CN219959521U - Shell, power supply rail and rail socket - Google Patents

Abstract

The present disclosure provides a casing, power supply rail and track socket, belongs to socket technical field. The shell comprises a shell cover and a bottom plate; the cover comprises a panel, the panel is provided with a rail mouth, and the bottom plate is provided with an electrode channel; the bottom plate and the panel are connected with each other through a connecting structure at two sides of the electrode channel along the width direction, and the track opening is opposite to the electrode channel. By adopting the structure, when the structure of the components inside the shell is changed, most of the conditions only need to adjust the shell cover, the bottom plate is used continuously, or only need to adjust the bottom plate, the shell cover is used continuously, and then the shell material can be saved, the cost is saved, the workload of adjusting the shell can be reduced, the split type shell is also beneficial to realizing the automatic assembly of the power supply rail, and therefore, the split type shell is beneficial to reducing the cost of processing the power supply rail and improving the competitiveness of the power supply rail in the industry.

Description

Shell, power supply rail and rail socket

Technical Field

The present disclosure relates to the field of sockets, and more particularly, to a housing, a power rail, and a rail socket.

Background

The track socket is a novel socket product and mainly comprises a power track (also called a power track) and an adapter in structure. Wherein the power supply rail is mounted on a wall or a table top or the like through a back plate thereof. The adapters are inserted on the power supply rail, can move left and right along the power supply rail, and the number of the adapters can be increased or decreased according to the requirements of users. Therefore, the track socket is popular in the market due to the flexible use, and the demand of the track socket is promoted to be larger and larger.

The track socket with larger demand can bring larger benefits by reducing the cost at any place, so how to further reduce the cost of the track socket is one of key means for improving the competitiveness of products in the industry.

Disclosure of Invention

The utility model provides a casing, power track and track socket can further reduce the cost of track socket, improves product competitiveness. The technical scheme is as follows:

in a first aspect, a housing is provided, the housing comprising a cover and a base plate;

the cover comprises a panel, the panel is provided with a rail mouth, and the bottom plate is provided with an electrode channel;

the bottom plate and the panel are connected with each other through a connecting structure at two sides of the electrode channel along the width direction, and the track opening is opposite to the electrode channel.

In one possible implementation, the connection structure includes a first clamping structure and a second clamping structure;

the first clamping structures are located on the inner surface of the panel and distributed along the length direction of the panel, the second clamping structures are located on the inner surface of the bottom plate and distributed along the length direction, and the first clamping structures are matched with the second clamping structures.

In one possible implementation, the connection structure further includes a screw, and the first clamping structure and the second clamping structure are connected by the screw.

In one possible implementation, the cover further includes a side plate located at a side portion of the panel in a width direction;

and a wiring channel is formed between the side plate and the first surface, wherein the first surface is the surface farthest from the electrode channel in the surface of the first clamping structure and the surface of the second clamping structure.

In one possible implementation manner, the housing further includes a back plate, where the back plate covers an outer surface of the bottom plate and is buckled on a first surface, and the first surface is a surface farthest from the electrode channel from among a surface of the first clamping structure and a surface of the second clamping structure.

In one possible implementation manner, one of the first clamping structure and the second clamping structure is a clamping groove, and the other is a convex rib;

the first clamping structure and the second clamping structure are clamped in the clamping groove through the convex ribs and are matched with each other.

In one possible implementation, the top wall of the electrode channel and the faceplate have a spacing therebetween when the bottom plate and the faceplate are secured.

In one possible implementation, a chamber for mounting a protective door is formed between the face plate, the electrode channel, and the bottom plate.

In one possible implementation, the inner surface of the bottom plate has a third bead in the chamber for fixing a protective door;

the third convex rib comprises a vertical part and an inclined part, wherein the inclined part is far away from the inner surface of the bottom plate and is inclined towards the position of the electrode channel, and an included angle between the inclined part and the vertical part is an obtuse angle.

In a second aspect, there is provided a power rail comprising the housing of the first aspect.

In a third aspect, there is provided a track receptacle comprising an adapter and the power track of the second aspect, the adapter and the power track being removably connected.

