CN212624546U - Movable type earthquake simulation platform - Google Patents

Abstract

The utility model discloses a portable simulation earthquake platform, including the function frame, the inside symmetry in both sides of function frame is equipped with rather than matched with flexible motor, be equipped with the simulation vibrating device between two liang of flexible motors, the simulation vibrating device includes the simulation frame, the both sides on simulation frame top all are equipped with rather than matched with protection frame, the intermediate position on simulation frame top is equipped with a plurality of evenly distributed's promotion frame, one side of promotion frame is equipped with and simulates frame matched with seat, the top that promotes frame and matched with seat all is equipped with the standing board, the bottom symmetry of standing board is equipped with and promotes frame and matched with seat matched with vibrating arm, the bottom of vibrating arm is equipped with and promotes frame and matched with seat matched with vibrating motor. The beneficial effects are that: the equipment can be used for effectively ensuring that people can participate in earthquake escape interaction while acquiring earthquake theoretical knowledge, and can conveniently provide a plurality of people for earthquake escape training, so that the equipment is more flexible and practical.

Description

Movable type earthquake simulation platform

Technical Field

The utility model relates to an earthquake simulation field particularly, relates to a portable simulation earthquake platform.

Background

The earthquake simulation method is characterized in that an earthquake simulation platform, an earthquake simulation house, an earthquake simulation demonstration instrument and the like are most common, the platforms for simulating earthquake scenes are numerous, most of the platforms are not enough in mobility and flexibility, the earthquake simulation method is fixedly installed and cannot be effectively moved, the application range and the use condition of earthquake simulation are limited, the earthquake simulation method is difficult to popularize, and the equipment can be flexibly used and targeted to users on a large scale if flexible position movement is achieved, so that the portability and the popularity can be greatly improved.

An effective solution to the problems in the related art has not been proposed yet.

SUMMERY OF THE UTILITY MODEL

To the problem in the correlation technique, the utility model provides a portable simulation earthquake platform to overcome the above-mentioned technical problem that current correlation technique exists.

Therefore, the utility model discloses a specific technical scheme as follows:

the utility model provides a portable simulation seismic platform, includes the function frame, the inside symmetry in both sides of function frame is equipped with rather than the flexible motor of matched with, two liang be equipped with simulation vibrating device between the flexible motor, simulation vibrating device includes the analog frame, the both sides on analog frame top all are equipped with rather than matched with protection frame, the intermediate position on analog frame top is equipped with a plurality of evenly distributed's promotion frame, one side of promotion frame be equipped with analog frame matched with seat, the promotion frame with the top of matched with seat all is equipped with the board of standing, the bottom symmetry of board of standing be equipped with the promotion frame with matched with seat matched with vibrating bar, the bottom of vibrating bar be equipped with promote the frame with matched with seat matched with vibrating motor.

Furthermore, a crack simulation push rod is arranged between the matching seat and the pushing frame.

Furthermore, one side of the vibrating rod is provided with a buffering supplement rod matched with the standing plate, the bottom end of the buffering supplement rod is sleeved with a buffering sleeve matched with the buffering supplement rod, and a buffering spring matched with the buffering supplement rod is arranged inside the buffering sleeve.

Furthermore, a connecting limiting rod is arranged between every two standing plates.

Furthermore, the inside symmetry of function frame is equipped with the sliding tray, the inside of sliding tray be equipped with simulation vibrating device matched with sliding connection piece.

Furthermore, a telescopic pushing rod is arranged between the simulated vibration device and the telescopic motor, and a connecting plate is arranged between the telescopic pushing rod and the simulated vibration device.

Furthermore, the top of the protection frame is provided with a guardrail matched with the protection frame, and a connecting block is arranged between the guardrail and the protection frame.

The utility model has the advantages that: the effectual equipment of having guaranteed can make people can also participate in the earthquake when acquireing earthquake theory knowledge and flee interdynamic in whole use, and equipment can conveniently provide most people and simulate the earthquake training of fleing, strengthen people's individual ability of fleing, and the dangerous condition when equipment can the biggest simulation earthquake, frequency varies, not equidirectional vibrations and slight production etc. of crack, and the structure is used in the installation of equipment, can make things convenient for equipment to utilize the carrier or realize nimble removal through being connected with the carrier installation, thereby make equipment more nimble and practical.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings required to be used in the embodiments will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to these drawings without creative efforts.

Fig. 1 is a schematic structural diagram of a mobile simulated seismic platform according to an embodiment of the present invention;

fig. 2 is a schematic structural diagram of a vibration simulation device of a mobile simulated seismic platform according to an embodiment of the present invention.

