CN214144121U - Shock attenuation formula connection structure for building - Google Patents

Abstract

The utility model discloses a shock attenuation formula connection structure for building, including vertical I-steel and horizontal I-steel, one side fixed mounting of vertical I-steel has the mounting panel, and the inside movable mounting of mounting panel has the shock attenuation gag lever post, and damping spring has been cup jointed in the outside activity of shock attenuation gag lever post, and damping spring's one end fixed mounting has the promotion splint, and one side fixed mounting of horizontal I-steel has the fixed plate, and the mounting groove has been seted up to the inside of fixed plate, and the outside activity of horizontal I-steel has cup jointed the locator card, and the inside movable mounting of one end of locator card has the construction bolt. Through installing vertical I-steel and horizontal I-steel together, when vibrations produced, the damping spring through the installation makes and promotes the splint and to clip horizontal I-steel downwards to this can reduce the mutual vibrations between vertical I-steel and the horizontal I-steel, through the mounting groove can be convenient for the horizontal I-steel's of absorbing in-process upper and lower skew, greatly increased connection structure's vertical buffering shock resistance.

Description

Shock attenuation formula connection structure for building

Technical Field

The utility model belongs to the technical field of the building, concretely relates to shock attenuation formula connection structure for building.

Background

I-steel, also known as steel beam, is a long steel bar having an i-shaped cross section. The I-shaped steel includes hot rolled I-shaped steel and light I-shaped steel. The section steel is I-shaped in cross section, and the I-shaped steel is mainly divided into common I-shaped steel, light I-shaped steel and low-alloy light I-shaped steel.

The connection structure of present I-shaped steel for building is mostly fixed connection structure, does not possess shock-absorbing function, and the shock resistance is relatively poor, and the security performance is not enough, can't satisfy the needs that use.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide shock attenuation formula connection structure for building to propose the current connection structure of building I-steel in solving above-mentioned background art in the use, owing to do not possess shock-absorbing function, thereby the shock resistance is relatively poor, and the security performance is not enough, can't satisfy the problem of the needs of use.

In order to achieve the above object, the utility model provides a following technical scheme: shock attenuation formula connection structure for building, including vertical I-steel and horizontal I-steel, one side fixed mounting of vertical I-steel has the mounting panel, the inside movable mounting of mounting panel has the shock attenuation gag lever post, damping spring has been cup jointed in the outside activity of shock attenuation gag lever post, damping spring's one end fixed mounting has the promotion splint, one side fixed mounting of horizontal I-steel has the fixed plate, the mounting groove has been seted up to the inside of fixed plate, the outside activity of horizontal I-steel has cup jointed the locator card, the inside movable mounting of one end of locator card has the construction bolt, construction bolt's bottom fixed mounting has the Z template, the inside interactive installation of Z template has the promotion gag lever post, the outside activity that promotes the gag lever post has cup jointed the promotion spring, the top fixed mounting that promotes the gag lever post has movable shock pad down.

Preferably, the shock attenuation gag lever post has four, four the symmetry movable mounting of shock attenuation gag lever post is in the top and the bottom of mounting panel, damping spring is located the mounting panel and promotes between the splint, it has two to promote splint the position of splint is corresponding two.

Preferably, one side fixed mounting of mounting panel has fixing bolt, fixing bolt has four, four fixing bolt is rectangle fixed mounting in one side of mounting panel, fixing bolt's outside activity has cup jointed fixation nut.

Preferably, the number of the mounting grooves is four, the four mounting grooves are fixedly mounted in the fixing plate in a rectangular mode, and the fixing plate is movably sleeved outside the four fixing bolts through the four mounting grooves.

Preferably, the bottom fixed mounting of locator card inner wall has last shock pad, the top fixed mounting of locator card inner wall has fixed shock pad down, it all contacts with horizontal I-steel with one side that the locator card was kept away from to go up shock pad and fixed shock pad down.

Preferably, the number of the pushing limiting rods is two, the two pushing limiting rods are symmetrically and movably mounted inside the Z-shaped plate, and the pushing spring is located between the lower movable shock absorption pad and the Z-shaped plate.

Compared with the prior art, the beneficial effects of the utility model are that:

1. through installing vertical I-steel and horizontal I-steel together, when vibrations produced, the damping spring through the installation makes and promotes the splint and to clip horizontal I-steel downwards to this can reduce the mutual vibrations between vertical I-steel and the horizontal I-steel, through the mounting groove can be convenient for the horizontal I-steel's of absorbing in-process upper and lower skew, greatly increased connection structure's vertical buffering shock resistance.

2. Through last shock pad of installation and fixed shock pad down respectively with the upside and the right side contact of horizontal I-steel to this can carry out the shock attenuation to fixed contact connection structure, the staff installation locator card of can being convenient for through left side movable mounting's Z template, and the promotion spring of installation can promote down the effective and firm laminating of movable shock pad in the bottom of horizontal I-steel inner wall, in order to reduce the vibrations between locator card and the equipment, greatly increased the buffering shock resistance when the equipment uses.

