CN109950763B - Clamping type built-in track power supply and electricity taking system - Google Patents

Abstract

The invention discloses a clamping type built-in track power supply and electricity taking system, which comprises a bearing assembly, wherein an electricity taking socket is formed in the side wall of the bearing assembly; the power supply assembly is a power supply rail and is arranged in an accommodating space formed in the bearing assembly through the mounting assembly; the conductive component is embedded in the bearing component and is connected with the power supply component; the power taking assembly is connected with the power supply assembly through the power taking socket; the invention can avoid the problem of messy distribution of wires when the wires are connected by the mutual matching among the bearing assembly, the power supply assembly, the conductive assembly and the power taking assembly, and is convenient and quick to supply and take power.

Description

Clamping type built-in track power supply and electricity taking system

Technical Field

The invention relates to the technical field of power supply and power taking of a display rack, in particular to a clamping type built-in rail power supply and power taking system.

Background

In recent years, modern market lighting creates a comfortable, quick and clear shopping environment for customers, can promote the shopping desire of the customers, and enables the customers to see as many and full commodities and relevant information thereof as possible in the desire naturally, thereby meeting the requirements of relevant commercial lighting facilities; the illumination of goods shelves district belongs to the very important part of market illumination, has in the illumination installation of current market in disorder scattered power termination mode, the installation is complicated and consuming time more problem, and occupies more goods shelves space after the installation, leads to the space extravagant, the lower problem of utilization ratio.

Disclosure of Invention

This section is intended to outline some aspects of embodiments of the application and to briefly introduce some preferred embodiments. Some simplifications or omissions may be made in this section as well as in the description of the application and in the title of the application, which may not be used to limit the scope of the application.

In view of the problem that the prior clamping type built-in track power supply and power take-off system has messy distribution of wires, the invention provides the clamping type built-in track power supply and power take-off system.

In order to solve the technical problems, the invention provides the following technical scheme: the clamping type built-in track power supply and electricity taking system comprises a bearing assembly, wherein an electricity taking socket is formed in the side wall of the bearing assembly; the power supply assembly is a power supply rail and is arranged in an accommodating space formed in the bearing assembly through the mounting assembly; the conductive component is embedded in the bearing component and is connected with the power supply component; and the power taking assembly is connected with the power supply assembly through the power taking socket.

As a preferable scheme of the clamping type built-in track power supply and power taking system, the invention comprises the following steps: limiting rails are symmetrically arranged on two sides of the slide body of the power supply assembly, and the limiting rails are inwards groove-shaped.

As a preferable scheme of the clamping type built-in track power supply and power taking system, the invention comprises the following steps: the power supply copper sheet of the power supply assembly is embedded and arranged in the limit rail.

As a preferable scheme of the clamping type built-in track power supply and power taking system, the invention comprises the following steps: the power supply assembly further comprises a fixing body, and the fixing body is arranged at one end of the carrier body;

Wherein the fixing body is matched with the groove of the mounting assembly.

As a preferable scheme of the clamping type built-in track power supply and power taking system, the invention comprises the following steps: the mounting assembly comprises a first plate, a second plate and a third plate, wherein two ends of the third plate are respectively connected with the first plate and the second plate, and the first plate and the second plate are arranged in parallel;

wherein the first, second and third plates form a channel.

As a preferable scheme of the clamping type built-in track power supply and power taking system, the invention comprises the following steps: the conductive component comprises a conductive box cover, a conductive copper sheet and a conductive box seat, wherein the conductive box cover is correspondingly covered on the conductive box seat, and a conductive connecting end of the conductive copper sheet is embedded in a clamping space formed by the conductive box cover and the conductive box seat;

Wherein, the lead passes through the perforation formed by the conductive box cover and the conductive box seat and is connected with the wire hole of the conductive connecting end;

wherein, the wire hole corresponds to the transverse clamping groove of the conductive box cover.

As a preferable scheme of the clamping type built-in track power supply and power taking system, the invention comprises the following steps: the conductor of the conductive copper sheet passes through the limit hole of the conductive box seat and is embedded into the limit rail to be contacted with the power supply copper sheet for power taking;

the electric conductors are arranged at two ends of the conductive connecting end.

As a preferable scheme of the clamping type built-in track power supply and power taking system, the invention comprises the following steps: the conductive box seat further comprises a limit groove, a clamping plate and a limit plate, wherein the limit holes are formed in two ends of the limit groove, the clamping plate is perpendicular to the limit groove, and the limit plate is fixed on the conductive box seat far away from one side of the clamping plate;

the limiting plate is divided into a fourth plate and a fifth plate, and the fourth plate and the fifth plate are vertically arranged;

the conductor passes through the limiting hole and is embedded into a limiting space formed by the conductive box seat, the fourth plate and the fifth plate;

The outer protrusions of the fifth plate are matched with grooves formed in the inner wall of the bearing assembly.

As a preferable scheme of the clamping type built-in track power supply and power taking system, the invention comprises the following steps: the electricity taking assembly comprises an electricity taking shell, an electricity taking seat, an electricity taking body, a magnet and a gasket, wherein an electricity taking head of the electricity taking body is arranged on the outer side of the electricity taking seat, the magnet is embedded into an electricity taking clamping groove of the electricity taking seat, the electricity taking head of the electricity taking body, the electricity taking seat and the magnet are embedded into an electricity taking space of the electricity taking shell along an electricity taking foot guide rail of the electricity taking shell, and the gasket is arranged on an electricity taking hole of the electricity taking shell;

Wherein, get the electricity foot and pass and get the electricity socket with the fixed draw-in groove cooperation of the fixed body.

As a preferable scheme of the clamping type built-in track power supply and power taking system, the invention comprises the following steps: the electricity taking body further comprises an electricity taking elastic piece, and the electricity taking elastic piece is embedded into a guide rail of the electricity taking pin;

the electricity taking elastic sheet passes through the electricity taking socket to be in contact with the power supply copper sheet;

wherein, get electric shell fragment with get electric head connection.

The invention has the beneficial effects that: the bearing assembly, the power supply assembly, the conductive assembly and the power taking assembly are matched with each other, so that the problem that wires are messy to distribute when the wires are connected can be avoided, the power supply and the power taking are convenient and quick, meanwhile, the power taking mode adopts the clamping type, the stability of power taking is ensured, and the use requirement is met.

Drawings

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

fig. 1 is a schematic diagram of the overall structure of the clamping type built-in track power supply and take-off system of the present invention.

Fig. 2 is a schematic diagram of a partial structure of a clamping type built-in track power supply and take-off system of the present invention.

Fig. 3 is a schematic structural view of a mounting assembly of the clamping type built-in track power supply and take-off system of the present invention.

