CN210270692U - Shock attenuation silica gel callus on sole for computer base plate - Google Patents

Abstract

The utility model discloses a shock-absorbing silica gel foot pad for a computer substrate, which comprises a shock-absorbing box, wherein the upper wall surface of the shock-absorbing box is provided with an opening, a shock-absorbing structure is installed in the shock-absorbing box, and a pair of clamping structures with the same structure are installed on the two side wall surfaces outside the shock-absorbing box; the utility model relates to a silica gel callus on sole technical field, this device is rational in infrastructure, and is with low costs, high durability and convenient use, can be with the silica gel pad through the bolt, loading board and base plate main part are fixed, can carry out the shock attenuation to the base plate main part through shock-absorbing structure, when the outside vibrations that takes place of base plate main part, the motion pole can extrude the motion piece, the motion piece can extrude first spring thereupon, the loading board drives the base plate main part and descends, extrude the second spring simultaneously, at this moment, the vibrations that the external world produced just can be absorbed by first spring and second spring and walk, and simultaneously, the installation and the dismantlement of base plate main part have been made things convenient for.

Description

Shock attenuation silica gel callus on sole for computer base plate

Technical Field

The utility model relates to a silica gel callus on the sole technical field specifically is a shock attenuation silica gel callus on the sole for computer base plate.

Background

At present, when a computer substrate is assembled, in order to play a role in damping the computer substrate, the damping silica gel foot pad is generally attached to the bottom of the computer substrate.

The side wall of the current shock-absorbing silica gel foot pad is generally an annular vertical edge, so the shock-absorbing effect is poor, and the current computer substrate is inconvenient to mount and dismount.

SUMMERY OF THE UTILITY MODEL

Not enough to prior art, the utility model provides a shock attenuation silica gel callus on sole for computer base plate.

In order to achieve the above purpose, the utility model discloses a following technical scheme realizes: a shock-absorbing silica gel foot pad for a computer substrate comprises a shock-absorbing box, wherein an opening is formed in the upper wall surface of the shock-absorbing box, a shock-absorbing structure is installed in the shock-absorbing box, and a pair of clamping structures with the same structure is installed on the two side wall surfaces outside the shock-absorbing box;

the shock-absorbing structure includes: the device comprises a pair of supporting seats with the same structure, a supporting rod, a first spring, a pair of motion blocks with the same structure, a pair of motion rods with the same structure, a bearing plate, two pairs of extrusion blocks with the same structure, two pairs of second springs with the same structure, a silica gel pad and a substrate main body;

the pair of supporting seats are fixedly arranged on the lower wall surface in the shock absorption box, one end of the supporting rod is fixedly embedded in the pair of supporting seats, the first spring is movably sleeved at the central part of the supporting rod, the pair of moving blocks is movably sleeved on the supporting rod and is fixedly connected with the two ends of the first spring respectively, one end of the pair of moving rods is movably connected with the pair of moving blocks, the bearing plate is movably connected with one end of the pair of moving rods, the two pairs of extrusion blocks are fixedly arranged on the lower wall surface of the bearing plate, one end of the two pairs of second springs is fixedly arranged at the lower ends of the two pairs of extrusion blocks, the other end of the two pairs of second springs is fixedly connected with the lower wall surface in the shock absorption box, the silica gel pad is fixedly arranged on.

Preferably, the clamping structure includes: the clamping device comprises a fixed box, a third spring, a clamping block, a case, a pair of slide rails with the same structure, a pair of slide blocks with the same structure and a push rod;

the fixed box is fixedly arranged on the outer side wall surface of the shock absorption box, a first through hole is formed in the fixed box, the third spring is fixedly embedded in the first through hole in the fixed box, one end of the clamping block is fixedly arranged at one end of the third spring, the other end of the clamping block can move left and right through the first through hole in the fixed box, a second through hole and a third through hole are formed in the two side wall surfaces in the machine box, the second through hole corresponds to the third through hole in position, the second through hole is movably sleeved on the clamping block and is matched with the clamping block, the pair of slide rails are fixedly embedded in the upper wall surface and the lower wall surface in the third through hole, the pair of slide blocks are movably embedded in the pair of slide rails, and the push rod is fixedly arranged.

