A cooling device for producing a transition connector
By introducing a filter drum screen and a motor-driven gear meshing system into the cooling device for transition connector production, the problem of debris residue inside the filtration mechanism was solved, achieving efficient filtration of coolant and convenient recovery of impurities, thus improving the practicality of the device.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- 河南利旺流体技术有限公司
- Filing Date
- 2025-06-16
- Publication Date
- 2026-06-09
AI Technical Summary
In existing cooling devices used for transition connector production, debris residue inside the filtration mechanism reduces the filtration area and clogs the pores, affecting the coolant recovery effect, and the residual debris is difficult to recover.
A cooling device comprising a spraying mechanism, a recovery mechanism, and a filtration mechanism was designed. Through a filter drum screen and a gear meshing system driven by a motor, the device achieves efficient filtration of the coolant and convenient recovery of impurities, ensuring the recycling of the coolant.
This allows the cooling device to maintain a high-efficiency filtration effect for a long time and to easily recover the filtered waste and particulate matter, thus improving the practicality of the cooling device.
Smart Images

Figure CN224340480U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of cooling device technology, specifically a cooling device for the production of transition connectors. Background Technology
[0002] The main function of transition connectors is to ensure a secure connection between pipes or equipment, preventing water and air leaks while meeting the design requirements of the piping system. In piping systems, different sections may require pipes of different diameters or types; therefore, transition connectors are needed to connect these different parts. During the manufacturing process of transition connectors, cooling treatment is required to control their temperature and prevent deformation or damage due to overheating. Therefore, cooling devices are necessary.
[0003] Existing cooling devices for transition connector production primarily spray coolant onto the transition connectors during processing. The coolant used for cooling is filtered to remove processing debris and can then be recycled. However, in traditional cooling devices, most of the debris filtered out by the filtration mechanism remains inside the filtration mechanism. This debris occupies filtration space, potentially reducing the filtration area and thus lowering filtration efficiency. Furthermore, the remaining debris can clog the filter holes, preventing the coolant from flowing smoothly and further affecting the coolant recovery effect. The debris located inside the filtration mechanism can also hinder the recovery process. Utility Model Content
[0004] The purpose of this invention is to provide a cooling device for the production of transition connectors, so as to solve the problems mentioned in the background art.
[0005] To achieve the above objectives, this utility model provides the following technical solution:
[0006] A cooling device for producing transition connectors includes a body with a control terminal, a processing chamber inside the body, a processing mechanism for processing the transition connectors inside the processing chamber, and a cooling mechanism for cooling the transition connectors during processing inside the body. The cooling mechanism includes a spraying mechanism for spraying coolant onto the transition connectors during processing and a recovery mechanism for filtering and recovering the used coolant. The spraying mechanism includes a cooling nozzle, a storage tank, and a first water pump, and the recovery mechanism includes a pipe, a filter box, and a second water pump.
[0007] Preferably, the machine body has a compartment inside, with a liquid storage tank and a water pump both located inside the compartment. The cooling nozzle is located inside the processing compartment and can cooperate with the transition connection during the processing. The liquid storage tank stores coolant, the inlet end of the water pump extends into the liquid storage tank, and the outlet end of the water pump is connected to one end of the cooling nozzle through a cooling pipe.
[0008] Preferably, the pipe body, filter box, and water pump 2 are all located inside the chamber. The filter box is rotatably equipped with a filter drum screen. One end of the pipe body is connected to the interior of the processing chamber, and the other end of the pipe body extends into the interior of the filter drum screen through the feed inlet. The water pump 2 is located on one side of the filter box, and the liquid inlet of the water pump 2 extends into the interior of the filter box. The liquid outlet of the water pump 2 extends into the interior of the storage tank through a pipe.
[0009] Preferably, a driven gear is fixedly installed on the outside of the filter drum screen, a motor is fixedly installed on the top of the filter box, a driving gear is fixedly installed at the output end of the motor, and the driving gear meshes with the driven gear. A storage basket is movably installed inside the hopper, and the storage basket is located below the discharge port of the filter drum screen.
