CN117129172B - Building structure shock resistance simulation detection device - Google Patents

Abstract

The invention relates to the technical field of detection devices, in particular to a building structure anti-seismic strength simulation detection device which comprises a support frame, simulation boards, placing tables and driving rods. The angle between the two simulation boards is adjustably set, the placement boards are always in a horizontal state, the movement of the placement table is ensured to simulate the vibration of an earthquake in all directions, and the accuracy of earthquake-resistant detection of the building structure model is improved.

Description

Building structure shock resistance simulation detection device

Technical Field

The invention relates to the technical field of detection devices, in particular to a building structure anti-seismic strength simulation detection device.

Background

The earthquake intensity detection of the building structure mainly simulates earthquake intensity through an earthquake simulator, the simulated earthquake intensity acts on the building structure model, and the earthquake simulator vibrates the building structure model to different degrees through simulating the frequency, the amplitude and the waveform of the real earthquake so as to evaluate the earthquake resistance of the building structure. The earthquake simulator usually uses a hydraulic system or a motor driving system to generate earthquake waves, and monitors and records the dynamic response of the building structure model under the earthquake action in real time, so as to acquire the earthquake-proof condition of the building structure under different earthquake conditions, help designers optimize the structural design and improve the earthquake-proof capacity.

When the conventional earthquake simulator is used for simulating an earthquake, the simulated vibration direction is single, the simulated vibration direction cannot be adjusted, and transverse waves and longitudinal waves of the earthquake cannot be completely simulated, so that the earthquake resistance of the building structure is detected inaccurately.

Disclosure of Invention

The invention provides a building structure anti-seismic strength simulation detection device, which aims to solve the problem that the existing earthquake simulator has poor simulation effect on vibration.

The invention relates to a building structure anti-seismic strength simulation detection device which adopts the following technical scheme:

a building structure anti-seismic strength simulation detection device comprises a support frame, a simulation board, a placement table and a driving rod.

The simulation board is arranged on the support frame, the simulation board and the horizontal plane are obliquely arranged with an included angle, the inclination angle is adjustable, the simulation board is provided with a chute, and the chute extends along the intersecting line direction of the simulation board and the horizontal plane; a plurality of guide rods are arranged in the sliding grooves and are abutted against the side walls of the simulation plates, and the guide rods can be arranged in a sliding manner along the sliding grooves; the plurality of placing tables are arranged, each placing table is arranged on one guide rod in a sliding way, and each placing table is provided with a placing plate which is always horizontal; the driving rod is rotatably arranged on the supporting frame, a driving ring is coaxially and slidably connected to the driving rod, a plurality of adjusting rods are uniformly arranged on the driving ring in the circumferential direction, and each adjusting rod is connected with a placing table; the support frame is provided with a first driving unit which is used for driving the driving rod to rotate in a reciprocating manner.

Further, two simulation plates are arranged on the support frame, the two simulation plates can form an included angle with the opening facing downwards, and the included angle can be adjusted; the sliding groove on each simulation board is parallel to the intersection line of the two simulation boards.

Further, the number of the placing tables is n, wherein n is an even number larger than zero, and the number of the placing tables on any one simulation board is n/2.

Further, a detection box is placed on the placement plate, a detection cavity is formed in the detection box, a displacement sensor and a visual sensor are installed in the detection cavity, and the displacement sensor can acquire movement of the building structure model in all directions in the detection process; the visual sensor can acquire the shape of the building structure model, the control board is arranged in the detection cavity, the control board can receive data of the visual sensor, and the control board can control an adjusting rod to be separated from the connection placement table according to the data of the visual sensor.

Further, each placing table is provided with a plugging groove, each adjusting rod is provided with a plugging block, each plugging block can be inserted into the plugging groove, each placing table is provided with a telescopic rod, each telescopic rod can push the plugging block to be separated from the plugging groove when being stretched, and each visual sensor can control the telescopic rod to stretch or shorten according to detection data.

Further, place the board and place the platform rotation and be connected, place the board and place and be provided with the bracing piece between the platform, the bracing piece can stretch out and draw back the setting, the length variation of bracing piece can change and place the board and place the contained angle between the platform.

Further, adjust the pole and include fixed part and sliding part, fixed part inside cavity, sliding part's one end slip grafting is in fixed part inside, and fixed part inside is provided with first cylinder, and first cylinder drive sliding part slides in fixed part inside.

Further, an adjusting cylinder is arranged on the supporting frame and used for adjusting the included angle of the two simulation plates.

