CN117353056A - Armored cable and manufacturing method thereof - Google Patents

Abstract

The application relates to the technical field of armored cables and provides an armored cable and a manufacturing method thereof, wherein the armored cable comprises a connecting device, a first electric wire and a second electric wire; the connecting device comprises a shell, a plurality of wiring mechanisms and an auxiliary mechanism; the wiring mechanism and the auxiliary mechanism are arranged in the shell; the first electric wire and the second electric wire are armored wires; the first wire comprises a plurality of first wires; the second wire comprises a plurality of second wires, and the first wires and the second wires are connected to the wiring mechanism so as to be electrically conducted with the first wire through the wiring mechanism; the auxiliary mechanism is connected to each wiring mechanism, so that each wiring mechanism simultaneously wires the first wire and the second wire. According to the armored cable and the manufacturing method thereof, when the cable is damaged, the first wire is communicated with the second wire through the wiring mechanism, so that electric energy transmission is realized; when the wiring mechanism is used for wiring the first lead and the second lead, the auxiliary mechanism can lead each wiring mechanism to be simultaneously wired, so that the wiring is simple and quick, and the working efficiency is improved.

Description

Armored cable and manufacturing method thereof

Technical Field

The application relates to the technical field of armored cables, in particular to an armored cable and a manufacturing method thereof.

Background

An armored cable is a power cable with an armor layer covering the insulation layer of the exterior of the cable, the armor layer being used to protect the wires inside the cable from the external environment and damage. Armored cables are commonly used in environments where additional protection is required, such as in underground, subsea, high temperature or chemically corrosive environments, and are more widespread in power transmission, communication and control systems.

The armored cable in the related art is generally used for an environment needing additional protection, but is easily damaged in working due to the influence of severe external environment, the damaged cable needs to be treated in time, the current treatment mode is complicated, wires in the cable need to be wired one by one in sequence, so that the working efficiency is low due to time consumption, and the safety and the stability of the wired cable are poor.

Disclosure of Invention

The embodiment of the application provides an armored cable and a manufacturing method thereof, which can solve the technical problems that the working efficiency is low, and the safety and the stability are poor due to complex treatment after the armored cable is damaged in the related technology.

In a first aspect, embodiments of the present application provide an armored cable comprising:

The connecting device comprises a shell, a plurality of wiring mechanisms and an auxiliary mechanism; the wiring mechanism and the auxiliary mechanism are arranged in the shell;

a first wire, the first wire being an armoured wire; the first electric wire comprises a plurality of first wires, and one ends of the first wires are connected to the wiring mechanism in a one-to-one correspondence manner; and

a second wire, which is an armoured wire; the second electric wire comprises a plurality of second wires, and one ends of the second wires are connected to the wiring mechanism in a one-to-one correspondence manner so as to be electrically conducted with the first electric wire through the wiring mechanism;

the auxiliary mechanism is connected to each wiring mechanism and used for enabling each wiring mechanism to simultaneously wire the first wire and the second wire; the wiring mechanisms are uniformly distributed around the circumference of the auxiliary mechanism.

The technical scheme in the embodiment of the application has at least the following technical effects:

according to the armored cable, as the first electric wire and the second electric wire are both armored wires, the mechanical strength, the anti-interference capability and the corrosion resistance are high, so that the cable can stably run for a long time in a severe environment; when the cable is damaged, a plurality of first wires of the first wire are electrically conducted with a plurality of second wires of the second wire in the shell through each wiring mechanism so as to realize the transmission of electric energy between the first wire and the second wire; meanwhile, when the wiring mechanism is used for wiring the first wire and the second wire, as the auxiliary mechanism is connected with each wiring mechanism, each wiring mechanism can be used for wiring simultaneously, so that the complicated step that the first wire and the second wire in the cable need to be wired one by one is avoided, the time is saved, and the working efficiency is improved; because the wiring is carried out through the wiring device, the quality of wiring is improved, and the safety and the stability of the cable after wiring are enhanced.

In some embodiments, the wiring mechanism comprises:

the wire inlet component is arranged in the shell; a first wire inlet hole and a second wire inlet hole are sequentially formed in the wire inlet part along the axis direction of the wire inlet part; and

the wiring part is rotatably arranged on the outer wall of the wire inlet part; the wiring part is sequentially provided with a third wire inlet hole and a fourth wire inlet hole along the axis direction of the wire inlet part;

wherein the first wire inlet hole is communicated with the fourth wire inlet hole; the second wire inlet hole is communicated with the third wire inlet hole; one end of the first wire is arranged through the first wire inlet hole and the fourth wire inlet hole in a penetrating mode; one end of the second wire is arranged through the second wire inlet hole and the third wire inlet hole in a penetrating mode; the wire inlet parts of the wiring mechanisms are uniformly distributed around the circumference of the auxiliary mechanism, and the auxiliary mechanism is connected with the wiring parts of the wiring mechanisms.

In some embodiments, the wiring component comprises:

the wiring piece is rotatably arranged on the outer wall of the wire inlet component; the wiring piece is provided with the third wire inlet hole and the fourth wire inlet hole;

The transmission piece is fixedly arranged on the wiring piece; a kind of electronic device with high-pressure air-conditioning system;

the rotating piece is fixedly arranged on the transmission piece;

wherein the auxiliary mechanism is connected to the transmission member of each wiring mechanism.

In some embodiments, a first groove and a second groove are sequentially formed on the wire inlet component along the axial direction of the wire inlet component; the wire connector is located between the first groove and the second groove, and the first groove and the second groove are used for limiting the rotation of the wire connector.

In some embodiments, the junction block further comprises:

the first sliding block is arranged on one side of the wiring piece in a sliding manner and is positioned below the third wire inlet hole; a kind of electronic device with high-pressure air-conditioning system;

the second sliding block is arranged on the other side of the wiring piece in a sliding manner and is positioned below the fourth wire inlet hole;

the first sliding block is used for being in limit fit with the first groove; the second sliding block is used for being in limit fit with the second groove.

In some embodiments, the bottom of the wire connector is provided with a swivel connection; the top of the wire inlet component is provided with a connecting and matching part; the rotary connecting part is in rotary connection fit with the connection fitting part.

In some embodiments, the auxiliary mechanism comprises:

two support frames fixed inside the shell; and

the two auxiliary rings are respectively arranged on the two supporting frames; the two auxiliary rings are oppositely arranged, and each transmission piece is positioned between the two auxiliary rings; auxiliary gear teeth are arranged on one side, facing the transmission piece, of the auxiliary ring; the peripheral outer side wall of the transmission piece is provided with transmission teeth which are meshed with the auxiliary gear teeth; the wire inlet parts are positioned on the inner side of the auxiliary ring and are uniformly distributed around the circumference of the auxiliary ring.

