KR101955302B1 - Coupler apparatus for distributing cable - Google Patents

Abstract

The present invention relates to a coupler apparatus for a distribution cable, which can prevent a short-circuit phenomenon and an accident caused by the short-circuit phenomenon such as electric shock by automatically releasing the connection between the distribution cables when overload and overheating occurs at a connection point between the distribution cables, can prevent fire, can be automatically returned to the connection state when the overload and overheating condition is released, and can stably maintain the connection state between the distribution cables by attenuating vibration when the vibration occurs due to excavation or blasting work in adjacent construction site or due to weak earthquake. The distribution cable of the present invention includes: a body housing; a first cable connection portion, a second cable connection portion, a first solenoid actuator, a contact detection sensor, and a temperature sensor installed in the body housing; an outer housing for accommodating a lower portion of the body housing in an upper portion of the outer housing; a second solenoid actuator installed in the outer housing; and a controller that controls the operation of the first solenoid actuator and the second solenoid actuator.

Description

{Coupler apparatus for distributing cable}

In the field of distribution technology, when the overload and overheating phenomenon occurs at the connection part between the distribution cables, the present invention automatically releases the connection between the distribution cables to prevent the occurrence of short-circuit and safety accidents such as electric shock, When the situation is canceled, the connection state is automatically restored. In addition, vibration occurs due to excavation or blasting work in the adjacent construction site, or when vibration occurs due to a weak earthquake, it is attenuated and the connection state between the distribution cables can be maintained more stably. Cable connection coupler.

Generally, the electricity used in each home or office is provided from a substation equipped with each region.

In other words, the substation is a facility installed to distribute the power and the change of voltage or current in the process of sending the power generated by the power plant to the customer through the transmission line or the distribution line.

These substations were generally installed on the ground, but they are changing to be installed underground due to the risk of exposing the high-voltage wires to the outside and the deterioration of the beauty of the city.

When the substation is installed in the basement, it is often the case that the high-voltage distribution cable is cut and re-connected according to the surrounding terrain in the process of installing the high-voltage distribution cable. It is often the case that you need to connect the distribution cable as you need it.

Therefore, a variety of apparatuses and apparatuses for connecting and using a distribution cable are provided. For example, Korean Patent No. 10-1046397 entitled " Substation Transmission & Distribution High-voltage Cable Connection Device " and Korean Patent No. 10-1785014 And "Distribution cable connection coupler with improved fixing force".

However, existing prior arts for connection of distribution cable including the above-mentioned registered patent can not properly control the overload and overheating phenomenon at the connection portion between the distribution cables, causing a short-circuit phenomenon and thus a safety accident or fire such as electric shock .

In other words, since the distribution cable supplies high-voltage to extra-high voltage electricity, a lot of heat is generated at the connection portion between the distribution cables. In particular, in a climate condition in which a heat wave lasts for a certain period of time, As well as the use of electric power by the users, the overload and overheating phenomenon at the connecting portion between the power distribution cables was intensified.

In addition, the prior art for connection of the existing distribution cable has a problem that the connection state between the distribution cables is released or becomes bad when vibration caused by excavation or blasting work of an adjacent construction site or vibration caused by a weak earthquake occurs.

Korean Registered Patent No. 10-1046397 (Published on July 5, 2011.), "Transmission and distribution substation high-voltage cable connection device" Korean Registered Patent No. 10-1785014 (October 10, 2017.), "Coupling of Distribution Cable with Improved Fixing Force"

The embodiment of the present invention automatically releases the connection between the power distribution cables in the event of overload and overheating at the connection portion between the power distribution cables, thereby preventing a safety accident such as short-circuit and electric shock, The connection cable is automatically returned to the connection state when the cable is disconnected.

In addition, in the embodiment of the present invention, vibrations are generated due to excavation or blasting operation at a construction site adjacent to a connection portion between distribution cables, or when vibration occurs due to a weak earthquake, the connection state between the distribution cables can be more stably maintained To provide a distribution cable connecting coupler device.