In this disclosure, power supply rail's casing is split type, and not integral type, and this kind of split type casing when the structure of its inside component changes, and most circumstances only need adjust the cap, and the bottom plate continues to use, perhaps only need adjust the bottom plate, and the cap continues to use, and then can save casing material, practices thrift the cost, can also reduce the work load of adjusting the casing. Moreover, the split type casing can improve the efficiency of assembly protection door. The split type shell is also beneficial to realizing automatic assembly of the power supply rail. The method is beneficial to reducing the cost of processing the power supply rail and improving the competitiveness of the power supply rail in the industry.

In addition, the split type casing can also facilitate the replacement of the protection door by a user, and prolong the service life of the power supply rail.

It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory only and are not restrictive of the disclosure.

Drawings

The accompanying drawings, which are incorporated in and constitute a part of this specification, illustrate embodiments consistent with the disclosure and together with the description, serve to explain the principles of the disclosure. In the drawings:

FIG. 1 is a schematic diagram of a housing of a power rail according to an embodiment;

FIG. 2 is a schematic diagram of a housing of a power rail according to an embodiment;

FIG. 3 is a schematic diagram of a housing of a power rail according to an embodiment;

fig. 4 is a schematic view showing a structure in which a protection door is located in a housing according to an embodiment.

Description of the reference numerals

1. A housing.

11. A cover; 111. a panel; 112. a rail road junction; 113. a first clamping structure; 114. the first convex rib; 115. the second convex rib; 116. a side plate; 117. and a routing channel.

12. A bottom plate; 121. an electrode channel; 122. an avoidance opening; 123. a second clamping structure; 124. and a third convex rib.

11-12, chamber.

2. A protective door; 21. a door frame; 22. door leaf.

Specific embodiments of the present disclosure have been shown by way of the above drawings and will be described in more detail below. These drawings and the written description are not intended to limit the scope of the disclosed concepts in any way, but rather to illustrate the disclosed concepts to those skilled in the art by reference to specific embodiments.

Detailed Description

For the purposes of clarity, technical solutions and advantages of the present disclosure, the following further details the embodiments of the present disclosure with reference to the accompanying drawings.

The terminology used in the description of the embodiments of the disclosure is for the purpose of describing the embodiments of the disclosure only and is not intended to be limiting of the disclosure. Unless defined otherwise, technical or scientific terms used herein should be given the ordinary meaning as understood by one of ordinary skill in the art to which this disclosure belongs. The terms "first," "second," "third," and the like in the description and in the claims, do not denote any order, quantity, or importance, but rather are used to distinguish one element from another. Likewise, the terms "a" or "an" and the like do not denote a limitation of quantity, but rather denote the presence of at least one. The word "comprising" or "comprises", and the like, is intended to mean that elements or items that are present in front of "comprising" or "comprising" are included in the word "comprising" or "comprising", and equivalents thereof, without excluding other elements or items. The terms "connected" or "connected," and the like, are not limited to physical or mechanical connections, but may include electrical connections, whether direct or indirect. "upper", "lower", "left", "right", etc. are used merely to denote relative positional relationships, which may also change accordingly when the absolute position of the object to be described changes.

The embodiment provides a shell, which is particularly applied to a power rail of a rail socket and is a shell of the power rail, wherein the rail socket is a novel socket product and structurally mainly comprises the power rail and an adapter. The power supply rail is arranged on a wall or embedded into a desktop, the adapter is inserted into the power supply rail in a pluggable mode and can be inserted into any position of the power supply rail, the adapter is provided with a jack for taking electricity, and the plug of the electricity utilization device can be inserted into the jack of the adapter to take electricity.

The number of the adapters of the track socket can be flexibly increased and decreased according to the requirements, the positions can be flexibly adjusted according to the positions of the power utilization devices, the power lines of the power utilization devices are short, and the track socket is safer and more attractive than a common socket, so that the track socket is popular in the market due to the advantages.

The power supply rail mainly comprises a shell, a conductive plate, an insulating support and a junction box in structure, wherein the shell is used as a shell of the power supply rail to play a role in protection, and the shell can be made of aluminum profiles. The conductive plate and the insulating holder are both mounted in a housing, for example, having an electrode channel therein, the insulating holder and the conductive plate are both located in the electrode channel, and the conductive plate is held by the insulating holder.

The terminal box is located the tip of casing, wherein, has inlet end and outlet end in the terminal box, and inlet end is connected with the power cord in the wall, and outlet end is connected with the current-conducting plate electricity, and like this, the power cord in the wall establishes electric connection with the power track.

