Building load-bearing beam combined support

By using a combination bracket made of welded cold-rolled galvanized square tubes and steel plates, along with locking and adjusting sliders, the complexity of supporting load-bearing beams during construction was solved, enabling rapid installation and multiple reuses, and reducing labor and material costs.

CN224495916UActive Publication Date: 2026-07-14

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Filing Date
2025-07-04
Publication Date
2026-07-14

AI Technical Summary

Technical Problem

In current building construction, the process of supporting load-bearing beams using materials such as wooden formwork and timber is cumbersome, consumes a lot of manpower and resources, and is not easy to reuse, resulting in waste of materials and labor costs.

Method used

The main support and sub-support are made of cold-rolled galvanized thin-walled square tubes and thin steel plates welded together, and a horizontal locking device and a height adjustment slider are added to form a set of combined supports. The load-bearing beams can be adjusted and fixed in multiple directions by bolts and sliders.

Benefits of technology

It enables rapid installation and repeated use on the construction site, saving manpower and materials, and improving construction efficiency and economic benefits.

✦ Generated by Eureka AI based on patent content.

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Abstract

The utility model relates to a kind of building load-bearing beam combination support, a new type of building support load-bearing beam special combination support, including several steel materials welded into metal support.The support is divided into main body support and vice body support, two parts of support are formed into an integral support, wherein there is a set of locking device, and there are two sets of mediation height sliders.This not only saves a lot of labor in the construction process, but also protects the steel-wood combined building formwork multiple reuse.New building load-bearing beam combination support, the material used by the main row frame and vice row frame used in previous building construction load-bearing beam (such as: wood square, square tube, etc.) is basically cancelled.New load-bearing beam combination support, design implements workshop mass production, can be pieced together in construction process Any shape to solve the height and width size variation of load-bearing beam, which not only solves the problem in construction, but also saves labor and material cost.
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Description

Technical Field

[0001] This utility model relates to a composite support for building load-bearing beams, a novel type of composite support specifically designed for supporting load-bearing beams in buildings. It employs a new process, using several steel materials welded together to form the main support and secondary support. A multi-functional locking mechanism is designed, and two sets of adjusting sliders are added to form a complete composite support. This composite support for load-bearing beams can be easily installed on-site, greatly facilitating construction. Background Technology

[0002] The original method of constructing support beams for load-bearing structures required building formwork, timber, and scaffolding, making on-site construction cumbersome, increasing the difficulty of operation, and requiring a large amount of manpower. This resulted in the waste of materials and labor, which could not be reused, leading to significant material and labor costs. Utility Model Content

[0003] The purpose of this utility model is to overcome the above-mentioned shortcomings in the manufacture of a new type of building load-bearing beam composite support.

[0004] It can be mass-produced in the workshop. The support frame is simple to make and easy to use. When using load-bearing beam combination support and steel-wood building combination formwork on the construction site, it not only saves manpower but also saves raw materials.

[0005] The present invention relates to a combined support for building load-bearing beams, which is implemented using the following method.

[0006] A composite support for load-bearing beams in buildings is constructed by welding cold-rolled galvanized thin-walled square tubes and thin steel plates into a main support and a secondary main support. An additional set of transverse locking devices and two additional sets of height adjustment slider devices are added to form a complete composite support for load-bearing beams.

[0007] Use a small round tube and weld a set of bolts to one side of the tube; then machine multiple small holes on the other side of the tube and use a set of internal angle bolts to fix the locking sleeve at the multiple small holes of the tube. Adjust the transverse dimension of the load-bearing beam as needed to create a locking device.

[0008] A cold-rolled galvanized square tube is used to machine two long strip holes longitudinally, one above the other, on the main support and the other below the secondary main support. These holes are used as bolt-fixed adjusting sliders, allowing for arbitrary adjustment of the longitudinal dimensions of the load-bearing beam to achieve the required height.

[0009] The aforementioned building load-bearing beam composite support uses two cold-rolled galvanized thin-walled square tubes with two thick-walled small square tubes welded to the middle of both ends of the two cold-rolled galvanized thin-walled square tubes. Two through holes are machined in the middle of the small square tubes at both ends to form a parallel fixed guide rail frame. A round tube is added below the parallel fixed guide rail frame for positioning the support beam plate. Then, two cold-rolled galvanized thin-walled square tubes are welded to a cold-rolled thin steel plate and two small square tubes to form a main support.

[0010] The aforementioned building load-bearing beam composite support uses two cold-rolled galvanized thin-walled square tubes welded to a cold-rolled thin steel plate to form a support; then two small square tubes are welded to the bottom of the support as guide rail sliders, and two through holes are machined in the middle of the two small square tubes as locking device shafts to pass through, thus making a secondary main support.

