CN220856141U

CN220856141U - Improved structure of conductive cable

Info

Publication number: CN220856141U
Application number: CN202322639777.XU
Authority: CN
Inventors: 曾浩华; 陈启胜; 陈春鹏; 袁华旸; 凌子洋; 王达锦; 欧志海
Original assignee: Zhongshan Eic Electric Co ltd; Zhongshan City Leaf Lighting Technology Co ltd
Current assignee: Zhongshan Eic Electric Co ltd; Zhongshan City Leaf Lighting Technology Co ltd
Priority date: 2023-09-27
Filing date: 2023-09-27
Publication date: 2024-04-26
Anticipated expiration: 2033-09-27

Abstract

An improved structure of a conductive cable relates to the technical field of power lines, and comprises a strip-shaped insulating wrapping object, a plurality of through holes which are arranged in the insulating wrapping object and are parallel to each other and are separated, a wire which is arranged in the through holes, a flat strip-shaped object with the ratio of a long side to a short side of a section being more than 2, wherein the flat strip-shaped object is a rigid object which can be bent around the long side, a flat strip-shaped hole with the section matched with the section of the flat strip-shaped object is arranged in the insulating wrapping object, and the flat strip-shaped object is connected in the flat strip-shaped hole in a penetrating way; or the side of the long side of the flat strip-shaped object is provided with an embedded groove with the cross section matched with that of the insulating wrapping object, and the insulating wrapping object with the wire is embedded in the embedded groove. Compared with the prior art, the utility model has the advantage that the modeling posture can be kept stable after the power line is bent and modeled.

Description

Improved structure of conductive cable

Technical Field

The utility model relates to the technical field of power lines, in particular to an improved structure of a conductive cable.

Background

The existing technology for taking electricity by puncturing the power line wrapping to contact the conducting wire in the wrapping adopts soft materials which are easy to puncture, such as silica gel, and the technology is widely used for taking electricity of the LED lamp with low power and small current because of easy puncturing and taking electricity, and the layout of an electric light source is very convenient by utilizing the characteristic that electricity can be taken randomly at all positions of the power line; however, the material of the sheath is insufficient to support the stretching or maintain the stability of the shape, and therefore, the present inventors have adopted a method of wrapping a steel cable to improve the performance of the tensile cord of the power cord, and although the problem of the tensile cord of the power cord is solved, the power cord is a flexible cord which can only be straightened to maintain the stability of the shape, and in actual use, various modeling designs such as bending are often required for the power cord, and once the modeling is completed, the modeling is required to have a stable posture, but due to the soft nature of the power cord, the stability of the modeling posture is not maintained.

Disclosure of Invention

The present utility model aims to provide an improved structure of an electrically conductive cable which can overcome one or more of the above-mentioned drawbacks and maintain a stable modeling posture after the power line is bent.

The utility model is realized in such a way that the insulation package comprises a strip-shaped insulation package, a plurality of through holes which are arranged in the insulation package and are separated and parallel to each other, and a wire which is arranged in the through holes, wherein the flat strip-shaped object with the ratio of the long side to the short side of the cross section being more than 2 is arranged, the flat strip-shaped object is a rigid object which can bend around the long side, the insulation package is internally provided with a flat strip-shaped hole with the cross section matched with the cross section of the flat strip-shaped object, and the flat strip-shaped object is connected in the flat strip-shaped hole in a penetrating way; or the side of the long side of the flat strip-shaped object is provided with an embedded groove with the cross section matched with that of the insulating wrapping object, and the insulating wrapping object with the wire is embedded in the embedded groove.

When the electric power cord is used, the electric power cord is bent along the long side by utilizing the flexibility and the rigidity of the flat bar-shaped object so as to manufacture an aesthetic appearance, then the electric connector with the electric light source is connected to the set position of the electric power cord according to the design requirement by a needling conductive technology, and the required aesthetic appearance light is displayed along the aesthetic appearance electric power cord by utilizing the brightness and the light color of each electric light source.

The insulation package is matched with the flat strip-shaped object, firstly, the characteristics that the insulation package is easy to puncture and insulated are utilized, electricity is conveniently taken from any position of an electric wire wrapped by the insulation package by adopting a conductive needling technology, secondly, various bending modeling is carried out by utilizing the flexibility and the rigidity of the flat strip-shaped object, and the set modeling is conveniently fixed through a fixing structure fixed on a ceiling or a wall or a bracket.

Preferably, the flat strips are made of steel strips or hard plastic strips or strip-shaped fiberglass boards or strip-shaped carbon fiber boards.

In this way, the bending can be performed, and the rigidity in the long side direction is high, and the bending performance in the short side direction is good, so that after bending, the bent model is easily fixed, and meanwhile, the whole model cannot be damaged due to falling down in the long side direction due to the action of gravity.

Preferably, the wire is disposed in the through hole after wrapping the insulator.

