CN112576136A - Glass lifting structure - Google Patents

Abstract

The invention discloses a glass lifting structure, which comprises a magnetic slide rail component arranged on the inner side of lifting glass and a magnetic guide rail component arranged on the inner side of corner window glass; the magnetic slide rail component is electrically connected with the magnetic pole changing component; one end of the magnetic slide rail assembly is positioned in the magnetic guide rail assembly; when the magnetic slide rail assembly and the magnetic guide rail assembly have opposite magnetic poles, the first side of the magnetic guide rail assembly is pressed against the first side of the magnetic slide rail assembly; when the magnetic slide rail assembly and the magnetic guide rail assembly have like magnetic poles, a distance is reserved between the first side of the magnetic guide rail assembly and the first side of the magnetic slide rail assembly, and the magnetic guide rail assembly can move in the magnetic slide rail assembly along the Z-axis direction. The invention can greatly reduce the noise and the frictional resistance generated in the lifting process of the lifting glass, and has stable lifting process and low use cost.

Description

Glass lifting structure

Technical Field

The invention relates to the technical field of glass lifting, in particular to a glass lifting structure.

Background

Existing window glass typically connects the glass directly to the riser. Taking a rear door window of an automobile as an example, the lifting guide rail of the rear window glass is integrally molded on the front side straight edge of the corner window glass, and a sealing strip and a U-shaped insert are assembled on the guide rail for ensuring the sealing property of the lifting glass. The sealing strip is in contact with the lifting glass, and the sliding rail slides up and down along the guide rail under the matching of the U-shaped insert. This lifting structure of car rear window glass, because lift glass can produce the friction with the sealing strip at the lift in-process, U type inserts also can produce the friction with the guide rail, lead to lift glass to produce the friction noise at the lift in-process, frictional resistance when going up and down is great, lead to requiring highly to the driving motor power of riser, and lift glass's lift action is unstable, consequently, higher to the requirement of regulator, it is high to the goodness of fit uniformity requirement of guide rail and glass, it is more difficult to be applicable to the structure of flush formula.

Disclosure of Invention

The technical problem to be solved by the invention is as follows: provided is a glass lifting structure which reduces frictional resistance and frictional noise of lifting glass.

In order to solve the technical problems, the invention adopts the technical scheme that:

a glass lifting structure comprises a magnetic slide rail component arranged on the inner side of lifting glass and a magnetic guide rail component arranged on the inner side of corner window glass;

one end of the magnetic slide rail assembly is positioned in the magnetic guide rail assembly;

when the magnetic slide rail assembly and the magnetic guide rail assembly have opposite magnetic poles, the first side of the magnetic guide rail assembly is pressed against the first side of the magnetic slide rail assembly;

when the magnetic slide rail assembly and the magnetic guide rail assembly have like magnetic poles, a distance is reserved between the first side of the magnetic guide rail assembly and the first side of the magnetic slide rail assembly, and the magnetic guide rail assembly can move in the magnetic slide rail assembly along the Z-axis direction.

The invention has the beneficial effects that: in the invention, the aim of controlling the position relation between the magnetic slide rail assembly and the magnetic guide rail assembly is achieved by changing the magnetic field between the magnetic slide rail assembly and the magnetic guide rail assembly. When the magnetic slide rail assembly and the magnetic guide rail assembly have like magnetic poles, the magnetic slide rail assembly is in a suspended state because like poles repel each other, and the magnetic guide rail assembly moves in the Z-axis direction in the magnetic slide rail assembly, so that the noise is low, and the purposes of reducing noise and reducing frictional resistance can be achieved in the lifting process of lifting glass. When the magnetic slide rail assembly and the magnetic guide rail assembly have opposite magnetic poles, the first side of the magnetic guide rail assembly is pressed against the first side of the magnetic slide rail assembly, and the glass lifting structure has small friction resistance, so that the requirements on the power of a motor are lower, the noise in the lifting process is low, the lifting glass is more stable in the lifting process, the requirements on a regulator are reduced, and the use cost is greatly reduced.