The first cable insertion hole 111 for insertion of the power distribution cable 200 is formed on one side of the two opposite sides of the power distribution cable connection coupler apparatus according to the embodiment of the present invention and the other power transmission cable And a second cable insertion hole 112 for insertion of the first cable insertion hole 111 and the second cable insertion hole 112. The first cable insertion hole 111 and the second cable insertion hole 112 are formed in a side A guide groove 113 is formed along one side of the inner surface in the horizontal direction and a rod insertion groove 114 is formed on the outer surface of the lower surface of the lower surface on which the first cable insertion hole 111 is formed And a first through hole 121 corresponding to the first cable insertion hole 111 is formed so that the first through hole 121 is connected to the first cable insertion hole 111 And is coupled to one side surface of the main body housing 110 in a connecting state, A first connection module 122 electrically and mechanically coupled to the distribution cable 200 inserted through the first cable insertion hole 111 and the first through hole 121 is provided at one end, An insulating first cable connecting portion 120 and a second connecting portion 120 are provided in a state where the push member 123 formed of an iron type shape memory alloy on both sides in the vertical direction around the module 122 is in contact with the first connecting module 122, A second through hole 132 corresponding to the second cable insertion hole 112 is formed and a guide roller 131 slidably coupled to the guide groove 113 is formed, The second cable insertion hole 112 and the second through hole 132 are slidably installed on the inner side of the main body housing 110 in a state in which the second through hole 132 can be selectively connected to the second cable insertion hole 112, ≪ / RTI > the electrical distribution cable < RTI ID = 0.0 > 200 ' And a second connection module 133 mechanically coupled to the first connection module 122 to electrically connect the distribution cable 200 'to the distribution cable 200 of the first connection module 122. [ And insertion grooves 134 are formed on both sides of the second connection module 133 in the vertical direction with respect to the second connection module 133 so that one of the push members 123 is inserted into the insertion groove 134, An insulating second cable connection part 130 having a weight 135 disposed on an opposite end of the lower side of the second connection module 133 on which the second connection module 133 is located, And the first rod 141 is provided on the side where the hole 112 is formed so that the forward movement of the first rod 141 is transmitted to the first solenoid actuator 130 which advances in the direction of pushing the second cable connection part 130 toward the first cable connection part 120, (140), a first connecting module (122) and a second connecting module (133) A contact detection sensor installed in a contact area between the first cable connection part 120 and the second cable connection part 130 according to the connection and detecting whether the first cable connection part 120 and the second cable connection part 130 are in contact with each other, At least one temperature sensor (160) installed at one or both of the first connection module (122) and the second connection module (133) to measure the temperature, A bellows connection part 200a and a bellows connection part 200b are provided on two sides of a direction perpendicular to the first direction with respect to a first direction which is a connection direction of the distribution cables 200 and 200 ' The housing body 171 is divided into an upper installation space 173 and a lower installation space 174 and the installation space 173 and the accommodation space 174 Through hole 172a for connecting the main housing 110 An outer housing 170 that houses the lower portion of the main body housing 110 in the installation space 173 and a partition wall 172 that is formed to correspond to the rod insertion groove 114 of the partition wall 172 The second rod 181 is installed in the receiving space 174 of the outer housing 170 in a state in which the second rod 181 can move in the vertical direction through the through hole 172a of the second rod 181, The first cable connecting portion is inserted into the rod insertion groove 114 of the main body housing 110 and is located on both sides of the lower surface of the main housing 110 during forward movement of the second rod 181 A second solenoid actuator 180 for lifting a lower surface of the first cable connection part 120 and the second cable connection part 130 upward by a predetermined height and a contact release signal between the first cable connection part 120 and the second cable connection part 130 via the contact detection sensor 150 The second solenoid actuator 180 is connected to the main housing 11 0 and a threshold temperature for operating the first solenoid actuator 140 and the second solenoid actuator 180 is set so that the measured value of the temperature transmitted through the temperature sensor 160 is The second solenoid actuator 180 operates to return the main housing 110 to a horizontal state and the first solenoid actuator 140 is operated to return the second solenoid actuator 130 to the second cable connection part 130. [ And a control part (190) sliding the first connection module (122) in the direction of the first cable connection part (120) so as to mechanically couple the second connection module (133) to the first connection module Are deformed to protrude toward the second cable connection part 130 at a predetermined temperature so that the mechanical connection between the first connection module 122 and the second connection module 133 is released, The weight 135 of the second cable connection part 130 pushes the cable connection part 130 from the first cable connection part 120 to the opposite side of the body housing 110) of the first cable connection part (120) in the direction of separating from the first cable connection part (120) of the second cable connection part (130).

