CN223573450U - Telescopic adjustable steel structure beam making pedestal - Google Patents

Abstract

The utility model relates to the technical field of novel products for processing and mounting, in particular to a telescopic adjusting type steel structure beam manufacturing pedestal, which comprises a concrete layer, wherein a fixed plate is fixedly arranged on the concrete layer, limit grooves are symmetrically arranged on the concrete layer, an adjusting plate is arranged in the limit grooves in a sliding manner, a first lifting plate is arranged in the adjusting plate in a sliding manner, a second lifting plate is arranged in the fixed plate in a sliding manner through a height adjusting mechanism, and a horizontal adjusting mechanism for driving the adjusting plate to move is arranged on the concrete layer. According to the utility model, the horizontal adjusting mechanism and the height adjusting mechanism are arranged, the jack can be used for adjusting the basic distance in the horizontal direction, and the motor is started to adjust the distance in the vertical direction, so that the beam manufacturing pedestal can be rapidly adapted to the beam production requirements of different sizes and specifications, the time for replacing the pedestal or adjusting equipment is reduced, and the production efficiency is improved.

Description

Telescopic adjustable steel structure beam making pedestal

Technical Field

The utility model relates to the technical field of novel products for processing and mounting, in particular to a telescopic adjusting beam-making pedestal of a steel structure.

Background

The steel structure beam making pedestal is specially designed beam making equipment, has wide application in building, bridge and other engineering fields, and is beam making equipment with steel structure as main bearing member for supporting and fixing beam body to perform concrete pouring, maintaining and other steps.

The standard steel structure beam making pedestal is suitable for concrete beams with the width of 33.6 meters and 24.6 meters and the bottom face beam, but cannot adjust the width of a foundation, so that the working efficiency is inconvenient to improve, when the foundation spacing needs to be adjusted, workers are inconvenient to operate during working, in different construction sites, the topography may have differences, and the existing equipment cannot adjust the height of the standard steel structure beam making pedestal, so that the beam making pedestal can adapt to different construction conditions and requirements, and the construction difficulty is improved.

Based on this, now provide scalable regulation shaped steel structure system roof beam pedestal, can eliminate the drawback that current device exists.

Disclosure of utility model

To above-mentioned problem, provide scalable regulation shaped steel structure system roof beam pedestal, solved through horizontal adjustment mechanism and can not carry out basic regulation and high regulation and lead to the inconvenient problem of construction.

In order to solve the problems in the prior art, the utility model provides a telescopic adjusting beam-making pedestal of a steel structure, which comprises a concrete layer, wherein a fixed plate is fixedly arranged on the concrete layer, limit grooves are symmetrically arranged on the concrete layer, an adjusting plate is slidably arranged in the limit grooves, a first lifting plate is slidably arranged in the adjusting plate, a second lifting plate is slidably arranged in the fixed plate through a height adjusting mechanism, and a horizontal adjusting mechanism for driving the adjusting plate to move is arranged on the concrete layer.

Preferably, the horizontal adjusting mechanism comprises a base, a mounting frame, a jack and a connecting shaft, wherein the base is symmetrically arranged on the concrete layer, the mounting frame is arranged on the base, the jack is arranged in the mounting frame, the output end of the jack penetrates through the side wall of the mounting frame to be connected with the connecting shaft, the other end of the connecting shaft is connected with the adjusting plate, and the mounting frame is provided with an auxiliary mechanism.