[0011] The aforementioned building load-bearing beam combination support includes a main support and a secondary main support, which are clamps used to fix the building steel-wood combination formwork when supporting the load-bearing beam; a load-bearing beam combination support locking device, which can arbitrarily adjust the lateral dimension of the load-bearing beam while simultaneously locking and securing it; and a fixed adjusting slider, which can arbitrarily adjust the longitudinal vertical dimension of the load-bearing beam during use.

[0012] This new type of combined support frame for load-bearing beams in buildings is constructed by welding several different types of metal square tubes and steel plates together to form the main support frame. A secondary main support frame is also welded together using several different types of metal square tubes and steel plates. Two different small round tubes are used, along with a set of hexagonal bolts to create a locking device. Two sets of adjusting sliders are made using metal square tubes and several sets of bolts. These four devices together form the new type of combined support frame for load-bearing beams. For load-bearing beams of varying heights and widths, any shape can be assembled to solve construction problems. Standardization can also be achieved during production and use. On-site construction and installation of this new type of combined support frame for load-bearing beams, along with steel-wood composite formwork, is simple and convenient, saving manpower and increasing efficiency.

[0013] The present invention will be further described below with reference to the accompanying drawings. Attached Figure Description

[0014] Figure 1 This is a schematic diagram of the overall assembly of a building load-bearing beam combined support according to the technical solution of this utility model.

[0015] Figure 2 This is a schematic diagram of the main support structure;

[0016] Figure 3 This is a schematic diagram of the secondary main support structure;

[0017] Figure 4 This is a schematic diagram of the locking device;

[0018] Figure 5 This is a schematic diagram of the adjusting slider;

[0019] Figure 6 This is a schematic diagram of the combined support frame and beam / slab support; Detailed Implementation

[0020] The following description, in conjunction with embodiments, further illustrates the present invention's combined support for building load-bearing beams.

[0021] The following embodiments are used to illustrate the present invention, but should not be used to limit the scope of protection of the present invention. The conditions in the embodiments can be further adjusted according to specific conditions, and simple improvements to the method of the present invention under the concept of the present invention are all within the scope of protection claimed by the present invention.

[0022] Please see Figures 1-5 In order to improve the installation speed of the composite support for load-bearing beams in buildings, this utility model provides a novel composite support for load-bearing beams. The main support (100) is made of cold-rolled galvanized thin-walled square tubing and thin steel plate, and the secondary main support (200) is made of the same cold-rolled galvanized thin-walled square tubing and thin steel plate. A locking device (300) is made of lightweight round tubing and bolts, and two sets of adjusting sliders (400) are made of square tubing and bolts. Several steel materials are used to weld the main and secondary main supports, and a transverse locking device and two sets of height adjusting slider devices are added to form a complete composite support for load-bearing beams.

[0023] Figure 2 In this process, two cold-rolled galvanized thin-walled square tubes (101) and two thick-walled small square tubes (105) and (106) are welded together to form a parallel fixed guide rail frame. Then, two cold-rolled galvanized thin-walled square tubes (102) are welded together with thin steel plate (103), two small square tubes (107), and the prepared parallel fixed guide rail frame to form a complete main support. The specific process is as follows: Two cold-rolled galvanized thin-walled square tubes (101) are welded together with two thick-walled small square tubes (105) and (106) at the middle of the two ends of the two cold-rolled galvanized thin-walled square tubes, and two through holes are processed in the middle of the small square tubes at both ends to form a parallel fixed guide rail frame; a round tube (104) is added below the parallel fixed guide rail frame for positioning the support beam plate, and then two cold-rolled galvanized thin-walled square tubes (102) are welded together with cold-rolled thin steel plate (103) and two small square tubes (107) to form a main support.

[0024] Figure 3In this process, cold-rolled galvanized thin-walled square tubes (202) and (204) are welded to thin steel plate (203) to form a bracket. Then, two small square tubes (201) and (205) are welded to form a fixed guide rail slider to make a secondary main bracket. The specific process is as follows: Two cold-rolled galvanized thin-walled square tubes (202) and (204) are welded to cold-rolled thin steel plate (203) to form a bracket. Then, two small square tubes (201) and (205) are welded to the bottom of the bracket as guide rail sliders. Then, two through holes are machined in the middle of the two small square tubes as locking device shafts to pass through. This makes a secondary main bracket.

