Patent Description:
In the prior art, during the installation of the damping toggle member and other accessories, an accessory is required to be mounted and configured to a mounting slot with narrow space, in which the accessory is required to enter the mounting slot from the opening of two ends of the mounting slot.

However, by adopting such an operating method, the accessory is required to be mounted into the mounting slot before sealing the opening of two ends of the mounting slot. In addition, when the accessory is required to be repaired or replaced, the seal of the opening of two ends should be disassembled to proceed with the maintenance or replacement.

For example, in a sliding door damping system, the mounting slot mentioned above is provided in an upper door frame and the accessory mentioned above is a damping toggle member. During the installation, if the installer installs the left and right door frames on two sides of the upper door frame but forgot to install the damping toggle member, the mounting of the damping toggle member may not proceed subsequently. Reinstalling the damping toggle member is required to disassemble the left and right door frames, which is too costly, time-consuming and labor-intensive. In addition, when the existing damping toggle member is damaged, similarly, the new damping toggle member may only be replaced after disassembling the current door frame. <CIT> discloses an intermediate part for fixing hardware to the frame of a door, window or the like, in which the intermediate part is formed by a profile in elastic deformable material with two substantially parallel walls connected by a connecting wall. <CIT> discloses a component combination of a first component and a second component with a T-slot, with a detachable connection between the two components, in which at least two clamping sections arranged adjacent to one another are provided on the first component.

In order to overcome at least one of the deficiencies of the prior art mentioned above, provided in the present disclosure is a mounting member, for C-shaped slots.

The technical solutions adopted in the present disclosure to solve the problem are as follows.

A mechanism body, a width of the mechanism body being changeable;
the mechanism body is configured to be embedded and restricted within a C-shaped slot from a slot opening of the C-shaped slot.

Width-changeable mechanism body is adopted in the present disclosure so that the mechanism body is easy to install and is restricted within the C-shaped slot.

Further, the mechanism body includes a first assembly and a second assembly;
the first assembly is an elastic element, and the second assembly is embedded in the first assembly.

Thus, the first assembly works as a shape-changing body of the mechanism body, used for changing the width of the mechanism body; the second assembly works as a backbone of the mechanism body, used for maintaining the stability of the mechanism body and controlling the change in the shape of the first assembly.

Further, the first assembly is provided with a placing part, in which the placing part is provided with a first contact surface on two sides thereof, and the second assembly is provided with a second contact surface on two sides thereof; the second assembly is placed in the placing part by abutting the second contact surface to the first contact surface.

Thus, the second assembly is provided in the placing part of the first assembly, so that the entire structure of the second assembly is more compact after assembling with the first assembly, which effectively reduces the space occupation rate of the two components and simplifies the assembly.

Further, the first contact surface is a first inclined surface inclined from top to bottom towards a middle of the first assembly, and the second contact surface is a second inclined surface adapted to the first contact surface.

Thus, the second assembly moves downward under its weight and may abut not only a bottom surface of the placing part but also two sides of the placing part, so that the first assembly may abut not only a bottom surface of the C-shaped slot but also two sides of the C-shaped slot.

Further, a height of the second assembly is less than a depth of the placing part, so that a top surface of the second assembly is lower than a top surface of the first assembly when the second assembly is placed in the placing part.

Thus, the role that the top surface of the second assembly is lower than the top surface of the first assembly is that: there is space allowing the second assembly to move upward, and the second assembly is less likely to fall out of the placing part. Specifically, when squeezing two sides of the first assembly, the second assembly moves upward, which may increase the compression of the entire width of the compressed mounting member, thereby facilitating mounting the mounting member into the C-shape slot from the slot opening.

Further, the placing part is provided with at least two guiding slots, and the second assembly is provided with a guiding block matching the guiding slot; when the second assembly is mounted on the placing part, the guiding block is inserted into the guiding slot to guide the assembly of the second assembly.