[0010] Compared with the prior art, the beneficial effects of this utility model are:
[0011] 1. This utility model, by installing a filter box, allows the used coolant to fall into the bottom of the processing chamber and then enter the filter drum screen through a pipe. Simultaneously, the motor starts, and the drive gear at the motor's output end begins to rotate, meshing with the driven gear and driving the filter drum screen to rotate as well. The rotation of the filter drum screen separates the waste and particulate matter in the coolant, which falls into the collection basket through the discharge port of the filter drum screen. The filtered coolant enters the bottom of the filter box, waiting for the second water pump to extract it. After the second water pump starts, it extracts the filtered coolant from the filter box and sends it back to the storage tank through a pipe. In the storage tank, the coolant can be extracted again by the first water pump and transported to the cooling nozzle for recycling. This allows the cooling device's filtration mechanism to maintain a high-efficiency filtration effect for a long time, while also making it easier for workers to collect the filtered waste and particulate matter, thus improving the practicality of the cooling device. Attached Figure Description
[0012] Figure 1 This is a schematic diagram of the overall structure of this utility model;
[0013] Figure 2 This is a schematic diagram of the processing chamber structure of this utility model;
[0014] Figure 3 This is a schematic diagram of the silo structure of this utility model;
[0015] Figure 4 This is a schematic diagram of the filter box structure of this utility model.
[0016] In the diagram: 1. Machine body; 2. Control terminal; 3. Processing chamber; 4. Processing mechanism; 5. Chamber body; 6. Liquid storage tank; 7. Water pump one; 8. Cooling nozzle; 9. Pipe body; 10. Filter box; 11. Filter drum screen; 12. Water pump two; 13. Storage basket; 14. Driven gear; 15. Motor; 16. Driven gear. Detailed Implementation
[0017] 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.
[0018] Please see Figures 1-4A cooling device for producing transition connectors includes a body 1, a control terminal 2 on the body 1, a processing chamber 3 inside the body 1, a processing mechanism 4 inside the processing chamber 3 for processing the transition connectors, and a cooling mechanism inside the body 1 for cooling the transition connectors during processing. The cooling mechanism includes a spraying mechanism for spraying coolant onto the transition connectors during processing and a recovery mechanism for filtering and recovering the used coolant. The spraying mechanism includes a cooling nozzle 8, a storage tank 6, and a water pump 7. The recovery mechanism includes a pipe 9, a filter box 10, and a second water pump 12. The body 1 is the main structure of the entire cooling device, housing all working parts. The control terminal 2 is used to operate and control the operation of the entire device. The processing chamber 3 is where the transition connectors are processed, and the processing mechanism 4 inside is used to perform necessary processing operations on the transition connectors. Through the installation of the filter box 10, the used coolant is cooled. After the coolant falls into the bottom of the processing chamber 3, it enters the filter drum screen 11 through the pipe 9. At the same time, the motor 15 starts. When the motor 15 starts, the drive gear 16 at its output end starts to rotate and meshes with the driven gear 14, driving the filter drum screen 11 to rotate together. The rotation of the filter drum screen 11 causes the waste and particulate matter in the coolant to be screened out and fall into the collection basket 13 through the discharge port of the filter drum screen 11. The filtered coolant enters the bottom of the filter box 10, waiting for the second water pump 12 to draw it out. After the second water pump 12 starts, it draws the filtered coolant out of the filter box 10 and sends it back to the storage tank 6 through the pipeline. In the storage tank 6, the coolant can be drawn out again by the first water pump 7 and transported to the cooling nozzle 8 for recycling. This allows the filtration mechanism of the cooling device to maintain a high-efficiency filtration effect for a long time, while making it easier for the filtered waste and particulate matter to be recycled by the staff, thus improving the practicality of the cooling device.
