An integrated shock-absorbing cooling tower
By installing a shock-absorbing base and auxiliary support mechanism at the bottom of the cooling tower, the low-frequency vibration of the cooling tower is absorbed and dispersed, solving the problem of the interference of cooling tower vibration on the lives of residents inside the building, and improving the stability and shock absorption effect of the cooling tower.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Applications(China)
- Current Assignee / Owner
- GUANGZHOU SINGLE BEAM ALL STEEL COOLING TOWER EQUIP CO LTD
- Filing Date
- 2023-12-15
- Publication Date
- 2026-06-05
AI Technical Summary
The low-frequency vibrations generated by the cooling tower during operation are transmitted to the main building through the cooling tower foundation, causing disturbance to the lives of residents inside the building and affecting their normal lives.
A vibration damping base is installed at the bottom of the cooling tower, including an upper frame, a lower frame and a spring connection structure. The damping structure formed by the plug-in parts absorbs low-frequency vibrations, and combined with the support airbag and auxiliary support mechanism, it reduces vibration transmission.
It effectively reduces the impact of low-frequency vibration on the lives of residents inside the building, improves the stability and vibration reduction effect of the cooling tower, reduces the vibration frequency of the fan and motor, and reduces the risk of bolt loosening and corrosion.
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Figure CN122148107A_ABST
Abstract
Description
Technical Field
[0001] This application relates to the field of cooling towers, and in particular to integrated vibration-damping cooling towers. Background Technology
[0002] A cooling tower is a cooling device that integrates multiple technologies such as thermodynamics, aerodynamics, fluid mechanics, structural mechanics, and manufacturing technology. It is usually installed on the roof of residential buildings or shopping malls to cool the circulating cooling water of central air conditioning systems.
[0003] In related technologies, cooling towers include the tower body, air chamber, air guide duct, water collection tray, packing, water distribution system, fan, and other main components. The fan typically uses a four-bladed fan, and the motor is usually a four-pole or six-pole motor. Because four-pole or six-pole motors have relatively high speeds, they usually require a speed reducer. Before installation, a foundation (usually several parallel concrete support beams) needs to be poured on the building's roof slab, and then the cooling tower is installed on the foundation.
[0004] Regarding the aforementioned technologies, during the daily operation of a cooling tower, both its motor and fan generate low-frequency vibrations when rotating. These low-frequency vibrations are transmitted through the main structure of the cooling tower to its foundation, and then from the foundation to the building structure. These low-frequency vibrations produce vibrations and noise, which can easily disrupt the normal lives of residents inside the building. Living in an environment with low-frequency vibrations for a long time can easily cause people to feel irritable and even suffer from insomnia. Therefore, there is room for improvement. Summary of the Invention
[0005] In order to reduce the transmission of low-frequency vibrations generated during the operation of the cooling tower to the interior of the building and thus affect the residents inside the building, this application provides an integrated vibration-damping cooling tower.
[0006] The integrated vibration-damping cooling tower provided in this application adopts the following technical solution: An integrated vibration-damping cooling tower includes a cooling tower body and a vibration-damping base; the vibration-damping base is installed at the bottom of the cooling tower body. The shock-absorbing base includes an upper frame and a lower frame. The upper frame is connected to the bottom of the cooling tower body, and the lower frame is located below the upper frame and overlaps the cooling tower foundation. The upper frame and the lower frame are connected by several springs. Several plug-in parts are provided on the bottom side of the upper frame, and several plug-in portions are provided on the lower frame corresponding to several plug-in parts. The plug-in parts are inserted and fitted into the corresponding plug-in portions.
[0007] By adopting the above technical solution, and by setting a shock-absorbing base at the bottom of the cooling tower body, the low-frequency vibration can be absorbed and dispersed by the damping structure formed by the plug and the plug part on the shock-absorbing base and the spring during subsequent operation of the cooling tower body. This reduces the transmission of low-frequency vibration to the main building and the impact on residents' daily lives.
[0008] Preferably, an upper connecting sleeve and a lower connecting sleeve are coaxially sleeved and fixed at both ends of the spring, and the inner circumferences of both the upper and lower connecting sleeves abut against the outer circumference of the spring. The opposite sides of the upper and lower connecting sleeves are respectively welded to the upper frame and the lower frame.
