque, and when the set maximum torque is exceeded, the wrench unit 131 and the rotating unit 132 ) may be separated to rotate relative to each other and may be configured not to transmit rotational force.

As an example, referring to FIG. 5, the torque transmission unit 140 is fastened to the wrench unit 131 and rotates together with the first rotating part 141, which is fastened to the rotating part 132 and rotates together, and the first rotating part 141 is fastened to the wrench part 131 and rotates together. 1 It may include a second rotating part 142 disposed around the rotating part 141 and in contact with the first rotating part 141 to have a predetermined frictional force.

Here, the torque transmitting unit 140 may be configured to set the maximum static friction force between the first rotating unit 141 and the second rotating unit 142 to a value corresponding to the set maximum torque value.

With this configuration, when the user rotates the rotating part 132 below the set maximum torque value, the second rotating part 142 and the first rotating part 141 rotate together by friction force to rotate the wrench part 131. You can do it.

And, if the user continues to rotate the rotating unit 132 and exceeds the set maximum torque value, the maximum static friction force of the second rotating unit 142 and the first rotating unit 141 is exceeded, and the second rotating unit ( 142) and the first rotating part 141 rotate relative to each other, so the wrench part 131 can no longer be rotated.

In this way, the fastening tool 130 can fasten the cable to the cable connection member 110 at an optimal torque value, thereby solving problems of cable separation or cable damage.

Although the present invention has been described in detail through specific examples, this is for detailed explanation of the present invention, and the present invention is not limited thereto, and the present invention is intended to be understood by those skilled in the art within the technical spirit of the present invention. It is clear that modification or improvement is possible.

All simple modifications or changes of the present invention fall within the scope of the present invention, and the specific scope of protection of the present invention will be made clear by the appended claims.

C1: 1st cable C2: 2nd cable
100: cable connector 110: cable connection material
111: Connection material body 112: First hollow portion
113: second hollow part 114: blocking wall
115: first screw groove 116: second screw groove
120: Fastening member 121: Fastening member body
122: Male thread 123: Fastening groove
130: fastening tool 131: wrench part
132: Rotating part 133: Sensor part
134: display unit 135: control unit
136: Notification unit 140: Torque transmission unit
141: first rotating part 142: second rotating part

Claims (10)

A cable connection material having a hollow portion through which a first cable is inserted on one side and a second cable on the other side, and having a screw groove penetrating in a direction perpendicular to the hollow portion and forming a female thread;
a fastening member screwed into a screw groove of the cable connection member to fasten and secure the first cable and the second cable to the cable connection member; and
Includes a fastening tool that rotates the fastening member so that it fastens to the screw groove,
The fastening tool is,
A wrench part fastened to the fastening member;
a rotating part to which the wrench part is fastened and to rotate the wrench part; and
A torque transmission unit provided between the wrench unit and the rotating unit, transmits rotational force up to a set maximum torque value, and does not transmit rotational force when the set maximum torque value is exceeded,
The torque transmission unit,
a first rotating part that is fastened to the wrench part and rotates together; and
A second rotating part is fastened to the rotating part and rotates together, and is disposed around the first rotating part and is in contact with the first rotating part to have a predetermined friction force,
The torque transmission unit,
A cable connection device, characterized in that the maximum static friction force between the first rotating part and the second rotating part is set to a value corresponding to the set maximum torque value.
According to paragraph 1,
The cable connection material is,
A straight connecting material body;
a first hollow portion inserted inward from one end of the connecting material body;
a second hollow portion inserted inward from the other end of the connecting member body;
a blocking wall blocking between the first hollow part and the second hollow part;
At least one first screw groove is formed to penetrate the first hollow portion on the outer peripheral surface of the connection material body and has a female thread formed on the inner peripheral surface; and
At least one second screw groove is formed to penetrate the second hollow portion on the outer peripheral surface of the connection material body and has a female thread formed on the inner peripheral surface;
A cable connection device comprising:
According to paragraph 1,
The fastening member is,
A cable connection device, characterized in that when rotated by the fastening tool, the entire body is located inside the cable connection material.
According to paragraph 1,
The fastening member is,
A fastening member body formed in a cylindrical shape;
a male thread formed on an outer peripheral surface of one side of the fastening member body and screwed to a thread formed in the thread groove; and
a fastening groove formed in the shape of a polygonal groove inward from the other end surface of the fastening member body, and through which the fastening tool is fastened to transmit a rotational force;
A cable connection device comprising:
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