The panel of the shell is provided with a rail mouth for the adapter to be inserted into the power supply rail, for example, the power taking part of the adapter can penetrate through the rail mouth and be inserted into the electrode channel of the power supply rail to be electrically connected with the conductive plate, the top of the adapter is provided with a jack, and the plug pin of the electric device is inserted into the jack of the adapter to take electricity.

In order to avoid dust, water drops and the like entering the power supply rail through the rail mouth and affecting the use of the power supply rail, the power supply rail also comprises a protection door which is positioned in the shell and used for shielding the rail mouth, for example, when the adapter is not inserted into the rail mouth, the protection door is in a closed state so as to prevent dust, water drops and the like from entering the power supply rail through the rail mouth, and when the adapter is inserted into the rail mouth, the protection door can be pushed open and inserted into the electrode channel and electrically connected with the conductive plate.

The existing shell is formed by integrating two ends along the length direction, the two ends of the existing shell are open, the shell with the structure is required to be inserted into the shell from one end when the protection door is installed, and the existing shell is pushed in along the length direction of the shell, so that the mode of assembling the protection door is time-consuming and is not beneficial to automatic assembly.

Moreover, in the case of such an integrally formed housing, once the structure of the internal member is changed, the structure of the entire housing is changed, for example, if the structure of the protective door is changed, the structure of the entire housing is changed, for example, the structure of the insulating bracket is changed, and thus the structure of the entire housing is changed, so that the suitability of the housing is poor, which is not suitable for mass production.

The embodiment provides a shell, which has strong adaptability and is beneficial to realizing mass production.

As shown in fig. 1, the case 1 includes a case cover 11 and a bottom plate 12, the case 11 includes a panel 111, the panel 111 has a rail opening 112, and the bottom plate 12 has an electrode passage 121; the bottom plate 12 and the face plate 111 are connected by a connection structure on both sides of the electrode channel 121 in the width direction, and the rail openings 112 are located opposite to the electrode channel 121.

As shown in fig. 1, the panel 111 and the bottom plate 12 are each of a long strip-like plate-like structure, the rail opening 112 is arranged at a central position of the panel 111 along a length direction of the panel 111, and the electrode channel 121 is arranged at a central position of the bottom plate 12 along the length direction of the bottom plate 12. After the base plate 12 and the face plate 111 are secured, the track opening 112 and the electrode channel 121 are positioned opposite to each other so that the adapter can pass through the track opening 112 and into the electrode channel 121.

In order to enable the power take-off portion of the adapter to pass through the rail opening 112 and into the electrode channel 121, then, as shown in fig. 1 and with reference to fig. 2, the electrode channel 121 has a relief opening 122, the relief opening 122 being located at the top wall of the electrode channel 121 and being arranged along the length direction. When the base plate 12 and the cover 11 are fixed, the track opening 112 and the avoiding opening 122 are positioned opposite to each other, so that the power-taking portion of the adapter can pass through the track opening 112 and the avoiding opening 122 in sequence and enter the electrode channel 121.

As shown in fig. 1 and referring to fig. 2, the case 1 is of a split type, including the case cover 11 and the bottom plate 12, so that when the structure of the member mounted inside the case 1 is changed, the entire case 1 is not necessarily changed, for example, if the structure of the member (such as an insulating holder) mounted inside the electrode path 121 is changed, only the structure of the bottom plate 12 where the electrode path 121 is located is required to be adaptively adjusted, and the case cover 11 is not required to be adjusted, and then the case cover 11 can still be used. For another example, if the structure of the member (e.g., the protection door) installed in the cover 11 is changed, only the structure of the cover 11 needs to be adaptively adjusted, and the adjustment of the bottom plate 12 is not required, so that the bottom plate 12 can still be used.

It can be seen that, once the structure of the split-type casing is changed with the structure of the casing cover 11, only the structure of the casing cover 11 needs to be adjusted, the structure of the bottom plate 12 does not need to be adjusted, the structure of the split-type casing is changed with the structure of the bottom plate 12, only the structure of the bottom plate 12 needs to be adjusted, and the structure of the casing cover 11 does not need to be adjusted. Therefore, the split shell has stronger adaptability and is beneficial to realizing large-scale production.