[0009] By adopting the above technical solution, the two ends of the spring are fixed to the upper frame and the lower frame respectively, while the upper connecting sleeve and the lower connecting sleeve restrict the horizontal displacement of the two ends of the spring, which helps to improve the connection strength and stiffness of the two ends of the spring.
[0010] Preferably, the lower connecting sleeve has several drain ports on its outer periphery.
[0011] By adopting the above technical solution and setting up a drain outlet, rainwater can be discharged in time after falling onto the lower connecting sleeve, reducing the accumulation of rainwater on the lower connecting sleeve and the situation where the lower connecting sleeve and spring are prone to rust.
[0012] Preferably, the connector includes a plurality of connector rods vertically connected to the bottom side of the upper frame; the connector includes a connector block connected to the lower frame, the connector block being positioned below the spring; the top of the connector block has a plurality of connector holes corresponding to the plurality of connector rods, the connector rods being inserted into the connector holes; the connector block is hollow inside, and a drain outlet is provided on one side of the connector block.
[0013] By adopting the above technical solution, the plug-in components are properly fitted together. Furthermore, when the cooling tower body experiences overload due to weight pressure, the bottom side of the upper frame can adhere to the top of the plug-in block of the lower frame to maintain the balance of the cooling tower body, reducing the likelihood of tilting or collapse. The plug-in block is hollow inside, and a drainage outlet is provided on one side. Rainwater that seeps into the plug-in block through the plug-in hole can be promptly discharged through the drainage outlet, reducing the accumulation of rainwater inside the plug-in block.
[0014] Preferably, each of the lower frames has a plurality of grids, and the grids of the lower frame are filled and connected to support plates. A first support airbag is provided on the support plate, and the top of the first support airbag abuts against the bottom of the cooling tower body.
[0015] By adopting the above technical solution, on the one hand, the cooling tower body can be supported by the first support airbag, and on the other hand, the setting of the first support airbag can absorb the low-frequency vibration generated by the cooling tower body during operation, which is conducive to further improving the vibration reduction effect of the vibration damping base.
[0016] Preferably, it also includes an auxiliary support mechanism, which further includes an annular support. The annular support is sleeved on the outer periphery of the cooling tower body, and the bottom of the annular support abuts against the surface of the floor slab at the top of the building. An annular groove is formed on the upper surface of the annular support, and an annular support block is inserted into the annular groove. A second support airbag is provided between the bottom of the annular support block and the bottom wall of the annular groove. The second support airbag is used to support the annular support block. Several connecting seats are protruding from the outer periphery of the bottom of the cooling tower body. The connecting seats are all connected to the annular support block by several connecting bolts.
[0017] By adopting the above technical solution, on the one hand, the auxiliary support mechanism can be used to provide auxiliary support for the cooling tower body, making it easier for the cooling tower body to be more stably supported on the cooling tower foundation. On the other hand, the second support airbag in the annular groove can absorb some of the low-frequency vibrations, reducing the transmission of low-frequency vibrations generated by the cooling tower body during operation to the main building.
[0018] Preferably, an annular connecting plate is connected to the outer periphery of the bottom of the cooling tower body, and the annular connecting plate is located above the connecting seat; a flexible rubber tube is sleeved on the outer periphery of the annular connecting plate, and the bottom end of the flexible rubber tube is sleeved on the outer periphery of the annular support.
[0019] By adopting the above technical solutions, on the one hand, the gap between the cooling tower body and the annular support can be sealed by the annular connecting plate and the flexible sealing pipe, reducing the possibility of rainwater flowing into the cooling tower foundation through the gap between the cooling tower body and the annular support, causing water accumulation at the bottom of the cooling tower body. At the same time, it can reduce the corrosion of the connecting bolts on the connecting plate by rainwater. On the other hand, the low-frequency vibration generated by the cooling tower body can be absorbed by the flexible rubber tube, further reducing the transmission of low-frequency vibration to the main building.
[0020] Preferably, the bottom outer wall of the annular support is also provided with a rubber pad.
