CN220037347U - Intelligent micro-grid power station buffering and damping base - Google Patents

Abstract

The utility model provides an intelligent micro-grid power station buffering shock-absorbing mount, relates to power station apparatus technical field, and including the base, the top of base is equipped with fixed platform, and fixed platform is close to on the bottom surface of four corners and supports on the base through vertical bumper shock absorber respectively, and the vertical rigid coupling of position rigid coupling respectively that corresponds fixed platform four corners on the base has the fixed plate, and fixed platform is close to on the lateral wall of four corners and supports on the fixed plate through horizontal bumper shock absorber respectively. The utility model solves the problems that the vibration damping base of the generator in the prior art can only damp in the vertical direction, the vibration direction of the engine of the generator can be split into horizontal vibration and vertical vibration, and the lack of the horizontal vibration damping can lead the generator to displace in the horizontal direction, thereby influencing the service condition of the generator set.

Description

Intelligent micro-grid power station buffering and damping base

Technical Field

The utility model relates to the technical field of power station appliances, in particular to an intelligent micro-grid power station buffering and damping base.

Background

With the rapid development of national economy in China and the continuous improvement of living standard of people, the situation that no power supply of a power grid exists in a plurality of infrastructures (such as high-speed rail, expressway, bridge, tunnel and other construction site automatic control systems or heat preservation systems) and some occasions of living facilities (such as uninterrupted refrigeration of a refrigeration train set in transportation or a marshalling station or small-sized refrigeration houses of remote villages) is involved.

The prior art discloses a patent with publication number CN111810772A, and this scheme includes prefabricated substation main part and installation base, and the mounting groove has been seted up at the top of installation base, and the equal fixed mounting in left and right sides of the bottom of mounting groove has two support frames, and equal sliding connection has the regulation slider on four support frames, and the equal fixed mounting in one side that two regulation sliders of controlling relative are on the back of the body has damping spring. According to the utility model, when the preassembled transformer substation main body receives downward impact force, the T-shaped mounting seat and the elastic block impact the mounting plate, so that the damping support part and the damping spring at the bottom of the mounting plate have damping and buffering effects, the impact resistance effect of the device is relatively good, the device is finally enabled to achieve relatively good damping effect, and when the transformer substation is impacted, the internal electric elements are not easy to damage, and the protection effect is relatively good.

The prior devices, including the above patents, gradually expose the disadvantages of the technology with use, mainly in the following aspects:

first, current generator damping mount can only install the generator of fixed model, need change the generator base in the lump when changing the generator of different models.

Secondly, the existing generator damping base can only damp in the vertical direction, the vibration direction of an engine of the generator can be split into horizontal vibration and vertical vibration, and the lack of the horizontal vibration can enable the generator to displace in the horizontal direction, so that the service condition of the generator set is affected;

third, the existing generator damping device mostly damps through damping spring, and damping effect can not be adjusted according to generator vibrations float, and engine vibration amplitude is big, and vibration after the shock attenuation floats relatively great, and damping device uses the limitation lower.

In summary, it is clear that the prior art has inconvenience and defects in practical use, so that improvement is needed.

Disclosure of Invention

Aiming at the defects in the prior art, the utility model solves the problems that the vibration damping base of the generator in the prior art can only damp in the vertical direction, the vibration direction of the engine of the generator can be split into horizontal vibration and vertical vibration, and the lack of the vibration damping in the horizontal direction can lead the generator to displace in the horizontal direction, thereby influencing the service condition of the generator set.

In order to solve the problems, the utility model provides the following technical scheme:

the intelligent micro-grid power station buffering and damping base comprises a base, a fixed platform is arranged above the base, the bottom surfaces of the fixed platform, which are close to four corners, are respectively supported on the base through vertical shock absorbers,

the base is fixedly connected with fixing plates at positions corresponding to four corners of the fixing platform respectively, and the side walls of the fixing platform, which are close to the four corners, are supported on the fixing plates through transverse shock absorbers respectively.

As an optimized scheme, the fixed rods are respectively arranged on the opposite side walls of the fixed platform in a horizontal sliding mode, and the fixed rods are arranged in a swinging mode in the horizontal direction.

As an optimized scheme, the vertical shock absorber comprises a cylinder body, the cylinder body is fixedly connected to the base, a vertical pressure spring is sleeved on the cylinder body, a vertical supporting rod is arranged in the cylinder body in a sliding mode, a vertical fixing plate is fixedly connected to the upper end portion of the vertical supporting rod, and two ends of the vertical pressure spring are respectively propped against the base and the vertical fixing plate.

