A prying block integrated cooling tower structure
The skid-mounted integrated cooling tower structure solves the problems of large footprint and inconvenient maintenance of traditional cooling towers through the synergistic effect of the installation connection mechanism and the drive spring mechanism, achieving rapid installation, improving heat exchange efficiency and system reliability.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- XINHUI CIMC WOOD CO LTD
- Filing Date
- 2025-07-24
- Publication Date
- 2026-06-19
AI Technical Summary
Traditional cooling tower designs occupy a large area, require space for pump rooms and complex piping, and have poor coordination between components, leading to installation difficulties and inconvenient maintenance.
The cooling tower adopts a skid-integrated structure, which achieves a quick and stable connection between the cooling tower shell and the base plate through the installation and connection mechanism. The drive mechanism drives the elastic mechanism to generate efficient vibration, and the integrated components centrally control the operation. The overall structure works in coordination through mechanical linkage and intelligent control.
It enables rapid installation and secure connection of cooling towers, improves assembly efficiency, reduces maintenance costs, enhances heat exchange efficiency and system reliability, extends maintenance cycles, and reduces energy consumption.
Smart Images

Figure CN224382180U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of cooling tower technology, and in particular to a skid-integrated cooling tower structure. Background Technology
[0002] Cooling towers are important heat exchange devices widely used in industrial production and civil applications. They are mainly used to cool hot water to a suitable temperature to meet the needs of production processes, power systems, and air conditioning.
[0003] Cooling towers achieve efficient cooling through direct contact between water and air. Their core principle includes two processes: evaporative cooling and sensible heat exchange. Evaporative cooling utilizes the property that water absorbs a large amount of heat of vaporization when it evaporates (each kilogram of water evaporates and carries away 2450 kJ of heat), and is the main cooling method. Sensible heat exchange, on the other hand, directly conducts heat through the temperature difference between the air and the water.
[0004] Traditional cooling towers require an additional pump room and external piping system for water circulation. This decentralized design has significant drawbacks: it occupies a large area, requires space for the pump room and complex piping, and the components have poor coordination. To address these issues, a skid-mounted integrated cooling tower structure is proposed. Utility Model Content
[0005] To overcome the above shortcomings, this utility model provides a skid-integrated cooling tower structure, which aims to improve the problems of large footprint, need for reserved pump room space and complex piping in the existing technology.
[0006] To achieve the above objectives, the present invention adopts the following technical solution:
[0007] A skid-integrated cooling tower structure includes a cooling tower shell and a base plate. An installation connection mechanism is installed on the side of the cooling tower shell that is close to the base plate. A driving mechanism is installed on the inner wall of the cooling tower shell. A spring mechanism is fixedly connected to the bottom of the driving mechanism. A processing mechanism is provided on the outside of the cooling tower shell.
[0008] The installation and connection mechanism includes four extension blocks, which are respectively fixedly connected to the four bottom corners of the cooling tower shell. The four top corners of the base plate are all fixedly connected to pry bars. The inner walls of the extension blocks and pry bars are all fixedly connected to telescopic rods. The drive end of the telescopic rod is rotatably connected to a control rod. The other end of the control rod is fixedly connected to a semi-circular block. The inner walls of the extension blocks and pry bars are all fixedly connected to a limiting sleeve. A connecting block is fixedly connected to one side of the limiting sleeve. An integrated assembly is fixedly connected to the top of the base plate.
[0009] Through the above technical solution: in the installation and connection mechanism, the extension block and the skid block are precisely locked by pushing the control rod and the semi-circular block through the telescopic rod, ensuring a stable connection between the shell and the base plate. The drive mechanism drives the elastic mechanism to make the packing generate efficient vibration, enhancing the heat exchange effect. The treatment mechanism is responsible for water circulation and heat dissipation. The integrated components centrally control the operation of each system. The entire structure works in concert through mechanical linkage and intelligent control, which significantly improves cooling efficiency while ensuring connection strength, and facilitates transportation and on-site assembly.
[0010] As a further description of the above technical solution:
[0011] The outer side of the semicircular block is slidably connected to the inner wall of the limiting shell, and the outer sides of the two connecting blocks are respectively slidably connected to the inner walls of the extension block and the pry block.
