WO2023185400A1 - Mounting assembly used for guide rail, and electrical product - Google Patents

Abstract

Provided in the present application are a mounting assembly used for a guide rail, and an electrical product. The mounting assembly comprises: fixed members, sliding blocks, elastic members and limiting portions. When the elastic members are subjected to an external force, the elastic members drive the sliding blocks in a first limiting position to move; in the first limiting position, the sliding blocks are kept by the limiting portions to release a guide rail; when the sliding blocks move to a second limiting position, the sliding blocks are kept by the limiting portions to tightly clamp the guide rail; when the elastic members are subjected to an external force again, the elastic members drive the sliding blocks in the second limiting position to move; and when the sliding blocks move to the first limiting position, the sliding blocks are kept by the limiting portions to release the guide rail. The embodiments of the present application can achieve a convenient mounting/dismounting operation, and improve customer experience.

Description

A mounting assembly and electrical product for guide rails

Cross-reference related citations

This application claims priority to the Chinese patent application with application number 202210327048.8 submitted on March 30, 2022. The above application is incorporated herein by reference.

Technical field

The present application relates to the field of electronic equipment, and in particular to an installation assembly and electrical product for a guide rail.

Background technique

Existing technologies include the use of guide rails to install electrical products. The guide rails can be various standard guide rails, such as the German Industrial Standard DIN rails. In addition, the electrical products can be, for example, electrical components or electrical devices. Electrical products include mounting components for mounting to rails and electrical units for implementing electrical functions.

In some structures of installation components for electrical products, the installation component includes a slider and a limit spring connected to the slider. When the electrical product is installed on the guide rail, the slider is made to abut against the guide rail and push (PUSH). In this case, the slider moves to install the electrical product on the guide rail. When removing the electrical product from the guide rail, use a tool to pull the slider apart to loosen the guide rail and remove the electrical product from the guide rail. After the tool is released, slide The block automatically resets under the action of the limit spring.

It should be noted that the above introduction to the technical background is only provided to facilitate a clear and complete description of the technical solution of the present application and to facilitate the understanding of those skilled in the art. It cannot be considered that the above technical solutions are known to those skilled in the art just because these solutions are described in the background art section of this application.

Contents of the invention

The inventor found that in the existing above-mentioned structure, when disassembling electrical products from the guide rails, additional tools need to be used, and the space requirements for the disassembly operation are relatively high, such as parts that cooperate with the tools and space for the tools to move. Moreover, the operation steps are complicated and often require both hands to complete the disassembly operation, which is inconvenient and leads to poor customer experience.

In order to solve at least one of the above problems or other similar problems, embodiments of the present application provide an installation assembly and electrical product for a guide rail, which can achieve convenient operation and improve customer experience.

According to a first aspect of an embodiment of the present application, a mounting component for a guide rail is provided, wherein the mounting component includes:

Fastener;

a slider that is movable relative to the fixing member to clamp or loosen the guide rail;

An elastic member is provided on the side of the slider close to the guide rail. One end of the elastic member is fixed relative to the fixing member, and the other end of the elastic member is connected to the side of the slider close to the guide rail. The elastic component can drive the slider to move relative to the fixed component under the action of external force, and the elastic component can drive the slider to move relative to the fixed component through elastic restoring force; and

a limiting part that keeps the slider clamping the guide rail or loosening the guide rail,

When the elastic member is acted upon by an external force, the elastic member drives the slider in the first limiting position to move. In the first limiting position, the slider is held by the limiting portion. In order to loosen the guide rail, when the slider moves to the second limiting position, the slider is held by the limiting part to clamp the guide rail,

When the elastic member is acted upon by an external force again, the elastic member drives the slider in the second limiting position to move. When the slider moves to the first limiting position, , the slider is held by the limiting part to release the guide rail.

In one or some embodiments,

When the elastic component is acted upon by an external force, the elastic component drives the slider in the first limiting position to move to the first transition position. When the slider is in the first transition position, the elastic component The elastic component drives the slider to move from the first transition position to the second limiting position through elastic restoring force. When the elastic component is acted upon by an external force again, the elastic component drives the slider to move to the second limiting position. The slider at the second limit position moves to the first limit position; or

When the elastic member is acted upon by an external force, the elastic member drives the slider in the first limiting position to move to the second limiting position. When the elastic member is acted upon by an external force again, , the elastic component drives the slider in the second limiting position to move to the second transition position. When the slider is in the second transition position, the elastic component drives the slider through elastic restoring force. The block moves from the second transition position to the first limiting position; or

When the elastic component is acted upon by an external force, the elastic component drives the slider in the first limiting position to move to the first transition position. When the slider is in the first transition position, the elastic component The elastic member drives the slider to move from the first transition position to the second limiting position through elastic restoring force. When the elastic member is acted upon by an external force again, the elastic member is driven to the second position. The slider moves to the limit position To the second transition position, when the slider is in the second transition position, the elastic component drives the slider to move from the second transition position to the first limiting position through elastic restoring force.

In one or some embodiments,

The limiting portion includes an annular first track provided on the slider and the other end of the elastic component. The first track includes a first limiting portion and a second limiting portion. The elastic member said other end of the component moves unidirectionally within said first track,

When the other end of the elastic member is located at the first limiting part, the elastic member limits the slider at the first limiting position. When the other end is located at the second limiting portion, the elastic member limits the slider at the second limiting position.

In one or some embodiments,

The first track also includes a first transition portion. When the other end of the elastic component is located at the first transition portion, the slider is in the first transition position, and the elastic component is in maximum deformation state, and/or

The first track also includes a second transition portion. When the other end of the elastic component is located at the second transition portion, the slider is in the second transition position, and the elastic component is in maximum deformation state,

The first rail is formed on the side opposite to the direction of the one-way movement of the first limiting part, the first transition part, the second limiting part, and the second transition part. Step difference surface.

In one or some embodiments,

The limiting part includes an annular second track provided on the slider and a limiting component. The second track includes a first limiting part and a second limiting part. One end of the limiting component is fixed to The other end of the fixing member and the limiting component moves in one direction in the second track,

When the other end of the limiting member is located at the first limiting part, the limiting member limits the slider at the first limiting position. When the other end is located at the second limiting part, the limiting component limits the slider at the second limiting position.

In one or some embodiments,

The second track also includes a first transition portion. When the other end of the limiting component is located at the first transition portion, the slider is in the first transition position, and the elastic component in a state of maximum deformation, and/or

The second track also includes a second transition portion. When the other end of the limiting component is located at the second transition portion, the slider is in the second transition position, and the elastic component in a state of maximum deformation,

The second rail is formed on the side opposite to the direction of the one-way movement of the first limiting part, the first transition part, the second limiting part, and the second transition part. Step difference surface.

In one or some embodiments,

The limiting component is a limiting spring.

In one or some embodiments,

The elastic component is a driving spring, one end of the driving spring is fixed on the first surface of the fixing part, and the other end of the driving spring is connected to the slider and is away from the first surface of the fixing part. ,

When the driving spring is in the minimum deformation state, the slider is in the first limiting position or the second limiting position. The minimum deformation state is when the other end of the driving spring is away from the first limiting position. The farthest state.

In one or more embodiments,

The slide block includes a first slide block and a second slide block, and the first slide block and the second slide block move in opposite directions relative to the fixing piece to clamp or loosen the guide rail,

The elastic member includes a first elastic member and a second elastic member. The first elastic member and the second elastic member are provided between the first slider and the second slider. The first elastic member One end of the elastic member is fixed relative to the fixing piece, the other end of the first elastic member is connected to the first slider, one end of the second elastic member is fixed relative to the fixing piece, and the second elastic member is fixed to the fixing piece. The other end of the elastic member is connected to the second slider, and the first elastic member and the second elastic member can drive the first slider and the second slider in opposite directions under the action of external force. The first elastic member and the second elastic member can drive the first slider and the second slider to move in opposite directions through elastic restoring force.

In one or more embodiments,

The number of the first elastic members and the number of the second elastic members are both 2, and the 2 first elastic members and the 2 second elastic members are both disposed on the first slider and the second elastic member. In the space between the second sliders, one of the first elastic members and one of the second elastic members are disposed on one side in the first direction in the space, and the other first elastic member and another second elastic member is disposed on the other side in the first direction in the space, and the first direction is perpendicular to the arrangement direction of the first slider and the second slider. .

In one or more embodiments,

The elastic component also includes a resilient component, and the resilient component includes a first resilient component and a second resilient component,

One end of the first resilient member is fixed to the fixing piece, the other end of the first resilient member is fixed to the first slider, and one end of the second resilient member is fixed to the fixing piece. , the other end of the second rebound component is fixed to the second slider,

Under the action of the first resilient member and the second resilient member, the first slider and the second slider move in opposite directions.

In one or more embodiments,

The resilient component is an S-shaped elastic piece.

According to an embodiment of the second aspect of the present application, an electrical product is provided, and the electrical product includes:

The mounting assembly as described in the aforementioned embodiment of the first aspect; and

An electrical unit is fixed to the fixture.

One of the beneficial effects of the embodiment of the present application is that when the slider is in the first limiting position without clamping the guide rail, when the elastic component is subjected to the force exerted by the guide rail by PUSH, the slider can move from the first limit position The limit position moves to the second limit position to clamp the guide rail, and the limit part keeps the slider clamping the guide rail. When the elastic component is once again subjected to the force exerted by the guide rail by pushing again, the slider The block can move from the second limit position to the first limit position to release the guide rail, and the stop portion holds the slide block to release the guide rail. As a result, installation or disassembly can be achieved with only one PUSH operation, making operation more convenient and improving customer experience.