Thus, when assembling the mounting member to the C-shapedslot or disassembling from the C-shaped slot, the second assembly moves in the placing part, inwhich the snap-in position of the guiding slot and the guiding block may effectively prevent displacement of the second assembly.

Further, the placing part is provided with a blocking piece; when the second assembly is mounted on the placing part, the blocking piece is located above the second assembly to restrict a movement of the second assembly.

Specifically, the second assembly is provided with a blocking slot matched with the blocking piece, and the blocking piece is snap-fitted to the blocking slot to position the second assembly to the placing part.

Thus, the blocking piece may lock and restrict the position of the second assembly after the second assembly is fully mounted on the placing part, which effectively prevents the second assembly from detaching from the placing part and ensures the normal operation of the mounting member.

Further, the second assembly is provided with a threaded hole, in which a screw is screwed into the threaded hole; and the screw is rotated to form a spiral push against the second assembly, the screw being moved in a reverse direction relative to the second assembly to enable the second assembly to squeeze against the first assembly.

Thus, the first assembly is fixed in the C-shaped slot by the compression of a reverse spiral force of the screw, so that the second assembly presses the first assembly against an inner wall of the C-shaped slot, in which the screw mentioned above does not have to pass through the C-shaped slot, thus effectively avoiding damage to the C-shaped slot.

Further, the mounting member also includes two auxiliary parts, the two auxiliary parts are provided on two ends of the first assembly respectively;
an upper part of two ends of the auxiliary part is a guiding inclined-surface, while a lower part thereof is a positioning surface.

Thus, the upper part of two ends of the auxiliary part is the guiding inclined-surface, used for guiding the mounting member to enter the C-shaped slot from the slot opening. After finishing the mounting of the mounting member,the positioning surface of the auxiliary part may abut two sides of the slot opening, so as to preliminarily and simply position the mounting member.

Further, a middle of the auxiliary part is provided with an empty slot.

Thus, the empty slot is used to provide space to facilitate the compression of the first assembly.

Further, a bottom of the auxiliary part is provided with a protrusion.

Thus, the bottom of the auxiliary part is provided with the protrusion, in which the protrusion is used as a handle used for pushing the first assembly and the second assembly to move in the C-shaped slot.

In a further embodiment, not according to the invention, a bottom of the mechanism body is provided with an operating part, in which a width of the mechanism body is changed by operating the operating part.

Thus, the operating part may change the width of the mechanism body. Therefore, the operating part may adjust the mechanism body to any width and fix the mechanism body of that width.

In a further embodiment, not according to the invention, the mechanism body is provided with an elastic sheet, in which a side of the elastic sheet is an operating surface; the operating part is provided below the operating surface so that the operating part abuts the operating surface when the operating part moves upwards, so as to push the elastic sheet and drive the elastic sheet to move towards outside the mechanism body.

Thus, the elastic sheet is tensioned outward and eventually snap-fitted in the C-shaped slot by abutting the operating part to the elastic sheet.

In a further embodiment, not according to the invention, the mechanism body is provided with a pusher, in which the pusher is a worm or a rack board;.

Thus, after mounting the mechanism body into the C-shaped slot, by transmission of engagement, the worm or the rack board is driven by the operating part respectively, and the worm or the rack board works on the mechanism body, and the mechanism body opens in the C-shaped slot, so as to achieve the installation of the C-shaped slot of the mechanism body.

A damping toggle member includes the mounting member and a toggle block, in which the toggle block is provided on a bottom of the mounting member.

Thus, the mounting member works as a mounting base of the toggle block of the damping toggle member to facilitate the installation of the toggle block.

A damping toggle system includes a damping toggle member and a sliding track for mounting damping pulleys, in which a top of the sliding track is provided with a C-shaped slot and the damping toggle member is mounted into the C-shaped slot and compressed against an interior wall of the C-shaped slot; the toggle block of the damping toggle member is extended downward from a slot opening of the C-shaped slot.

In summary, the mounting member provided in the present disclosure has technical effects as follows.