Fig. 4 is a schematic structural diagram of a power supply assembly of the clamping type built-in track power supply and power take-off system of the present invention.

Fig. 5 is a schematic structural diagram of a conductive component of the clamping type built-in track power supply and take-off system of the present invention.

Fig. 6 is a schematic structural diagram of a conductive box cover of the clamping type built-in track power supply and take-off system of the invention.

Fig. 7 is a schematic diagram of a conductive copper sheet structure of the clamping type built-in track power supply and extraction system of the present invention.

Fig. 8 is a schematic structural diagram of a conductive box base of the clamping type built-in track power supply and take-off system of the present invention.

Fig. 9 is a schematic view of another view angle structure of the conductive box base of the clamping type built-in track power supply and power take-off system of the present invention.

Fig. 10 is a schematic structural view of a bearing assembly of the clamping type built-in track power supply and take-off system of the present invention.

Fig. 11 is a schematic diagram of the overall top view structure of the clamping type built-in track power supply and take-off system of the present invention.

Fig. 12 is a schematic diagram of an explosion structure of a power take-off assembly of the clamping type built-in track power supply and take-off system of the present invention.

Fig. 13 is a schematic view of another view of an explosion structure of the power take-off assembly of the clamping type built-in track power supply and take-off system of the present invention.

Fig. 14 is a schematic diagram of the overall structure of the clamping type built-in track power supply and take-off system of the present invention.

Fig. 15 is a schematic view of a power taking housing of the clamping type built-in track power supply and power taking system of the present invention.

Detailed Description

In order that the above-recited objects, features and advantages of the present invention will become more readily apparent, a more particular description of the invention will be rendered by reference to specific embodiments thereof which are illustrated in the appended drawings.

In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present invention, but the present invention may be practiced in other ways other than those described herein, and persons skilled in the art will readily appreciate that the present invention is not limited to the specific embodiments disclosed below.

Further, reference herein to "one embodiment" or "an embodiment" means that a particular feature, structure, or characteristic can be included in at least one implementation of the invention. The appearances of the phrase "in one embodiment" 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.

Further, in describing the embodiments of the present invention in detail, the cross-sectional view of the device structure is not partially enlarged to a general scale for convenience of description, and the schematic is only an example, which should not limit the scope of protection of the present invention. In addition, the three-dimensional dimensions of length, width and depth should be included in actual fabrication.

Examples

Referring to fig. 1 and 2, for a first embodiment of the present invention, there is provided an overall structure schematic diagram of a clamping type built-in track power supply and power take-off system, as shown in fig. 1, the clamping type built-in track power supply and power take-off system includes a carrier assembly 100, and a power take-off socket 101 is formed on a side wall of the carrier assembly 100; the power supply assembly 200 is a power supply rail, and the power supply assembly 200 is arranged in a containing space N1 formed in the bearing assembly 100 through the mounting assembly 300; the conductive component 400 is embedded in the bearing component 100 and connected with the power supply component 200; and, a power take-off assembly 500 connected to the power supply assembly 200 through the power take-off socket 101.

Specifically, the main structure of the invention comprises the bearing component 100, the power supply component 200, the mounting component 300, the conductive component 400 and the power taking component 500, and the bearing component 100, the power supply component 200, the mounting component 300, the conductive component 400 and the power taking component 500 are mutually matched, so that the convenient power taking of the display rack can be realized, the shelf space is effectively utilized, the power supply, the mounting and the power taking operations are convenient, the goods on the shelf can be better displayed, and meanwhile, the problem of messy distribution of wires during wire connection can be avoided; the bearing assembly 100 is used for bearing the power supply assembly 200, the installation assembly 300, the conductive assembly 400 and the power taking assembly 500 and playing a role of supporting legs or supporting rods, and the side wall of the bearing assembly 100 is provided with the power taking socket 101, and it is noted that the bearing assembly 100 is a square tube or a hollow cylinder tube made of materials such as plastics or aluminum alloy; the power supply assembly 200 is a power supply track and comprises at least one track body with a single groove and copper wires arranged in the single groove, and further, the power supply assembly 200 is arranged in a containing space N1 formed by the bearing assembly 100 through the installation assembly 300; the conductive assemblies 400 play a role of connecting the power transmission line with the power supply assembly 200, and are embedded into the accommodating space N1 of the bearing assembly 100 to be in contact with the power supply assembly 200, so that the power supply process of the power supply assembly 200 is realized, and it is emphasized that the conductive assemblies 400 are provided with two in total, the two conductive assemblies 400 are respectively arranged at two ends of the bearing assembly 100, and meanwhile, in order to avoid electric leakage, rubber plugs can be arranged on the power taking jack 101 and the through hole K1 of the conductive assemblies 400, and the shape of the rubber plugs is the same as that of the power taking jack 101 and the through hole K1; the power taking assembly 500 plays a role of a power taking connector, and is connected with the power supply assembly 200 through the power taking socket 101 of the bearing assembly 100, so that the processes of conducting, supplying power and taking power can be realized.

Further, as shown in fig. 3, the mounting assembly 300 plays a role in stabilizing the installation of the power supply assembly 200 in the carrier assembly 100, specifically, the mounting assembly 300 includes a first plate 301, a second plate 302 and a third plate 303, two ends of the third plate 303 are respectively connected with the first plate 301 and the second plate 302, and the first plate 301 and the second plate 302 are arranged in parallel, wherein the first plate 301, the second plate 302 and the third plate 303 form two symmetrically arranged grooves M1, the power supply assembly 200 is embedded in the grooves M1, the lengths H of the first plate 301 and the second plate 302 are equal to the rectangular (or circular) cross-section length (or diameter) of the carrier assembly 100, and the length L of the third plate 303 is equal to the width (or diameter) of the carrier assembly 100, so that the power supply assembly 200 is stably installed in the carrier assembly 100; it should be noted that the mounting assembly 300 is made of a plastic material.