With reference to the following description and drawings, specific embodiments of the present application are disclosed in detail, and the manner in which the principles of the present application may be adopted is indicated. It should be understood that the embodiments of the present application are not limited in scope thereby. Embodiments of the present application include numerous alterations, modifications and equivalents within the spirit and scope of the appended claims.

Features described and/or illustrated with respect to one embodiment may be used in the same or similar manner in one or more other embodiments, in combination with features in other embodiments, or in place of features in other embodiments .

Description of drawings

The accompanying drawings are included to provide a further understanding of the embodiments of the application, and constitute a part of the specification for illustrating the embodiments of the application and together with the written description to explain the principles of the application. Obviously, the drawings in the following description are only some embodiments of the present application. For those of ordinary skill in the art, other drawings can be obtained based on these drawings without exerting creative efforts. In the attached picture:

Figure 1 is a schematic diagram of the installation assembly of the embodiment of the first aspect of the present application;

Figure 2 is another schematic diagram of the mounting assembly of the embodiment of the first aspect of the present application;

Figure 3 is another schematic diagram of the installation assembly of the embodiment of the first aspect of the present application;

Figure 4 is an enlarged schematic diagram of the first track according to the embodiment of the first aspect of the present application;

Figure 5 is another schematic diagram of the installation assembly of the embodiment of the first aspect of the present application;

Figure 6 is another schematic diagram of the installation assembly shown in Figure 5;

Figure 7 is a schematic diagram of some components of the installation assembly shown in Figure 5;

Figure 8 is an enlarged schematic diagram of the second track according to the embodiment of the first aspect of the present application;

Figure 9 is another schematic diagram of the installation assembly of the embodiment of the first aspect of the present application;

Figure 10 is another schematic diagram of the mounting assembly shown in Figure 9;

Figure 11 is a three-dimensional schematic view of the installation assembly according to the first embodiment of the present application;

Figure 12 is another schematic diagram of the installation assembly of the embodiment of the first aspect of the present application;

Figure 13 is another schematic diagram of the installation assembly of the embodiment of the first aspect of the present application;

Figure 14 is another schematic diagram of the installation assembly of the embodiment of the first aspect of the present application;

Figure 15 is a schematic diagram of an electrical product according to the second embodiment of the present application.

Detailed ways

The foregoing and other features of the present application will become apparent from the following description, taken in conjunction with the accompanying drawings. In the description and drawings, specific embodiments of the present application are disclosed in detail, indicating some of the embodiments in which the principles of the present application may be employed. It is to be understood that the present application is not limited to the described embodiments, but rather, the present application is This application includes all modifications, variations, and equivalents falling within the scope of the appended claims.

In addition, in each of the drawings used in the following description, since each structural element is of a size that can be recognized on the drawing, the scale differs for each structural element, and the present application is not limited to those described in these drawings. The number of structural elements, the shape of structural elements, the proportion of the size of structural elements, and the relative positional relationship of each structural element.

In the embodiments of this application, the terms "comprising", "including", "having", etc. refer to the presence of stated features, elements, components or components, but do not exclude the presence or addition of one or more other features, elements , component or component.

In the embodiments of this application, the singular forms "a", "the", etc. include plural forms and should be broadly understood as "a" or "a type" and not limited to the meaning of "one"; in addition, the term "the" "" shall be understood to include both the singular and the plural unless the context clearly indicates otherwise. Furthermore, the term "based on" shall be understood to mean "based at least in part on," and the term "based on" shall be understood to mean "based at least in part on," unless the context clearly indicates otherwise.

The embodiments of the present application will be described below with reference to the accompanying drawings.

Embodiments of the first aspect

An embodiment of a first aspect of the present application provides a mounting assembly for a guide rail.

Figure 1 is a schematic diagram of the mounting assembly 10 according to the embodiment of the first aspect of the present application, showing the mounting assembly 10 Release guide rail 2.

As shown in FIG. 1 , the mounting assembly 10 includes a fixing member 11 , a slider 12 and an elastic member 13 . The slider 12 can move relative to the fixing part 11 to clamp or loosen the guide rail 2. For example, the slider 12 is shown in Figure 1 to loosen the guide rail 2, that is, the guide rail 2 is not clamped. The slider 12 can move relative to the fixing part 11. Move in the S direction or S' direction to loosen or clamp the guide rail 2.

As shown in FIG. 1 , the elastic member 13 is disposed on the side of the slider 12 close to the guide rail 2 , and one end 131 of the elastic member 13 is fixed relative to the fixing member 11 . For example, one end 131 of the elastic member 13 is fixed to the fixing member 11 or fixed Regarding the components fixed relative to the fixing member 11, the other end 132 of the elastic member 13 is connected to the slider 12, for example, to the portion 121 of the slider 12 on one side close to the guide rail 2. The elastic member 13 can drive the slider under the action of external force. The block 12 moves relative to the fixed member 11. For example, the elastic component 13 is pressed by the guide rail 2 to drive the slider 12 to move. In this case, the elastic component 13 can drive the slider 12 to move in the direction S or in the direction S'. The elastic member 13 can drive the slider 12 to move relative to the fixing member 11 through the elastic restoring force. For example, the elastic member 13 can drive the slider 12 to move in the S direction or S' direction through the elastic restoring force. For example, the elastic member 13 When deformed by a force exerted by, for example, the guide rail 2, an elastic restoring force will be generated to return to the original shape. When the extruding force of the guide rail 2 on the elastic member 13 disappears or is reduced, the elastic member 13 can pass through Its elastic restoring force drives the driving slider 12 to move relative to the fixing member 11 .

In FIG. 1 , the slider 12 is in the position of releasing the guide rail 2 . In this case, the position of the slider 12 is called the first limiting position.

As shown in Figure 1, when the slider 12 is in the first limiting position, when the elastic member 13 is acted upon by an external force, for example, the mounting assembly 10 is subjected to a PUSH operation in the P direction, causing the guide rail 2 to exert force on the elastic member. The elastic component 13 drives the slider 12 to move due to the force of 13. For example, the elastic component 13 drives the slider 12 to move through the end 132 connected to the slider 12.

Figure 2 is another schematic diagram of the mounting assembly 10 according to the first embodiment of the present application, showing the position of the slider 12 in a clamping guide rail state. In this case, the position of the slider 12 is called the second limit. position.

As shown in FIG. 2 , when the slider 12 moves to the second limiting position, the slider 12 clamps the guide rail 2 . Therefore, the installation assembly 10 can be installed on the guide rail 2 through one PUSH operation.

As shown in FIG. 2 , when the elastic member 12 is acted upon by an external force again, for example, the mounting assembly 10 is subjected to a PUSH operation in the P direction, causing the guide rail 2 to generate a force exerted on the elastic member 13 , and the elastic member 12 is driven to the second limit. The slider 12 moves to the first position, and when the slider moves to the first limiting position shown in Figure 1, the slider 12 releases the guide rail 2. Therefore, the mounting assembly 10 can be detached from the guide rail 2 through one PUSH operation.

In the embodiment of the present application, the mounting assembly 10 further includes a limiting portion, which is inflated when an external force is applied to the elastic component. When it disappears, the slider 12 is kept to release the guide rail 2 or to clamp the guide rail 2, that is, the slider is limited to the first limit position or the second limit position.

It can be seen from the above embodiment that when the slider 12 is in the first limiting position and does not clamp the guide rail 2, when the elastic member 13 is subjected to the force exerted by the guide rail 2 through PUSH, the slider 12 can move from the first position. The limit position moves to the second limit position to clamp the guide rail 2. When the force exerted on the elastic member 13 disappears, the limit part limits the slider at the second limit position to keep the guide rail 2 clamped. When the elastic member 13 is again subjected to the force exerted by the guide rail 2 by pushing again, the slider can move from the second limiting position to the first limiting position and release the guide rail 2. When the force exerted on the elastic member 13 When the force disappears, the limiting part limits the slider at the first limiting position and keeps releasing the guide rail 2 . Therefore, it only takes one push to install the installation component 10 on the guide rail 2 or to remove the installation component from the guide rail 2, which realizes the convenience of operation and improves the customer experience.

As shown in Figures 1 and 2, in one or more embodiments, when the elastic member 13 is acted upon by an external force, the elastic member 13 drives the slider 12 in the first limiting position shown in Figure 1 to move to The second limit position is shown in Figure 2. Thereby, the mounting assembly 10 can be mounted on the guide rail 2 with one PUSH operation.

Figure 3 is another schematic diagram of the mounting assembly 10 according to the first embodiment of the present application, showing the elastic component 13 in the maximum deformation state. In this case, the position of the slider 12 is called the second transition position. .

In one or more embodiments, when the slider is in the second limiting position shown in Figure 2, when the elastic member 13 is acted upon by an external force again, the elastic member 13 drives the slider 12 in the second limiting position to move. To the second transition position shown in Figure 3, when the slider 12 is in the second transition position, the elastic member 13 is in the maximum deformation state. When the PUSH operation in the P direction is canceled, the elastic member 13 is restored by the elastic restoring force. The driving slider 12 moves from the second transition position shown in FIG. 3 to the first limiting position shown in FIG. 1 .

It is worth noting that the maximum deformation state of the elastic member 13 should be understood to mean that when the elastic member 13 is acted upon by an external force again and drives the slider 12 in the second limiting position to move, the elastic member 13 interacts with other components, such as the slider. The maximum deformation state that the elastic member 13 can reach due to the interference of the block 12 and/or the fixing member 11, etc., in other words, the state in which the elastic member 13 cannot be further deformed due to the interference of the slider 12 and/or the fixing member 11, etc. For example, the end 132 of the elastic member 13 abuts the fixing member 11 or the slider 12 and cannot be further deformed, or when the slider 12 is provided with a track for the end 132 of the elastic member 13 to slide, the end 132 of the elastic member 13 The local apex position of the orbit is reached.

