CN112284665A

CN112284665A - Be used for building steel structure model anti-seismic test detection device

Info

Publication number: CN112284665A
Application number: CN202011137401.3A
Authority: CN
Inventors: 王倩颖; 倪松远
Original assignee: Qingdao Agricultural University
Current assignee: Qingdao Agricultural University
Priority date: 2020-10-22
Filing date: 2020-10-22
Publication date: 2021-01-29

Abstract

The invention discloses a detection device for an earthquake resistance test of a building steel structure model, which comprises a detection table, a moving groove and a mounting plate, wherein a support frame is arranged at the lower end of the detection table, a motor is arranged on the support frame and is connected with a rotating shaft, the upper end of the driving shaft penetrates through an opening groove to be connected with a longitudinal wave test mechanism, the moving groove is arranged on the upper end surface of the detection table and is arranged on the front side and the rear side of the opening groove, a second moving wheel is arranged in the moving groove, the mounting plate is arranged at the upper end of the longitudinal wave test mechanism through a limiting sliding groove, a first screw rod penetrates through the mounting plate, a steel structure frame model is arranged at the upper end of the mounting plate, and a second screw rod penetrates through the steel structure. This be used for building steel structure model anti-seismic test detection device, through the setting of longitudinal wave test mechanism and motor, pivot, crank connection structure and transmission shaft, can accomplish the test testing result of the longitudinal wave and the transverse wave that the earthquake brought on equipment.

Description

Be used for building steel structure model anti-seismic test detection device

Technical Field

The invention relates to the technical field of building steel structures, in particular to a detection device for a building steel structure model earthquake resistance test.

Background

Building steel construction usually can test building steel structure model when putting into application and detect, thereby whether the wholeness ability of inferring building steel construction is practical, building steel construction's test detection is categorised a lot, mainly including steel construction bearing capacity test, shock resistance test and fire prevention coating performance test etc, wherein building steel construction shock resistance test, mainly accomplish experimental detection through vibration testing machine, but the longitudinal wave or the transverse wave vibrations that the earthquake brought can only be imitated to the vibration testing machine of big majority, if need reachd longitudinal wave and transverse wave vibrations test data, then need accomplish on two different equipment, it is comparatively troublesome.

Disclosure of Invention

The invention aims to provide a device for detecting an earthquake-resistant test of a building steel structure model, which aims to solve the problem that the existing building steel structure earthquake-resistant test in the background art is troublesome because the test detection is mainly completed by a vibration testing machine, but most vibration testing machines can only imitate the longitudinal wave or transverse wave vibration caused by an earthquake, and if the longitudinal wave and transverse wave vibration test data need to be obtained, the longitudinal wave and transverse wave vibration test data need to be completed on two different devices.

In order to achieve the purpose, the invention provides the following technical scheme: a detection device for a building steel structure model earthquake resistance test comprises a detection platform, a movable groove and a mounting plate,

the device comprises a detection table, a support frame is arranged at the lower end of the detection table, a first moving wheel is arranged at the lower end of the support frame, bearing capacity detection mechanisms are arranged on the front side and the rear side of the support frame, a motor is arranged on the support frame and connected with a rotating shaft, the rotating shaft is connected with a crank connecting mechanism, one end, far away from the rotating shaft, of the crank connecting mechanism is rotatably connected onto a transmission shaft, the upper end of the transmission shaft penetrates through a through groove to be connected with a longitudinal wave testing mechanism, and the through groove is formed in the detection table;

the moving grooves are formed in the upper end face of the detection table and are formed in the front side and the rear side of the through hole groove, second moving wheels are arranged in the moving grooves and are arranged at the lower end of the longitudinal wave testing mechanism, and meanwhile, a limiting sliding groove is formed in the upper end of the longitudinal wave testing mechanism;

the mounting panel, the mounting panel passes through spacing spout setting in the longitudinal wave test mechanism upper end, and runs through on the mounting panel and be provided with first screw rod, the mounting panel upper end is provided with steel structure frame model, and runs through on the steel structure frame model and be provided with the second screw rod.

Preferably, the support frame is including connecting plate, runner, lead screw and antiskid to the board, and the left and right sides of support frame all is provided with the connecting plate, the connecting plate upper end is rotated and is connected with the runner, and runs through threaded connection in the runner and have the lead screw, and the lead screw lower extreme is connected with the antiskid to the board simultaneously.

