Angle-adjustable air cooler device

CN224343637UActive Publication Date: 2026-06-09PANJIN HUANBANG ENERGY SAVING EQUIP CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
PANJIN HUANBANG ENERGY SAVING EQUIP CO LTD
Filing Date
2025-07-07
Publication Date
2026-06-09

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Abstract

The utility model relates to cooling device technical field discloses the angle adjustable air cooler device, including base, the top of base is opened and is limited in position direction sliding slot, the inside of base is provided with fixed mechanism, fixed mechanism is used for fixed device, the top of base is provided with rotating mechanism, the top of rotating mechanism is provided with cooling mechanism, the bottom of rotating mechanism is provided with drive assembly, drive assembly is used for driving fixed mechanism and rotating mechanism operation, the top of cooling mechanism is provided with adjusting mechanism, adjusting mechanism is used for adjusting the direction that cooling airflow discharged, in the utility model, when adjusting air cooler angle, servo motor no.
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Description

Technical Field

[0001] This utility model relates to the field of cooling device technology, and in particular to an adjustable-angle air cooler device. Background Technology

[0002] An air cooler is a heat exchange device used in industrial production processes. Its function is to remove heat through a gas medium, thereby cooling a specific object. It transfers the heat generated by the equipment to the air, keeping the equipment temperature within a reasonable range, ensuring stable and efficient operation, extending the equipment's service life, and guaranteeing the continuity and stability of the production process.

[0003] Adjustable-angle air coolers are optimized and upgraded versions of traditional air coolers. They break the limitations of fixed angles and can flexibly adjust their relative angle to the heat source according to actual needs. This adjustability enhances the adaptability of the air cooler. Whether in production workshops with different layouts or equipment with varying heat sources, adjustable-angle air coolers can adjust the angle to allow the cooling airflow to act more precisely on the heat-generating area, thereby improving cooling efficiency and more effectively meeting diverse cooling needs.

[0004] Traditional air cooler devices rely on manual operation to adjust their angle, which not only consumes a lot of manpower but also exposes operators to harsh environments with high temperatures and high dust levels, increasing workload and risks. Existing technologies use automated air cooler angle adjustment mechanisms to eliminate the need for frequent manual operation at the air cooler installation location, improving overall work efficiency and protecting the health and safety of operators. However, in actual use, after the air cooler is adjusted, the existing adjustment mechanism relies on only a single connection point and contact surface to maintain its fixation. When the air cooler is subjected to the external force of airflow impact, this single support cannot guarantee its stability, resulting in angle deviation, causing cooling area deviation and reduced cooling efficiency. Utility Model Content

[0005] To overcome the above shortcomings, this utility model provides an adjustable-angle air cooler device, which aims to improve the problem that the angle of the air cooler will deviate when subjected to the external force of airflow impact in the prior art.

[0006] To achieve the above objectives, the present invention adopts the following technical solution: an adjustable-angle air cooler device, including a base, a limiting guide groove formed on the top of the base, a fixing mechanism provided inside the base for fixing the device, a rotating mechanism provided on the top of the base, a cooling mechanism provided on the top of the rotating mechanism, a driving component provided at the bottom of the rotating mechanism for driving the fixing mechanism and the rotating mechanism, and an adjusting mechanism provided on the top of the cooling mechanism for adjusting the direction of the cooling airflow.

[0007] The fixing mechanism includes two U-shaped blocks. The bottoms of the two U-shaped blocks are respectively fixedly connected to the left and right ends of the inner bottom side of the base. Sliding pressure blocks are slidably connected to the inner walls of the two U-shaped blocks. Anti-slip pads are fixedly connected to the opposite sides of the two sliding pressure blocks. The same bidirectional lead screw is threaded to the inner walls of the two U-shaped blocks. A transmission bevel gear is fixedly connected to the middle of the bidirectional lead screw. A rotating guide ring is rotatably connected to the inner wall of the limiting guide groove. The opposite sides of the two anti-slip pads are respectively in contact with the inner wall of the rotating guide ring.