As a result, the slider in the second limiting position is moved to the second transition position through one PUSH operation. When the PUSH operation is completed and the pushing force is removed, the elastic restoring force of the elastic member 13 itself can be used to move the slider from the second transition position. 2 transition position moves to the first limit position, thereby releasing the guide rail 2. Therefore, through a PUSH operation, that is The installation assembly 10 installed on the guide rail 2 can be detached from the guide rail 2 .

It is worth noting that FIGS. 1 to 3 exemplarily show that when the slider 12 in the second limiting position shown in FIG. 2 moves to the first limiting position shown in FIG. 1 , the elastic member 13 moves The acting force first moves the slider 12 to the transition position (second transition position) shown in FIG. 3 , and then moves the slider 12 in the transition position to the first limiting position through the elastic restoring force of the elastic member 13 itself.

However, the present application is not limited to this. For example, when the slider in the first limiting position is moved to the second limiting position by the force of the elastic member, it can also be caused by the force of the elastic member. The slider first moves to the transition position (the first transition position), and then moves the slider in the transition position to the second limit position through the elastic restoring force of the elastic component itself, so that the installation component 10 can be installed in the transition position through one PUSH operation. Installation on rail 2.

For example, in one or more embodiments, when the elastic component is acted upon by an external force, the elastic component drives the slider in the first limiting position to move to the first transition position. When the slider is in the first transition position, , the elastic member drives the slider to move from the first transition position to the second limiting position through the elastic restoring force. When the elastic member is acted upon by an external force again, the elastic member drives the slider in the second limiting position to move to the second limiting position. 1 limit position.

In addition, when the slider moves from the first limit position to the second limit position and from the second limit position to the first limit position, the elastic component can be used to move the slider to the transition position. position, and then use the elastic restoring force of the elastic component itself to move the slider in the transition position to the second limit position or the first limit position.

For example, in one or more embodiments, when the elastic component is acted upon by an external force, the elastic component drives the slider in the first limiting position to move to the first transition position. When the slider is in the first transition position, , the elastic member drives the slider to move from the first transition position to the second limiting position through the elastic restoring force. When the elastic member is acted upon by an external force again, the elastic member drives the slider in the second limiting position to move to the second limiting position. 2 transition position: when the slider is in the second transition position, the elastic component drives the slider to move from the second transition position to the first limiting position through elastic restoring force. Therefore, the installation assembly 10 can be installed on the guide rail 2 or detached from the guide rail 2 by only one push.

In the embodiment of the present application, when the slider 12 reaches the first limit position or the second limit position, when the external force exerted on the elastic component 13 is removed, the slider 12 can be held at the first limit position through the limiter. The limit position or the second limit position allows the slider 12 to maintain the state of loosening the guide rail 2 or the state of clamping the guide rail 2, thereby achieving reliable execution of installation and disassembly operations.

In the embodiment of the present application, the specific structure of the limiting part may be various, and the following is an exemplary description.

As shown in Figures 1 to 3, in one or more embodiments, the slider 12 is provided with an annular first track G1, The end 132 of the elastic member 13 moves in one direction in the first track G1. The first track G1 includes a first limiting part GP1 and a second limiting part GP2. The one-way movement means that the end 132 of the elastic member 13 moves in one direction. The first track G1 moves in the clockwise direction or the counterclockwise direction. For example, FIGS. 1 to 2 show that the end 132 of the elastic member 13 moves in the counterclockwise direction in the first track. That is to say, the end 132 of the elastic member 13 moves in the counterclockwise direction. End 132 can move counterclockwise from the first limiting part GP1 to the second limiting part GP2, but cannot move clockwise from the second limiting part GP2 to the first limiting part GP1.

In the embodiment of the present application, as shown in Figure 1, when the end 132 of the elastic member 13 is located at the first limiting portion GP1, the elastic member 13 limits the slider 12 at the first limiting position, as shown in Figure 2 As shown in the figure, when the end 132 of the elastic member 13 is located at the second limiting portion GP2, the elastic member 13 limits the slider 12 at the second limiting position. That is to say, the limiting portion includes the first rail G1 provided on the slider 12 and the end 132 of the elastic member 13 , thereby keeping the slider 12 in a state of releasing the guide rail 2 or clamping the guide rail 2 .

In one or more embodiments, as shown in FIGS. 1 to 3 , the first track G1 also includes a second transition part GP3. When the end 132 of the elastic component 13 is located at the second transition part GP3, the slider 12 In the second transition position, the elastic member 13 is in the maximum deformation state. That is to say, when an external force is applied to the elastic member 13, the end 132 of the elastic member 13 cannot deform further when it reaches the second transition part GP3. In this case , the elastic member 13 can drive the slider 12 to move through its elastic restoring force until the end 132 of the elastic member 13 reaches the first limiting part GP1. In this case, the sliding slide 12 is in the first limiting position and the guide rail 12 is released.

However, the application is not limited thereto. The first track G1 may only include the first transition part without including the second transition part GP3, where the first transition part represents the elastic member 13 when the slider is in the first transition position. The 132 end is located in the first track G1. In other words, when the end 132 of the elastic member 13 is located at the first transition portion, the slider 12 is in the first transition position and the elastic member 13 is in the maximum deformation state.

In addition, the first rail G1 may also include both the first transition part and the second transition part GP3. That is to say, during the installation operation of moving the slider 12 from the first limiting position to the second limiting position, by The PUSH operation squeezes the elastic member 13 to the maximum deformation state. During the disassembly operation of moving the slider 12 from the second limit position to the first limit position, the elastic member 13 is also squeezed to the maximum deformation state through the PUSH operation. , thus ensuring reliable execution of installation and disassembly operations without causing misoperations. It should be noted that the maximum deformation state of the elastic member 13 in the first transition part and the maximum deformation state in the second transition part may be the same or different, and examples will be described later.

In the embodiment of the present application, Figures 1 to 3 show an example in which the first track G1 includes a first limiting portion GP1, a second limiting portion GP2, and a second transition portion GP3, where the first track G1 is Oval, 2nd limit Part GP2 is located on the arc connecting the first limiting part GP1 and the second transition part GP3, but the application is not limited thereto. The first rail G1 may also be of other shapes. For example, the second limiting part GP2 may not be It is located on the arc formed by connecting the first limiting part GP1 and the second transition part GP3, that is, the first track G1 is not an ellipse. This application does not limit this. It only requires that the elastic member 13 is under the action of external force. , the end 132 of the elastic member 13 can move sequentially along the first limiting part GP1, the second limiting part GP2, and the second transition part GP3 in the first rail G1.

However, the application is not limited thereto. The first rail G1 may also include a first limiting part GP1, a first transition part and a second limiting part GP2, or the first rail G1 may also include a first limiting part GP1, a first limiting part GP2. The transition part, the second limiting part GP2 and the second transition part GP3. In this case, regarding the specific shape of the first rail G1 and the specific installation positions of each limiting part and the transition part in the first rail G1, this application will This is not limiting, and reference may be made to the first track G1 illustrated in Figures 1 to 3, which are not listed here.

FIG. 4 is an enlarged schematic diagram of the first track G1 according to the embodiment of the first aspect of the present application.

In one or more embodiments, as shown in FIG. 4 , the first rail G1 is on the opposite side to the direction of the one-way movement of the first limiting part GP1, the second limiting part GP2, and the second transition part GP3. A stepped surface S is formed. That is, as shown in FIG. 4 , when the elastic member 13 moves in one direction clockwise in the first rail G1 , the first rail G1 moves between the first limiting part GP1 , the second limiting part GP2 , and the first limiting part GP2 . 2. A step surface S is formed on one side of the transition portion GP3 in the counterclockwise direction. In addition, when the elastic member 13 moves in one direction counterclockwise in the first rail G1, the first rail G1 is in the first limiting portion. A step surface S is formed on one side in the clockwise direction of GP1, the second limiting part GP2, and the second transition part GP3, which can be provided according to actual needs.

This ensures that the 132 end of the elastic member 13 moves in one direction within the first track G1. For example, the 132 end of the elastic member 13 includes a protrusion that intersects or is perpendicular to the surface 12S of the slider 12 on which the first track G1 is disposed. Therefore, the end of the protruding portion contacts the bottom surface G1S of the first rail G1, which ensures that the end 132 of the elastic member 13 contacts the step surface when the first limiting portion GP1, the second limiting portion GP2, and the second transition portion GP3 And to prevent the end 132 of the elastic member 13 from moving in the wrong direction, that is to say, when the end 132 of the elastic member 13 is located at the first limiting part GP1 or the second limiting part GP2 or the second transition part GP3, through 132 The mutual contact between the ends and the step surfaces prevents the end 132 of the elastic member 13 from moving in the wrong direction due to the elastic restoring force of the elastic member 13, or prevents the end 132 of the elastic member 13 from moving in the wrong direction during the PUSH operation. direction movement to ensure the reliability of installation and disassembly operations.

In the embodiment of the present application, when a step surface is formed in the first track G1, the bottom surface G1S in the first track G1 can be a slope surface. As shown in Figure 4, the bottom of the first track G1 is composed of three connected end to end. It consists of slope sections.