As an optimized scheme, the vertical fixing plate is hinged with a top column, and the upper end part of the top column is hinged with the bottom surface of the fixing platform.

As an optimized scheme, a piston is arranged in the cylinder body in a sliding manner, a gas storage cavity is formed between the lower end part of the piston and the inner cavity of the cylinder body, a gas storage channel connected with the gas storage cavity is fixedly connected to the side wall of the cylinder body, and a gas filling and discharging nozzle communicated with the outside is connected to the gas storage channel.

As an optimized scheme, the transverse shock absorber comprises a sleeve which is horizontally arranged, the sleeve is vertically arranged on the fixed plate in a sliding mode, a transverse supporting rod is horizontally arranged in the sleeve in a sliding mode, and the other end of the transverse supporting rod is fixedly connected with the side wall of the fixed platform.

As an optimized scheme, the sleeve is sleeved with a transverse pressure spring, the sleeve and the outer wall of the transverse supporting rod are fixedly connected with the retaining plates respectively, and two ends of the transverse pressure spring are abutted against the two retaining plates respectively.

As an optimized scheme, a guide groove is vertically formed in the side wall of the fixing plate, and the sleeve is fixedly connected with a guide block constrained in the guide groove.

As an optimized scheme, the side wall of the fixed platform is provided with a T-shaped chute, the hinged end of the fixed plate is hinged to the sliding seat, and the sliding seat is fixedly connected with a T-shaped sliding block constrained in the T-shaped chute.

As an optimized scheme, the fixed rod is horizontally provided with a sliding hole, and a fixed bolt is arranged in the sliding hole.

Compared with the prior art, the utility model has the beneficial effects that:

when the generators with different sizes are required to be installed, the fixing rod is slid to a position matched with the size of the generator, the fixing rod is swung to enable the fixing rod to be matched with the generator in length and angle, and the fixing bolt is fixed with the ear plate of the generator, so that the function of installing generators with different models is realized;

the vibration direction of the generator is split into the vertical direction and the horizontal direction during operation, the vibration in the vertical direction is transmitted to the vertical vibration damper through the fixed platform to be damped, meanwhile, the horizontal vibration damper can move up and down through the guide groove, the horizontal vibration can drive the fixed platform to vibrate horizontally, the fixed platform and the jacking column can be driven to shake left and right during horizontal vibration of the fixed platform, the horizontal vibration is transmitted to the horizontal vibration damper to be damped, the vibration damping in the horizontal direction and the vertical direction of the generator is realized, and the function of enhancing the vibration damping effect is realized;

when vertical direction vibration transmits vertical bumper shock absorber time downward movement, vertical spring produces ascending elasticity and slows down the motion range, and the piston downward movement compresses the gas in the gas storage cavity simultaneously, and the piston produces ascending thrust, slows down vibration range, when changing different model generators, if vibration range grow, the accessible fills the inflation and deflation mouth and aerifys in to the cylinder body, makes the thrust that the piston can provide grow, reduces vibration range, has realized reinforcing bumper shock absorber shock attenuation effect and according to the function of different generator adjustment vibration ranges.

Drawings

In order to more clearly illustrate the embodiments of the present utility model or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below. Like elements or portions are generally identified by like reference numerals throughout the several figures. In the drawings, elements or portions thereof are not necessarily drawn to scale.

FIG. 1 is a schematic diagram of the structure of the present utility model;

fig. 2 is a schematic structural view of the vertical shock absorber of the present utility model.

In the figure: 1-a base; 2-a fixed platform; 3-T-shaped sliding grooves; 4-a sliding seat; 5-a fixed rod; 6-fixing bolts; 7-sliding holes; 8-jacking columns; 9-a vertical shock absorber; 10-fixing plates; 11-a sleeve; 12-a transverse supporting rod; 13-a transverse compression spring; 14-a retaining plate; 15-a guide groove; 16-cylinder; 17-a gas storage cavity; 18-a gas storage channel; 19-an air charging and discharging nozzle; 20-a vertical compression spring; 21-a piston; 22-vertical support rods; 23-vertical fixing plate.