[0008] As a further description of the above technical solution:

[0009] The rotating mechanism includes a turntable, the bottom of which is fixedly connected to the top of a rotating guide ring. A transmission gear is fixedly connected to the bottom of the turntable. Mounting slots are provided on both the left and right sides of the top of the turntable, and support frames are fixedly connected to the inner walls of both mounting slots.

[0010] As a further description of the above technical solution:

[0011] The drive assembly includes a second servo motor, the bottom of which is fixedly connected to the inner bottom side of the base. The output end of the second servo motor is fixedly connected to a second drive gear, which meshes with a transmission gear plate. The rear end of the inner bottom side of the base is fixedly connected to a third servo motor, the output end of which is fixedly connected to a drive bevel gear, which meshes with a transmission bevel gear.

[0012] As a further description of the above technical solution:

[0013] The cooling mechanism includes a cooling body, the bottom left and right sides of which are fixedly connected to the top of the support frame, a front tube box fixedly connected to the left end of the cooling body, a rear tube box fixedly connected to the right end of the cooling body, the same heat exchange tube group fixedly connected to the adjacent side of the rear tube box and the front tube box, multiple baffles fixedly connected at equal intervals to the inner wall of the cooling body, an air inlet pipe fixedly connected to the rear left end of the cooling body, and a cold air outlet pipe fixedly connected to the top right end of the cooling body.

[0014] As a further description of the above technical solution:

[0015] The adjustment mechanism includes an air guide pipe, the bottom end of which is fixedly connected to the top end of a cold air exhaust pipe. A limiting groove is formed at the right end of the air guide pipe, and a limiting ring is rotatably connected to the inner wall of the limiting groove. A rotating air guide pipe is fixedly connected to the right side of the limiting ring. A transmission gear is fixedly connected to the outer wall of the rotating air guide pipe. A servo motor is fixedly connected to the top of the air guide pipe, and a drive gear is fixedly connected to the output end of the servo motor. The drive gear meshes with the transmission gear. An air guide assembly is provided inside the rotating air guide pipe.

[0016] As a further description of the above technical solution:

[0017] The air guiding assembly includes multiple air guiding plates, the front and rear ends of which are rotatably connected to the inner wall of the rotating air guiding pipe. The inner walls of the multiple air guiding plates are rotatably connected to the same connecting rod component. A telescopic rod is fixedly connected to the top of the rotating air guiding pipe, and the bottom end of the telescopic rod is fixedly connected to the top end of the connecting rod component.

[0018] As a further description of the above technical solution:

[0019] The inner walls of the two U-shaped blocks are fixedly connected with buffer pads, and the two buffer pads are respectively attached to the corresponding sliding pressure blocks.

[0020] As a further description of the above technical solution:

[0021] The sliding pressure block is fixedly connected to the front and rear sides of the sliding pressure block. The inner walls of the two U-shaped blocks are provided with a sliding groove on the front and rear sides. The inner walls of the two sliding grooves are slidably connected to the outer walls of the corresponding limiting guide blocks.

[0022] This utility model has the following beneficial effects:

[0023] 1. In this utility model, when adjusting the angle of the air cooler, servo motor two starts, and its active gear drives the transmission gear disk, causing the turntable to rotate around the axis of the rotating guide ring, thereby driving the cooling mechanism to rotate to complete the angle adjustment. At the same time, the operation of the cooling mechanism realizes the cooling and discharge of gas. When it is necessary to fix the output angle of the cooling mechanism, servo motor three starts, and the active bevel gear drives the bidirectional lead screw, causing the sliding pressure block to slide in the opposite direction. Its anti-slip pad is tightly attached to the inner wall of the rotating guide ring, fixing the rotating mechanism and the cooling mechanism to prevent angle deviation.