Preferably, connecting pieces are fixedly mounted at two ends of the first spring.

Preferably, the pair of motion blocks is connected with the pair of motion rods through a pin shaft.

Preferably, the push rod can push the clamping block to be separated from the second through hole.

Advantageous effects

Compared with the prior art, the beneficial effects of the utility model are that: this device is rational in infrastructure, with low costs, high durability and convenient use, can be with the silica gel pad through the bolt, loading board and base plate main part are fixed, can carry out the shock attenuation to the base plate main part through shock-absorbing structure, when the outside vibrations that take place of base plate main part, the motion pole can extrude the motion piece, the motion piece can extrude first spring thereupon, the loading board drives the decline of base plate main part, extrude the second spring simultaneously, at this moment, the vibrations of external production just can be absorbed away by first spring and second spring, and simultaneously, the installation and the dismantlement of base plate main part have been made things convenient for through fixed knot structure.

Drawings

Fig. 1 is a schematic view of the structure of the present invention;

FIG. 2 is an enlarged schematic view of the position A of the present invention;

fig. 3 is a schematic side view of the shock-absorbing structure of the present invention.

In the figure: 1. a damper box; 2. a supporting seat; 3. a support bar; 4. a first spring; 5. a motion block; 6. a motion bar; 7. a carrier plate; 8. extruding the block; 9. a second spring; 10. a silica gel pad; 11. a substrate main body; 12. a bolt; 13. a fixed box; 14. a first through hole; 15. a third spring; 16. a clamping block; 17. a chassis; 18. a second through hole; 19. a third through hole; 20. a slide rail; 21. a slider; 22. a push rod; 23. and (7) connecting the sheets.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Referring to fig. 1-3, the present invention provides a technical solution: a shock-absorbing silica gel foot pad for a computer substrate comprises a shock-absorbing box 1, wherein an opening is formed in the upper wall surface of the shock-absorbing box 1, a shock-absorbing structure is installed in the shock-absorbing box 1, and a pair of clamping structures with the same structure is installed on the outer side wall surface of the shock-absorbing box 1; shock-absorbing structure includes: the device comprises a pair of supporting seats 2 with the same structure, a supporting rod 3, a first spring 4, a pair of motion blocks 5 with the same structure, a pair of motion rods 6 with the same structure, a bearing plate 7, two pairs of extrusion blocks 8 with the same structure, two pairs of second springs 9 with the same structure, a silica gel pad 10 and a substrate main body 11; a pair of supporting seats 2 is fixedly arranged on the lower wall surface in a damping box 1, one end of a supporting rod 3 is fixedly embedded in the pair of supporting seats 2, a first spring 4 is movably sleeved at the central part of the supporting rod 3, a pair of moving blocks 5 is movably sleeved on the supporting rod 3 and is respectively fixedly connected with the two ends of the first spring 4, one end of a pair of moving rods 6 is movably connected with the pair of moving blocks 5, a bearing plate 7 is movably connected with one end of the pair of moving rods 6, two pairs of squeezing blocks 8 are fixedly arranged on the lower wall surface of the bearing plate 7, one ends of two pairs of second springs 9 are fixedly arranged at the lower ends of the two pairs of squeezing blocks 8, the other ends of the two pairs of second springs are fixedly connected with the lower wall surface in the damping box 1, a silica gel pad 10 is fixedly arranged on the upper wall surface of the bearing plate 7, a substrate main body, can carry out the shock attenuation to base plate main part 11 through shock-absorbing structure, when base plate main part 11 outside takes place vibrations, motion pole 6 can extrude motion block 5, and motion block 5 can extrude first spring 4 thereupon, and loading board 7 drives base plate main part 11 and descends, extrudees second spring 9 simultaneously.