Drawings

Fig. 1 is a schematic view of the overall three-dimensional structure of the present invention;

FIG. 2 is a schematic view of the three-dimensional structure of the vertical I-steel of the present invention;

FIG. 3 is a schematic view of the three-dimensional structure of the transverse I-shaped steel of the present invention;

fig. 4 is a schematic view of the three-dimensional structure of the locator card of the present invention.

In the figure: 1. vertical I-steel; 2. mounting a plate; 3. a shock-absorbing limit rod; 4. a damping spring; 5. pushing the clamping plate; 6. fixing the bolt; 7. fixing a nut; 8. transverse I-shaped steel; 9. a fixing plate; 10. mounting grooves; 11. positioning the card; 12. an upper shock pad; 13. a lower fixed shock pad; 14. installing a bolt; 15. a Z-shaped plate; 16. pushing the limiting rod; 17. a push spring; 18. and a lower movable shock pad.

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. 1-4, the present invention provides a technical solution: shock attenuation formula connection structure for building, including vertical I-steel 1 and horizontal I-steel 8, one side fixed mounting of vertical I-steel 1 has mounting panel 2, the inside movable mounting of mounting panel 2 has shock attenuation gag lever post 3, damping spring 4 has been cup jointed in the outside activity of shock attenuation gag lever post 3, damping spring 4's one end fixed mounting has promotion splint 5, one side fixed mounting of horizontal I-steel 8 has fixed plate 9, mounting groove 10 has been seted up to the inside of fixed plate 9, the outside activity of horizontal I-steel 8 has cup jointed locator card 11, the inside movable mounting of one end of locator card 11 has mounting bolt 14, the bottom fixed mounting of mounting bolt 14 has Z template 15, the inside interactive mounting of Z template 15 has promotion gag lever post 16, the outside activity that promotes gag lever post 16 has cup jointed promotion spring 17, the top fixed mounting that promotes gag lever post 16 has movable shock pad 18 down.

In the scheme of the embodiment, the vertical I-steel 1 and the transverse I-steel 8 are installed together, when vibration is generated, the transverse I-steel 8 is clamped downwards by the pushing clamp plate 5 through the installed damping spring 4, so that the mutual vibration between the vertical I-steel 1 and the transverse I-steel 8 can be reduced, the vertical buffering and anti-seismic capacity of the connecting structure can be greatly increased by facilitating the vertical offset of the transverse I-steel 8 in the damping process through the installation groove 10, the fixed contact connecting structure can be damped by respectively contacting the upper side and the right side of the transverse I-steel 8 through the installed upper damping pad 12 and the lower fixed damping pad 13, the positioning card 11 can be conveniently installed by a worker through the Z-shaped plate 15 movably installed on the left side, and the installed pushing spring 17 can push the lower movable damping pad 18 to be effectively and stably attached to the bottom of the inner wall of the transverse I-steel 8, so as to reduce the vibration between the positioning card 11 and the equipment and greatly increase the buffering and shock-resistant capacity of the equipment during use.

Specifically, there are four shock attenuation gag lever post 3, and four shock attenuation gag lever post 3 symmetry movable mounting are in the top and the bottom of mounting panel 2, and damping spring 4 is located mounting panel 2 and promotes between the splint 5, and it has two to promote splint 5, and two positions that promote splint 5 are corresponding.

In the embodiment, the four damping limiting rods 3 are symmetrically and movably arranged at the top and the bottom of the mounting plate 2, and the damping springs 4 are arranged between the mounting plate 2 and the pushing clamping plate 5, so that the upper part and the lower part of the transverse I-shaped steel 8 can be buffered and damped.

Specifically, one side fixed mounting of mounting panel 2 has fixing bolt 6, and fixing bolt 6 has four, and four fixing bolt 6 are rectangle fixed mounting in one side of mounting panel 2, and fixing nut 7 has been cup jointed in fixing bolt 6's outside activity.

In this embodiment, four fixing bolts 6 are fixedly installed on one side of the mounting plate 2 in a rectangular shape, and fixing nuts 7 are movably sleeved outside the fixing bolts 6, so that the vertical i-shaped steel 1 and the transverse i-shaped steel 8 can be conveniently installed.

Specifically, there are four mounting grooves 10, and four mounting grooves 10 are rectangle fixed mounting in the inside of fixed plate 9, and fixed plate 9 cup joints the outside at four fixing bolt 6 through four mounting groove 10 activities.

In this embodiment, the fixing plate 9 is movably sleeved outside the four fixing bolts 6 through the four mounting grooves 10, so that the vertical i-beam 1 and the horizontal i-beam 8 can be conveniently mounted.

Specifically, the bottom of the inner wall of the positioning clamp 11 is fixedly provided with an upper shock pad 12, the top of the inner wall of the positioning clamp 11 is fixedly provided with a lower fixed shock pad 13, and one sides of the upper shock pad 12 and the lower fixed shock pad 13, which are far away from the positioning clamp 11, are both contacted with the transverse I-shaped steel 8.