Preferably, the height adjusting mechanism comprises a mounting column, a mounting block, a mounting plate, a motor, a screw rod, an adjusting block, a fixing block, a connecting plate, a limiting sleeve, a connecting block and a limiting rod, wherein the mounting column is mounted on a base, the mounting block is fixedly mounted on the side wall of the mounting column, the mounting plate is fixedly mounted on the top wall of the mounting block, the motor is mounted on the mounting plate, the motor output end penetrates through the side wall of the mounting plate to be connected with the screw rod, the other end of the screw rod is in running fit with the bottom wall of the concrete layer, the adjusting block is slidably arranged on the screw rod, threads matched with the screw rod are arranged in the adjusting block, the connecting plate is fixedly mounted on the side wall of the adjusting block, the other end of the connecting plate is slidably arranged in the limiting sleeve, the other end of the limiting sleeve is mounted on the side wall of the connecting block, the connecting block is fixedly mounted on the side wall of the first lifting plate, the fixing block is fixedly mounted on the side wall of the mounting plate, the limiting rod is arranged on the fixing block, the other end of the limiting rod penetrates through the side wall of the connecting plate to be connected with the bottom wall of the concrete layer, and the other end of the adjusting block is connected with the top wall of the second lifting plate.

Preferably, the auxiliary mechanism comprises a bearing plate and lifting lugs, wherein the lifting lugs are arranged on the bearing plate, and the bearing plate is detachably arranged on the side wall of the mounting frame.

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

According to the utility model, the horizontal adjusting mechanism and the height adjusting mechanism are arranged, the jack can be used for adjusting the basic distance in the horizontal direction, and the motor is started to adjust the distance in the vertical direction, so that the beam manufacturing pedestal can be rapidly adapted to the beam production requirements of different sizes and specifications, the time for replacing the pedestal or adjusting equipment is reduced, and the production efficiency is improved.

Drawings

Fig. 1 is a schematic perspective view of a telescopic adjustable steel structure beam making pedestal.

Fig. 2 is a partially enlarged perspective view of the telescopic adjustable steel structure beam-making stand of fig. 1 a.

Fig. 3 is a schematic diagram of jack installation of a telescopically adjustable steel structure beam making pedestal.

The concrete layer is marked by 101, a concrete layer, 102, a fixing plate, 103, an adjusting plate, 104, a first lifting plate, 105, a limiting groove, 106, a second lifting plate, 200, a height adjusting mechanism, 201, a mounting column, 202, a mounting block, 203, a mounting plate, 204, a motor, 205, a screw rod, 206, an adjusting block, 207, a fixing block, 208, a connecting plate, 209, a limiting sleeve, 210, a connecting block, 211, a limiting rod, 300, a horizontal adjusting mechanism, 301, a base, 302, a mounting frame, 303, a jack, 304, a connecting shaft, 400, an auxiliary mechanism, 401, a receiving plate, 402 and a lifting lug.

Detailed Description

The utility model will be further described in detail with reference to the drawings and the detailed description below, in order to further understand the features and technical means of the utility model and the specific objects and functions achieved.

Referring to fig. 1-3, the telescopic adjusting type steel structure beam making pedestal comprises a concrete layer 101, wherein a fixed plate 102 is fixedly arranged on the concrete layer 101, limit grooves 105 are symmetrically arranged on the concrete layer 101, an adjusting plate 103 is slidably arranged in the limit grooves 105, a first lifting plate 104 is slidably arranged in the adjusting plate 103, a second lifting plate 106 is slidably arranged in the fixed plate 102 through a height adjusting mechanism 200, and a horizontal adjusting mechanism 300 for driving the adjusting plate 103 to move is arranged on the concrete layer 101.

The horizontal adjustment mechanism 300 can adjust the interval between the horizontal directions, can adjust the interval of the vertical direction through the height adjustment mechanism 200, is convenient for the workman to operate for the beam body production demand of different sizes and specifications can be adapted to rapidly to the beam body pedestal, has reduced the time of changing pedestal or adjusting equipment, thereby has improved production efficiency.

Referring to fig. 2-3, the horizontal adjusting mechanism 300 comprises a base 301, a mounting frame 302, a jack 303 and a connecting shaft 304, wherein the base 301 is symmetrically mounted on the concrete layer 101, the mounting frame 302 is mounted on the base 301, the jack 303 is mounted in the mounting frame 302, the output end of the jack 303 penetrates through the side wall of the mounting frame 302 to be connected with the connecting shaft 304, the other end of the connecting shaft 304 is connected with the adjusting plate 103, and the auxiliary mechanism 400 is mounted on the mounting frame 302.