Because each wire is close in the insulating wrapping, the wire is not blocked by the insulating wrapping which is not formed by the wire in the process of combining the wire and the insulating wrapping due to the reason that the wires are close to each other in the manufacturing process of combining the wire and the insulating wrapping, and the manufacturing failure is caused by the contact short circuit of the wires; moreover, the problem of manufacturing process is easy to cause that no insulating wrap material permeates between the wires to form a hollowing phenomenon, at the moment, in the use process, the wires are easy to shift at the hollowing position to cause mutual contact short circuit, even if the insulating wrap can be filled between the wires in manufacturing, the forming of the insulating wrap at the position is often imperfect, in the use process, if the external force twists, torsion also easily causes the wires to break through the blocking of the insulating wrap at the position to approach each other until the wires are in mutual contact, and the short circuit is caused.

The insulation is wrapped by the wires and then arranged in the through holes, so that the insulation wrapped by the wires has perfect physical properties, and even if external force is applied to enable the wires to approach each other in the manufacturing or using process, the insulation with perfect physical properties can effectively prevent the wires from contacting each other.

Preferably, the plate of the flat bar is provided with a recess corresponding to the wire, the wire being positioned at the recess. The notch is adopted, so that the wires can overcome the action of external force under the positioning of the notch even if the wires are pushed to be close to each other by external force in the manufacturing process or the using process, and the wires are ensured to be separated from each other and not to be close together.

Preferably, the flat bar is provided with a through hole on the plate surface. Through holes are adopted, and during manufacturing, the insulation wrapping material is guaranteed to fully fill the peripheral positions of the lead, and no hollowing phenomenon occurs.

Preferably, the flat bar has embossments on the face thereof. The concave-convex patterns are arranged, so that the contact area between the flat strip-shaped object and the insulating wrapping object is large, the flat strip-shaped object and the insulating wrapping object are ensured to be firmly connected, and the situation that the flat strip-shaped object is separated from the insulating wrapping object to influence the modeling due to large-scale bending modeling in the use process is avoided.

Compared with the prior art, the utility model has the advantage that the modeling posture can be kept stable after the power line is bent and modeled under the condition of not influencing the electricity taking by adopting the conductive needling technology.

Drawings

Fig. 1 is a schematic structural diagram of a modified structure of a first conductive cable according to embodiment 1 of the present utility model;

fig. 2 is a schematic cross-sectional structure of a modified structure of a second conductive cable according to embodiment 1 of the present utility model;

fig. 3 is a schematic cross-sectional structure of a modified structure of a third conductive cable according to embodiment 1 of the present utility model;

Fig. 4 is a schematic cross-sectional structure of a modified structure of a fourth conductive cable according to embodiment 1 of the present utility model;

Fig. 5 is a schematic cross-sectional structure of a modified structure of a sixth conductive cable according to embodiment 1 of the present utility model;

FIG. 6 is a schematic view of the flat bar of FIG. 5;

FIG. 7 is a schematic structural view showing a modified structure of the conductive cable of embodiment 2 of the present utility model;

FIG. 8 is a schematic view of a piercing power take-off configuration;

FIG. 9 is an exploded view of a piercing power take structure;

Fig. 10 is a state diagram of the use of the technique of the present utility model.

Reference numerals illustrate: 1-insulating wrap; 2-through holes; 3-conducting wires; 4-flat bar; 5-a flat bar-shaped hole; 6-insulator; 7-notch; 8-embossments; 9-a through hole; 10-embedding grooves; 11-a connector; 1101-conductive lancet; 12-an electric light source; 13-a pressing mechanism; 1301-Shi Yatou; 1302-a latch structure; 14-a fixing member; a-conductive cable.

Detailed Description

The improved structure of the conductive cable of the present utility model will now be described in further detail with reference to the accompanying drawings and examples:

as shown in fig. 1, the improved structure of the conductive cable of the utility model is realized by comprising a flat strip-shaped insulating wrapping 1 (made of insulating silica gel material), a plurality of through holes 2 (2 or 4 through holes 2) which are arranged in the insulating wrapping 1 and are parallel to each other and are separated, and a wire 3 arranged in the through holes 2, wherein the flat strip 4 with the ratio of long side to short side of the section being larger than 2 is arranged, the flat strip 4 is a rigid object capable of bending around the long side, a flat strip-shaped hole 5 with the section matched with the section of the flat strip 4 is arranged in the insulating wrapping 1, and the flat strip 4 is connected in the flat strip-shaped hole 5 in a penetrating way.

Preferably, the section of the strip-shaped insulating wrap 1 is trapezoidal, and the flat strip 4 is located on the side of the base of the trapezoid. The trapezoid shape can increase the ratio of the long side to the short side of the flat bar 4, so that the rigidity in the long side direction is increased, and meanwhile, the flexibility in the short side direction is increased, and the molding is easily fixed while the easy bending molding is ensured.

