CN219870252U - Bearing capacity detection device of support frame body - Google Patents

Abstract

The utility model discloses a bearing capacity detection device of a support frame body, which comprises a tool type assembly tool main body and intelligent control hydraulic loading equipment; tool type group's frock main part includes two rows of parallel arrangement's frock base post groups, two rows be equipped with the bearing frame bottom plate between the frock base post group, frock base post group is including a plurality of frock base posts of evenly setting, is located on the same frock base post group be equipped with the frock sill beam between the frock base post, every the upper portion of frock base post all is equipped with the standard that quantity equals and connects the high post, is located the bottom on the same frock base post group, top the standard connects transversely to be equipped with standard stand crossbeam between the high post. The device and the method for detecting the bearing capacity of the support frame body can simulate the construction working conditions of all tower-type support frame bodies on the market, are simple in structure and convenient to operate, can simulate the construction working conditions of the newly developed support bodies or the optimally designed support bodies, and are high in universality.

Description

Bearing capacity detection device of support frame body

Technical Field

The utility model relates to the technical field of mechanical detection, in particular to a bearing capacity detection device of a support frame body.

Background

At present, the support frame body plate is widely applied to the construction, and plays an important role in other industries, so that after the support frame body is optimally designed or new products are developed, the first piece is to carry out a loading experiment on the support frame body, and the bearing capacity of the support frame body, the rigidity, the strength and the stability of the support frame body material are detected.

In order to simulate the actual condition of the frame body, professional experiment detection equipment is needed, but with the high-speed development of the industry, various types of frame bodies are continuously developed, not only are the existing frame bodies optimized and updated, but also new products newly developed and designed, but no matter the frame bodies are updated in that type, the experiment is needed to be carried out to verify the reliability of the frame bodies, the most important embodiment of the frame body experiment is that the actual construction loading condition can be simulated, meanwhile, the safety of the experiment is ensured, and after all performances of new products are only in theory, and the theory and reality have a quite large distance.

In order to meet the experiment of the support frame body, a plurality of experiment tools are designed on the market, each tool has the characteristics of the tool, and some tools have strong pertinence at the beginning of the design, although the experiment can be accurately and safely completed on the specific support body, the universality is poor, the aim of repeatedly using one set of tools cannot be achieved, the burden is caused on the material cost, the trouble is brought to the management and manufacturing of materials, places and the like, and the requirements on operators are higher and higher for using the tools in different forms for good operation.

There is currently no better solution to the above problems.

Disclosure of Invention

The present utility model provides a bearing capacity detecting device for a supporting frame body, which can overcome the above-mentioned shortcomings of the prior art.

In order to achieve the technical purpose, the technical scheme of the utility model is realized as follows:

the utility model provides a bearing capacity detection device of support body, includes instrument formula group's frock main part and intelligent control hydraulic pressure loading equipment;

the tool type assembling tool main body comprises two rows of tool base column groups which are arranged in parallel, a bearing frame bottom plate is arranged between the two rows of tool base column groups, the tool base column groups comprise a plurality of tool base columns which are uniformly arranged, tool bottom beams are arranged between the tool base columns which are positioned on the same tool base column group, standard height connecting columns which are equal in number are arranged at the upper part of each tool base column, standard upright column cross beams are transversely arranged between the standard height connecting columns which are positioned at the bottom and the top of the same tool base column group, standard upright column diagonal braces are respectively arranged between the standard height connecting columns which are positioned at the middle part of the same tool base column group, a plurality of parallel tool main beams are transversely arranged between the standard height connecting columns which are positioned at the top of different tool base column groups, and equipment load beams which are perpendicular to the tool main beams are arranged at the bottom of the tool main beams;

the intelligent control hydraulic loading equipment comprises a portable hydraulic pump station, the portable hydraulic pump station is electrically connected with a numerical control operation console, the portable hydraulic pump station is connected with a hydraulic loading oil cylinder pipeline, the portable hydraulic pump station is positioned on the upper portion of the tool main beam, and the hydraulic loading oil cylinder is fixedly connected with the bottom of the equipment loading beam through an equipment fixing sliding seat.

Further, the portable hydraulic pump station is also connected with an oil tank pipeline.

Further, in use, the support frame body to be detected is located on the support frame base plate.

Further, the tool type assembling tool main body is fixed at the experimental position through the embedded ribs or the expansion bolts.

The utility model has the beneficial effects that: the device and the method for detecting the bearing capacity of the support frame body can simulate the construction working conditions of all tower-type support frame bodies on the market, are simple in structure and convenient to operate, can simulate the construction working conditions of the newly developed support bodies or the optimally designed support bodies, and are high in universality.

