CN220790723U - Multifunctional steel structure support for constructional engineering - Google Patents

Abstract

The utility model provides a multifunctional steel structure support for construction engineering, which comprises a movable plate, a double-shaft motor, a screw rod, a sliding seat, an electric push rod, an arc plate and a supporting mechanism, wherein the supporting mechanism comprises a lifting rod, a supporting plate and a clamping mechanism, the position of the supporting plate is regulated according to the splicing or welding positions of the steel structure after the movable plate is arranged below the steel structure to be supported, the screw rod is driven to rotate by the double-shaft motor, the sliding seat converts the rotation motion of the screw rod into the self linear motion, so that the lifting rod is driven to perform horizontal motion, finally, the supporting plate can be moved below the splicing position of the steel structure, and then the lifting rod is lifted, so that the supporting plate is abutted to the lower part of the steel structure and clamped and fixed by the clamping mechanism, the steel structure support for different sizes and different splicing requirements can be applied, the construction efficiency is improved, the construction cost is reduced, and the problem of safety quality of a subsequently constructed building is avoided.

Description

Multifunctional steel structure support for constructional engineering

Technical Field

The utility model relates to the technical field of constructional engineering, in particular to a multifunctional steel structure support for constructional engineering.

Background

With the continuous improvement of people's living standard, people are also increasing to the demand of mental recreation, various sports events, concert and the place such as phone drafts are also increasing, consequently, the construction demand to the venue is also increasing constantly, because of steel construction transportation convenience, with low costs, structural strength is great and construction period characteristics such as shorter, in present venue construction, most use steel construction to build, and for transportation convenience and reduction of erection time, steel construction generally falls into the structure of multistage formula and produces and process in the mill, after the production is accomplished, splice in unifying to construction place, in the venue structure, part is located in the structure of sky, for example floor, back timber, steel truss etc. after splice or welding is accomplished, all need external bearing structure, avoid dropping, and at present in venue construction, most bearing structure is temporarily built, can't guarantee to support steel structure't, on the one hand, the other is that the manufacturing process is comparatively loaded down with trivial details, often seek some material combinations of putting up in the construction place to be used for the transportation convenience and reduction of construction period, if the size is not required to be the waste of some bearing structure, when splice point is required, the size is required to be adjusted at will, in addition, the cost is great, the cost is required to be adjusted at the same time or the time is required to be more than the welding point is required, the splice point is required, can's waste, can't be carried out at the time is needed, in the construction point is required to be adjusted at the time, and the cost is required to be adjusted, and is required to be convenient to be easily to be used.

Disclosure of Invention

In view of the above, the utility model provides a multifunctional steel structure support for construction engineering, which can adjust the position of a support plate so as to be suitable for a plurality of splicing positions of different steel structures.

The technical scheme of the utility model is realized as follows:

the utility model provides a multi-functional steel structure support of building engineering, includes movable plate, biax motor, lead screw, sliding seat, electric putter, arc and supporting mechanism, biax motor sets up in the movable plate top surface, and its output shaft is connected with the lead screw, be provided with the through-hole on the sliding seat, electric putter sets up in the through-hole, and its output shaft is connected with the arc convex surface, the arc concave surface is provided with the internal thread, the lead screw passes between the arc, sliding seat bottom surface and movable plate top surface sliding connection; the supporting mechanism comprises a lifting rod, a supporting plate and a clamping mechanism, wherein the lifting rod is arranged on the top surface of the sliding seat, the supporting plate is arranged on the top surface of the lifting rod, and the clamping mechanism is arranged on the supporting plate and used for clamping the steel structure.

Preferably, the device further comprises a fixing plate and bearings, wherein the fixing plate is arranged on two sides of the top surface of the moving plate, the bearings are arranged on the side wall, facing the double-shaft motor, of the fixing plate, and the end part, far away from the double-shaft motor, of the screw rod is connected with the bearings.

Preferably, the top surface of the moving plate is provided with a lower groove, and the bottom surface of the sliding seat is embedded into the lower groove.