Further, the fixed part of adjusting the pole is articulated with the actuating ring, and the sliding part of adjusting the pole is fixed to be provided with the connecting ball, is provided with the ball groove on the joint piece, and the connecting ball rotates to set up in the ball groove.

Further, the first driving unit is a driving motor, and the driving motor drives the driving rod to rotate in a reciprocating manner.

The beneficial effects of the invention are as follows: the invention relates to a building structure anti-seismic strength simulation detection device, which comprises a support frame, simulation boards, placing tables and driving rods, wherein building structure models are placed on the placing boards when the anti-seismic strength of a building structure is detected, and building structure models with different shapes can be placed on a plurality of placing tables on the same simulation board, but the building structure models placed on the placing tables in the same vertical plane on two simulation boards are the same, so that the sliding stability of the placing tables on the simulation boards is ensured. The angle between the two simulation boards is adjustably set, the placement boards are always in a horizontal state, the movement of the placement table is ensured to simulate the vibration of an earthquake in all directions, and the accuracy of earthquake-resistant detection on the building structure model is improved.

Drawings

In order to more clearly illustrate the embodiments of the invention or the technical solutions of the prior art, the drawings which are used in the description of the embodiments or the prior art will be briefly described, it being obvious that the drawings in the description below are only some embodiments of the invention, and that other drawings can be obtained according to these drawings without inventive faculty for a person skilled in the art.

Fig. 1 is a schematic structural diagram of a building structure anti-seismic strength simulation detection device according to an embodiment of the present invention;

fig. 2 is a plan view of a building structure earthquake resistance simulation detection device according to an embodiment of the present invention;

FIG. 3 is a side view of a device for simulating and detecting the earthquake resistance of a building structure according to an embodiment of the invention;

fig. 4 is a schematic structural diagram of a support frame and a simulation board in a device for simulating and detecting earthquake resistance of a building structure according to an embodiment of the present invention;

fig. 5 is a schematic structural view of a simulation board and a guide rod in a simulation detection device for earthquake resistance of a building structure according to an embodiment of the present invention;

fig. 6 is a schematic structural diagram of a building structure with a support frame and a simulation board omitted in a device for simulating and detecting earthquake resistance of a building structure according to an embodiment of the present invention;

fig. 7 is a schematic structural view of a driving shaft, a driving ring and an adjusting rod in the device for simulating and detecting the earthquake resistance of a building structure according to the embodiment of the invention;

fig. 8 is a schematic structural view of an adjusting rod in a device for simulating and detecting earthquake resistance of a building structure according to an embodiment of the present invention;

fig. 9 is a schematic structural diagram of a placement table in a building structure earthquake resistance simulation detection device according to an embodiment of the present invention.

In the figure: 110. a support frame; 111. a first support plate; 112. a second support plate; 113. a first guide rail; 114. a second guide rail; 120. a simulation board; 121. a chute; 130. a placement table; 131. a guide rod; 132. placing a plate; 133. a support rod; 134. a placement groove; 140. a detection box; 210. a driving rod; 220. a driving motor; 230. a drive ring; 240. an adjusting rod; 241. a fixing part; 242. a sliding part; 243. a plug block; 244. a top plate; 250. a telescopic rod; 260. and adjusting the cylinder.

Detailed Description

The following description of the embodiments of the present invention 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 invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

The numbering of components herein, such as "first," "second," etc., is used merely to distinguish between the described objects and does not have any sequential or technical meaning. The terms "coupled" and "connected," as used herein, are intended to encompass both direct and indirect coupling (coupling), unless otherwise indicated. In the description of the present invention, it should be understood that the terms "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "clockwise", "counterclockwise", etc. indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, are merely for convenience in describing the present invention and simplifying the description, and do not indicate or imply that the device or element in question must have a specific orientation, be configured and operated in a specific orientation, and thus should not be construed as limiting the present invention.

In the present invention, unless expressly stated or limited otherwise, a first feature "up" or "down" a second feature may be the first and second features in direct contact, or the first and second features in indirect contact via an intervening medium. Moreover, a first feature "above," "over" and "on" a second feature may be a first feature directly above or obliquely above the second feature, or simply indicate that the first feature is higher in level than the second feature. The first feature being "under", "below" and "beneath" the second feature may be the first feature being directly under or obliquely below the second feature, or simply indicating that the first feature is less level than the second feature.

As shown in fig. 1 to 9, the building structure anti-seismic strength simulation detection device provided by the embodiment of the invention comprises a support frame, a simulation board, a placing table and a driving rod.