Drawings

Fig. 1 is a partial cross-sectional view of a magnetic slide rail assembly and a magnetic guide rail assembly in a state of opposite magnetic poles in a second glass lifting structure according to an embodiment of the present invention;

FIG. 2 is a partial cross-sectional view of a magnetic slide rail assembly and a magnetic guide rail assembly in a same magnetic polarity state in a second glass lifting structure according to an embodiment of the present invention;

fig. 3 is a partial cross-sectional view of a magnetic slide rail assembly and a magnetic guide rail assembly in a glass lifting structure in a state of opposite magnetic poles according to a fourth embodiment of the present invention;

fig. 4 is a partial cross-sectional view of a magnetic slide rail assembly and a magnetic guide rail assembly in a state of like magnetic poles in a glass lifting structure according to a fourth embodiment of the present invention.

Description of reference numerals:

1. a magnetic slide rail assembly; 11. a first side of a magnetic slide rail assembly;

2. a magnetic guide rail assembly; 21. a first side of a magnetic guide rail assembly; 22. a magnetic guide rail body; 221. a magnetic member; 222. a support member; 23. a first seal member; 24. a second seal member;

3. lifting the glass; 4. a displacement sensor; 5. a support assembly; 6. a quarter window glass.

Detailed Description

In order to explain technical contents, achieved objects, and effects of the present invention in detail, the following description is made with reference to the accompanying drawings in combination with the embodiments.

Referring to fig. 1 to 4, a glass lifting structure includes a magnetic slide rail assembly installed inside a lifting glass and a magnetic guide rail assembly installed inside a quarter window glass;

one end of the magnetic slide rail assembly is positioned in the magnetic guide rail assembly;

when the magnetic slide rail assembly and the magnetic guide rail assembly have opposite magnetic poles, the first side of the magnetic guide rail assembly is pressed against the first side of the magnetic slide rail assembly;

when the magnetic slide rail assembly and the magnetic guide rail assembly have like magnetic poles, a distance is reserved between the first side of the magnetic guide rail assembly and the first side of the magnetic slide rail assembly, and the magnetic guide rail assembly can move in the magnetic slide rail assembly along the Z-axis direction.

The working principle of the invention is as follows:

by controlling the magnetic poles between the magnetic slide rail assembly and the magnetic guide rail assembly, the noise of the lifting glass in the lifting process is reduced, and the sealing performance of the lifting glass and the angle window glass in a static state is ensured.

From the above description, the beneficial effects of the present invention are: in the invention, the aim of controlling the position relation between the magnetic slide rail assembly and the magnetic guide rail assembly is achieved by changing the magnetic field between the magnetic slide rail assembly and the magnetic guide rail assembly. When magnetism sliding rail set spare and magnetism guide rail set spare have like magnetic pole, because like poles repel each other, magnetism sliding rail set spare is in unsettled state, and when magnetism guide rail set spare removed along Z axle direction in magnetism sliding rail set spare, the noise was little, can play the purpose of making an uproar and reducing frictional resistance at lift glass's lift in-process. The glass lifting structure has small friction resistance, so that the requirement on the power of a motor is lower, the noise in the lifting process is low, the lifting glass is more stable in the lifting process, the requirement on a regulator is reduced, and the use cost is greatly reduced.

Further, the magnetic rail assembly includes a magnetic rail body, a first seal, and a second seal;

the first sealing element is arranged at the first end of the magnetic guide rail body and is positioned between the lifting glass and one end of the magnetic slide rail component;

the second sealing element is arranged at the second end of the magnetic guide rail body and is positioned between one end of the magnetic slide rail component and the second end of the magnetic guide rail body;

when the magnetic slide rail assembly and the magnetic guide rail assembly have opposite magnetic poles, the lifting glass is pressed against the first sealing element, and one end of the magnetic slide rail assembly is pressed against the second sealing element.

As apparent from the above description, the first sealing member and the second sealing member are provided for securing the sealability between the lift glass and the quarter window glass when there is a magnetic polarity of opposite polarity between the magnetic slide rail assembly and the magnetic rail assembly.

Further, the magnetic guide rail body comprises an L-shaped magnetic part and an L-shaped supporting part;

the supporting piece is arranged on the inner side of the corner window glass;

the magnetic part is arranged on one side of the supporting part and forms an inverted F-shaped structure;

one end of the magnetic slide rail component is positioned between the supporting piece and the magnetic piece.

From the above description, when the magnetic member and the magnetic sliding rail assembly have the same magnetic pole, the L-shaped magnetic member can generate acting force on the magnetic sliding rail assembly in the X-axis direction and the Y-axis direction, so as to ensure the stability of the magnetic sliding rail assembly in the lifting process.

