CN205046696U - Building isolation bearing - Google Patents

Abstract

The utility model discloses a building isolation bearing, including the support body, support body bottom is equipped with elevating gear, the elevating gear bottom sets up the base, the elevating gear bottom still is equipped with the shock attenuation base, shock attenuation base bottom is equipped with the cushion chamber, the both sides of base are equipped with fixing bolt, the support body includes upper bracket board and bottom suspension bedplate, the upper bracket board with be equipped with anti -skidding groove between the bottom suspension bedplate, the antiskid inslot is equipped with displacement sensor, be equipped with pressure sensor in the cushion chamber, power electric connection the control unit, the control unit includes controller and control switch, the control unit electric connection sensor circuit, lift circuit, warning circuit and control circuit, this building isolation bearing reasonable in design improves the anti -seismic performance of building engineering structure.

Description

A kind of architectural vibration-insulation bearing

Technical field

The utility model relates to building implements technical field, establishes especially and a kind of architectural vibration-insulation bearing.

Background technology

At present, the shock isolating pedestal of known use is suppressed by high temperature layering after steel plate, the vulcanization of rubber and is formed.Be placed in building bottom or Bridge Pier, when an earthquake occurs, stop and reduce seismic energy and propagate to top-out or bridge main body.But general shock isolating pedestal can produce larger vertical deformation under the vertical uniform load q of top; Easily excessive horizontal movement is produced under Horizontal Seismic Load; Resistance to tension is not enough, easily bearing is drawn bad, simultaneously because rubber layer is thinner, and vertical earthquake isolating DeGrain; In addition, present shock isolating pedestal does not have checkout gear, anticipation can not be made to building by calculating, safety is lower, for already installed bearing, to test its work bearing capacity, need to be measured by other special test systems and measuring method, and very important person is the installation site arriving bearing, the operation easier of test is comparatively large, and test manpower and materials expend high.

Utility model content

For deficiency of the prior art, the technical problems to be solved in the utility model there are provided architectural vibration-insulation bearing, and for solving the problems of the technologies described above, the utility model is realized by following scheme:

A kind of architectural vibration-insulation bearing, comprise support body, lifting gear is provided with bottom described support body, bottom described lifting gear, pedestal is set, also damping base is provided with bottom described lifting gear, cushion chamber is provided with bottom described damping base, the both sides of described pedestal are provided with set bolt, described support body comprises upper bracket plate and lower support plate, anti-slip tank is provided with between described upper bracket plate and described lower support plate, displacement transducer is provided with in described anti-slip tank, pressure sensor is provided with in described cushion chamber, the electrical connection control unit of power supply, described control unit comprises controller and gauge tap, described control unit is electrically connected sensor circuit, lifting circuit, warning circuit and control circuit, described sensor circuit comprises pressure sensor and displacement transducer, described lifting circuit comprises lifting gear, described warning circuit comprises alarm, described control circuit comprises lift control switch.

Preferably, described controller comprises control circuit mainboard and the microprocessor be arranged on control circuit mainboard and process chip, described microprocessor and described process chip are electrically connected, and described microprocessor and described process chip are welded on control circuit mainboard.

Preferably, described lift control switch comprises raise button and reduces button.

Preferably, described lifting gear comprises support bar, central axis, pedestal and turning cylinder, and described support bar comprises intermediate bar and two ends bar, and described intermediate bar length is greater than described two ends bar, described two ends bar is connected by central axis with described intermediate bar, and described central axis can carry out Double-directional rotary.

Relative to prior art, the beneficial effects of the utility model are: this architectural vibration-insulation bearing, comprise lifting gear, damping base, cushion chamber, set bolt, anti-slip tank, displacement transducer and pressure sensor, owing to being provided with lifting gear bottom support body, slightly can be adjusted common building thing by lifting gear, ensure the vertical anti-seismic performance of building, owing to being provided with damping base bottom lifting gear, and cushion chamber is provided with bottom damping base, the vertical shock resistance of building can be strengthened further by damping base and cushion chamber, owing to being provided with anti-slip tank in upper bracket plate and lower support plate, building can be made to carry out slight moving horizontally by anti-slip tank, the energy that earthquake brings building can be consumed, stability is better, owing to being provided with displacement transducer in anti-slip tank, pressure sensor is provided with in cushion chamber, by displacement transducer and pressure sensor can be real-time monitoring information is passed to control unit, effectively can promote the safety of building, this architectural vibration-insulation susceptor design is reasonable, improve the anti-seismic performance of building engineering structure.

Accompanying drawing explanation

In order to be illustrated more clearly in the utility model embodiment or technical scheme of the prior art, be briefly described to the accompanying drawing used required in embodiment or description of the prior art below, apparently, accompanying drawing in the following describes is only embodiments more of the present utility model, for those of ordinary skill in the art, under the prerequisite not paying creative work, other accompanying drawing can also be obtained according to these accompanying drawings.

Fig. 1 is the structural representation of a kind of architectural vibration-insulation bearing described in the utility model embodiment;

Fig. 2 is the structural representation of a kind of architectural vibration-insulation bearing anti-slip tank described in the utility model embodiment;

Fig. 3 is a kind of architectural vibration-insulation bearing control system block diagram described in the utility model embodiment;

Mark in accompanying drawing: 1, support body; 2, lifting gear; 3, support bar; 4, turning cylinder; 5, central axis; 6, pedestal; 7, damping base; 8, set bolt; 9, alarm; 10, cushion chamber; 11, upper bracket plate; 12, lower support plate; 13, anti-slip tank; 14, pressure sensor; 15, displacement transducer; 16, sensor circuit; 17, power supply; 18, control unit; 19, controller; 20, gauge tap; 21, control circuit; 22, lift control switch; 23, circuit is elevated; 24, warning circuit; 25, alarm.