Preferably, the first moving wheels are arranged in two groups, and the first moving wheels are symmetrically arranged about the center line of the support frame.

Preferably, the bearing capacity detection mechanism comprises an installation frame, a first hydraulic telescopic rod and an extrusion plate, the installation frame is provided with the first hydraulic telescopic rod in a penetrating mode, and the inner end of the first hydraulic telescopic rod is connected with the extrusion plate.

Preferably, the motor, the rotating shaft and the crank connecting mechanism form a rotating mechanism.

Preferably, longitudinal wave test mechanism is including lower carriage, second hydraulic telescoping rod, connection frame, third hydraulic telescoping rod and go up the carriage, and the carriage upper end is provided with the second hydraulic telescoping rod down, second hydraulic telescoping rod upper end is rotated with the connection frame lower extreme and is connected, and the one end that the second hydraulic telescoping rod was kept away from to the connection frame rotates and connects under on the carriage, the last rotation of connection frame is connected with third hydraulic telescoping rod, and third hydraulic telescoping rod upper end rotates and is connected with and connects the carriage, go up and connect the carriage and keep away from third hydraulic telescoping rod one end and rotate and connect on the connection frame, and third hydraulic telescoping rod sets up in second hydraulic telescoping rod front side.

Preferably, the second moving wheels are symmetrically arranged at the lower end of the longitudinal wave testing mechanism, two groups of second moving wheels are arranged, and each group of second moving wheels corresponds to the moving groove.

Preferably, the first screw rod penetrates through the mounting plate and is in threaded connection with the longitudinal wave testing mechanism, and the mounting plate is in sliding connection with the longitudinal wave testing mechanism through the limiting sliding groove.

Preferably, the lower end of the second screw penetrates through the steel structure frame model and is connected to the mounting plate in a threaded mode.

Compared with the prior art, the invention has the beneficial effects that: the earthquake-resistant test detection device for the building steel structure model,

(1) the position of the detection table is conveniently moved and placed under the action of the first moving wheel, the screw rod drives the anti-skidding abutting plate to descend to abut against the ground by rotating the rotating wheel, the supporting stability of the detection table is enhanced, the detection table is movably placed at the bearing capacity detection mechanism through the first moving wheel, the bearing capacity detection test is conveniently carried out, an additional supporting mechanism is not needed for supporting a building steel structure for the bearing capacity detection test, and the versatility of the detection table is improved;

(2) the device is provided with a motor, a rotating shaft, a crank connecting mechanism and a transmission shaft, and under the action of the motor, the steel structure frame model can make transverse reciprocating motion on a detection table through the rotating shaft, the crank connecting mechanism and the transmission shaft, so that the transverse wave vibration test of the steel structure frame model is detected;

(3) the longitudinal wave test mechanism drives the connecting frame to move under the action of the second hydraulic telescopic rod, and the third hydraulic telescopic rod drives the upper connecting frame to move under the action of the third hydraulic telescopic rod, so that the longitudinal wave vibration test detection of the steel structure frame model is realized;

(4) the steel structure frame model is fixed on the mounting panel through the installation of second screw rod, passes through spacing spout sliding connection with the mounting panel on last grafting frame, and the rethread first screw rod carries out spacing fixed to the mounting panel, makes things convenient for steel structure frame model to change and install.

Drawings

FIG. 1 is a front view of the supporting frame of the present invention;

FIG. 2 is a schematic structural diagram of a steel structural frame model and a bearing capacity detection mechanism according to the present invention;

FIG. 3 is a schematic left side view of the longitudinal wave test mechanism according to the present invention;

FIG. 4 is a rear view of the longitudinal wave testing mechanism of the present invention;

FIG. 5 is an enlarged view of the structure at A in FIG. 2 according to the present invention;

FIG. 6 is a schematic top view of the inspection table of the present invention.