Preferably, the flat strips 4 are made of steel strips or hard plastic strips or strip-shaped fiberglass boards or strip-shaped carbon fiber boards.

Preferably, as shown in fig. 2, the wire 3 is wrapped with an insulator 6 (made of an insulating silica gel material) and then disposed in the through hole 2.

Preferably, as shown in fig. 3, the flat bar 4 is provided with a notch 7 on the plate surface corresponding to the wire 3, and the wire 3 or the wire 3 wrapping the insulator 6 is positioned at the notch 7.

Preferably, as shown in fig. 4, the flat bar 4 is provided with embossments 8 on the plate surface.

Preferably, as shown in fig. 5 and 6, the flat bar 4 is provided with a through hole 9 on the plate surface.

When in manufacture, the insulator 6 is wrapped on the wire 3 to ensure that the wire 3 is fully insulated by the insulator 6, and meanwhile, the wrapped insulator 6 has good physical properties and has no defects; the corresponding conductor 3 wrapped with the insulator 6 is then positioned against the notch 7 of the flat bar 4 and then wrapped with the insulating wrap together with the flat bar 4 to form the conductive cable a.

In embodiment 2, as shown in fig. 7, the side of the long side of the flat bar 4 is provided with a damascene groove 10 with a cross section matching that of the insulating wrap 1, and the insulating wrap 1 with the wire 3 is inlaid in the damascene groove 10.

As shown in fig. 8 and 9, when the puncture is performed, the connector 11 with the electric light source 12 is connected to a position set by a power line according to design requirements, and the conductive puncture needle 1101 on the connector 11 is penetrated into the insulating wrapper 1 and is contacted with the corresponding wire 3 in the insulating wrapper 1 by the pressing mechanism 13 (including the pressing head 1301 arranged in a swinging manner and the locking structure 1302 for locking the pressing head 1301 after pressing) on the connector 11, so as to acquire the power transmitted by the wire 3, thereby lighting the electric light source 12 on the connector 11.

As shown in fig. 10, in the modeling design, the conductive cable a of the present invention is bent along a long side using the flexibility and rigidity of the flat bar, so as to make an aesthetic model, then is fixed to a ceiling or a wall by a fixing member 14 to fix the finished model, and then the power connector 11 with the electric light sources 12 is connected to a power line set position according to the design requirement, and the desired aesthetic lamp light is displayed along the power line having the aesthetic model by using the brightness and light color of each electric light source 12.

Claims

1. The improved structure of a conductive cable, including rectangular insulating wrapping, several through holes that separate and set up in insulating wrapping and parallel to each other, the wire set up in the through hole, characterized by that there is a long side of the cross section that is greater than the flat strip thing that the ratio of the short side is greater than 2, the flat strip thing is the rigid thing that can bend around long side, there are flat strip holes that the cross section matches with flat strip thing cross section in the insulating wrapping, the flat strip thing is connected in flat strip hole in a cross section; or the side of the long side of the flat strip-shaped object is provided with an embedded groove with the cross section matched with that of the insulating wrapping object, and the insulating wrapping object with the wire is embedded in the embedded groove.

2. The improvement in an electrically conductive cable according to claim 1, characterized in that the flat strips are made of steel strips or rigid plastic strips or strips of fiberglass board or strips of carbon fiber board.

3. The improvement in a conductive cable according to claim 1, characterized in that the elongated insulating wrap has a trapezoidal cross section, the flat strip being located on the side of the bottom side of the trapezoid.

4. The improved structure of the conductive cable according to claim 1 or 2, wherein the conductive wire is disposed in the through hole after wrapping the insulator.

5. An improved structure of an electrically conductive cable according to claim 1 or 2, wherein the plate surface of the flat bar is provided with a recess corresponding to the wire, the wire being positioned at the recess.

6. The improvement in a conductive cable according to claim 1 or 2, characterized in that the flat strip has embossments on its face.

7. The improved structure of the conductive cable according to claim 1 or 2, wherein the flat bar is provided with a through hole on the plate surface.

8. The improved structure of the conductive cable according to claim 1 or 2, wherein when the puncture is performed, the power connector with the electric light source is connected to the set position of the power line according to the design requirement, and the conductive puncture needle on the power connector is penetrated into the insulating wrapper and contacted with the corresponding wire in the insulating wrapper by the pressing mechanism on the power connector, so as to acquire the power transmitted by the wire, thereby lighting the electric light source on the power connector.

9. The improved structure of the conductive cable according to claim 8, wherein the conductive cable is bent along a long side to make an esthetic model, then is fixed to a ceiling or a wall by a fixing member to fix the finished model, and then the power connector with the electric light source is connected to a position set by the power line according to design requirements, and a desired esthetic light is displayed along the esthetic model of the power line by using brightness and light color of each electric light source.