[0012] Through the above technical solution: the semicircular block slides within the limiting shell to achieve precise guidance, and the connecting block moves smoothly within the extension block and the skid block. This design ensures that when the telescopic rod pushes the control rod, the semicircular block can accurately lock the connection part, so that the cooling tower shell and the base plate can quickly and stably complete the docking.
[0013] As a further description of the above technical solution:
[0014] The integrated component includes a control box, the bottom of which is mounted on the top of the base plate. A transformer is mounted on the top of the base plate, and a pump is mounted on the top of the base plate. The input end of the pump is connected to the drain outlet at the bottom of the cooling tower shell via a flange.
[0015] Through the above technical solution: the integrated components operate through a centralized control system controlled by the control box, the transformer provides stable power support, the extraction pump is connected to the drain outlet of the housing via a flange seal to achieve efficient drainage, and all components are integrated into the base plate, resulting in a compact structure that ensures stable operation of the cooling tower and facilitates maintenance.
[0016] As a further description of the above technical solution:
[0017] The driving mechanism includes a motor, one side of which is fixedly connected to one side of the cooling tower shell. A rotating rod is fixedly connected to the driving end of the motor. A rotating disk is fixedly connected to one side of the rotating rod. A pulling rod is rotatably connected to the inner wall of the rotating disk. A packing block is rotatably connected to the bottom of the pulling rod.
[0018] Through the above technical solution: when the motor is running, it drives the rotating rod to rotate, which in turn drives the rotating disk to make a circular motion. The rotating disk is converted into reciprocating motion through the pull rod, which drives the packing block to vibrate regularly in the vertical direction. This mechanical transmission design makes the packing generate high-frequency micro-amplitude vibration, which effectively breaks the surface tension of the water film and increases the gas-liquid contact area. The rigid connection between the motor and the rotating rod ensures efficient power transmission, and the bearing connection between the rotating disk and the pull rod reduces friction loss. The overall mechanism operates smoothly and reliably, significantly improving the heat exchange efficiency of the cooling tower.
[0019] As a further description of the above technical solution:
[0020] The elastic mechanism includes a support frame, the outside of which is fixedly connected to the inner wall of the cooling tower shell. Each of the four top corners of the support frame is fixedly connected to a fixing sleeve. A limiting plate is slidably connected to the inner wall of the fixing sleeve. A connecting rod is fixedly connected to the top of the limiting plate. A spring is sleeved on the outside of the connecting rod.
[0021] Through the above technical solution: when the drive mechanism drives the packing block to move, the connecting rod pushes the limiting plate to slide in the fixed sleeve, causing the spring to compress and deform. The support frame provides stable support, the elastic restoring force of the spring enhances the vibration amplitude of the packing, and the precise fit between the inner wall of the fixed sleeve and the limiting plate ensures smooth movement. This mechanism significantly improves the vibration effect of the packing and optimizes the water-air heat exchange efficiency by storing and releasing energy through the reciprocating energy of the spring.
[0022] As a further description of the above technical solution:
[0023] One end of the spring is fixedly connected to one side of the fixed sleeve, and the other end of the spring is fixedly connected to one end of the limiting plate;
[0024] The above technical solution involves fixing the two ends of the spring to the fixed sleeve and the limiting plate, respectively. When the limiting plate slides, it compresses the spring to store energy and releases energy when it rebounds. This design forms a stable reciprocating elastic potential energy conversion, providing continuous and uniform vibration power to the packing block and enhancing the cooling effect.
[0025] As a further description of the above technical solution:
[0026] The connecting rod is externally slidably connected to the top of the fixed sleeve, and the packing block is externally slidably connected to the inner wall of the cooling tower shell;
[0027] Through the above technical solution: the connecting rod slides precisely on the top of the fixed sleeve to ensure stable vibration transmission; the packing block moves smoothly along the inner wall of the shell to form regular vibration; the double sliding structure effectively reduces friction loss, enabling the elastic mechanism to continuously provide efficient vibration and significantly improve cooling efficiency.
[0028] As a further description of the above technical solution:
[0029] The processing mechanism includes a water inlet pipe, which is fixedly connected to one side of the cooling tower shell. Multiple nozzles are fixedly connected to the bottom of the water inlet pipe, and a fan is installed on the top of the cooling tower shell.
[0030] Through the above technical solution: when the processing mechanism is working, the water inlet pipe delivers cooling water to the nozzle array, which is then atomized and sprayed evenly. The top fan drives air convection to accelerate the evaporation and heat dissipation of the water mist. The spraying and ventilation work together to achieve efficient heat exchange and significantly improve cooling efficiency.