[0019] Please see Figure 3 and Figure 4The machine body 1 contains a chamber 5, a liquid storage tank 6, and a water pump 7. A cooling nozzle 8 is located inside the processing chamber 3 and can cooperate with transitional connecting parts during processing. The liquid storage tank 6 stores coolant. The inlet of the water pump 7 extends into the liquid storage tank 6, and the outlet of the water pump 7 is connected to one end of the cooling nozzle 8 via a cooling pipe. The machine body 1 is the main structure of the cooling device, containing all necessary components and functional areas. The chamber 5, located inside the machine body 1, houses key components of the cooling mechanism such as the liquid storage tank 6 and the water pump 7. The liquid storage tank 6, located inside the chamber 5, stores coolant, which is a crucial medium in the cooling process, used to absorb and remove transitional components. The water pump 7 draws coolant from the storage tank 6 and delivers it to the cooling nozzle 8 through the cooling pipe to remove the heat generated during the processing of the connecting parts. The cooling nozzle 8 ensures that the coolant is sprayed evenly and effectively onto the transition connecting parts, thereby achieving the best cooling effect. The cooling pipe connects the outlet end of the water pump 7 and one end of the cooling nozzle 8 to transport the coolant. When the transition connecting parts are being processed in the processing chamber 3, the cooling mechanism starts working. The water pump 7 starts, draws coolant from the storage tank 6 and delivers it to the cooling nozzle 8 through the cooling pipe. The cooling nozzle 8 sprays the coolant evenly onto the transition connecting parts during processing, absorbing and carrying away the heat generated, thus cooling the transition connecting parts during processing.
[0020] Please see Figure 3 and Figure 4The pipe body 9, filter box 10, and water pump 12 are all located inside the chamber 5. A filter drum screen 11 is rotatably mounted inside the filter box 10. One end of the pipe body 9 is connected to the interior of the processing chamber 3, and the other end extends into the filter drum screen 11 through its inlet. The water pump 12 is located on one side of the filter box 10, with its inlet extending into the filter box 10 and its outlet extending into the storage tank 6 via a pipe. One end of the pipe body 9 is connected to the interior of the processing chamber 3 to collect coolant containing impurities after use. The other end of the pipe body 9 extends into the filter drum screen 11 through its inlet, sending the collected coolant into the filter drum screen 11 for filtration. The filter drum screen 11 is rotatably mounted inside the filter box 10 to filter the coolant, removing debris and particulate matter. The filter box 10 can accommodate the filter drum screen 11 and provide it with sufficient cooling water. The filter drum screen 11 is rotatable, and by rotating, it can continuously screen out impurities in the coolant. The screen material and aperture of the filter drum screen 11 can be selected according to the type and size of impurities in the coolant to ensure the filtration effect. The second water pump 12 is located on one side of the filter box 10 and is used to draw the filtered coolant from the filter box 10 and send it back to the storage tank 6 for recycling. When the used coolant falls into the bottom of the processing chamber 3, it will enter the filter drum screen 11 through the pipe 9. The filter drum screen 11 starts to work, screening out the waste and particulate matter. The filtered coolant enters the bottom of the filter box 10 and waits for the second water pump 12 to draw it out. After the second water pump 12 starts, it draws the filtered coolant from the filter box 10 and sends it back to the storage tank 6 through the pipe. In the storage tank 6, the coolant can be drawn out again by the first water pump 7 and sent to the cooling nozzle 8 for recycling.
[0021] Please see Figure 3 and Figure 4A driven gear 14 is fixedly mounted on the outside of the filter drum screen 11. A motor 15 is fixedly mounted on the top of the filter box 10. A driving gear 16 is fixedly mounted on the output end of the motor 15, and the driving gear 16 meshes with the driven gear 14. A storage basket 13 is movably mounted inside the chamber 5, and the storage basket 13 is located below the discharge port of the filter drum screen 11. The filter drum screen 11 is used to filter the coolant and remove waste and particulate matter. The driven gear 14 is fixedly mounted on its outside to mesh with the driving gear 16 to realize power transmission. The motor 15 is fixed on the top of the filter box 10. The motor 15 provides power to the filter drum screen 11. Its output end is fixedly equipped with a drive gear 16, which meshes with the driven gear 14 to transmit power. The collection basket 13 is movably installed inside the bin body 5, located below the discharge port of the filter drum screen 11, to collect the waste and particles screened out from the filter drum screen 11. When the motor 15 starts, the drive gear 16 at its output end starts to rotate and meshes with the driven gear 14, driving the filter drum screen 11 to rotate together. The rotation of the filter drum screen 11 causes the waste and particles in the coolant to be screened out and fall into the collection basket 13.
