CN111649930A

CN111649930A - Steel construction building girder stability detection device

Info

Publication number: CN111649930A
Application number: CN202010556873.6A
Authority: CN
Inventors: 赵桂荣
Original assignee: Individual
Current assignee: Individual
Priority date: 2020-06-18
Filing date: 2020-06-18
Publication date: 2020-09-11

Abstract

The invention relates to the field of steel structures, in particular to a steel structure building main beam stability detection device and a working method thereof, and the device comprises a positioning clamping mechanism, a simulation frame, a containing box body, a position adjusting frame, four deformation quantity detection mechanisms, a plurality of pressure applying mechanisms, two lifting mechanisms and a tension testing mechanism, wherein the positioning clamping mechanism is fixedly arranged at the bottom of the inner side of the containing box body, the position adjusting frame is fixedly arranged at the bottom of the two lifting mechanisms, the two tension testing mechanisms are fixedly arranged on the position adjusting frame, the steel structure building main beam stability detection device applies pressure to a plurality of positions of a building main beam on the simulation frame through the plurality of pressure applying mechanisms, applies tension to the building main beam on the simulation frame through the tension testing mechanism, and further analyzes that the building main beam is arranged on the steel structure frame, the stability of the building girder avoids the limitation of the analyzed building girder.

Description

Steel construction building girder stability detection device

Technical Field

The invention relates to the field of steel structures, in particular to a device for detecting the stability of a steel structure building main beam.

Background

The steel structure is a structure composed of steel materials and is one of main building structure types, when a conventional steel structure main beam is subjected to tensile test and compressive test, software is often used for stress analysis, or a simulation entity main beam is processed, and a simulation test is carried out by momentarily pressurizing or applying tensile force by workers, but a simulation frame of the assembled main beam cannot be analyzed, so that the stability of the analyzed building main beam has limitation.

Chinese patent application No.: CN 201911373125.8; the utility model discloses a steel structure intelligence measuring device for building to detect the installation condition of steel in assembly process and assembly completion after, can in time detect steel not hard up or other situations and inform relevant operating personnel, improve operating personnel's work efficiency, reduce the emergence of incident.

Chinese patent application No.: CN 201810364333.0; the invention discloses a monitoring device for a welding main beam of a steel structure building, which can monitor a steel structure more accurately through a monitoring device, and can enable an operator to more conveniently see the positions of a first conical block and a second conical block through a viewing device to know whether the steel structure is deformed, thereby achieving the effect of directly monitoring the steel structure without manpower, realizing accurate monitoring and avoiding danger.

Both solutions have the following disadvantages:

1. the second scheme prevents accidents by installing equipment on the building main beam and then monitoring in real time, but the scheme cannot detect and analyze the stability of the building main beam on the simulation frame at the beginning.

2. The first installation condition through to the building girder detects, and then prevents to take place the incident, but this scheme can't detect the analysis to the building girder stability on the simulated frame at the beginning.

Disclosure of Invention

The invention aims to provide a steel structure building main beam stability detection device and a working method.

In order to achieve the purpose, the invention adopts the following technical scheme:

the steel structure building main beam stability detection device comprises a positioning clamping mechanism, a simulation frame, a containing box body, a position adjusting frame, four deformation quantity detection mechanisms, a plurality of pressure applying mechanisms, two pulling mechanisms and a tension testing mechanism, wherein the two pulling mechanisms are respectively and fixedly arranged on the inner walls of the two sides of the containing box body, the two pulling mechanisms are mutually and symmetrically arranged, the simulation frame is placed at the bottom of the inner side of the containing box body, the positioning clamping mechanism for clamping the simulation frame is fixedly arranged at the bottom of the inner side of the containing box body, the position adjusting frame is fixedly arranged at the bottom of the two pulling mechanisms, the plurality of pressure applying mechanisms can be slidably arranged on the position adjusting frame, the four deformation quantity detection mechanisms are respectively positioned at the four sides of the bottom of the position adjusting frame, the four deformation quantity detection mechanisms are fixedly connected with the position adjusting frame, the two tension testing mechanisms are fixedly arranged on the position adjusting, and the two tension testing mechanisms are symmetrically arranged.

Further, the positioning and clamping mechanism comprises a clamping plate, two guide plates, clamping plate plates and inserting plates, wherein the two guide plates are fixedly arranged at the same end of the two inserting plates respectively, one side of each guide plate is attached to the inner wall of the accommodating box body, the bottom of each guide plate is attached to the inner side bottom of the accommodating box body, the clamping plate is clamped on the two guide plates and fixedly connected with the inner wall of the accommodating box body, a guide chute for the guide plates to slide is formed in the clamping plate, a plurality of first inserting ports are formed in the top of each inserting plate and uniformly distributed along the length direction of the inserting plate, a plurality of second inserting ports are formed in the bottom of each clamping plate and uniformly distributed along the length direction of the clamping plate, the two second inserting ports of each clamping plate are clamped in the two first inserting ports respectively, and the inner walls of the two clamping plate are contacted with the outer walls of two sides of the simulation frame, the inner walls of the two insertion plates are in contact with the outer walls of the two sides of the simulation frame.

Further, the position adjusting frame comprises two first square sliding tubes, two second square sliding tubes and connecting plates, the two first square sliding tubes are symmetrically arranged, the outer sides of the two first square sliding tubes are attached to the inner walls of the two sides of the accommodating box body, the two connecting plates are positioned between the two first square sliding tubes, the two ends of each connecting plate are fixedly connected with the inner walls of the two first square sliding tubes respectively, the outer walls of the two connecting plates are attached to the inner walls of the other two sides of the accommodating box body, the two second square sliding tubes are positioned between the two first square sliding tubes, the two ends of each second square sliding tube are inserted into the two first square sliding tubes respectively, the two ends of each second square sliding tube are attached to the outer walls of the two sides of the accommodating box body, accommodating grooves are formed in the tops of the two ends of each second square sliding tube, a friction plate is fixedly arranged in each accommodating groove, and friction strips are arranged on the upper surfaces of the inner sides of the first square sliding tubes, two first square slide tubes are respectively and fixedly arranged at the bottoms of the two pulling-up mechanisms, and the plurality of pressing mechanisms can be respectively arranged on the two second square slide tubes in a sliding manner.