However, the application is not limited to this. Other structures can also be used to ensure that the end 132 of the elastic member 13 is on the first track G1 For unidirectional movement within the first rail G1, for example, the bottom surface of the first rail G1 may also be a flat surface. The first rail G1 moves in the opposite direction of the unidirectional movement of the first limiting part GP1, the second limiting part GP2, and the second transition part GP3. A protrusion may be formed on one side of the elastic member 13 to prevent the end 132 of the elastic member 13 from moving in the wrong direction in the first track G1, that is, in the opposite direction to the one-way movement. For example, as shown in FIG. 4 The position of the step surface S can form a protrusion. When the PUSH operation is not performed, the protrusion can limit the end 132 of the elastic member 13 to the first limiting portion or the second limiting portion. When an external force acts, such as when performing a PUSH operation, the PUSH operation can overcome the obstruction of the end 132 of the elastic member 13 by the protrusion and cause the end 132 of the elastic member 13 to move in one direction, for example, from the first limiting portion. Moving to the second limiting part and moving from the second limiting part to the second transition part produces a frustrating feeling of the PUSH operation, making it easy to identify whether the end 132 of the elastic member 13 is pushed in place.

In the embodiment of the present application, the steepness on both sides of the protrusion may be different. For example, taking the protrusion at the second limiting part GP2 in Figure 4 as an example, one of the protrusions is close to the first limiting part GP1. The side is flatter than the side close to the second transition portion GP3, thereby reducing the operating force required for the PUSH operation and preventing damage to the protrusion.

In the implementation of the present application, as shown in FIGS. 1 to 3 , when the first track G1 is formed in the slider 12 , the first track G1 may be formed on the side of the slider 12 that is parallel to the direction P of the PUSH operation. , but the application is not limited thereto. For example, a groove can also be formed in the central part of the slider 12, and the opening of the groove faces the end 132 of the elastic member 13. The first track G1 can be formed in the direction P of the groove in relation to the PUSH operation. on the sides of parallel walls. This application does not limit this and can be set according to actual conditions.

In the embodiment of the present application, the factory state or original state of the installation assembly 10 can be in a variety of ways. For example, it can be the state shown in Figure 1 , that is, the slider 12 is in the first limiting position and remains in the released state. In this case, the installation assembly 10 can be installed on the guide rail 2 through one PUSH operation as described above. However, it is not limited to this. The slider 12 can also be in the position shown in Figure 2, that is, the end 132 of the elastic member 13 is located at The second limiting part GP2, but the difference is that the slider 12 does not clamp the guide rail 2 at this time. In this case, the initial installation of the mounting assembly 10 on the guide rail 2 can also be achieved through a PUSH operation. For example, in Figure Under the PUSH operation in the P direction shown in 2, the guide rail 2 acts on the slider 12 so that the slider 12 moves in the S direction to expand the opening 16. At this time, the end 132 of the elastic member 13 moves from the second rail G1 to the second rail G1. The limiting part GP2 moves toward the second transition part GP3. When the guide rail 2 completely enters the opening 16, the end 132 of the elastic member 13 has not yet reached the second transition part GP3. At this time, the PUSH operation is removed, and the end 132 of the elastic member 13 faces the second transition part GP3. 2. The limiting part GP2 retracts. The slider 12 moves in the S' direction under the elastic restoring force of the elastic member 13 to clamp the guide rail 2. The end 132 of the elastic member 13 retracts and is held at the second limiting part GP2. to maintain the clamping of the guide rail 2, so that the initial installation of the mounting assembly 10 on the guide rail 2 is achieved through one PUSH operation.

The above is an exemplary description of the structure of the limiting part including the first rail GP1 and the elastic member 13 , that is to say, the limiting structure of the slider is realized through the mutual cooperation between the elastic member 13 and the slider 12 . However, the present application is not limited to this, and the limiting part can also be realized through other structures.

Figure 5 is another schematic diagram of the installation assembly of the embodiment of the first aspect of the present application, showing the situation in which the installation assembly loosens the guide rail 2. Figure 6 is another schematic diagram of the installation assembly shown in Figure 5, showing the installation assembly. Clamping rail 2.

As shown in Figures 5 and 6, the installation assembly 10 also includes a limiting component 14. One end 141 of the limiting component 14 is fixed to the fixing member 11, and the other end 142 (see Figure 7) of the limiting component 14 is disposed on the slider. 12 moves in one direction in the second track G2 (see Figure 7). The second track includes a first limiting part and a second limiting part. When the other end of the limiting component 14 is located at the first limiting part, The limiting member 14 limits the slider 12 to the first limiting position. When the other end of the limiting member 14 is located at the second limiting part, the limiting member 14 limits the slider 12 to the second limiting position. Location.

That is to say, the limiting part may include a separately provided limiting component 14 and a second track G2 provided on the slider 12 , but the application is not limited thereto. For example, the limiting part may include an elastic component 13 and a limiting component 14 and the first track G1 and the second track G2 provided on the slider, or the limiting portion can be formed in other ways. For example, an annular track with multiple step surfaces can be formed on the fixing member 11, and the slider is in an annular shape. One-way movement in the track, driven by the driving force of the elastic component and/or the elastic restoring force of the elastic component, the slider can be respectively limited at the position of clamping the guide rail and the position of releasing the guide rail, that is, the limiting part can include The above descriptions of the slider and the fixing part are only exemplary. Those skilled in the art can select appropriate structures as the limiting parts according to the actual situation.

The installation of the installation assembly 10 on the guide rail 2 and its removal from the guide rail 2 will be exemplified below with reference to the installation assembly shown in FIGS. 5 and 6 .

FIG. 7 is a schematic view of some components of the mounting assembly shown in FIG. 5 , showing the situation viewed from the side away from the guide rail 2 toward the mounting assembly along the direction P of the PUSH operation.

As shown in Figure 7, an annular second track G2 is provided on the slider 12. The end 142 of the limiting member 14 moves in one direction in the second track G2. The second track G2 includes a first limiting portion GP1 and a second limiting portion. position GP2, where the one-way movement refers to the movement of the end 142 of the limiting member 14 in the second track G2 in the clockwise direction or the counterclockwise direction. For example, FIG. 7 shows that the end 142 of the limiting member 14 moves in the second track G2. The second track G2 moves in the counterclockwise direction. That is to say, for example, the end 142 of the limiting part 14 can move from the first limiting part GP1 to the second limiting part via the first transition part GP4 in the counterclockwise direction. GP2, and cannot move from the first limiting part GP1 to the second limiting part GP2 via the second transition part GP3 in the clockwise direction.

In the embodiment of the present application, as shown in Figures 5 and 7, the end 132 of the limiting component 14 is located at the first limiting portion. In the case of GP1, the limiting component 14 limits the slider 12 at the first limiting position as shown in Figure 5. In this case, the slider 12 releases the guide rail 2; as shown in Figures 6 and 7, When the end 142 of the limiting member 14 is located at the second limiting portion GP2, the limiting member 14 limits the slider 12 at the second limiting position as shown in Figure 6. In this case, the slider 12 Clamp rail 2. Thereby, the slider 12 can be maintained in the state of releasing the guide rail 2 or the state of clamping the guide rail 2.

In one or more embodiments, as shown in FIGS. 5 to 7 , the second track G2 also includes a first transition part GP4 and a second transition part GP3. The first transition part GP4 is located at end 142 of the limiting component 14 Or in the case of the second transition part GP3, the slider 12 is in the first transition position (the elastic component 13' indicated by the dotted line in Figure 5) or the second transition position, and the elastic component 13 is in the maximum deformation state, that is, when When an external force is applied to the elastic member 13, the end 132 of the elastic member 13 cannot be further deformed when it reaches the first transition part GP4 or the second transition part GP3. The elastic member 13 cannot further drive the slider 12 through the external force. Here In this case, when the PUSH operation is removed, the elastic member 13 drives the slider 12 to move through its elastic restoring force until the end 132 of the elastic member 13 reaches the second limiting part GP2 or the first limiting part GP1. In this case, The slider 12 is in the second limit position GP2 to clamp the guide rail 12 or is in the first limit position GP1 to release the guide rail 12 .

However, the application is not limited thereto. The second track G2 may only include the first transition part GP4 but not the second transition part GP3. That is to say, the slider 12 in the first limiting position is subjected to the force of the elastic member 13. When moving to the second limiting position, the slider 12 first moves to the first transition position through the force of the elastic member 13, and then is in the first transition position through the elastic restoring force of the elastic member 13 itself. The slider 12 moves to the second limiting position, so that the installation component 10 can be installed on the guide rail 2 through a single PUSH operation. When the elastic member 13 is acted upon by an external force again, the elastic member 13 drives the slider 12 in the second limiting position to move directly to the first limiting position without passing through the second transition position. Thus, through repeated PUSH operations, The mounting assembly 10 can be detached from the guide rail 2 .

For example, the second track G2 may not include the first transition part GP4 but only the second transition part GP3. That is to say, the slider 12 in the first limiting position moves directly under the force of the elastic member 13. to the second limiting position without passing through the first transition position, so that the installation component 10 can be installed on the guide rail 2 through one PUSH operation. When the elastic member 13 is acted upon by an external force again, the slider 12 in the second limiting position is moved to the first limiting position by the force of the elastic member 13 . The acting force first moves the slider 12 to the second transition position, and then moves the slider 12 in the second transition position to the first limit position through the elastic restoring force of the elastic component 13 itself, which can be achieved through one PUSH operation. The mounting assembly 10 is disassembled from the guide rail 2 .