According to the embodiment of the present invention, when an overload and an overheating phenomenon occur at a connection portion between power distribution cables, the connection between the power distribution cables is automatically released, thereby preventing a short-circuit phenomenon and subsequent safety accidents such as electric shock, When the overheat situation is canceled, the connection state is automatically restored and the power distribution function can be normalized.

In addition, when vibration occurs due to excavation or blasting operation at a construction site adjacent to a connection site between distribution cables, or vibration occurs due to a weak earthquake, the connection state between the distribution cables can be more stably maintained.

1 is a perspective view illustrating an outer shape of a distribution cable connecting coupler apparatus according to an embodiment of the present invention;
FIG. 2 is a cross-sectional view illustrating an internal configuration of a distribution cable connecting coupler apparatus according to an embodiment of the present invention,
3 is a block diagram illustrating an electrical configuration of a distribution cable connecting coupler apparatus according to an embodiment of the present invention.
And
4 is a diagram sequentially illustrating operation procedures of a distribution cable connecting coupler apparatus according to an embodiment of the present invention;

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Reference will now be made in detail to the embodiments of the present invention, examples of which are illustrated in the accompanying drawings. These embodiments are described in sufficient detail to enable those skilled in the art to practice the invention. It should be understood that the various embodiments of the present invention are different, but need not be mutually exclusive. For example, certain features, structures, and characteristics described herein may be implemented in other embodiments without departing from the spirit and scope of the invention in connection with one embodiment. It is also to be understood that the position or arrangement of the individual components in each described embodiment may be varied without departing from the spirit and scope of the present invention.

The following detailed description is, therefore, not to be taken in a limiting sense, and the scope of the present invention is to be limited only by the appended claims, along with the full scope of equivalents to which the claims are entitled, if properly explained. In the drawings, like reference numerals refer to the same or similar functions throughout the several views.

While the present invention has been described in connection with what is presently considered to be the most practical and preferred embodiment, it is to be understood that the invention is not limited to the disclosed embodiments. Also, in certain cases, there may be a term selected arbitrarily by the applicant, in which case the meaning thereof will be described in detail in the description of the corresponding invention. Therefore, the term used in the present invention should be defined based on the meaning of the term, not on the name of a simple term, but on the entire contents of the present invention.

Whenever an element is referred to as " including " an element throughout the description, it is to be understood that the element may include other elements as well, without departing from the other elements unless specifically stated otherwise. In addition, the term " "... Module " or the like means a unit for processing at least one function or operation, which may be implemented in hardware or software, or a combination of hardware and software.

A distribution cable connecting coupler apparatus according to an embodiment of the present invention will be described with reference to FIGS. 1 to 4. FIG.

FIG. 1 is a perspective view illustrating an outline of a distribution cable connecting coupler apparatus according to an embodiment of the present invention, FIG. 2 is a cross-sectional view illustrating an internal configuration of a distribution cable connecting coupler apparatus according to an embodiment of the present invention, And FIG. 3 is a block diagram illustrating an electrical configuration of a distribution cable connecting coupler apparatus according to an embodiment of the present invention.

A coupler apparatus 100 according to an embodiment of the present invention includes a main body housing 110, a first cable connection unit 120, a second cable connection unit 120, A first solenoid actuator 140, a contact detection sensor 150, a temperature sensor 160, an outer housing 170, a second solenoid actuator 180, and a controller 190.

The main body housing 110 is formed of an insulating material. In the main body housing 110, a first cable insertion hole 111 for insertion of the power distribution cable 200 is formed on one of the two opposite sides, And a second cable insertion hole 112 for insertion of another distribution cable 200 'is formed on the side surface. The main body housing 110 has guide grooves 113 on one side of a horizontal reference surface of the inner surface of one side disposed at right angles to the two side surfaces of the first cable insertion hole 111 or the second cable insertion hole 112, Are formed along the horizontal direction. In addition, the main body housing 110 has a rod insertion groove 114 formed on the outer surface of the lower surface of the lower housing on which the first cable insertion hole 111 is formed.