Moreover, because the casing is split type, then, can assemble the protection door on cap or bottom plate earlier, then, fix cap and bottom plate together again, like this, the protection door need not to follow the one end along length direction of casing, inserts and pushes gradually in the casing, and then can improve the assembly efficiency of protection door. The assembly mode of the protection door can be operated by a manipulator, so that automatic assembly is facilitated, and the assembly efficiency is further improved.

Moreover, the power supply rail may be damaged and the sealability is reduced after the power supply rail is used for a long time, but since the housing 1 is of a split type, the housing cover 11 and the bottom plate 12 thereof can be detached, and then the user can detach the housing cover 11 and the bottom plate 12, replace the protection door, and further can prolong the service life of the power supply rail.

Therefore, when the structure of the internal components of the split type shell is changed, most of the cases only need to adjust the shell cover, and the bottom plate is used continuously, or only need to adjust the bottom plate, the shell cover is used continuously, so that the shell material can be saved, the cost is saved, and the workload of adjusting the shell can be reduced. Moreover, the split type casing can improve the efficiency of assembly protection door. The split type shell is also beneficial to realizing automatic assembly of the power supply rail. The method is beneficial to reducing the cost of processing the power supply rail and improving the competitiveness of the power supply rail in the industry.

In addition, the split type casing can also facilitate the replacement of the protection door by a user, and prolong the service life of the power supply rail.

In one example, the case cover 11 and the bottom plate 12 are fixedly connected by a connection structure at both sides of the electrode channel 121 in the width direction.

For example, the cover 11 and the base plate 12 are fixedly connected by a connection structure at one side of the electrode path 121, and fixedly connected by a connection structure at the other side of the electrode path 121.

In one example, the connection structure may be a clamping structure, and accordingly, as shown in fig. 2, the inner surface of the panel 111 has first clamping structures 113 distributed along the length direction, and the inner surface of the bottom plate 12 has second clamping structures 123 distributed along the length direction. Thus, the first clamping structure 113 and the second clamping structure 123 form a connecting structure, and the bottom plate 12 is fixed on the inner surface of the panel 111 through the cooperation of the first clamping structure 113 and the second clamping structure 123.

Wherein the inner surface of the panel 111 is a surface facing the bottom plate 12, and the inner surface of the bottom plate 12 is a surface facing the panel 111.

In one example, as shown in fig. 2, the first clamping structure 113 may be a clamping groove, and the second clamping structure 123 may be a protruding rib. In another example, the first clamping structure 113 may be a rib, and the second clamping structure 123 is a slot.

Like this, in first joint structure 113 and the second joint structure 123, one is the draw-in groove, and another is protruding muscle, and first joint structure 113 and second joint structure 123 cooperate, namely, protruding muscle joint is in the draw-in groove, and then realizes the fixed connection of cap 11 and bottom plate 12.

Wherein, protruding muscle card is in the draw-in groove, and protruding muscle card is in the draw-in groove through interference mode for example.

In this embodiment, which of the first clamping structure 113 and the second clamping structure 123 is a clamping groove and which is a protruding rib is not specifically limited, and the first clamping structure 113 may be a clamping groove and the second clamping structure 123 may be a protruding rib.

In one example, since the number of the connection structures is two, the number of the first clamping structures 113 and the second clamping structures 123 is also two, and as shown in fig. 2, the two first clamping structures 113 are located at the left and right sides of the rail opening 112 in the width direction, and the two second clamping structures 123 are located at the left and right sides of the electrode channel 121 in the width direction.

Thus, as shown in fig. 2, the first clamping structure 113 and the second clamping structure 123 located at the left side of the electrode channel 121 are matched, and the first clamping structure 113 and the second clamping structure 123 located at the right side of the electrode channel 121 are matched, so that the bottom plate 12 is positioned on the inner surface of the panel 111.

In an example, the first clamping structure 113 may be formed in such a manner that, as shown in fig. 2, the first ribs 114 and the second ribs 115 may be disposed on the inner surface of the panel 111 along the length direction of the panel 111, and a clamping groove is formed between the first ribs 114 and the second ribs 115 as the first clamping structure 113.

Since the number of the first engaging structures 113 is two, the number of the first ribs 114 and the second ribs 115 is also two. As shown in fig. 2, a first clamping structure 113 is formed between a first rib 114 and a second rib 115 on the left side of the rail mouth 112, and another first clamping structure 113 is formed between the first rib 114 and the second rib 115 on the right side of the rail mouth 112.