[0021] By adopting the above technical solution, the setting of the rubber pad can, on the one hand, improve the sealing between the bottom of the building floor slab of the ring support, which helps to prevent rainwater from flowing into the bottom of the cooling tower foundation through the gap between the ring support and the building floor slab, thus preventing water accumulation at the bottom of the cooling tower foundation and the cooling tower body.
[0022] In summary, this application includes at least one of the following beneficial technical effects: 1. By installing a shock-absorbing base at the bottom of the cooling tower, the low-frequency vibration generated by the cooling tower body is absorbed by the spring of the shock-absorbing base and the cooperation between the plug and the plug block. This reduces the transmission of low-frequency vibration to the main building through the cooling tower foundation, thus reducing the impact on the daily life of residents inside the building.
[0023] 2. By fitting an upper connecting sleeve and a lower connecting sleeve on both ends of the spring, the horizontal displacement of both ends of the spring can be restricted by the upper and lower connecting sleeves, which helps to improve the connection strength and stiffness of both ends of the spring.
[0024] 3. A support plate is installed in the frame of the lower frame. The support plate is equipped with a first support airbag and the top of the first support airbag abuts against the bottom of the cooling tower body. On the one hand, the first support airbag can assist in supporting the cooling tower body. On the other hand, the first support airbag can absorb some of the low-frequency vibrations generated by the cooling tower body during operation, which is conducive to further improving the vibration reduction effect of the shock-absorbing base. Attached Figure Description
[0025] Figure 1 This is a schematic diagram of the overall structure of the cooling tower body and the shock-absorbing base, as shown in Embodiment 1.
[0026] Figure 2 This is a schematic diagram of the structure of the shock-absorbing base used in Embodiment 1.
[0027] Figure 3 and Figure 4 This is a schematic diagram of Embodiment 1 used to illustrate different specifications of shock-absorbing bases.
[0028] Figure 5 yes Figure 2 Enlarged schematic diagram of part A in the middle.
[0029] Figure 6 This is a schematic diagram of the structure of the shock-absorbing base used in Embodiment 2.
[0030] Figure 7 This is a schematic diagram of the overall structure of the cooling tower body and the shock-absorbing base used in Embodiment 3.
[0031] Figure 8 yes Figure 7 Enlarged schematic diagram of section B.
[0032] Explanation of reference numerals in the attached figures: 1. Cooling tower body; 11. Motor; 12. Connecting seat; 2. Vibration damping base; 20. Channel steel; 21. Upper frame; 22. Lower frame; 23. Spring; 231. Upper connecting sleeve; 232. Lower connecting sleeve; 233. Drain outlet; 24. Insert block; 241. Insert hole; 242. Drain outlet; 25. Insert rod; 26. Rock wool strip; 3. Floor slab; 31. Cooling tower foundation; 4. Support plate; 41. First support airbag; 5. Annular support; 50. Annular groove; 51. Annular support block; 52. Second support airbag; 53. Rubber pad; 6. Annular connecting plate; 61. Flexible rubber tube. Detailed Implementation
[0033] The following is in conjunction with the appendix Figure 1-8 This application will be described in further detail.
[0034] Reference Figure 1 The cooling tower foundation 31 includes three sets of concrete support beams arranged parallel to each other on the top floor slab 3 of the building.
[0035] This application discloses an integrated vibration-damping cooling tower, referring to... Figure 1 and Figure 2 The system includes a cooling tower body 1 and a vibration damping base 2. The vibration damping base 2 is located at the bottom of the cooling tower body 1 and includes an upper frame 21, a lower frame 22, and several springs 23. The upper frame 21 is connected to the bottom of the cooling tower body 1, and the lower frame 22 is located directly below the upper frame 21 and rests on the cooling tower foundation 31. The two ends of the springs 23 are respectively connected to the upper frame 21 and the lower frame 22 on the same side. Several plug-in parts are evenly arranged on the bottom side of the upper frame 21, and several plug-in parts are arranged on the top of the lower frame 22 corresponding to the plug-in parts. The plug-in parts are inserted and fitted into the corresponding plug-in parts.