[0024] 2. In this utility model, a servo motor is started. The motor is fixed at the top of the air guide pipe. Its driving gear meshes with the transmission gear on the outer wall of the rotating air guide pipe, driving the rotating air guide pipe to rotate around the limiting ring in the limiting groove, initially adjusting the airflow direction. The air guide assembly consists of an air guide plate, a connecting rod assembly, and a telescopic rod. When fine adjustment is required, the telescopic rod is controlled to extend and retract, driving the connecting rod assembly, which in turn causes the air guide plate to rotate, accurately adjusting the airflow direction, achieving flexible adjustment, and improving the adaptability of the cooler. Attached Figure Description

[0025] Figure 1 This is a perspective view of the adjustable-angle air cooler device proposed in this utility model;

[0026] Figure 2 This is a front view of the adjustable-angle air cooler device proposed in this utility model;

[0027] Figure 3 This is a schematic diagram of the cooling mechanism of the adjustable-angle air cooler device proposed in this utility model;

[0028] Figure 4 This is a schematic diagram of the rotating mechanism of the adjustable-angle air cooler device proposed in this utility model;

[0029] Figure 5 This is a schematic diagram of the fixing mechanism of the adjustable-angle air cooler device proposed in this utility model;

[0030] Figure 6 This is a schematic diagram of the adjustment mechanism of the adjustable angle air cooler device proposed in this utility model.

[0031] Legend:

[0032] 1. Base; 2. Fixing mechanism; 201. U-shaped block; 202. Sliding pressure block; 203. Anti-slip pad; 204. Two-way lead screw; 205. Transmission bevel gear; 206. Rotating guide ring; 3. Adjusting mechanism; 301. Air guide pipe; 302. Limiting groove one; 303. Limiting ring; 304. Rotating air guide pipe; 305. Transmission gear; 306. Servo motor one; 307. Drive gear one; 308. Air guide assembly; 3081. Air guide plate; 3082. Connecting rod assembly; 3083. Telescopic rod; 4. Limiting... 5. Guide chute; 6. Rotating mechanism; 501. Turntable; 502. Transmission gear plate; 503. Mounting slot; 504. Support frame; 7. Drive assembly; 601. Servo motor II; 602. Drive gear II; 603. Servo motor III; 604. Drive bevel gear; 8. Cooling mechanism; 701. Cooling body; 702. Front tube box; 703. Rear tube box; 704. Inlet pipe; 705. Cold air exhaust pipe; 706. Heat exchange tube assembly; 707. Baffle plate; 8. Buffer pad; 9. Limiting guide block; 10. Chute I. Detailed Implementation

[0033] 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.

[0034] Reference Figure 3 , Figure 4 and Figure 5 An embodiment of this utility model provides an adjustable-angle air cooler device, including a base 1, which provides a stable support foundation for the entire device. A limiting guide groove 4 is provided on the top of the base 1. The limiting guide groove 4 is used to provide a rotation track for the rotating guide ring 206 and limit its position. A fixing mechanism 2 is provided inside the base 1. The fixing mechanism 2 is used to fix the device firmly in a specific position. The fixing mechanism 2 is used to fix the device. A rotating mechanism 5 is provided on the top of the base 1. The rotating mechanism 5 can drive the cooling mechanism 7 to rotate and adjust the angle. The cooling mechanism 7 is provided on the top of the rotating mechanism 5. The cooling mechanism 7 is responsible for cooling the gas. A drive assembly 6 is provided at the bottom of the rotating mechanism 5. The drive assembly 6 provides a power source for the operation of the fixing mechanism 2 and the rotating mechanism 5. The drive assembly 6 is used to drive the fixing mechanism 2 and the rotating mechanism 5 to operate. An adjustment mechanism 3 is provided on the top of the cooling mechanism 7. The adjustment mechanism 3 can adjust the direction of the cooling airflow. The adjustment mechanism 3 is used to adjust the direction of the cooling airflow.