Examples

Referring to fig. 4, this embodiment differs from the first embodiment in that: the power supply assembly 200 comprises a carrier body 201, a power supply copper sheet 202 and a fixing body 203, and the carrier body 201, the power supply copper sheet 202 and the fixing body 203 are matched with each other to provide guarantee for safe power supply, and meanwhile the problem that wires are placed in disorder can be avoided. Specifically, referring to fig. 1, the main structure of the electric power rack comprises a bearing component 100, a power supply component 200, a mounting component 300, a conductive component 400 and an electricity taking component 500, and through mutual matching among the bearing component 100, the power supply component 200, the mounting component 300, the conductive component 400 and the electricity taking component 500, the electric power rack can conveniently take electricity, the space of the electric power rack is effectively utilized, the power supply, the mounting and the electricity taking operations are convenient, the goods on the electric power rack can be better displayed, and meanwhile, the problem that wires are distributed in disorder during wire connection can be avoided; the bearing assembly 100 is used for bearing the power supply assembly 200, the installation assembly 300, the conductive assembly 400 and the power taking assembly 500 and playing a role of supporting legs or supporting rods, and the side wall of the bearing assembly 100 is provided with the power taking socket 101, and it is noted that the bearing assembly 100 is a square tube or a hollow cylinder tube made of materials such as plastics or aluminum alloy; the power supply assembly 200 is a power supply track and comprises at least one track body with a single groove and copper wires arranged in the single groove, and further, the power supply assembly 200 is arranged in a containing space N1 formed by the bearing assembly 100 through the installation assembly 300; the conductive assemblies 400 play a role of connecting the power transmission line with the power supply assembly 200, and are embedded into the accommodating space N1 of the bearing assembly 100 to be in contact with the power supply assembly 200, so that the power supply process of the power supply assembly 200 is realized, and it is emphasized that the conductive assemblies 400 are provided with two in total, the two conductive assemblies 400 are respectively arranged at two ends of the bearing assembly 100, and meanwhile, in order to avoid electric leakage, rubber plugs can be arranged on the power taking jack 101 and the through hole K1 of the conductive assemblies 400, and the shape of the rubber plugs is the same as that of the power taking jack 101 and the through hole K1; the power taking assembly 500 plays a role of a power taking connector, and is connected with the power supply assembly 200 through the power taking socket 101 of the bearing assembly 100, so that the processes of conducting, supplying power and taking power can be realized.

Further, as shown in fig. 3, the mounting assembly 300 plays a role in stabilizing the installation of the power supply assembly 200 in the carrier assembly 100, specifically, the mounting assembly 300 includes a first plate 301, a second plate 302 and a third plate 303, two ends of the third plate 303 are respectively connected with the first plate 301 and the second plate 302, and the first plate 301 and the second plate 302 are arranged in parallel, wherein the first plate 301, the second plate 302 and the third plate 303 form two symmetrically arranged grooves M1, the power supply assembly 200 is embedded in the grooves M1, the lengths H of the first plate 301 and the second plate 302 are equal to the rectangular (or circular) cross-section length (or diameter) of the carrier assembly 100, and the length L of the third plate 303 is equal to the width (or diameter) of the carrier assembly 100, so that the power supply assembly 200 is stably installed in the carrier assembly 100; it should be noted that the mounting assembly 300 is made of a plastic material.

The power supply assembly 200 comprises a carrier body 201, a power supply copper sheet 202 and a fixed body 203, and guarantees are provided for safe power supply by mutual matching among the carrier body 201, the power supply copper sheet 202 and the fixed body 203, wherein the carrier body 201 provides a foundation for installing the power supply copper sheet 202, two sides of the carrier body 201 of the power supply assembly 200 are symmetrically provided with limiting rails 201a, the limiting rails 201a are inwards groove-shaped, the power supply copper sheet 202 is used for conducting electricity, one end of the limiting rails 201a is embedded and installed in the limiting rails 201a, the inwards groove-shaped limiting rails 201a limit the power supply copper sheet 202, and the power supply copper sheet 202 can be prevented from being folded in half; the fixing body 203 is connected with the installation component 300, and the power taking component 500 is limited to realize the function of power taking stability, the fixing body 203 is arranged at one end of the carrier body 201, the fixing body 203 is matched with the groove M1 of the installation component 300, and the connection between the fixing body 203 and the installation component 300 is reinforced by screws, and it is emphasized that the fixing body 203 is of an M-shaped structure, the carrier body 201 is of a T-shaped structure, and the fixing body 203 and the carrier body 201 are of an integrated structure, and are made of materials such as plastics or aluminum alloy.

Further, the power supply copper sheet 202 is strip-shaped, and the width of the power supply copper sheet is the same as the maximum width of the groove of the limit rail 201 a.

Examples

Referring to fig. 5, this embodiment differs from the above embodiment in that: the conductive assembly 400 comprises a conductive box cover 401, a conductive copper sheet 402 and a conductive box seat 403, and the conductive box cover 401, the conductive copper sheet 402 and the conductive box seat 403 are matched with each other, so that the safety performance of power transmission, power supply and power taking can be ensured. Specifically, referring to fig. 1, the main structure of the electric power rack comprises a bearing component 100, a power supply component 200, a mounting component 300, a conductive component 400 and an electricity taking component 500, and through mutual matching among the bearing component 100, the power supply component 200, the mounting component 300, the conductive component 400 and the electricity taking component 500, the electric power rack can conveniently take electricity, the space of the electric power rack is effectively utilized, the power supply, the mounting and the electricity taking operations are convenient, the goods on the electric power rack can be better displayed, and meanwhile, the problem that wires are distributed in disorder during wire connection can be avoided; the bearing assembly 100 is used for bearing the power supply assembly 200, the installation assembly 300, the conductive assembly 400 and the power taking assembly 500 and playing a role of supporting legs or supporting rods, and the side wall of the bearing assembly 100 is provided with the power taking socket 101, and it is noted that the bearing assembly 100 is a square tube or a hollow cylinder tube made of materials such as plastics or aluminum alloy; the power supply assembly 200 is a power supply track and comprises at least one track body with a single groove and copper wires arranged in the single groove, and further, the power supply assembly 200 is arranged in a containing space N1 formed by the bearing assembly 100 through the installation assembly 300; the conductive assemblies 400 play a role of connecting the power transmission line with the power supply assembly 200, and are embedded into the accommodating space N1 of the bearing assembly 100 to be in contact with the power supply assembly 200, so that the power supply process of the power supply assembly 200 is realized, and it is emphasized that the conductive assemblies 400 are provided with two in total, the two conductive assemblies 400 are respectively arranged at two ends of the bearing assembly 100, and meanwhile, in order to avoid electric leakage, rubber plugs can be arranged on the power taking jack 101 and the through hole K1 of the conductive assemblies 400, and the shape of the rubber plugs is the same as that of the power taking jack 101 and the through hole K1; the power taking assembly 500 plays a role of a power taking connector, and is connected with the power supply assembly 200 through the power taking socket 101 of the bearing assembly 100, so that the processes of conducting, supplying power and taking power can be realized.

Further, as shown in fig. 3, the mounting assembly 300 plays a role in stabilizing the installation of the power supply assembly 200 in the carrier assembly 100, specifically, the mounting assembly 300 includes a first plate 301, a second plate 302 and a third plate 303, two ends of the third plate 303 are respectively connected with the first plate 301 and the second plate 302, and the first plate 301 and the second plate 302 are arranged in parallel, wherein the first plate 301, the second plate 302 and the third plate 303 form two symmetrically arranged grooves M1, the power supply assembly 200 is embedded in the grooves M1, the lengths H of the first plate 301 and the second plate 302 are equal to the rectangular (or circular) cross-section length (or diameter) of the carrier assembly 100, and the length L of the third plate 303 is equal to the width (or diameter) of the carrier assembly 100, so that the power supply assembly 200 is stably installed in the carrier assembly 100; it should be noted that the mounting assembly 300 is made of a plastic material.