Preferably, the automatic hydraulic control device further comprises a moving mechanism, wherein the moving mechanism comprises a first hydraulic rod, a support and a moving wheel, the bottom surface of the moving plate is provided with a containing groove, the support is located in the containing groove, the moving wheel is installed on the support, the first hydraulic rod is arranged on the top surface of the containing groove, and an output shaft of the first hydraulic rod is connected with the top surface of the support.

Preferably, the clamping mechanism comprises a clamping plate, a clamping spring and a side plate, wherein the side plate is oppositely arranged on the top surface of the supporting plate, the clamping plate is oppositely arranged between the side plates, the clamping spring is connected with the clamping plate and the side plates, and a clamping position is formed between the clamping plates.

Preferably, the clamping mechanism further comprises rubber shims disposed on opposite side walls of the clamping plate.

Preferably, the lifting rod comprises a sleeve, a moving rod and a second hydraulic rod, the sleeve is arranged on the top surface of the sliding seat, the second hydraulic rod is arranged inside the sleeve, the bottom end of the moving rod stretches into the sleeve to be connected with the output shaft of the second hydraulic rod, and the top end of the moving rod is connected with the bottom surface of the supporting plate.

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

(1) the supporting plate can be lifted through the lifting rod, after the supporting plate is contacted with the bottom surface of the steel structure, the steel structure is clamped through the clamping mechanism, so that the steel structure splicing point is stably supported;

(2) the output shaft of the double-shaft motor is provided with the screw rod, the screw rod penetrates through the sliding seat, when the arc plate is in threaded connection with the screw rod, the rotary motion of the screw rod can be converted into linear motion of the sliding seat, and accordingly the lifting rod is driven to move, the supporting plate is enabled to move to the splicing position of the steel structure, adjustment can be carried out according to different splicing positions of the steel structure, and the supporting effect is guaranteed.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present utility model, the drawings required for the description of the embodiments will be briefly described below, it being obvious that the drawings in the following description are only preferred embodiments of the present utility model, and that other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

FIG. 1 is a schematic structural view of a multi-functional steel structural support for construction work according to the present utility model;

FIG. 2 is a schematic structural view of a support mechanism for a multi-functional steel structural support for construction work according to the present utility model;

FIG. 3 is a schematic structural view of a sliding seat of a multifunctional steel structural support for construction engineering according to the present utility model;

in the figure, 1 is a movable plate, 2 is a double-shaft motor, 3 is a screw rod, 4 is a sliding seat, 5 is an electric push rod, 6 is an arc-shaped plate, 7 is a through hole, 8 is a lifting rod, 9 is a supporting plate, 10 is a fixed plate, 11 is a bearing, 12 is a lower groove, 13 is a first hydraulic rod, 14 is a bracket, 15 is a driving wheel, 16 is a containing groove, 17 is a clamping plate, 18 is a clamping spring, 19 is a side plate, 20 is a clamping position, 21 is a rubber gasket, 22 is a sleeve, 23 is a movable rod, and 24 is a second hydraulic rod.

Detailed Description

For a better understanding of the technical content of the present utility model, a specific example is provided below, and the present utility model is further described with reference to the accompanying drawings.

Referring to fig. 1 to 3, the multifunctional steel structure support for construction engineering provided by the utility model comprises a moving plate 1, a double-shaft motor 2, a screw rod 3, a sliding seat 4, an electric push rod 5, an arc plate 6 and a supporting mechanism, wherein the double-shaft motor 2 is arranged on the top surface of the moving plate 1, an output shaft of the double-shaft motor is connected with the screw rod 3, a through hole 7 is arranged on the sliding seat 4, the electric push rod 5 is arranged in the through hole 7, an output shaft of the electric push rod 5 is connected with the convex surface of the arc plate 6, an internal thread (not shown in the figure) is arranged on the concave surface of the arc plate 6, the screw rod 3 penetrates between the arc plates 6, and the bottom surface of the sliding seat 4 is in sliding connection with the top surface of the moving plate 1; the supporting mechanism comprises a lifting rod 8, a supporting plate 9 and a clamping mechanism, wherein the lifting rod 8 is arranged on the top surface of the sliding seat 4, the supporting plate 9 is arranged on the top surface of the lifting rod 8, and the clamping mechanism is arranged on the supporting plate 9 and used for clamping a steel structure.