The jack 303 is started to drive the connecting shaft 304 to move, the connecting shaft 304 pushes the adjusting plates 103 at the two sides to move according to the required distance, and the mounting frame 302 is used for mounting the jack 303.

Referring to fig. 1-2, the height adjusting mechanism 200 comprises a mounting column 201, a mounting block 202, a mounting plate 203, a motor 204, a screw rod 205, an adjusting block 206, a fixing block 207, a connecting plate 208, a limiting sleeve 209, a connecting block 210 and a limiting rod 211, wherein the mounting column 201 is mounted on the base 301, the mounting block 202 is fixedly mounted on the side wall of the mounting column 201, the mounting plate 203 is fixedly mounted on the top wall of the mounting block 202, the motor 204 is mounted on the mounting plate 203, the output end of the motor 204 penetrates through the side wall of the mounting plate 203 to be connected with the screw rod 205, the other end of the screw rod 205 is in running fit with the bottom wall of the concrete layer 101, the screw rod 205 is slidably provided with an adjusting block 206, threads matched with the screw rod 205 are arranged in the adjusting block 206, a connecting plate 208 is fixedly mounted on the side wall of the adjusting block 206, the other end of the connecting plate 208 is slidably arranged in the limiting sleeve 209, the other end of the limiting sleeve 209 is mounted on the side wall of the connecting block 210, the connecting block 210 is symmetrically and fixedly mounted on the side wall of the first lifting plate 104, the other end of the mounting plate 203 is provided with the fixing block 207, the limiting rod 207 is rotatably mounted on the side wall, the other end of the connecting plate 207 is provided with the limiting rod 208, and the other end of the connecting rod 211 penetrates through the bottom wall 211 to be connected with the second bottom wall 106.

When the screw rod 205 rotates, the adjusting block 206 is matched with the screw rod 205, the adjusting block 206 can reciprocate up and down on the screw rod 205, the adjusting block 206 can drive the connecting plate 208 and the limiting sleeve 209 to reciprocate up and down, the limiting sleeve 209 drives the connecting block 210 to reciprocate up and down, the connecting block 210 drives the first lifting plate 104 to slide on the adjusting plate 103, so that the adjustment of the omnibearing height is realized, when the jack 303 drives the connecting shaft 304 to push the adjusting plate 103, the adjusting plate 103 drives the first lifting plate 104 to synchronously move, the first lifting plate 104 drives the connecting block 210 to synchronously move, and the connecting block 210 drives the limiting sleeve 209 to synchronously move in one end of the connecting plate 208.

Referring to fig. 1-2, the auxiliary mechanism 400 comprises a receiving plate 401 and a lifting lug 402, wherein the lifting lug 402 is mounted on the receiving plate 401, and the receiving plate 401 is detachably mounted on the side wall of the mounting frame 302.

The bearing plate 401 is used for installing the lifting lug 402 on the mounting frame 302, and the lifting lug 402 is used for matching and ensuring the safety and stability of the precast beam in the lifting and carrying processes, and the precast beam can be conveniently lifted from the beam making pedestal by using lifting equipment through the lifting lug 402 and safely moved to a designated position, which is the prior art and is not repeated here.

The lifting device comprises a jack 303, a motor 204, a screw rod 205, a connecting plate 208, a limiting sleeve 209, a connecting block 210, a first lifting plate 104, a connecting block 210, a limiting sleeve 209 and a beam manufacturing pedestal, wherein the jack 303 is started to drive the connecting shaft 304 to drive the connecting plate 304 to move, the connecting shaft 304 drives the adjusting plates 103 on two sides to move according to required basic intervals, the motor 204 is started to drive the screw rod 205 to rotate, when the screw rod 205 rotates, the adjusting block 206 is matched with the screw rod 205, the adjusting block 206 can reciprocate up and down on the screw rod 205, the connecting plate 208 and the limiting sleeve 209 can be driven to reciprocate up and down by the adjusting block 206, the connecting block 210 is driven by the limiting sleeve 209 to reciprocate up and down, the connecting block 210 is driven by the connecting block 210 to slide on the adjusting plate 103, so that the omnibearing height is adjusted, when the jack 303 drives the connecting shaft 304 to drive the adjusting plate 103 to push the adjusting plate 103, the adjusting plate 103 is driven by the first lifting plate 104 to synchronously move, the connecting block 210 is driven by the connecting block 210 to synchronously move, and the limiting sleeve 209 moves in one end of the connecting plate 208.

