A cooling tank for rapid cooling of a nutrient product
By installing a pre-cooling and cooling system in the cooling tank for nutritional product production, including a pre-cooling box, servo motor, stirring paddle, transition cooling pipe, and cooling conveying system, the problem of slow cooling speed in the prior art is solved, realizing rapid cooling and thorough cooling and filtration of materials, thereby improving cooling efficiency and finished product quality.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- METHUSELAH MEDICAL TECH (SHANGHAI) CO LTD
- Filing Date
- 2025-07-28
- Publication Date
- 2026-07-14
Smart Images

Figure CN224498926U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of nutritional food processing technology, specifically a cooling tank for rapid cooling in the production of nutritional products. Background Technology
[0002] Nutritional food processing refers to the process of transforming natural raw materials or nutrients into finished foods that are easy to consume and have specific health benefits through specialized techniques. In the processing of nutritional foods, a cooling tank is needed to rapidly lower the product temperature, prevent microbial growth, and preserve heat-sensitive nutrients. However, current cooling tanks still have the following shortcomings:
[0003] For example, patent document CN216049285U discloses a cooling tank. This cooling tank reduces the temperature of tap water by setting a refrigeration mechanism in the tank body. Tap water can be used to reduce the oil temperature to the required temperature, eliminating the need for a continuous supply of cooling water, which can greatly reduce factory costs. However, it does not have a pre-cooling mechanism, resulting in a slow cooling rate and low overall cooling efficiency. Utility Model Content
[0004] The purpose of this invention is to provide a cooling tank for rapid cooling in the production of nutritional products, 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: a cooling tank for rapid cooling in nutritional product production, comprising a cooling tank body and a cooling assembly. A support frame is installed at the bottom of the cooling tank body, and a fixed base is provided at the bottom of the support frame. The cooling assembly is located on the rear side of the upper surface of the fixed base, and the cooling assembly includes a pre-cooling tank, a servo motor, a stirring paddle, a transition cooling tank, a cooling conveying pipe, a water inlet, a cold air jacket, an exhaust valve, a cooler, and a cold air pipe. The pre-cooling tank is located on the left end of the rear side of the upper surface of the fixed base, and a servo motor is installed on the left surface of the pre-cooling tank. The output end of the servo motor is connected to the stirring paddle via a coupling. A transition cooling tank is installed at the front end of the upper surface of the pre-cooling tank, and a cooling conveying pipe is provided inside the transition cooling tank.
[0006] Furthermore, a water inlet is installed at the upper front end of the transition cooling box, and cold air jackets are provided on the side wall surfaces of both the transition cooling box and the pre-cooling box, with an exhaust valve installed on the left side of the cold air jacket.
[0007] Furthermore, a cooler is installed on the right side of the precooling box, and a cooler pipe is provided on the upper side of the cooler. There are two sets of cooler pipes, and the upper end of the cooler pipe is connected to the inner side of the cooler jacket.
[0008] Furthermore, a feed inlet is provided on the upper side of the cooling tank, and a rotating motor is installed on the right side of the cooling tank. The output end of the rotating motor is connected to a stirring impeller through a coupling, and a CNC discharge valve is installed on the lower side of the cooling tank.
[0009] Furthermore, a cooling mechanism is installed on the upper left side of the support frame, and a CNC controller is provided at the front right side of the cooling mechanism.
[0010] Furthermore, a high-pressure liquid pump is installed at the front right side of the precooling tank, and a high-pressure liquid delivery pipe is connected to the right end of the high-pressure liquid pump. The upper end of the high-pressure liquid delivery pipe is connected to the feed inlet.
[0011] Furthermore, the bottom of the CNC discharge valve is provided with a filter assembly for filtration, and the filter assembly includes a fixed box, a movable box, an auxiliary handle and a discharge port. The fixed box is located at the bottom of the CNC discharge valve, and the movable box is slidably connected to the inside of the fixed box. An auxiliary handle is installed on the upper right side of the movable box, and a discharge port is provided on the lower right side of the movable box.
[0012] Furthermore, the filter assembly also includes a coarse-pore filter, a fine-pore filter, and a filter membrane. A coarse-pore filter is installed on the upper side of the movable housing, a fine-pore filter is installed below the coarse-pore filter, and a filter membrane is installed below the fine-pore filter.
[0013] This invention provides a cooling tank for rapid cooling in the production of nutritional products, which has the following beneficial effects:
[0014] 1. This utility model incorporates a cooling assembly, which includes a pre-cooling tank, a servo motor, a stirring paddle, a transition cooling tank, a cooling conveying pipe, a water inlet, a cold air jacket, an exhaust valve, a chiller, and a cold air pipe. In use, cold water is supplied to the transition cooling tank through the water inlet, and the chiller is simultaneously activated, supplying cold air through the cold air pipe to the cold air jacket in both the pre-cooling tank and the transition cooling tank. The cold air is then discharged through the exhaust valve, maintaining the flow of cold air in the cold air jacket and ensuring the water in the transition cooling tank retains its temperature. The material is then conveyed to the cooling conveying pipe for initial cooling. The material then enters the pre-cooling tank through the cooling conveying pipe. Simultaneously, the servo motor is activated, driving the stirring paddle to agitate the material, improving cooling efficiency. This dual pre-cooling mechanism effectively achieves rapid cooling of the material.