Further, every mechanism that draws rises all includes the hydro-cylinder, two first guide pillars, mounting panel and first linear bearing, the hydro-cylinder passes through support frame fixed mounting on the inner wall of one side that holds the box body, and the output of hydro-cylinder and the top fixed connection of first square slide tube, two first guide pillars are located the both sides of hydro-cylinder, and the bottom of two first guide pillars and the top fixed connection of first square slide tube, two mounting panels fixed mounting are on the inner wall that holds the box body, and two first linear bearings are installed respectively on two mounting panels, first linear bearing is passed at the top of every first guide pillar, and two first guide pillars and two first linear bearings sliding connection.

Furthermore, each pressure mechanism comprises a cylinder, a fixing plate, a guide frame, a pressure applying column, a friction pad, two heightening plates and a C-shaped clamping frame, the guide frame is inserted in the second square sliding pipe, the outer walls of the two sides of the guide frame are attached to the inner walls of the two sides of the second square sliding pipe, the two C-shaped clamping frames are fixedly arranged on the two sides of the guide frame, the top of the inner side of each C-shaped clamping frame is contacted with the top of the second square sliding pipe, the bottom of the inner side of each C-shaped clamping frame is contacted with the bottom of the second square sliding pipe, the two heightening plates are fixedly arranged on the tops of the two C-shaped clamping frames, the fixed plate is fixedly arranged at the tops of the two heightening plates, the air cylinder is fixedly arranged at the top of the fixed plate, the output end of the air cylinder penetrates through the fixed plate and is fixedly connected with the pressure applying column, the guide frame is provided with a sliding hole for the pressure applying column to slide, the pressure applying column is positioned in the sliding hole, and the bottom of the pressure applying column penetrates through the sliding hole and is fixedly connected with the friction pad.

Furthermore, every deformation quantity detection mechanism all includes electronic slip table, CCD camera and high adjustment mechanism, and high adjustment mechanism fixed mounting is on the connecting plate, and electronic slip table fixed mounting is at high adjustment mechanism's top, and CCD camera fixed mounting is on the slide of electronic slip table, and electronic slip table and CCD camera all are connected with the controller electricity.

Further, height adjusting mechanism includes the roof, fixed plate adjusting screw, two second linear bearing and second guide pillar, fixed plate fixed mounting is on the connecting plate, the roof is located second linear bearing directly over, and two second linear bearing fixed mounting are on the fixed plate, and the top of every second guide pillar pass second linear bearing and with roof fixed connection, electronic slip table fixed mounting is on the top of roof, set up the screw hole with adjusting screw meshing on the fixed plate, adjusting screw installs on the fixed plate, and adjusting screw's top is contradicted with the bottom of roof.

Further, every pulling force accredited testing organization all includes guide rail, two barrier plates, a plurality of guide holder and tensile subassembly, and guide rail fixed mounting is on the connecting plate, and two barrier plates fixed mounting are on the connecting plate, and two barrier plates are located the both sides of guide rail, and a plurality of guide holder is installed on the guide rail, and a plurality of tensile subassembly is installed respectively on a plurality of guide holder.

Further, every tensile subassembly all includes the bottom plate, the speed reducer, driving motor, the steel cable, the tensiometer, the wind-up wheel, wind-up roll and two rod seats, bottom plate fixed mounting is on the guide holder, two rod seat fixed mounting are on the bottom plate, the wind-up roll is installed on two rod seats, the wind-up wheel is installed on the wind-up roll, and the wind-up wheel is located between two rod seats, and the both sides of wind-up wheel and the inboard contact of two rod seats, the one end fixed mounting of steel cable is on the wind-up wheel, and the steel cable winding is on the wind-up wheel, and the other end of steel cable is fixed on the simulation frame, the tensiometer is installed on the steel cable, the speed reducer passes through supporting seat fixed mounting on the bottom plate, and driving motor fixed mounting is on the.

The invention has the beneficial effects that: this steel construction building girder stability detection device places holding the box internally through the analog framework that will install the building girder, and the rethread a plurality of mechanism of exerting pressure is to building girder's on the analog framework many places exerting pressure, exerts the pulling force through the building girder of pulling force accredited testing organization on the analog framework, and then assay department installs the back on steel structural framework as the building girder, and the stability of building girder has avoided the building girder limitation that the analysis came out.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings required to be used in the embodiments of the present invention will be briefly described below.

FIG. 1 is a schematic perspective view of the present invention;

FIG. 2 is a schematic perspective view of the present invention with the receiving case removed;

FIG. 3 is a schematic perspective view of the positioning and clamping mechanism and the simulation frame;

FIG. 4 is a perspective view of a position adjustment frame;

FIG. 5 is an exploded view of a portion of the position adjustment frame;

FIG. 6 is a perspective view of the lifting mechanism;

FIG. 7 is a perspective view of the pressing mechanism;

FIG. 8 is a schematic perspective view of a deformation amount detecting mechanism;

FIG. 9 is a schematic perspective view of the height adjustment mechanism;

FIG. 10 is a partial perspective view of the present invention;

FIG. 11 is a schematic perspective view of a tension testing mechanism;

FIG. 12 is a perspective view of a stretching assembly;

in the figure:

1. a positioning and clamping mechanism; 1a, clamping a strip plate; 1a1, second jack; 1b, inserting plates; 1b1, first jack; 1c, a clamping plate; 1c1, a guide chute; 1d, a guide plate;

2. simulating a frame;

3. a deformation amount detection mechanism; 3a, an electric sliding table; 3c, a CCD camera; 3d, a height adjusting mechanism; 3d1, top plate; 3d2, fixing plate; 3d3, second linear bearing; 3d4, adjusting screw; 3d5, second guide post;

4. a pressure applying mechanism; 4a, a cylinder; 4b, fixing plates; 4c, heightening plates; 4d, C-shaped clamping frames; 4e, a guide frame; 4f, pressing a column; 4h, friction pad;

5. a pulling-up mechanism; 5a, an oil cylinder; 5b, a first guide post; 5c, mounting a plate; 5d, a first linear bearing;

6. a position adjustment frame; 6a, a first square sliding pipe; 6b, a second square sliding pipe; 6c, a connecting plate; 6d, friction plates;

7. a tension testing mechanism; 7a, a guide seat; 7b, a guide rail; 7c, a blocking plate; 7d, a stretching assembly; 7d1, bottom plate; 7d2, speed reducer; 7d3, drive motor; 7d4, steel cord; 7d5, tensiometer; 7d6, a winding wheel; 7d7, a wind-up roll; 7d8, stick base;

8. accommodating the cartridge.