The foregoing examples merely illustrate one or more embodiments of the utility model, which are described in greater detail and are not to be construed as limiting the scope of the utility model. It should be noted that it will be apparent to those skilled in the art that several variations and modifications can be made without departing from the spirit of the utility model, which are all within the scope of the utility model. Accordingly, the scope of the utility model should be assessed as that of the appended claims.

Claims (4)

1. A telescopic adjustable steel structure beam support, characterized in that it includes a concrete layer (101), a fixing plate (102) is fixedly installed on the concrete layer (101), a limiting groove (105) is symmetrically provided on the concrete layer (101), an adjusting plate (103) is slidably provided in the limiting groove (105), a first lifting plate (104) is slidably provided in the adjusting plate (103), a second lifting plate (106) is slidably provided in the fixing plate (102) through a height adjustment mechanism (200), and a horizontal adjustment mechanism (300) for driving the adjustment plate (103) to move is provided on the concrete layer (101). 2. The telescopic adjustable steel structure beam support according to claim 1, characterized in that the horizontal adjustment mechanism (300) includes a base (301), a mounting frame (302), a jack (303), and a connecting shaft (304), the base (301) is symmetrically installed on the concrete layer (101), the mounting frame (302) is installed on the base (301), the jack (303) is installed inside the mounting frame (302), the output end of the jack (303) passes through the side wall of the mounting frame (302) and is connected to the connecting shaft (304), the other end of the connecting shaft (304) is connected to the adjustment plate (103), and an auxiliary mechanism (400) is installed on the mounting frame (302). 3. The telescopic adjustable steel structure beam support according to claim 2, characterized in that the height adjustment mechanism (200) includes a mounting column (201), a mounting block (202), a mounting plate (203), a motor (204), a lead screw (205), an adjusting block (206), a fixing block (207), a connecting plate (208), a limiting sleeve (209), a connecting block (210), and a limiting rod (211). The mounting column (201) is mounted on the base (301). The mounting block (202) is fixedly mounted on the side wall of the mounting column (201). The mounting plate (203) is fixedly mounted on the top wall of the mounting block (202). The motor (204) is mounted on the mounting plate (203). The output end of the motor (204) passes through the side wall of the mounting plate (203) and connects to the lead screw (205). The other end of the lead screw (205) is connected to the concrete layer. (101) The bottom wall rotates and fits, and the lead screw (205) is slidably provided with an adjusting block (206). The adjusting block (206) is provided with a thread that fits with the lead screw (205). A connecting plate (208) is fixedly installed on the side wall of the adjusting block (206). The other end of the connecting plate (208) is slidably set in the limiting sleeve (209). The other end of the limiting sleeve (209) is installed on the side wall of the connecting block (210). The first lifting plate (104) is provided with connecting blocks (210) on its side wall. The mounting plate (203) is symmetrically fixedly installed with fixing blocks (207). The fixing block (207) is provided with a limiting rod (211). The other end of the limiting rod (211) passes through the side wall of the connecting plate (208) and connects to the bottom wall of the concrete layer (101). The other end of the bottom wall of the adjusting block (206) is connected to the top wall of the second lifting plate (106). 4. The telescopic adjustable steel structure beam support according to claim 2, characterized in that the auxiliary mechanism (400) includes a support plate (401) and a lifting lug (402), the support plate (401) is equipped with the lifting lug (402), and the support plate (401) is detachably installed on the side wall of the mounting frame (302).