[0035] The fixing mechanism 2 includes two U-shaped blocks 201, which provide sliding tracks and support for the sliding pressure blocks 202. The bottoms of the two U-shaped blocks 201 are respectively fixedly connected to the left and right ends of the inner bottom side of the base 1, ensuring that the U-shaped blocks 201 are stably installed in the base 1. The inner walls of the two U-shaped blocks 201 are slidably connected to the sliding pressure blocks 202, which can slide within the U-shaped blocks 201 to fix and release the rotating guide ring 206. Anti-slip pads 203 are fixedly connected to the opposite sides of the two sliding pressure blocks 202. The anti-slip pads 203 increase the friction with the inner wall of the rotating guide ring 206, enhancing the fixing effect. As a result, the inner walls of the two U-shaped blocks 201 are threaded with the same bidirectional lead screw 204. When the bidirectional lead screw 204 rotates, it can drive the two sliding pressure blocks 202 to move towards and away from each other. The middle part of the bidirectional lead screw 204 is fixedly connected with a transmission bevel gear 205, which is used to transmit power from the driving bevel gear 604. The inner wall of the limiting guide groove 4 is rotatably connected with a rotating guide ring 206. The rotating guide ring 206 can rotate in the limiting guide groove 4 and support the rotating mechanism 5. The two anti-slip pads 203 are respectively attached to the inner wall of the rotating guide ring 206 on the opposite side, so as to clamp and fix the rotating guide ring 206.

[0036] The rotating mechanism 5 includes a turntable 501, which serves as a support platform and connects the rotating guide ring 206 to the cooling mechanism 7. The bottom of the turntable 501 is fixedly connected to the top of the rotating guide ring 206 to ensure that the turntable 501 and the rotating guide ring 206 rotate synchronously. A transmission gear 502 is fixedly connected to the bottom of the turntable 501. The transmission gear 502 meshes with the drive gear 602 to receive power and realize the rotation of the turntable 501. The top left and right sides of the turntable 501 are provided with mounting slots 503 for mounting support frames 504. The inner walls of the two mounting slots 503 are fixedly connected to the support frames 504, which provide support for the cooling mechanism 7.

[0037] The drive assembly 6 includes a second servo motor 601, which serves as the power source for the rotation of the rotating mechanism 5. The bottom of the second servo motor 601 is fixedly connected to the inner bottom side of the base 1 to ensure the stable installation of the second servo motor 601. The output end of the second servo motor 601 is fixedly connected to a second drive gear 602, which transmits the power of the second servo motor 601 to the transmission gear disk 502. The second drive gear 602 meshes with the transmission gear disk 502 to realize power transmission and drive the turntable 501 to rotate. The rear end of the inner bottom side of the base 1 is fixedly connected to a third servo motor 603, which provides power for the operation of the fixed mechanism 2. The output end of the third servo motor 603 is fixedly connected to a drive bevel gear 604, which transmits the power of the third servo motor 603 to the transmission bevel gear 205. The drive bevel gear 604 meshes with the transmission bevel gear 205 to make the bidirectional lead screw 204 rotate and drive the sliding pressure block 202 to move.

[0038] The cooling mechanism 7 includes a cooling body 701, which is the main site for gas cooling. The bottom left and right sides of the cooling body 701 are fixedly connected to the top of the support frame 504, ensuring that the cooling body 701 is stably installed on the rotating mechanism 5. A front tube box 702 is fixedly connected to the left end of the cooling body 701. The front tube box 702 is used to guide the gas into the heat exchange tube assembly 706. A rear tube box 703 is fixedly connected to the right end of the cooling body 701. The rear tube box 703 is used to guide the cooled gas out of the heat exchange tube assembly 706. The rear tube box 703 and the front tube box... The same heat exchange tube group 706 is fixedly connected to each adjacent side of 702. The heat exchange tube group 706 realizes heat exchange between the gas and the outside. Multiple baffles 707 are fixedly connected at equal intervals to the inner wall of the cooling body 701. The baffles 707 change the gas flow path and enhance the heat exchange effect. An air inlet pipe 704 is fixedly connected to the rear left end of the cooling body 701. The air inlet pipe 704 is used to introduce the outside gas to be cooled into the cooling body 701. A cold air exhaust pipe 705 is fixedly connected to the top right end of the cooling body 701. The cold air exhaust pipe 705 is used to exhaust the cooled gas.

