阅读说明：本技术 电缆附件结构 (Cable accessory structure ) 是由 石继荣 何启鹏 斯荣 代聪 于 2019-08-29 设计创作，主要内容包括：本发明涉及一种电缆附件结构,包括封堵件、防尘件及无线功率传输模块。封堵件包括绝缘体及金属接头。绝缘体具有相对的接线端及传送端。金属接头预制于接线端内,并用于与内置于电缆线内的传感器电连接。防尘件包括防护壳及接线插口。防护壳具有收容腔。传送端可拆卸地收容于收容腔内。接线插口设置于防护壳的外壁上。无线功率传输模块包括信号接收单元及信号发送单元。信号接收单元预制于传送端内,并与金属接头电连接。信号发送单元预制于防护壳侧壁的内部,并与接线插口电连接。上述电缆附件结构的使用,使得电缆在线参数测试的准确性较高。(The invention relates to a cable accessory structure which comprises a plugging piece, a dustproof piece and a wireless power transmission module. The plugging piece comprises an insulator and a metal joint. The insulator has opposite terminals and a transfer end. The metal connector is prefabricated in the wiring terminal and is used for being electrically connected with a sensor arranged in the cable. The dustproof piece comprises a protective shell and a wiring socket. The protective shell is provided with an accommodating cavity. The transmission end is detachably accommodated in the accommodating cavity. The wiring socket is arranged on the outer wall of the protective shell. The wireless power transmission module comprises a signal receiving unit and a signal sending unit. The signal receiving unit is prefabricated in the transmitting end and is electrically connected with the metal joint. The signal transmitting unit is prefabricated in the side wall of the protective shell and is electrically connected with the wiring jack. Due to the adoption of the cable accessory structure, the accuracy of the online parameter test of the cable is higher.)

1. An electrical cable accessory structure, comprising:

the blocking piece comprises an insulator and a metal connector, wherein the insulator is provided with a terminal and a transmitting end which are opposite, and the metal connector is prefabricated in the terminal and is used for being electrically connected with a sensor arranged in a cable;

the dustproof piece comprises a protective shell and a wiring socket, the protective shell is provided with an accommodating cavity, the transmission end is detachably accommodated in the accommodating cavity, and the wiring socket is arranged on the outer wall of the protective shell; and

the wireless power transmission module comprises a signal receiving unit and a signal sending unit, wherein the signal receiving unit is prefabricated in the transmitting end and is electrically connected with the metal joint, and the signal sending unit is prefabricated in the inner part of the side wall of the protective shell and is electrically connected with the wiring socket.

2. The cable accessory structure according to claim 1, wherein a terminal surface of the metal joint remote from the transmission end is provided with a wiring screw hole for screwing the cable line.

3. The cable accessory structure according to claim 2, wherein the end portion of the transmitting end is provided with a grip portion extending in a direction of a line connecting the terminal and the transmitting end, and a radial cross-sectional shape of the grip portion is a polygon; the inner wall of the accommodating cavity is provided with an accommodating groove at a position opposite to the holding part, the accommodating groove is communicated with the accommodating cavity, and when the conveying end is accommodated in the accommodating cavity, the holding part is accommodated in the accommodating groove.

4. The cable accessory structure according to claim 1, wherein the metal terminal extends in a direction of a line connecting the terminal and the transmission terminal, a side wall of the metal terminal is circumferentially provided with a stopper groove, and the stopper groove is located inside the insulator.

5. The cable accessory structure of claim 1, wherein an end of the metal fitting near the transmitting end is detachably connected to the signal receiving unit.

6. The cable accessory structure of claim 5, wherein an end of the metal fitting proximate the transmitting end is coupled to the signal receiving unit by a threaded fastener.

7. The cable accessory structure according to claim 1, wherein the end of the terminal is formed with a protective groove, and an end of the metal terminal remote from the transmission end is located in the protective groove.

8. The cable accessory structure according to claim 1, wherein the protective shell includes a bottom plate and a side plate disposed along a circumferential direction of the bottom plate and connected to the bottom plate, the bottom plate and the side plate are enclosed to form an accommodation cavity, the signal transmitting unit is pre-fabricated inside the bottom plate, and the outer surface of the bottom plate is provided with the wiring socket electrically connected to the signal transmitting unit.