The utility model relates to a multifunctional steel structure support for construction engineering, which can be suitable for supporting steel structures with various heights and splicing requirements, wherein a double-shaft motor 2 is arranged on the top surface of a movable plate 1, output shafts at two ends of the double-shaft motor 2 are connected with a screw rod 3, the screw rod 3 penetrates through a sliding seat 4, when an electric push rod 5 pushes an arc-shaped plate 6 to be in threaded connection with the screw rod 3, the rotary motion of the screw rod 3 can be converted into linear motion of the sliding seat 4, the sliding seat 4 moves along the top surface of the movable plate 1, the sliding seats 4 are arranged into a plurality of groups, lifting rods 8 are arranged on the top surface of each sliding seat 4, the top ends of the lifting rods 8 are connected with a supporting plate 9, the lifting rods 8 can adjust the height of the supporting plate 9, so that the supporting plate 9 rises to the lower part of the steel structure to be supported, and finally, the steel structure can be firmly supported through clamping mechanisms, and meanwhile, the supporting plate 9 can be moved to different steel structure splicing positions to be firmly supported due to the fact that the positions of the sliding seat 4 can be adjusted.

In addition, because the electric push rod 5 is arranged in the through hole 7 of the sliding seat 4, the electric push rod 5 can drive the arc plate 6 to move, and when the arc plate 6 leaves the screw rod 3, the rotary motion of the screw rod 3 cannot be converted into the linear motion of the sliding seat 4, so that the sliding seat 4 can be static on the moving plate 1, and the simultaneous adjustment of the positions of the single or multiple sliding seats 4 is realized.

Preferably, the device further comprises a fixing plate 10 and bearings 11, wherein the fixing plate 10 is arranged on two sides of the top surface of the moving plate 1, the bearings 11 are arranged on the side wall, facing the double-shaft motor 2, of the fixing plate 10, and the end, far away from the double-shaft motor 2, of the screw rod 3 is connected with the bearings 11.

When the double-shaft motor 2 drives the screw rod 3 to rotate, the end part of the screw rod 3 can stably rotate under the supporting action of the bearing 11.

Preferably, the top surface of the moving plate 1 is provided with a lower groove 12, and the bottom surface of the sliding seat 4 is embedded in the lower groove 12.

In order to avoid the rotation of the screw rod 3 to drive the sliding seat 4 to rotate, a lower groove 12 is formed in the top surface of the moving plate 1, the lower groove 12 can limit the sliding seat 4, and meanwhile, the sliding seat 4 can be prevented from moving to deviate.

Preferably, the device further comprises a moving mechanism, the moving mechanism comprises a first hydraulic rod 13, a support 14 and a driving wheel 15, the bottom surface of the moving plate 1 is provided with a containing groove 16, the support 14 is located in the containing groove 16, the driving wheel 15 is installed on the support 14, the first hydraulic rod 13 is arranged on the top surface of the containing groove 16, and an output shaft of the first hydraulic rod is connected with the top surface of the support 14.

In order to apply the utility model to different venues, the moving plate 1 is provided with the moving wheel 15 on the bottom surface thereof, the moving plate 1 can be driven to move by the moving wheel 15, and when the moving plate 1 moves to a designated place, the first hydraulic rod 13 can drive the output shaft thereof to shrink, under the action of gravity, the moving plate 1 wholly descends, finally the bracket 14 and the moving wheel 15 are completely accommodated in the accommodating groove 16, the bottom surface of the moving plate 1 can be contacted with the ground, and the movement of the supporting plate 9 when supporting the steel structure is avoided.

Preferably, the clamping mechanism comprises a clamping plate 17, a clamping spring 18 and a side plate 19, wherein the side plate 19 is oppositely arranged on the top surface of the supporting plate 9, the clamping plate 17 is oppositely arranged between the side plates 19, the clamping spring 18 is connected with the clamping plate 17 and the side plate 19, a clamping position 20 is formed between the clamping plates 17, the clamping mechanism further comprises a rubber gasket 21, and the rubber gasket 21 is arranged on the opposite side walls of the clamping plate 17.