Detailed Description

The technical scheme of the invention is further explained by the specific implementation mode in combination with the attached drawings.

Wherein the showings are for the purpose of illustration only and are shown by way of illustration only and not in actual form, and are not to be construed as limiting the present patent; to better illustrate the embodiments of the present invention, some components of the drawings may be omitted, enlarged or reduced, and do not represent the size of an actual product.

Referring to fig. 1 to 12, the steel structure building main beam stability detecting device comprises a positioning clamping mechanism 1, a simulation frame 2, a containing box 8, a position adjusting frame 6, four deformation quantity detecting mechanisms 3, a plurality of pressure applying mechanisms 4, two pulling mechanisms 5 and a tension testing mechanism 7, wherein the two pulling mechanisms 5 are respectively and fixedly arranged on the inner walls of the two sides of the containing box 8, the two pulling mechanisms 5 are mutually and symmetrically arranged, the simulation frame 2 is arranged at the bottom of the inner side of the containing box 8, the positioning clamping mechanism 1 for clamping the simulation frame 2 is fixedly arranged at the bottom of the inner side of the containing box 8, the position adjusting frame 6 is fixedly arranged at the bottom of the two pulling mechanisms 5, the plurality of pressure applying mechanisms 4 are slidably arranged on the position adjusting frame 6, and the four deformation quantity detecting mechanisms 3 are respectively positioned at the four sides of the bottom of the position adjusting frame 6, and four deformation detection mechanisms 3 are all fixedly connected with the position adjusting frame 6, two tension testing mechanisms 7 are fixedly arranged on the position adjusting frame 6, and the two tension testing mechanisms 7 are symmetrically arranged. When the compression strength and the blocking and pulling strength of the simulation frame 2 need to be detected, firstly, the simulation frame 2 is placed in the accommodating box body 8 by a worker, then the worker uses the positioning and clamping mechanism 1 to clamp the bottom of the simulation frame 2, the worker controls the deformation quantity detection mechanism 3 to work through the controller, further, the deformation quantity detection mechanism 3 transmits the original appearance of the simulation frame 2 to the controller in a digital signal analog-digital mode, the controller transmits the signal to the intelligent device, the intelligent device carries out digital processing on the signal, further, a linear image is formed, the worker slides the plurality of pressure applying mechanisms 4 along the position adjusting frame 6, further, the plurality of pressure applying mechanisms 4 are adjusted to the positions needing to apply pressure, the worker controls the plurality of pressure applying mechanisms 4 to work through the controller, further, the plurality of pressure applying mechanisms 4 apply pressure to the simulation frame 2, in the process, the deformation quantity detection mechanism 3 also continues to work, so that the change condition of the simulation framework 2 is transmitted to the intelligent equipment in real time through the controller, the intelligent equipment analyzes the change condition, the deformation quantity generated by the simulation framework 2 along with the change of time is determined,

workers control the tension testing mechanism 7 to work through the controller, tension is applied to the simulation framework 2, meanwhile, the deformation quantity detecting mechanism 3 transmits the change situation of the simulation framework 2 to the intelligent equipment through the controller in real time, the intelligent equipment analyzes the change situation, deformation quantity generated by the simulation framework 2 along with the change of time is determined,

the worker controls the pulling-up mechanism 5 to work through the controller, and then adjusts the height of the position adjusting frame 6, that is, the positions of the pressing mechanism 4 and the tensile testing mechanism 7.

The positioning and clamping mechanism 1 comprises a clamping plate 1c, two guide plates 1d, a clamping plate 1a and an inserting plate 1b, wherein the two guide plates 1d are respectively and fixedly arranged at the same end of the two inserting plates 1b, one side of each guide plate 1d is attached to the inner wall of the accommodating box body 8, the bottom of each guide plate 1d is attached to the bottom of the inner side of the accommodating box body 8, the clamping plate 1c is clamped on the two guide plates 1d, the clamping plate 1c is fixedly connected with the inner wall of the accommodating box body 8, a guide chute 1c1 for the guide plates 1d to slide is formed in the clamping plate 1c, a plurality of first inserting ports 1b1 are formed in the top of each inserting plate 1b, a plurality of first inserting ports 1b1 are uniformly distributed along the length direction of the inserting plate 1b, a plurality of second inserting ports 1a1 are formed in the bottom of each clamping plate 1a, and a plurality of second inserting ports 1a1 are uniformly distributed along the length direction, the two second inserting holes 1a1 of each lath plate 1a are respectively inserted into the two first inserting holes 1b1, the inner walls of the two lath plates 1a contact with the outer walls of the two sides of the simulation frame 2, and the inner walls of the two lath plates 1b contact with the outer walls of the two sides of the simulation frame 2. When the simulation frame 2 placed in the accommodating box body 8 needs to be clamped, the two inserting plates 1b are moved by a worker, so that the inner walls of the two inserting plates 1b are in contact with the outer walls of the two sides of the simulation frame 2, the two inserting plates 1a are clamped on the two inserting plates 1b, the inner walls of the two inserting plates 1a are in contact with the outer walls of the other two sides of the simulation frame 2, and the simulation frame 2 is fixed.