In the figure: 1. the detection table comprises a detection table body, 2, a support frame, 201, a connecting plate, 202, a rotating wheel, 203, a screw rod, 204, an anti-skidding resisting plate, 3, a first movable wheel, 4, a bearing capacity detection mechanism, 401, a mounting frame, 402, a first hydraulic telescopic rod, 403, an extrusion plate, 5, a motor, 6, a rotating shaft, 7, a crank connecting mechanism, 8, a transmission shaft, 9, an opening groove, 10, a longitudinal wave test mechanism, 1001, a lower mounting frame, 1002, a second hydraulic telescopic rod, 1003, a connecting frame, 1004, a third hydraulic telescopic rod, 1005, an upper mounting frame, 11, a second movable wheel, 12, a movable groove, 13, a limiting sliding groove, 14, a mounting plate, 15, a first screw rod, 16, a steel structure frame model, 17 and a second screw rod.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1-6, the present invention provides a technical solution: a detection device for earthquake resistance tests of building steel structure models is disclosed, as shown in figures 1 and 2, a support frame 2 is arranged at the lower end of a detection platform 1, a first moving wheel 3 is arranged at the lower end of the support frame 2, bearing capacity detection mechanisms 4 are arranged on the front side and the rear side of the support frame 2, the support frame 2 comprises a connecting plate 201, a rotating wheel 202, a screw rod 203 and an anti-skid resisting plate 204, the connecting plate 201 is arranged on the left side and the right side of the support frame 2, the rotating wheel 202 is rotatably connected to the upper end of the connecting plate 201, the screw rod 203 is connected with the rotating wheel 202 in a penetrating and threaded manner, the lower end of the screw rod 203 is connected with the anti-skid resisting plate 204, the screw rod 203 pushes the anti-skid resisting plate 204 downwards to be abutted against the ground by rotating the rotating wheel 202, the placing stability of the device is enhanced, two sets of first moving wheels 3 are arranged, the first moving, bearing capacity detection mechanism 4 is including mounting bracket 401, first hydraulic telescoping rod 402 and stripper plate 403, and run through on the mounting bracket 401 and be provided with first hydraulic telescoping rod 402, first hydraulic telescoping rod 402 inner is connected with stripper plate 403 simultaneously, promote stripper plate 403 to extrude steel structure frame model 16 under the effect of the first hydraulic telescoping rod 402 in both sides, to the experimental detection of steel structure frame model 16 bearing capacity, be provided with motor 5 on the support frame 2, and motor 5 is connected with pivot 6, motor 5, pivot 6 and crank coupling mechanism 7 constitute slewing mechanism, motor 5 is through pivot 6, crank coupling mechanism 7 drives transmission shaft 8 and removes about in opening groove 9, pivot 6 is connected with crank coupling mechanism 7, and crank coupling mechanism 7 keeps away from the one end rotation connection of pivot 6 on transmission shaft 8.

As shown in fig. 1, 2, 3, 4 and 6, the upper end of the transmission shaft 8 penetrates through the opening slot 9 to be connected with the longitudinal wave testing mechanism 10, and the opening slot 9 is opened on the inspection table 1, the longitudinal wave testing mechanism 10 comprises a lower bracket 1001, a second hydraulic telescopic rod 1002, a connecting frame 1003, a third hydraulic telescopic rod 1004 and an upper bracket 1005, the upper end of the lower bracket 1001 is provided with the second hydraulic telescopic rod 1002, the upper end of the second hydraulic telescopic rod 1002 is rotatably connected with the lower end of the connecting frame 1003, one end of the connecting frame 1003 far from the second hydraulic telescopic rod 1002 is rotatably connected with the lower bracket 1001, the connecting frame 1003 is rotatably connected with the third hydraulic telescopic rod 1004, the upper end of the third hydraulic telescopic rod 1004 is rotatably connected with the upper bracket 1005, one end of the upper bracket 1005 far from the third hydraulic telescopic rod 1004 is rotatably connected with the connecting frame 1003, and the third hydraulic telescopic rod 1004 is arranged at the front side of the second hydraulic telescopic rod 1002, drive connecting frame 1003 and remove under the effect of second hydraulic telescoping rod 1002, third hydraulic telescoping rod 1004 drives down and connects a 1005 to remove, thereby reach and detect 16 longitudinal wave vibration tests of steel structure frame model, shifting chute 12 sets up on examining test table 1 up end, and shifting chute 12 sets up both sides around through port groove 9, be provided with second movable wheel 11 in the shifting chute 12, and second movable wheel 11 sets up at the 10 lower extremes of longitudinal wave test mechanism, simultaneously the 10 upper ends of longitudinal wave test mechanism are provided with spacing spout 13, second movable wheel 11 symmetry sets up the lower extreme at longitudinal wave test mechanism 10, and second movable wheel 11 is provided with two sets ofly, simultaneously every group second movable wheel 11 is corresponding with shifting chute 12, second movable wheel 11 plays the steady supporting role to longitudinal wave test mechanism 10.