Thus, as shown in fig. 2, the second locking structure 123 located at the left side of the electrode channel 121 is locked in the first locking structure 113 formed between the first rib 114 and the second rib 115 located at the left side of the rail mouth 112, and the second locking structure 123 located at the right side of the electrode channel 121 is locked in the first locking structure 113 formed between the first rib 114 and the second rib 115 located at the right side of the rail mouth 112, so as to achieve the fixed connection between the cover 11 and the base plate 12.

In another example, the connection structure that enables the cover 11 and the base plate 12 to be fixedly connected may include not only the first clamping structure 113 and the second clamping structure 123 but also screws.

Thus, the cover 11 and the base plate 12 may be pre-positioned or pre-assembled by the engagement of the first clamping structure 113 and the second clamping structure 123, and then fastened by screws.

In one example, as shown in fig. 2, a screw may be connected between the first and second clamping structures 113 and 123, that is, the first and second clamping structures 113 and 123, through the screw connection.

For example, the second clamping structure 123 is provided with a plurality of mounting holes along the length direction, and as shown in fig. 2, a plurality of screws may respectively pass through the plurality of mounting holes on the second clamping structure 123 and are mounted in the first clamping structure 113, wherein the mounting holes are bare holes.

As an example, the screw may be located in the first clamping structure 113 by way of interference, for example, the screw is interference in a clamping groove formed between the first rib 114 and the second rib 115.

As another example, a screw may be screwed into the first clamping structure 113, for example, the first clamping structure 113, a plurality of screw holes may be arranged along the length direction, and the screw may be screwed into the screw hole of the first clamping structure 113 through the mounting hole of the second clamping structure 123.

In one example, the power rail is mounted on a wall, e.g., a junction box of the power rail covers directly above the wall power supply to facilitate wiring.

In order to improve the installation flexibility of the power supply rail, correspondingly, a wiring channel can be arranged in the shell 1, and thus, a connecting wire between the junction box and the wall power supply can be arranged in the wiring channel, and then, in the installation of the power supply rail, the junction box of the power supply rail does not need to be covered right above the wall power supply, and the installation flexibility of the power supply rail can be improved.

In order to form the routing channels in the housing, correspondingly, as shown in fig. 2, the housing cover 11 further includes a side plate 116, the side plate 116 is located at a side portion of the panel 111 along the width direction, and the routing channels 117 are formed between the side plate 116 and the first surface.

The first surface is the surface farthest from the electrode channel 121, among the surface of the first clamping structure 113 and the surface of the second clamping structure 123.

For example, as shown in fig. 2, a routing channel 117 is formed between the side plate 116 and the surface of the first clamping structure 113 away from the electrode channel 121, that is, a routing channel 117 is formed between the side plate 116 and the surface of the second bead 115 away from the electrode channel 121.

In one example, the number of routing channels 117 may be one, and then the number of side plates 116 is one. In another example, the number of the routing channels 117 is two, and as shown in fig. 2, the number of the side plates 116 is two, and the two side plates 116 are located on both sides of the panel 111 in the width direction. Thus, one routing channel 117 is formed between one side plate 116 and the second rib 115, and another routing channel 117 is formed between the other side plate and the second rib 115.

In one example, to mount the power rail on a wall, the housing 1 may further include a back plate 13, as shown in fig. 3, and the back plate 13 covers the outer surface of the bottom plate 12 and is fastened to the first surface. The first surface and the first surface are the same surface, that is, the surface farthest from the electrode channel 121 among the surface of the first clamping structure 113 and the surface of the second clamping structure 123.

For example, the first surface is a surface of the first clamping structure 113 away from the electrode channel 121, e.g., the first surface is a surface of the second rib 115 facing away from the electrode channel 121.

As an example, the surface of the second rib 115 facing away from the electrode channel 121 may have a convex structure, and the inner surface of the sidewall of the back plate 13 may have a convex structure, so that the back plate 13 is fixedly connected with the housing cover 11 by the convex structure of the second rib 115 and the convex structure of the back plate 13 being fastened together.

As shown in fig. 3, the back plate 13 has a U-shape, and may specifically be a U-shaped structure with a length adapted to the length of the cover 11. Alternatively, the length of the back plate 13 is much smaller than the length of the cover 11, but the number of back plates 13 may be plural, for example, may be two or three, or more, and these back plates 13 may be arranged along the length direction of the cover 11.