The first cable connection part 120 is formed of an insulating material and the first cable connection part 120 is formed with a first through hole 121 corresponding to the first cable insertion hole 111 of the main body housing 110 And is coupled to one side of the main body housing 110 in a state where the first through hole 121 is connected to the first cable insertion hole 111 of the main body housing 110. The first cable connecting part 120 is electrically connected to the first cable connecting hole 111 of the main housing 110 through the first through hole 121, A module 122 is provided at one end and a push member 123 formed of an iron shape memory alloy on both sides in the vertical direction around the first connection module 122 is in contact with the first connection module 122 Respectively.

The second cable connection part 130 is formed of an insulating material and the second cable connection part is formed with a second through hole 132 corresponding to the second cable insertion hole 112 of the main body housing 110, A guide roller 131 slidably coupled to the guide groove 113 of the main body housing 110 is formed to selectively connect the second through hole 132 to the second cable insertion hole 112 of the main housing 110. [ And is slidably installed inside the main body housing 110 in a state in which the main body housing 110 can be opened.

The second cable connection part 130 is electrically and mechanically coupled to the power cable 200 'inserted through the second cable insertion hole 112 and the second through hole 132 of the main body housing 110, A second connection module 133 mechanically coupled to the first connection module 122 of the cable connection part 120 and electrically connecting the distribution cable 200 'to the distribution cable 200 of the first connection module 122, Is provided at one end. The second cable connection part 130 is inserted into the first cable connection part 120 in a state where one of the push members 123 of the first cable connection part 120 is in contact with one side of the second connection module 133 in the vertical direction, And a weight 135 is provided at an end opposite to the side where the second connection module 133 is located.

Here, when the first connection module 122 and the second connection module 133 are mechanically coupled to each other, the power supply cable 200 of the first connection module 122 and the power supply cable 200 'of the second connection module 133 The configuration in which the electrical connection is made can be variously implemented through various known technologies, so that detailed description and illustration thereof are omitted in the present embodiment.

The first solenoid actuator 140 is installed on a side surface of the main housing 110 where the second cable insertion hole 112 is formed and the first solenoid actuator 140 is connected to the first solenoid actuator 140, 2 cable connection part 130 toward the first cable connection part 120. In this case, And power supply to the first solenoid actuator 140 may be performed using a power supply for the electrical components including the controller 190. [

The contact detection sensor 150 is installed in the contact area between the first cable connection part 120 and the second cable connection part 130 in accordance with the mechanical coupling between the first connection module 122 and the second connection module 133, The contact detection sensor 150 senses whether the first cable connection part 120 and the second cable connection part 130 are in contact with each other.

The temperature sensor 160 is installed on one or both of the first connection module 122 and the second connection module 133 and functions to measure the temperature.

The outer housing 170 includes a housing body 171 and a partition 172.

The housing main body 171 is opened at an upper portion thereof and is provided at two sides of a direction perpendicular to the first direction with respect to a first direction which is a connection direction of the power distribution cables 200 and 200 ' And a bellows connecting portion 171a that exerts a stretching function in the first direction is formed.

The partition 172 divides the inside of the housing main body 171 into an upper installation space 173 and a lower reception space 174 and has a through hole 172a for connecting the installation space 173 and the accommodation space 174 Is formed on one side so as to correspond to the rod insertion groove 114 of the main body housing 110.

The lower portion of the main body housing 110 is accommodated in the installation space 173 of the housing main body 171 formed above the partition 172. In other words, the main body housing 110 is installed on the upper portion of the outer housing 170 in a state where the lower portion is drawn into the installation space 173 of the housing main body 171.

The bellows connecting portion 171a of the housing main body 171 is connected to the power supply cable 171 by the external housing 170 when vibration occurs due to excavation or blasting operation at the construction site adjacent to the coupler device 100 or when vibration occurs due to a weak earthquake, The vibrations transmitted to the main housing 110 are attenuated while being expanded or contracted in the same direction as the connecting direction of the main body housing 200 and the main body housing 110, Vibration transmission is minimized so that the connection state between the power distribution cables 200 and 200 'can be more stably maintained.