The position adjusting frame 6 comprises two first square sliding tubes 6a, two second square sliding tubes 6b and connecting plates 6c, wherein the two first square sliding tubes 6a are symmetrically arranged, the outer sides of the two first square sliding tubes 6a are attached to the inner walls of two sides of the accommodating box body 8, the two connecting plates 6c are positioned between the two first square sliding tubes 6a, two ends of each connecting plate 6c are fixedly connected to the inner walls of the two first square sliding tubes 6a respectively, the outer walls of the two connecting plates 6c are attached to the inner walls of the other two sides of the accommodating box body 8, the two second square sliding tubes 6b are positioned between the two first square sliding tubes 6a, two ends of each second square sliding tube 6b are inserted into the two first square sliding tubes 6a respectively, two ends of each second square sliding tube 6b are attached to the outer walls of two sides of the accommodating box body 8, the top parts of two ends of each second square sliding tube 6b are provided with accommodating grooves, every holding tank internal fixation is provided with friction plate 6d, and the inboard upper surface of first square slide pipe 6a is provided with the friction strip, and two first square slide pipes 6a are fixed mounting respectively in the bottom of two mechanisms 5 that draw, and a plurality of application of pressure mechanism 4 can slide respectively and set up on two square slide pipes 6b of second. When the position of the pressing mechanism 4 needs to be adjusted, the second square sliding tube 6b is pushed along the length direction of the first square sliding tube 6a, the position of one side of the pressing mechanism 4 is adjusted, the pressing mechanism 4 is pushed to slide along the second square sliding tube 6b, the position of the other side of the pressing mechanism 4 is adjusted, after the position of the pressing mechanism 4 is adjusted, the pressing mechanism 4 is started, the pressing mechanism 4 drives the second square sliding tube 6b to move upwards, the friction plate 6d is abutted against the upper surface of the inner side of the first square sliding tube 6a, the second square sliding tube 6b is prevented from sliding with the first square sliding tube 6a through the action of friction force, the top of the simulation frame 2 is abutted through the pressing mechanism 4, and the pressing mechanism 4 is difficult to slide on the second square sliding tube 6b, thereby completing the positioning of the pressing mechanism 4.

Each lifting mechanism 5 comprises an oil cylinder 5a, two first guide columns 5b, mounting plates 5c and first linear bearings 5d, the oil cylinder 5a is fixedly mounted on the inner wall of one side of the accommodating box body 8 through a support frame, the output end of the oil cylinder 5a is fixedly connected with the top of the first square sliding pipe 6a, the two first guide columns 5b are located on two sides of the oil cylinder 5a, the bottoms of the two first guide columns 5b are fixedly connected with the top of the first square sliding pipe 6a, the two mounting plates 5c are fixedly mounted on the inner wall of the accommodating box body 8, the two first linear bearings 5d are respectively mounted on the two mounting plates 5c, the top of each first guide column 5b penetrates through the first linear bearing 5d, and the two first guide columns 5b are slidably connected with the two first linear bearings 5 d. When the positions of the pressing mechanism 4 and the tension testing mechanism 7 need to be adjusted, a worker controls the oil cylinder 5a to work through the controller, so that the oil cylinder 5a drives the first square sliding pipe 6a to move upwards, the first square sliding pipe 6a drives the two first guide pillars 5b to move upwards, the two first guide pillars 5b slide on the two first linear bearings 5d, the position of the first square sliding pipe 6a is adjusted, the first square sliding pipe 6a drives the connecting plate 6c and the second square sliding pipe 6b to move, the connecting plate 6c drives the pressing mechanism 4 to move, the second square sliding pipe 6b drives the tension testing mechanism 7 to move, and the positions of the pressing mechanism 4 and the tension testing mechanism 7 are adjusted.

Each pressure mechanism 4 comprises a cylinder 4a, a fixed plate 4b, a guide frame 4e, a pressure applying column 4f, a friction pad 4h, two heightening plates 4C and a C-shaped clamping frame 4d, wherein the guide frame 4e is inserted in a second square sliding tube 6b, the outer walls of the two sides of the guide frame 4e are attached to the inner walls of the two sides of the second square sliding tube 6b, the two C-shaped clamping frames 4d are fixedly arranged on the two sides of the guide frame 4e, the top of the inner side of each C-shaped clamping frame 4d is contacted with the top of the second square sliding tube 6b, the bottom of the inner side of each C-shaped clamping frame 4d is contacted with the bottom of the second square sliding tube 6b, the two heightening plates 4C are fixedly arranged on the tops of the two C-shaped clamping frames 4d, the fixed plate 4b is fixedly arranged on the tops of the two heightening plates 4C, the cylinder 4a is fixedly arranged on the top of the fixed plate 4b, the output end of the cylinder 4a passes, the guide frame 4e is provided with a sliding hole for the pressure applying column 4f to slide, the pressure applying column 4f is positioned in the sliding hole, and the bottom of the pressure applying column 4f passes through the sliding hole and is fixedly connected with the friction pad 4 h. When the pressure mechanism 4 is required to apply pressure to the top of the simulation frame 2, a worker controls the cylinder 4a to move through the controller, so that the cylinder 4a drives the pressure applying column 4f to move, so that the pressure applying column 4f drives the friction pad 4h to move, so that the friction pad 4h applies pressure to the top of the simulation frame 2, and the cylinder 4a cannot move in the working process of the cylinder 4a through the friction force between the friction pad 4h and the simulation frame 2, and when the position of the pressure mechanism 4 is required to be adjusted, the cylinder 4a is pushed, so that the C-shaped clamping frame 4d slides along the second square sliding pipe 6 b.