The power supply assembly 200 comprises a carrier body 201, a power supply copper sheet 202 and a fixed body 203, and guarantees are provided for safe power supply by mutual matching among the carrier body 201, the power supply copper sheet 202 and the fixed body 203, wherein the carrier body 201 provides a foundation for installing the power supply copper sheet 202, two sides of the carrier body 201 of the power supply assembly 200 are symmetrically provided with limiting rails 201a, the limiting rails 201a are inwards groove-shaped, the power supply copper sheet 202 is used for conducting electricity, one end of the limiting rails 201a is embedded and installed in the limiting rails 201a, the inwards groove-shaped limiting rails 201a limit the power supply copper sheet 202, and the power supply copper sheet 202 can be prevented from being folded in half; the fixing body 203 is connected with the installation component 300, and the power taking component 500 is limited to realize the function of power taking stability, the fixing body 203 is arranged at one end of the carrier body 201, the fixing body 203 is matched with the groove M1 of the installation component 300, and the connection between the fixing body 203 and the installation component 300 is reinforced by screws, and it is emphasized that the fixing body 203 is of an M-shaped structure, the carrier body 201 is of a T-shaped structure, and the fixing body 203 and the carrier body 201 are of an integrated structure, and are made of materials such as plastics or aluminum alloy.

Further, the power supply copper sheet 202 is strip-shaped, and the width of the power supply copper sheet is the same as the maximum width of the groove of the limit rail 201 a. The conductive assembly 400 comprises a conductive box cover 401, a conductive copper sheet 402 and a conductive box seat 403, and the conductive box cover 401, the conductive copper sheet 402 and the conductive box seat 403 are mutually matched, so that a power transmission line and the power supply assembly 200 are safely and stably connected, and the power supply and power taking stability can be ensured, wherein the conductive box cover 401 and the conductive box seat 403 play roles of protecting and connecting the conductive assembly 400 and the bearing assembly 100, the mounting protrusion 401c of the conductive box cover 401 is embedded into the box seat groove 403e correspondingly covered on the conductive box seat 403, the conductive copper sheet 402 plays a role of conveying electricity of a wire to the power supply copper sheet 202, and the conductive connecting end 402a of the conductive copper sheet 402 is embedded into a clamping space formed by the conductive box cover 401 and the conductive box seat 403.

Further, as shown in fig. 6, the wire passes through the through hole K1 formed by the conductive box cover 401 and the conductive box seat 403 to be connected with the wire hole 402a-1 of the conductive connecting end 402a, the wire hole 402a-1 corresponds to the transverse clamping groove 401a of the conductive box cover 401, and the longitudinal clamping groove 401b of the conductive box cover 401 is clamped with the clamping plate 403c, so that the connection stability of the conductive box cover 401 and the conductive box seat 403, and the wire hole 402a-1 can be further ensured.

Further, as shown in fig. 7, the conductor 402b of the conductive copper sheet 402 passes through the limit hole 403a of the conductive box base 403 and is embedded in the limit rail 201a to contact with the power supply copper sheet 202 for getting electricity; the conductive body 402b is disposed at two ends of the conductive connection end 402a, it should be noted that the conductive body 402b has a "J" structure with at least 1, and the conductive body 402b and the conductive connection end 402a are in an integral structure, the conductive body 402b and the conductive connection end 402a have a limiting groove 402c, and the limiting groove 402c is embedded in the limiting groove 403b, so that the conductive copper sheet 402 can be installed and stabilized.

Further, as shown in fig. 8 and 9, the conductive box base 403 further includes a limit groove 403b, a clamping plate 403c and a limit plate 403d, wherein the limit groove 403b provides a condition for the conductive copper sheet 402 to be stably installed in the conductive box base 403, the limit holes 403a of the limit groove 403b are arranged at two ends of the limit groove 403b, the clamping plate 403c is perpendicular to the limit groove 403b, and the limit plate 403d is fixed on the conductive box base 403 far away from one side of the clamping plate 403 c; wherein the limiting plate 403d is divided into a fourth plate 403d-1 and a fifth plate 403d-2, and the fourth plate 403d-1 is arranged perpendicular to the fifth plate 403 d-2; the conductor 402b is inserted into the limiting space N2 formed by the conductive housing 403, the fourth plate 403d-1 and the fifth plate 403d-2 through the limiting hole 403a, and it should be noted that the outer protrusion 403d-21 of the fifth plate 403d-2 is matched with the groove 102 formed on the inner wall of the carrier 100 (as shown in fig. 10).

Examples

Referring to fig. 11 to 13, this embodiment is different from the above embodiment in that: get electric subassembly 500 includes gets electric casing 501, gets electric seat 502, gets electric body 503, magnet 504 and packing ring 505, through getting electric casing 501, get electric seat 502, get electric body 503, magnet 504 and packing ring 505 between mutually supporting, the operating personnel of being convenient for gets electricity according to required, and operation simple, convenient, swift. Specifically, referring to fig. 1, the main structure of the electric power rack comprises a bearing component 100, a power supply component 200, a mounting component 300, a conductive component 400 and an electricity taking component 500, and through mutual matching among the bearing component 100, the power supply component 200, the mounting component 300, the conductive component 400 and the electricity taking component 500, the electric power rack can conveniently take electricity, the space of the electric power rack is effectively utilized, the power supply, the mounting and the electricity taking operations are convenient, the goods on the electric power rack can be better displayed, and meanwhile, the problem that wires are distributed in disorder during wire connection can be avoided; the bearing assembly 100 is used for bearing the power supply assembly 200, the installation assembly 300, the conductive assembly 400 and the power taking assembly 500 and playing a role of supporting legs or supporting rods, and the side wall of the bearing assembly 100 is provided with the power taking socket 101, and it is noted that the bearing assembly 100 is a square tube or a hollow cylinder tube made of materials such as plastics or aluminum alloy; the power supply assembly 200 is a power supply track and comprises at least one track body with a single groove and copper wires arranged in the single groove, and further, the power supply assembly 200 is arranged in a containing space N1 formed by the bearing assembly 100 through the installation assembly 300; the conductive assemblies 400 play a role of connecting the power transmission line with the power supply assembly 200, and are embedded into the accommodating space N1 of the bearing assembly 100 to be in contact with the power supply assembly 200, so that the power supply process of the power supply assembly 200 is realized, and it is emphasized that the conductive assemblies 400 are provided with two in total, the two conductive assemblies 400 are respectively arranged at two ends of the bearing assembly 100, and meanwhile, in order to avoid electric leakage, rubber plugs can be arranged on the power taking jack 101 and the through hole K1 of the conductive assemblies 400, and the shape of the rubber plugs is the same as that of the power taking jack 101 and the through hole K1; the power taking assembly 500 plays a role of a power taking connector, and is connected with the power supply assembly 200 through the power taking socket 101 of the bearing assembly 100, so that the processes of conducting, supplying power and taking power can be realized.