[0036] With the above settings, the damping structure formed by the spring 23 on the damping base 2 and the plug and plug part can absorb the low-frequency vibration generated by the cooling tower body 1 during operation. This reduces the transmission of low-frequency vibration to the building body through the cooling tower foundation 31, thereby reducing the impact of low-frequency vibration on the lives of residents inside the building.
[0037] In this embodiment of the application, the fan of the cooling tower body 1 is an eight-bladed fan with a width of 350mm. Compared with a four-bladed fan under the same width conditions, the operating speed of the eight-bladed fan is much lower than that of the four-bladed fan when the air intake is fixed, which helps to reduce the low-frequency vibration generated during the operation of the fan.
[0038] The motor 11 of the cooling tower body 1 adopts a permanent magnet direct drive motor 11. Compared with the solution of using a four-pole motor 11 or a six-pole motor 11 in traditional cooling towers, the permanent magnet direct drive motor 11 can be directly connected to the fan, without the need to additionally configure a belt reducer to reduce the speed of the motor 11, which is beneficial to reducing the generation of low-frequency vibration; and there is no need to regularly maintain the belt of the belt reducer, reducing the labor maintenance cost.
[0039] All bolt connectors inside the cooling tower body 1 are connected by using anti-loosening bolts and nuts with check washers. After the screw of the anti-loosening bolt is threadedly connected with the nut, the thread on the screw undergoes irregular deformation to lock the internal thread of the nut, realizing forming an integral body of the anti-loosening bolt and the nut, reducing the situation that the bolt connectors inside the cooling tower body 1 become loose due to the low-frequency vibration generated by the cooling tower body 1 subsequently.
[0040] Both the upper frame 21 and the lower frame 22 are spliced by a number of channel steels 20; specifically, in this embodiment, both the upper frame 21 and the lower frame 22 are spliced by three groups of long-side channel steels 20 and two groups of short-side channel steels 20. Both ends of the three groups of long-side channel steels 20 are respectively welded and fixed to the two groups of short-side channel steels 20 to form a "曰" shape. The channel steel 20 of the upper frame 21 is specifically a No. 16 galvanized channel steel 20 with the opening facing upwards. Both the long-side channel steel 20 and the short-side channel steel 20 of the upper frame 21 are welded and fixed to the bottom of the cooling tower body, realizing the connection between the upper frame 21 and the cooling tower body 1. The channel steel 20 of the lower frame 22 is specifically a No. 16 galvanized channel steel 20 with the opening facing downwards.
[0041] In its embodiment, referring to Figure 3 and Figure 4 , according to the specifications and actual needs of the cooling tower, the number of channel steels 20 of the upper frame 21 and the lower frame 22 can be increased and the specifications of the channel steels 20 can be changed.
[0042] Referring to Figure 2 and Figure 5 , the spring 23 is an electrophoretic galvanized spring 23, which is convenient for improving the durability of the spring 23. Both ends of the spring 23 are respectively sleeved and fixed with an upper connection sleeve plate 231 and a lower connection sleeve plate 232. The inner circumferences of both the upper connection sleeve plate 231 and the lower connection sleeve plate 232 are in contact with the outer circumference of the spring 23. The upper connection sleeve plate 231 and the lower connection sleeve plate 232 are respectively welded and fixed to the channel steels 20 on the opposite sides of the upper frame 21 and the lower frame 22. Through the above settings, on the one hand, both ends of the spring 23 are respectively fixed to the upper frame 21 and the lower frame 22. On the other hand, by setting the inner circumferences of both the upper connection sleeve plate 231 and the lower connection sleeve plate 232 to be in contact with the outer circumference of the spring 23, the horizontal displacement of both ends of the spring 23 is restricted by the upper connection sleeve plate 231 and the lower connection sleeve plate 232, which is beneficial to improving the connection strength and stiffness of both ends of the spring 23.
[0043] The lower connecting sleeve 232 has several drainage outlets 233 on its outer periphery. With the drainage outlets 233 in place, rainwater falling into the lower connecting sleeve 232 can be discharged in time through the drainage outlets 233, reducing the likelihood of the lower connecting sleeve 232 rusting due to rainwater accumulation.