[0039] Specifically, when the angle of the air cooler needs to be adjusted, servo motor 2 601 starts, and its output end is connected to drive gear 2 602. Drive gear 2 602 rotates, and through the meshing transmission between the gears, it drives the transmission gear disk 502 to rotate, thereby causing the turntable 501 to rotate around the central axis of the rotating guide ring 206 in the limiting guide groove 4. Since the bottom left and right sides of the cooling mechanism 7 are respectively fixedly connected to the support frame 504 in the mounting groove 503 on the top left and right sides of the turntable 501, the rotation of the turntable 501 synchronously drives the cooling mechanism 7 to rotate, realizing the adjustment of the air cooler angle. When the cooling mechanism 7 is running, the outside gas enters the cooling body 701 from the air inlet pipe 704. In the cooling body 701, the gas is guided by the baffle 707 to flow in a tortuous manner, and fully exchanges heat with the heat exchange tube group 706 between the front tube box 702 and the rear tube box 703 to achieve cooling. The cooled gas is finally discharged from the cold gas outlet pipe 705. When the output angle of the cooling mechanism 7 needs to be fixed, servo motor 3 603 starts. Its output end is connected to the active bevel gear 604, which meshes with the transmission bevel gear 205 to drive the bidirectional lead screw 204 to rotate, causing the two sliding pressure blocks 202 to slide along the axial direction of the bidirectional lead screw 204 on the inner wall of the U-shaped block 201. The two sliding pressure blocks 202 move in opposite directions, and anti-slip pads 203 are fixedly connected to the opposite side of the two sliding pressure blocks 202. As the sliding pressure blocks 202 slide, the anti-slip pads 203 gradually come into close contact with the inner wall of the rotating guide ring 206. Due to the large friction of the anti-slip pads 203, and the fact that the two anti-slip pads 203 apply pressure to the rotating guide ring 206 from opposite sides, the rotating guide ring 206 is firmly fixed in the limiting guide groove 4 and cannot rotate freely. The bottom of the turntable 501 is fixedly connected to the top of the rotating guide ring 206, thereby making the entire rotating mechanism 5 and the cooling mechanism 7 installed on it stable and fixed, ensuring that the air cooler will not shift its angle due to the external force of the airflow impact after the angle is adjusted.

[0040] Reference Figure 1 , Figure 2 and Figure 6The regulating mechanism 3 includes an air guide pipe 301, which guides the cooling airflow discharged from the cold air exhaust pipe 705. The bottom end of the air guide pipe 301 is fixedly connected to the top end of the cold air exhaust pipe 705 to achieve communication with the cold air exhaust pipe 705 and ensure smooth airflow transmission. A limiting groove 302 is provided at the right end of the air guide pipe 301. The limiting groove 302 provides rotation space for the limiting ring 303 and restricts its position. The inner wall of the limiting groove 302 is rotatably connected to the limiting ring 303, allowing the limiting ring 303 to rotate flexibly within the limiting groove 302. A rotating air duct 304 is fixedly connected to the right side of 303, causing the rotating air duct 304 to change direction as the limiting ring 303 rotates. A transmission gear 305 is fixedly connected to the outer wall of the rotating air duct 304, which transmits power to drive the rotating air duct 304 to rotate. A servo motor 306 is fixedly connected to the top of the air duct 301, which provides power for the rotation of the rotating air duct 304. A drive gear 307 is fixedly connected to the output end of the servo motor 306, which drives the servo motor 304 to rotate. The power of motor 306 is transmitted to transmission gear 305. Drive gear 307 meshes with transmission gear 305 to achieve power transmission, thereby driving the rotating air duct 304 to rotate. An air guide assembly 308 is installed inside the rotating air duct 304. The air guide assembly 308 is used to more precisely adjust the direction of airflow passing through the rotating air duct 304. The air guide assembly 308 includes multiple air guide plates 3081, which work together to change the airflow direction. The front and rear ends of the air guide plates 3081 are rotatably connected to the inner wall of the rotating air duct 304. This allows the air guide plate 3081 to rotate flexibly within the rotating air guide duct 304. The inner walls of multiple air guide plates 3081 are rotatably connected to the same connecting rod component 3082. The connecting rod component 3082 is used to synchronously control the rotation of multiple air guide plates 3081. The top of the rotating air guide duct 304 is fixedly connected to a telescopic rod 3083. The telescopic rod 3083 controls the movement of the connecting rod component 3082 by extending and retracting. The bottom end of the telescopic rod 3083 is fixedly connected to the top end of the connecting rod component 3082 to ensure that the extension and retraction of the telescopic rod 3083 can be accurately transmitted to the connecting rod component 3082.

