CN216973817U - Structure is built to antidetonation room - Google Patents

Abstract

The utility model belongs to the technical field of the technique of structure is built in the room and specifically relates to a structure is built in antidetonation room is related to, a structure is built in antidetonation room, including base, bottom plate and the room body, two standing grooves have been seted up on the base, two backup pads have been preset on the base the backup pad is arranged in two standing grooves respectively, two the inserting groove has all been seted up in the backup pad, be provided with two plugboards on the bottom plate, two the plugboard is pegged graft respectively in two inserting grooves, the room position is on the bottom plate, be provided with the first shock attenuation piece that is used for reducing longitudinal vibration in the backup pad, be provided with the second shock attenuation piece that is used for reducing lateral vibration in the backup pad, be provided with the connecting piece that is used for joint support board on the base. This application has the effect that improves activity board house shock resistance.

Description

Structure is built to antidetonation room

Technical Field

The application relates to the technical field of structures are built in the room, especially relate to a structure is built in antidetonation room.

Background

With the frequent occurrence of natural disasters in recent years, earthquakes become natural disasters seriously harming, property loss and casualties caused by earthquakes are mainly caused by collapse of buildings, and a temporary movable board house needs to be built in a disaster area while earthquake relief is generally carried out.

In the related art, for the existing portable house, a color steel plate is usually adopted as a framework, a sandwich plate is adopted as a containment material, and members are connected by bolts, but the portable house is too simple and is not firm, and the anti-seismic effect is poor.

In view of the above-mentioned related technologies, the inventor considers that the prefabricated house is too simple and has poor earthquake-resistant effect, which is not favorable for resisting aftershocks.

SUMMERY OF THE UTILITY MODEL

In order to improve the shock resistance of activity board house, this application provides a structure is built to antidetonation room.

The application provides a structure is built to antidetonation room adopts following technical scheme:

the utility model provides a structure is built in antidetonation room, includes base, bottom plate and the room body, two standing grooves have been seted up on the base, two backup pads have been preset on the base, two the backup pad is arranged in two standing grooves respectively, two the inserting groove has all been seted up in the backup pad, be provided with two plugboards on the bottom plate, two the plugboard is pegged graft respectively in two inserting groove, the room body is arranged in the bottom plate, be provided with the first shock attenuation piece that is used for reducing longitudinal vibration in the backup pad, be provided with the second shock attenuation piece that is used for reducing transverse vibration in the backup pad, be provided with the connecting piece that is used for joint support board on the base.

By adopting the technical scheme, the two supporting plates are preset in the placing grooves, the two inserting plates on the bottom plate are respectively inserted into the two inserting grooves, so that a house body can be built on the bottom plate, the assembly and disassembly are convenient and quick, the building efficiency of the prefabricated house is improved, and a certain gap is formed between the bottom plate and the base, so that the moisture on the ground is reduced from entering the prefabricated house, and the prefabricated house is convenient to use; through the fore-and-aft vibration vibrations of first bumper shock-absorbing member in order to reduce the backup pad, through the horizontal vibration vibrations of second bumper shock-absorbing member in order to reduce the backup pad to in the backup pad the shock resistance of the room body, and through the steadiness when the connecting piece is ensured ordinary use.

Optionally, the first damping member includes a longitudinal supporting block disposed on the supporting plate, a first damping spring is sleeved on the longitudinal supporting block, and the first damping spring is located between the supporting plate and the bottom wall of the placing groove.

Through adopting above-mentioned technical scheme, first shock-absorbing spring cover is established on vertical supporting shoe, plays to support the backup pad and live and use to in play fore-and-aft shock attenuation effect to the backup pad.

Optionally, the second damping member includes a plurality of transverse supporting blocks disposed on the supporting plate, the plurality of transverse supporting blocks are symmetrically distributed on two sides of the supporting plate, a second damping spring is sleeved on each transverse supporting block, and the second damping spring is located between the supporting plate and the side wall of the placing groove.

Through adopting above-mentioned technical scheme, establish on horizontal supporting shoe through second damping spring cover, transversely support the backup pad through the relative second damping spring that sets up to in the horizontal shock attenuation effect of improvement backup pad.

Optionally, the connecting piece includes a first telescopic rod hinged on the base, one end of the first telescopic rod is hinged on the base, the other end of the first telescopic rod is hinged on the supporting plate, and the two sides of the supporting plate are provided with the first telescopic rods.

Through adopting above-mentioned technical scheme, support the backup pad through first telescopic link to in the stability of improvement backup pad when normal use, reduce rocking of backup pad, improve the stability of the room body.

Optionally, a third damping spring is sleeved on the first telescopic rod.

Through adopting above-mentioned technical scheme, make first telescopic link have certain absorbing capacity of buffering through third damping spring to the shock-absorbing capacity of further improvement backup pad improves the shock attenuation effect of backup pad.

Optionally, a shock pad is arranged on the supporting plate and located between the supporting plate and the bottom wall of the placing groove.

Through adopting above-mentioned technical scheme, the shock pad plays the supporting role to the backup pad to in reducing rocking of backup pad, so that the use in activity board house, and the further fore-and-aft shock attenuation effect of backup pad that has strengthened of shock pad.