In the figure:

1. a functional rack; 2. a telescopic motor; 3. simulating a vibration device; 4. a simulation frame; 5. a protective frame; 6. a pushing frame; 7. a mating seat; 8. standing the plate; 9. a vibrating rod; 10. a vibration motor; 11. simulating a push rod in a crack; 12. a buffer supplement rod; 13. a buffer sleeve; 14. a buffer spring; 15. connecting a limiting rod; 16. a sliding groove; 17. a sliding connection block; 18. a telescopic push rod; 19. a connecting plate; 20. a guardrail; 21. and (4) connecting the blocks.

Detailed Description

For further explanation of the embodiments, the drawings are provided as part of the disclosure and serve primarily to illustrate the embodiments and, together with the description, to explain the principles of operation of the embodiments, and to provide further explanation of the invention and advantages thereof, it will be understood by those skilled in the art that various other embodiments and advantages of the invention are possible, and that elements in the drawings are not to scale and that like reference numerals are generally used to designate like elements.

According to the utility model discloses an embodiment provides a portable simulation earthquake platform.

The first embodiment is as follows:

as shown in fig. 1-2, the mobile simulated seismic platform according to the embodiment of the invention comprises a functional frame 1, telescopic motors 2 matched with the functional frame 1 are symmetrically arranged inside two sides of the functional frame 1, a simulated vibration device 3 is arranged between every two telescopic motors 2, the simulated vibration device 3 comprises a simulated frame 4, two sides of the top end of the simulated frame 4 are provided with protective frames 5 matched with the simulated frame, a plurality of pushing frames 6 which are uniformly distributed are arranged in the middle of the top end of the simulation frame 4, one side of each pushing frame 6 is provided with a matching seat 7 which is matched with the simulation frame 4, standing plates 8 are arranged above the pushing frame 6 and the matching seat 7, vibrating rods 9 matched with the pushing frame 6 and the matching seat 7 are symmetrically arranged at the bottom ends of the standing plates 8, and a vibration motor 10 matched with the pushing frame 6 and the matching seat 7 is arranged at the bottom end of the vibration rod 9.

The specific arrangement and function of the functional rack 1, the standing board 8, the simulation rack 4, the matching seat 7, the pushing rack 6, the buffer sleeve 13, the protection rack 5 and the buffer sleeve 13 are described in detail below.

As shown in figure 1, when the device is used, an experiential person walks onto a station board 8, at the moment, the device starts to operate after a functional frame 1 is plugged with electricity and is communicated with other electric connection components through the functional frame, at the moment, the experiential person grasps a guardrail 20, a pushing frame 6 and a matching seat 7 enable a vibrating rod 9 to carry out high-frequency reciprocating operation through a vibrating motor 10, due to the fact that the vibrating structures are matched in a sufficient number of arrangements, when the experiential person stands on the device, after the device operates, the station board 8 can guarantee vibration with the same frequency or different frequencies through advance presetting, namely, concave-convex unevenness is generated on a treading surface and is used for simulating a severe earthquake environment or a slight earthquake environment, during the period, when the station board 8 drives vibration through the vibrating rod 9, a buffering supplement rod 12 on one side can enter a buffering sleeve 13, structural support is carried out, and the vibration of the structure can be guaranteed not to generate, guarantee the security of structure simultaneously, during the vibration, flexible motor 2 can make the plane that experience personnel stood carry out longitudinal vibration and improve earthquake simulation authenticity greatly, and promote frame 6 and cooperation seat 7 and can drive crack simulation catch bar 11 and promote slowly, thereby make the station board 8 of symmetric distribution slowly expand and produce the crack that is not enough to reach danger level, further improve earthquake simulation and experience, and promote between frame 6 and cooperation seat 7 and the simulation frame 4 and be connected the practicality through spout and slider structure equally, the benefit of equipment lies in, equipment has nimble connection structure, for a plurality of partial combinations be whole equipment, can be light cooperate with other carriers, the light realization mobility of the strength that utilizes the carrier.

Example two:

as shown in fig. 1-2, a crack simulation push rod 11 is arranged between the matching seat 7 and the push frame, a buffering supplement rod 12 matched with the station plate 8 is arranged on one side of the vibrating rod 9, a buffering sleeve 13 matched with the buffering supplement rod 12 is sleeved at the bottom end of the buffering supplement rod 12, a buffering spring 14 matched with the buffering supplement rod 12 is arranged inside the buffering sleeve 13, a connection limit rod 15 is arranged between every two station plates 8, sliding grooves 16 are symmetrically arranged inside the function frame 1, a sliding connection block 17 matched with the simulation vibrating device 3 is arranged inside the sliding groove 16, a telescopic push rod 18 is arranged between the simulation vibrating device 3 and the telescopic motor 2, a connection plate 19 is arranged between the telescopic push rod 18 and the simulation vibrating device 3, a guardrail 20 matched with the protection frame 5 is arranged at the top end of the protection frame, a connecting block 21 is arranged between the guardrail 20 and the protective frame 5.

For the convenience of understanding the technical solution of the present invention, the following detailed description is made on the working principle or the operation mode of the present invention in the practical process.