Thus, the back plate 13 may be fixed to the wall, the assembled housing 1 is fastened to the back plate 13, and then the power rail is mounted to the wall, and a wiring channel 117 is formed between the side wall of the back plate 13 and the side plate 116 of the housing cover 11.

In one example, as shown in fig. 4, the power supply rail further includes a protection door 2, and accordingly, when the bottom plate 12 and the face plate 111 are fixed, there is a space between the top wall of the electrode channel 121 and the face plate 111. In this way, the protection door 2 can be installed in the space between the top wall of the electrode channel 121 and the panel 111.

In one example, some of the protective doors, as shown in fig. 4, include a door frame 21 and a door sheet 22, the door sheet 22 being located between the electrode channel 121 and the panel 111, the door sheet 22 being fixed to the door frame 21, the door frame 21 being installed in the housing 1. Then, for mounting the door frame 21, accordingly, as shown in fig. 2, the chambers 11-12 for mounting the protective door can be formed between the panel 111, the electrode channel 121 and the bottom plate 12.

In order to mount the gantry in the chamber 11-12, correspondingly, as shown in fig. 4, the inner surface of the bottom plate 12 is provided with a third rib 124 in the chamber 11-12, the gantry 21 may be clamped with the third rib 124, or a clamping groove is formed between the third rib 124 and the second clamping structure 123, and the gantry 21 may be clamped in the clamping groove.

Wherein, for convenience of assembly, as shown in fig. 4, the third ribs 124 may include a vertical portion directly located on the inner surface of the bottom plate 12 and an inclined portion remote from the inner surface of the bottom plate 12, the inclined portion being inclined toward the electrode channel 121 and having an obtuse angle with the vertical portion. Thus, the inclined portion can be used as a guide structure for installing the protection door, so that the third rib 124 can be conveniently positioned between two side walls of the door frame 21, or the door frame 21 can be conveniently positioned in a clamping groove between the second clamping structure 123 and the third rib 124, and the efficiency of assembling the protection door is further improved.

In this disclosed embodiment, the power supply rail's casing is split type, and not integral type, and this kind of split type casing when the structure of its inside component changes, and most circumstances only need adjust the cap, and the bottom plate continues to use, or only need adjust the bottom plate, and the cap continues to use, and then can save casing material, practices thrift the cost, can also reduce the work load of adjusting the casing. Moreover, the split type casing can improve the efficiency of assembly protection door. The split type shell is also beneficial to realizing automatic assembly of the power supply rail. The method is beneficial to reducing the cost of processing the power supply rail and improving the competitiveness of the power supply rail in the industry.

In addition, the split type casing can also facilitate the replacement of the protection door by a user, and prolong the service life of the power supply rail.

The present embodiment also provides a power supply rail, which may include a housing 1, a conductive plate, an insulating bracket, a tail cap, a junction box, and the like. The housing 1 is the housing described above. The conducting plate and the insulating support are both located in the electrode channel of the shell 1, the conducting plate is clamped by the insulating support, the tail cover is installed at one end of the shell 1 along the length direction, and the junction box is installed at the other end of the shell 1 along the length direction.

In one example, the power supply rail may further include a protection door installed in the housing 1 for shielding the rail mouth. When the adapter is not inserted into the rail road junction, the protection door shields the rail road junction and plays a role in sealing the rail road junction. When the adapter inserts in the rail mouth, the adapter exerts effort to the protection door, pushes the protection door to one side of rail mouth, and the protection door no longer shelters from the rail mouth for the adapter contacts with the current conducting plate in the electrode passageway, and when the adapter is pulled out from the rail mouth, the protection door takes place to kick-back, resets the position department that shelters from the rail mouth. Furthermore, the power supply rail can improve the safety of the power supply rail through shielding the rail mouth by the protection door, and achieve the effects of preventing water and dust from being discharged so as to prolong the service life of the power supply rail.

The shell of the power supply rail is split instead of integral as described above, and when the structure of the internal components of the split shell is changed, most of the cases only need to be adjusted to the shell cover, and the bottom plate is used continuously, or only need to be adjusted to the bottom plate, the shell cover is used continuously, so that the shell material can be saved, the cost is saved, and the workload of adjusting the shell can be reduced. Moreover, the split type casing can improve the efficiency of assembly protection door. The split type shell is also beneficial to realizing automatic assembly of the power supply rail. The method is beneficial to reducing the cost of processing the power supply rail and improving the competitiveness of the power supply rail in the industry.