In some embodiments, the support stand comprises:

a center rod fixed to the inside of the housing; the axis of each central rod is arranged in line with the axis of the auxiliary ring; and

the support assembly comprises a plurality of support rods and a plurality of support pieces, and one ends of the support rods are vertically arranged on the center rod; the support piece is positioned on one side of the support rod facing the auxiliary ring; one end of the supporting piece is vertically arranged at the other end of the supporting rod in a one-to-one correspondence manner; the other end of the supporting piece is in sliding fit with one side of the auxiliary ring, which faces away from the auxiliary gear teeth.

In some embodiments, a limiting ring groove is formed in one side of the auxiliary ring, which is away from the transmission piece; one end of the supporting piece is provided with a sliding limiting part which is in sliding fit with the limiting ring groove.

In a second aspect, embodiments of the present application provide a method for manufacturing an armored cable, including:

acquiring a connecting device, a first electrical property and a second electrical wire;

connecting a plurality of first wires of the first electric wire to each wiring mechanism of the connecting device in a one-to-one correspondence manner;

connecting a plurality of second wires of the second electric wire to each wiring mechanism of the connecting device in a one-to-one correspondence manner;

and carrying out wiring operation on one of the wiring mechanisms so as to lead the other wiring mechanisms to simultaneously carry out wiring on the first wires and the second wires through the auxiliary mechanism, thereby leading each first wire to be respectively electrically conducted with each second wire.

The technical scheme in the embodiment of the application has at least the following technical effects:

the armored cable provided by the embodiment of the application is characterized in that a connecting device, first electrical property and second electrical wires are obtained; the first electric wire and the second electric wire are armored wires, so that the cable has high mechanical strength, high anti-interference capability and high corrosion resistance, and can stably work for a long time in a severe environment; when the cable is damaged due to severe environmental influence, a plurality of first wires of the first wire are electrically connected with a plurality of second wires of the second wire in the shell through each wiring mechanism, so that electric energy is conveyed between the first wire and the second wire; meanwhile, when the wiring mechanism is used for wiring the first wire and the second wire, as the auxiliary mechanism is connected with the wiring mechanisms, the wiring mechanisms can be used for wiring simultaneously, so that the complicated step that the first wire and the second wire in the cable need to be wired one by one is avoided, the time is saved, and the working efficiency is improved; because the wiring is carried out by using the wiring device, the quality of wiring is improved, and the safety performance and stability of the cable after wiring are improved.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present application, the drawings that are required for the embodiments or the description of the prior art will be briefly described below, it being obvious that the drawings in the following description are only some embodiments of the present application, and that other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

Fig. 1 is a schematic structural diagram of an armored cable according to an embodiment of the present disclosure;

fig. 2 is a schematic structural diagram of a first electric wire according to an embodiment of the present application;

fig. 3 is a schematic diagram of an internal structure of a connection device according to an embodiment of the present application;

fig. 4 is a schematic structural diagram of a wiring mechanism and an auxiliary mechanism in cooperation provided in an embodiment of the present application;

fig. 5 is a schematic structural diagram of an incoming line component according to an embodiment of the present application;

fig. 6 is a schematic structural diagram of a wiring member according to an embodiment of the present application;

fig. 7 is a schematic cross-sectional view of a wire inlet component and a wire connecting component according to an embodiment of the present application;

fig. 8 is a schematic structural diagram of an auxiliary mechanism according to an embodiment of the present disclosure;

FIG. 9 is a schematic structural view of a support assembly according to an embodiment of the present disclosure;

Fig. 10 is a schematic structural diagram of a housing according to an embodiment of the present application.

Wherein, each reference sign in the figure:

100. an armored cable; 10. a connecting device; 11. a housing; 1101. a wire hole; 111. an insulating member; 112. a first sub-housing; 1121. a first screw; 113. a second sub-housing; 1131. a second screw; 114. a fastener; 11101. a wire guide; 12. a wiring mechanism; 121. a wire inlet component; 12101. a first wire inlet hole; 12102. a second wire inlet hole; 12103. a first groove; 12104. a second groove; 1211. a connection mating portion; 122. a wiring member; 12201. a third wire inlet hole; 12202. a fourth wire inlet hole; 1221. a wiring member; 12211. a rotary connection part; 1222. a transmission member; 12221. a drive tooth; 1223. a rotating member; 1224. a first slider; 1225. a second slider; 1226. a movable member; 1227. a junction cover; 13. an auxiliary mechanism; 131. a support frame; 132. an auxiliary ring; 13201. a limit ring groove; 1321. auxiliary gear teeth; 1311. a central rod; 1312. a support assembly; 13121. a support rod; 13122. a support; 131221, a sliding limit part; 20. a first electric wire; 21. a first wire; 30. a second electric wire; 31. and a second wire.

Detailed Description

In order to make the technical problems, technical schemes and beneficial effects to be solved by the present application more clear, the present application is further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the present application.

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 application belongs; the terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the application. The terms "comprising" and "having" and any variations thereof in the description and claims of the present application and in the description of the figures above are intended to cover non-exclusive inclusions.

It will be understood that when an element is referred to as being "mounted" or "disposed" on another element, it can be directly on the other element or be indirectly on the other element. When an element is referred to as being "connected to" another element, it can be directly connected to the other element or be indirectly connected to the other element.

It is to be understood that the terms "length," "width," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," and the like indicate or are based on the orientation or positional relationship shown in the drawings, merely to facilitate description of the present application and simplify description, and do not indicate or imply that the devices or elements referred to must have a particular orientation, be configured and operated in a particular orientation, and therefore should not be construed as limiting the present application.

Furthermore, the terms "first," "second," and the like, are used for descriptive purposes only and are not to be construed as indicating or implying a relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defining "a first" or "a second" may explicitly or implicitly include one or more such feature. In the description of the present application, the meaning of "a plurality" is two or more, unless explicitly defined otherwise.

In the present application, "and/or" is merely one association relationship describing the association object, meaning that three relationships may exist; for example, a and/or B may represent: a exists alone, A and B exist together, and B exists alone. In addition, the character "/" herein generally indicates that the front and rear associated objects are an "or" relationship.

It is noted that in this application, words such as "in some embodiments," "illustratively," "for example," and the like are used to indicate examples, illustrations, or descriptions. Any embodiment or design described herein as "in some embodiments," "illustratively," "for example," should not be construed as preferred or advantageous over other embodiments or designs. Rather, the use of words such as "in some embodiments," "illustratively," "for example," and the like is intended to present related concepts in a concrete fashion, meaning that a particular feature, structure, or characteristic described in connection with an embodiment may be included in at least one embodiment of the present application. The appearances of the phrase in various places in the specification are not necessarily all referring to the same embodiment, nor are separate or alternative embodiments mutually exclusive of other embodiments. Those of skill in the art will explicitly and implicitly appreciate that the embodiments described herein may be combined with other embodiments.