9. The cable accessory structure according to claim 1, wherein the protective shell comprises an insulating outer sleeve and a heat insulating inner sleeve, the heat insulating inner sleeve is accommodated in the insulating outer sleeve, an outer wall of the heat insulating inner sleeve is attached to an inner wall of the insulating outer sleeve, and the signal transmitting unit is prefabricated inside a side wall of the heat insulating inner sleeve.

10. The cable accessory structure of claim 9, wherein the insulator and the insulating jacket are both of an insulating silicone rubber structure.

Technical Field

The invention relates to the technical field of cable accessories, in particular to a cable accessory structure.

Background

The cable accessories are the general names of cable terminals and intermediate connectors in power cable lines, and are indispensable components in the cable lines. The cable terminal head accessory is assembled at the tail end of a cable, leads out a high-voltage current-carrying conductor from a cable body, is connected to a power grid or electric equipment, plays a role in ensuring the electrical insulation performance and the mechanical sealing performance of the lead-out part of a cable conductor wire core, and provides a function of electrically connecting the cable with the power grid or the air pressure electric equipment.

In the practical application process of the cable, parameters such as the temperature of the cable and the like are inevitably required to be tested on line. At present, the on-line test of the cable is generally carried out by directly contacting a test device such as a sensor with an insulator of the cable. However, in the test method in which the test device such as the sensor is directly contacted with the insulator outside the conductor of the cable, the insulation effect of the insulator cannot accurately test the parameters such as the temperature of the conductor in the cable.

Disclosure of Invention

Therefore, it is necessary to provide a cable accessory structure capable of improving the accuracy of the cable online test, aiming at the problem that the accuracy of the conventional cable online test is not high.

An electrical cable accessory structure comprising:

the blocking piece comprises an insulator and a metal connector, wherein the insulator is provided with a terminal and a transmitting end which are opposite, and the metal connector is prefabricated in the terminal and is used for being electrically connected with a sensor arranged in a cable;

the dustproof piece comprises a protective shell and a wiring socket, the protective shell is provided with an accommodating cavity, the transmission end is detachably accommodated in the accommodating cavity, and the wiring socket is arranged on the outer wall of the protective shell; and

the wireless power transmission module comprises a signal receiving unit and a signal sending unit, wherein the signal receiving unit is prefabricated in the transmitting end and is electrically connected with the metal joint, and the signal sending unit is prefabricated in the inner part of the side wall of the protective shell and is electrically connected with the wiring socket.

In one embodiment, a terminal surface of the metal joint, which is far away from the transmission end, is provided with a wiring screw hole, and the wiring screw hole is used for screwing the cable.

In one embodiment, a holding part extending along the direction of a connecting line between the wiring terminal and the conveying end is arranged at the end part of the conveying end, and the radial cross section of the holding part is polygonal; the inner wall of the accommodating cavity is provided with an accommodating groove at a position opposite to the holding part, the accommodating groove is communicated with the accommodating cavity, and when the conveying end is accommodated in the accommodating cavity, the holding part is accommodated in the accommodating groove.

In one embodiment, the metal joint extends along a connection direction of the wiring end and the transmission end, a limit groove is formed in a side wall of the metal joint along the circumferential direction, and the limit groove is located inside the insulator.

In one embodiment, one end of the metal joint close to the transmitting end is detachably connected with the signal receiving unit.

In one embodiment, the metal fitting is connected to the signal receiving unit at an end thereof adjacent to the transmitting end by a threaded fastener.

In one embodiment, a protective groove is formed in the end portion of the terminal, and the end portion of the metal joint, which is far away from one end of the transmission end, is located in the protective groove.

In one embodiment, the protective shell includes a bottom plate and a side plate disposed along a circumferential direction of the bottom plate and connected to the bottom plate, the bottom plate and the side plate are surrounded to form an accommodation cavity, the signal transmitting unit is pre-fabricated in the bottom plate, and the outer surface of the bottom plate is provided with the wiring socket electrically connected to the signal transmitting unit.

In one embodiment, the protective shell comprises an insulating outer sleeve and a heat insulating inner sleeve, the heat insulating inner sleeve is accommodated in the insulating outer sleeve, the outer wall of the heat insulating inner sleeve is attached to the inner wall of the insulating outer sleeve, and the signal transmitting unit is prefabricated inside the side wall of the heat insulating inner sleeve.

In one embodiment, the insulator and the insulating outer sleeve are both of an insulating silicone rubber structure.

