CN220119896U - Water-cooled cooling tower auxiliary structure - Google Patents

Abstract

The utility model discloses a water-cooled cooling tower auxiliary structure which comprises a cooling tower and a shell, wherein the cooling tower is positioned in the shell, a cavity is formed in the shell, and fixing blocks are fixedly connected to the front side, the rear side, the left side and the right side of the cooling tower. According to the auxiliary structure of the water-cooled cooling tower, which is provided by the utility model, through the arrangement of the cooling tower, the shell, the cavity, the fixed block, the damping components, the first connecting block and other structural components, the cooling tower can reduce impact damage through a plurality of damping components in the shaking process of the shell, the surface damage caused by vibration impact is avoided, the bottom of the cooling tower can be protected through the use of four lugs and damping springs, the cooling tower has the damping effect, the impact with the ground is reduced, and the auxiliary structure of the water-cooled cooling tower solves the problems that the existing cooling tower does not have the damping effect, the cooling tower can impact with the ground when vibrating, the damage is caused, and the service life is influenced.

Description

Water-cooled cooling tower auxiliary structure

Technical Field

The utility model belongs to the technical field of cooling towers, and particularly relates to an auxiliary structure of a water-cooled cooling tower.

Background

The cooling tower is water-cooled as circulating coolant, water exchanges heat and mass with air flowing through the cooling tower, so that the water temperature is reduced, the existing cooling tower vibrates if faults occur in the using process, the cooling tower is often contacted with the ground, the vibration of the cooling tower is caused to collide with the ground, the surface is damaged easily due to long time, the damage and the using effect of the cooling tower are affected, and the problems in the prior art are that: the cooling tower does not have the cushioning effect, can strike with ground when the cooling tower vibrates, leads to impaired, influences life, therefore proposes a water-cooled cooling tower auxiliary structure for solve above-mentioned problem.

Disclosure of Invention

Aiming at the problems existing in the prior art, the utility model provides a water-cooled cooling tower auxiliary structure which has the advantages of enabling a cooling tower to have a damping effect and reducing the impact with the ground, and solves the problems that the existing cooling tower does not have the damping effect, and the cooling tower can impact with the ground when vibrating, so that the cooling tower is damaged and the service life is influenced.

The utility model discloses a water-cooled cooling tower auxiliary structure, which comprises a cooling tower and a shell, wherein the cooling tower is positioned in the shell, a cavity is formed in the shell, fixed blocks are fixedly connected to the front side, the rear side, the left side and the right side of the cooling tower, and damping components are arranged on the left side and the right side of the fixed blocks.

As the preferred one of the utility model, the left side the said damper assembly includes the first linkage block, the right side of the said linkage block is fixedly connected with left side of the fixed block, the surface of the said first linkage block is movably connected with the drive rod, the left side of the said drive rod is movably connected with the second linkage block, the left side of the said second linkage block is fixedly connected with the elastic spring, the left side of the said elastic spring is fixedly connected with the supporting block, the front side of the said supporting block is fixedly connected with front side of the inner wall of cavity, through setting up damper assembly, the cooling tower can buffer through damper assembly in the inside of the body while shaking, thus reduce the impact that the cooling tower shakes and produces.

As the preferred shape of the front side of the second connecting block is trapezoid, the front side of the second connecting block is slidingly connected with a trapezoid groove, the trapezoid groove is formed in the front side of the inner wall of the cavity, and the second connecting block can only move leftwards or rightwards through the trapezoid groove by arranging the trapezoid groove, so that the trapezoid groove has a limiting and supporting function.

As the preferable mode of the utility model, the top of the inner wall of the cavity is provided with the movable hole, the diameter of the movable hole is larger than that of the cooling tower, and the movable hole can enable the cooling tower to have a movable space through the movable hole, so that the surface of the cooling tower is prevented from being in close contact with the top of the shell, and the damping effect cannot be achieved.

As the preferred mode of the utility model, the bottom of the cooling tower is fixedly connected with four convex blocks which are uniformly distributed, the materials of the four convex blocks are all damping materials, the bottom of the cooling tower is fixedly connected with a damping spring, and the bottom of the damping spring and the bottom of the inner wall of the cavity can play a damping role on the bottom of the cooling tower and reduce the impact damage with the shell by arranging the four convex blocks and the damping spring.

Preferably, the bottom of the front side of the inner wall of the cavity is provided with a connecting hole for fixedly communicating the pipeline with the cooling tower through the connecting hole, and the connecting hole is arranged to enable the pipeline to be fixedly communicated with the cooling tower through the connecting hole, so that water can circulate through the pipeline.

Preferably, the bottom of the inner wall of the cavity is provided with four water outlets which are uniformly distributed and used for discharging water in the shell, and when water exists in the shell, the water can flow out through the four water outlets.

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

1. according to the utility model, through arranging the cooling tower, the shell, the cavity, the fixed block, the damping components, the first connecting block and other structural components, the cooling tower can reduce impact damage through a plurality of damping components in the shaking process of the shell, so that the damage to the surface caused by the impact of vibration is avoided, the bottom of the cooling tower can be protected through the use of four lugs and the damping springs, and the cooling tower has the advantages of damping effect and reduction of impact with the ground.