In this embodiment, the side of the upper shock pad 12 and the side of the lower fixed shock pad 13 far away from the positioning clip 11 are both in contact with the transverse i-beam 8, so that convenience can be brought to the contact connection structure for fixing shock absorption.

Specifically, there are two pushing limiting rods 16, the two pushing limiting rods 16 are symmetrically and movably mounted inside the Z-shaped plate 15, and the pushing spring 17 is located between the lower movable shock absorption pad 18 and the Z-shaped plate 15.

In the embodiment, the two pushing limiting rods 16 are symmetrically and movably arranged inside the Z-shaped plate 15, and the pushing spring 17 is positioned between the lower movable shock absorption pad 18 and the Z-shaped plate 15, so that the shock between the positioning card 11 and the equipment is reduced, and the buffering shock resistance of the equipment during use is greatly increased.

The utility model discloses a theory of operation and use flow: the device is moved to a designated place, the vertical I-beam 1 and the transverse I-beam 8 are installed together through the fixing nut 7 and the fixing bolt 6, when vibration is generated, the transverse I-beam 8 is clamped downwards through the push clamping plate 5 through the installed damping spring 4, so that the mutual vibration between the vertical I-beam 1 and the transverse I-beam 8 can be reduced, the vertical buffer and shock resistance of the connecting structure can be greatly improved by facilitating the vertical offset of the transverse I-beam 8 in the shock absorption process through the installation groove 10, the upper damping pad 12 and the lower fixed damping pad 13 are respectively contacted with the upper side and the right side of the transverse I-beam 8, so that the fixed contact connecting structure can be damped, a positioning card 11 can be conveniently installed by a worker through the Z-shaped plate 15 movably installed on the left side, and the installed push spring 17 can push the lower movable damping pad 18 to be effectively and stably attached to the bottom of the inner wall of the transverse I-beam 8, so as to reduce the vibration between the positioning card 11 and the equipment and greatly increase the buffering and shock-resistant capacity of the equipment during use.

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 (6)

1. Shock attenuation formula connection structure for building, including vertical I-steel (1) and horizontal I-steel (8), its characterized in that: the shock absorption and protection device is characterized in that a mounting plate (2) is fixedly mounted on one side of a vertical I-shaped steel (1), a shock absorption limiting rod (3) is movably mounted inside the mounting plate (2), a shock absorption spring (4) is sleeved outside the shock absorption limiting rod (3), a pushing clamping plate (5) is fixedly mounted at one end of the shock absorption spring (4), a fixing plate (9) is fixedly mounted on one side of a transverse I-shaped steel (8), a mounting groove (10) is formed inside the fixing plate (9), a positioning card (11) is sleeved outside the transverse I-shaped steel (8), a mounting bolt (14) is movably mounted inside one end of the positioning card (11), a Z-shaped plate (15) is fixedly mounted at the bottom of the mounting bolt (14), a pushing limiting rod (16) is installed in an interactive mode inside the Z-shaped plate (15), and a pushing spring (17) is sleeved outside the pushing limiting rod (16), the top of the pushing limiting rod (16) is fixedly provided with a lower movable shock pad (18).

2. The shock-absorbing type connecting structure for buildings according to claim 1, wherein: shock attenuation gag lever post (3) have four, four shock attenuation gag lever post (3) symmetry movable mounting is in the top and the bottom of mounting panel (2), damping spring (4) are located mounting panel (2) and promote between splint (5), it has two, two to promote splint (5) the position that promotes splint (5) is corresponding.

3. The shock-absorbing type connecting structure for buildings according to claim 1, wherein: one side fixed mounting of mounting panel (2) has fixing bolt (6), fixing bolt (6) have four, four fixing bolt (6) are rectangle fixed mounting in one side of mounting panel (2), fixation nut (7) have been cup jointed in the outside activity of fixing bolt (6).

4. The shock-absorbing type connecting structure for buildings according to claim 3, wherein: the mounting grooves (10) are four, the mounting grooves (10) are fixedly mounted in the fixing plate (9) in a rectangular mode, and the fixing plate (9) is movably sleeved outside the four fixing bolts (6) through the four mounting grooves (10).

5. The shock-absorbing type connecting structure for buildings according to claim 1, wherein: the bottom fixed mounting of locator card (11) inner wall has last shock pad (12), the top fixed mounting of locator card (11) inner wall has down fixed shock pad (13), it all contacts with horizontal I-steel (8) to go up one side that locator card (11) was kept away from in shock pad (12) and lower fixed shock pad (13).

6. The shock-absorbing type connecting structure for buildings according to claim 1, wherein: the two pushing limiting rods (16) are symmetrically movably mounted inside the Z-shaped plate (15) through the two pushing limiting rods (16), and the pushing spring (17) is located between the lower movable shock absorption pad (18) and the Z-shaped plate (15).

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