An armored cable is a power cable with an armor layer covering the insulation layer of the exterior of the cable, the armor layer being used to protect the wires inside the cable from the external environment and damage. Armored cables are commonly used in environments where additional protection is required, such as in underground, subsea, high temperature or chemically corrosive environments, and are more widespread in power transmission, communication and control systems.

The armored cable in the related art is generally used in an environment needing additional protection, but is easily damaged in working due to the influence of severe external environment, the damaged cable needs to be treated in time, the current treatment mode is complicated, wires in the cable need to be wired one by one in sequence, so that the working efficiency is low due to time consumption, and the safety and the stability of the cable after the cable is poor.

Based on the above, in order to solve the technical problems that after an armored cable in the related art is damaged, the processing is complicated, so that the working efficiency is low, and the safety and the stability are poor, the following scheme is provided in the embodiment of the application.

Referring to fig. 1 to 3 and 5, an armored cable 100 is provided in the embodiment of the present application, the armored cable 100 includes a connecting device 10, a first electric wire 20 and a second electric wire 30, wherein:

The connection device 10 includes a housing 11, a plurality of wiring mechanisms 12, and an auxiliary mechanism 13; the wiring mechanism 12 and the auxiliary mechanism 13 are provided inside the housing 11.

The first wire 20 is an armoured wire; the first electric wire 20 includes a plurality of first wires 21, and one ends of the first wires 21 are connected to the wiring mechanism 12 in a one-to-one correspondence.

The second wire 30 is an armoured wire; the second wire 30 includes a plurality of second wires 31, and one ends of the second wires 31 are connected to the wiring mechanism 12 in a one-to-one correspondence manner, so as to be electrically connected to the first wire 20 through the wiring mechanism 12.

Wherein the auxiliary mechanism 13 is connected to each wiring mechanism 12, and is used for enabling each wiring mechanism 12 to simultaneously wire the first wire 21 and the second wire 31; the wiring members 12 are uniformly distributed around the circumference of the auxiliary mechanism 13, and the case where the number of wiring members 12 is three and uniformly distributed around the circumference of the auxiliary mechanism 13 is exemplarily shown in fig. 3 and 4.

It will be appreciated that the wiring mechanism 12 may be any mechanism capable of connecting a damaged cable, such as, but not limited to, a mechanism that wires by rotational movement of a component. The assist mechanism 13 may be any mechanism capable of simultaneously operating the respective wiring mechanisms 12, and may be, for example, an assist linkage (mechanism capable of linking members to each other) device or the like, but is not limited thereto. The circumferentially uniform distribution may be such that the wiring members 12 are uniformly circumferentially distributed around the auxiliary mechanism 13.

The armoured wire is a wire with a metal sheath, and the material of the armoured wire can be galvanized steel tape or aluminum tape, so that the armoured wire has high strength and corrosion resistance, and can better resist the influence of external mechanical pressure, chemical substances, flame and other severe environmental conditions, so as to ensure the safe and reliable operation of the cable. The armoured wire has a plurality of conductors inside.

As can be seen from the above, the armored cable 100 provided in the embodiment of the present application has high mechanical strength, anti-interference capability and corrosion resistance, so that the cable can stably operate for a long time in a severe environment, because the first electric wire 20 and the second electric wire 30 are both armored wires; when the cable is damaged, the plurality of first conducting wires 21 of the first electric wire 20 are electrically conducted with the plurality of second conducting wires 31 of the second electric wire 30 in the shell 11 through the wiring mechanisms 12 so as to realize the transmission of electric energy between the first electric wire 20 and the second electric wire 30; meanwhile, when the wiring mechanism 12 is used for wiring the first wire 21 and the second wire 31, as the auxiliary mechanism 13 is connected to each wiring mechanism 12, each wiring mechanism 12 can be used for wiring at the same time, so that the complicated step that the first wire 21 and the second wire 31 in the cable need to be wired one by one is avoided, and therefore, the time is saved and the working efficiency is improved; because the wiring is carried out through the wiring device, the quality of wiring is improved, the safety and the stability of the cable after wiring are enhanced, and the armored wire can be protected more.

In some embodiments, referring to fig. 3, 5 and 6, the wiring mechanism 12 includes a wire inlet member 121 and a wire outlet member 122, wherein:

the wire inlet part 121 is arranged inside the shell 11; the wire inlet member 121 is provided with a first wire inlet hole 12101 and a second wire inlet hole 12102 in sequence along the axial direction of the wire inlet member 121.

The wire connection part 122 is rotatably provided at an outer wall of the wire inlet part 121; the wire connection part 122 is sequentially provided with a third wire hole 12201 and a fourth wire hole 12202 along the axial direction of the wire feeding part 121.

Wherein the first wire inlet 12101 is in communication with the fourth wire inlet 12202; the second wire inlet 12102 communicates with the third wire inlet 12201; one end of the first wire 21 is inserted through the first wire hole 12101 and the fourth wire hole 12202; one end of the second wire 31 is inserted through the second wire hole 12102 and the third wire hole 12201; the extension lines of the holes formed by the connection of the first wire inlet 12101 and the fourth wire inlet 12202 are crossed with the extension lines of the holes formed by the connection of the second wire inlet 12102 and the third wire inlet 12201, and the first wires 21 penetrating through the first wire inlet 12101 and the fourth wire inlet 12202 are crossed with the second wires 31 penetrating through the second wire inlet 12102 and the third wire inlet 12201. The wiring member 122 is used to connect the first wire 21 with the second wire 31. The wire-feeding members 121 of the respective wiring mechanisms 12 are uniformly distributed around the circumferential direction of the auxiliary mechanism 13, and the auxiliary mechanism 13 is connected to the wire-connecting members 122 of the respective wiring mechanisms 12.

It is to be understood that the wire-feeding member 121 may be various members capable of freely inserting or extracting the first electric wire 20 and the second electric wire 30, for example, a block member having a wire-feeding portion formed therein or a cylindrical member having a wire-feeding portion formed therein, but is not limited thereto. The connection member 122 may be various members capable of firmly connecting the first wire 21 and the second wire 31, for example, but not limited to, a member that drives the first wire 21 and the second wire 31 to be connected by a rotating member.