Detailed description of the invention

Below in conjunction with accompanying drawing, preferred embodiment of the present utility model is described in detail, to make advantage of the present utility model and feature can be easier to be readily appreciated by one skilled in the art, thus more explicit defining is made to protection domain of the present utility model.

Embodiment: as Figure 1-3, a kind of architectural vibration-insulation bearing of the utility model, comprise support body 1, lifting gear 2 is provided with bottom described support body 1, bottom described lifting gear 2, pedestal 6 is set, damping base 7 is also provided with bottom described lifting gear 2, cushion chamber 10 is provided with bottom described damping base 7, the both sides of described pedestal 6 are provided with set bolt 8, described support body 1 comprises upper bracket plate 11 and lower support plate 12, anti-slip tank 13 is provided with between described upper bracket plate 11 and described lower support plate 12, displacement transducer 15 is provided with in described anti-slip tank 13, pressure sensor 14 is provided with in described cushion chamber 10, power supply 17 is electrically connected control unit 18, described control unit 18 comprises controller 19 and gauge tap 20, described control unit 18 is electrically connected sensor circuit 16, lifting circuit 23, warning circuit 24 and control circuit 21, described sensor circuit 16 comprises pressure sensor 14 and displacement transducer 15, described lifting circuit 23 comprises lifting gear 2, described warning circuit 24 comprises alarm 25, described control circuit 21 comprises lift control switch 22.

Described controller 19 comprises control circuit mainboard and the microprocessor be arranged on control circuit mainboard and process chip, described microprocessor and described process chip are electrically connected, described microprocessor and described process chip are welded on control circuit mainboard, described lift control switch 22 comprises raise button and reduces button, described lifting gear 2 comprises support bar 3, central axis 5, pedestal 6 and turning cylinder 4, described support bar 3 comprises intermediate bar and two ends bar, described intermediate bar length is greater than described two ends bar, described two ends bar is connected by central axis 5 with described intermediate bar, described central axis 5 can carry out Double-directional rotary, owing to being provided with lifting gear 2 bottom support body 1, slightly can be adjusted common building thing by lifting gear 2, ensure the vertical anti-seismic performance of building, owing to being provided with damping base 7 bottom lifting gear 2, and cushion chamber 10 is provided with bottom damping base 7, the vertical shock resistance of building can be strengthened further by damping base 7 and cushion chamber 10, owing to being provided with anti-slip tank 13 in upper bracket plate 11 and lower support plate 12, building can be made to carry out slight moving horizontally by anti-slip tank 13, the energy that earthquake brings building can be consumed, stability is better, owing to being provided with displacement transducer 15 in anti-slip tank 13, pressure sensor 14 is provided with in cushion chamber 10, by displacement transducer 15 and pressure sensor 14 can be real-time monitoring information is passed to control unit 18, if monitor pressure sensor 14 or displacement transducer 15 when exceeding control unit 18 setting range value, control unit 18 controls alarm 25 by warning circuit 24 and reports to the police, effectively can promote the safety of building, this architectural vibration-insulation susceptor design is reasonable, improve the anti-seismic performance of building engineering structure.

The foregoing is only preferred embodiment of the present utility model; not thereby the scope of the claims of the present utility model is limited; every utilize the utility model manual and accompanying drawing content to do equivalent structure or equivalent flow process conversion; or be directly or indirectly used in other relevant technical field, be all in like manner included in scope of patent protection of the present utility model.

Claims (4)

1. an architectural vibration-insulation bearing, comprise support body (1), it is characterized in that, described support body (1) bottom is provided with lifting gear (2), described lifting gear (2) bottom arranges pedestal (6), described lifting gear (2) bottom is also provided with damping base (7), described damping base (7) bottom is provided with cushion chamber (10), the both sides of described pedestal (6) are provided with set bolt (8), described support body (1) comprises upper bracket plate (11) and lower support plate (12), anti-slip tank (13) is provided with between described upper bracket plate (11) and described lower support plate (12), displacement transducer (15) is provided with in described anti-slip tank (13), pressure sensor (14) is provided with in described cushion chamber (10), power supply (17) is electrically connected control unit (18), described control unit (18) comprises controller (19) and gauge tap (20), described control unit (18) is electrically connected sensor circuit (16), lifting circuit (23), warning circuit (24) and control circuit (21), described sensor circuit (16) comprises pressure sensor (14) and displacement transducer (15), described lifting circuit (23) comprises lifting gear (2), described warning circuit (24) comprises alarm (25), described control circuit (21) comprises lift control switch (22).

2. a kind of architectural vibration-insulation bearing according to claim 1, it is characterized in that described controller (19) comprises control circuit mainboard and the microprocessor be arranged on control circuit mainboard and process chip, described microprocessor and described process chip are electrically connected, and described microprocessor and described process chip are welded on control circuit mainboard.

3. a kind of architectural vibration-insulation bearing according to claim 1, is characterized in that described lift control switch (22) comprises raise button and reduces button.

4. a kind of architectural vibration-insulation bearing according to claim 1, it is characterized in that described lifting gear (2) comprises support bar (3), central axis (5), pedestal (6) and turning cylinder (4), described support bar (3) comprises intermediate bar and two ends bar, described intermediate bar length is greater than described two ends bar, described two ends bar is connected by central axis (5) with described intermediate bar, and described central axis (5) can carry out Double-directional rotary.