In the embodiment of the present application, as shown in Figure 7, the end 142 of the limiting component 14 is in the first transition part GP4 or in the first transition part GP4. 2 When in the transition portion GP3, the displacement amount of the slider 12 relative to the fixing piece 11 in the S direction is the same, and the deformation state of the elastic member 13 is the same, that is, the elastic member 13 has the same maximum deformation state. However, the application is not limited to this. When the 142 end of the bit member 14 is in the first transition part GP4 or the second transition part GP3, the deformation state of the elastic member 13 may also be different. That is to say, the first transition part GP4 and the second transition part GP3 are relatively different from each other. The straight lines parallel to the S direction may be asymmetrical. This application does not limit this and can be set according to actual needs. Figure 7 shows an example in which the second rail G2 includes a first limiting part GP1, a first transition part GP4, a second limiting part GP2 and a second transition part GP3, where the first limiting part GP1 and the second transition part GP3 The limiting part GP2 is provided along the S direction, but the application is not limited thereto. The second rail G2 may also have other shapes. For example, the line connecting the first limiting part GP1 and the second limiting part GP2 may be in the S direction. Cross, this application does not limit this, as long as the slider is acted upon by the elastic component 13, the end 142 of the limiting component 14 can move along the first limiting part GP1, the first transition part GP4, The second limiting part GP2 and the second transition part GP3 only need to be moved sequentially.

However, the application is not limited thereto. The second rail G2 may also include the first limiting part GP1, the first transition part GP4, and the second limiting part GP2, or the second rail G2 may also include the first limiting part GP1, the first limiting part GP4, and the second limiting part GP2. 2. The limiting part GP2 and the second transition part GP3. In this case, the specific shape of the second rail G2 and the specific installation position of each limiting part and the transition part in the second rail G2 are not limited by this application. Reference may be made to the second track G2 illustrated in FIG. 7 and the above description, which are not listed here.

FIG. 8 is an enlarged schematic diagram of the second track G2 according to the embodiment of the first aspect of the present application.

In one or more embodiments, as shown in FIG. 8 , the second rail G2 moves in one direction between the first limiting part GP1, the first transition part GP4, the second limiting part GP2, and the second transition part GP3. A step surface S is formed on the opposite side of the direction. That is to say, when the limiting member 14 moves in one direction clockwise in the second track G2, that is, the limiting member 14 moves in the second track G2 along the pattern of GP1→GP4→GP2→GP3→GP1. , the second rail G2 forms a step surface S on one side in the counterclockwise direction of the first stopper portion GP1, the first transition portion GP4, the second stopper portion GP2, and the second transition portion GP3, and the stopper member 14 When the second rail G2 moves counterclockwise in one direction, that is, the limiting member 14 moves in the second rail G2 along the pattern of GP1→GP3→GP2→GP4→GP1, the second rail G2 moves in the first limit A step surface S is formed on one side in the clockwise direction of the position portion GP1, the first transition portion GP4, the second limiting portion GP2, and the second transition portion GP3, which can be provided according to actual needs.

This ensures that the end 142 of the limiting member 14 moves in one direction within the second rail G2. For example, the end 142 of the limiting member 14 includes a protrusion that is intersecting or perpendicular to the surface of the second rail G2, whereby, The end of the protruding portion contacts the bottom surface of the second rail G2 to ensure that the end 142 of the limiting member 14 contacts the first limiting portion GP1, the first transition portion GP4, the second limiting portion GP2, and the second transition portion GP3. The end 142 of the limiting member 14 is connected to the differential surface to prevent the Move in the wrong direction to ensure the reliability of installation operations and disassembly operations.

In the embodiment of the present application, when a step surface is formed in the second rail G2, the bottom surface in the second rail G2 is a slope surface. As shown in Figure 8, the bottom of the second rail G2 consists of four slopes connected end to end. composition.

However, the application is not limited to this. Other structures can also be used to ensure that the end 142 of the elastic member 14 moves in one direction in the second track G2. For example, the bottom surface of the second track G2 can also be a flat surface, and the bottom surface of the second track G2 can be To form a protrusion, please refer to the above description about the first track G1 for details. They are not listed here one by one and can be selected according to actual needs.

In the implementation of the present application, as shown in FIGS. 7 and 8 , when the second track G2 is formed in the slider 12 , the second track G2 may be formed on the end surface 12D of the slider 12 that is perpendicular to the direction P of the PUSH operation. , but the application is not limited thereto. For example, the second track G2 may also be formed on the side of the slider 12 parallel to the direction P of the PUSH operation, such as the side 12S shown in FIG. 4 , or in the center of the slider 12 A groove may also be formed in the groove, the opening of the groove faces the end 142 of the limiting component 14, and the second track G2 may be formed on the end surface of the wall of the groove that is perpendicular to the direction P of the PUSH operation. This application does not limit this and can be set according to actual conditions.

In the embodiment of the present application, the factory state or original state of the installation assembly 10 can be in a variety of ways. For example, it can be the state shown in Figure 5 , that is, the slider 12 is in the first limiting position and remains in the released state. In this case, the installation assembly 10 can be installed on the guide rail 2 through a single PUSH operation as described above. However, it is not limited to this. The slider 12 can also be in the position shown in Figure 6, but the difference is that at this time, the slider 10 can be installed in the guide rail 2. The block 12 does not clamp the guide rail 2. In this case, the initial installation of the mounting assembly 10 on the guide rail 2 can also be achieved through a PUSH operation. For example, under the PUSH operation in the P direction shown in Figure 6, the guide rail 2 acts on The slider 12 moves toward the S direction to enlarge the opening 16. At this time, the end 142 of the limiting member 14 moves from the second limiting portion toward the second transition portion in the second track. When the guide rail 2 is fully inserted When the opening 16 is opened, the end 142 of the limiting member 14 has not yet reached the second transition part. At this time, the PUSH operation is removed, and the slider 12 moves toward the S′ direction under the action of the elastic restoring force of the elastic member 13 to re-clamp the guide rail 2 , the end 142 of the limiting component 14 is retracted and held in the second limiting part to keep the guide rail 2 clamped. Therefore, the initial installation of the mounting assembly 10 on the guide rail 2 is achieved through one PUSH operation.

In one or more embodiments, as shown in FIGS. 5 to 8 , the limiting component 14 is a limiting spring. For details about the limiting spring, please refer to the related art, but the application is not limited thereto.

In one or more embodiments, as shown in FIGS. 1 to 8 , the elastic component 13 is a driving spring. For details of the driving spring, please refer to the related art, but the application is not limited thereto.

In the embodiment of the present application, as shown in FIGS. 1 and 6 , when the elastic member 13 is a driving spring, one end 131 of the elastic member 13 is fixed to the first surface 11S of the fixing member 11 , and the other end of the elastic member 13 132 with slider 12 is connected to and away from the first surface 11S of the fixing member 11 , that is to say, the end 132 of the elastic component 13 is closer to the opening 16 of the mounting assembly 10 than the end 131 .

When the elastic member 13 is in the minimum deformation state, the slider is in the first limiting position or the second limiting position. The minimum deformation state is the state where the end 132 of the elastic member 13 is farthest from the first surface 11S, for example, as As shown in Figure 1, when the end 132 of the elastic member 13 is in the state farthest from the surface of the fixing 131, the slider 12 is in the first limiting position to release the guide rail, or, as shown in Figure 6, the elastic When the end 132 of the component 13 is farthest from the surface of the fixing 131, the slider 12 is in the second limiting position to clamp the guide rail. This application does not limit this and can be selected according to actual needs.

In the embodiment of the present application, as shown in Figures 1 and 6, the installation assembly 10 may only include one slider 12, and the installation assembly 10 may include a fixed portion 15 that is opposite to the slider 12 when the slider 12 moves, An opening 16 is formed between the fixed part 15 and the slider 12 to clamp or engage the guide rail 2. Regarding the specific structure of the guide rail 2 and the specific structure of the mounting assembly 10 for engaging with the guide rail 2, for example, on the slider 12 It includes a protruding part 123 for catching the guide rail 2, and the fixed part 15 includes a protruding part 151 for catching the guide rail 2. Please refer to the related technology.

It is worth noting that when the slider is disposed in the S' direction of Figure 1, Figure 4 can be a schematic diagram of the first track G1 formed on the slider. When the slider is disposed in the opposite direction to the S direction in FIG. 5 , FIG. 8 is a diagram of the second rail G2 formed on the slider.

However, the application is not limited thereto. For example, the mounting assembly 10 may include two slide blocks, and the two slide blocks may be arranged on both sides of the opening 16 along the direction in which the slide blocks slide. In other words, the two slide blocks move along the direction in which the slide blocks slide. The two slide blocks are spaced apart and an opening 16 is formed between them, so that the guide rail 2 can be clamped more reliably in the clamping state. However, the application is not limited to this. The two slide blocks can also be arranged side by side in the opening 16 On one end, in addition, the mounting assembly 10 may also include three or more slide blocks, which is not limited in this application. The following takes two slide blocks arranged on both sides of the opening 16 along the sliding direction as an example for detailed description.

FIG. 9 is another schematic diagram of the installation assembly 10 according to the embodiment of the first aspect of the present application, showing the installation assembly 10 releasing the guide rail 2 , and the installation assembly 10 includes two slide blocks. FIG. 10 is another schematic diagram of the mounting assembly 10 shown in FIG. 9 , showing the mounting assembly 10 clamping the guide rail 2 , and the mounting assembly includes two slide blocks. Two sliders are respectively provided on both sides of the opening 16. In addition, an elastic component and a limiting component are respectively provided on both sides of the opening 16. Regarding the structure of any one of the sliders, the elastic component and the limiting component Please refer to the above description of Figures 5 to 8, which will not be introduced one by one here.

As shown in FIGS. 9 and 10 , in one or more embodiments, the slider 12 includes a first slider 12a and a second slider 12b. The first slider 12a and the second slider 12b are relative to the fixing member 11 Move in the opposite direction to clamp or loosen the guide Rail 2.

Correspondingly, as shown in FIGS. 9 and 10 , the elastic member 13 also includes a first elastic member 13a and a second elastic member 13b.