So configured, when it is desired to connect the first wire 20 with the second wire 30 (e.g., connect the two wires after the cable is damaged), the first wire 21 of the first wire 20 is inserted into the first wire-in hole 12101 of the wire-in member 121 and the fourth wire-in hole 12202 of the wire-connecting member 122, and is inserted out of the fourth wire-in hole 12202. The second wire 31 of the second electric wire 30 is threaded into the second wire-in hole 12102 of the wire-in member 121 and the third wire-in hole 12201 of the wire-connecting member 122, and is threaded out of the third wire-in hole 12201; when the first wire 21 and the second wire 31 pass through the hole, the rotating wire connecting member 122 rotates, so as to drive the wire connecting portion (i.e. crossing portion) of the first wire 21 and the second wire 31 in the wire connecting member 122 to wind and connect. Because the first wire 21 passes through the fourth wire inlet 12202 and the second wire 31 passes through the third wire inlet 12201, the length of the wire connecting between the first wire 21 and the second wire 31 can be reserved enough to be screwed, and when the wire connecting piece 1221 is connected in a rotating manner, the ends of the first wire 21 and the second wire 31 can be retracted into the holes due to the rotation force by winding the first wire 21 and the second wire 31, so that other parts outside the holes cannot be interfered, and more accurate and stable wire connection can be achieved. Since the junction (i.e., the intersection) of the first wire 21 and the second wire 31 is located between the wire inlet part 121 and the wire connecting part 122 after the wire connection, the junction of the first wire 21 and the second wire 31 is protected, and further, the wire is prevented from being damaged again due to the influence of the severe environment in the external environment due to direct leakage of the junction, so that the wire is safer and more stable.

Optionally, in some embodiments, referring to fig. 6 and 7, the wiring component 122 includes a wiring member 1221, a transmission member 1222, and a rotation member 1223. The wire connecting piece 1221 is rotatably arranged on the outer wall of the wire inlet part 121; the wire connecting piece 1221 is provided with a third wire inlet 12201 and a fourth wire inlet 12202. The transmission member 1222 is fixedly disposed on the junction element 1221. The rotary member 1223 is fixedly disposed on the transmission member 1222. Wherein the auxiliary mechanism 13 is connected to the transmission member 1222 of each wiring mechanism 12.

It is to be understood that the wire connecting member 1221 may be various members capable of connecting two wires damaged or broken, for example, may be a cylindrical, conical, or block-shaped structure having a through hole or a hole formed therein, etc., but is not limited thereto. The transmission member 1222 may be various members capable of rotationally moving the transmission member, for example, but not limited to, a gear, etc. The rotary member 1223 may be any of various components capable of moving the transmission member 1222, such as, but not limited to, a knob or a rotatable cylinder, cone or a rotatable block structure.

So configured, since the first wire 21 of the first electric wire 20 passes through the first wire hole 12101 of the wire inlet member 121 and the fourth wire hole 12202 of the wire connecting member 1221, and passes out of the fourth wire hole 12202; since the second wire 31 of the second electric wire 30 is threaded into the second wire-in hole 12102 of the wire-in member 121 and the third wire-in hole 12201 of the wire-in member 1221, and is threaded out of the third wire-in hole 12201. The first and second wires 21 and 31 are connected inside the connector 1221, so that the connection between the first and second wires 21 and 31 is safe and stable. The rotation member 1223 is rotated to drive the transmission member 1222 to rotate, so that the connection member 1221 is driven by the transmission member 1222 to rotate to twist the first wire 21 and the second wire 31 together, thereby connecting the first wire 21 and the second wire 31. Therefore, the wiring component 122 can more conveniently connect the first wire 21 and the second wire 31, and greatly improve the firmness and safety of wiring, and meanwhile, the steps of wiring are simplified, time and manpower are saved, and further the working efficiency is improved.

Alternatively, referring to fig. 5 to 7, the first wire hole 12101 is inclined to the axis of the wire member 121 and extends toward the fourth wire hole 12202 of the wire member 122, and the first wire hole 12101 and the fourth wire hole 12202 extend on the same extension line, i.e., in the same extension direction. The second wire hole 12102 is inclined to the axis of the wire member 121 and extends toward the third wire hole 12201 of the wire member 122, and the second wire hole 12102 and the third wire hole 12201 are on the same extension line, i.e., the extending directions of the two are identical. The first wire hole 12101 intersects the second wire hole 12102.

So configured, when it is desired to connect the first wire 20 to the second wire 30 (e.g., to connect the two wires after the cable is damaged). The first wire 21 is conveniently inserted into the first wire inlet 12101 inclined to the axis of the wire inlet member 121, is inserted into the intersection of the first wire inlet 12101 and the second wire inlet 12102, and then smoothly continues to be inserted into the fourth wire inlet 12202 of the wire connecting member 122 and extends out of the hole. The second wire 31 is inserted into the second wire hole 12102 inclined to the axis of the wire-feeding member 121 and is inserted into the intersection of the first wire hole 12101 and the second wire hole 12102, and then smoothly continues to be inserted into the third wire hole 12201 of the wire-connecting member 122 and extends out of the hole, and at this time, the first wire 21 and the second wire 31 form a wire intersection at the intersection of the first wire hole 12101 and the second wire hole 12102. Because of the inclination direction setting reason of the holes, the first wires 21 and the second wires 31 are easier to cross, and the crossing angle is more suitable for the angle of wiring, so as to achieve the stability, the firmness and the safety of wiring. The rotation member 1223 is rotated to drive the transmission member 1222 to rotate, so that the connection member 1221 is driven by the transmission member 1222 to rotate to twist the first wire 21 and the second wire 31 together, thereby connecting the first wire 21 and the second wire 31. Therefore, the wiring part 122 can more conveniently connect the first wire 21 and the second wire 31, greatly improve the firmness and stability of wiring, simplify the wiring steps, save a great deal of time and effort, and improve the working speed and further the working efficiency.

Alternatively, referring to fig. 4 and 7, the junction block 122 includes two movable members 1226 and two junction caps 1227. The two moving parts 1226 are respectively disposed at the top of the third wire inlet 12201 and the top of the fourth wire inlet 12202. One ends of the two movable members 1226 are respectively disposed on the outer walls of the wire connecting members 1221. The two wire covers 1227 are respectively provided at the other ends of the two movable pieces 1226 such that the two wire covers 1227 can open or close the top openings of the third wire hole 12201 and the fourth wire hole 12202 by moving the respective connected movable pieces 1226 with respect to the wire piece 1221.

It is understood that the movable member 1226 may be a variety of components capable of moving the wire cover 1227, such as, but not limited to, a hinge connection, a spring member, etc. The junction cap 1227 may be a variety of caps that are movable on the junction block 122 by a movable member 1226. The material of the junction cover 1227 may be an insulating material, for example, may be plastic or rubber, etc., but is not limited thereto.

So configured, when the first wire 20 needs to be connected with the second wire 30 (for example, when the two wires are connected after the cable is damaged), the first wire 21 of the first wire 20 is inserted into the first wire hole 12101 of the wire inlet member 121 and is inserted into the fourth wire hole 12202 of the wire inlet member 122 and extends to the outside of the fourth wire hole 12202, the first wire 21 is inserted into the first wire hole 12101 of the wire inlet member 121 and the fourth wire hole 12202 of the wire inlet member 122 without resistance, but when the first wire 21 is continuously inserted into the fourth wire hole 12202, the first wire 21 contacts the wire cover 1227 to receive resistance, when the resistance is just sensed, the first wire 21 is proved to be just contacted with the wire cover 1227, and the wire cover 1227 is continuously inserted (for example, continuously inserted into 0.5 cm to 3 cm) out of the fourth wire hole 12202, and when the first wire 21 is inserted into the hole, the wire cover 1227 is moved by the force of the first wire 21 and is temporarily abutted against the first wire 12221 under the action of the movable member 1226, and the wire is threaded.