The second solenoid actuator 180 is configured to receive the outer housing 170 in a state in which the second rod 181 can move in the vertical direction through the through hole 172a of the partition wall 172 of the outer housing 170, The tip of the second rod 181 is inserted into the rod insertion groove 114 of the main housing 110. [ When the second rod 181 is moved forward in the upward direction of the second rod 181, the second solenoid actuator 180 moves downward from the lower surface of the lower surface of the main housing 110 to the first cable connecting portion 120, It acts to raise height. And power supply to the second solenoid actuator 180 may be performed using a power supply for the electrical components including the controller 190. [

The control unit 190 controls the second solenoid actuator 180 to transmit the contact release signal between the first cable connection unit 120 and the second cable connection unit 130 via the contact detection sensor 150 to one side of the main housing 110 . The control unit 190 sets a threshold temperature for operating the first solenoid actuator 140 and the second solenoid actuator 180 so that the measured value of the temperature transmitted through the temperature sensor 160 is lower than the predetermined threshold temperature The second solenoid actuator 180 operates to return the main body housing 110 to a horizontal state and the first solenoid actuator 140 moves the second cable connection portion 130 toward the first cable connection portion 120 So that the first connection module 122 is mechanically coupled to the second connection module 133.

The pushing members 123 of the first cable connecting part 120 are deformed to protrude toward the second cable connecting part 130 at a predetermined temperature so that mechanical coupling between the first connecting module 122 and the second connecting module 133 The second cable connection part 130 is pushed away from the first cable connection part 120 so as to be released.

The weight 135 of the second cable connection part 130 is connected to the first cable connection part 120 of the second cable connection part 130 when the first solenoid actuator 180 is lifted at one side of the main housing 110, ) In the direction of separating from the moving direction.

4 is a diagram illustrating an operation of the coupler apparatus 100 having the above-described configuration.

(A) shows a state in which the pushing member 123 of the first cable connecting part 120 is deformed due to overheating of the first connecting module 122 and the second connecting module 133 is moved from the first connecting module 122 to the opposite side And the mechanical coupling between the first connection module 122 and the second connection module 133 is separated.

In step (b), a signal is input from the touch sensing sensor 150 to the controller 190 according to the above-described process (a), and the controller 190 operates the second solenoid actuator 180, 110 are lifted upward and the second cable connection part 130 is accelerated by the load of the weight 135 and is slid in a direction separating from the first cable connection part 120 It is.

When the overload and overheating phenomenon of the coupler device 100 are solved in the state of (b) and the measured value of the temperature is inputted to the controller 190 through the temperature sensor 160, the controller 190 controls the first and The second solenoid actuators 140 and 180 are operated to return the main body housing 110 to a horizontal state and the second cable connection part 130 is slid in the direction of the first cable connection part 120, The second connection module 133 is mechanically coupled to the coupler device 100. Thus, the coupler device 100 is returned to the state of FIG.

As can be seen from the embodiments of FIGS. 1 to 4, when the overload and overheating phenomenon occurs at the connection part between the distribution cables, the connection cable between the distribution cables according to the embodiment of the present invention It is automatically released to prevent a short-circuit phenomenon and subsequent electric shock, as well as to prevent a fire. When overload and overheating are canceled, the connection function is automatically returned to normalize the power distribution function.

In addition, when vibration occurs due to excavation or blasting operation at a construction site adjacent to a connection site between power distribution cables, or vibration occurs due to a weak earthquake, the connection state between the power distribution cables can be more stably maintained.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the exemplary embodiments or constructions. It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims.

Accordingly, the spirit of the present invention should not be construed as being limited to the embodiments described, and all the equivalents or equivalents of the claims, as well as the claims set forth below, fall within the scope of the present invention.

100: coupler device 110: main housing
111: first cable insertion hole 112: second cable insertion hole
113: guide groove 114: rod insertion groove
120: first cable connecting portion 121: first through hole
122: first connection module 123: push member
130: second cable connection part 131: guide roller
132: second through hole 133: second connection module
134: insertion groove 135: weight
140: first solenoid actuator 141: first rod
150: contact detection sensor 160: temperature sensor
170: outer housing 171: housing body
171a: Bellows connection part 172:
172a: Through hole 173: Installation space
174: accommodation space 180: second solenoid actuator
181: second load 190:
200,200 ': Distribution cable

Claims (1)