[0044] The connector and spring 23 are spaced apart. The connector includes two sets of connector rods 25 vertically welded to the bottom side of the channel steel 20 of the upper frame 21. The connector part includes a connector block 24 welded and fixed to the top side of the channel steel 20 of the lower frame 22; both the connector block 24 and the connector rods 25 are hot-dip galvanized. The top of the connector block 24 has two sets of connector holes 241 corresponding to the two sets of connector rods 25. The two sets of connector rods 25 are respectively inserted into the two sets of connector holes 241, realizing the connector's insertion into the connector part. In this embodiment, the spring 23 is 200mm high and the connector block 24 is 150mm high. By making the spring 23 higher than the connector block 24, the spring 23 can better perform its vibration damping and buffering effect.
[0045] The insertion of the plug rod 25 into the plug hole 241 serves two purposes: firstly, it limits the horizontal displacement of the upper frame 21 and the lower frame 22; secondly, the plug block 24 and the plug rod 25 form a friction damping structure, facilitating the absorption of low-frequency vibrations generated by the cooling tower body 1 by the spring 23 between the upper frame 21 and the lower frame 22. Furthermore, when the cooling tower body 1 experiences a weight overload, the bottom of the upper frame 21 can fit against the top of the plug block 24, and the plug blocks 24 on the lower frame 22 provide support for the upper frame 21 and the cooling tower body 1, preventing the cooling tower body 1 from tilting or collapsing.
[0046] The length of the plug rod 25 is such that when the bottom side of the upper frame 21 abuts against the top of the plug block 24, the bottom end of the plug rod 25 abuts against the inner bottom wall of the plug block 24. This allows the plug rod 25 to work with the plug block 24 to support the upper frame 21 and the cooling tower body 1 when the bottom side of the upper frame 21 is attached to the top of the plug block 24 due to overload caused by the weight pressure of the cooling tower body 1.
[0047] The plug block 24 is hollow inside, and a drain outlet 242 is provided on one side of the plug block 24. With the above configuration, rainwater that enters the plug block 24 through the plug hole 241 can be discharged from the plug block 24 in a timely manner through the drain outlet 242, reducing the accumulation of rainwater inside the plug block 24, which can easily cause corrosion of the plug block 24 and the plug rod 25.
[0048] The implementation principle of Example 1 is as follows: the low-frequency vibration generated by the cooling tower body 1 during operation is transmitted to the bottom of the cooling tower body 1 and then absorbed by the plug-in structure formed by the plug-in part and the plug-in component on the shock-absorbing base 2 in conjunction with the spring 23. This helps to reduce the transmission of the low-frequency vibration generated by the cooling tower body 1 during operation to the main building through the cooling tower foundation 31, which would affect the normal life of residents.
[0049] Example 2 The difference between Example 2 and Example 1 is that: Reference Figure 1 and Figure 6 Both the upper connecting sleeve 231 and the lower connecting sleeve 232 are vertically connected to positioning rods on opposite sides. The positioning rods are inserted into the corresponding channel steel 20. On the one hand, the positioning rods can be used to position the upper connecting sleeve 231 and the lower connecting sleeve 232, making it easier to weld and fix the upper connecting sleeve 231 and the lower connecting sleeve 232 to the corresponding channel steel 20. On the other hand, the positioning rods can restrict the horizontal displacement of the upper connecting sleeve 231 and the lower connecting sleeve 232 on the channel steel 20, which is beneficial to further improve the connection strength between the upper connecting sleeve 231 and the lower connecting sleeve 232 and the channel steel 20.
[0050] Both the upper frame 21 and the lower frame 22 have rock wool strips 26 inside their channel steel 20. The rock wool strips 26 can absorb some low-frequency vibrations, which helps to improve the vibration damping effect of the shock-absorbing base 2.