After pulling the clamping plate 17 to the outside, the clamping position 20 is increased, then the steel structure is positioned in the clamping position 20, then the clamping plate 17 is slowly loosened, under the action of the clamping spring 18, the clamping plate 17 can move towards the middle, finally the clamping plate 17 can clamp and fix the steel structure, the steel structure can be supported through the clamping plate 17 and the supporting plate 9, and the rubber gasket 21 can prevent the clamping plate 17 from damaging the outer wall of the steel structure.

Preferably, the lifting rod 8 comprises a sleeve 22, a moving rod 23 and a second hydraulic rod 24, the sleeve 22 is arranged on the top surface of the sliding seat 4, the second hydraulic rod 24 is arranged inside the sleeve 22, the bottom end of the moving rod 23 stretches into the sleeve 22 to be connected with the output shaft of the second hydraulic rod 24, and the top end of the moving rod is connected with the bottom surface of the supporting plate 9.

In order to be suitable for supporting steel structures with different heights, the lifting rod 8 can be adjusted in height, and the second hydraulic rod 24 can drive the moving rod 23 to move along the sleeve 22, so that the part of the lifting rod 8 positioned outside the sleeve 22 is changed in length, and the height of the supporting plate 9 is adjusted.

The foregoing description of the preferred embodiments of the utility model is not intended to be limiting, but rather is intended to cover all modifications, equivalents, alternatives, and improvements that fall within the spirit and scope of the utility model.

Claims (7)

1. The utility model provides a multi-functional steel structure support of building engineering, its characterized in that includes movable plate, biax motor, lead screw, sliding seat, electric putter, arc and supporting mechanism, biax motor sets up in the movable plate top surface, and its output shaft is connected with the lead screw, be provided with the through-hole on the sliding seat, electric putter sets up in the through-hole, and its output shaft is connected with the arc convex surface, the arc concave surface is provided with the internal thread, the lead screw passes between the arc, sliding seat bottom surface and movable plate top surface sliding connection; the supporting mechanism comprises a lifting rod, a supporting plate and a clamping mechanism, wherein the lifting rod is arranged on the top surface of the sliding seat, the supporting plate is arranged on the top surface of the lifting rod, and the clamping mechanism is arranged on the supporting plate and used for clamping the steel structure.

2. The multifunctional steel structural support for construction engineering according to claim 1, further comprising a fixing plate and bearings, wherein the fixing plate is arranged on two sides of the top surface of the moving plate, the bearings are arranged on the side wall, facing the double-shaft motor, of the fixing plate, and the end portion, far away from the double-shaft motor, of the screw rod is connected with the bearings.

3. The multi-functional steel structural support for construction engineering according to claim 1, wherein the top surface of the moving plate is provided with a lower groove, and the bottom surface of the sliding seat is embedded in the lower groove.

4. The multifunctional steel structural support for construction engineering according to claim 1, further comprising a moving mechanism, wherein the moving mechanism comprises a first hydraulic rod, a support and a driving wheel, the bottom surface of the moving plate is provided with a containing groove, the support is located in the containing groove, the driving wheel is installed on the support, the first hydraulic rod is arranged on the top surface of the containing groove, and an output shaft of the first hydraulic rod is connected with the top surface of the support.

5. The multi-functional steel structural support of claim 1, wherein the clamping mechanism comprises clamping plates, clamping springs and side plates, the side plates are oppositely arranged on the top surface of the support plate, the clamping plates are oppositely arranged between the side plates, the clamping springs are connected with the clamping plates and the side plates, and clamping positions are formed between the clamping plates.

6. The structural support of claim 5, wherein the clamping mechanism further comprises rubber shims disposed on opposite side walls of the clamping plate.

7. The multifunctional steel structural support for constructional engineering according to claim 1, wherein the lifting rod comprises a sleeve, a moving rod and a second hydraulic rod, the sleeve is arranged on the top surface of the sliding seat, the second hydraulic rod is arranged inside the sleeve, the bottom end of the moving rod extends into the sleeve to be connected with an output shaft of the second hydraulic rod, and the top end of the moving rod is connected with the bottom surface of the supporting plate.