Detailed Description

Embodiments of the technical scheme of the present utility model will be described in detail below with reference to the accompanying drawings. The following examples are only for more clearly illustrating the technical aspects of the present utility model, and thus are merely examples, and are not intended to limit the scope of the present utility model.

As shown in fig. 1 and 2, the damping base of the intelligent micro-grid power station comprises a base 1, a fixed platform 2 is arranged above the base 1, the bottom surfaces of the fixed platform 2 close to four corners are respectively supported on the base 1 through vertical dampers 9,

the base 1 is fixedly connected with fixing plates 10 respectively corresponding to the four corners of the fixing platform 2, and the side walls of the fixing platform 2, which are close to the four corners, are respectively supported on the fixing plates 10 through transverse shock absorbers.

The opposite side walls of the fixed platform 2 are respectively provided with a fixed rod 5 in a horizontal sliding manner, and the fixed rods 5 are also arranged in a swinging manner along the horizontal direction.

The vertical shock absorber 9 comprises a cylinder body 16, the cylinder body 16 is fixedly connected to the base 1, a vertical pressure spring 20 is sleeved on the cylinder body 16, a vertical supporting rod 22 is arranged in the cylinder body 16 in a sliding mode, a vertical fixing plate 23 is fixedly connected to the upper end portion of the vertical supporting rod 22, and two ends of the vertical pressure spring 20 are respectively abutted to the base 1 and the vertical fixing plate 23.

The vertical fixing plate 23 is hinged with a jacking column 8, and the upper end part of the jacking column 8 is hinged with the bottom surface of the fixed platform 2.

The cylinder body 16 is internally provided with a piston 21 in a sliding manner, a gas storage cavity 17 is formed between the lower end part of the piston 21 and the inner cavity of the cylinder body 16, a gas storage channel 18 connected with the gas storage cavity 17 is fixedly connected to the side wall of the cylinder body 16, and a gas charging and discharging nozzle 19 communicated with the outside is connected to the gas storage channel 18.

The transverse shock absorber comprises a sleeve 11 which is horizontally arranged, the sleeve 11 is arranged on the fixed plate 10 in a vertical sliding manner, a transverse supporting rod 12 is horizontally arranged in the sleeve 11 in a sliding manner, and the other end of the transverse supporting rod 12 is fixedly connected with the side wall of the fixed platform 2.

The sleeve 11 is sleeved with a transverse pressure spring 13, the sleeve 11 and the outer wall of the transverse supporting rod 12 are fixedly connected with a retaining plate 14 respectively, and two ends of the transverse pressure spring are abutted against the two retaining plates 14 respectively.

The side wall of the fixed plate 10 is vertically provided with a guide groove 15, and the sleeve 11 is fixedly connected with a guide block restrained in the guide groove 15.

The side wall of the fixed platform 2 is provided with a T-shaped chute 3, the hinged end of the fixed plate 10 is hinged on a sliding seat 4, and a T-shaped sliding block constrained in the T-shaped chute 3 is fixedly connected on the sliding seat 4.

The fixed rod 5 is horizontally provided with a slide hole 7, and a fixed bolt 6 is arranged in the slide hole 7.

The working principle of the device is as follows:

when generators with different sizes are required to be installed, the fixing rod 5 is slid to a position matched with the size of the generator, the fixing rod 5 is swung to adapt the length and the angle of the fixing rod to the generator, and the fixing bolt 6 is fixed with the lug plate of the generator, so that the function of installing generators with different models is realized;

the vibration direction of the generator is split into the vertical direction and the horizontal direction during operation, the vibration in the vertical direction is transmitted to the vertical vibration damper 9 through the fixed platform 2 to be damped, meanwhile, the horizontal vibration damper can move up and down through the guide groove 15, the vibration in the horizontal direction can drive the fixed platform 2 to vibrate horizontally, the fixed platform 2 and the jacking posts 8 can be driven to shake left and right during horizontal vibration of the fixed platform 2, the horizontal vibration is transmitted to the horizontal vibration damper to be damped, and the functions of damping in the horizontal direction and the vertical direction of the generator and enhancing the damping effect are realized;

when vertical direction vibration is transmitted to the vertical shock absorber 9 and moves downwards, the vertical spring generates upward elasticity to slow down the movement amplitude, meanwhile, the piston 21 moves downwards to compress gas in the gas storage cavity 17, the piston 21 generates upward thrust to slow down the vibration amplitude, when different types of generators are replaced, if the vibration amplitude is increased, the air inflation nozzle 19 can be used for inflating the cylinder 16, so that the thrust provided by the piston 21 is increased, the vibration amplitude is reduced, and the functions of enhancing the shock absorption effect of the shock absorber and adjusting the vibration amplitude according to different generators are realized.