[0041] Specifically, when adjusting the cooling airflow direction, servo motor 306 is activated. Servo motor 306 is fixed to the top of the air duct 301. Its output drive gear 307 meshes with the transmission gear 305 on the outer wall of the rotating air duct 304. The motor's rotation drives the drive gear 307 to rotate, and through gear meshing, the transmission gear 305 rotates, thereby causing the rotating air duct 304 to rotate around the limiting ring 303 within the limiting groove 302, thus adjusting the cooling airflow direction. The air guide assembly 308 further precisely adjusts the airflow direction. The air guide assembly 308 consists of multiple air guide plates 3081, connecting rod components 3082, and telescopic rods 3083. When more precise airflow adjustment is needed, the telescopic rods 3083 are controlled. The telescopic rod 3083 is connected at its bottom to the top of the connecting rod component 3082. Its telescopic movement will drive the connecting rod component 3082 to move. Since the inner walls of multiple air guide plates 3081 are rotatably connected to the connecting rod component 3082, and the front and rear ends of the air guide plates 3081 are also rotatably connected to the inner wall of the rotating air guide duct 304, the movement of the connecting rod component 3082 will drive the air guide plates 3081 to rotate around the connection point with the inner wall of the rotating air guide duct 304, changing the angle of the air guide plates 3081, thereby precisely adjusting the flow direction of the cooling airflow in the rotating air guide duct 304, realizing precise control of the cooling airflow discharge direction, realizing flexible adjustment of the cooling airflow discharge direction of the air cooler, and improving the adaptability of the air cooler to different heat dissipation demand scenarios.

[0042] Reference Figure 4 and Figure 5 The inner walls of the two U-shaped blocks 201 are fixedly connected with buffer pads 8. The buffer pads 8 can reduce the impact on the inner walls of the U-shaped blocks 201 when the sliding pressure block 202 slides. The two buffer pads 8 are respectively attached to the corresponding sliding pressure block 202, so that the buffer pads 8 can effectively play a buffering role. The front and rear sides of the sliding pressure block 202 are fixedly connected with limit guide blocks 9. The limit guide blocks 9 are used to limit the sliding direction of the sliding pressure block 202. The front and rear sides of the inner walls of the two U-shaped blocks 201 are provided with sliding grooves 10. The sliding grooves 10 provide a sliding path for the limit guide blocks 9. The inner walls of the two sliding grooves 10 are respectively slidably connected to the outer walls of the corresponding limit guide blocks 9, ensuring that the limit guide blocks 9 slide smoothly in the sliding grooves 10.

[0043] Specifically, when the sliding pressure block 202 slides within the U-shaped block 201, the buffer pad 8 can buffer the impact force generated, preventing damage to the U-shaped block 201 and the sliding pressure block 202. At the same time, the limiting guide block 9 cooperates with the slide groove 10 to restrict the sliding direction of the sliding pressure block 202, so that it can only slide smoothly along the slide groove 10, ensuring the stability and accuracy of the device operation.