The width dimension of the mechanism body is changeable to enable the mechanism body to be mounted into the C-shaped slot through the slot opening. By extending and retracting to change the width of the mechanism body, this method is simple to operate, which avoids repeated assembly and disassembly of the mechanism body, thereby reducing the mounting time and enhancing the mounting efficiency. The damping toggle member includes a mounting member and a toggle block, in which the mounting member works as a mounting base of the toggle block of the damping toggle member to facilitate the installation of the toggle block. The damping toggle system includes a damping toggle member and a sliding track for mounting damping pulleys, in which a top of the sliding track is provided with a C-shaped slot and the mounting member may be quickly mounted into the C-shaped slot. The quick installation of the damping toggle member improves the overall mounting efficiency of the system.

The meanings of the attached markings are as follows:
<NUM> mechanism body; <NUM> first assembly; <NUM> second assembly; <NUM> C-shaped slot; <NUM> slot opening; <NUM> placing part; <NUM> first contact surface; <NUM> guiding slot; <NUM> blocking piece; <NUM> second contact surface; <NUM> guiding block; <NUM> blocking slot; <NUM> threaded hole; <NUM> screw; <NUM> auxiliary part; <NUM> guiding inclined-surface; <NUM> positioning surface; <NUM> empty slot; <NUM> protrusion; <NUM> sliding track; <NUM> toggle; <NUM> avoiding slot; <NUM> positioning slot; <NUM> operating part; <NUM> pushing rod; <NUM> abutting ring; <NUM> driving gear; <NUM> elastic sheet; <NUM> pusher.

For better understanding and implementation, the technical solutions in the embodiments of the present disclosure are clearly and completely described below in conjunction with the attached drawings of the present disclosure.

In the description of the present disclosure, it is to be noted that the terms "up", "down", "front", "back", "left", "right", "vertical", "horizontal", "top", "bottom", "inside", "outside" and other orientation or position relationships are based on the orientation or position relationships shown in the attached drawings. It is only intended to facilitate description and simplify operation, but not to indicate or imply that the referred device or element has a specific orientation, or is constructed and operated in a specific orientation. Therefore, they should not be construed as a limitation of the present disclosure.

Unless otherwise defined, all terms including technical and scientific terms used herein have the same meaning as commonly understood by those skilled in the art to which the present disclosure belongs. The terms used herein in the specification of the present disclosure are used only to describe specific embodiments and are not intended as a limitation of the present disclosure.

Referring to <FIG>, disclosed in the present disclosure is a mounting member, for C-shaped slots. The mounting member includes:.

Referring to <FIG>, <FIG>, in order to fix the mounting member embedded in a C-shaped slot into the C-shaped slot <NUM>, on the basis of embodiment <NUM>, the mechanism body <NUM> includes:
a second assembly <NUM>, the second assembly <NUM> being a rigid element aiming that: the second assembly <NUM> is embedded in the first assembly <NUM> so as to support and fix the shape of the first assembly <NUM>. Therefore, it is to be known that, the second assembly <NUM> may directly enter the C-shaped slot <NUM> from the slot opening <NUM>, in which a width of the second assembly <NUM> is smaller than that of the slot opening <NUM>.

The assembling process between the first assembly <NUM> and the second assembly <NUM> is as follows. A top of the first assembly <NUM> is provided with a placing part <NUM>, specifically, the placing part being a bar slot. A bottom of the second assembly <NUM> is provided with steps protruding inward on both sides. After the second assembly <NUM> is mounted into the placing part <NUM>, a bottom of the second assembly <NUM> abuts a top surface of the step.

Specifically, the placing part <NUM> is provided with a first contact surface <NUM> on two sides thereof, and the second assembly <NUM> is provided with a second contact surface <NUM> on two sides thereof; the second assembly <NUM> is placed in the placing part <NUM> by contacting the second contact surface <NUM> with the first contact surface <NUM>.