According to the cable accessory structure, when the parameters such as temperature in a cable are required to be tested on line, the metal connector is fixed on the cable and is electrically connected with the sensor arranged in the cable, and then the data display device is inserted into the wiring socket and is electrically connected with the wiring socket, so that the on-line test can be carried out. Therefore, parameter information such as temperature and the like collected by the sensor arranged in the cable is transmitted through the cable accessory structure, and the accuracy of the online parameter test of the cable is greatly improved. Furthermore, through prefabricating signal receiving unit and the signal transmission unit in shutoff piece and dust keeper respectively, can realize the wireless transmission to the temperature isoparametric signal of built-in sensor collection, improve the charging distance of wireless power transmission module effectively, improved the stability of performance of wireless power transmission module greatly, further improved the accuracy of cable on-line test. Therefore, the cable accessory structure is used, so that the accuracy of the on-line parameter test of the cable is high.

Drawings

FIG. 1 is a schematic structural view of a cable accessory structure according to a preferred embodiment of the present invention;

FIG. 2 is a schematic view of the closure of the cable accessory construction of FIG. 1;

FIG. 3 is a schematic structural diagram of a dust cover according to an embodiment of the present invention;

FIG. 4 is a schematic structural diagram of a dust-proof case according to another embodiment of the present invention;

fig. 5 is a schematic view of the metal joint in the closure of fig. 2.

Detailed Description

To facilitate an understanding of the invention, the invention will now be described more fully with reference to the accompanying drawings. Preferred embodiments of the present invention are shown in the drawings. This invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete.

It will be understood that when an element is referred to as being "secured to" another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present. The terms "vertical," "horizontal," "left," "right," and the like as used herein are for illustrative purposes only.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. The terminology used in the description of the invention herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. As used herein, the term "and/or" includes any and all combinations of one or more of the associated listed items.

Referring to fig. 1, a cable accessory structure 100 according to a preferred embodiment of the present invention includes a plugging member 110, a dust-proof member 120, and a wireless power transmission module 130.

When on-line testing parameters such as temperature in a cable (not shown), the cable accessory structure 100 is used for transmitting a parameter signal such as temperature collected by a sensor (not shown) built in the cable, and acquiring parameter information such as temperature through a data display device (not shown) electrically connected with the cable accessory structure 100.

Referring also to fig. 2, the plugging member 110 includes an insulator 111 and a metal terminal 112. The insulator 111 has opposing terminals 1111 and transmission ends 1112. Metal tabs 112 are preformed in terminal 1111 and are used to make electrical connections to sensors embedded in the cable wires.

Among them, the insulator 111 is usually made of a material with a high resistivity, such as rubber, silicone, plastic, and ceramic, so that the insulator 111 has a good electrical insulation performance. Since the metal tab 112 is used for electrical connection with the sensor built in the cable, one end of the metal tab 112 used for electrical connection with the sensor built in the cable is exposed outside the insulator 111. Therefore, the plugging member 110 is an integral body formed by the metal joint 112 and the insulator 111 which are prefabricated in the insulator 111, so that the connection between the metal joint 112 and the insulator 111 is firmer, and the probability of position change of the metal joint 112 in the insulator 111 is greatly reduced.

Referring to fig. 3 and 4, the dust-proof member 120 includes a protective shell 121 and a wire-connecting jack 122. The protective shell 121 has a receiving cavity 1211. The transmitting end 1112 is detachably received in the receiving cavity 1211. The wiring insertion opening 122 is provided on the outer wall of the shield case 121. The wiring socket 122 is electrically connected to a data display device for displaying or reading parameters such as temperature, and the data display device is used for displaying parameter information such as temperature collected by a sensor built in the cable.

Referring to fig. 1 again, the wireless power transmission module 130 includes a signal receiving unit 131 and a signal sending unit 132. The signal receiving unit 131 is prefabricated in the transmitting end 1112 and electrically connected to the metal connector 112. The signal transmitting unit 132 is prefabricated inside the side wall of the shield case 121 and electrically connected to the wiring jack 122. Specifically, the signal receiving unit 131 is fixedly connected to the metal connector 112, so that the signal receiving unit 131 is electrically connected to the metal connector 112.