Similarly, after the second wire 31 of the second wire 30 is threaded into the second wire hole 12102 of the wire-feeding member 121 and is threaded into the third wire hole 12201 of the wire-feeding member 122 and extends to the outside of the third wire hole 12201, the second wire 31 is threaded into the second wire hole 12102 of the wire-feeding member 121 and the third wire hole 12201 of the wire-feeding member 122 without resistance, but when the second wire 31 is threaded out of the third wire hole 12201, the second wire 31 is contacted with the wire-connecting cover 1227 to receive resistance, when the resistance is just sensed, the second wire 31 is just contacted with the wire-connecting cover 1227, and the wire-connecting cover 1227 is threaded out of the third wire-connecting hole 12201 (for example, continuously threaded by 0.5 cm to 3 cm) against the resistance, and when the second wire 31 is threaded out of the hole, the wire-connecting cover 1227 is moved by the force of the second wire 31 under the action of the moving member 1226 and temporarily leaned against the second wire-connecting cover 1227, at this time, the threading is completed.

When the first wire 21 and the second wire 31 are all threaded, when one group of the first wire 21 and the second wire 31 is connected, the rotating member 1223 of the wiring member 122 where the group of the first wire 21 and the second wire 31 are located is screwed to drive the corresponding driving member 1222 and the wiring member 1221 to rotate for wiring, and when the first wire 21 and the second wire 31 are wired, the first wire 21 and the second wire 31 are slowly retracted to the crossing position of the first wire hole 12101 and the second wire hole 12102 due to the rotation of the wiring member 1221, and the wiring cover 1227 is returned under the action of the moving member 1226 when the first wire 21 and the second wire 31 are retracted. Through the effect of wiring lid 1227, can make the specific position that operating personnel can know first wire 21 and second wire 31 more clearly to reserve sufficient extension, and more accurate connect first wire 21 and second wire 31, still have simultaneously and cover third inlet wire hole 12201 and fourth inlet wire hole 12202 respectively after the wiring is accomplished two wiring lid 1227 lids, so that the crossing position plays safer, stable guard action. The auxiliary mechanism 13 is connected to the transmission members 1222 of each wiring mechanism 12, so that the auxiliary mechanism 13 drives each wiring mechanism 12 to make each transmission member 1222 simultaneously wire each first wire 21 and each second wire 31, thereby further improving the convenience of wiring and the safety of wiring, and improving the working efficiency.

Alternatively, referring to fig. 5 and 6, a first groove 12103 and a second groove 12104 are sequentially formed on the wire inlet member 121 in the axial direction of the wire inlet member 121. The wire 1221 is positioned between the first groove 12103 and the second groove 12104, the first groove 12103 and the second groove 12104 serving to limit rotation of the wire 1221.

It is understood that the first groove 12103 and the second groove 12104 may be various grooves capable of being engaged with other components, for example, but not limited thereto, square grooves, rectangular grooves, circular grooves, or the like.

So set up, when the wiring member 1221 rotates under the drive of the transmission member 1222, and then the first wire 21 and the second wire 31 are connected, after the connection is completed, the first groove 12103 and the second groove 12104 are used for limiting the rotation of the wiring member 1221, so as to avoid the connection of the first wire 21 and the second wire 31 from loosening or breaking after being damaged again due to the influence of the external environment, and further improve the safety and stability of the connection of the first wire 21 and the second wire 31 due to the limitation of the rotation of the wiring member 1221, and simultaneously improve the working efficiency.

Further, referring to fig. 6, the wiring member 122 further includes a first sliding block 1224 and a second sliding block 1225. The first sliding block 1224 is slidably disposed on one side of the wire connecting member 1221 and located below the third wire inlet 12201. The second sliding block 1225 is slidably disposed on the other side of the wire connecting piece 1221 and below the fourth wire inlet 12202. Wherein, the first sliding block 1224 is used for being in limit fit with the first groove 12103; the second sliding block 1225 is adapted to be in a limit fit with the second recess 12104.

It is understood that the first and second sliding blocks 1224 and 1225 (which may be sliding structures that mate through bumps and grooves) may be various block structures that are capable of sliding freely over the wire connector 1221.

When the wire connecting piece 1221 is driven by the transmission piece 1222 to perform rotational movement, and then the first wire 21 and the second wire 31 are connected, after the wire connecting is completed, the first sliding block 1224 on the wire connecting piece 1221 slides to the position of the first groove 12103, and the second sliding block 1225 on the wire connecting piece 1221 slides to the position of the second groove 12104, so that the first sliding block 1224 performs limit fit with the first groove 12103, and the second sliding block 1225 performs limit fit with the second groove 12104, so as to avoid the connection part of the first wire 21 and the second wire 31 from loosening or breaking due to the influence of the outside, and the limit fit of the first sliding block 1224 and the first groove 12103, and the limit fit of the second sliding block 1225 and the second groove 12104, thereby avoiding loosening or breaking due to the long time or the influence of the external environment on the wire connecting part, and further ensuring the reliability and stability of the connection part of the first wire 21 and the second wire 31, and further improving the safety.

Further, referring to fig. 5 and 6, the bottom of the wire connecting member 1221 is provided with a rotary connecting portion 12211. The top of the incoming line part 121 is provided with a connection mating part 1211. The rotary connecting portion 12211 is rotationally coupled to the coupling fitting portion 1211.

It is to be understood that the rotation connection portion 12211 may be various structures capable of performing the mating connection rotation with the connection mating portion 1211, for example, may be a protrusion structure or a groove structure, etc., but is not limited thereto. The connection fitting portion 1211 may be various members capable of being rotated in fit connection with the rotation connection portion 12211, and may be, for example, a groove structure, a protrusion structure, or the like, but is not limited thereto.

So set up, because there is rotary connection portion 12211 on the bottom of wire connecting piece 1221, and the top of wire inlet component 121 is equipped with connection mating portion 1211, when through rotary wire connecting piece 1221, rotary connection portion 12211 of wire connecting piece 1221 bottom can cooperate with connection mating portion 1211 at wire inlet component 121's top (rotary connection portion 12211 and connection mating portion 1211 can be the built-in part or can be detachable and freely install the part on wire connecting piece 1221 or wire inlet component 121), can make the electric wire wiring after the damage simpler through the cooperation of rotary connection portion 12211 and connection mating portion 1211 each other, the time consuming is also less, when first wire 21 and second wire 31 are connected, the rethread first slider 1224 carries out spacing cooperation with first recess 12103, second slider 1225 carries out spacing cooperation with second recess 12104, make the junction of first wire 21 and second wire 31 has improved stability and security, work efficiency further.