The support frame 110 includes a first support plate 111 and a second support plate 112, wherein the first support plate 111 and the second support plate 112 are both horizontally arranged, the first support plate 111 is located above the second support plate 112, and a connecting rod is connected between the first support plate 111 and the second support plate 112. The first support plate 111 is provided with two first guide rails 113 in the horizontal direction, and the two first guide rails 113 are disposed at left and right intervals. The first support plate 111 is fixedly provided with second guide rails 114 in the vertical direction, and the second guide rails 114 are located at the middle portions of the two first guide rails 113.

The two simulation boards 120 are provided with two, one end of the two simulation boards 120 is rotationally connected and is slidably arranged along the second guide rail 114, one ends of the two simulation boards 120, which are far away from each other, are slidably arranged along the first guide rail 113, the two simulation boards 120 jointly form an included angle with a downward opening, and then the size of the included angle between the two simulation boards 120 can be changed when the one end of the two simulation boards 120, which are rotationally connected, slides along the second guide rail 114. Both ends of each of the simulation boards 120 are provided with sliding grooves 121 extending back and forth, and each sliding groove 121 is parallel to the intersection line of the two simulation boards 120. Each of the simulation boards 120 is provided with a plurality of guide rods 131, and on any one of the simulation boards 120, both ends of each guide rod 131 are respectively slidably arranged in the sliding groove 121, so that the guide rods 131 can slide in the sliding groove 121.

The placing table 130 is provided with n, where n is an even number greater than zero, and the number of guide bars 131 provided on any one of the analog boards 120 is n/2. Each placing table 130 is slidably connected to one guide rod 131, so that each placing table 130 can slide along the guide rod 131, and the placing tables 130 are always abutted to the plate surface of the simulation plate 120, each placing table 130 is connected with a placing plate 132, one end of each placing plate 132 is rotatably connected with one end of each placing table 130, and an intersecting line of each placing plate 132 and each placing table 130 is parallel to an intersecting line of two simulation plates 120. The support rod 133 is arranged between the placing plate 132 and the placing table 130, when the length of the support rod 133 changes, the included angle between the placing plate 132 and the placing table 130 changes, a second cylinder is arranged inside the support rod 133, and when the second cylinder is started, the length of the support rod 133 changes synchronously. The included angle between any one of the simulation boards 120 and the first support board 111 is always equal to the included angle between the placement board 132 and the placement table 130, so that the placement board 132 on each placement table 130 is always in a horizontal state.

In this embodiment, each placing table 130 is provided with a placing groove 134, an opening of the placing groove 134 faces upwards, each placing groove 134 is internally provided with a detection box 140, a detection cavity is formed in the detection box 140, an opening communicated with the detection cavity is formed in the detection box 140, a plugging plate capable of plugging the opening is arranged on the detection box 140, and a building structure model to be detected can be placed in the detection cavity. The displacement sensor and the visual sensor are arranged in the detection cavity, and the displacement sensor can acquire the movement of the building structure model in all directions in the detection process. The vision sensor is capable of acquiring the shape of the building structure model.

The driving rod 210 is vertically disposed, and the driving rod 210 and the second guide rail 114 are in the same vertical plane extending back and forth. The junction of two simulation boards 120 is provided with first groove that runs through, is provided with the second on the first backup pad 111 and runs through the groove, and the second runs through groove and the coaxial setting in first groove that runs through, and actuating lever 210 passes first groove and the setting of second groove that runs through, is provided with first drive unit in the clearance between first backup pad 111 and the second backup pad 112, and first drive unit is used for driving actuating lever 210 reciprocal rotation, and first drive unit is driving motor 220, driving motor 220 and second backup pad 112 fixed connection, driving motor 220's power output shaft and the coaxial fixed connection of actuating lever 210. The driving rod 210 is coaxially provided with a driving ring 230, the driving ring 230 is connected with the driving rod 210 in a vertically sliding manner, and the driving ring 230 rotates synchronously when the driving rod 210 rotates. The driving ring 230 is provided with a plurality of adjusting rods 240, the plurality of adjusting rods 240 are uniformly distributed around the circumference of the driving ring 230, one end of each adjusting rod 240 is hinged with the driving ring 230, and when the driving ring 230 rotates, the plurality of adjusting rods 240 synchronously rotate around the axis of the driving ring 230. The other end of each adjustment lever 240 is connected to one of the placement stages 130, and when the driving ring 230 rotates, the placement stage 130 moves on the dummy plate 120.