Preferably, for positioning the installation of the second assembly <NUM> in the placing part <NUM>, the placing part <NUM> is provided with at least two guiding slots <NUM>. In the present embodiment, a number of the guiding slots <NUM> is two, and the two guiding slots <NUM> are provided on two ends of the placing part <NUM>. Correspondingly, the second assembly <NUM> is provided with a guiding block <NUM> matching the guiding slot <NUM>; when the second assembly <NUM> is mounted on the placing part <NUM>, the guiding block <NUM> is inserted to the guiding slot <NUM>.

Further, each side of the placing part <NUM> is provided at least one blocking piece <NUM> respectively. A top of the second assembly <NUM> is provided with a blocking slot <NUM> matching the blocking piece <NUM>. When the second assembly <NUM> is mounted on the placing part <NUM>, the blocking piece <NUM> is snap-fitted to the blocking slot <NUM>. It is to be noted that, since the second assembly <NUM> is able to move upward and downward in the placing part <NUM>, when mounting the blocking piece <NUM> to the placing part <NUM>, there is a gap between a bottom surface of the blocking piece <NUM> and a bottom surface of the blocking slot <NUM>.

Particularly, a height of the second assembly <NUM> is less than a depth of the placing part <NUM> so that a top surface of the second assembly <NUM> is lower than a top surface of the first assembly <NUM> when the second assembly <NUM> is placed in the placing part <NUM>.

Further, after mounting the first assembly <NUM> into the C-shaped slot <NUM>, the second assembly <NUM> is then mounted into the placing part <NUM>. Therefore, it is clear that an external force is required to push the second assembly <NUM> into the placing part. In the present embodiment, since the internal space of the C-shaped slot <NUM> is relatively small, the second assembly <NUM> is pushed into the placing part <NUM> through the spiral force of the screw. Therefore, the second assembly <NUM> is provided with, but is not limited to, two threaded holes <NUM>.

The mounting process between the mounting member and the C-shaped slot <NUM> is as follows. The second assembly <NUM> is firstly mounted into the placing part <NUM>, and then the screw <NUM> passes through a bottom of the placing part <NUM> to screw the screw <NUM> at least partially into the threaded hole <NUM>. Squeezing two sides of the first assembly <NUM>, so that the second assembly <NUM> slides to a top of the placing part <NUM>; until a width of the first assembly <NUM> is smaller than that of the slot opening <NUM>, the mounting member may be mounted into the C-shaped slot <NUM> through the slot opening <NUM>. Particularly, since the positioning restriction of the blocking piece <NUM>, when the second assembly <NUM> moves upward to a highest position, a bottom surface of the blocking slot <NUM> abuts a bottom surface of the blocking piece <NUM>. After the mounting member is completely placed into the C-shaped slot <NUM>, the mounting member recovers and stretches to two sides by the first assembly's <NUM> own elasticity, so that the placing part <NUM> is re-extended and re-opened. In such case, the second assembly <NUM> falls back into the placing part <NUM> by gravity and allows a bottom surface of the second assembly <NUM> to abut a top surface of the step at the bottom of the placing part <NUM>. Then, the screw <NUM> is screwed into the C-shaped slot <NUM>, and an end of the screw <NUM> passes through the second assembly <NUM> to abut to an inner wall of the C-shaped slot <NUM>. Finally, the second assembly <NUM> moves towards a side of the C-shaped slot provided with the slot opening <NUM> by the reverse spiral force, so as to compress against the first assembly <NUM>. Particularly, referring to <FIG>, in order to prevent an end of the screw <NUM> abutted an inner wall of the C-shaped slot <NUM> from displacing, an inner wall opposite to the slot opening <NUM> is provided with a positioning slot <NUM>. Therefore, an end of the screw <NUM> abuts the positioning slot <NUM>.