Drawings

In order to more clearly illustrate the embodiments of the present utility model or the technical solutions in the prior art, the drawings that are needed in the embodiments will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present utility model, and 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 diagram of a tool type assembly tool main body of a bearing capacity detection device of a support frame according to an embodiment of the utility model;

fig. 2 is a schematic structural diagram of an intelligent control hydraulic loading device of a bearing capacity detection device of a supporting frame according to an embodiment of the present utility model;

fig. 3 is a schematic diagram of an assembly structure of a bearing capacity detection device of a supporting frame according to an embodiment of the present utility model;

in the figure: 1. a tool type assembling tool main body; 11. a tooling base column; 12. standard high column connection; 13. standard upright post cross beams; 14. standard upright post diagonal bracing; 15. a tooling bottom beam; 16. an equipment carrying beam; 17. a tool main beam; 18. a support base plate; 2. intelligent control of the hydraulic loading device; 21. a numerical control operation table; 22. portable hydraulic pump station; 23. a hydraulic loading cylinder; 24. the device secures the slide.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which are derived by a person skilled in the art based on the embodiments of the utility model, fall within the scope of protection of the utility model.

As shown in fig. 1-3, a bearing capacity detection device for a support frame according to an embodiment of the present utility model includes a tool type assembly tool main body 1 and an intelligent control hydraulic loading device 2;

the tool type assembling tool main body 1 comprises two rows of parallel tool base column groups, a bearing frame bottom plate 18 is arranged between the two rows of tool base column groups, the tool base column groups comprise a plurality of uniformly arranged tool base columns 11, tool bottom beams 15 are arranged between the tool base columns 11 on the same tool base column group, standard height connecting columns 12 with the same number are arranged on the upper part of each tool base column 11, standard upright column cross beams 13 are transversely arranged between the standard height connecting columns 12 at the bottom and the top of the same tool base column group, standard upright column diagonal braces 14 are respectively arranged between the standard height connecting columns 12 at the middle part of the same tool base column group, a plurality of parallel tool main beams 17 are transversely arranged between the standard height connecting columns 12 at the top of different tool base column groups, and equipment load beams 16 perpendicular to the standard height connecting columns are arranged at the bottom of the tool main beams 17;

the intelligent control hydraulic loading device 2 comprises a portable hydraulic pump station 22, the portable hydraulic pump station 22 is electrically connected with a numerical control operation table 21, the portable hydraulic pump station 22 is in pipeline connection with a hydraulic loading cylinder 23, the portable hydraulic pump station 22 is located on the upper portion of the tool main beam 17, and the hydraulic loading cylinder 23 is fixedly connected with the bottom of the device loading beam 16 through a device fixing sliding seat 24.

In an embodiment, the portable hydraulic power unit 22 is further connected to a tank line.

In an embodiment, in use, the support frame body to be inspected is positioned on the carrier floor 18.

In the embodiment, the tool type assembling tool main body 1 is fixed at an experimental position through a bar planting or expansion bolt.

In order to facilitate understanding of the above technical solutions of the present utility model, the following describes the above technical solutions of the present utility model in detail by a specific usage manner.

When the tool device is specifically used, the tool device is divided into two parts, wherein the two parts are respectively a tool type assembly tool main body and an intelligent control hydraulic loading device. The tool type assembling tool main body is a straight pin type high-bearing steel structure skeleton frame, in the experimental process, the generated load is borne by the frame body, so that the requirement on an experimental field is not very high, as long as the ground is flat, the area is large enough, the reinforcing bars can be planted or expansion bolts can be punched, and the tool is an assembled steel structure, so that the tool can be freely moved or disassembled for combination. The intelligent control hydraulic loading equipment is provided with a corresponding intelligent control system, remote operation, data collection and monitoring can be performed in the experimental process, the sensitivity is high, the accuracy is high, the safety and the reliability are high, and even if the experimental frame body has technical defects, the personal safety of operators can be ensured due to destructive accidents.

(1) Tool type assembly tool main body: the device comprises a tool base column, a standard high-connection column, a standard upright column cross beam, a standard upright column diagonal brace, a tool bottom beam, a device carrying beam and a bearing frame bottom plate;

the tool type assembling tool main body is placed in an experimental land, is fixed in the experimental land in a mode of embedding ribs or expansion bolts, is free from moving, a frame body to be tested is placed on a bearing frame bottom plate, and the early-stage preparation work of the test is completed by adjusting the equipment carrying beam and the equipment position;

(2) Intelligent control hydraulic loading equipment: the device comprises a numerical control operation table, a portable hydraulic pump station, a hydraulic loading oil cylinder and an equipment fixing sliding seat;

the intelligent control hydraulic loading equipment is a whole set of experimental equipment formed by connecting multiple special tools in series with the existing equipment, wherein a pressurized hydraulic cylinder and a portable hydraulic pump station are used for bearing simulated site load, a fixed sliding seat of the equipment is a tool for effectively connecting the pressurized equipment with a tool type assembling tool main body together to play a role of a tie, and a numerical control operation table comprises various sensors and controls the work of the hydraulic equipment through a numerical control optical cable and is used as a data terminal for collecting relevant experimental data.