Optionally, referring to fig. 4, 6 and 8, the auxiliary mechanism 13 includes two supporting frames 131 and two auxiliary rings 132. Two support brackets 131 are fixed to the inside of the housing 11. The two auxiliary rings 132 are rotatably disposed on the two supporting frames 131, respectively. The two auxiliary rings 132 are oppositely arranged, and each transmission piece 1222 is positioned between the two auxiliary rings 132; the auxiliary ring 132 is provided at a side facing the transmission member 1222 with a plurality of auxiliary gear teeth 1321, and each auxiliary gear tooth 1321 is uniformly arranged in the circumferential direction of the auxiliary ring 132. A plurality of driving teeth 12221 are provided on the circumferential outer side wall of the driving member 1222, and the driving teeth 12221 are engaged with the auxiliary gear teeth 1321; the wire feeding members 121 are located inside the auxiliary ring 132 and are uniformly distributed around the circumference of the auxiliary ring 132.

It is understood that the supporting frame 131 may be various frames capable of supporting the auxiliary ring 132, for example, may be a supporting frame 131 composed of one or more rods or columns, etc., but is not limited thereto. The material of the supporting frame 131 may be, but not limited to, plastic or insulator. The auxiliary ring 132 may be various kinds of auxiliary rings 132 rotatably provided on the supporting frame 131. In the engaged condition, the transmission teeth 12221 of one of the transmission members 1222 drive the auxiliary ring 132 to rotate through the auxiliary gear teeth 1321; after the auxiliary ring 132 rotates, the auxiliary gear teeth 1321 on the auxiliary ring 132 are meshed with the gear teeth 12221 of the other transmission members 1222 to drive the transmission members 1222 of the other connection members 122 to rotate, so as to drive the connection members 1221 on the connection members 122 to rotate, and connect the plurality of first wires 21 and the plurality of second wires 31 penetrating through the connection members 122.

So configured, when one of the first wires 21 and the second wires 31 is connected, the corresponding transmission member 1222 and the corresponding connection member 1221 are driven to rotate by screwing the rotation member 1223 of the connection member 122 where the first wire 21 and the second wire 31 are located, so that the transmission member 1222 drives the transmission teeth 12221 to rotate, and simultaneously, the auxiliary teeth 1321 on the auxiliary ring 132 are meshed with the transmission teeth 12221 on the transmission member 1222, after the auxiliary teeth 1321 are meshed with the transmission teeth 12221, the transmission teeth 12221 drive the auxiliary teeth 1321 to rotate, and then the auxiliary teeth 1321 drive the two oppositely arranged auxiliary rings 132 to rotate, and after the two oppositely arranged auxiliary teeth 132 are rotated, the auxiliary teeth 1321 on the auxiliary ring 132 drive the transmission teeth 12221 of each connection member 122 to rotate through the meshing with the transmission teeth 12221 on the other transmission member 1222, and drive each connection member 1221 on each connection member 122 to rotate, so that a plurality of first wires 21 and a plurality of second wires 31 penetrating each connection member 122 are connected. Therefore, the first wire 21 and the second wire 31 are connected, and the transmission teeth 12221 and the auxiliary gear teeth 1321 are meshed to drive the connection parts 122 to work simultaneously, so that damaged wires can be connected rapidly, the complicated step that one strand of wires are needed manually is reduced, and further the working efficiency and the working speed are improved.

Further, referring to fig. 8, the support bracket 131 includes a central rod 1311 and two support assemblies 1312, wherein:

the center rod 1311 is fixed to the inside of the housing 11; the axis of each center rod 1311 is disposed collinear with the axis of the auxiliary ring 132.

Two support members 1312 are secured to each end of the central rod 1311. The support assembly 1312 includes a plurality of support rods 13121 and a plurality of support members 13122, with one end of the support rods 13121 being vertically disposed on the central rod 1311. The support 13122 is located on a side of the support bar 13121 facing the auxiliary ring 132. One end of the supporting member 13122 is vertically disposed at the other end of the supporting bar 13121 in one-to-one correspondence. The other end of the support 13122 is a sliding fit with the side of the auxiliary ring 132 facing away from the auxiliary cog 1321.

It will be appreciated that the central rod 1311 may be of various rod-like configurations capable of providing secure attachment of other components upon attachment to the housing 11. The support 13122 may be various components that can be used to support the stabilization of the auxiliary ring 132, for example, but not limited thereto, the support 13122 may be composed of a plurality of columnar structures, or the like.

So configured, when one of the first wires 21 and the second wires 31 is connected, the corresponding transmission member 1222 and the corresponding connection member 1221 are driven to rotate by screwing the rotation member 1223 of the connection member 122 where the first wire 21 and the second wire 31 are located, and the transmission member 1222 drives the transmission teeth 12221 to rotate, so that the auxiliary gear teeth 1321 on the auxiliary ring 132 and the transmission teeth 12221 on the transmission member 1222 perform meshing motion, and meanwhile, since the support member 13122 on the support rod 13121 is in sliding fit with one side of the auxiliary ring 132 facing away from the auxiliary gear teeth 1321, and the auxiliary ring 132 rotates steadily under the support effect of the support member 13122 through sliding fit, the auxiliary gear teeth 1321 and the transmission teeth 12221 perform meshing rotation. When the two opposite auxiliary rings 132 rotate, the auxiliary gear teeth 1321 on the auxiliary rings 132 are meshed with the gear teeth 12221, so that the auxiliary gear teeth 1321 drive the gear teeth 12221 of each wire connecting component 122 to rotate, and drive each wire connecting component 1221 on each wire connecting component 122 to rotate by the rotation of each gear tooth 12221, so that the plurality of first wires 21 and the plurality of second wires 31 penetrating through each wire connecting component 122 are connected. Therefore, the first wire 21 and the second wire 31 are connected, the transmission teeth 12221 and the auxiliary gear teeth 1321 are meshed to drive the connection parts 122 to work, so that the stability during connection is improved, damaged wires can be quickly connected, the working efficiency and the working speed are improved, and the stability and the safety are further improved.

Further, referring to fig. 8 and 9, a limiting ring groove 13201 is formed on a side of the auxiliary ring 132 facing away from the transmission member 1222. One end of the support 13122 is provided with a sliding limiting portion 131221, and the sliding limiting portion 131221 is in sliding fit with the limiting ring groove 13201.

It is understood that the retaining ring groove 13201 can be a variety of ring grooves that can limit movement of the component. The slide stopper 131221 may have various structures capable of sliding in the stopper ring groove 13201, and may be, for example, a protrusion or the like, but is not limited thereto.