The wireless power transmission module 130 may implement remote transmission of signals through the signal receiving unit 131 and the signal transmitting unit 132 which are disposed at intervals and coupled to each other. Specifically, the wireless power transfer module 130 includes circuitry (not shown). The circuit system comprises an inverter circuit, a rectifying circuit, a power conditioning circuit and a resonance compensation circuit.

Specifically, in the manufacturing process of the plugging member 110, the signal receiving unit 131 and the metal connector 112 which are fixedly connected are firstly placed in a cavity of a casting mold for processing the insulator 111, then the casting material of the insulator 111 is filled into the cavity, after the casting material of the insulator 111 is cooled and solidified, the metal connector 112 and the insulator 111 form the plugging member 110 together, and the plugging member 110 and the signal receiving unit 131 form an integral structure;

in the manufacturing process of the dust-proof member 120, the signal transmitting unit 132 is first placed in a mold cavity of a casting mold for processing the dust-proof member 120, and then the casting material of the dust-proof member 120 is filled into the mold cavity, so that the signal transmitting unit 132 and the dust-proof member 120 form an integral structure together after the casting material of the dust-proof member 120 is cooled and solidified.

In practical applications, the cable is usually electrically connected to other devices through a tee joint. Specifically, three terminals 1111 of the three-way joint are electrically connected to the cable, the electrical equipment (or the power grid) and the cable accessory structure 100, respectively.

In the process of online testing the parameters such as the temperature inside the cable, the sensor, the metal connector 112, the signal receiving unit 131, the signal sending unit 132, the wiring socket 122 and the data display device which are arranged in the cable form a finished signal transmission path, so that the parameter signals such as the temperature of the cable sensed by the sensor are transmitted to the data display device along the signal transmission path and displayed, and an operator can read the data.

The process of on-line testing the cable line using the cable accessory structure 100 described above is: firstly, the plugging piece 110 is fixed on a cable wire, and the metal joint 112 is electrically connected with a sensor arranged in the cable wire; then, the data display device is inserted into the wiring socket 122 and electrically connected with the wiring socket 122; then, the dust-proof member 120 is sleeved on the transmitting end 1112 of the insulator 111, so as to perform an on-line test operation on the cable.

Therefore, through the cable accessory structure 100, parameter information such as temperature and the like collected by a sensor arranged in a cable can be transmitted, and the accuracy of the online parameter test of the cable is greatly improved. Furthermore, the signal receiving unit 131 and the signal sending unit 132 which are respectively prefabricated in the plugging piece 110 and the dustproof piece 120 can realize remote wireless transmission of parameter signals such as temperature collected by the built-in sensor, effectively improve the charging distance of the wireless power transmission module 130, greatly improve the performance stability of the wireless power transmission module 130, and further improve the accuracy of online testing of cables.

Referring to fig. 5, in the present embodiment, the metal tab 112 extends along a connection direction of the terminal 1111 and the transmitting end 1112. The sidewall of the metal connector 112 has a limiting groove 1212 along the circumferential direction. The spacing groove 1212 is located inside the insulator 111. Thus, during molding of the insulator 111, the casting material of the insulator 111 flows into the retaining groove 1212 to form the retaining protrusion 1115. Therefore, the arrangement of the limiting groove 1212 can form the limiting convex strip 1115 in the insulator 111 for limiting the metal joint 112 along the axial direction of the metal joint 112, thereby avoiding the situation that the metal joint 112 loosens along the axial direction thereof and even breaks away from the insulator 111 after long-time use, and greatly improving the reliability of the cable accessory structure 100.

Specifically, the number of the limiting grooves 1212 is plural. A plurality of retaining grooves 1212 are provided at intervals in the axial direction of the metal joint 112. Therefore, in the process of forming the shell, one limiting convex strip 1115 can be formed in each limiting groove 1212, so that the connection effect between the metal joint 112 and the insulator 111 is further improved.

In the present embodiment, a terminal surface of the metal joint 112 away from the transmission end 1112 is provided with a wiring screw 1121. The wiring screw hole 1121 is used for screwing a cable. Thereby, the block piece 110 is detachably connected with the cable line by a metal structure. Therefore, the cable accessory structure 100 can be freely connected and separated with and from the cable according to actual needs, so that the cable accessory structure 100 is more free and convenient to use.