Preferably, further, the clamping structure includes: the device comprises a fixed box 13, a third spring 15, a clamping block 16, a case 17, a pair of slide rails 20 with the same structure, a pair of slide blocks 21 with the same structure and a push rod 22;

the fixed box 13 is fixedly arranged on the outer side wall surface of the damping box 1, a first through hole 14 is arranged in the fixed box, a third spring 15 is fixedly embedded in the first through hole 14 in the fixed box 13, one end of a clamping block 16 is fixedly arranged at one end of the third spring 15, and the other end can move left and right through the first through hole 14 in the fixed box 13, the two side wall surfaces in the machine box 17 are provided with a second through hole 18 and a third through hole 19, the second through hole 18 corresponds to the third through hole 19, the second through hole 18 is movably sleeved on the clamping block 16, and is matched with the clamping block 16, a pair of slide rails 20 are fixedly embedded on the upper wall surface and the lower wall surface of the third through hole 19, a pair of slide blocks 21 are movably embedded in the pair of slide rails 20, a push rod 22 is fixedly arranged between the pair of slide blocks 21, the mounting and dismounting of the base plate main body 11 are facilitated by the cooperation of the third spring 15, the clamping block 16 and the push rod 22 in the fixing structure.

Preferably, the first spring 4 is fixedly provided with connecting pieces 23 at two ends: the connecting piece 23 serves to increase the contact area of the first spring 4.

Preferably, the pair of motion blocks 5 is connected with the pair of motion rods 6 by a pin.

Preferably, the push rod 22 pushes the engaging block 16 out of the second through hole 18.

The following working principles, detailed connecting means thereof, and the following main descriptions of the working principles and processes thereof are well known in the art, and will be referred to by those skilled in the art for the specific connection and operation sequence of the components in the present disclosure.

Example (b): as shown in the attached drawings 1-3, when in use, a silicon rubber pad 10 is placed on a bearing plate 7, then a substrate main body 11 is placed on the silicon rubber pad 10, the silicon rubber pad 10 and the clamping block 16 are connected together through a bolt 12, when the device is installed, the clamping block 16 is pressed inwards, the third spring 15 is elastically compressed, the clamping block 16 enters a fixed box 13, the damping box 1 is moved downwards, the whole device enters a machine box 17, the device continues to move downwards, when the clamping block 16 moves to the side edge of a second through hole 18, the third spring 15 is elastically restored, the clamping block 16 is pushed into the second through hole 18, at the moment, the substrate main body 11 is installed, when the device needs to be disassembled, a push rod 22 is pushed, sliding blocks 21 at two ends of the push rod 22 slide forwards through a slide rail 20, the push rod 22 presses the clamping block 16, so that the clamping block 16 is separated from the second through hole 18, the damping box 1 is moved upwards, and at the moment, when the substrate body 11 is affected by the outside to generate vibration, the motion rod 6 can extrude the motion block 5 inwards, the motion block 5 can extrude the first spring 4 inwards through the support rod 3, the substrate body 11 descends along with the bearing plate 7, meanwhile, the bearing plate 7 can extrude the second spring 9, at the moment, the vibration generated by the outside can be absorbed by the first spring 4 and the second spring 9, and the substrate body 11 is effectively protected.