A first cable insertion hole 111 for insertion of the power distribution cable 200 is formed on one of two opposite sides and a second cable insertion hole 111 for insertion of another power distribution cable 200 ' 112 are formed on the inner side of the first cable insertion hole 111 or the second cable insertion hole 112. A guide groove 113 is formed on one side of the inner surface of one side surface, An insulating main body housing 110 formed along the horizontal direction and having rod insertion grooves 114 formed on the outer surface of the lower surface on which the first cable insertion holes 111 are formed;
A first through hole 121 corresponding to the first cable insertion hole 111 is formed to connect the first through hole 121 to the first cable insertion hole 111, And a first connection module 122 electrically and mechanically coupled to the power cable 200 inserted through the first cable insertion hole 111 and the first through hole 121 is connected to one side And a push member 123 formed of an iron-type shape memory alloy on both sides in the vertical direction around the first connection module 122 is provided in contact with the first connection module 122, A first cable connection part (120);
A second through hole 132 corresponding to the second cable insertion hole 112 is formed and a guide roller 131 slidably coupled to the guide groove 113 is formed, 112 are slidably installed on the inner side of the main housing 110 in a state in which the second through hole 132 is selectively connectable to the second cable insertion hole 112 and the second through hole 132, The power supply cable 200 'inserted through the first connection module 132 is electrically and mechanically coupled and mechanically coupled with the first connection module 122 so that the power distribution cable 200' And a second connection module 133 electrically connected to the cable 200 is provided at one end of the first connection module 133. One of the push members 123 is disposed on one side Respectively, of the lower surface of the lower surface An insulative second cable connection part 130 having a weight 135 at the opposite end of the side where the second connection module 133 is located;
The first cable 141 is installed on the side of the main housing 110 where the second cable insertion hole 112 is formed and the forward movement of the first rod 141 connects the second cable connection part 130 to the first cable connection part 120 A first solenoid actuator 140 moving in a direction of pushing toward the first solenoid actuator 140;
The first cable connection part 120 and the second cable connection part 130 are provided in a contact area between the first cable connection part 120 and the second cable connection part 130 according to the mechanical coupling between the first connection module 122 and the second connection module 133, A contact detection sensor 150 for detecting contact between the first cable connection part 130 and the second cable connection part 130;
At least one temperature sensor (160) installed at one or both of the first connection module (122) and the second connection module (133) to measure the temperature;
The upper portion of the main body housing 110 is opened and the first and second side surfaces of the main body housing 110 are connected to the first and second side surfaces of the main body housing 110, The housing body 171 is divided into an upper space 173 and a lower space 174 in which the bellows connection portion 171a is formed. And a partition wall 172 formed at one side of the main body housing 110 so as to correspond to the rod insertion groove 114 of the main housing 110. The installation space 173 has a through- An outer housing 170 in which a lower portion of the main body housing 110 is housed;
The second rod 181 is installed in the receiving space 174 of the outer housing 170 so that the second rod 181 can move in the vertical direction through the through hole 172a of the partition 172, Is inserted into the rod insertion groove 114 of the main housing 110. When the second rod 181 is moved forward in the upward direction of the main housing 110, A second solenoid actuator 180 for lifting the lower surface area of the side on which the connecting part is located upward by a predetermined height;
When the second solenoid actuator 180 transmits a contact release signal between the first cable connection part 120 and the second cable connection part 130 through the contact detection sensor 150, And a threshold temperature for operating the first solenoid actuator 140 and the second solenoid actuator 180 is set so that a measured value of the temperature transmitted through the temperature sensor 160 is set to a predetermined threshold temperature The second solenoid actuator 180 operates to return the main body housing 110 to a horizontal state and the first solenoid actuator 140 moves the second cable connection part 130 to the first cable 130. [ And a controller 190 sliding the first connection module 122 in the direction of the connection part 120 to mechanically couple the second connection module 133 to the first connection module 122,
The pushing members 123 are deformed to protrude toward the second cable connecting part 130 at a predetermined temperature so that the mechanical coupling between the first connecting module 122 and the second connecting module 133 is released, The weight 135 of the second cable connection part 130 pushes the connection part 130 from the first cable connection part 120 to the opposite side of the main body housing 110 according to the operation of the second solenoid actuator 180 ) Of the second cable connecting part (130) is accelerated in a direction of separating from the first cable connecting part (120) of the second cable connecting part (130).

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