So set up, when connecting first wire 21 and second wire 31 by wiring part 122, rotate rotating member 1223 earlier, and then drive the rotation of transmission piece 1222, simultaneously, auxiliary teeth 1321 on auxiliary ring 132 meshes with transmission teeth 12221 on the transmission piece 1222, and by spacing annular 13201 and the slip spacing portion 131221 both sliding fit on support piece 13122 of seting up on auxiliary ring 132, so can make the more steady drive other each wiring mechanism 12 simultaneous working of auxiliary ring 132, and then make the wiring work simpler, save more time, convenient operation has reduced the loaded down with trivial details step of manual work needs one ply to carry out the wiring, further improved the stability and the security of device wiring.

Further, in some embodiments, referring to fig. 10, wire holes 1101 are formed at both ends of the housing 11 for allowing the first wire 20 and the second wire 30 to enter the housing 11, respectively. The two ends of the interior of the housing 11 are provided with the insulating members 111, the two supporting frames 131 are respectively positioned at the two ends of the interior of the housing 11, and the center rods 1311 of the two supporting frames 131 are respectively fixed on the two insulating members 111. The insulating members 111 are provided with a plurality of wire guides 11101, wherein the wire guides 11101 of one insulating member 111 are penetrated by the first wires 21 of the first wires 20, and the wire guides 11101 of the other insulating member 111 are penetrated by the second wires 31 of the second wires 30.

It is to be understood that the insulating member 111 may be various members capable of preventing liquid, gas, etc. from entering the inside of the apparatus, thereby protecting the inside of the apparatus, and may be, for example, a circular plate-like or sheet-like structure, etc., but is not limited thereto.

So set up, after inserting first electric wire 20 and second electric wire 30 respectively into wire hole 1101 at casing 11 both ends, pass first wire 21 and second wire 31 respectively through wire hole 11101 on two insulating member 111, make first wire 21 get into first inlet 12101 and fourth inlet 12202, second wire 31 gets into second inlet 12102 and third inlet 12201, and then make wiring member 1221 wire first wire 21 and second wire 31, through insulating member 111 can make first wire 21 and second wire 31 part of electric wire isolate inside, avoid damaging the electric wire once more because of abominable external environment, further promote the security of electric wire.

Alternatively, referring to fig. 10, the housing 11 includes a first sub-housing 112, a second sub-housing 113, and a fastener 114, the first sub-housing 112 and the second sub-housing 113 being engaged to form an accommodating space therebetween, and the wiring mechanism 12 and the auxiliary mechanism 13 being disposed in the accommodating space. The outer wall of the first sub-housing 112 is provided with a first screw member 1121, the outer wall of the second sub-housing 113 is provided with a second screw member 1131, the first screw member 1121 and the second screw member 1131 are spliced to form a screw column structure, and the first screw member 1121 and the second screw member 1131 are of a semi-column structure or a semi-shell structure. The fastener 114 is screwed on a threaded column structure formed by splicing the first screw 1121 and the second screw 1131.

It is understood that the first sub-housing 112 and the second sub-housing 113 may be various integrated structures, for example, one end of the first sub-housing 112 is embedded into the second sub-housing 113, so that the first sub-housing 112 and the second sub-housing 113 are connected in a matching manner, and a predetermined embedded edge is formed between one end of the first sub-housing 112 and the first screw member 1121, so that when the embedded edge is embedded into the second sub-housing 113, the first screw member 1121 and the second screw member 1131 exactly match to form a screw column structure, but not limited thereto. The fastener 114 may be various components capable of being covered on the first screw 1121 and the second screw 1131, and may fasten the first screw 1121 and the second screw 1131 by screwing, for example. The materials of the first sub-housing 112 and the second sub-housing 113, the fastening member 114, the first screw 1121 and the second screw 1131 are all corrosion-resistant and anti-interference materials, such as polymer plastics, polytetrafluoroethylene, polyetheretherketone, etc., but not limited thereto.

After the first wire 21 is connected with the second wire 31, the first sub-housing 112 and the second sub-housing 113 are combined into a whole (for example, the first sub-housing 112 is embedded into the second sub-housing 113, so that the first sub-housing 112 and the second sub-housing 113 are matched and connected), the first screw 1121 and the second screw 1131 are matched, at this time, the fastener 114 is fastened by being screwed with the first screw 1121 and the second screw 1131, and the first sub-housing 112 and the second sub-housing 113 are separated, so that the installation of the internal components is more convenient, the time is saved, the use stability, the anti-interference performance and the corrosion performance in a severe environment are improved, the first wire 21 and the second wire 31 in the housing 11 are safer and more stable, the safety in the housing 11 and the firmness of the housing 11 are further improved through the fixation of the fastener 114, and the safety and the durability of the armored cable 100 are further improved.

Referring to fig. 1 to 8, the embodiment of the present application further provides a method for manufacturing an armored cable, where the method includes:

the connection device 10, the first electrical property, and the second electrical wire 30 are obtained.

The plurality of first wires 21 of the first electric wire 20 are connected to the respective wiring mechanisms 12 of the connection device 10 in one-to-one correspondence.

A plurality of second wires 31 of the second electric wire 30 are connected to the respective wiring mechanisms 12 of the connection device 10 in one-to-one correspondence.

One of the wiring mechanisms 12 is wired such that the remaining wiring mechanisms 12 simultaneously wire the first wires 21 and the second wires 31 through the auxiliary mechanism 13, so that each of the first wires 21 is electrically connected to each of the second wires 31.

First and second wires 20 and 30 are inserted into wire holes 1101 at both ends of the housing 11, and then a plurality of first and second wires 21 and 31 are respectively passed through wire holes 11101 of the two insulation members 111, and then the first wire 21 of the first wire 20 is passed through a first wire hole 12101 of the wire-in member 121 and a fourth wire hole 12202 of the wire-in member 1221, and passed out of the fourth wire hole 12202; the second wire 31 of the second electric wire 30 is threaded into the second wire-in hole 12102 of the wire-in member 121 and the third wire-in hole 12201 of the wire-in member 1221, and is threaded out of the third wire-in hole 12201. When the wiring parts 122 connect the first lead wire 21 and the second lead wire 31, the rotating part 1223 of one wiring part 122 is rotated to drive the transmission part 1222 to rotate, meanwhile, the auxiliary gear teeth 1321 on the auxiliary ring 132 are meshed with the transmission gear 12221 on the transmission part 1222, and under the meshing condition, the transmission gear 12221 drives the auxiliary gear teeth 1321 to rotate, so that the auxiliary gear teeth 1321 drive the auxiliary ring 132 to rotate; after the auxiliary ring 132 rotates, the auxiliary gear teeth 1321 on the auxiliary ring 132 are meshed with the gear teeth 12221 on the other transmission members 1222, and the auxiliary gear teeth 1321 drive the gear teeth 12221 of each wiring member 122 to rotate, and drive each wiring member 1221 on each wiring member 122 to rotate by the rotation of each gear teeth 12221, so that the plurality of first wires 21 and the plurality of second wires 31 penetrating through each wiring member 122 are connected. The limit ring groove 13201 arranged on the auxiliary ring 132 is in sliding fit with the sliding limit part 131221 on the supporting piece 13122, so that the auxiliary ring 132 can drive other wiring mechanisms 12 to work simultaneously more stably under the support of the supporting piece 13122, wiring work is simplified, more time is saved, operation is convenient, complicated steps of manually needing one strand of wiring are reduced, the wiring stability and safety of the device are further improved, and the working efficiency and the working speed are improved.