In practical application, an experiential person walks onto the standing plate 8, at the moment, after the functional frame 1 starts to operate and is connected with other electric connection components through the electric connection components, the experiential person grasps the guardrail 20, the pushing frame 6 and the matching seat 7 enable the vibrating rod 9 to carry out high-frequency reciprocating operation through the vibrating motor 10, due to the fact that the vibrating structures are matched in a sufficient number of arrangement, when the experiential person stands on the standing plate, after the equipment operates, the standing plate 8 can guarantee the vibration with the same frequency or different frequencies through advance presetting, namely, the treading surface generates unevenness, the unevenness is used for simulating a severe earthquake environment or a slight earthquake environment, during the period, when the standing plate 8 drives the vibration through the vibrating rod 9 every time, the buffering and supplementing rod 12 on one side of the standing plate can enter the buffering sleeve 13 to carry out structural support, and meanwhile, the vibration amplitude of the structure can be guaranteed that dangerous signals cannot be generated, guarantee the security of structure simultaneously, during the vibration, flexible motor 2 can make the plane that experience personnel stood carry out longitudinal vibration and improve earthquake simulation authenticity greatly, and promote frame 6 and cooperation seat 7 and can drive crack simulation catch bar 11 and promote slowly, thereby make the station board 8 of symmetric distribution slowly expand and produce the crack that is not enough to reach danger level, further improve earthquake simulation and experience, and promote between frame 6 and cooperation seat 7 and the simulation frame 4 and be connected the practicality through spout and slider structure equally, the benefit of equipment lies in, equipment has nimble connection structure, for a plurality of partial combinations be whole equipment, can be light cooperate with other carriers, the light realization mobility of the strength that utilizes the carrier.

To sum up, with the help of the above technical scheme of the utility model, the effectual equipment of having guaranteed is during whole use, can make people can also participate in the earthquake when acquireing earthquake theory knowledge and flee interactively, and equipment can conveniently provide most people and simulate the earthquake and flee the training, strengthen people's individual ability of fleing, and the dangerous condition when equipment can the maximum simulation earthquake, frequency varies, the vibrations and the slight production of fissured etc. of equidirectional not, and the installation of equipment uses the structure, can make things convenient for equipment to utilize the carrier or realize nimble removal through being connected with the carrier installation, thereby make equipment more nimble and practical.

The above description is only a preferred embodiment of the present invention, and should not be taken as limiting the invention, and any modifications, equivalent replacements, improvements, etc. made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (7)

1. A movable simulated seismic platform is characterized by comprising a function frame (1), wherein telescopic motors (2) matched with the function frame (1) are symmetrically arranged inside two sides of the function frame (1), a simulated vibration device (3) is arranged between every two telescopic motors (2), the simulated vibration device (3) comprises a simulation frame (4), protective frames (5) matched with the simulation frame (4) are arranged on two sides of the top end of the simulation frame (4), a plurality of pushing frames (6) which are uniformly distributed are arranged in the middle of the top end of the simulation frame (4), a matching seat (7) matched with the simulation frame (4) is arranged on one side of each pushing frame (6), a station plate (8) is arranged above each pushing frame (6) and the matching seat (7), vibration rods (9) matched with the pushing frames (6) and the matching seats (7) are symmetrically arranged at the bottom ends of the station plates (8), and a vibrating motor (10) matched with the pushing frame (6) and the matching seat (7) is arranged at the bottom end of the vibrating rod (9).

2. A mobile simulated seismic platform as claimed in claim 1 wherein a crack simulating pusher bar (11) is provided between the mating seat (7) and the pusher carriage.

3. A mobile simulated seismic platform as claimed in claim 1 wherein said vibrating rod (9) is provided with a buffer supplement rod (12) at one side thereof for engaging with said standing plate (8), said buffer supplement rod (12) is provided with a buffer sleeve (13) at a bottom end thereof for engaging with said vibrating rod, and said buffer sleeve (13) is provided with a buffer spring (14) engaging with said buffer supplement rod (12) inside thereof.

4. A mobile simulated seismic platform as claimed in claim 1 wherein a connecting spacer (15) is provided between each two of said standing plates (8).

5. A mobile simulated seismic platform as claimed in claim 1 wherein the functional frame (1) is provided with sliding grooves (16) symmetrically inside, and the sliding grooves (16) are provided with sliding connection blocks (17) inside for cooperating with the simulated vibration device (3).

6. A mobile simulated seismic platform as claimed in claim 1 wherein a telescopic pusher rod (18) is provided between the simulated vibration means (3) and the telescopic motor (2), and a connecting plate (19) is provided between the telescopic pusher rod (18) and the simulated vibration means (3).

7. A mobile simulated seismic platform as claimed in claim 1 wherein the top of the protective frame (5) is provided with a guardrail (20) fitted thereto, and a connecting block (21) is provided between the guardrail (20) and the protective frame (5).

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