Every deformation amount detection mechanism 3 all includes electronic slip table 3a, CCD camera 3c and high adjustment mechanism 3d, and high adjustment mechanism 3d fixed mounting is on connecting plate 6c, and electronic slip table 3a fixed mounting is at high adjustment mechanism 3 d's top, and CCD camera 3c fixed mounting is on electronic slip table 3 a's slide, and electronic slip table 3a and CCD camera 3c all are connected with the controller electricity. The worker controls the CCD camera 3c of the electric sliding table 3a to work through the controller, so that the electric sliding table 3a drives the CCD camera 3c to move left and right, so as to record the appearance of one side of the simulation frame 2, the appearances of four sides of the simulation frame 2 are recorded through the four deformation quantity detection mechanisms 3, the original appearance of the simulation frame 2 is transmitted to the controller in an analog-digital mode of a digital signal, the controller transmits the signal to the intelligent device, the intelligent device carries out digital processing on the signal, so as to form a linear image, the pressing mechanism 4 and the tension testing mechanism 7 work, so that the deformation quantity is generated on the simulation frame 2, meanwhile, the electric sliding table 3a drives the CCD camera 3c to move left and right, and the CCD camera 3c transmits the change condition of the simulation frame 2 to the intelligent device through the controller in real time, analysis is performed by means of a smart device, which determines the amount of deformation generated by the simulation framework 2 as a function of time.

The height adjusting mechanism 3d comprises a top plate 3d1, a fixing plate 3d2 adjusting screw 3d4, two second linear bearings 3d3 and a second guide post 3d5, the fixing plate 3d2 is fixedly mounted on a connecting plate 6c, the top plate 3d1 is located right above the second linear bearings 3d3, the two second linear bearings 3d3 are fixedly mounted on a fixing plate 3d2, the top end of each second guide post 3d5 penetrates through the second linear bearing 3d3 and is fixedly connected with the top plate 3d1, the electric sliding table 3a is fixedly mounted on the top of the top plate 3d1, a threaded hole meshed with the adjusting screw 3d4 is formed in the fixing plate 3d2, the adjusting screw 3d4 is mounted on the fixing plate 3d2, and the top of the adjusting screw 3d4 abuts against the bottom of the top plate 3d 1. When the height of the CCD camera 3c needs to be adjusted, the adjusting screw 3d4 is twisted, the adjusting screw 3d4 is meshed with the fixing plate 3d2, the top of the adjusting screw 3d4 jacks up the top plate 3d1, or the adjusting screw 3d4 moves downwards, the top plate 3d1 moves downwards, the height of the CCD camera 3c is adjusted, and the guiding effect is achieved on the up-and-down movement of the top plate 3d1 through the second guide pillar 3d5 and the second linear bearing 3d 3.

Every pulling force accredited testing organization 7 all includes guide rail 7b, two baffle 7c, a plurality of guide seat 7a and tensile subassembly 7d, and guide rail 7b fixed mounting is on connecting plate 6c, and two baffle 7c fixed mounting are on connecting plate 6c, and two baffle 7c are located guide rail 7 b's both sides, and a plurality of guide seat 7a installs on guide rail 7b, and a plurality of tensile subassembly 7d installs respectively on a plurality of guide seat 7 a. Prevent that guide holder 7a from breaking away from out from guide rail 7b through two barrier plates 7c, when the fender of needs test simulation frame 2 draws intensity, through removing tensile subassembly 7d, make tensile subassembly 7d drive guide holder 7a and remove along guide rail 7b, and then make tensile subassembly 7d remove corresponding position, corresponding position connection on rethread tensile subassembly 7d and the simulation frame 2, the workman controls tensile subassembly 7d through the controller again and works, and then make tensile subassembly 7d exert the pulling force on to simulation frame 2.

Each tension assembly 7d comprises a base plate 7d1, a speed reducer 7d2, a driving motor 7d3, a steel rope 7d4, a tension meter 7d5, a winding wheel 7d6, a winding roller 7d7 and two roller holders 7d8, the base plate 7d1 is fixedly mounted on the guide holder 7a, the two roller holders 7d8 are fixedly mounted on the base plate 7d8, the winding roller 7d8 is mounted on the two roller holders 7d8, the winding wheel 7d8 is mounted on the winding roller 7d8, the winding wheel 7d8 is located between the two roller holders 7d8, two sides of the winding wheel 7d8 are in contact with the inner sides of the two roller holders 7d8, one end of the steel rope 7d8 is fixedly mounted on the winding wheel 7d8, the steel rope 7d8 is wound on the winding wheel 7d8, and the other end of the steel rope 7d8 is fixed on the simulation roller holder 7d 362, the tension meter 7d8 is mounted on the steel rope 7d8, the speed reducer is fixedly mounted on the base plate 8 and the speed reducer 7d8, the output end of the speed reducer 7d2 is fixedly connected with the take-up roll 7d7 through a coupler. The worker controls the driving motor 7d3 to move through the controller, so that the driving motor 7d3 drives the guide seat 7a2 to move, the speed reducer 7d2 drives the winding wheel 7d6 to move, the winding wheel 7d6 winds the steel rope 7d4, the steel rope 7d4 pulls the simulation frame 2, so that the tension value is displayed on the tension meter 7d5, a wireless transmission module is arranged in the tension meter 7d5, so that the tension meter 7d5 transmits the numerical value to the controller through the wireless transmission module, when the numerical value is transmitted to the controller, the controller transmits the numerical value to the intelligent device, when the numerical value is equal to a preset numerical value, the intelligent device transmits a signal to the controller, the controller controls the driving motor 7d3 to keep rotating force, so that the numerical value on the tension meter 7d5 is not changed, and further changes along with time to simulate the deformation amount generated by the frame 2, when the value of the tension meter 7d5 is decreased, the driving motor 7d3 increases the rotation force, so that the tension of the steel rope 7d4 on the simulation frame 2 is increased.