Furthermore, a permanent magnetic substance is arranged inside the first end of the magnetic guide rail body.

As can be seen from the above description, the first end of the magnetic rail body has a permanent magnetic substance, so that the magnetic field between the magnetic rail body and the magnetic rail assembly can be changed by changing the magnetism of the magnetic rail assembly, so that the magnetic pole conversion is more reliable.

Further, the magnetic part and the supporting part are integrally formed.

From the above description, it can be known that the magnetic member and the supporting member are integrally formed, so that the formed inverted F-shaped structure is more stable.

Furthermore, the magnetic slide rail component is L-shaped.

Further, the magnetic pole changing assembly is also included;

the magnetic pole changing assembly is electrically connected with the magnetic sliding rail assembly or the magnetic guide rail assembly.

From the above description, it can be known that the magnetic poles of the magnetic sliding rail assembly or the magnetic guide rail assembly are changed by the magnetic pole changing assembly and are matched with the magnetic piece with permanent magnetism, so as to control the position of the magnetic sliding rail assembly.

Further, when the magnetic slide rail assembly and the magnetic guide rail assembly have opposite magnetic poles, the outer surface of the lifting glass is flush with the outer surface of the corner window glass.

As can be seen from the above description, the outer surface of the lift glass is flush with the outer surface of the quarter window glass, which improves the flatness of the appearance of the vehicle door.

Further, the device also comprises a displacement sensor used for sensing the change of the distance value;

the displacement sensor is embedded in the first side of the magnetic sliding rail assembly or the first side of the magnetic guide rail assembly;

the displacement sensor is electrically connected with the magnetic change component.

It can be known from the above description that set up displacement sensor for the interval between the first side of response magnetic rail subassembly and the first side of magnetic slide rail subassembly changes, is convenient for control magnetic rail subassembly's magnetic strength, and then makes magnetic slide rail subassembly keep going up and down in suitable position.

Further, the device also comprises a support component;

the supporting component is arranged on the first side of the magnetic guide rail component;

when the magnetic slide rail assembly and the magnetic guide rail assembly have opposite magnetic poles, the first side of the magnetic slide rail assembly is pressed against the supporting assembly;

or the supporting component is arranged on the first side of the magnetic slide rail component;

when the magnetic slide rail assembly and the magnetic guide rail assembly have opposite magnetic poles, the supporting assembly is pressed against the first side of the magnetic guide rail assembly.

As can be seen from the above description, the supporting component is used for supporting the magnetic sliding rail component when the magnetic sliding rail component is in a static state, and the lifting glass is prevented from sinking after being subjected to external force, so that the lifting structure is prevented from being damaged.

Example one

Referring to fig. 1 and 2, a glass lifting structure includes a magnetic slide rail assembly 1 installed inside a lifting glass 3 and a magnetic guide rail assembly 2 installed inside a quarter window glass 6; one end of the magnetic slide rail component 1 is positioned in the magnetic guide rail component 2; when the magnetic slide rail assembly 1 and the magnetic guide rail assembly 2 have opposite magnetic poles, the first side 21 of the magnetic guide rail assembly is pressed against the first side 11 of the magnetic slide rail assembly, and the outer surface of the lifting glass 3 is flush with the outer surface of the corner window glass 6; when the magnetic slide rail assembly 1 and the magnetic guide rail assembly 2 have like magnetic poles, there is a distance a between the first side 21 of the magnetic guide rail assembly and the first side 11 of the magnetic slide rail assembly in the X-axis direction, and the magnetic guide rail assembly 2 can move in the Z-axis direction in the magnetic slide rail assembly 1. Specifically, the lifting glass 3 is mounted on the vehicle window lifter, and the lifting glass 3 and the magnetic slide rail assembly 1 are controlled to lift by the vehicle window lifter.

Example two

Referring to fig. 1 and 2, a glass lifting structure, on the basis of the first embodiment, a magnetic rail assembly 2 includes a magnetic rail body 22, a first sealing member 23, and a second sealing member 24; the first sealing element 23 is arranged on the first end of the magnetic guide rail body 22, and the first sealing element 23 is positioned between the lifting glass 3 and one end of the magnetic slide rail assembly 1; the second sealing element 24 is installed on the second end of the magnetic guide rail body 22, and the second sealing element 24 is located between one end of the magnetic slide rail assembly 1 and the second end of the magnetic guide rail body 22; when the magnetic slide rail assembly 1 and the magnetic guide rail assembly 2 have opposite magnetic poles, the lifting glass 3 is pressed against the first sealing member 23, and one end of the magnetic slide rail assembly 1 is pressed against the second sealing member 24. Wherein the first seal 23 and the second seal 24 each have at least one tongue.