In the description of the present invention, it is to be understood that the terms "coaxial", "bottom", "one end", "top", "middle", "other end", "upper", "one side", "top", "inner", "front", "center", "both ends", and the like, indicate orientations or positional relationships based on the orientations or positional relationships illustrated in the drawings, and are only for convenience of description and simplicity of description, and do not indicate or imply that the device or element referred to must have a particular orientation, be constructed and operated in a particular orientation; meanwhile, unless explicitly specified or limited otherwise, the terms "mounted", "disposed", "opened", "embedded", "extended", "penetrated", "nested", and the like are to be understood in a broad sense, and may be, for example, fixedly connected, detachably connected, or integrated; can be mechanically or electrically connected; they may be directly connected or indirectly connected through an intermediate medium, and may be connected through the inside of two elements or in an interaction relationship between two elements, unless otherwise specifically defined, and the specific meaning of the above terms in the present invention will be understood by those skilled in the art according to specific situations.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (5)

1. A shock-absorbing silica gel foot pad for a computer substrate comprises a shock-absorbing box (1) and is characterized in that an opening is formed in the upper wall surface of the shock-absorbing box (1), a shock-absorbing structure is installed in the shock-absorbing box (1), and a pair of clamping structures with the same structure are installed on the outer side wall surface of the shock-absorbing box (1);

the shock-absorbing structure includes: the device comprises a pair of supporting seats (2) with the same structure, a supporting rod (3), a first spring (4), a pair of motion blocks (5) with the same structure, a pair of motion rods (6) with the same structure, a bearing plate (7), two pairs of extrusion blocks (8) with the same structure, two pairs of second springs (9) with the same structure, a silica gel pad (10) and a substrate main body (11);

the pair of supporting seats (2) are fixedly arranged on the inner lower wall surface of the damping box (1), one end of the supporting rod (3) is fixedly embedded in the pair of supporting seats (2), the first spring (4) is movably sleeved at the central part of the supporting rod (3), the pair of moving blocks (5) is movably sleeved on the supporting rod (3) and is respectively fixedly connected with two ends of the first spring (4), one end of the pair of moving rods (6) is movably connected with the pair of moving blocks (5), the bearing plate (7) is movably connected with one end of the pair of moving rods (6), the two pairs of extrusion blocks (8) are fixedly arranged on the lower wall surface of the bearing plate (7), one end of the two pairs of second springs (9) is fixedly arranged at the lower ends of the two pairs of extrusion blocks (8) and the other end of the two pairs of second springs are fixedly connected with the inner lower wall surface of the damping box (1), and the silica gel pad (10) is, the substrate main body (11) is connected with the bearing plate (7) and the silica gel pad (10) through bolts (12).

2. The shock-absorbing silica gel foot pad for the computer substrate as claimed in claim 1, wherein the clamping structure comprises: the device comprises a fixed box (13), a third spring (15), a clamping block (16), a case (17), a pair of slide rails (20) with the same structure, a pair of slide blocks (21) with the same structure and a push rod (22);

the fixed box (13) is fixedly arranged on the outer side wall surface of the damping box (1), a first through hole (14) is formed in the fixed box, the third spring (15) is fixedly embedded in the first through hole (14) in the fixed box (13), one end of the clamping block (16) is fixedly arranged at one end of the third spring (15), the other end of the clamping block (16) can move left and right through the first through hole (14) in the fixed box (13), the two side wall surfaces in the case (17) are provided with a second through hole (18) and a third through hole (19), the second through hole (18) corresponds to the third through hole (19), the second through hole (18) is movably sleeved on the clamping block (16) and is matched with the clamping block (16), the pair of slide rails (20) are fixedly embedded on the upper wall surface and the lower wall surface in the third through hole (19), and the pair of slide blocks (21) are movably embedded in the pair of slide rails (20), the push rod (22) is fixedly arranged between the pair of sliding blocks (21).

3. The shock-absorbing silica gel foot pad for the computer substrate as claimed in claim 1, wherein connecting pieces (23) are fixedly installed at two ends of the first spring (4).

4. The shock-absorbing silica gel foot pad for the computer substrate as claimed in claim 1, wherein a pair of the motion blocks (5) and a pair of the motion rods (6) are connected through a pin.

5. The shock-absorbing silica gel foot pad for the computer substrate as claimed in claim 2, wherein the push rod (22) can push the clamping block (16) to be separated from the second through hole (18).

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