[0025] Figure 4 In this process, a locking device is made using a small round tube (301) (303) and bolts (302). The specific process is as follows: a small round tube (301) is used, and a set of bolts (304) is welded to one side of the round tube; then, multiple small holes are processed on the other side of the small round tube, and a set of internal angle bolts (302) is used to fix the locking sleeve (303) at the multiple small holes of the small round tube. The transverse dimensions of the load-bearing beam can be adjusted arbitrarily to create a locking device. In the construction process, the steel-wood composite formwork and the load-bearing beam composite support can be reused multiple times, saving a lot of labor and material costs.

[0026] Figure 5 In the middle, two square tubes (401) and bolts (402) are used, and two long strip holes are machined longitudinally on the cold-rolled thin steel plates (103) (203) on the main and auxiliary body supports, respectively, to be used as bolts (402) to fix the adjusting slider (400). Together with the main body support (100) and the auxiliary body support (200) made, they are made into two sets of upper and lower adjusting sliders for use, which can arbitrarily adjust the longitudinal upper and lower dimensions of the load-bearing beam to achieve the required dimensions for the height of the load-bearing beam.

[0027] Figure 1In this system, a complete load-bearing beam composite support is assembled from four components: (100), (200), (300), and (400). The parallel frame of the main support (100) bears the downward weight of the load-bearing beam, while the lateral supports of the main support (100) bear the lateral pressure of the load-bearing beam. By combining the secondary main support (200) with the locking device (300), it is fixed to the main support (100), thus bearing the lateral pressure of the load-bearing beam in the opposite direction. More importantly, the locking device (300) allows the lateral dimension of the load-bearing beam to be arbitrarily adjusted to achieve the required dimensions during construction, and then locked when the required dimensions are achieved. Two sets of adjusting sliders (400) are combined with the longitudinal tracks of the two main and secondary supports (100) and (200), allowing the height of the load-bearing beam to be adjusted arbitrarily during construction. During construction, the load-bearing beam composite support and the new steel-wood composite building formwork can be reused multiple times, saving a lot of labor and reducing material costs, thus increasing economic benefits.

[0028] The main support (100) and the secondary main support (200) are clamps used to fix the steel-wood composite formwork of the building when supporting the load-bearing beam; the load-bearing beam composite support locking device (300) can adjust the transverse dimension of the load-bearing beam at will, while locking and securing it; when using the fixed adjustment slider (400), the longitudinal upper and lower dimensions of the load-bearing beam can be adjusted at will; the new type of building load-bearing beam composite support saves a lot of labor and material costs during the construction process.

Claims

1. A composite support for a building load-bearing beam, characterized in that, The main support and sub-main support are made of cold-rolled galvanized thin-walled square tubes and thin steel plates welded together. A set of transverse locking devices is added, and two sets of height adjustment slider devices are added to form a complete load-bearing beam combination support. Use a small round tube and weld a set of bolts to one side of the tube; then machine multiple small holes on the other side of the tube and use a set of internal angle bolts to fix the locking sleeve at the multiple small holes of the tube. Adjust the transverse dimension of the load-bearing beam as needed to create a locking device. A cold-rolled galvanized square tube is used to machine two long strip holes longitudinally, one above the other, on the main support and the other below the secondary main support. These holes are used as bolt-fixed adjusting sliders, allowing for arbitrary adjustment of the longitudinal dimensions of the load-bearing beam to achieve the required height.

2. The composite support for a building load-bearing beam according to claim 1, characterized in that, Two cold-rolled galvanized thin-walled square tubes are welded to the middle of both ends of the two cold-rolled galvanized thin-walled square tubes, and two through holes are machined in the middle of the small square tubes at both ends to make a parallel fixed guide rail frame. A round tube is added below the parallel fixed guide rail frame for positioning the support beam plate. Then, two cold-rolled galvanized thin-walled square tubes are welded to cold-rolled thin steel plates and two small square tubes to form a main support.

3. The composite support for a building load-bearing beam according to claim 1, characterized in that, Two cold-rolled galvanized thin-walled square tubes are welded to a cold-rolled thin steel plate to form a support; then two small square tubes are welded to the bottom of the support as guide rail sliders, and two through holes are machined in the middle of the two small square tubes as the shafts for the locking device to pass through, thus making a secondary main support.

4. A composite support for a building load-bearing beam according to claim 1, characterized in that, The main support and secondary main support are clamps used to fix the steel-wood composite formwork when supporting the load-bearing beams; the load-bearing beam composite support locking device allows for arbitrary adjustment of the lateral dimensions of the load-bearing beams while simultaneously locking and securing them; the fixed adjusting slider allows for arbitrary adjustment of the longitudinal dimensions of the load-bearing beams.