[0051] Both the upper frame 21 and the lower frame 22 have several frames, with each frame in the upper frame 21 corresponding to one another in the lower frame 22. Each frame in the lower frame 22 is filled with a support plate 4, and the outer periphery of the support plate 4 is welded and fixed to the channel steel 20 around the frame of the lower frame 22, thus securing the support plate 4 within the frame of the lower frame 22. A first support airbag 41 is installed and fixed on the support plate 4. The first support airbag 41 passes through the frame of the upper frame 21, with its top end abutting against the bottom of the cooling tower body 1. This arrangement serves two purposes: firstly, the first support airbag 41 helps absorb the low-frequency vibrations generated during the operation of the cooling tower body 1, further improving the vibration damping effect of the shock-absorbing base 2; secondly, the first support airbag 41 assists in supporting the cooling tower body 1, reducing the concentrated load of the cooling tower body 1 on the channel steel 20 of the upper frame 21, which could lead to deformation and damage to the upper frame 21.
[0052] The implementation principle of Example 2 is similar to that of Example 1, so it will not be described again.
[0053] Example 3 The difference between Example 3 and Example 1 is that: (Refer to...) Figure 7 and Figure 8 The integrated vibration-damping cooling tower also includes an auxiliary support mechanism, which includes an annular support 5. The annular support 5 is fitted around the outer periphery of the cooling tower body 1, and its bottom abuts against the floor slab 3 at the top of the building. An annular groove 50 is formed at the top of the annular support 5, and an annular support block 51 is inserted into the annular groove 50. A second support airbag 52 is also embedded in the annular groove 50. The second support airbag 52 is located between the annular support block 51 and the bottom wall of the annular groove 50, and its top abuts against the bottom end of the annular support block 51, thereby supporting the annular support plate 4. An inflation pipe is connected to the outer periphery of the second support airbag 52. The inflation pipe passes through the annular support 5 and extends outward from the annular support 5, facilitating inflation of the second support airbag 52 through the inflation pipe.
[0054] Several connecting seats 12 are welded and fixed to the outer periphery of the bottom end of the cooling tower body 1. The end of the connecting seat 12 away from the cooling tower body 1 is connected to the top end face of the annular support block 51 by connecting bolts. Through the above arrangement, the cooling tower body 1 can be assisted by the auxiliary support mechanism. On the other hand, the low-frequency vibration generated by the operation of the cooling tower body 1 can be absorbed by the second support airbag 52 in the annular support 5, so as to reduce the transmission of low-frequency vibration to the interior of the building.
[0055] Meanwhile, the ring support 5 can also restrict the flow of rainwater on the floor slab 3 to the cooling tower foundation 31, reducing the accumulation of rainwater on the cooling tower foundation 31, which would cause the bottom of the cooling tower body 1 to be in a damp state for a long time, making the shock-absorbing base 2 and the bottom parts of the cooling tower body 1 prone to corrosion.
[0056] The bottom of the annular support 5 is also provided with a rubber pad 53, which can improve the sealing of the gap between the annular support 5 and the floor slab 3 at the top of the building, and can also absorb low-frequency vibrations and reduce the transmission of low-frequency vibrations to the floor slab 3.
[0057] A ring-shaped connecting plate 6 is also connected around the bottom periphery of the cooling tower body 1. The ring-shaped connecting plate 6 is located above several connecting seats 12. A flexible rubber tube 61 is sleeved on the outer periphery of the ring-shaped connecting plate 6. The inner periphery of the flexible rubber tube 61 is glued and fixed to the outer periphery of the ring-shaped connecting plate 6. The inner periphery of the bottom end of the flexible rubber tube 61 abuts against the outer periphery of the ring support 5. Through the above arrangement, on the one hand, the ring-shaped connecting plate 6 and the flexible rubber tube 61 seal the gap between the cooling tower body 1 and the ring support 5, reducing the flow of rainwater into the cooling tower foundation 31 through the gap between the cooling tower body 1 and the ring support 5 and its accumulation, which would cause the bottom of the cooling tower body 1 and the shock-absorbing base 2 to be in a damp state for a long time; on the other hand, the flexible rubber tube 61 can absorb some of the low-frequency vibration generated by the cooling tower body 1, reducing the transmission of the low-frequency vibration generated by the operation of the cooling tower body 1 to the floor slab 3 of the building.