Optionally, a second telescopic rod is arranged on the supporting plate, one end of the second telescopic rod is hinged to the bottom plate, the other end of the second telescopic rod is hinged to the supporting plate, and a fourth damping spring is sleeved on the second telescopic rod.

Through adopting above-mentioned technical scheme, be connected bottom plate and backup pad through the second telescopic link, strengthened the joint strength between bottom plate and the backup pad to in the improvement backup pad and the bottom plate between be connected the steadiness.

Optionally, a sealing gasket for sealing a gap between the supporting plate and the side wall of the placing groove is arranged on the supporting plate.

Through adopting above-mentioned technical scheme, through sealed clearance between the sealed backup pad of filling up and the standing groove lateral wall to in reduce debris or rainwater entering into the standing groove, in order to improve the life of first shock attenuation piece, second shock attenuation piece and connecting piece.

In summary, the present application includes at least one of the following beneficial technical effects:

the two supporting plates are preset in the placing grooves, the two inserting plates on the bottom plate are respectively inserted into the two inserting grooves, a house body can be built on the bottom plate, the assembly and disassembly are convenient and rapid, the building efficiency of the movable plate house is improved, and a certain gap is formed between the bottom plate and the base, so that ground moisture is reduced from entering the movable plate house, and the movable plate house is convenient to use; the first shock absorbing part is used for reducing the longitudinal vibration and the transverse vibration of the supporting plate, and the second shock absorbing part is used for reducing the transverse vibration and the shock resistance of the house body on the supporting plate, so that the shock resistance of the house body on the supporting plate is improved, and the stability in normal use is ensured through the connecting part;

the supporting plate is supported through the first telescopic rod, so that the stability of the supporting plate in normal use is improved, the shaking of the supporting plate is reduced, and the stability of a house body is improved.

Drawings

Fig. 1 is a schematic overall structure diagram of an embodiment of the present application.

FIG. 2 is a cross-sectional view of one end of a base according to an embodiment of the present application.

Figure 3 is a cross-sectional view of the middle of the base of an embodiment of the present application.

Description of reference numerals: 1. a base; 2. a base plate; 3. a house body; 4. a placement groove; 5. a support plate; 6. inserting grooves; 7. a plugboard; 8. a longitudinal support block; 9. a first damping spring; 10. a transverse support block; 11. a second damping spring; 12. a first telescopic rod; 13. a third damping spring; 14. a shock pad; 15. a second telescopic rod; 16. a fourth damping spring; 17. a gasket; 18. a transverse slot; 19. and (4) mounting the groove.

Detailed Description

The present application is described in further detail below with reference to figures 1-3.

The embodiment of the application discloses structure is built to antidetonation room. Referring to fig. 1 and as 2, the structure is built in antidetonation room includes base 1, bottom plate 2 and the room body 3, two standing grooves 4 have been seted up on the base 1, 4 parallel arrangement in two standing grooves, two backup pads 5 have been preset on the base 1, two backup pads 5 are arranged in two standing grooves 4 respectively, inserting groove 6 has all been seted up on two backup pads 5, both ends difference welded fastening on the bottom plate 2 have two plugboards 7, two plugboards 7 are pegged graft respectively in two inserting groove 6, the room body 3 is installed on bottom plate 2, be provided with the first shock attenuation piece that is used for reducing longitudinal vibration on the backup pad 5, be provided with the second shock attenuation piece that is used for reducing transverse vibration on the backup pad 5, be provided with the connecting piece that is used for joint support board 5 on the base 1.

Referring to fig. 2, the first damping member includes a longitudinal supporting block 8 welded and fixed at two ends of the supporting plate 5, a first damping spring 9 is sleeved on the longitudinal supporting block 8, the first damping spring 9 is located between the supporting plate 5 and the bottom wall of the placing groove 4, one end of the first damping spring 9 is abutted to the supporting plate 5, the other end of the first damping spring is abutted to the bottom wall of the placing groove 4, and the supporting block is separated from the bottom wall of the placing groove 4.

Referring to fig. 2, the second damping member includes a plurality of transverse support blocks 10 welded and fixed on the support plate 5, the plurality of transverse support blocks 10 are symmetrically distributed on two sides of the support plate 5, a second damping spring 11 is sleeved on the transverse support block 10, the second damping spring 11 is located between the support plate 5 and the side wall of the placement groove 4, a transverse groove 18 is formed in the side wall of the placement groove 4, the transverse support block 10 is located in the transverse groove 18, one end of the second damping spring 11 is abutted to the transverse support block 10, and the other end is abutted to the bottom wall of the transverse groove 18.

Referring to fig. 3, the connecting piece includes first telescopic link 12 hinged on base 1, the hinge axis of first telescopic link 12 is parallel to the length direction of backup pad 5, mounting groove 19 has been seted up on base 1, mounting groove 19 and standing groove 4 intercommunication, first telescopic link 12 is located mounting groove 19, the one end of first telescopic link 12 articulates on the diapire of mounting groove 19, the other end articulates on backup pad 5, the both sides of backup pad 5 all are provided with first telescopic link 12. The first telescopic rod 12 is sleeved with a third damping spring 13, and the piston rod of the first telescopic rod 12 is sleeved with the third damping spring 13.