[0015] 2. This utility model incorporates a filtration assembly, which includes a fixed housing, a movable housing, an auxiliary handle, and a discharge port. The assembly also includes a coarse-pore filter, a fine-pore filter, and a filter membrane. During use, material falls into the movable housing within the fixed housing through a CNC discharge valve. The coarse-pore filter intercepts and filters larger impurities, the fine-pore filter filters smaller particles, and the filter membrane further filters out minute particles, achieving thorough filtration. Simultaneously, the filtered material is discharged through the discharge port. After material processing, the movable housing is moved outwards along the inner surface of the fixed housing by pulling the auxiliary handle, facilitating cleaning of the inner side of the movable housing. This allows the device to achieve thorough filtration of the material, improving the quality of the finished product. Attached Figure Description
[0016] Figure 1 This is a three-dimensional structural diagram of a cooling tank for rapid cooling in the production of nutritional products according to the present invention.
[0017] Figure 2 This is a three-dimensional rear view structural diagram of a cooling tank for rapid cooling in the production of nutritional products according to this utility model.
[0018] Figure 3 This is a three-dimensional structural diagram of the cooling component of a cooling tank for rapid cooling in the production of nutritional products according to this utility model.
[0019] Figure 4 This is a three-dimensional cross-sectional view of the cooling tank body of a cooling tank for rapid cooling in the production of nutritional products according to this utility model.
[0020] Figure 5 This is a three-dimensional structural diagram of the filter assembly of a cooling tank for rapid cooling in the production of nutritional products according to this utility model.
[0021] In the diagram: 1. Cooling tank; 2. Support frame; 3. Fixed base; 4. Cooling assembly; 401. Pre-cooling tank; 402. Servo motor; 403. Agitator; 404. Transition cooling tank; 405. Cooling conveying pipe; 406. Water inlet; 407. Cooling jacket; 408. Exhaust valve; 409. Air conditioner; 410. Cooling pipe; 5. Feed inlet; 6. Rotary motor; 7. Agitator impeller; 8. CNC discharge valve; 9. Cooling mechanism; 10. CNC controller; 11. High-pressure liquid pump; 12. High-pressure liquid conveying pipe; 13. Filter assembly; 1301. Fixed housing; 1302. Movable housing; 1303. Auxiliary handle; 1304. Discharge port; 1305. Coarse pore filter screen; 1306. Fine pore filter screen; 1307. Filter membrane. Detailed Implementation
[0022] The embodiments of this utility model will be described in further detail below with reference to the accompanying drawings and examples. The following examples are for illustrative purposes only and should not be construed as limiting the scope of this utility model.
[0023] like Figures 1 to 5 As shown, a cooling tank for rapid cooling in nutritional product production includes a cooling tank body 1 and a cooling assembly 4. A support frame 2 is installed at the bottom of the cooling tank body 1, and a fixed base 3 is provided at the bottom of the support frame 2. The cooling assembly 4 is located on the rear side of the upper surface of the fixed base 3, and includes a pre-cooling tank 401, a servo motor 402, a stirring paddle 403, a transition cooling tank 404, a cooling conveying pipe 405, a water inlet 406, a cold air jacket 407, an exhaust valve 408, a chiller 409, and a cold air pipe 410. The pre-cooling tank 401 is located on the left end of the rear side of the upper surface of the fixed base 3, and a servo motor 402 is installed on the left surface of the pre-cooling tank 401. The output end of motor 402 is connected to a stirring paddle 403 via a coupling. A transition cooling box 404 is installed at the front end of the upper surface of the pre-cooling box 401, and a cooling conveying pipe 405 is provided inside the transition cooling box 404. A water inlet 406 is installed at the front end of the upper side of the transition cooling box 404. Both the transition cooling box 404 and the side wall surface of the pre-cooling box 401 are provided with a cold air jacket 407. An exhaust valve 408 is installed on the left side of the cold air jacket 407. A cooler 409 is installed on the right side of the pre-cooling box 401, and a cold air pipe 410 is provided on the upper side of the cooler 409. Two sets of cold air pipes 410 are provided, and the upper end of the cold air pipes 410 is connected to the inside of the cold air jacket 407.
[0024] The specific operation is as follows: During use, cold water is supplied to the transition cooling tank 404 through the water inlet 406. At the same time, the air cooler 409 is started, so that the air cooler 409 supplies cold air to the pre-cooling tank 401 and the cold air jacket 407 in the transition cooling tank 404 through the cold air pipe 410. At the same time, the cold air is discharged through the exhaust valve 408 to maintain the flow of cold air in the cold air jacket 407, so that the water in the transition cooling tank 404 can maintain the temperature. The material is transported to the cooling conveying pipe 405 for preliminary cooling. The material enters the pre-cooling tank 401 through the cooling conveying pipe 405. At the same time, the servo motor 402 is started, so that the servo motor 402 drives the stirring paddle 403 to stir the material and improve the cooling efficiency.