[0044] Working principle: When the angle of the air cooler needs to be adjusted, servo motor 2 601 starts, and its output end is connected to drive gear 2 602. Drive gear 2 602 rotates, and through the meshing transmission between the gears, it drives the transmission gear disk 502 to rotate, thereby causing the turntable 501 to rotate around the central axis of the rotating guide ring 206 in the limit guide groove 4. Since the bottom left and right sides of the cooling mechanism 7 are respectively fixedly connected to the support frame 504 in the top left and right mounting grooves 503 of the turntable 501, the rotation of the turntable 501 synchronously drives the cooling mechanism 7 to rotate, realizing the adjustment of the air cooler angle. When the cooling mechanism 7 is running, the outside gas enters the cooling body 701 from the air inlet pipe 704. In the cooling body 701, the gas is guided by the baffle 707 to flow in a tortuous manner, and fully exchanges heat with the heat exchange tube group 706 between the front tube box 702 and the rear tube box 703 to achieve cooling. The cooled gas is finally discharged from the cold gas outlet pipe 705. When it is necessary to fix the output angle of the cooling mechanism 7, servo motor 3 603 starts. Its output end is connected to the active bevel gear 604, which meshes with the transmission bevel gear 205 to drive the bidirectional lead screw 204 to rotate, so that the two sliding pressure blocks 202 slide along the axial direction of the bidirectional lead screw 204 on the inner wall of the U-shaped block 201. The two sliding pressure blocks 202 move in opposite directions. Anti-slip pads 203 are fixedly connected to the side of the two sliding pressure blocks 202 that are far apart. As the sliding pressure blocks 202 slide, the anti-slip pads 203 gradually come into close contact with the inner wall of the rotating guide ring 206. Due to the large friction of the anti-slip pads 203, and the fact that the two anti-slip pads 203 apply pressure to the rotating guide ring 206 from opposite sides at the same time, the rotating guide ring 206 is firmly fixed in the limiting guide groove 4 and cannot rotate at will. The bottom of the turntable 501 is fixedly connected to the top of the rotating guide ring 206, thereby making the entire rotating mechanism 5 and the cooling mechanism 7 installed on it stable and fixed, ensuring that the air cooler will not shift its angle due to the external force of the airflow impact after the angle is adjusted.

[0045] Furthermore, when further adjustment of the cooling airflow direction is required, servo motor 306 is activated. Servo motor 306 is fixed to the top of the air duct 301, and its output drive gear 307 meshes with the transmission gear 305 on the outer wall of the rotating air duct 304. The motor rotation drives the drive gear 307 to rotate, and through gear meshing, the transmission gear 305 rotates, thereby driving the rotating air duct 304 to rotate around the limiting ring 303 within the limiting groove 302, thus adjusting the cooling airflow direction. The air guide assembly 308 further precisely adjusts the airflow direction. The air guide assembly 308 consists of multiple air guide plates 3081, connecting rod components 3082, and telescopic rods 3083. When more precise airflow adjustment is needed, the extension rod is controlled... The telescopic rod 3083 extends and retracts, with its bottom end connected to the top end of the connecting rod component 3082. Its extension and retraction movement drives the connecting rod component 3082 to move. Since the inner walls of multiple air guide plates 3081 are rotatably connected to the connecting rod component 3082, and the front and rear ends of the air guide plates 3081 are also rotatably connected to the inner wall of the rotating air guide duct 304, the movement of the connecting rod component 3082 will drive the air guide plates 3081 to rotate around the connection point with the inner wall of the rotating air guide duct 304, changing the angle of the air guide plates 3081. This precisely adjusts the flow direction of the cooling airflow in the rotating air guide duct 304, achieving precise control of the cooling airflow discharge direction. This enables flexible adjustment of the cooling airflow discharge direction of the air cooler, improving the adaptability of the air cooler to different heat dissipation scenarios.

[0046] Finally, it should be noted that the above description is only a preferred embodiment of the present utility model and is not intended to limit the present utility model. Although the present utility model has been described in detail with reference to the foregoing embodiments, those skilled in the art can still modify the technical solutions described in the foregoing embodiments or make equivalent substitutions for some of the technical features. Any modifications, equivalent substitutions, improvements, etc., made within the spirit and principles of the present utility model should be included within the protection scope of the present utility model.

Claims

1. An adjustable-angle air cooler device, comprising a base (1), characterized in that: The base (1) has a limit guide groove (4) on its top. The base (1) has a fixing mechanism (2) inside it for fixing the device. The base (1) has a rotating mechanism (5) on its top. The rotating mechanism (5) has a cooling mechanism (7) on its top. The rotating mechanism (5) has a driving component (6) at its bottom for driving the fixing mechanism (2) and the rotating mechanism (5). The cooling mechanism (7) has an adjusting mechanism (3) on its top for adjusting the direction of the cooling airflow. The fixing mechanism (2) includes two U-shaped blocks (201). The bottoms of the two U-shaped blocks (201) are fixedly connected to the left and right ends of the inner bottom side of the base (1). The inner walls of the two U-shaped blocks (201) are slidably connected to sliding pressure blocks (202). The opposite sides of the two sliding pressure blocks (202) are fixedly connected to anti-slip pads (203). The inner walls of the two U-shaped blocks (201) are threadedly connected to the same bidirectional lead screw (204). The middle part of the bidirectional lead screw (204) is fixedly connected to a transmission bevel gear (205). The inner wall of the limiting guide groove (4) is rotatably connected to a rotating guide ring (206). The opposite sides of the two anti-slip pads (203) are respectively in contact with the inner wall of the rotating guide ring (206).