[0031] This utility model has the following beneficial effects:
[0032] 1. In this utility model, the precise alignment of the extension block and the pry bar, and the rotational locking design of the semi-circular block, enable the rapid installation and stable connection of the cooling tower shell and the base plate. The mechanical locking structure driven by the telescopic rod avoids the cumbersome operation of traditional bolt connections, significantly improving assembly efficiency. The split design of the limiting shell and the lubrication structure of the connecting block ensure that it is not prone to jamming during long-term use, reducing maintenance costs. The overall integrated solution solves the problems of difficult alignment and weak connection in traditional decentralized installation, and provides a standardized interface for the subsequent layout of integrated components, making the entire cooling tower system more reliable and easier to maintain.
[0033] 2. In this utility model, the motor drive device drives the packing block to produce regular movement, which, together with the elastic energy storage effect of the spring mechanism, forms a continuous and stable vibration effect. This dynamic operation mode not only ensures that the packing layer is always unobstructed, but also significantly improves the uniformity of water film distribution. The synergistic effect of the spray system and the vibrating packing greatly improves the heat exchange efficiency. At the same time, the fan system maintains stable air flow. The overall design makes the equipment operation more reliable, extends the maintenance cycle, and reduces energy consumption. Attached Figure Description
[0034] Figure 1 This is a three-dimensional schematic diagram of a skid-integrated cooling tower structure proposed in this utility model;
[0035] Figure 2 This is a schematic diagram of the semi-circular block of a skid-integrated cooling tower structure proposed in this utility model;
[0036] Figure 3 This is a schematic diagram of the pull rod of a skid-integrated cooling tower structure proposed in this utility model;
[0037] Figure 4 for Figure 3 Enlarged view of point A in the middle.
[0038] Legend:
[0039] 1. Cooling tower shell; 2. Base plate; 3. Installation and connection mechanism; 31. Extension block; 32. Skid; 33. Telescopic rod; 34. Control rod; 35. Semicircular block; 36. Restricting sleeve; 37. Connecting block; 4. Integrated assembly; 41. Control box; 42. Transformer; 43. Extraction pump; 5. Drive mechanism; 51. Motor; 52. Rotating rod; 53. Rotating disc; 54. Pulling rod; 55. Packing block; 6. Elastic mechanism; 61. Support frame; 62. Fixing sleeve; 63. Restricting plate; 64. Connecting rod; 65. Spring; 7. Processing mechanism; 71. Water inlet pipe; 72. Spray nozzle; 73. Fan. Detailed Implementation
[0040] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments. Obviously, the described embodiments are only some embodiments of the present utility model, and not all embodiments. Based on the embodiments of the present utility model, all other embodiments obtained by those of ordinary skill in the art without creative effort are within the protection scope of the present utility model.
[0041] The following is in conjunction with the appendix Figure 1 - Appendix Figure 4 This application will be described in further detail below.
[0042] Reference Figures 1 to 2 This utility model provides an embodiment of a skid-integrated cooling tower structure, including a cooling tower shell 1 and a base plate 2. The cooling tower shell 1 and the base plate 2 are quickly assembled through an installation connection mechanism 3. This modular design greatly simplifies the installation process. A drive mechanism 5 is installed on the inner wall of the cooling tower shell 1, which can provide stable power output. A spring mechanism 6 is fixedly connected to the bottom of the drive mechanism 5. The two work together to effectively enhance the vibration effect of the packing. A treatment mechanism 7 is provided on the outside of the cooling tower shell 1. This mechanism is made of corrosion-resistant material to ensure long-term stable operation.
[0043] Specifically, the drive mechanism 5 provides power to drive the elastic mechanism 6 to generate high-frequency vibration, which causes the packing layer to vibrate uniformly, enhancing the water film distribution and air contact efficiency. The treatment mechanism 7 performs corrosion-resistant treatment on the external medium to ensure long-term operational stability. The installation and connection mechanism 3 enables rapid modular assembly of the cooling tower shell 1 and the base plate 2. The overall structure significantly improves heat exchange efficiency through the synergistic effect of forced ventilation and vibrating packing, while reducing energy consumption and maintenance costs.