The processing steps are as follows:

firstly, cutting and welding the section steel, the steel pipe and the steel plate according to the dimension marked by the processing diagram to finish the part 1;

secondly, customizing and purchasing equipment according to the use requirement, connecting the equipment together through accessories such as a numerical control optical cable, a cable, an oil pipe and the like according to the use specification, debugging the equipment to meet the use requirement, and completing part 2;

and thirdly, assembling according to the design assembly drawing, and finishing the practical use of the product described in the patent.

The specific detection method comprises the following steps:

first, assembling tool type assembling tool main body: all the components are connected together through bolts according to a tooling design drawing, so that assembly of the main frame is completed;

and secondly, fixing the assembled tool main body at an experimental position in a manner of planting ribs or expansion bolts.

And thirdly, installing the portable hydraulic pump station, the equipment fixing sliding seat and the hydraulic loading oil cylinder on the tool main body according to design requirements, and connecting the pump station with the oil cylinder through an oil pipe.

Fourthly, connecting the experimental equipment with the numerical control operation table by using a cable and a numerical control optical cable, and debugging the equipment to ensure that the equipment can normally run and the data is accurate;

fifthly, arranging a support frame to be detected on a bottom plate of the tool main body, and correcting to ensure that the actual working condition can be effectively simulated in the experimental process;

and sixthly, controlling the experimental equipment to start an experiment through the numerical control operation table, conveying liquid to the oil cylinder through the pump station, enabling the oil cylinder to stretch out and draw back to generate mechanical energy, finally converting the mechanical energy into kinetic energy and applying the kinetic energy to the support frame body, enabling the support frame body to deform, ending the experiment until the support frame body reaches a damage limit, and recording experimental data.

In summary, by means of the technical scheme, the construction working conditions of all tower-type support frames on the market can be simulated, the device is simple in structure and convenient to operate, and the new research and development frames of the same type or the frames after the optimization design can be subjected to construction working condition simulation experiments, so that the universality is strong.

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 (4)

1. The bearing capacity detection device of the support frame body is characterized by comprising a tool type assembly tool main body (1) and intelligent control hydraulic loading equipment (2);

the tool type assembling tool main body (1) comprises two rows of tool base column groups which are arranged in parallel, a bearing frame bottom plate (18) is arranged between the two rows of tool base column groups, each tool base column group comprises a plurality of tool base columns (11) which are uniformly arranged, tool bottom beams (15) are arranged between the tool base columns (11) which are positioned on the same tool base column group, standard height connecting columns (12) with the same number are arranged on the upper part of each tool base column (11), standard upright column cross beams (13) are transversely arranged between the standard height connecting columns (12) which are positioned at the bottom and the top of the same tool base column group, standard upright column diagonal braces (14) are respectively arranged between the standard height connecting columns (12) which are positioned at the middle part of the same tool base column group, a plurality of parallel tool main beams (17) are transversely arranged between the standard height connecting columns (12) which are positioned at the top of different tool base column groups, and equipment load beams (16) which are perpendicular to the standard height connecting columns are arranged at the bottom of the tool main beams (17);

the intelligent control hydraulic loading device (2) comprises a portable hydraulic pump station (22), the portable hydraulic pump station (22) is electrically connected with a numerical control operation table (21), the portable hydraulic pump station (22) is connected with a hydraulic loading oil cylinder (23) through a pipeline, the portable hydraulic pump station (22) is positioned on the upper portion of the tool main beam (17), and the hydraulic loading oil cylinder (23) is fixedly connected with the bottom of the equipment loading beam (16) through a device fixing sliding seat (24).

2. The load capacity sensing device of a support frame according to claim 1, characterized in that the portable hydraulic pump station (22) is further connected to a tank line.

3. The device for detecting the bearing capacity of a supporting frame body according to claim 1, characterized in that, in use, the supporting frame body to be detected is located on the carrier floor (18).

4. The bearing capacity detection device of a supporting frame body according to claim 1, wherein the tool type assembling tool main body (1) is fixed at an experimental position through a bar planting or expansion bolt.