Referring to fig. 1 and 2, the magnetic rail body 22 includes a magnetic member 221 in an L-shape and a support member 222 in an L-shape; the supporting member 222 is installed inside the quarter window glass 6; the magnetic member 221 is installed at one side of the supporting member 222 and forms an inverted F-shaped structure; one end of the magnetic slide rail assembly 1 is located between the supporting member 222 and the magnetic member 221.

Referring to fig. 1 and 2, the first end of the magnetic rail body 22 has a permanent magnetic substance therein; specifically, the magnetic member 221 is plastic with a permanent magnetic substance inside, the permanent magnetic substance is magnetic powder, the permanent magnetic substance inside the magnetic member 221 is filled inside the magnetic member 221, and the supporting member 222 is also plastic. Preferably, the magnetic member 221 is integrally formed with the supporting member 222.

Referring to fig. 1 and 2, the magnetic sliding rail assembly 1 is L-shaped, and preferably, the magnetic sliding rail assembly 1 is made of plastic with magnetic substances inside. Preferably, the magnetic substance is magnetic powder; the plastic of the magnetic slide rail assembly 1 is PA66+ GF30 or PP + GF30, but is not limited to PA66+ GF30 or PP + GF 30.

Referring to fig. 1 and 2, a pole changing assembly is further included; the magnetic pole changing assembly is electrically connected with the magnetic slide rail assembly 1.

Referring to fig. 1 and 2, a displacement sensor 4 for sensing a change in a pitch value is further included; the displacement sensor 4 is embedded in the first side 11 of the magnetic slide rail component or the first side 21 of the magnetic guide rail component; the displacement sensor 4 is electrically connected to the magnetic changing assembly through a controller.

The specific implementation process in this embodiment is as follows:

taking the magnetic member 221 as an N pole for example, the magnetic slide rail assembly 1 switches between an N pole and an S pole.

When the magnetic slide rail assembly 1 is an S-pole, one end of the magnetic slide rail assembly 1 is suspended between the magnetic member 221 and the supporting member 222, and the lifter controls the lifting glass 3 and the magnetic slide rail assembly 1 to move in the Z-axis direction. In the process that the magnetic slide rail assembly 1 moves along the Z-axis direction, the displacement sensor 4 senses the distance a between one end of the magnetic slide rail assembly 1 and the magnetic part 221 in real time, and when the distance a is too small, the current passing through the magnetic slide rail assembly 1 is increased to improve the magnetic force between the magnetic slide rail assembly 1 and the magnetic part 221 and enlarge the distance a, and on the contrary, the current passing through the magnetic slide rail assembly 1 is reduced to reduce the magnetic force between the magnetic slide rail assembly 1 and the magnetic part 221.

After the lifting glass 3 moves to a specified height in the Z-axis direction, the magnetic slide rail assembly 1 converts the magnetic pole into an S-pole under the action of the magnetic changing assembly, the magnetic slide rail assembly 1 and the magnetic part 221 attract each other, so that the first side 11 of the magnetic slide rail assembly is pressed against the second sealing member 24, the lifting glass 3 is pressed against the first sealing member 23, and the outer surface of the lifting glass 3 and the outer surface of the corner window glass 6 are located on the same plane.

In this embodiment, the magnetic property of the magnetic member 221 may be an S-pole.

EXAMPLE III

Referring to fig. 1 and 2, a glass lifting structure further comprises a support assembly 5 on the basis of the first embodiment; the supporting component 5 is arranged on the first side 21 of the magnetic guide rail component or the first side 11 of the magnetic slide rail component; when the magnetic slide rail assembly 1 and the magnetic guide rail assembly 2 have opposite magnetic poles, the first side 21 of the magnetic guide rail assembly is pressed against the supporting assembly 5. Specifically, the support assembly 5 is a support block. Specifically, the supporting component 5 and the displacement sensor 4 should be respectively located at two sides, that is, when the displacement sensor 4 is installed at the first side 21 of the magnetic guiding rail component, the supporting component 5 is installed at the first side 11 of the magnetic sliding rail component; on the contrary, when the displacement sensor 4 is mounted on the first side 11 of the magnetic sliding rail assembly, the supporting assembly 5 is mounted on the first side 21 of the magnetic guiding rail assembly.