Referring to fig. 2 and 3, a second telescopic rod 15 is hinged to the supporting plate 5, one end of the second telescopic rod 15 is hinged to the bottom plate 2, the other end of the second telescopic rod 15 is hinged to the supporting plate 5, the hinge axis of the second telescopic rod 15 is parallel to the length direction of the supporting plate 5, a fourth damping spring 16 is sleeved on the second telescopic rod 15, and the fourth damping spring 16 is sleeved on a piston rod of the second telescopic rod 15. The supporting plate 5 is fixedly bonded with a shock pad 14, the shock pad 14 is located between the supporting plate 5 and the bottom wall of the placing groove 4, the shock pad 14 is a rubber pad, and the shock pad 14 is located between the two longitudinal supporting blocks 8. The joint has the sealed pad 17 that is used for sealed backup pad 5 and the sealed clearance between the lateral wall of standing groove 4 on backup pad 5, and sealed pad 17 is the rubber pad, and sealed pad 17 can reduce rainwater debris and enter into standing groove 4, can also reduce the striking of backup pad 5 and standing groove 4 lateral wall, and further play shock-resistant effect.

The implementation principle of the structure is built to antidetonation room of this application embodiment is: presetting the two supporting plates 5 in the placing groove 4, and connecting the two supporting plates 5; when the portable house needs to be built, the house body 3 can be built on the bottom plate 2 only by respectively inserting the two insertion plates 7 on the bottom plate 2 into the two insertion grooves 6, the assembly and disassembly are convenient and quick, so that the building efficiency of the portable house is improved, and a certain gap is formed between the bottom plate 2 and the base 1, so that the moisture on the ground is reduced from entering the portable house, and the portable house is convenient to use; the first damping springs 9 and the damping cushions 14 reduce the longitudinal vibration of the supporting plate 5, and the second damping springs 11 reduce the transverse vibration of the supporting plate 5, so as to improve the shock resistance of the house body 3 on the supporting plate 5.

The above embodiments are preferred embodiments of the present application, and the protection scope of the present application is not limited by the above embodiments, so: all equivalent changes made according to the structure, shape and principle of the present application shall be covered by the protection scope of the present application.

Claims (8)

1. The utility model provides a structure is built to antidetonation room which characterized in that: including base (1), bottom plate (2) and the room body (3), two standing grooves (4) have been seted up on base (1), two backup pad (5) have been preset on base (1), two backup pad (5) are arranged in two standing grooves (4) respectively, two inserting groove (6) have all been seted up on backup pad (5), be provided with two plugboard (7) on bottom plate (2), two plugboard (7) are pegged graft respectively in two inserting groove (6), the room body (3) are arranged in on bottom plate (2), be provided with the first shock attenuation piece that is used for reducing longitudinal vibration on backup pad (5), be provided with the second shock attenuation piece that is used for reducing transverse vibration on backup pad (5), be provided with the connecting piece that is used for joint support board (5) on base (1).

2. An earthquake-resistant building structure according to claim 1, wherein: the first damping piece comprises a longitudinal supporting block (8) arranged on the supporting plate (5), a first damping spring (9) is sleeved on the longitudinal supporting block (8), and the first damping spring (9) is located between the supporting plate (5) and the bottom wall of the placing groove (4).

3. An earthquake-resistant building structure according to claim 1, wherein: the second damping piece comprises a plurality of transverse supporting blocks (10) arranged on the supporting plate (5), the transverse supporting blocks (10) are symmetrically distributed on two sides of the supporting plate (5), a second damping spring (11) is sleeved on each transverse supporting block (10), and the second damping spring (11) is located between the supporting plate (5) and the side wall of the placing groove (4).

4. An earthquake-resistant building structure according to claim 1, wherein: the connecting piece is including articulating first telescopic link (12) on base (1), the one end of first telescopic link (12) articulates on base (1), and the other end articulates on backup pad (5), the both sides of backup pad (5) all are provided with first telescopic link (12).

5. An earthquake-resistant building structure according to claim 4, wherein: and a third damping spring (13) is sleeved on the first telescopic rod (12).

6. An earthquake-resistant building structure according to claim 1, wherein: the shock absorption device is characterized in that a shock absorption pad (14) is arranged on the supporting plate (5), and the shock absorption pad (14) is located between the supporting plate (5) and the bottom wall of the placing groove (4).

7. An earthquake-resistant building structure according to claim 1, wherein: the support plate (5) is provided with a second telescopic rod (15), one end of the second telescopic rod (15) is hinged to the bottom plate (2), the other end of the second telescopic rod is hinged to the support plate (5), and a fourth damping spring (16) is sleeved on the second telescopic rod (15).

8. An earthquake-resistant building structure according to claim 1, wherein: and a sealing gasket (17) for sealing a gap between the supporting plate (5) and the side wall of the placing groove (4) is arranged on the supporting plate (5).

Images