As shown in Figures 9 and 10, in the embodiment of the present application, the first elastic member 13a and the second elastic member 13b are provided between the first slider 12a and the second slider 12b. One end of the first elastic member 13a 13a1 is fixed relative to the fixing member 11, the other end 13a2 of the first elastic member 13a is connected to the first slider 12a, one end 13b1 of the second elastic member 13b is fixed relative to the fixing member 11, and the other end 13b2 of the second elastic member 13b is connected to the first slider 12a. The second slider 12b is connected. The first elastic member 13a and the second elastic member 13b can drive the first slider 12a and the second slider 12b to move in opposite directions under the action of external force. The first elastic member 13a and the second elastic member 13a are connected to each other. The member 13b can drive the first slider 12a and the second slider 12b to move in opposite directions through elastic restoring force.

As shown in Figures 9 and 10, the limiting component 14 also includes a first limiting component 14a and a second limiting component 14b. One end 14a1 of the first limiting component 14a is fixed to the fixing member 11. The first limiting component 14a The other end 14a2 (see Figure 11) is provided on the first slider 12a and moves along the second track provided on the first slider 12a. One end 14b1 of the second limiting member 14b is fixed on the fixing member 11. The other end 14b2 (see FIG. 11) of the member 14b is provided on the second slider 12b and moves along the second rail provided on the second slider 12b. Regarding the second track, please refer to the above description of the second track G2 in Figures 5 to 8, which will not be repeated here.

The installation operation of the installation assembly 10 on the guide rail 2 will be described below with reference to FIGS. 9 and 10 .

As shown in Figure 9, in the state shown in Figure 9, the first slider 12a and the second slider 12b are in the first limiting position and release the guide rail 2, that is, the other end of the first limiting member 14a 14a2 is at the first limiting part of the second rail in the first slider 12a, and the other end 14b2 of the second limiting member 14b is at the first limiting part of the second rail at the second slider 12b. In this case, The guide rail 2 can directly enter the opening 16 of the mounting component 10 and abut against the first elastic component 13a and the second elastic component 13b. When a force is exerted on the mounting component 10 in the direction P shown in Figure 9, a PUSH operation is performed. , the first elastic member 13a and the second elastic member 13b will receive the force opposite to the P direction from the guide rail 2. When the first elastic member 13a and the second elastic member 13b receive the force opposite to the P direction, The other ends 13a2 and 13b2 exert forces on the first slider 12a and the second slider 12b respectively to move the first slider 12a and the second slider 12b in a direction away from each other. That is to say, the first slider 12a and the second slider 12b move away from each other. The block 12a moves in the S direction, and the second slider 12b moves in the S' direction.

When the first elastic member 13a and the second elastic member 13b reach the maximum deformation state, in this case, the first slider 12a and the second slider 12b reach the first transition position. As shown in Figure 9, the elastic members 13a' and 13b' shown in dotted lines in Figure 9 represent the first elastic member and the second elastic member that have reached the maximum deformation state. The sliders 12a' and 12b' express the first slider and the second slider reaching the first transition position.

In this case, when the force applied to the first elastic member and the second elastic member decreases or disappears, that is, when the PUSH operation is canceled and the pushing force in the P direction of the mounting assembly 10 decreases or disappears, the The elastic member 13a and the second elastic member 13b can rebound to the state shown in Figure 10 by elastic restoring force.

As shown in FIG. 10 , the first elastic member 13a and the second elastic member 13b drive the first slider by the elastic restoring force of the elastic member when the first slider 12a and the second slider 12b are in the first transition position. 12a and the second slider 12b move to the second limit position shown in Figure 10 to clamp the guide rail 2, that is, the first slider 12a moves in the S' direction until it moves to the second limit position, and the second slider 12b faces Move in the S direction until it moves to the second limiting position. In this case, the other end 14a2 of the first limiting member 14a moves from the first transition part to the second limiting part in the second track of the first slider 12a. , the other end 14b2 of the second limiting member 14b moves from the first transition part to the second limiting part in the second track of the second slider 12b. When the other end 14a2 of the first limiting member 14a and the second limiting part When the other end 14b2 of the positioning member 14b moves to the second limiting part, the first limiting member 14a limits the first slider 12a at the second limiting position, and the second limiting member 14b limits the second slider 12b. In the second limiting position, the first slider 12a and the second slider 12b are held and clamped on the guide rail 2 to realize the installation of the installation assembly 10 on the guide rail 2 . Thus, the mounting assembly 10 is installed on the guide rail 2 through one PUSH operation.

The disassembly operation of the mounting assembly 10 from the guide rail 2 will be described below with reference to FIGS. 10 and 9 .

As shown in Figure 10, in the state shown in Figure 10, the first slider 12a and the second slider 12b are in the second limiting position, that is, the first slider 12a and the second slider 12b are in the clamping guide rail 2 position, and when no external force is applied to the first elastic member 13a and the second elastic member 13b, the second limiting member 14b limits the second slider 12b at the second limiting position, so that the first slider 12a and the second slider 12b are on the clamping guide rail 2. In this case, when a force is exerted on the mounting assembly 10 in the direction P shown in Figure 10, the first elastic component 13a and the second elastic component 13b will be affected by the guide rail 2. 2, when the first elastic member 13a and the second elastic member 13b receive the force opposite to the P direction, their other ends 13a2 and 13b2 respectively push the first slider 12a and the second elastic member 13b. The second slider 12b exerts an urging force to move the first slider 12a and the second slider 12b in directions away from each other, that is, the first slider 12a moves in the S direction and the second slider 12b moves in the S' direction.

When the first elastic member 13a and the second elastic member 13b reach the maximum deformation state, for example, the first elastic member 13a reaches the state shown by the elastic member 13a' shown by the dotted line in Fig. 9, and the second elastic member 13b reaches the state shown in Fig. 9 In the state shown by the elastic member 13b' shown by the middle dotted line, the first slider 12a and the second slider 12b have reached the second transition position. It is worth noting that when the slider (the first slider 12a and the second slider 12b) is in the second transition position, the maximum deformation state reached by the elastic component (the first elastic component 13a and the second elastic component 13b) can be It is the same as the maximum deformation state reached by the elastic component when the slider is in the first transition position, but it can also be different. For example, when the first transition part and the second transition part are asymmetrical with respect to the S direction, the maximum deformation state reached by the elastic component Differently, in the examples of FIG. 9 and FIG. 10 , the maximum deformation state reached by the elastic component is the same for ease of explanation.

In this case, when the force applied to the first elastic member 13 a and the second elastic member 13 b decreases or disappears, that is, when the PUSH operation is canceled and the pushing force in the P direction of the mounting assembly 10 decreases or disappears, , the first elastic member 13a and the second elastic member 13b rebound by elastic restoring force.

As shown in Figure 9, the first elastic member 13a and the second elastic member 13b drive the first slider 12a and the second slider 12b to move toward each other through their elastic restoring force, that is, the first slider 12a Moving in the S' direction, the second slider 12b moves in the S direction, the other end 14a2 of the first limiting member 14a moves in the second track of the first slider 12a, and the other end 14b2 of the second limiting member 14b moves in the S' direction. The second slider 12b moves in the second track. When the first elastic component 13a and the second elastic component 13b rebound to the state shown by the solid line elastic component 13 in Figure 9, that is, the first elastic component 13a and the third elastic component The component 13b moves to the first limiting position, the other end 14a2 of the first limiting component 14a and the other end 14b2 of the second limiting component 14b move to the first limiting part, and the first slider 12a and the second slider 12b remains at the first limiting position, that is, the first slider 12a and the second slider 12b are in a state of releasing the guide rail 2. In this case, the installation assembly 10 can be disassembled from the guide rail 2, thereby realizing the installation assembly 10 To detach from the guide rail 2, in addition, according to the above description, in this case, the guide rail 2 can also be directly inserted into the opening 16 of the mounting assembly 10 and abutted against the first elastic member 13a and the second elastic member 13b to be installed again. operate. Thus, the mounting assembly 10 is detached from the guide rail 2 through one PUSH operation.

In the embodiment of the present application, since the installation and removal of the installation component 10 can be performed with one PUSH, no additional tools are needed, and the user can complete it with one-handed operation, which greatly improves the user's operational convenience. It is flexible and does not need to be provided with parts for cooperating with tools on the slider, such as the hook portion exposed on the fixing part for pulling the slider, which can save the required installation operation/disassembly operation space. In addition, it includes installation When the electrical product of component 10 is large, there is no need to set the mounting component on the edge of the electrical product to expose the hooking portion. In other words, the mounting component can be located anywhere on the electrical product, such as the center of the product, and can be lifted and installed on the guide rail. The installation stability of electrical products.

In the embodiment of the present application, the fixing member may be made of, for example, a metal material, but this application is not limited to this. A track structure for the slider to slide may be formed on the fixing member 11. For example, the fixing member 11 may be formed to slide along the slider. The slider slides in the receiving part under force, but the application is not limited to this. For example, the fixing member 11 can also form a track portion extending along the sliding direction of the slider, and the track is formed on the slider. The clamping parts cooperate with each other, so that the slider can slide along the track part under force. This application does not limit this, and it can be based on actual Make settings as needed.

In the embodiment of the present application, the first elastic component 13a can drive the first slider 12a to move in the S' direction through its elastic restoring force, and the second elastic component 13b can drive the second slider 12b to move in the S' direction through its elastic restoring force. Move in S direction. For example, the other end 13a2 of the first elastic member 13a and the first slider 12a are movably connected, as shown in Figures 1 to 4, but are not limited to this. The other end 13a2 of the first elastic member 13a The matching structure with the first slider 12a is such that the other end 13a2 of the first elastic member 13a can drive the first slider 12a to move. For example, the other end 132a of the first slider 12a with the first elastic member 13a2 The fitting part is a groove, and the other end 13a2 of the first elastic member 13a is embedded in the groove and drives the first slider 12a to move. That is, when the other end 13a2 of the first elastic member 13a moves in the direction P, it can drive the first slider. The block 12a moves relative to the fixed member 11, and when the other end 13a2 of the first elastic member 13a moves in the opposite direction to the direction P, it can also drive the first sliding block 12a to move relative to the fixed member 11. Therefore, when the guide rail 2 applies When the force of the first elastic member 13a disappears, the other end 13a2 of the first elastic member 13a rebounds and drives the first slider 12a to move in the S' direction. The other end 13b2 of the second elastic member 13b and the second slider The connection method of block 12b is the same and will not be introduced one by one.