A working method of a building cement uniform smearing device is characterized in that,

s1: fixing the simulation frame;

firstly, a worker places the simulation frame 2 in the accommodating box body 8, the worker moves the two inserting plates 1b to enable the inner walls of the two inserting plates 1b to be in contact with the outer walls of the two sides of the simulation frame 2, then the two clamping strip plates 1a are clamped on the two inserting plates 1b, the inner walls of the two clamping strip plates 1a are in contact with the outer walls of the other two sides of the simulation frame 2, and then the simulation frame 2 is fixed;

s2: inputting an initial shape of the simulation frame;

a worker controls a CCD camera 3c of the electric sliding table 3a to work through the controller, so that the electric sliding table 3a drives the CCD camera 3c to move left and right, the appearance of one side of the simulation frame 2 is recorded, the appearances of four sides of the simulation frame 2 are recorded through the four deformation quantity detection mechanisms 3, the original appearance of the simulation frame 2 is transmitted to the controller in an analog-digital mode of a digital signal, the controller transmits the signal to the intelligent equipment, and the intelligent equipment carries out digital processing on the signal, so that a linear image is formed;

s3: adjusting the pressing position;

when the position of the pressing mechanism 4 needs to be adjusted, the position of one side of the pressing mechanism 4 is adjusted by pushing the second square sliding tube 6b along the length direction of the first square sliding tube 6a, the position of the other side of the pressing mechanism 4 is adjusted by pushing the pressing mechanism 4 to slide along the second square sliding tube 6b, and the position adjustment of the pressing mechanism 4 is completed,

s4: the top of the simulation frame is pressed, and a pressing mechanism is used for positioning;

the worker controls the air cylinder 4a to move through the controller, so that the air cylinder 4a drives the pressure application column 4f to move, so that the pressing column 4f drives the friction pad 4h to move, the friction pad 4h applies pressure to the top of the simulation frame 2, and the pressing mechanism 4 drives the second square sliding tube 6b to move upwards, so that the friction plate 6d is abutted against the upper surface of the inner side of the first square sliding tube 6a, and the second square sliding tube 6b is not slid with the first square sliding tube 6a by the action of friction force, and is abutted against the top of the simulation frame 2 by the pressing mechanism 4, through the friction force between the friction pad 4h and the simulation frame 2, the air cylinder 4a cannot move in the working process of the air cylinder 4a, and then the positioning of the pressure applying mechanism 4 and the top pressure application of the simulation frame 2 are completed;

s5: applying pressure to simulate the change analysis of the frame;

in the process of pressing by the pressing mechanism, the deformation quantity detection mechanism 3 also continues to work, so that the change condition of the simulation frame 2 is transmitted to the intelligent equipment in real time through the controller, and is analyzed through the intelligent equipment, so that the deformation quantity generated by the simulation frame 2 along with the change of time is determined;

s6: positioning a tension detection mechanism;

when the blocking tensile strength of the simulation frame 2 needs to be tested, the stretching assembly 7d is moved to drive the guide seat 7a to move along the guide rail 7b by the stretching assembly 7d, so that the stretching assembly 7d moves to a corresponding position, and then the stretching assembly 7d is connected with the corresponding position on the simulation frame 2, a worker controls the driving motor 7d3 to move through the controller, so that the driving motor 7d3 drives the guide seat 7a2 to move, so that the speed reducer 7d2 drives the winding wheel 7d6 to move, so that the winding wheel 7d6 winds the steel rope 7d4, so that the steel rope 7d4 pulls the simulation frame 2, and the positioning of the tension detection mechanism is completed through the constraint of tension;

s7: tension feedback;

the tension meter 7d5 displays a tension value, a wireless transmission module is arranged in the tension meter 7d5, the tension meter 7d5 transmits a numerical value to the controller through the wireless transmission module, when the numerical value is transmitted to the controller, the controller transmits the numerical value to the intelligent equipment, when the numerical value is equal to a preset numerical value, the intelligent equipment transmits a signal to the controller, the controller controls the driving motor 7d3 to keep rotating force, the numerical value on the tension meter 7d5 is not changed, deformation generated by the simulation frame 2 along with time change is further determined, when the numerical value on the tension meter 7d5 is reduced, the driving motor 7d3 increases the rotating force, and further the tension of the steel rope 7d4 on the simulation frame 2 is increased;

s8: applying tension, and simulating frame change analysis;

in the working process of the tension testing mechanism 7, the deformation quantity detecting mechanism 3 also continues to work, so that the change condition of the simulation frame 2 is transmitted to the intelligent device in real time through the controller, and is analyzed through the intelligent device, and the deformation quantity generated by the simulation frame 2 along with the change of time is further determined.

The working principle is as follows: firstly, a worker places the simulation frame 2 in the accommodating box body 8, the worker moves the two plug boards 1b to enable the inner walls of the two plug boards 1b to be in contact with the outer walls of two sides of the simulation frame 2, then the two clamping strip boards 1a are clamped on the two plug boards 1b, the inner walls of the two clamping strip boards 1a are in contact with the outer walls of the other two sides of the simulation frame 2, and then the simulation frame 2 is fixed, the worker controls the CCD camera 3c of the electric sliding table 3a to work through the controller, so that the electric sliding table 3a drives the CCD camera 3c to move left and right, and further the appearance of one side of the simulation frame 2 is recorded, the appearance of four sides of the simulation frame 2 is recorded through the four deformation amount detection mechanisms 3, then the original appearance of the simulation frame 2 is transmitted to the controller through the analog-to-digital converter of a digital signal, and the controller transmits the signal to the, the intelligent device then carries out digital processing on the signal to form a linear image, when the position of the pressure mechanism 4 needs to be adjusted, the second square sliding tube 6b is pushed along the length direction of the first square sliding tube 6a, the position of one side direction of the pressure mechanism 4 is adjusted, the pressure mechanism 4 is pushed to slide along the second square sliding tube 6b, the position of the other side direction of the pressure mechanism 4 is adjusted, after the position of the pressure mechanism 4 is adjusted, a worker controls the air cylinder 4a to move through the controller, the air cylinder 4a drives the pressure applying column 4f to move, the pressure applying column 4f drives the friction pad 4h to move, the friction pad 4h applies pressure to the top of the simulation frame 2, the pressure mechanism 4 drives the second square sliding tube 6b to move upwards, and the friction plate 6d is abutted against the upper surface of the inner side of the first square sliding tube 6a, and then the second square sliding pipe 6b and the first square sliding pipe 6a will not slide each other by the action of friction force, and the top of the simulation frame 2 is abutted by the pressing mechanism 4, the cylinder 4a will not move in the working process of the cylinder 4a by the friction force between the friction pad 4h and the simulation frame 2, and then the positioning of the pressing mechanism 4 and the top pressing of the simulation frame 2 are completed, and in this process, the deformation amount detection mechanism 3 is working continuously, and then the change situation of the simulation frame 2 is transmitted to the intelligent device in real time by the controller, and analyzed by the intelligent device, and further the deformation amount generated by the simulation frame 2 along with the change of time is determined, when the blocking and pulling strength of the simulation frame 2 needs to be tested, the stretching component 7d is moved to make the stretching component 7d drive the guide seat 7a to move along the guide rail 7b, further, the stretching assembly 7d is moved to a corresponding position, the stretching assembly 7d is connected with a corresponding position on the simulation frame 2 through the stretching assembly 7d, a worker controls the driving motor 7d3 to move through the controller, further, the driving motor 7d3 drives the guide seat 7a2 to move, further, the speed reducer 7d2 drives the winding wheel 7d6 to move, further, the winding wheel 7d6 winds the steel rope 7d4, further, the steel rope 7d4 pulls the simulation frame 2, further, the positioning of the tension detection mechanism is completed through the constraint of tension, the tension value is displayed on the tension meter 7d5, a wireless transmission module is arranged in the tension meter 7d5, further, the tension meter 7d5 transmits the numerical value to the controller through the wireless transmission module, when the numerical value is transmitted to the controller, the controller transmits the numerical value to the intelligent device, when the numerical value is equal to the preset numerical value, the intelligent device transmits a signal to the controller, the controller controls the driving motor 7d3 to keep rotating force, so that the value on the tension meter 7d5 is not changed, the deformation quantity generated by the simulation frame 2 along with the change of time is further determined, when the value on the tension meter 7d5 is reduced, the driving motor 7d3 increases the rotating force, the tensile force of the steel rope 7d4 on the simulation frame 2 is further increased, in the working process of the tension testing mechanism 7, the deformation quantity detecting mechanism 3 also continues to work, the change condition of the simulation frame 2 is further transmitted to the intelligent equipment through the controller in real time, analysis is carried out through the intelligent equipment, the deformation quantity generated by the simulation frame 2 along with the change of time is further determined, and the detection of the stability of the steel structure building girder is further completed.