Finally, it should be noted that: the above embodiments are only for illustrating the technical solution of the present utility model, and not for limiting the same; although the utility model has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that: the technical scheme described in the foregoing embodiments can be modified or some or all of the technical features thereof can be replaced by equivalents; such modifications and substitutions do not depart from the spirit of the utility model, and are intended to be included within the scope of the appended claims and description.

Claims (10)

1. Intelligent micro-grid power station buffering shock-absorbing base, its characterized in that: comprises a base (1), a fixed platform (2) is arranged above the base (1), the bottom surfaces of the fixed platform (2) close to four corners are respectively supported on the base (1) through vertical shock absorbers (9),

the base (1) is fixedly connected with fixing plates (10) at positions corresponding to four corners of the fixing platform (2) respectively, and the side walls of the fixing platform (2) close to the four corners are supported on the fixing plates (10) through transverse shock absorbers respectively.

2. The intelligent microgrid power station buffering vibration damping mount according to claim 1, wherein: the fixed platform is characterized in that fixed rods (5) are respectively arranged on the opposite side walls of the fixed platform (2) in a horizontal sliding mode, and the fixed rods (5) are arranged in a swinging mode along the horizontal direction.

3. The intelligent microgrid power station buffering vibration damping mount according to claim 2, wherein: the vertical shock absorber (9) comprises a cylinder body (16), the cylinder body (16) is fixedly connected to the base (1), a vertical pressure spring (20) is sleeved on the cylinder body (16), a vertical support rod (22) is arranged in the cylinder body (16) in a sliding mode, a vertical fixing plate (23) is fixedly connected to the upper end portion of the vertical support rod (22), and two ends of the vertical pressure spring (20) are respectively abutted to the base (1) and the vertical fixing plate (23).

4. The intelligent microgrid power station buffering vibration damping mount according to claim 3, wherein: the vertical fixing plate (23) is hinged with a jacking column (8), and the upper end part of the jacking column (8) is hinged with the bottom surface of the fixing platform (2).

5. The intelligent microgrid power station buffering vibration damping mount of claim 4, wherein: the gas storage device is characterized in that a piston (21) is arranged in the cylinder body (16) in a sliding mode, a gas storage cavity (17) is formed between the lower end portion of the piston (21) and the inner cavity of the cylinder body (16), a gas storage channel (18) connected with the gas storage cavity (17) is fixedly connected to the side wall of the cylinder body (16), and a gas filling and discharging nozzle (19) communicated with the outside is connected to the gas storage channel (18).

6. The intelligent microgrid power station buffering vibration damping mount of claim 5, wherein: the horizontal shock absorber comprises a sleeve (11) which is horizontally arranged, the sleeve (11) is vertically and slidably arranged on the fixed plate (10), a horizontal supporting rod (12) is horizontally arranged in the sleeve (11) in a moving mode, and the other end of the horizontal supporting rod (12) is fixedly connected with the side wall of the fixed platform (2).

7. The intelligent microgrid power station buffering vibration damping mount of claim 6, wherein: the sleeve (11) is sleeved with a transverse pressure spring (13), the sleeve (11) and the outer wall of the transverse supporting rod (12) are fixedly connected with a retaining plate (14) respectively, and two ends of the transverse pressure spring are abutted against the two retaining plates (14) respectively.

8. The intelligent microgrid power station buffering vibration damping mount of claim 7, wherein: the side wall of the fixed plate (10) is vertically provided with a guide groove (15), and the sleeve (11) is fixedly connected with a guide block constrained in the guide groove (15).

9. The intelligent microgrid power station buffering vibration damping mount of claim 8, wherein: the side wall of the fixed platform (2) is provided with a T-shaped sliding groove (3), the hinged end of the fixed plate (10) is hinged to the sliding seat (4), and the sliding seat (4) is fixedly connected with a T-shaped sliding block constrained in the T-shaped sliding groove (3).

10. The intelligent microgrid power station buffering vibration damping mount of claim 9, wherein: the sliding hole (7) is horizontally formed in the fixing rod (5), and the fixing bolt (6) is arranged in the sliding hole (7).