However, the application is not limited thereto. For example, the elastic member 13 may also include a special rebound member to realize the movement of the first slider 12a toward the S' direction and the movement of the second slider 12b toward the S direction.

For example, FIG. 11 is a three-dimensional schematic view of the mounting assembly according to the embodiment of the first aspect of the present application.

As shown in Figure 11, in one or more embodiments, the elastic component 13 also includes a rebound component 133. When the elastic component 13 includes a first elastic component 13a and a second elastic component 13b, the rebound component 133 corresponds to The ground may include a first resilient component 133a and a second resilient component 133b. Therefore, when the first slider 12a and the second slider 12b reach the first transition position or the second transition position and the guide rail 2 no longer exerts force on the first elastic member 13a and the second elastic member 13b, , the rebound member 133 can further ensure that the first slider 12a and the second slider 12b move from the first transition position or the second transition position to the second limiting position or the first limiting position. As shown in Figure 11, in the embodiment of the present application, one end 133a1 of the first rebound member 133a is fixed to the fixing member 11, and the other end 133a2 of the first rebound member 133a is fixed to the first slider 12a. When the block 12a moves to the first transition part or the second transition part, the first rebound member 133a can move the first slider 12a to the second limiting position or the first limiting position through elastic restoring force. The second rebound component 133b has the same principle and will not be introduced one by one.

In this case, the first elastic member 13a and the second elastic member 13b can be used to move the first slider 12a and the second slider 12b from the first transition position or The second transition position moves to the second limit position or the first limit position, that is, the first elastic member 13a and the second elastic member 13b are only used to drive the first slide when receiving the force of the guide rail 2 due to the PUSH operation. The block 12a and the second slider 12b move When the PUSH operation is removed, both the first elastic member 13a and the second elastic member 13b can be in a natural state, that is, not deformed by force, which can improve the use of the first elastic member 13a and the second elastic member 13b. life. In addition, one end of the rebound member 133 is fixed to the slider 12, that is, the first slider 12a and the second slider 12b are connected as a whole through the rebound member 133 provided in the middle, which can enhance the strength of the slider 12, so that it can For example, the clamping state clamps the guide rail 2 more reliably.

However, the present application is not limited to this. Resilient force can also be provided by the resilient member 133 and the first elastic member 13a and the second elastic member 13b at the same time, or only by the elastic member (the first elastic member 13a and the second elastic member 13b). Resilience can be set according to actual needs.

As shown in Figure 11, in one or more embodiments, the number of first elastic members 13a and the number of second elastic members 13b are both 2, 2 first elastic members 13a and 2 second elastic members 13b Both are arranged in the space K between the first slider 12a and the second slider 12b, and a first elastic component 13a-1 and a second elastic component 13b-1 are arranged in the first direction DD in the space K. On one side of the space K, another first elastic member 13a-2 and another second elastic member 13b-2 are provided on the other side in the first direction DD in the space K, and the first direction DD is perpendicular to the first slider 12a The arrangement direction of the first slider 12a and the second slider 12b is parallel to the direction S and the direction S'.

Thus, by providing a pair of elastic members at both ends in the direction perpendicular to the arrangement direction of the first slider 12a and the second slider 12b, the slider 12 (the first slider 12a, the second slider 12b) It can receive the balanced driving force exerted by the elastic component 13 to ensure the smooth progress of the installation/disassembly operation.

However, the application is not limited thereto. For example, the elastic component 13 can also be provided at other positions in the first direction DD within the space K. For example, a group of elastic components 13 can be provided at an intermediate position in the first direction within the space K ( One elastic member 13 may include a first elastic member 13a and a second elastic member 13b), or multiple groups of elastic members may be provided at intervals in the first direction in the space K, for example, one group may be provided at both ends and in the middle. The elastic component is provided with three groups of elastic components, but the application is not limited to this. More than three groups of elastic components can also be provided. The intervals between the multiple groups of elastic components can be the same or different and can be selected according to actual needs.

As shown in Figure 11, a set of elastic components (the first elastic component 13a-2 and the second elastic component 13b-2) in Figure 11 is used as an example for explanation. In one or more embodiments, the first elastic component One end of 13a-2 (the end close to the center of space K) and one end of the second elastic member 13b-2 (the end close to the center of space K) are connected and fixed relative to the fixing member 11, for example, the first elastic member 13a-2 One end of the first elastic member 13b-2 and one end of the second elastic member 13b-2 can be fixed to the fixing member 11 or fixed relative to the fixing member 11 through other components. This application does not limit this. For example, one end of the first elastic member 13a-2 and the second One end of the elastic component 13b-2 can be connected together and fixed to the fixing member 11 Or fixed to other components, that is to say, the first elastic component 13a-2 and the second elastic component 13b-2 can be an integrally formed structure. Therefore, the guide rail 2 can apply a balanced force to the elastic component to ensure the operation effect. .

In one or more embodiments, as shown in Figure 11, when the first elastic component 13a-2 and the second elastic component 13b-2 are pressed by the guide rail 2, the first elastic component 13a-2 is in the first elastic component 13a-2. The inclined surface 12aS of the slider 12a moves toward the fixed member 11 to drive the first slider 12a. The second elastic member 13b-2 moves toward the fixed member 11 on the inclined surface 12bS of the second slider 12b to drive the second slider 12b.

Thus, the structure of driving the slider through the elastic member is realized in a simple manner.

However, the present application is not limited thereto. For example, taking the first slider 12a as an example, the surface of the first slider 12a that the first elastic member 13a-1 acts on may not be an inclined surface. For example, the surface may be in the same direction as the first direction. DD is a vertical vertical plane. In this case, when the first elastic member 13a-1 is in a natural state, that is, when the first elastic member 13a-1 is not deformed due to force, the approach of the first elastic member 13a-1 The end of the space K can be disposed close to the fixing member 11, and the end of the first elastic member 13a-1 close to the first slider 12a is far away from the fixing member 11, so that the first elastic member 13a-1 is supported by the guide rail. In the case of a force of 2, the end of the first elastic member 13a-1 close to the first slider 12a moves toward the fixing member along the vertical surface of the first slider 12a to drive the first slider 12a.

However, the present application is not limited thereto. For example, taking the first slider 12a as an example, the surface of the first slider 12a acted upon by the first elastic member 13a-1 may also be a curved surface or the inclination direction is opposite to the direction shown in Figure 11 The inclined surface can be set according to actual needs (for example, the first elastic member 13a-1 drives the first slider 12a to clamp or loosen the guide rail 2).

As shown in Figure 11, in one or more embodiments, the mounting assembly 10 may also include a base portion 17 disposed between the first slider 12a and the second slider 12b, one end of the first elastic component 13a ( The end portion close to the center of the space K) and one end (the end portion close to the center of the space K) of the second elastic member 13b are fixed to the base portion 17 . Thereby, the first elastic member can be reliably fixed. However, the present application is not limited to this. For example, the end portions of the first elastic member 13 a and the second elastic member 13 b close to the center of the space K may also be directly fixed to the fixing member 11 .

As shown in Figure 11, in one or more embodiments, one end 133a1 of the first resilient member 133a (the end close to the center of the space K) and one end 133b1 (near the center of the space K) of the second resilient member 133b end) is fixed to the base part 17. Thereby, the first rebound member 133a can be reliably fixed. However, the present application is not limited thereto. For example, the end portions 133a1 and 133b1 of the first resilient member 133a and the second resilient member 133b may also be directly fixed to the fixing member 11.

As shown in Figure 11, in one or more embodiments, one end of the first limiting component 14a is fixed to one end of the fixing member along the arrangement direction of the first slider and the second slider. The other end 14a2 of 14a moves in the second track when the first slider moves, and one end of the second limiting member 14b is fixed to the fixing member along the first The other end in the arrangement direction of the slider and the second slider, the other end 14b2 of the second stopper member 14b moves within the second rail when the second slider moves. However, the present application is not limited to this, and the first limiting component 14a and the second limiting component 14b can be installed in other ways.

FIG. 12 is another schematic diagram of the installation assembly of the embodiment of the first aspect of the present application, showing the situation viewed from the side away from the guide rail 2 toward the installation assembly along the direction P of the PUSH operation.

As shown in Figure 12, the mounting assembly 10 includes two slide blocks, namely a first slide block 12a and a second slide block 12b. As shown in Figure 12, the first slide block 12a and the second slide block 12b can be positioned relative to the fixing member. The first slider 12a and the first slider 12b are both provided with second rails G2. The two second rails G2 can also be provided symmetrically with respect to the center of the fixing member 11. In addition, regarding the first slider 12a and the first slider 12b, For the block 12a and the second slider 12b, please refer to the above description. For the second track G2 of the first slider 12a, please refer to the foregoing description, especially in Figure 7. For the second track G2 of the second slider 12b, please refer to The foregoing description, especially the description in Figure 7, will not be introduced one by one here.