On the basis of that, further, the first contact surface <NUM> is restricted as a first inclined surface from top to bottom toward a middle of the first assembly <NUM>. Specifically, the two first contact surfaces <NUM> form a V-shaped structure with an upward opening. The second contact surface <NUM> is a second inclined surface matching the first contact surface <NUM>. The objective of the restriction of the inclined surface mentioned above is as follows. According to the description mentioned above, when the screw <NUM> pushes the second contact surface <NUM> into the placing part <NUM>, the second inclined surface squeezes the first inclined surface. Therefore, two sides of the first assembly <NUM> abut two inner walls of the C-shaped slot <NUM>, so as to fix the mounting member embedded in a C-shaped slot to the C-shaped slot <NUM>.

Preferably, the mounting member further includes two auxiliary parts <NUM>, and the two auxiliary parts <NUM> are provided on two sides of the first assembly <NUM> respectively. An upper part of two ends of the auxiliary part <NUM> is a guiding inclined-surface <NUM>, while a lower part thereof is a positioning surface <NUM>. A middle of the auxiliary part <NUM> is provided with an empty slot <NUM>. A bottom of the auxiliary part <NUM> is provided with a protrusion <NUM>.

Specifically, a distance between two positioning surfaces <NUM> is slightly greater than a width of the slot opening <NUM>, and a position of the positioning surface <NUM> is lower than a position of a main part of the first assembly <NUM>. Two guiding inclined surfaces <NUM> are inclined from the top of the two positioning surfaces <NUM> in a direction of contraction from bottom to top towards the middle of the auxiliary part <NUM> respectively. The protrusion <NUM> is provided on a bottom of the auxiliary part <NUM>.

The role of auxiliary part <NUM> is as follows. When the mounting member embedded in a C-shaped slot is mounted into the C-shaped slot <NUM>, the first assembly is compressed while the auxiliary part <NUM> is also compressed. In such a case, the empty slot <NUM> of the auxiliary part <NUM> is squeezed and closed. When a distance between two positioning surfaces <NUM> is smaller than a width of the slot opening <NUM>, then the mounting member is mountedinto the C-shaped slot <NUM>. After that, loosening the compression on the auxiliary part <NUM>, the two sides of the auxiliary part <NUM> abut the two sides of the slot opening <NUM> respectively, so as to preliminarily position the mounting member. Finally, the mounting member is fully fixed by screwing the screw <NUM>. It is to be noted that, after mounting the mounting member, the protrusion <NUM> is locatedoutside the C-shaped slot <NUM>; the protrusion <NUM> works as an operating part that takes out the mounting member from the C-shaped slot <NUM> or that pushes the mounting member to move in the C-shaped slot <NUM>.

The mounting member of embodiment <NUM> and embodiment <NUM> is applied to the damping toggle system. The damping toggle system also includes a sliding track <NUM> and a damping toggle member.

Specifically, the damping toggle member includes a mounting member and a toggle <NUM>. In the present embodiment, referring to <FIG>, <FIG> and <FIG>, the sliding track <NUM> exemplifies as an upper track. It is to be known that, abottom of the sliding track is provided with an avoiding slot <NUM> used for installation and movementof a damping assembly, in which the avoiding slot <NUM> is provided in a length direction of the slidingtrack <NUM>.

Specifically, the mounting member is mounted inside on a topwall. Specifically, the C-shaped slot <NUM> of the mounting member maybe designed as an integral part with the sliding track <NUM>. The C-shaped slot <NUM> is located right above the avoiding slot <NUM> of the sliding track <NUM>, in which the slot opening <NUM> is now located on a bottom of the C-shaped slot <NUM>.

The toggle <NUM> is provided on a bottom of the auxiliary part <NUM>, so the toggle <NUM> and the protrusion <NUM> are located outside the C-shaped slot <NUM>, and then the toggle <NUM> and the protrusion <NUM> form a double-toggle structure. After the toggle is provided on the bottom of the auxiliary part <NUM>, the mounting member is mounted into the C-shaped slot <NUM> based on the method mentioned above.

It is to be noted that, before the mounting member is fully fixed by the screw <NUM>, if the position of the toggle <NUM> is required to be adjusted, the positioning surface 72on two sides of the auxiliary part <NUM> may be pressed to temporarily release the positioning surface72 from contacting the track so as to move the mounting assembly.