Referring to fig. 2 again, in the present embodiment, a holding portion 1113 is disposed at an end of the transmitting end 1112 and extends along a connecting line between the terminal 1111 and the transmitting end 1112. The grip 1113 has a polygonal radial cross-sectional shape. Specifically, when the plugging member 110 needs to be screwed to the cable, the operator needs to clamp the holding portion 1113 with a tool such as a wrench or to hold the holding end with a hand to rotate the plugging member 110, so as to screw the plugging member 110 to the cable. Specifically, an end threaded connector is usually fixedly arranged on the cable, and when the cable needs to be tested online, the end threaded connector needs to be screwed into the wiring screw hole 1121.

Furthermore, the radial cross section of the holding part 1113 is polygonal, so that the holding part 1113 can be gripped by hands of an operator or the holding part 1113 can be clamped by using tools such as a wrench, and the metal joint 112 is not easy to slip when being screwed on the cable, so that the connection between the plugging piece 110 and the cable is more convenient. Specifically, the grip portion 1113 has a hexagonal plate-like structure.

Referring to fig. 3 and 4 again, a receiving groove 1212 is formed in a position of the inner wall of the receiving cavity 1211 opposite to the holding portion 1113. The receiving cavity 1212 is in communication with the receiving cavity 1211. When the transmitting end 1112 is received in the receiving cavity 1211, the holding portion 1113 is received in the receiving cavity 1212. Therefore, when the plugging piece 110 is accommodated in the accommodating cavity 1211, the holding portion 1113 is accommodated in the accommodating groove 1212, so that the contact area between the outer wall of the insulator 111 and the inner wall of the accommodating cavity 1211 is larger, and the connection between the plugging piece 110 and the dust-proof piece 120 is more stable, so that the stability of signal transmission between the signal receiving unit 131 and the signal sending unit 132 which are respectively prefabricated in the plugging piece 110 and the dust-proof piece 120 is improved, and the accuracy of the online parameter test of the cable is further improved.

Referring to fig. 1 to fig. 2 again, in the present embodiment, one end of the metal joint 112 close to the transmitting end 1112 is detachably connected to the signal receiving unit 131. The metal connector 112 and the signal receiving unit 131 can be connected by screwing, clipping, etc. Therefore, in the processing process of the cable accessory structure 100, if the metal connector 112 and the signal receiving unit 131 are detachably connected and fixed, the connection stability of the metal connector 112 and the signal receiving unit 131 in the molding process of the insulator 111 can be improved, which is beneficial to improving the product yield of the cable accessory structure 100 in the processing process of the cable accessory structure 100.

Further, after a long period of use, the signal receiving unit 131, the insulator 111, and the like may be damaged or performance parameters may be degraded. At this time, the metal connector 112 can be reused only by removing the metal connector 112 from the signal receiving unit 131 and the insulator 111, thereby effectively reducing the processing cost of the cable accessory structure 100.

Further, in the present embodiment, an end of the metal joint 112 near the transmitting end 1112 is connected to the signal receiving unit 131 through a threaded fastener (not shown). Because the threaded fastener is a standard component, the processing cost is lower. Therefore, compared with other connection methods, the connection method through the threaded fastener not only facilitates the installation between the signal receiving unit 131 and the metal connector 112, but also further reduces the processing cost of the cable accessory structure 100.

Referring to fig. 2 again, in the present embodiment, the end of the terminal 1111 is opened with a protection slot 1114. The end of the metal fitting 112 distal to the transfer end 1112 is located within the shield 1114. Thus, the shield trench 1114 opens on the insulator 111.

Specifically, the positional relationship between the metal tab 112 and the shield groove 1114 includes the following two cases: first, the end of the metal tab 112 remote from the transmitting end 1112 extends into the shield 1114; second, the end of the metal tab 112 distal from the delivery end 1112 is flush with the inner wall of the guard channel 1114.

Therefore, when the metal connector 112 is fixed on the cable, the end connector on the cable or the conductor of the cable needs to extend into the protective groove 1114 to be connected with the metal connector 112, so the protective groove 1114 can play an insulating protection role on the joint of the metal connector 112 and the cable, the probability of electric shock of an operator caused by electric leakage at the joint of the metal connector 112 and the cable is greatly reduced, and the use safety of the cable accessory structure 100 is effectively improved.