2. According to the utility model, by arranging structural components such as the cooling tower, the shell, the cavity, the fixed block, the damping component, the first connecting block and the like, the damping spring can generate a deformation force when the cooling tower shakes up and down, the damping can give the cooling tower an identical force, the cooling tower rebounds to the original position, impact damage can be reduced through four lugs, the movable range of the damping spring can be reduced through the restraint of a plurality of damping components in the process of shaking up and down, the fixed block can be moved when the cooling tower shakes back and forth or left and right, the first connecting block can be moved by moving the fixed block, the transmission rod can be rotated in the process of moving the first connecting block, the second connecting block can be moved by rotating the transmission rod, the elastic spring can be moved by the moving process of the second connecting block, so that the elastic spring generates an identical deformation force, the second connecting block can give the same force, the second connecting block drives the movable rod, the first connecting block and the fixed block to rebound to the original position, the cooling tower can be driven to rebound to the original position, the damping and the impact damage can be reduced, the pipeline can be fixedly communicated with the cooling tower through the connecting hole, and water in the shell can flow out through four water outlets.

Drawings

FIG. 1 is a schematic diagram of a structure provided by an embodiment of the present utility model;

FIG. 2 is a cross-sectional perspective view of a housing provided by an embodiment of the present utility model;

FIG. 3 is a schematic top view of an embodiment of the present utility model providing an interior of a housing;

FIG. 4 is a detailed view of a partial structure provided by an embodiment of the present utility model;

fig. 5 is a perspective view of a shock assembly according to an embodiment of the present utility model.

In the figure: 1. a cooling tower; 2. a housing; 3. a cavity; 4. a fixed block; 5. a shock absorbing assembly; 501. a first connection block; 502. a transmission rod; 503. a second connection block; 504. an elastic spring; 505. a support block; 6. a trapezoid groove; 7. a movable hole; 8. a bump; 9. a damping spring; 10. a connection hole; 11. and a water outlet.

Detailed Description

For a further understanding of the utility model, its features and advantages, reference is now made to the following examples, which are illustrated in the accompanying drawings.

The structure of the present utility model will be described in detail with reference to the accompanying drawings.

As shown in fig. 1 to 5, the water-cooled cooling tower auxiliary structure provided by the embodiment of the utility model comprises a cooling tower 1, a shell 2, a cavity 3, a fixed block 4, a damping component 5, a first connecting block 501, a transmission rod 502, a second connecting block 503, an elastic spring 504, a supporting block 505, a trapezoid groove 6, a movable hole 7, a protruding block 8, a damping spring 9, a connecting hole 10 and a water outlet 11, wherein the cooling tower 1 is positioned in the shell 2, the cavity 3 is formed in the shell 2, the front side, the rear side, the left side and the right side of the cooling tower 1 are fixedly connected with the fixed block 4, and the damping component 5 is arranged on the left side and the right side of the front side fixed block 4.

Referring to fig. 2 and 5, the left shock absorbing assembly 5 includes a first connection block 501, the right side of which is fixedly connected with the left side of the fixed block 4, the surface of the first connection block 501 is movably connected with a transmission rod 502, the left side of the transmission rod 502 is movably connected with a second connection block 503, the left side of the second connection block 503 is fixedly connected with an elastic spring 504, the left side of the elastic spring 504 is fixedly connected with a supporting block 505, and the front side of the supporting block 505 is fixedly connected with the front side of the inner wall of the cavity 3.

The scheme is adopted: through setting up damper 5, when cooling tower 1 appears rocking, cooling tower 1 can cushion through damper 5 in the inside of casing 2 to reduce the striking that cooling tower 1 vibration produced.

Referring to fig. 4 and 5, the front side of the second connection block 503 is trapezoidal in shape, the front side of the second connection block 503 is slidably connected with a trapezoidal groove 6, and the trapezoidal groove 6 is opened at the front side of the inner wall of the cavity 3.

The scheme is adopted: by providing the trapezoidal groove 6, the second connection block 503 can move only in the left or right direction through the trapezoidal groove 6, and the use of the trapezoidal groove 6 plays a role of limiting and supporting.

Referring to fig. 1, a movable hole 7 is formed at the top of the inner wall of the cavity 3, and the diameter of the movable hole 7 is larger than that of the cooling tower 1.

The scheme is adopted: through setting up movable hole 7, can make cooling tower 1 have the activity space through movable hole 7, avoid the surface of cooling tower 1 and the top in close contact of casing 2, lead to can not playing the shock attenuation effect.

Referring to fig. 2, the bottom of the cooling tower 1 is fixedly connected with four protruding blocks 8 which are uniformly distributed, the material of the four protruding blocks 8 is damping material, the bottom of the cooling tower 1 is fixedly connected with a damping spring 9, and the bottom of the damping spring 9 and the bottom of the inner wall of the cavity 3 are respectively connected.