In addition, the split type casing can also facilitate the replacement of the protection door by a user, and prolong the service life of the power supply rail.

The embodiment also provides a track socket, which comprises an adapter and the power supply track, wherein the adapter and the power supply track are connected in a pluggable manner. The number of the adapters is multiple, and each adapter is connected with the power supply rail in a pluggable mode.

The power supply rail of the rail socket is split instead of integral, and when the structure of the internal components is changed, most of the cases only need to be adjusted to the shell cover, the bottom plate is used continuously or only need to be adjusted to the bottom plate, and the shell cover is used continuously, so that the shell material can be saved, the cost is saved, and the workload of adjusting the shell can be reduced. Moreover, the split type casing can improve the efficiency of assembly protection door. The split type shell is also beneficial to realizing automatic assembly of the power supply rail. The method is beneficial to reducing the cost of processing the power supply rail and improving the competitiveness of the power supply rail in the industry.

In addition, the split type casing can also facilitate the replacement of the protection door by a user, and prolong the service life of the power supply rail.

The foregoing description of the preferred embodiments of the present disclosure is provided for the purpose of illustration only, and is not intended to limit the disclosure to the particular embodiments disclosed, but on the contrary, the intention is to cover all modifications, equivalents, alternatives, and alternatives falling within the spirit and scope of the disclosure.

Claims (10)

1. A shell (1) is characterized in that the shell (1) is a split shell and comprises a shell cover (11) and a bottom plate (12) which are mutually independent;

the cover (11) comprises a panel (111), the panel (111) has a rail opening (112), and the bottom plate (12) has an electrode channel (121);

the bottom plate (12) and the panel (111) are connected on both sides of the electrode channel (121) along the width direction through a connecting structure, and the track opening (112) is opposite to the electrode channel (121);

wherein the connecting structure comprises a first clamping structure (113) and a second clamping structure (123); the first clamping structure (113) is located on the inner surface of the panel (111) and distributed along the length direction of the panel (111), the second clamping structure (123) is located on the inner surface of the bottom plate (12) and distributed along the length direction of the bottom plate (12), and the first clamping structure (113) and the second clamping structure (123) are matched.

2. The housing (1) according to claim 1, wherein the connection structure further comprises a screw;

the first clamping structure (113) and the second clamping structure (123) are connected through the screw.

3. The housing (1) according to claim 1, wherein the cover (11) further includes a side plate (116), the side plate (116) being located at a side portion of the panel (111) in a width direction;

a wiring channel (117) is formed between the side plate (116) and a first surface, wherein the first surface is the surface farthest from the electrode channel (121) among the surface of the first clamping structure (113) and the surface of the second clamping structure (123).

4. The housing (1) according to claim 1, wherein the housing (1) further comprises a back plate (13), the back plate (13) covers the outer surface of the bottom plate (12) and is buckled on a first surface, and the first surface is the surface farthest from the electrode channel (121) among the surface of the first clamping structure (113) and the surface of the second clamping structure (123).

5. The housing (1) according to claim 1, wherein one of the first and second clamping structures (113, 123) is a clamping groove and the other is a protruding rib;

the first clamping structure (113) and the second clamping structure (123) are clamped in the clamping groove through the convex ribs to be matched.

6. The housing (1) according to any one of claims 1 to 5, wherein a space is provided between a top wall of the electrode channel (121) and the panel (111) when the bottom plate (12) and the panel (111) are fixed.

7. The housing (1) according to claim 6, wherein a chamber (11-12) for fitting a protective door is formed between the panel (111), the electrode channel (121) and the bottom plate (12).

8. The housing (1) according to claim 7, characterized in that the inner surface of the bottom plate (12) has third ribs (124) for fixing the protective door (2) in the chamber (11-12);

the third ribs (124) comprise vertical portions and inclined portions, wherein the inclined portions are far away from the inner surface of the bottom plate (12) and inclined to the position of the electrode channel (121), and an included angle between each inclined portion and the vertical portion is an obtuse angle.

9. A power rail, characterized in that it comprises a housing (1) according to any one of claims 1 to 8.

10. A track socket comprising an adapter and the power track of claim 9, the adapter and the power track being removably connected.