Claims

1. The building cement uniform smearing equipment is characterized by comprising a positioning clamping mechanism (1), a simulation frame (2), a containing box body (8), a position adjusting frame (6), four deformation quantity detecting mechanisms (3), a plurality of pressure applying mechanisms (4), two pulling mechanisms (5) and a tension testing mechanism (7), wherein the two pulling mechanisms (5) are respectively and fixedly arranged on the inner walls of the two sides of the containing box body (8), the two pulling mechanisms (5) are symmetrically arranged, the simulation frame (2) is arranged at the bottom of the inner side of the containing box body (8), the positioning clamping mechanism (1) for clamping the simulation frame (2) is fixedly arranged at the bottom of the inner side of the containing box body (8), the position adjusting frame (6) is fixedly arranged at the bottom of the two pulling mechanisms (5), and the pressure applying mechanisms (4) can be slidably arranged on the position adjusting frame (6), four deformation quantity detection mechanisms (3) are respectively positioned on four sides of the bottom of the position adjusting frame (6), the four deformation quantity detection mechanisms (3) are fixedly connected with the position adjusting frame (6), the two tension testing mechanisms (7) are fixedly installed on the position adjusting frame (6), and the two tension testing mechanisms (7) are symmetrically arranged with each other.

2. The uniform building cement smearing equipment as claimed in claim 1, wherein the positioning and clamping mechanism (1) comprises a clamping plate (1 c), two guide plates (1 d), a clamping plate (1 a) and an inserting plate (1 b), the two guide plates (1 d) are respectively and fixedly arranged at the same end of the two inserting plates (1 b), one side of each guide plate (1 d) is attached to the inner wall of the accommodating box body (8), the bottom of each guide plate (1 d) is attached to the inner bottom of the accommodating box body (8), the clamping plate (1 c) is clamped on the two guide plates (1 d), the clamping plate (1 c) is fixedly connected with the inner wall of the accommodating box body (8), a guide chute (1 c 1) for the guide plate (1 d) to slide is formed in the clamping plate (1 c), a plurality of first inserting holes (1 b 1) are formed in the top of each inserting plate (1 b), the length direction evenly distributed of a plurality of first socket (1 b 1) along picture peg (1 b), a plurality of second socket (1 a 1) have all been seted up to the bottom of every card slat (1 a), a plurality of second socket (1 a 1) are along the length direction evenly distributed of card slat (1 a), two second sockets (1 a 1) of every card slat (1 a) joint respectively in two first sockets (1 b 1), and the both sides outer wall contact of the inner wall of two card slats (1 a) and simulation frame (2), the both sides outer wall contact of the inner wall of two picture pegs (1 b) and simulation frame (2).

3. The uniform building cement smearing equipment as claimed in claim 2, wherein the position adjusting frame (6) comprises two first square sliding tubes (6 a), two second square sliding tubes (6 b) and connecting plates (6 c), the two first square sliding tubes (6 a) are symmetrically arranged, the outer sides of the two first square sliding tubes (6 a) are attached to the inner walls of two sides of the containing box body (8), the two connecting plates (6 c) are located between the two first square sliding tubes (6 a), two ends of each connecting plate (6 c) are fixedly connected to the inner walls of the two first square sliding tubes (6 a) respectively, the outer walls of the two connecting plates (6 c) are attached to the inner walls of the other two sides of the containing box body (8), the two second square sliding tubes (6 b) are located between the two first square sliding tubes (6 a), and two ends of each second square sliding tube (6 b) are inserted into the two first square sliding tubes (6 a) respectively, the both ends of every square slide tube of second (6 b) and the laminating of the both sides outer wall that holds box body (8), the holding tank has all been seted up at the both ends top of every square slide tube of second (6 b), every holding tank internal fixation is provided with friction plate (6 d), and the inboard upper surface of first square slide tube (6 a) is provided with the friction strip, two first square slide tubes (6 a) fixed mounting respectively are in the bottom of two mechanisms (5) that rise that draw, a plurality of biasing means (4) can slide the setting respectively on two square slide tubes of second (6 b).