The adjusting rod 240 includes a fixing portion 241 and a sliding portion 242, the fixing portion 241 is hollow, one end of the sliding portion 242 is slidably inserted into the fixing portion 241, a first cylinder is disposed in the fixing portion 241, and the first cylinder drives the sliding portion 242 to slide in the fixing portion 241, so that the length of the adjusting rod 240 is changed. The fixed portion 241 of the adjustment lever 240 is hinged to the drive ring 230, and the sliding portion 242 of the adjustment lever 240 is connected to the placement table 130.

Each of the placement tables 130 is provided with a plugging slot, and the opening of the plugging slot faces upwards. The end of the sliding portion 242 of each adjusting rod 240 is provided with a plug-in block 243, the plug-in block 243 can be inserted into the plug-in groove, and when the plug-in block 243 is positioned in the plug-in groove, the rotation of the driving ring 230 drives the placing table 130 to slide on the simulation board 120. Each of the placing tables 130 is provided with a telescopic rod 250, and the telescopic rods 250 are arranged perpendicular to the placing tables 130. The top plate 244 is arranged on the plugging block 243, one end of the telescopic rod 250 is abutted against the top plate 244, the other end of the telescopic rod 250 is fixedly connected with the placing table 130, and when the telescopic rod 250 stretches, the plugging block 243 can be pushed by the top plate 244 to be separated from the plugging groove, so that the adjusting rod 240 is separated from the placing table 130. The detection chamber is provided with a control board, the control board can receive relevant data of the vision sensor, and the control board controls the expansion link 250 to be expanded or contracted according to the received data, so that each control board controls whether one adjustment link 240 is disconnected from the connection placement table 130 according to the received data.

In this embodiment, the support frame 110 is provided with an adjusting cylinder 260, and the adjusting cylinder 260 is used for adjusting the included angle of the two analog boards 120. Specifically, the adjusting cylinder 260 is vertically disposed, the adjusting cylinder 260 is disposed on the second guide rail 114, the lower end of the adjusting cylinder 260 is fixedly connected with the first support plate 111, the upper end of the adjusting cylinder 260 is fixedly connected with the connection point of the two simulation plates 120, and when the length of the adjusting cylinder 260 changes, the angle of the two simulation plates 120 changes.

In this embodiment, the sliding portion 242 of the adjusting lever 240 is fixedly provided with a connection ball, the socket 243 is provided with a ball groove, and the connection ball is rotatably disposed in the ball groove.

In combination with the above embodiments, the embodiment of the present invention provides a use principle and a working process of a building structure anti-seismic strength simulation detection device as follows:

during operation, the plugging plate is used for plugging the opening of the detection box 140, the building structure model to be detected is placed in the detection cavity, the displacement sensor and the visual sensor in the detection cavity detect the building structure model, the elongation of the adjusting cylinder 260 and the length of the supporting rod 133 are adjusted according to detection requirements, the angle of the included angle between the two simulation plates 120 is adjusted, the length of the supporting rod 133 is adjusted, the placing plate 132 is ensured to be in a horizontal state, and the length of the adjusting rod 240 is adjusted. Among the plurality of placing tables 130 placed on the two simulation boards 120, since the number of the plurality of placing tables 130 is n and n is an even number greater than zero, the placing tables 130 having n/2 pairs are always located in the same vertical plane, and the vertical plane passes through the axis of the driving rod 210, and the building structure models placed on the two placing tables 130 in the same vertical plane of the driving rod 210 are identical.

Then, the driving motor 220 is started, the driving motor 220 drives the driving rod 210 to coaxially rotate, the rotation of the driving rod 210 drives the driving ring 230 to synchronously rotate, the plurality of adjusting rods 240 connected to the driving ring 230 start to swing, and the rotation mode of the driving motor 220 is set to reciprocally rotate at a fixed frequency. When the driving ring 230 rotates, the adjusting rods 240 drive the placing tables 130 to slide on the simulation board 120, since each placing table 130 is connected with one guide rod 131, and the guide rods 131 are arranged in a sliding manner along the sliding grooves 121 on the simulation board 120, the sliding track of the placing tables 130 on the simulation board 120 is arc-shaped under the driving of the adjusting rods 240, and since the simulation board 120 has a certain inclination angle, the movement of the placing tables 130 in the vertical direction has a certain height difference, and the placing tables 130 move a certain distance in the horizontal direction, and since the rotation mode of the starting motor is the reciprocating rotation with a fixed frequency, the sliding of the placing tables 130 on the simulation board 120 simulates the longitudinal wave of an earthquake and the transverse wave of the earthquake.