Example four

Referring to fig. 3 and 4, a glass lifting structure, on the basis of the first embodiment, a magnetic rail assembly 2 includes a magnetic rail body 22, a first sealing member 23, and a second sealing member 24; the first sealing element 23 is arranged on the first end of the magnetic guide rail body 22, and the first sealing element 23 is positioned between the lifting glass 3 and one end of the magnetic slide rail assembly 1; the second sealing element 24 is installed on the second end of the magnetic guide rail body 22, and the second sealing element 24 is located between one end of the magnetic slide rail assembly 1 and the second end of the magnetic guide rail body 22; when the magnetic slide rail assembly 1 and the magnetic guide rail assembly 2 have opposite magnetic poles, the lifting glass 3 is pressed against the first sealing member 23, and one end of the magnetic slide rail assembly 1 is pressed against the second sealing member 24. Wherein the first seal 23 and the second seal 24 each have at least one tongue.

Referring to fig. 3 and 4, the magnetic rail body 22 includes a magnetic member 221 in an L-shape and a support member 222 in an L-shape; the supporting member 222 is installed inside the quarter window glass 6; the magnetic member 221 is installed at one side of the supporting member 222 and forms an inverted F-shaped structure; one end of the magnetic slide rail assembly 1 is located between the supporting member 222 and the magnetic member 221.

Preferably, the first end of the magnetic guide rail body 22 has a magnetic substance therein; specifically, the magnetic member 221 is plastic with magnetic substances inside, the magnetic substances are magnetic powder, the magnetic substances inside the magnetic member 221 are filled inside the magnetic member 221, and the support member 222 is also plastic. Preferably, the magnetic member 221 is integrally formed with the supporting member 222.

Referring to fig. 3 and 4, the magnetic sliding rail assembly 1 is L-shaped, and preferably, the magnetic sliding rail assembly 1 is made of plastic with permanent magnetic substances inside. Preferably, the permanent magnetic substance is magnetic powder; the plastic of the magnetic slide rail assembly 1 is PA66+ GF30 or PP + GF30, but is not limited to PA66+ GF30 or PP + GF 30.

Referring to fig. 3 and 4, a pole changing assembly is also included; the pole changing assembly is electrically connected to the magnetic rail assembly 2.

Referring to fig. 3 and 4, a displacement sensor 4 for sensing a change in the pitch value is further included; the displacement sensor 4 is embedded in the first side 11 of the magnetic slide rail component or the first side of the magnetic guide rail component 2; the displacement sensor 4 is electrically connected to the magnetic changing assembly through the controller, and the magnetic member 221 is electrically connected to the magnetic pole changing assembly for switching the magnetic pole of the magnetic member 221.

The specific implementation process in this embodiment is as follows:

taking the magnetic slide rail assembly 1 as an N pole for example, the magnetic member 221 is switched between an N pole and an S pole.

When the magnetic member 221 is an S-pole, one end of the magnetic member 221 is suspended on the side of the magnetic sliding rail assembly 1 away from the lifting glass 3, and the lifter controls the lifting glass 3 and the magnetic sliding rail assembly 1 to move in the Z-axis direction. In the process that the magnetic member 221 moves along the Z-axis direction, the displacement sensor 4 senses the distance a between one end of the magnetic slide rail assembly 1 and the magnetic member 221 in real time, when the distance a is too small, the controller increases the current passing through the magnetic member 221 to increase the magnetic force between the magnetic slide rail assembly 1 and the magnetic member 221, and enlarges the distance a, and conversely, the current passing through the magnetic member 221 is decreased to decrease the magnetic force between the magnetic slide rail assembly 1 and the magnetic member 221.

After the lifting glass 3 moves to a specified height in the Z-axis direction, the magnetic member 221 converts the magnetic pole into an S-pole under the action of the magnetic changing assembly, the magnetic sliding rail assembly 1 and the magnetic member 221 attract each other, so that the first side 11 of the magnetic sliding rail assembly is pressed against the second sealing member 24, the lifting glass 3 is pressed against the first sealing member 23, and the outer surface of the lifting glass 3 and the outer surface of the quarter window glass 6 are located on the same plane.

In this embodiment, the magnetism of the magnetic slide rail assembly 1 may also be S-pole.