[0044] The mounting and connecting mechanism 3 includes four extension blocks 31, which are made of high-strength material and are fixedly connected to the four bottom corners of the cooling tower shell 1 to ensure a stable connection. Each of the four top corners of the base plate 2 is fixedly connected to a pry bar 32, which has an internal guide structure for precise alignment with the extension blocks 31. Telescopic rods 33 are fixedly connected to the inner walls of both the extension blocks 31 and the pry bars 32. The telescopic rods 33 are hydraulically driven to provide sufficient connection force. A control rod 34 is rotatably connected to the drive end of the telescopic rod 33, and a semi-circular block 35 is fixedly connected to the other end of the control rod 34. The surface of the semicircular block 35 is specially treated to have good wear resistance. The inner walls of the extension block 31 and the pry block 32 are fixedly connected to the limiting sleeve 36. The limiting sleeve 36 adopts a split design for easy maintenance. A connecting block 37 is fixedly connected to one side of the limiting sleeve 36. The connecting block 37 is equipped with a lubrication structure to ensure smooth movement. The top of the base plate 2 is fixedly connected to the integrated component 4. The outside of the semicircular block 35 is slidably connected to the inner wall of the limiting sleeve 36. The outside of the two connecting blocks 37 are slidably connected to the inner walls of the extension block 31 and the pry block 32, respectively. The entire connection mechanism is easy to operate.
[0045] Specifically, precise docking is achieved through the guiding structure of the extension block 31 and the skid block 32. The hydraulically driven telescopic rod 33 pushes the control rod 34 and the semi-circular block 35 to lock, providing a stable connection force. The split design of the limiting sleeve 36 facilitates maintenance. The lubrication structure of the connecting block 37 ensures smooth movement. The high-strength materials of the extension block 31 and the skid block 32 ensure structural stability. The wear-resistant surface of the semi-circular block 35 extends service life. The integrated component 4 further strengthens the overall rigidity, enabling the cooling tower shell 1 and the base plate 2 to be quickly assembled and firmly and reliably.
[0046] refer to Figure 3 and Figure 4 The integrated component 4 includes a control box 41, which has complete protection functions. The bottom of the control box 41 is installed on the top of the base plate 2, and the installation is firm and reliable. A transformer 42 is installed on the top of the base plate 2. The transformer 42 has stable voltage output characteristics. An extraction pump 43 is installed on the top of the base plate 2. The extraction pump 43 adopts a high-quality sealing structure to ensure no leakage. The input end of the extraction pump 43 is connected to the drain port at the bottom of the cooling tower shell 1 through a flange, and the connection is well sealed.
[0047] Specifically, the transformer 42 provides a stable voltage to ensure the reliable operation of the drive mechanism 5 and the extraction pump 43. The extraction pump 43 is connected to the drain port of the cooling tower shell 1 through a sealed flange, which efficiently discharges wastewater without leakage. All components are modularly integrated on the base plate 2, with a compact structure that is easy to maintain. The protective design of the control box 41 ensures that the equipment operates stably under complex working conditions. The whole system works together to achieve efficient heat dissipation and automated management of the cooling tower.
[0048] The drive mechanism 5 includes a motor 51, which is frequency-controlled and can adjust the speed as needed. One side of the motor 51 is fixedly connected to one side of the cooling tower shell 1. The mounting base is equipped with a shock-absorbing device. A rotating rod 52 is fixedly connected to the drive end of the motor 51. The rotating rod 52 is precision-machined to ensure smooth operation. A rotating disk 53 is fixedly connected to one side of the rotating rod 52. The rotating disk 53 is made of high-quality materials and has reliable strength. A pulling rod 54 is rotatably connected to the inner wall of the rotating disk 53. The two ends of the pulling rod 54 are connected by wear-resistant bearings. A packing block 55 is rotatably connected to the bottom of the pulling rod 54. The packing block 55 is made of high-temperature resistant material.
[0049] Specifically, the variable frequency motor 51 controls the rotation speed of the rotating rod 52 by adjusting the speed, which drives the rotating disk 53 to rotate smoothly. The rotating disk 53 drives the packing block 55 to reciprocate through the pull rod 54, which enhances the uniform distribution of the water film in the cooling tower and the efficiency of air contact. The wear-resistant bearing ensures that the pull rod 54 runs smoothly for a long time. The high-temperature resistant packing block 55 is adapted to the humid and hot environment. The vibration damping mounting base of the motor 51 effectively reduces vibration and noise and improves the stability of the system.