The scheme is adopted: by arranging the four lugs 8 and the damping springs 9, the bottom of the cooling tower 1 can be damped, and impact damage with the shell 2 is reduced.

Referring to fig. 1, a connection hole 10 is formed at the bottom of the front side of the inner wall of the cavity 3 for fixedly communicating the pipe with the cooling tower 1 through the connection hole 10.

The scheme is adopted: by providing the connection holes 10, the pipe can be fixedly communicated with the cooling tower 1 through the connection holes 10, thereby circulating water through the pipe.

Referring to fig. 3 and 4, four water outlets 11 are provided at the bottom of the inner wall of the cavity 3 and uniformly distributed for discharging water inside the housing 2.

The scheme is adopted: by providing four water outlets 11, when water is present inside the housing 2, water can flow out through the four water outlets 11.

The working principle of the utility model is as follows:

when the cooling tower 1 shakes up and down, the damping spring 9 can generate a deformation force, the damping can give the cooling tower 1 the same force, the cooling tower 1 is enabled to rebound to the original position, impact damage can be reduced through four lugs 8, the movable range of the damping spring 9 can be reduced through the restraint of a plurality of damping assemblies 5 in the process of shaking up and down, the fixed block 4 can be enabled to move when the cooling tower 1 vibrates back and forth or left and right, the first connecting block 501 can be enabled to move through the movement of the fixed block 4, the transmission rod 502 can be enabled to rotate in the process of moving the first connecting block 501, the second connecting block 503 can be enabled to move through the rotation of the transmission rod 502, the elastic spring 504 can be enabled to move through the process of moving the second connecting block 503, the elastic spring 504 can give the second connecting block 503 the same force, the second connecting block 503 drives the movable rod, the first connecting block 501 and the fixed block 4 to rebound to the original position, the cooling tower 1 can be enabled to rebound to the original position, impact damage is enabled to be reduced, the pipeline is enabled to rebound, and the pipeline is enabled to be communicated with the cooling tower 1 through the four water outlets 11 through the connecting holes 10 and the cooling tower 1.

To sum up: this water-cooled cooling tower auxiliary structure through setting up cooling tower 1, casing 2, cavity 3, fixed block 4, damper 5, first connecting block 501, transfer line 502, second connecting block 503, elastic spring 504, supporting shoe 505, dovetail groove 6, movable hole 7, lug 8, damping spring 9, connecting hole 10 and delivery port 11's cooperation use, has solved current cooling tower and does not possess the cushioning effect, can strike with ground when the cooling tower vibrates, leads to impaired, influences life's problem.

It is noted that relational terms such as first and second, and the like are used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Moreover, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

Although embodiments of the present utility model have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein without departing from the principles and spirit of the utility model, the scope of which is defined in the appended claims and their equivalents.

Claims (7)

1. The utility model provides a cooling tower auxiliary structure of water cooling, includes cooling tower (1) and casing (2), cooling tower (1) are located the inside of casing (2), its characterized in that: the inside of casing (2) has seted up cavity (3), both sides and left and right sides all fixedly connected with fixed block (4) around cooling tower (1), the front side the left and right sides of fixed block (4) all is provided with damper (5).

2. A water-cooled cooling tower auxiliary structure according to claim 1, wherein: left side damper (5) include first connecting block (501), the right side of connecting block and the left side fixed connection of fixed block (4), the surface swing joint of first connecting block (501) has transfer line (502), the left side swing joint of transfer line (502) has second connecting block (503), the left side fixedly connected with elasticity spring (504) of second connecting block (503), the left side fixedly connected with supporting shoe (505) of elasticity spring (504), the front side of supporting shoe (505) and the front side fixed connection of cavity (3) inner wall.

3. A water-cooled cooling tower auxiliary structure according to claim 2, wherein: the shape of the front side of the second connecting block (503) is trapezoid, the front side of the second connecting block (503) is slidingly connected with a trapezoid groove (6), and the trapezoid groove (6) is arranged on the front side of the inner wall of the cavity (3).

4. A water-cooled cooling tower auxiliary structure according to claim 1, wherein: the top of the inner wall of the cavity (3) is provided with a movable hole (7), and the diameter of the movable hole (7) is larger than that of the cooling tower (1).

5. A water-cooled cooling tower auxiliary structure according to claim 1, wherein: the cooling tower is characterized in that four lugs (8) are fixedly connected to the bottom of the cooling tower (1) and uniformly distributed, the four lugs (8) are made of damping materials, damping springs (9) are fixedly connected to the bottom of the cooling tower (1), and the bottoms of the damping springs (9) and the bottoms of the inner walls of the cavities (3) are formed.

6. A water-cooled cooling tower auxiliary structure according to claim 1, wherein: the bottom of the front side of the inner wall of the cavity (3) is provided with a connecting hole (10) for fixedly communicating a pipeline with the cooling tower (1) through the connecting hole (10).

7. A water-cooled cooling tower auxiliary structure according to claim 1, wherein: four water outlets (11) are formed in the bottom of the inner wall of the cavity (3) and are uniformly distributed and used for discharging water in the shell (2).