As can be seen from the above, the method for manufacturing an armored cable provided in the embodiment of the present application is achieved by obtaining the connecting device 10, the first electric wire 20 and the second electric wire 30; because the first electric wire 20 and the second electric wire 30 are armored wires, the cable has higher mechanical strength, anti-interference capability and corrosion resistance, and can stably work for a long time in a severe environment; when the cable is damaged due to severe environmental influence, the first wires 21 of the first electric wire 20 are electrically connected with the second wires 31 of the second electric wire 30 in the shell 11 through the wiring mechanisms 12, so as to realize the transmission of electric energy between the first electric wire 20 and the second electric wire 30; meanwhile, when the wiring mechanism 12 is used for wiring the first wire 21 and the second wire 31, as the auxiliary mechanism 13 is connected with each wiring mechanism 12, each wiring mechanism 12 can be used for wiring simultaneously, so that the complicated step that the first wire 21 and the second wire 31 in the cable need to be wired one by one is avoided, the time is saved, and the working efficiency is improved; because the wiring is carried out by using the wiring mechanism 12, the quality of wiring is improved, and the safety performance and the stability performance of the cable after wiring are improved.

The foregoing description of the preferred embodiments of the present application is not intended to be limiting, but is intended to cover any and all modifications, equivalents, and alternatives falling within the spirit and principles of the present application.

Claims (10)

1. An armored cable, comprising:

the connecting device comprises a shell, a plurality of wiring mechanisms and an auxiliary mechanism; the wiring mechanism and the auxiliary mechanism are arranged in the shell;

a first wire, the first wire being an armoured wire; the first electric wire comprises a plurality of first wires, and one ends of the first wires are connected to the wiring mechanism in a one-to-one correspondence manner; and

a second wire, which is an armoured wire; the second electric wire comprises a plurality of second wires, and one ends of the second wires are connected to the wiring mechanism in a one-to-one correspondence manner so as to be electrically conducted with the first electric wire through the wiring mechanism;

the auxiliary mechanism is connected to each wiring mechanism and used for enabling each wiring mechanism to simultaneously wire the first wire and the second wire; the wiring mechanisms are uniformly distributed around the circumference of the auxiliary mechanism.

2. The armored cable of claim 1, wherein the wiring mechanism comprises:

the wire inlet component is arranged in the shell; a first wire inlet hole and a second wire inlet hole are sequentially formed in the wire inlet part along the axis direction of the wire inlet part; and

The wiring part is rotatably arranged on the outer wall of the wire inlet part; the wiring part is sequentially provided with a third wire inlet hole and a fourth wire inlet hole along the axis direction of the wire inlet part;

wherein the first wire inlet hole is communicated with the fourth wire inlet hole; the second wire inlet hole is communicated with the third wire inlet hole; one end of the first wire is arranged through the first wire inlet hole and the fourth wire inlet hole in a penetrating mode; one end of the second wire is arranged through the second wire inlet hole and the third wire inlet hole in a penetrating mode; the wire inlet parts of the wiring mechanisms are uniformly distributed around the circumference of the auxiliary mechanism, and the auxiliary mechanism is connected with the wiring parts of the wiring mechanisms.

3. The armored cable of claim 2, wherein the junction block comprises:

the wiring piece is rotatably arranged on the outer wall of the wire inlet component; the wiring piece is provided with the third wire inlet hole and the fourth wire inlet hole;

the transmission piece is fixedly arranged on the wiring piece; and

the rotating piece is fixedly arranged on the transmission piece;

wherein the auxiliary mechanism is connected to the transmission member of each wiring mechanism.

4. The armored cable of claim 3, wherein a first groove and a second groove are sequentially provided on the incoming member along the axial direction of the incoming member; the wire connector is located between the first groove and the second groove, and the first groove and the second groove are used for limiting the rotation of the wire connector.

5. The armored cable of claim 4, wherein the junction block further comprises:

the first sliding block is arranged on one side of the wiring piece in a sliding manner and is positioned below the third wire inlet hole; and

the second sliding block is arranged on the other side of the wiring piece in a sliding manner and is positioned below the fourth wire inlet hole;

the first sliding block is used for being in limit fit with the first groove; the second sliding block is used for being in limit fit with the second groove.

6. The armored cable of claim 5, wherein the bottom of the wire connection is provided with a swivel connection; the top of the wire inlet component is provided with a connecting and matching part; the rotary connecting part is in rotary connection fit with the connection fitting part.

7. The armored cable of claim 3, wherein the auxiliary mechanism comprises:

Two support frames fixed inside the shell; and

the two auxiliary rings are respectively arranged on the two supporting frames; the two auxiliary rings are oppositely arranged, and each transmission piece is positioned between the two auxiliary rings; auxiliary gear teeth are arranged on one side, facing the transmission piece, of the auxiliary ring; the peripheral outer side wall of the transmission piece is provided with transmission teeth which are meshed with the auxiliary gear teeth; the wire inlet parts are positioned on the inner side of the auxiliary ring and are uniformly distributed around the circumference of the auxiliary ring.

8. The armored cable of claim 7, wherein the support bracket comprises:

a center rod fixed to the inside of the housing; the axis of each central rod is arranged in line with the axis of the auxiliary ring; and

the support assembly comprises a plurality of support rods and a plurality of support pieces, and one ends of the support rods are vertically arranged on the center rod; the support piece is positioned on one side of the support rod facing the auxiliary ring; one end of the supporting piece is vertically arranged at the other end of the supporting rod in a one-to-one correspondence manner; the other end of the supporting piece is in sliding fit with one side of the auxiliary ring, which faces away from the auxiliary gear teeth.

9. The armored cable of claim 8, wherein a limiting ring groove is formed in a side of the auxiliary ring facing away from the transmission piece; one end of the supporting piece is provided with a sliding limiting part which is in sliding fit with the limiting ring groove.

10. An armored cable manufacturing process for manufacturing an armored cable as claimed in any one of claims 1 to 9, comprising:

acquiring a connecting device, a first electrical property and a second electrical wire;

connecting a plurality of first wires of the first electric wire to each wiring mechanism of the connecting device in a one-to-one correspondence manner;

connecting a plurality of second wires of the second electric wire to each wiring mechanism of the connecting device in a one-to-one correspondence manner;

and carrying out wiring operation on one of the wiring mechanisms so as to lead the other wiring mechanisms to simultaneously carry out wiring on the first wires and the second wires through the auxiliary mechanism, thereby leading each first wire to be respectively electrically conducted with each second wire.