In the process that the placing table 130 slides on the simulation board 120, if a building structure model in a certain detection cavity is broken, a visual sensor in the detection cavity transmits a detected relevant signal to the control board, the control board arranged in the detection cavity controls the expansion link 250 on the placing table 130 to extend, the expansion link 250 gradually pushes the top plate 244, the plug-in block 243 connected on the sliding part 242 of the adjusting lever 240 gradually breaks away from the plug-in groove, the adjusting lever 240 is further disconnected from the placing table 130, and at the moment, the expansion link 250 connected on the other placing table 130 which is positioned on the same vertical plane with the placing table 130 synchronously extends, so that the two placing tables 130 which are positioned on the same vertical plane are simultaneously disconnected from the adjusting lever 240, and stable operation of the driving ring 230 during rotation is ensured. The placing table 130, which is disconnected from the adjusting lever 240, is free to slide along the dummy plate 120 under the action of its own gravity until the placing table 130 slides to the edge of the dummy plate 120, ensuring that the placing table 130 does not interfere with the swinging of the adjusting lever 240.

The foregoing description of the preferred embodiments of the invention 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 invention.

Claims (6)

1. The utility model provides a building structure shock resistance simulation detection device which characterized in that: comprising the following steps:

a support frame;

the simulation board is arranged on the support frame, the simulation board and the horizontal plane are obliquely arranged with an included angle, the inclination angle is adjustable, the simulation board is provided with a chute, and the chute extends along the intersecting line direction of the simulation board and the horizontal plane; a plurality of guide rods are arranged in the sliding grooves and are abutted against the side walls of the simulation plates, and the guide rods can be arranged in a sliding manner along the sliding grooves; the device comprises a plurality of placing tables, wherein each placing table is arranged on one guide rod in a sliding manner, and each placing table is provided with a placing plate which is always horizontal;

the driving rod is rotatably arranged on the supporting frame, a driving ring is coaxially and slidably connected to the driving rod, a plurality of adjusting rods are uniformly arranged on the driving ring in the circumferential direction, and each adjusting rod is connected with one placing table; the support frame is provided with a first driving unit which is used for driving the driving rod to rotate in a reciprocating manner;

the two simulation plates are arranged on the support frame, the two simulation plates can form an included angle with the opening facing downwards, and the included angle can be adjusted; the sliding chute on each simulation board is parallel to the intersection line of the two simulation boards;

the number of the placing tables is n, wherein n is an even number larger than zero, and the number of the placing tables on any one simulation board is n/2;

the detection box is arranged on the placement plate, a detection cavity is formed in the detection box, a displacement sensor and a visual sensor are arranged in the detection cavity, and the displacement sensor can acquire the movement of the building structure model in all directions in the detection process; the visual sensor can acquire the shape of the building structure model, the control board is arranged in the detection cavity, the control board can receive the data of the visual sensor, and the control board can control one adjusting rod to be separated from the connection placement table according to the data of the visual sensor;

every is placed bench and all is provided with the jack-in groove, all is provided with the grafting piece on every regulation pole, and the grafting piece can be inserted in the jack-in groove, and every is placed bench and all is provided with the telescopic link, can promote the grafting piece and break away from the jack-in groove when the telescopic link extends, and every vision sensor can control the telescopic link extension or shorten.

2. The building structure earthquake resistance simulation detection device according to claim 1, wherein: place the board and place the platform rotation and be connected, place the board and place and be provided with the bracing piece between the platform, the bracing piece can stretch out and draw back the setting, the length variation of bracing piece can change and place the board and place the contained angle between the platform.

3. The building structure earthquake resistance simulation detection device according to claim 1, wherein: the adjusting rod comprises a fixing part and a sliding part, wherein the fixing part is hollow, one end of the sliding part is inserted into the fixing part in a sliding mode, a first air cylinder is arranged in the fixing part, and the first air cylinder drives the sliding part to slide in the fixing part.

4. The building structure earthquake resistance simulation detection device according to claim 1, wherein: an adjusting cylinder is arranged on the supporting frame and used for adjusting the included angle of the two simulation boards.

5. A building structure shock resistance simulation test device according to claim 3, wherein: the fixed part of adjusting the pole is articulated with the actuating ring, and the sliding part of adjusting the pole is fixed to be provided with the connecting ball, is provided with the ball groove on the joint piece, and the connecting ball rotates to set up in the ball groove.

6. The building structure earthquake resistance simulation detection device according to claim 1, wherein: the first driving unit is a driving motor, and the driving motor drives the driving rod to rotate in a reciprocating manner.