[0058] The implementation principle of Example 3 is as follows: some of the low-frequency vibrations generated during the operation of the cooling tower body 1 are transmitted to its bottom and absorbed by the plug-in structure formed by the plug-in part and the plug-in component on the shock-absorbing base 2 in conjunction with the spring 23; at the same time, another part of the low-frequency vibrations are transmitted to the annular support block 51 through the connecting seat 12 of the cooling tower body 1 and absorbed by the second support airbag 52 at the bottom of the annular support block 51, thereby reducing the transmission of low-frequency vibrations through the cooling tower foundation 31 to the interior of the building and affecting the normal life of residents.
[0059] The above are all preferred embodiments of this application, and are not intended to limit the scope of protection of this application. Therefore, all equivalent changes made in accordance with the structure, shape and principle of this application should be covered within the scope of protection of this application.
Claims
1. An integrated vibration-damping cooling tower, comprising a cooling tower body (1) and a vibration-damping base (2); the vibration-damping base (2) is installed at the bottom of the cooling tower body (1); The shock-absorbing base (2) includes an upper frame (21) and a lower frame (22). The upper frame (21) is connected to the bottom of the cooling tower body (1). The lower frame (22) is located below the upper frame (21) and overlaps the cooling tower foundation (31). The upper frame (21) and the lower frame (22) are connected by several springs (23). Several plug-in parts are provided on the bottom side of the upper frame (21). Several plug-in parts are provided on the lower frame (22) corresponding to several plug-in parts. The plug-in parts are plugged into and cooperate with the corresponding plug-in parts.
2. The integrated vibration-damping cooling tower according to claim 1, characterized in that: The upper connecting sleeve (231) and the lower connecting sleeve (232) are coaxially sleeved and fixed at both ends of the spring (23). The inner circumferences of the upper connecting sleeve (231) and the lower connecting sleeve (232) abut against the outer circumference of the spring (23). The opposite sides of the upper connecting sleeve (231) and the lower connecting sleeve (232) are respectively welded to the upper frame (21) and the lower frame (22).
3. The integrated vibration-damping cooling tower according to claim 2, characterized in that: The lower connecting sleeve (232) has several drain ports (233) on its outer periphery.
4. An integrated vibration-damping cooling tower according to any one of claims 1-3, characterized in that: The connector includes several plug rods (25) vertically connected to the bottom side of the upper frame (21); the connector includes a plug block (24) connected to the lower frame (22), the plug block (24) being positioned below the spring (23); the top of the plug block (24) has several plug holes (241) corresponding to the several plug rods (25), the plug rods (25) being inserted into the plug holes (241); the plug block (24) is hollow inside, and a drain outlet (242) is provided on one side of the plug block (24).
5. The integrated vibration-damping cooling tower according to claim 1, characterized in that: Each of the lower frame (22) has several frames, and the frames of the lower frame (22) are filled and connected with support plates (4). A first support airbag (41) is provided on the support plate (4), and the top of the first support airbag (41) abuts against the bottom of the cooling tower body (1).
6. The integrated vibration-damping cooling tower according to claim 1, characterized in that: It also includes an auxiliary support mechanism, which includes an annular support (5). The annular support (5) is sleeved on the outer periphery of the cooling tower body (1) and the bottom of the annular support (5) abuts against the surface of the floor slab (3) at the top of the building. An annular groove (50) is provided on the upper surface of the annular support (5). An annular support block (51) is inserted into the annular groove (50). A second support airbag (52) is provided between the bottom of the annular support block (51) and the bottom wall of the annular groove (50). The second support airbag (52) is used to support the annular support block (51). Several connecting seats (12) are protruding from the outer periphery of the bottom of the cooling tower body (1). The connecting seats (12) are all connected to the annular support block (51) by several connecting bolts.
7. The integrated vibration-damping cooling tower according to claim 6, characterized in that: The cooling tower body (1) is connected to an annular connecting plate (6) at the bottom outer periphery, and the annular connecting plate (6) is located above the connecting seat (12); a flexible rubber tube (61) is sleeved on the outer periphery of the annular connecting plate (6), and the bottom end of the flexible rubber tube (61) is sleeved on the outer periphery of the annular support (5).
8. The integrated vibration-damping cooling tower according to claim 6, characterized in that: A rubber pad (53) is also provided on the bottom outer wall of the annular support (5).