As shown in fig. 1, 2 and 5, the mounting plate 14 is disposed at the upper end of the longitudinal wave testing mechanism 10 through the limiting chute 13, and a first screw 15 is disposed on the mounting plate 14 in a penetrating manner, the first screw 15 penetrates the mounting plate 14 and is in threaded connection with the longitudinal wave testing mechanism 10, and the mounting plate 14 is in sliding connection with the longitudinal wave testing mechanism 10 through the limiting chute 13, the first screw 15 is detached to facilitate mounting and fixing of the mounting plate 14, the mounting plate 14 is mounted through the limiting chute 13 to enhance fixing stability, the upper end of the mounting plate 14 is disposed with a steel structure frame model 16, the steel structure frame model 16 is disposed on the steel structure frame model 16 in a penetrating manner, the lower end of the second screw 17 penetrates the steel structure frame model 16 and is in threaded connection with the mounting plate 14, the steel structure frame model 16 is fixedly mounted through the second screw 17, and the steel structure frame model 16 may not be mounted and fixed with the, fixing with concrete.

The working principle is as follows: when the device for the building steel structure model anti-seismic test detection is used, the device position can be moved and adjusted through the first moving wheel 3, the device is moved to the bearing capacity detection mechanism 4, the detection platform 1 and other structures can be used for not only the transverse wave and longitudinal wave vibration detection of the steel structure frame model 16, but also the bearing capacity test detection of the steel structure frame model 16, the power supply is switched on, the mounting plate 14 provided with the steel structure frame model 16 is slidably mounted on the upper connecting frame 1005 through the limiting chute 13 and is fixedly reinforced through the first screw 15, when the longitudinal wave vibration detection is carried out, the connecting frame 1005 is driven to move under the action of the second hydraulic telescopic rod 1002, the upper connecting frame 1005 is driven to move under the action of the third hydraulic telescopic rod 1004, so that the longitudinal wave vibration test detection of the steel structure frame model 16 is achieved, when the transverse wave vibration is detected, the motor 5 drives the rotating shaft 6 to rotate, the rotating shaft 6 drives the transmission shaft 8 to move left and right in the through hole groove 9, the transverse wave vibration test detection of the steel structure frame model 16 is achieved, the second moving wheel 11 plays a role in stably supporting the longitudinal wave test mechanism 10, the first hydraulic telescopic rods 402 on the two sides push the extrusion plates 403 to act on the steel structure frame model 16, the bearing capacity test of the steel structure frame model 16 is detected, when the steel structure frame model 16 needs to be replaced in the test detection, the first screw rod 15 is detached, the mounting plate 14 is pulled out from the limiting sliding groove 13, and the mounting plate is replaced.

The terms "central," "longitudinal," "lateral," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," and the like are used in the orientation or positional relationship indicated in the drawings for simplicity of description only and are not intended to indicate or imply that the referenced devices or elements must be in a particular orientation, constructed and operative in a particular orientation, and are not to be considered limiting of the claimed invention.

Although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that various changes in the embodiments and/or modifications of the invention can be made, and equivalents and modifications of some features of the invention can be made without departing from the spirit and scope of the invention.

Claims

1. The utility model provides a be used for building steel structure model earthquake test detection device, is including examining test table (1), shifting chute (12) and mounting panel (14), its characterized in that:

the device comprises a detection table (1), wherein a support frame (2) is arranged at the lower end of the detection table (1), a first movable wheel (3) is arranged at the lower end of the support frame (2), bearing capacity detection mechanisms (4) are arranged on the front side and the rear side of the support frame (2), a motor (5) is arranged on the support frame (2), the motor (5) is connected with a rotating shaft (6), the rotating shaft (6) is connected with a crank connection mechanism (7), one end, far away from the rotating shaft (6), of the crank connection mechanism (7) is rotatably connected onto a transmission shaft (8), the upper end of the transmission shaft (8) penetrates through a through hole groove (9) to be connected with a longitudinal wave test mechanism (10), and the through hole groove (9) is formed in the detection table (1);