2. The adjustable-angle air cooler device according to claim 1, characterized in that: The rotating mechanism (5) includes a turntable (501), the bottom of which is fixedly connected to the top of the rotating guide ring (206). A transmission gear plate (502) is fixedly connected to the bottom of the turntable (501). Mounting grooves (503) are provided on the left and right sides of the top of the turntable (501), and support frames (504) are fixedly connected to the inner walls of the two mounting grooves (503).

3. The adjustable-angle air cooler device according to claim 1, characterized in that: The drive assembly (6) includes a second servo motor (601), the bottom of which is fixedly connected to the inner bottom side of the base (1). The output end of the second servo motor (601) is fixedly connected to a second drive gear (602), which meshes with a transmission gear plate (502). The rear end of the inner bottom side of the base (1) is fixedly connected to a third servo motor (603), the output end of which is fixedly connected to a drive bevel gear (604), which meshes with a transmission bevel gear (205).

4. The adjustable-angle air cooler device according to claim 1, characterized in that: The cooling mechanism (7) includes a cooling body (701). The bottom left and right sides of the cooling body (701) are fixedly connected to the top of the support frame (504). The left end of the cooling body (701) is fixedly connected to a front tube box (702). The right end of the cooling body (701) is fixedly connected to a rear tube box (703). The adjacent sides of the rear tube box (703) and the front tube box (702) are both fixedly connected to the same heat exchange tube group (706). The inner wall of the cooling body (701) is fixedly connected to multiple baffles (707) at equal intervals. The left rear end of the cooling body (701) is fixedly connected to an air inlet pipe (704). The right top end of the cooling body (701) is fixedly connected to a cold air outlet pipe (705).

5. The adjustable-angle air cooler device according to claim 4, characterized in that: The adjustment mechanism (3) includes an air guide pipe (301), the bottom end of which is fixedly connected to the top end of the cold air exhaust pipe (705). A limiting groove (302) is provided at the right end of the air guide pipe (301). A limiting ring (303) is rotatably connected to the inner wall of the limiting groove (302). A rotating air guide pipe (304) is fixedly connected to the right side of the limiting ring (303). A transmission gear (305) is fixedly connected to the outer wall of the rotating air guide pipe (304). A servo motor (306) is fixedly connected to the top of the air guide pipe (301). A drive gear (307) is fixedly connected to the output end of the servo motor (306). The drive gear (307) meshes with the transmission gear (305). An air guide assembly (308) is provided inside the rotating air guide pipe (304).

6. The adjustable-angle air cooler device according to claim 5, characterized in that: The air guide assembly (308) includes multiple air guide plates (3081), the front and rear ends of which are rotatably connected to the inner wall of the rotating air guide tube (304). The inner walls of the multiple air guide plates (3081) are rotatably connected to the same connecting rod component (3082). The top of the rotating air guide tube (304) is fixedly connected to a telescopic rod (3083), and the bottom end of the telescopic rod (3083) is fixedly connected to the top end of the connecting rod component (3082).

7. The adjustable-angle air cooler device according to claim 1, characterized in that: The inner walls of the two U-shaped blocks (201) are fixedly connected with buffer pads (8), and the two buffer pads (8) are respectively attached to the corresponding sliding pressure blocks (202).

8. The adjustable-angle air cooler device according to claim 1, characterized in that: The sliding pressure block (202) is fixedly connected to the front and rear sides of the limiting guide block (9), and the inner walls of the two U-shaped blocks (201) are provided with a sliding groove (10) on the front and rear sides. The inner walls of the two sliding grooves (10) are slidably connected to the outer walls of the corresponding limiting guide blocks (9).