[0050] The elastic mechanism 6 includes a support frame 61, which is made of high-quality steel and has a sturdy structure. The support frame 61 is externally fixedly connected to the inner wall of the cooling tower shell 1, and the connection is firm. The top four corners of the support frame 61 are fixedly connected to fixing sleeves 62. The inner wall of the fixing sleeves 62 is lined with wear-resistant material. The inner wall of the fixing sleeves 62 is slidably connected to a limiting plate 63. The surface of the limiting plate 63 is hardened. The top of the limiting plate 63 is fixedly connected to a connecting rod 64, which is made of high-strength material. The connecting rod 64 is externally fitted with a spring 65, which has excellent elastic properties. One end of the spring 65 is fixedly connected to one side of the fixing sleeve 62, and the other end is fixedly connected to one end of the limiting plate 63. The pre-compression amount is moderate. The connecting rod 64 is externally slidably connected to the top of the fixing sleeve 62, with high fitting precision. The packing block 55 is externally slidably connected to the inner wall of the cooling tower shell 1, and the sliding surface is provided with wear-resistant material.
[0051] Specifically, when the drive mechanism 5 moves the packing block 55, the connecting rod 64 slides within the fixed sleeve 62 along with the limiting plate 63, causing the spring 65 to undergo elastic deformation. The rigid structure of the support frame 61 provides stable support for the entire elastic system. The pre-compressed spring 65 enhances the vibration amplitude of the packing block 55 through elastic restoring force. The wear-resistant bushing and hardened limiting plate 63 ensure the reliability of the mechanism's long-term operation, while the high-precision sliding connection effectively reduces friction loss. Through the energy storage-release cycle of the spring 65, this mechanism significantly improves the packing vibration effect, thereby optimizing the water film distribution and heat exchange efficiency.
[0052] The treatment unit 7 includes a water inlet pipe 71, which adopts standard specifications and provides uniform water flow. The water inlet pipe 71 is externally and fixedly connected to one side of the cooling tower shell 1, ensuring reliable connection. Multiple nozzles 72 are fixedly connected to the bottom of the water inlet pipe 71. The nozzles 72 are specially designed for good atomization. A fan 73 is installed on the top of the cooling tower shell 1. The fan 73 is made of high-quality materials and operates smoothly. The entire system is reasonably designed, has high operating efficiency, and is easy to maintain.
[0053] Specifically, the water inlet pipe 71 evenly delivers cooling water to the nozzle 72. The specially designed nozzle 72 atomizes and sprays the water, increasing the water vapor contact area. The top fan 73 forces airflow, creating air convection and accelerating the evaporation and heat dissipation of the atomized water. High-quality materials ensure the long-term stable operation of the fan 73, and the standard-specification water inlet pipe 71 ensures a stable water supply. This mechanism significantly improves cooling efficiency through the synergistic effect of atomized spraying and forced ventilation, while the modular design facilitates maintenance.
[0054] Working principle: When it is necessary to install the cooling tower shell 1 and the base plate 2, the extension block 31 and the skid block 32 are aligned by controlling the cooling tower shell 1. Then, the extension block 31 is moved by moving the cooling tower shell 1. The connecting block 37 slides on the inner wall of the extension block 31 and the skid block 32 until the two limiting sleeves 36 contact, so that the two semicircular blocks 35 also contact, forming a complete circle. Then, the telescopic rod 33 is activated, which drives the control rod 34 to rotate. The rotation of the control rod 34 drives the semicircular block 35 to rotate. The rotation of the semicircular block 35 moves on the inner wall of the limiting sleeve 36. The semicircular block 35 contacts the two limiting sleeves 36 at the same time. The two semicircular blocks 35 tilt by rotating, so that the limiting sleeves 36 are restricted and fixed, thereby connecting the extension block 31 and the skid block 32. Integration is achieved by arranging the integrated component 4 on the top of the base plate 2.
[0055] When the cooling tower shell 1 is in operation, water is added through the inlet pipe 71 and discharged from the nozzle 72. The fan 73 is started to achieve cooling. During this process, the water is processed by the packing block 55. At this time, the motor 51 can be started, which will drive the rotating rod 52 to rotate. The rotation of the rotating rod 52 will drive the rotating disk 53 to rotate. The rotating disk 53 will drive the pulling rod 54 to rotate. The rotation of the pulling rod 54 can pull the packing block 55 to move. The movement of the packing block 55 will generate vibration, which will prevent the packing block 55 from clogging. During the movement of the packing block 55, the packing block 55 can drive the connecting rod 64 to move. At this time, the connecting rod 64 will drive the limiting plate 63 to move. The limiting plate 63 will compress the spring 65, causing the spring 65 to deform and generate elastic potential energy, thereby improving the vibration efficiency and further preventing the packing block 55 from clogging.