Referring again to fig. 3, in one embodiment, the protective casing 121 includes a bottom plate 1213 and a side plate 1214 disposed along a circumference of the bottom plate 1213 and connected to the bottom plate 1213. The bottom plate 1213 and the side plate 1214 enclose a receiving cavity 1211. The signal transmission unit 132 is prefabricated inside the bottom plate 1213. The bottom plate 1213 is provided on an outer surface thereof with a wiring jack 122 electrically connected to the signal transmission unit. Specifically, the patch jack 122 is provided coaxially with the signal transmission unit 132. Therefore, the connection jack 122 and the signal transmitting unit 132 are both disposed on the bottom plate 1213, so that the connection jack 122 can directly contact with the signal transmitting unit 132 and realize electrical connection, and an auxiliary structure (such as an electric wire) for electrical connection between the signal transmitting unit 132 and the connection jack 122 is omitted, thereby greatly simplifying the structure of the cable accessory structure 100.

Referring again to fig. 4, in another embodiment, the protective shell 121 includes an outer insulating sleeve 1215 and an inner insulating sleeve 1216. The inner insulating sleeve 1216 is received within the outer insulating sleeve 1215. The outer wall of the inner insulating sleeve 1216 is attached to the inner wall of the outer insulating sleeve 1215. The signal transmitting unit 132 is prefabricated inside the sidewall of the heat insulating inner case 1216. Thus, the inner insulating sleeve 1216 has a receiving cavity 1211 that can receive the blocking member 110. The protective case 121 has a two-layer structure.

The insulating cover 1215 may be made of a material having a relatively high resistivity, such as rubber, silica gel, plastic, ceramic, etc., so that the insulating cover 1215 has a good point insulating property. Therefore, the insulating sheath 1215 can avoid the electric leakage and other situations when the cable accessory structure 100 is used for carrying out online parameter measurement on the cable, thereby not only preventing the occurrence of electric shock for operators and effectively improving the use safety of the cable accessory structure 100, but also ensuring the accuracy of online parameter measurement of the cable.

The inner heat-insulating sleeve 1216 may be made of heat-insulating materials such as asbestos, aerogel felt, foamed plastic, etc., so that the inner heat-insulating sleeve 1216 has good heat-insulating and heat-preserving properties. Thus, the arrangement of the heat insulation inner sleeve 1216 can ensure that the wireless power transmission module 130 can realize wireless transmission of parameter signals such as temperature and the like in an environment with relatively stable temperature, and further improve the accuracy of the online parameter test of the cable accessory structure 100.

Further, in the present embodiment, the insulator 111 and the insulating sheath 1215 are both of insulating silica gel structure. Since the silica gel has high adhesion, high temperature resistance, aging resistance and good electrical insulation performance, the insulator 111 and the insulating outer sleeve 1215 also have the advantages of high adhesion, high temperature resistance, aging resistance, good electrical insulation performance and the like. Therefore, the insulator 111 and the insulating sheath 1215 are both configured as an insulating silicone structure, so that the insulator 111 and the insulating sheath 1215 have good electrical insulating performance and long service life.

In the cable accessory structure 100, when on-line testing of parameters such as temperature in a cable is required, the metal connector 112 needs to be fixed on the cable and electrically connected to a sensor built in the cable, and then the data display device is inserted into the connection socket 122 and electrically connected to the connection socket 122, so that on-line testing can be performed. Therefore, the cable accessory structure 100 transmits the parameter information such as temperature and the like collected by the sensor arranged in the cable, and the accuracy of the online parameter test of the cable is greatly improved. Furthermore, the signal receiving unit 131 and the signal sending unit 132 which are respectively prefabricated in the plugging piece 110 and the dustproof piece 120 can realize wireless transmission of parameter signals such as temperature collected by the built-in sensor, effectively improve the charging distance of the wireless power transmission module 130, greatly improve the performance stability of the wireless power transmission module 130, and further improve the accuracy of on-line testing of cables. Therefore, the cable accessory structure 100 is used, so that the accuracy of the online parameter test of the cable is high.

The technical features of the embodiments described above may be arbitrarily combined, and for the sake of brevity, all possible combinations of the technical features in the embodiments described above are not described, but should be considered as being within the scope of the present specification as long as there is no contradiction between the combinations of the technical features.

The above-mentioned embodiments only express several embodiments of the present invention, and the description thereof is more specific and detailed, but not construed as limiting the scope of the invention. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the inventive concept, which falls within the scope of the present invention. Therefore, the protection scope of the present patent shall be subject to the appended claims.