Further, as shown in fig. 3, the mounting assembly 300 plays a role in stabilizing the installation of the power supply assembly 200 in the carrier assembly 100, specifically, the mounting assembly 300 includes a first plate 301, a second plate 302 and a third plate 303, two ends of the third plate 303 are respectively connected with the first plate 301 and the second plate 302, and the first plate 301 and the second plate 302 are arranged in parallel, wherein the first plate 301, the second plate 302 and the third plate 303 form two symmetrically arranged grooves M1, the power supply assembly 200 is embedded in the grooves M1, the lengths H of the first plate 301 and the second plate 302 are equal to the rectangular (or circular) cross-section length (or diameter) of the carrier assembly 100, and the length L of the third plate 303 is equal to the width (or diameter) of the carrier assembly 100, so that the power supply assembly 200 is stably installed in the carrier assembly 100; it should be noted that the mounting assembly 300 is made of a plastic material.

The power supply assembly 200 comprises a carrier body 201, a power supply copper sheet 202 and a fixed body 203, and guarantees are provided for safe power supply by mutual matching among the carrier body 201, the power supply copper sheet 202 and the fixed body 203, wherein the carrier body 201 provides a foundation for installing the power supply copper sheet 202, two sides of the carrier body 201 of the power supply assembly 200 are symmetrically provided with limiting rails 201a, the limiting rails 201a are inwards groove-shaped, the power supply copper sheet 202 is used for conducting electricity, one end of the limiting rails 201a is embedded and installed in the limiting rails 201a, the inwards groove-shaped limiting rails 201a limit the power supply copper sheet 202, and the power supply copper sheet 202 can be prevented from being folded in half; the fixing body 203 is connected with the installation component 300, and the power taking component 500 is limited to realize the function of power taking stability, the fixing body 203 is arranged at one end of the carrier body 201, the fixing body 203 is matched with the groove M1 of the installation component 300, and the connection between the fixing body 203 and the installation component 300 is reinforced by screws, and it is emphasized that the fixing body 203 is of an M-shaped structure, the carrier body 201 is of a T-shaped structure, and the fixing body 203 and the carrier body 201 are of an integrated structure, and are made of materials such as plastics or aluminum alloy.

Further, the power supply copper sheet 202 is strip-shaped, and the width of the power supply copper sheet is the same as the maximum width of the groove of the limit rail 201 a. The conductive assembly 400 comprises a conductive box cover 401, a conductive copper sheet 402 and a conductive box seat 403, through the mutual matching among the conductive box cover 401, the conductive copper sheet 402 and the conductive box seat 403, the power transmission line and the power supply assembly 200 are enabled to be connected safely and stably, and the power supply and power taking stability can be ensured, wherein the conductive box cover 401 and the conductive box seat 403 play roles of protecting and connecting the conductive assembly 400 and the bearing assembly 100, the mounting protrusion 401c of the conductive box cover 401 is embedded into the box seat groove 403e correspondingly covered on the conductive box seat 403, the conductive copper sheet 402 plays the role of conveying the electricity of the electric wire to the power supply copper sheet 202, the conductive connecting end 402a of the conductive copper sheet 402 is embedded into the clamping space formed by the conductive box cover 401 and the conductive box seat 403, and the conductive copper sheet 402 is provided with two conductive copper sheets, the two conductive copper sheets 402 are arranged in the clamping space in a mirror image mode, and are respectively connected with the positive electrode and negative electrode of the power transmission line, namely the conductive copper sheet 402 arranged in a mirror image mode is respectively conductive to a positive charge and charge is respectively paid to the power taking body 503 arranged in the clamping mode;

Further, as shown in fig. 6, the wire passes through the through hole K1 formed by the conductive box cover 401 and the conductive box seat 403 to be connected with the wire hole 402a-1 of the conductive connecting end 402a, the wire hole 402a-1 corresponds to the transverse clamping groove 401a of the conductive box cover 401, and the longitudinal clamping groove 401b of the conductive box cover 401 is clamped with the clamping plate 403c, so that the connection stability of the conductive box cover 401 and the conductive box seat 403, and the wire hole 402a-1 can be further ensured.

Further, as shown in fig. 7, the conductor 402b of the conductive copper sheet 402 passes through the limit hole 403a of the conductive box base 403 and is embedded in the limit rail 201a to contact with the power supply copper sheet 202 for getting electricity; the conductive body 402b is disposed at two ends of the conductive connection end 402a, it should be noted that the conductive body 402b has a "J" structure with at least 1, and the conductive body 402b and the conductive connection end 402a are in an integral structure, the conductive body 402b and the conductive connection end 402a have a limiting groove 402c, and the limiting groove 402c is embedded in the limiting groove 403b, so that the conductive copper sheet 402 can be installed and stabilized.

Further, as shown in fig. 8 and 9, the conductive box base 403 further includes a limit groove 403b, a clamping plate 403c and a limit plate 403d, wherein the limit groove 403b provides a condition for the conductive copper sheet 402 to be stably installed in the conductive box base 403, the limit holes 403a of the limit groove 403b are arranged at two ends of the limit groove 403b, the clamping plate 403c is perpendicular to the limit groove 403b, and the limit plate 403d is fixed on the conductive box base 403 far away from one side of the clamping plate 403 c; wherein the limiting plate 403d is divided into a fourth plate 403d-1 and a fifth plate 403d-2, and the fourth plate 403d-1 is arranged perpendicular to the fifth plate 403 d-2; the conductor 402b is inserted into the limiting space N2 formed by the conductive housing 403, the fourth plate 403d-1 and the fifth plate 403d-2 through the limiting hole 403a, and it should be noted that the outer protrusion 403d-21 of the fifth plate 403d-2 is matched with the groove 102 formed on the inner wall of the carrier 100 (as shown in fig. 10).