Figures 13 and 14 show two schematic diagrams of the installation assembly of the embodiment of the first aspect of the present application. Two sliders 12 are provided on the fixing member 11 along the S direction and the S' direction. Figure 13 corresponds to that shown in Figure 1 Shown in the state, Figure 14 is a schematic three-dimensional view, showing the situation where a pair of elastic members 13 are respectively provided on both sides of the first direction D-D of the space K. Regarding the specific structure of the installation assembly shown in Figures 13 and 14 and the through The specific manner in which the installation component is installed on and removed from the guide rail 2 can be found in the foregoing content, and will not be introduced one by one here.

The above embodiments only illustrate the embodiments of the present application, but the present application is not limited thereto, and appropriate modifications can be made based on the above embodiments. For example, each of the above embodiments can be used alone, or one or more of the above embodiments can be combined.

It can be seen from the above embodiment that when the slider 12 is in the first limiting position and does not clamp the guide rail 2, when the elastic member 13 is subjected to the force exerted by the guide rail 2 through PUSH, the slider 12 can move from the first position. The limit position moves to the second limit position to clamp the guide rail 2. When the force exerted on the elastic member 13 disappears, the limit part limits the slider at the second limit position to keep the guide rail 2 clamped. When the elastic member 13 is again subjected to the force exerted by the guide rail 2 by pushing again, the slider can move from the second limiting position to the first limiting position and release the guide rail 2. When the force exerted on the elastic member 13 When the force disappears, the limiting part limits the slider at the first limiting position and keeps releasing the guide rail 2 . Therefore, it only takes one push to install the installation component 10 on the guide rail 2 or to remove the installation component from the guide rail 2, which realizes the convenience of operation and improves the customer experience.

Embodiments of the second aspect

An embodiment of the present application also provides an electrical product.

Figure 15 is a diagram of an electrical product according to the second embodiment of the present application. As shown in Figure 15, the electrical product 20 has the mounting assembly 10 and the electrical unit 21 described in the first embodiment. The unit 21 is fixed to the fixing member 11 . For example, the electrical unit 21 may be fixed to a surface of the fixing member 11 opposite to the surface on which the slider 12 is disposed. Since the structure of the mounting assembly 10 has been described in detail in the embodiment of the first aspect, its content is incorporated here, and the description is omitted here.

It can be seen from the above embodiments that the electrical product 20 can be installed on or removed from the guide rail 2 by only one PUSH operation, which realizes the convenience of operation and improves the customer experience.

The present application has been described above in conjunction with specific embodiments, but those skilled in the art should understand that these descriptions are exemplary and do not limit the scope of the present application. Those skilled in the art can make various variations and modifications to this application based on the spirit and principles of this application, and these variations and modifications are also within the scope of this application.

The preferred embodiments of the present application have been described above with reference to the accompanying drawings. The many features and advantages of these embodiments are apparent from this detailed description, and thus it is intended by the appended claims to cover all such features and advantages of these embodiments that fall within their true spirit and scope. Furthermore, since many modifications and changes will readily occur to those skilled in the art, the embodiments of the present application are not intended to be limited to the precise structures and operations illustrated and described, but rather to encompass all suitable modifications and equivalents falling within the scope thereof. things.

Claims (13)

1. A mounting component for a guide rail, characterized in that the mounting component includes:

   Fastener;

   a slider that is movable relative to the fixing member to clamp or loosen the guide rail;

   An elastic member is provided on the side of the slider close to the guide rail. One end of the elastic member is fixed relative to the fixing member, and the other end of the elastic member is connected to the side of the slider close to the guide rail. The elastic component can drive the slider to move relative to the fixed component under the action of external force, and the elastic component can drive the slider to move relative to the fixed component through elastic restoring force; and

   a limiting part that keeps the slider clamping the guide rail or loosening the guide rail,

   When the elastic member is acted upon by an external force, the elastic member drives the slider in the first limiting position to move. In the first limiting position, the slider is held by the limiting portion. In order to loosen the guide rail, when the slider moves to the second limiting position, the slider is held by the limiting part to clamp the guide rail,

   When the elastic member is acted upon by an external force again, the elastic member drives the slider in the second limiting position to move. When the slider moves to the first limiting position, , the slider is held by the limiting part to release the guide rail.
2. The installation assembly according to claim 1, characterized in that:

   When the elastic component is acted upon by an external force, the elastic component drives the slider in the first limiting position to move to the first transition position. When the slider is in the first transition position, the elastic component The elastic component drives the slider to move from the first transition position to the second limiting position through elastic restoring force. When the elastic component is acted upon by an external force again, the elastic component drives the slider to move to the second limiting position. The slider at the second limit position moves to the first limit position; or

   When the elastic member is acted upon by an external force, the elastic member drives the slider in the first limiting position to move to the second limiting position. When the elastic member is acted upon by an external force again, , the elastic component drives the slider in the second limiting position to move to the second transition position. When the slider is in the second transition position, the elastic component drives the slider through elastic restoring force. The block moves from the second transition position to the first limit position; or

   When the elastic component is acted upon by an external force, the elastic component drives the slider in the first limiting position to move to the first transition position. When the slider is in the first transition position, the elastic component The elastic component is The elastic restoring force drives the slider to move from the first transition position to the second limiting position. When the elastic member is acted upon by an external force again, the elastic member is driven to the second limiting position. The slider moves to the second transition position. When the slider is in the second transition position, the elastic component drives the slider to move from the second transition position to the second transition position through elastic restoring force. 1st limit position.
3. The installation assembly according to claim 2, characterized in that:

   The limiting portion includes an annular first track provided on the slider and the other end of the elastic component. The first track includes a first limiting portion and a second limiting portion. The elastic member said other end of the component moves unidirectionally within said first track,

   When the other end of the elastic member is located at the first limiting part, the elastic member limits the slider at the first limiting position. When the other end is located at the second limiting portion, the elastic member limits the slider at the second limiting position.
4. The installation assembly according to claim 3, characterized in that:

   The first track also includes a first transition portion. When the other end of the elastic component is located at the first transition portion, the slider is in the first transition position, and the elastic component is in maximum deformation state, and/or

   The first track also includes a second transition portion. When the other end of the elastic component is located at the second transition portion, the slider is in the second transition position, and the elastic component is in maximum deformation state,

   The first rail is formed on the side opposite to the direction of the one-way movement of the first limiting part, the first transition part, the second limiting part, and the second transition part. Step difference surface.
5. The installation assembly according to claim 2, characterized in that:

   The limiting part includes an annular second track provided on the slider and a limiting component. The second track includes a first limiting part and a second limiting part. One end of the limiting component is fixed to The other end of the fixing member and the limiting component moves in one direction in the second track,

   When the other end of the limiting member is located at the first limiting part, the limiting member limits the slider at the first limiting position. When the other end is located at the second limiting part, the limiting component limits the slider at the second limiting position.
6. The installation assembly according to claim 5, characterized in that:

   The second track also includes a first transition portion. When the other end of the limiting component is located at the first transition portion, the slider is in the first transition position, and the elastic component in a state of maximum deformation, and/or

   The second track also includes a second transition portion. When the other end of the limiting component is located at the second transition portion, the slider is in the second transition position, and the elastic component in a state of maximum deformation,

   The second rail is formed on the side opposite to the direction of the one-way movement of the first limiting part, the first transition part, the second limiting part, and the second transition part. Step difference surface.
7. The installation assembly according to claim 5 or 6, characterized in that:

   The limiting component is a limiting spring.
8. The mounting assembly according to any one of claims 1 to 6, characterized in that:

   The elastic component is a driving spring, one end of the driving spring is fixed on the first surface of the fixing part, and the other end of the driving spring is connected to the slider and is away from the first surface of the fixing part. ,

   When the driving spring is in the minimum deformation state, the slider is in the first limiting position or the second limiting position. The minimum deformation state is when the other end of the driving spring is away from the first limiting position. The farthest state.
9. The mounting assembly according to any one of claims 1 to 6, characterized in that:

   The slide block includes a first slide block and a second slide block, and the first slide block and the second slide block move in opposite directions relative to the fixing piece to clamp or loosen the guide rail,

   The elastic member includes a first elastic member and a second elastic member. The first elastic member and the second elastic member are provided between the first slider and the second slider. The first elastic member One end of the elastic member is fixed relative to the fixing piece, the other end of the first elastic member is connected to the first slider, one end of the second elastic member is fixed relative to the fixing piece, and the second elastic member is fixed to the fixing piece. The other end of the elastic member is connected to the second slider, and the first elastic member and the second elastic member can drive the first slider and the second slider in opposite directions under the action of external force. The first elastic member and the second elastic member can drive the first slider and the second slider to move in opposite directions through elastic restoring force.
10. The installation assembly according to claim 9, characterized in that:

    The number of the first elastic members and the number of the second elastic members are both 2, and the 2 first elastic members and the 2 second elastic members are both disposed on the first slider and the second elastic member. In the space between the second sliders, one of the first elastic members and one of the second elastic members are disposed on one side in the first direction in the space, and the other first elastic member and another second elastic member is disposed on the other side in the first direction in the space, and the first direction is perpendicular to the arrangement direction of the first slider and the second slider. .
11. The installation assembly according to claim 9, characterized in that:

    The elastic component also includes a resilient component, and the resilient component includes a first resilient component and a second resilient component,

    One end of the first resilient component is fixed to the fixing member, and the other end of the first resilient component is fixed to the In the first slider, one end of the second rebound member is fixed to the fixing member, and the other end of the second rebound member is fixed to the second slider,

    Under the action of the first resilient member and the second resilient member, the first slider and the second slider move in opposite directions.
12. The installation assembly according to claim 11, characterized in that:

    The resilient component is an S-shaped elastic piece.
13. An electrical product, characterized in that the electrical product includes:

    A mounting assembly as claimed in any one of claims 1 to 12; and

    An electrical unit is fixed to the fixture.