The damping assembly passes through the avoiding slot <NUM> and is located below the toggle <NUM>. When the damping assembly moves along the avoiding slot <NUM>, the damping assembly abuts the toggle <NUM> to trigger the damping mechanism.

In the present embodiment, the difference from embodiment <NUM> is the structure of the first assembly <NUM>. Specifically, the first assembly <NUM> includes two terminals and two clamping blocks. Specifically, a width of the terminal is smaller than that of the slot opening <NUM>, and the two terminals are connected to two ends of the two clamping blocks respectively, so as to form a closed-loop series connection of the four components. Particularly, an end of the clamping block is slidably connected to the terminal. Meanwhile, to ensure the reset of the clamping block, a reset spring is provided between an end of the clamping block and the terminal. An inner surface of the clamping block is provided with a first contact surface <NUM>, and the placing part <NUM> is the position between the two first contact surface <NUM>, in which the protrusion <NUM> is provided on the first contact surface <NUM>.

Similarly, a width of the first assembly <NUM> of the present embodiment is adjusted as follows. Two clamping blocks are compressed in opposite directions, then the reset spring is compressed. When the overall width of the first assembly <NUM> is smaller than that of the slot opening <NUM>, the first assembly <NUM> is able to pass through the slot opening <NUM> and be mounted into the C-shaped slot <NUM>. After that, the two clamping blocks are pushed apart back-to-back by the elastic force of the reset spring, and eventually, the first assembly <NUM> is snap-fitted into the C-shaped slot <NUM>.

In the present embodiment, referring to <FIG>, the mounting member embedded in a C-shaped slot includes a mechanism body <NUM> and an operating part <NUM>.

The mechanism body <NUM> includes a base and two elastic sheets <NUM>. Two elastic sheets <NUM> are provided on two lateral edges of a top of the base at an opposite inclination. An inner surface of the elastic sheet <NUM> is an operating surface. A width of the base is slightly less than that of the slot opening <NUM> and the base is a rigid member. Particularly, a thickness of a top of the elastic sheet <NUM> is greater than that of a bottom thereof.

The operating part <NUM> includes a pushing rod <NUM> and an abutting ring <NUM>, in which a top of the pushing rod <NUM> passes through the base and finally is located between the two elastic sheets <NUM>. Preferably, the pushing rod <NUM> is screwed to the base and the abutting ring <NUM> is provided on the pushing rod <NUM> and located between the two elastic sheets <NUM>.

Referring to <FIG>, in the present embodiment, before the mounting member is mounted into the C-shaped slot <NUM>, an overall width thereof is smaller than thatof the slot opening <NUM>. Therefore, the mounting process of the mounting member and the C-shaped slot <NUM> is as follows. A top of the mechanism body <NUM> passes through the slot opening <NUM> and enters the C-shaped slot <NUM>. Then, the mechanism body <NUM> pushes the pushing rod <NUM> to move into the C-shaped slot <NUM>. The abutting ring <NUM> abuts the operatingsurface of two elastic sheets <NUM> respectively, so that upper parts of the two elastic sheets <NUM> movein opposite directions and spread out. Finally, the upper parts of the two elastic sheets <NUM> abut and compress against an inner wall of the C-shaped slot <NUM>. Then, the pushing rod <NUM> is rotatedto spirally push the base, so that the pushing rod <NUM> and the base are moving oppositely, which ensures that the base and the pushing rod <NUM> are compressed against an upper wall and a lowerwall of the C-shaped slot <NUM> respectively. Therefore, the mounting member embedded in a C- shaped slot is mounted into the C-shaped slot <NUM>.

In the present embodiment, referring to <FIG>, the mounting member embedded in a C-shaped slot includes a mechanism body <NUM>, an operating part <NUM> and a pusher.

The pusher is provided in the mechanism body <NUM>. Specifically, the mechanism body <NUM> includes a bottom base and an elastomer provided on the bottom base, in which a middle of the elastomer is provided with a mounting slot, and the pusher is provided on the bottom base and located in the mounting slot. Specifically, a width of the bottom base is smaller than a width of the slot opening <NUM> of the C-shaped slot <NUM>.