The electricity taking assembly 500 comprises an electricity taking housing 501, an electricity taking seat 502, electricity taking bodies 503, a magnet 504 and a gasket 505, wherein the electricity taking housing 501, the electricity taking seat 502, the electricity taking bodies 503, the magnet 504 and the gasket 505 are mutually matched, so that an operator can conveniently take electricity according to the requirement, the operation process is simple, convenient and quick, the electricity taking heads 503a of the electricity taking bodies 503 are arranged on the outer side of the electricity taking seat 502, wherein the electricity taking bodies 503 are provided with two, the electricity taking heads 503a of the two electricity taking bodies 503 are of L-shaped structures, meanwhile, the two electricity taking heads 503a are arranged on two sides of the electricity taking seat 502 in a mirror image mode, preferably, the electricity taking heads 503a and the electricity taking seat 502 are reinforced by screws, and the magnet 504 is embedded in the electricity taking clamping groove 502a of the electricity taking seat 502, the electricity taking head 503a, the electricity taking seat 502 and the magnet 504 of the electricity taking body 503 are assembled and are integrally seen to extend into the electricity taking space N3 of the electricity taking housing 501, namely, the electricity taking head 503a is clamped and limited by the electricity taking housing 501 and the electricity taking seat 502, wherein, the two electricity taking feet 501b arranged in mirror images pass through the two electricity taking sockets 101 to be clamped and are matched with the fixing clamping grooves 203a symmetrically arranged on the fixing body 203, thus ensuring the electricity taking stability, the gasket 505 is used for preventing the connecting wire from falling off in the using process and playing the role of protecting the connecting wire, the gasket 505 is arranged on the electricity taking hole 501a of the electricity taking housing 501, and the electricity taking body 503 is made of copper materials, and the gasket 505 is made of rubber materials.

Further, the electricity taking body 503 further includes an electricity taking elastic piece 503b, and the electricity taking elastic piece 503b is embedded in a guide rail of the electricity taking pin 501b, and the electricity taking elastic piece 503b passes through the electricity taking socket 101 to contact with the power supply copper sheet 202; the power-taking elastic piece 503b is connected with the power-taking head 503a, and it should be emphasized that the power-taking head 503a and the power-taking elastic piece 503b are integrated, and the power-taking elastic piece 503b is of a hillside structure and has a certain elasticity.

During assembly, the connecting wire passes through the gasket 505 to be connected with the power taking hole 503a-1 of the power taking head 503a, then the magnet 504 is installed in the power taking slot 502a, then the two power taking bodies 503 are fixed on two sides of the power taking seat 502 through strong glue, finally the guide rail of the power taking foot 501b of the power taking housing 501 is embedded in the power taking space N3 of the power taking housing 501, and the power taking elastic piece 503b is embedded in the elastic piece limiting rail 501b-1 of the power taking foot 501 b.

In the use process, the electricity taking pins 501b of the electricity taking assembly 500 are inserted into the two electricity taking sockets 101 adjacent to each other on the left and right of the bearing assembly 100, and the elastic electricity taking elastic sheets 503b on the electricity taking body 503 are in elastic contact with the power supply copper sheets 202 in the limit rail 201a to finish electricity taking; when the carrier 100 is made of iron, the magnet 504 is attracted to the carrier 100 during the power taking process, so as to further ensure the stability of power taking.

Examples

Referring to fig. 14 to 15, this embodiment is different from the above embodiment in that: the power taking housing 501 further includes a card body 501c, where the card body 501c is configured to facilitate assembling of a rack of the display rack. Specifically, referring to fig. 1, the main structure of the electric power rack comprises a bearing component 100, a power supply component 200, a mounting component 300, a conductive component 400 and an electricity taking component 500, and through mutual matching among the bearing component 100, the power supply component 200, the mounting component 300, the conductive component 400 and the electricity taking component 500, the electric power rack can conveniently take electricity, the space of the electric power rack is effectively utilized, the power supply, the mounting and the electricity taking operations are convenient, the goods on the electric power rack can be better displayed, and meanwhile, the problem that wires are distributed in disorder during wire connection can be avoided; the bearing assembly 100 is used for bearing the power supply assembly 200, the installation assembly 300, the conductive assembly 400 and the power taking assembly 500 and playing a role of supporting legs or supporting rods, and the side wall of the bearing assembly 100 is provided with the power taking socket 101, and it is noted that the bearing assembly 100 is a square tube or a hollow cylinder tube made of materials such as plastics or aluminum alloy; the power supply assembly 200 is a power supply track and comprises at least one track body with a single groove and copper wires arranged in the single groove, and further, the power supply assembly 200 is arranged in a containing space N1 formed by the bearing assembly 100 through the installation assembly 300; the conductive assemblies 400 play a role of connecting the power transmission line with the power supply assembly 200, and are embedded into the accommodating space N1 of the bearing assembly 100 to be in contact with the power supply assembly 200, so that the power supply process of the power supply assembly 200 is realized, and it is emphasized that the conductive assemblies 400 are provided with two in total, the two conductive assemblies 400 are respectively arranged at two ends of the bearing assembly 100, and meanwhile, in order to avoid electric leakage, rubber plugs can be arranged on the power taking jack 101 and the through hole K1 of the conductive assemblies 400, and the shape of the rubber plugs is the same as that of the power taking jack 101 and the through hole K1; the power taking assembly 500 plays a role of a power taking connector, and is connected with the power supply assembly 200 through the power taking socket 101 of the bearing assembly 100, so that the processes of conducting, supplying power and taking power can be realized.

Further, as shown in fig. 3, the mounting assembly 300 plays a role in stabilizing the installation of the power supply assembly 200 in the carrier assembly 100, specifically, the mounting assembly 300 includes a first plate 301, a second plate 302 and a third plate 303, two ends of the third plate 303 are respectively connected with the first plate 301 and the second plate 302, and the first plate 301 and the second plate 302 are arranged in parallel, wherein the first plate 301, the second plate 302 and the third plate 303 form two symmetrically arranged grooves M1, the power supply assembly 200 is embedded in the grooves M1, the lengths H of the first plate 301 and the second plate 302 are equal to the rectangular (or circular) cross-section length (or diameter) of the carrier assembly 100, and the length L of the third plate 303 is equal to the width (or diameter) of the carrier assembly 100, so that the power supply assembly 200 is stably installed in the carrier assembly 100; it should be noted that the mounting assembly 300 is made of a plastic material.

The power supply assembly 200 comprises a carrier body 201, a power supply copper sheet 202 and a fixed body 203, and guarantees are provided for safe power supply by mutual matching among the carrier body 201, the power supply copper sheet 202 and the fixed body 203, wherein the carrier body 201 provides a foundation for installing the power supply copper sheet 202, two sides of the carrier body 201 of the power supply assembly 200 are symmetrically provided with limiting rails 201a, the limiting rails 201a are inwards groove-shaped, the power supply copper sheet 202 is used for conducting electricity, one end of the limiting rails 201a is embedded and installed in the limiting rails 201a, the inwards groove-shaped limiting rails 201a limit the power supply copper sheet 202, and the power supply copper sheet 202 can be prevented from being folded in half; the fixing body 203 is connected with the installation component 300, and the power taking component 500 is limited to realize the function of power taking stability, the fixing body 203 is arranged at one end of the carrier body 201, the fixing body 203 is matched with the groove M1 of the installation component 300, and the connection between the fixing body 203 and the installation component 300 is reinforced by screws, and it is emphasized that the fixing body 203 is of an M-shaped structure, the carrier body 201 is of a T-shaped structure, and the fixing body 203 and the carrier body 201 are of an integrated structure, and are made of materials such as plastics or aluminum alloy.