the movable groove (12) is arranged on the upper end face of the detection table (1), the movable groove (12) is arranged on the front side and the rear side of the through hole groove (9), a second movable wheel (11) is arranged in the movable groove (12), the second movable wheel (11) is arranged at the lower end of the longitudinal wave test mechanism (10), and meanwhile, a limiting sliding groove (13) is arranged at the upper end of the longitudinal wave test mechanism (10);

mounting panel (14), mounting panel (14) set up in longitudinal wave test mechanism (10) upper end through spacing spout (13), and run through on mounting panel (14) and be provided with first screw rod (15), mounting panel (14) upper end is provided with steel structure frame model (16), and runs through on steel structure frame model (16) and be provided with second screw rod (17).

2. The device for detecting the earthquake-resistant test of the building steel structure model according to the claim 1 is characterized in that: the support frame (2) is including connecting plate (201), runner (202), lead screw (203) and anti-skidding support plate (204), and the left and right sides of support frame (2) all is provided with connecting plate (201), connecting plate (201) upper end is rotated and is connected with runner (202), and runs through threaded connection in runner (202) has lead screw (203), and lead screw (203) lower extreme is connected with anti-skidding support plate (204) simultaneously.

3. The device for detecting the earthquake-resistant test of the building steel structure model according to the claim 1 is characterized in that: the first moving wheels (3) are arranged in two groups, and the first moving wheels (3) are symmetrically arranged relative to the central line of the support frame (2).

4. The device for detecting the earthquake-resistant test of the building steel structure model according to the claim 1 is characterized in that: the bearing capacity detection mechanism (4) comprises an installation frame (401), a first hydraulic telescopic rod (402) and an extrusion plate (403), the first hydraulic telescopic rod (402) penetrates through the installation frame (401), and meanwhile the inner end of the first hydraulic telescopic rod (402) is connected with the extrusion plate (403).

5. The device for detecting the earthquake-resistant test of the building steel structure model according to the claim 1 is characterized in that: the motor (5), the rotating shaft (6) and the crank connecting mechanism (7) form a rotating mechanism.

6. The device for detecting the earthquake-resistant test of the building steel structure model according to the claim 1 is characterized in that: the longitudinal wave test mechanism (10) comprises a lower connecting frame (1001), a second hydraulic telescopic rod (1002), a connecting frame (1003), a third hydraulic telescopic rod (1004) and an upper connecting frame (1005), the upper end of the lower connecting frame (1001) is provided with a second hydraulic telescopic rod (1002), the upper end of the second hydraulic telescopic rod (1002) is rotatably connected with the lower end of the connecting frame (1003), and one end of the connecting frame (1003) far away from the second hydraulic telescopic rod (1002) is rotatably connected to the lower connecting frame (1001), the connecting frame (1003) is rotatably connected with a third hydraulic telescopic rod (1004), the upper end of the third hydraulic telescopic rod (1004) is rotatably connected with an upper connecting frame (1005), one end of the upper connecting frame (1005) far away from the third hydraulic telescopic rod (1004) is rotatably connected to the connecting frame (1003), and the third hydraulic telescopic rod (1004) is arranged at the front side of the second hydraulic telescopic rod (1002).

7. The device for detecting the earthquake-resistant test of the building steel structure model according to the claim 1 is characterized in that: the second moving wheels (11) are symmetrically arranged at the lower end of the longitudinal wave testing mechanism (10), two groups of second moving wheels (11) are arranged, and each group of second moving wheels (11) corresponds to the moving groove (12).

8. The device for detecting the earthquake-resistant test of the building steel structure model according to the claim 1 is characterized in that: first screw rod (15) run through mounting panel (14) threaded connection on longitudinal wave test mechanism (10), and mounting panel (14) are sliding connection through between spacing spout (13) and longitudinal wave test mechanism (10).

9. The device for detecting the earthquake-resistant test of the building steel structure model according to the claim 1 is characterized in that: the lower end of the second screw rod (17) penetrates through the steel structure frame model (16) and is connected to the mounting plate (14) in a threaded mode.