[0056] The embodiments described in this specific implementation are preferred embodiments of this application and are not intended to limit the scope of protection of this application. Identical components are represented by the same reference numerals. Therefore, all equivalent changes made to the structure, shape, and principle of this application should be covered within the scope of protection of this application.
Claims
1. A skid-mounted integrated cooling tower structure, comprising a cooling tower shell (1) and a base plate (2), characterized in that: An installation connection mechanism (3) is installed on the side of the cooling tower shell (1) and the bottom plate (2). A drive mechanism (5) is installed on the inner wall of the cooling tower shell (1). A spring mechanism (6) is fixedly connected to the bottom of the drive mechanism (5). A processing mechanism (7) is provided on the outside of the cooling tower shell (1). The installation and connection mechanism (3) includes four extension blocks (31), which are fixedly connected to the bottom four corners of the cooling tower shell (1). The top four corners of the base plate (2) are fixedly connected to pry bars (32). The inner walls of the extension blocks (31) and the pry bars (32) are fixedly connected to telescopic rods (33). The drive end of the telescopic rod (33) is rotatably connected to a control rod (34). The other end of the control rod (34) is fixedly connected to a semi-circular block (35). The inner walls of the extension blocks (31) and the pry bars (32) are fixedly connected to a limiting sleeve (36). One side of the limiting sleeve (36) is fixedly connected to a connecting block (37). The top of the base plate (2) is fixedly connected to an integrated assembly (4).
2. The skid-mounted integrated cooling tower structure according to claim 1, characterized in that: The outer side of the semicircular block (35) is slidably connected to the inner wall of the limiting shell (36), and the outer sides of the two connecting blocks (37) are respectively slidably connected to the inner walls of the extension block (31) and the pry bar (32).
3. The skid-mounted integrated cooling tower structure according to claim 1, characterized in that: The integrated component (4) includes a control box (41), the bottom of which is mounted on the top of the base plate (2). A transformer (42) is mounted on the top of the base plate (2), and a pump (43) is mounted on the top of the base plate (2). The input end of the pump (43) is connected to the drain outlet at the bottom of the cooling tower shell (1) via a flange.
4. The skid-mounted integrated cooling tower structure according to claim 1, characterized in that: The drive mechanism (5) includes a motor (51), one side of which is fixedly connected to one side of the cooling tower shell (1). A rotating rod (52) is fixedly connected to the drive end of the motor (51). A rotating disk (53) is fixedly connected to one side of the rotating rod (52). A pulling rod (54) is rotatably connected to the inner wall of the rotating disk (53). A packing block (55) is rotatably connected to the bottom of the pulling rod (54).
5. The skid-mounted integrated cooling tower structure according to claim 4, characterized in that: The elastic mechanism (6) includes a support frame (61), the outside of which is fixedly connected to the inner wall of the cooling tower shell (1). The top four corners of the support frame (61) are fixedly connected to a fixing sleeve (62). The inner wall of the fixing sleeve (62) is slidably connected to a limiting plate (63). The top of the limiting plate (63) is fixedly connected to a connecting rod (64), and a spring (65) is sleeved on the outside of the connecting rod (64).
6. The skid-mounted integrated cooling tower structure according to claim 5, characterized in that: One end of the spring (65) is fixedly connected to one side of the fixed sleeve (62), and the other end of the spring (65) is fixedly connected to one end of the limiting plate (63).
7. The skid-mounted integrated cooling tower structure according to claim 5, characterized in that: The connecting rod (64) is externally slidably connected to the top of the fixed sleeve (62), and the packing block (55) is externally slidably connected to the inner wall of the cooling tower shell (1).
8. The skid-mounted integrated cooling tower structure according to claim 1, characterized in that: The processing mechanism (7) includes a water inlet pipe (71), the outside of which is fixedly connected to one side of the cooling tower shell (1), and a plurality of nozzles (72) are fixedly connected to the bottom of the water inlet pipe (71). A fan (73) is installed on the top of the cooling tower shell (1).