Further, the power supply copper sheet 202 is strip-shaped, and the width of the power supply copper sheet is the same as the maximum width of the groove of the limit rail 201 a. The conductive assembly 400 comprises a conductive box cover 401, a conductive copper sheet 402 and a conductive box seat 403, through the mutual matching among the conductive box cover 401, the conductive copper sheet 402 and the conductive box seat 403, the power transmission line and the power supply assembly 200 are enabled to be connected safely and stably, and the power supply and power taking stability can be ensured, wherein the conductive box cover 401 and the conductive box seat 403 play roles of protecting and connecting the conductive assembly 400 and the bearing assembly 100, the mounting protrusion 401c of the conductive box cover 401 is embedded into the box seat groove 403e correspondingly covered on the conductive box seat 403, the conductive copper sheet 402 plays the role of conveying the electricity of the electric wire to the power supply copper sheet 202, the conductive connecting end 402a of the conductive copper sheet 402 is embedded into the clamping space formed by the conductive box cover 401 and the conductive box seat 403, and the conductive copper sheet 402 is provided with two conductive copper sheets 402 in mirror images, and the two conductive copper sheets 402 are respectively connected with the positive electrode and the negative electrode of the power transmission line, namely the conductive copper sheet 402 in mirror image arrangement is respectively conductive to the positive charge and negative electrode of the power taking body 503 arranged in a mirror image manner, and the charge feeding mode is arranged in the clamping mode;

Further, as shown in fig. 6, the wire passes through the through hole K1 formed by the conductive box cover 401 and the conductive box seat 403 to be connected with the wire hole 402a-1 of the conductive connecting end 402a, the wire hole 402a-1 corresponds to the transverse clamping groove 401a of the conductive box cover 401, and the longitudinal clamping groove 401b of the conductive box cover 401 is clamped with the clamping plate 403c, so that the connection stability of the conductive box cover 401 and the conductive box seat 403, and the wire hole 402a-1 can be further ensured.

Further, as shown in fig. 7, the conductor 402b of the conductive copper sheet 402 passes through the limit hole 403a of the conductive box base 403 and is embedded in the limit rail 201a to contact with the power supply copper sheet 202 for getting electricity; the conductive body 402b is disposed at two ends of the conductive connection end 402a, it should be noted that the conductive body 402b has a "J" structure with at least 1, and the conductive body 402b and the conductive connection end 402a are in an integral structure, the conductive body 402b and the conductive connection end 402a have a limiting groove 402c, and the limiting groove 402c is embedded in the limiting groove 403b, so that the conductive copper sheet 402 can be installed and stabilized.

Further, as shown in fig. 8 and 9, the conductive box base 403 further includes a limit groove 403b, a clamping plate 403c and a limit plate 403d, wherein the limit groove 403b provides a condition for the conductive copper sheet 402 to be stably installed in the conductive box base 403, the limit holes 403a of the limit groove 403b are arranged at two ends of the limit groove 403b, the clamping plate 403c is perpendicular to the limit groove 403b, and the limit plate 403d is fixed on the conductive box base 403 far away from one side of the clamping plate 403 c; wherein the limiting plate 403d is divided into a fourth plate 403d-1 and a fifth plate 403d-2, and the fourth plate 403d-1 is arranged perpendicular to the fifth plate 403 d-2; the conductor 402b is inserted into the limiting space N2 formed by the conductive housing 403, the fourth plate 403d-1 and the fifth plate 403d-2 through the limiting hole 403a, and it should be noted that the outer protrusion 403d-21 of the fifth plate 403d-2 is matched with the groove 102 formed on the inner wall of the carrier 100 (as shown in fig. 10). The electricity taking assembly 500 comprises an electricity taking housing 501, an electricity taking seat 502, electricity taking bodies 503, a magnet 504 and a gasket 505, wherein the electricity taking housing 501, the electricity taking seat 502, the electricity taking bodies 503, the magnet 504 and the gasket 505 are mutually matched, so that an operator can conveniently take electricity according to the requirement, the operation process is simple, convenient and quick, the electricity taking heads 503a of the electricity taking bodies 503 are arranged on the outer side of the electricity taking seat 502, wherein the electricity taking bodies 503 are provided with two, the electricity taking heads 503a of the two electricity taking bodies 503 are of L-shaped structures, meanwhile, the two electricity taking heads 503a are arranged on two sides of the electricity taking seat 502 in a mirror image mode, preferably, the electricity taking heads 503a and the electricity taking seat 502 are reinforced by screws, and the magnet 504 is embedded in the electricity taking clamping groove 502a of the electricity taking seat 502, the electricity taking head 503a, the electricity taking seat 502 and the magnet 504 of the electricity taking body 503 are assembled and are integrally seen to extend into the electricity taking space N3 of the electricity taking housing 501, namely, the electricity taking head 503a is clamped and limited by the electricity taking housing 501 and the electricity taking seat 502, wherein, the two electricity taking feet 501b arranged in mirror images pass through the two electricity taking sockets 101 to be clamped and are matched with the fixing clamping grooves 203a symmetrically arranged on the fixing body 203, thus ensuring the electricity taking stability, the gasket 505 is used for preventing the connecting wire from falling off in the using process and playing the role of protecting the connecting wire, the gasket 505 is arranged on the electricity taking hole 501a of the electricity taking housing 501, and the electricity taking body 503 is made of copper materials, and the gasket 505 is made of rubber materials.

Further, the electricity taking body 503 further includes an electricity taking elastic piece 503b, and the electricity taking elastic piece 503b is embedded in a guide rail of the electricity taking pin 501b, and the electricity taking elastic piece 503b passes through the electricity taking socket 101 to contact with the power supply copper sheet 202; the power-taking elastic piece 503b is connected with the power-taking head 503a, and it should be emphasized that the power-taking head 503a and the power-taking elastic piece 503b are integrated, and the power-taking elastic piece 503b is of a hillside structure and has a certain elasticity.

The electricity taking housing 501 further includes a card body 501c, the card body 501c is arranged on one side of the electricity taking housing 501 and is close to the electricity taking hole 501a, and preferably, at least two card bodies 501c are arranged on the side of the electricity taking housing 501, and it is noted that the card body 501c and the electricity taking housing 501 are of an integral structure and are made of plastic or aluminum alloy materials.