4. The uniform building cement smearing equipment as claimed in claim 3, wherein each lifting mechanism (5) comprises an oil cylinder (5 a), two first guide columns (5 b), a mounting plate (5 c) and a first linear bearing (5 d), the oil cylinder (5 a) is fixedly mounted on one side inner wall of the containing box body (8) through a support frame, the output end of the oil cylinder (5 a) is fixedly connected with the top of the first square sliding pipe (6 a), the two first guide columns (5 b) are positioned on two sides of the oil cylinder (5 a), the bottoms of the two first guide columns (5 b) are fixedly connected with the top of the first square sliding pipe (6 a), the two mounting plates (5 c) are fixedly mounted on the inner wall of the containing box body (8), the two first linear bearings (5 d) are respectively mounted on the two mounting plates (5 c), the top of each first guide column (5 b) passes through the first linear bearing (5 d), and the two first guide columns (5 b) are connected with the two first linear bearings (5 d) in a sliding way.

5. The building cement uniform smearing equipment as claimed in claim 4, wherein each pressing mechanism (4) comprises a cylinder (4 a), a fixed plate (4 b), a guide frame (4 e), a pressing column (4 f), a friction pad (4 h), two heightening plates (4C) and C-shaped clamping frames (4 d), the guide frame (4 e) is inserted in the second square sliding pipe (6 b), the outer walls of the two sides of the guide frame (4 e) are attached to the inner walls of the two sides of the second square sliding pipe (6 b), the two C-shaped clamping frames (4 d) are fixedly installed on the two sides of the guide frame (4 e), the top of the inner side of each C-shaped clamping frame (4 d) is in contact with the top of the second square sliding pipe (6 b), the bottom of the inner side of each C-shaped clamping frame (4 d) is in contact with the bottom of the second square sliding pipe (6 b), and the two heightening plates (4C) are fixedly installed on the top of the two C-shaped clamping frames (4 d), and fixed plate (4 b) fixed mounting increases the top of board (4 c) at two, cylinder (4 a) fixed mounting increases the top of board (4 b), the output of cylinder (4 a) passes fixed plate (4 b) and exerts pressure post (4 f) fixed connection, offer on guide frame (4 e) and supply to exert pressure post (4 f) gliding slide opening, it is located the slide opening to exert pressure post (4 f), and the bottom of exerting pressure post (4 f) passes slide opening and friction pad (4 h) fixed connection.

6. The uniform building cement smearing equipment as claimed in claim 5, wherein each deformation quantity detecting mechanism (3) comprises an electric sliding table (3 a), a CCD camera (3 c) and a height adjusting mechanism (3 d), the height adjusting mechanism (3 d) is fixedly installed on a connecting plate (6 c), the electric sliding table (3 a) is fixedly installed at the top of the height adjusting mechanism (3 d), the CCD camera (3 c) is fixedly installed on a sliding seat of the electric sliding table (3 a), and the electric sliding table (3 a) and the CCD camera (3 c) are electrically connected with a controller.

7. The building cement uniform smearing equipment as claimed in claim 6, wherein the height adjusting mechanism (3 d) comprises a top plate (3 d 1), a fixed plate (3 d 2) adjusting screw (3 d 4), two second linear bearings (3 d 3) and second guide pillars (3 d 5), the fixed plate (3 d 2) is fixedly installed on the connecting plate (6 c), the top plate (3 d 1) is located right above the second linear bearings (3 d 3), the two second linear bearings (3 d 3) are fixedly installed on the fixed plate (3 d 2), the top end of each second guide pillar (3 d 5) passes through the second linear bearing (3 d 3) and is fixedly connected with the top plate (3 d 1), the electric sliding table (3 a) is fixedly installed on the top of the top plate (3 d 1), a threaded hole meshed with the adjusting screw (3 d 4) is formed on the fixed plate (3 d 2), and the adjusting screw (3 d 4) is installed on the fixed plate (3 d 2), and the top of the adjusting screw (3 d 4) is abutted against the bottom of the top plate (3 d 1).

8. The building cement uniform smearing equipment as claimed in claim 7, wherein each tension testing mechanism (7) comprises a guide rail (7 b), two blocking plates (7 c), a plurality of guide seats (7 a) and a stretching assembly (7 d), the guide rail (7 b) is fixedly installed on the connecting plate (6 c), the two blocking plates (7 c) are located on two sides of the guide rail (7 b), the plurality of guide seats (7 a) are installed on the guide rail (7 b), and the plurality of stretching assemblies (7 d) are respectively installed on the plurality of guide seats (7 a).

9. An apparatus for evenly applying building cement according to claim 8, wherein each stretching assembly (7 d) comprises a bottom plate (7 d 1), a speed reducer (7 d 2), a driving motor (7 d 3), steel ropes (7 d 4), a tension meter (7 d 5), a winding wheel (7 d 6), a winding roller (7 d 7) and two roller seats (7 d 8), the bottom plate (7 d 1) is fixedly installed on the guide seat (7 a), the two roller seats (7 d 8) are fixedly installed on the bottom plate (7 d 1), the winding roller (7 d 7) is installed on the two roller seats (7 d 8), the winding wheel (7 d 6) is installed on the winding roller (7 d 7), the winding wheel (7 d 6) is located between the two roller seats (7 d 8), two sides of the winding wheel (7 d 6) are in contact with the inner sides of the two roller seats (7 d 8), one end of the steel rope (7 d 4) is fixedly installed on the winding wheel (6), and the steel rope (7 d 4) is wound on the winding wheel (7 d 6), the other end of the steel rope (7 d 4) is fixed on the simulation frame (2), the tension meter (7 d 5) is installed on the steel rope (7 d 4), the speed reducer (7 d 2) is fixedly installed on the bottom plate (7 d 1) through a supporting seat, the driving motor (7 d 3) is fixedly installed on the speed reducer (7 d 2), and the output end of the speed reducer (7 d 2) is fixedly connected with the winding roller (7 d 7) through a coupler.