[0022] Working principle: After the used coolant falls into the bottom of the processing chamber 3, it enters the filter drum screen 11 through the pipe 9. At the same time, the motor 15 starts. When the motor 15 starts, the drive gear 16 at its output end starts to rotate and meshes with the driven gear 14, driving the filter drum screen 11 to rotate together. The rotation of the filter drum screen 11 causes the waste and particulate matter in the coolant to be screened out and fall into the collection basket 13 through the discharge port of the filter drum screen 11. The filtered coolant enters the bottom of the filter box 10, waiting for the second water pump 12 to draw it out. After the second water pump 12 starts, it draws the filtered coolant out of the filter box 10 and sends it back to the storage tank 6 through the pipeline. In the storage tank 6, the coolant can be drawn out again by the first water pump 7 and sent to the cooling nozzle 8 for recycling. This allows the filtration mechanism of the cooling device to maintain a high-efficiency filtration effect for a long time, while making it easier for the filtered waste and particulate matter to be recycled by the staff, thus improving the practicality of the cooling device.
[0023] It will be apparent to those skilled in the art that this invention is not limited to the details of the exemplary embodiments described above, and that it can be implemented in other specific forms without departing from the spirit or essential characteristics of this invention. Therefore, the embodiments should be considered illustrative and non-limiting in all respects, and the scope of this invention is defined by the appended claims rather than the foregoing description. Thus, it is intended that all variations falling within the meaning and scope of equivalents of the claims be included within this invention. No reference numerals in the claims should be construed as limiting the scope of the claims.
Claims
1. A cooling device for producing transition connectors, comprising: a body (1), a control terminal (2) disposed on the body (1), a processing chamber (3) disposed inside the body (1), and a processing mechanism (4) for processing transition connectors disposed inside the processing chamber (3), characterized in that: The machine body (1) is provided with a cooling mechanism for cooling the transition connecting parts during the processing. The cooling mechanism includes a spraying mechanism for spraying coolant onto the transition connecting parts during the processing and a recycling mechanism for filtering and recycling the used coolant. The spraying mechanism includes a cooling nozzle (8), a liquid storage tank (6), and a water pump one (7). The recycling mechanism includes a pipe body (9), a filter box (10), and a water pump two (12).
2. The cooling device for producing transition connectors according to claim 1, characterized in that: The machine body (1) is provided with a chamber (5), a liquid storage tank (6) and a water pump (7) are both located inside the chamber (5), and a cooling nozzle (8) is located inside the processing chamber (3) and can cooperate with the transition connection during the processing. The liquid storage tank (6) stores coolant inside, the inlet end of the water pump (7) extends into the liquid storage tank (6), and the outlet end of the water pump (7) is connected to one end of the cooling nozzle (8) through a cooling pipe.
3. A cooling device for producing transition connectors according to claim 2, characterized in that: The pipe (9), filter box (10) and water pump 2 (12) are all located inside the chamber (5). The filter box (10) is rotatably equipped with a filter drum screen (11). One end of the pipe (9) is connected to the interior of the processing chamber (3), and the other end of the pipe (9) extends into the interior of the filter drum screen (11) through the feed inlet. The water pump 2 (12) is located on one side of the filter box (10), and the liquid inlet of the water pump 2 (12) extends into the interior of the filter box (10). The liquid outlet of the water pump 2 (12) extends into the interior of the storage tank (6) through a pipe.
4. A cooling device for producing transition connectors according to claim 3, characterized in that: The external of the filter drum screen (11) is fixedly provided with a driven gear (14), the top of the filter box (10) is fixedly provided with a motor (15), the output end of the motor (15) is fixedly provided with a driving gear (16), and the driving gear (16) meshes with the driven gear (14). The internal of the silo body (5) is provided with a storage basket (13), and the storage basket (13) is located below the discharge port of the filter drum screen (11).