In summary, in the glass lifting structure provided by the present invention, the magnetic pole changing manner is adopted to control the distance between the magnetic sliding rail assembly and the magnetic member, so that on one hand, the noise of the magnetic sliding rail assembly during the lifting process of the lifting glass can be minimized, and on the other hand, the sealing performance between the lifting glass and the quarter window glass can be ensured when the magnetic sliding rail assembly and the lifting glass are in the static state. The invention greatly reduces the noise and frictional resistance generated in the lifting process of the car window glass and greatly reduces the use cost; the invention has the advantages of reducing the requirement on the consistency of the goodness of fit of the guide rail and the glass, reducing the manufacturing difficulty and reducing the cost, and can be applied to the structure that the outer surface of the lifting glass is flush or not flush with the outer surface of the corner window glass, thereby improving the application range of the glass.

The above description is only an embodiment of the present invention, and not intended to limit the scope of the present invention, and all equivalent changes made by using the contents of the present specification and the drawings, or applied directly or indirectly to the related technical fields, are included in the scope of the present invention.

Claims (10)

1. A glass lifting structure is characterized by comprising a magnetic slide rail component arranged on the inner side of lifting glass and a magnetic guide rail component arranged on the inner side of corner window glass;

one end of the magnetic slide rail assembly is positioned in the magnetic guide rail assembly;

when the magnetic slide rail assembly and the magnetic guide rail assembly have opposite magnetic poles, the first side of the magnetic guide rail assembly is pressed against the first side of the magnetic slide rail assembly;

when the magnetic slide rail assembly and the magnetic guide rail assembly have like magnetic poles, a distance is reserved between the first side of the magnetic guide rail assembly and the first side of the magnetic slide rail assembly, and the magnetic guide rail assembly can move in the magnetic slide rail assembly along the Z-axis direction.

2. The glass lifting structure of claim 1, wherein the magnetic rail assembly comprises a magnetic rail body, a first seal, and a second seal;

the first sealing element is arranged at the first end of the magnetic guide rail body and is positioned between the lifting glass and one end of the magnetic slide rail component;

the second sealing element is arranged at the second end of the magnetic guide rail body and is positioned between one end of the magnetic slide rail component and the second end of the magnetic guide rail body;

when the magnetic slide rail assembly and the magnetic guide rail assembly have opposite magnetic poles, the lifting glass is pressed against the first sealing element, and one end of the magnetic slide rail assembly is pressed against the second sealing element.

3. The glass lifting structure of claim 2, wherein the magnetic guide rail body comprises an L-shaped magnetic member and an L-shaped support member;

the supporting piece is arranged on the inner side of the corner window glass;

the magnetic part is arranged on one side of the supporting part and forms an inverted F-shaped structure;

one end of the magnetic slide rail component is positioned between the supporting piece and the magnetic piece.

4. The window regulator structure of claim 2, wherein the first end of the magnetic track body has a permanent magnetic substance therein.

5. A glazing construction according to claim 3, wherein the magnetic member is formed integrally with the support member.

6. A glazing structure as claimed in claim 1 or 4, wherein the magnetic track assembly is L-shaped.

7. A glass lifting structure according to claim 1, further comprising a magnetic pole changing assembly;

the magnetic pole changing assembly is electrically connected with the magnetic sliding rail assembly or the magnetic guide rail assembly.

8. A glass lifting structure as claimed in claim 1, wherein the outer surface of the lifting glass is flush with the outer surface of the quarter light glass when the magnetic slide assembly and the magnetic guide assembly have opposite magnetic poles.

9. A glass lifting structure according to claim 1, further comprising a displacement sensor for sensing a change in the value of the separation distance;

the displacement sensor is embedded in the first side of the magnetic sliding rail assembly or the first side of the magnetic guide rail assembly;

the displacement sensor is electrically connected with the magnetic change component.

10. A glass lifting structure according to claim 1, further comprising a support assembly;

the supporting component is arranged on the first side of the magnetic guide rail component;

when the magnetic slide rail assembly and the magnetic guide rail assembly have opposite magnetic poles, the first side of the magnetic slide rail assembly is pressed against the supporting assembly;

or the supporting component is arranged on the first side of the magnetic slide rail component;

when the magnetic slide rail assembly and the magnetic guide rail assembly have opposite magnetic poles, the supporting assembly is pressed against the first side of the magnetic guide rail assembly.

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