During assembly, the connecting wire passes through the gasket 505 to be connected with the power taking hole 503a-1 of the power taking head 503a, then the magnet 504 is installed in the power taking slot 502a, then the two power taking bodies 503 are fixed on two sides of the power taking seat 502 through strong glue, finally the guide rail of the power taking foot 501b of the power taking housing 501 is embedded in the power taking space N3 of the power taking housing 501, and the power taking elastic piece 503b is embedded in the elastic piece limiting rail 501b-1 of the power taking foot 501 b.

During the use, the electricity taking pin 501b of the electricity taking assembly 500 is inserted into the two adjacent electricity taking sockets 101 on the left and right sides of the bearing assembly 100, the elastic electricity taking elastic sheet 503b on the electricity taking body 503 is in spring contact with the power supply copper sheet 202 in the limit rail 201a to finish electricity taking, and when the bearing assembly 100 is made of iron materials, the magnet 504 can be adsorbed on the bearing assembly 100 during the electricity taking process, so that the stability of electricity taking is further ensured.

It should be appreciated that in the development of any such actual implementation, as in any engineering or design project, numerous implementation-specific decisions may be made. Such a development effort might be complex and time consuming, but would nevertheless be a routine undertaking of design, fabrication, and manufacture for those of ordinary skill having the benefit of this disclosure.

It should be noted that the above embodiments are only for illustrating the technical solution of the present invention and not for limiting the same, and although the present invention has been described in detail with reference to the preferred embodiments, it should be understood by those skilled in the art that the technical solution of the present invention may be modified or substituted without departing from the spirit and scope of the technical solution of the present invention, which is intended to be covered in the scope of the claims of the present invention.

Claims (5)

1. A clamping type built-in track power supply and electricity taking system is characterized in that: comprising the steps of (a) a step of,

The bearing assembly (100), the sidewall of the bearing assembly (100) is provided with an electricity taking socket (101); the power supply assembly (200) is a power supply track, the power supply assembly (200) is arranged in a containing space (N1) formed by the bearing assembly (100) through the mounting assembly (300), limit rails (201 a) are symmetrically arranged on two sides of a carrier body (201) of the power supply assembly (200), the limit rails (201 a) are inwards groove-shaped, and a power supply copper sheet (202) of the power supply assembly (200) is embedded in the limit rails (201 a);

the conductive component (400) is embedded in the bearing component (100) and is connected with the power supply component (200); and

The power taking assembly (500) is connected with the power supply assembly (200) through the power taking socket (101);

the conductive assembly (400) comprises a conductive box cover (401), a conductive copper sheet (402) and a conductive box seat (403), wherein the conductive box cover (401) is correspondingly covered on the conductive box seat (403), and a conductive connecting end (402 a) of the conductive copper sheet (402) is embedded in a clamping space formed by the conductive box cover (401) and the conductive box seat (403);

Wherein, the lead passes through a perforation (K1) formed by the conductive box cover (401) and the conductive box seat (403) and is connected with a wire hole (402 a-1) of the conductive connecting end (402 a);

Wherein the wire hole (402 a-1) corresponds to a transverse clamping groove (401 a) of the conductive box cover (401);

The conductor (402 b) of the conductive copper sheet (402) passes through the limit hole (403 a) of the conductive box seat (403) and is embedded into the limit rail (201 a) to be contacted with the power supply copper sheet (202) for taking electricity;

wherein the conductor (402 b) is disposed at both ends of the conductive connection terminal (402 a);

The conductive box seat (403) further comprises a limit groove (403 b), a clamping plate (403 c) and a limit plate (403 d), wherein the limit hole (403 a) is formed in two ends of the limit groove (403 b), the clamping plate (403 c) is perpendicular to the limit groove (403 b), and the limit plate (403 d) is fixed on the conductive box seat (403) far away from one side of the clamping plate (403 c);

Wherein the limiting plate (403 d) is divided into a fourth plate (403 d-1) and a fifth plate (403 d-2), and the fourth plate (403 d-1) is arranged perpendicular to the fifth plate (403 d-2);

wherein the conductor (402 b) passes through the limit hole (403 a) and is embedded in a limit space (N2) formed by the conductive box seat (403), the fourth plate (403 d-1) and the fifth plate (403 d-2); wherein, the outer side bulge (403 d-21) of the fifth plate (403 d-2) is matched with the groove (102) arranged on the inner wall of the bearing assembly (100);

wherein, the vertical clamping groove (401 b) of the conductive box cover (401) is clamped with the clamping plate (403 c).

2. The clip-on built-in track power supply and take-off system of claim 1, wherein: the power supply assembly (200) further comprises a fixing body (203), and the fixing body (203) is arranged at one end of the slide body (201);

wherein the fixing body (203) is matched with a groove (M1) of the mounting assembly (300).

3. The clip-on built-in track power supply and take-off system of claim 2, wherein: the mounting assembly (300) comprises a first plate (301), a second plate (302) and a third plate (303), wherein two ends of the third plate (303) are respectively connected with the first plate (301) and the second plate (302), and the first plate (301) and the second plate (302) are arranged in parallel;

Wherein the first plate (301), the second plate (302) and the third plate (303) constitute a groove (M1).

4. A clip-on built-in rail power supply and extraction system as claimed in claim 3, wherein: the electricity taking assembly (500) comprises an electricity taking shell (501), an electricity taking seat (502), an electricity taking body (503), a magnet (504) and a gasket (505), wherein an electricity taking head (503 a) of the electricity taking body (503) is arranged on the outer side of the electricity taking seat (502), the magnet (504) is embedded into an electricity taking clamping groove (502 a) of the electricity taking seat (502), the electricity taking head (503 a) of the electricity taking body (503), the electricity taking seat (502) and the magnet (504) extend along an electricity taking foot (501 b) guide rail of the electricity taking shell (501) to be embedded into an electricity taking space (N3) of the electricity taking shell (501), and the gasket (505) is arranged on an electricity taking hole (501 a) of the electricity taking shell (501).

Wherein, get electric foot (501 b) pass get electric socket (101) with fixed draw-in groove (203 a) cooperation of fixed body (203).

5. The clip-on built-in rail power supply and take-off system of claim 4, wherein: the electricity taking body (503) further comprises an electricity taking elastic piece (503 b), and the electricity taking elastic piece (503 b) is embedded into a guide rail of the electricity taking pin (501 b);

The electricity taking elastic sheet (503 b) passes through the electricity taking socket (101) to be in contact with the power supply copper sheet (202); wherein, get electric shell fragment (503 b) with get electric head (503 a) connection.