The operating part <NUM> includes a rotating rod and a driving gear <NUM>, in which the rotating rod is rotatably provided on the bottom base, and the driving gear <NUM> is provided on the rotating rod and located in the mounting slot. Preferably, the pusher is a worm. A number of the worms is two. Two worms are movably provided in the mounting slot. Two worms are symmetrically engaged on two sides of the driving gear <NUM>. Two worms driven by the driving gear <NUM> vertically abut two inner walls of the mounting slot.

In the present embodiment, referring to <FIG>, before the mounting member is mounted into the C-shaped slot <NUM>, the overall width thereof is smaller than thatof the slot opening <NUM>. Therefore, the mounting process of the mounting member and the C-shaped slot <NUM> is as follows. A top of the mechanism body <NUM> passes through the slot opening <NUM> and enters the C-shaped slot <NUM>. Then the rotating rod is rotated to drive the two worms to move oppositely and finally push the two lateral walls of the mounting slotto spread out. Finally, the elastomer abuts and compresses against an inner wall of the C-shapedslot <NUM>. Then the rotating rod is rotated to spirally push the mechanism body <NUM> so that the rotatingrod and the mechanism body <NUM> are moving oppositely, which ensures that the mechanism body <NUM> and the rotating rod are compressed against an upper wall and a lower wall of the C-shaped slot <NUM> respectively. Therefore, the mounting member is mounted into the C-shaped slot <NUM>.

In the other preferred embodiment, the worm may be substituted to a rack board. Similarly, two rack boards are symmetrically engaged on two sides of the driving gear <NUM>. Two rack boards driven by the driving gear <NUM> vertically abut two inner walls of the mounting slot. Particularly, in order to increase the abutting area between the rack board and an inner wall of the mounting slot, an end of the rack board used for abutting an inner wall of the mounting slot is provided with an abutting board.

Claim 1:
A mounting member, for C-shaped slots, comprising
a mechanism body (<NUM>), a width of the mechanism body (<NUM>) being changeable;
wherein the mechanism body (<NUM>) is configured to be embedded and restricted within a C-shaped slot (<NUM>) from a slot opening (<NUM>) of the C-shaped slot (<NUM>), the mechanism body (<NUM>) comprises a first assembly (<NUM>) and a second assembly (<NUM>), the first assembly (<NUM>) is an elastic element, the second assembly (<NUM>) is embedded in the first assembly (<NUM>), first assembly (<NUM>) is provided with a placing part (<NUM>), and the placing part (<NUM>) is provided with a first contact surface (<NUM>) on two sides thereof, the second assembly (<NUM>) is provided with a second contact surface (<NUM>) on two sides thereof, the second assembly (<NUM>) is placed in the placing part (<NUM>) by contacting the second contact surface (<NUM>) with the first contact surface (<NUM>), wherein the second assembly (<NUM>) is provided with a threaded hole, and a screw (<NUM>) is screwed into the threaded hole; and the screw (<NUM>) is rotated to form a spiral push against the second assembly (<NUM>), the screw (<NUM>) being moved in a reverse direction relative to the second assembly (<NUM>) to enable the second assembly (<NUM>) to squeeze against the first assembly (<NUM>), characterized in that
the first contact surface (<NUM>) is a first inclined surface inclined from top to bottom towards a middle of the first assembly (<NUM>), the second contact surface (<NUM>) is a second inclined surface adapted to the first contact surface (<NUM>), the placing part (<NUM>) is provided with at least two guiding slots (<NUM>), the second assembly (<NUM>) is provided with a guiding block (<NUM>) matching the guiding slot (<NUM>), and when the second assembly (<NUM>) is mounted on the placing part (<NUM>), the guiding block (<NUM>) is inserted to the guiding slot (<NUM>) to guide the second assembly (<NUM>).