[0025] Please refer to Figure 2 , Figure 4 and Figure 5A feed inlet 5 is provided on the upper side of the cooling tank 1, and a rotary motor 6 is installed on the right side of the cooling tank 1. The output end of the rotary motor 6 is connected to a stirring impeller 7 via a coupling. A CNC discharge valve 8 is installed on the lower side of the cooling tank 1. A cooling mechanism 9 is installed on the upper left end of the support frame 2, and a CNC controller 10 is provided at the front right side of the cooling mechanism 9. A high-pressure liquid pump 11 is installed at the front right side of the pre-cooling tank 401, and a high-pressure liquid delivery pipe 12 is connected to the right end of the high-pressure liquid pump 11. The upper end of the high-pressure liquid delivery pipe 12 is connected to the feed inlet 5. A filter assembly 13 for filtration is provided at the bottom of the CNC discharge valve 8, and the filter assembly 13 includes a fixed housing 1301 and a movable housing 1. 302, auxiliary handle 1303 and discharge port 1304, fixed housing 1301 is set at the bottom of CNC discharge valve 8, and movable housing 1302 is slidably connected to the inner side of fixed housing 1301. Auxiliary handle 1303 is installed at the upper right end of movable housing 1302, and discharge port 1304 is set at the lower right end of movable housing 1302. Filter assembly 13 also includes coarse pore filter screen 1305, fine pore filter screen 1306 and filter membrane 1307. Coarse pore filter screen 1305 is installed at the upper inner end of movable housing 1302. Fine pore filter screen 1306 is set below coarse pore filter screen 1305, and filter membrane 1307 is installed below fine pore filter screen 1306.
[0026] The specific operation is as follows: When in use, start the high-pressure pump 11 to extract the pre-cooled material from the pre-cooling tank 401 and transport it to the high-pressure delivery pipe 12. Then, the material enters the cooling tank 1 through the inlet 5. Start the rotating motor 6 to drive the stirring impeller 7 to rotate, thereby improving the cooling efficiency. After cooling is completed, the CNC controller 10 controls the CNC discharge valve 8 to open, allowing the material to fall into the movable tank 1302 in the fixed tank 1301. Larger impurities are intercepted and filtered by the coarse-pore filter screen 1305, smaller particulate impurities are filtered by the fine-pore filter screen 1306, and the filter membrane 1307 can further filter the tiny particles in the material, achieving thorough filtration of the material. At the same time, the filtered material is discharged through the discharge port 1304. After the material is processed, the movable tank 1302 is pulled by the auxiliary handle 1303 to move the movable tank 1302 outward along the inner surface of the fixed tank 1301, which facilitates the cleaning of the inside of the movable tank 1302.
[0027] In summary, as Figures 1 to 5As shown, this rapid cooling cooling tank for nutritional product production operates as follows: First, cold water is supplied to the transition cooling tank 404 through the water inlet 406. Simultaneously, the air cooler 409 is started, supplying cold air through the air pipe 410 to the pre-cooling tank 401 and the cold air jacket 407 in the transition cooling tank 404. Simultaneously, the cold air is discharged through the exhaust valve 408, maintaining the flow of cold air in the cold air jacket 407 and ensuring the water in the transition cooling tank 404 maintains its temperature. The material is then conveyed to the cooling conveying pipe 405 for initial cooling. The material then enters the pre-cooling tank 401 through the cooling conveying pipe 405. Simultaneously, the servo motor 402 is started, driving the stirring paddle 403 to agitate the material and improve cooling efficiency. Subsequently, the high-pressure pump 11 is started, causing the material to be further cooled in the pre-cooling tank 401. The pre-cooled material is extracted and transported to the high-pressure infusion pipe 12, and then enters the cooling tank 1 through the feed port 5. The rotating motor 6 is started, which drives the stirring impeller 7 to rotate, improving the cooling efficiency. After cooling is completed, the CNC controller 10 controls the CNC discharge valve 8 to open, allowing the material to fall into the movable box 1302 in the fixed box 1301. Larger impurities are intercepted and filtered by the coarse-pore filter screen 1305, smaller particulate impurities are filtered by the fine-pore filter screen 1306, and the filter membrane 1307 can further filter the tiny particles in the material, achieving thorough filtration of the material. At the same time, the filtered material is discharged through the discharge port 1304. After the material is processed, the movable box 1302 is pulled by the auxiliary handle 1303, causing the movable box 1302 to move outward along the inner surface of the fixed box 1301, which facilitates the cleaning of the inside of the movable box 1302.
[0028] The embodiments of this utility model are given for illustrative and descriptive purposes only, and are not intended to be exhaustive or to limit the utility model to the forms disclosed. Many modifications and variations will be apparent to those skilled in the art. The embodiments were chosen and described in order to better illustrate the principles and practical applications of this utility model, and to enable those skilled in the art to understand this utility model and design various embodiments with various modifications suitable for a particular purpose.
Claims
1. A cooling tank for rapid cooling in the production of nutritional products, comprising a cooling tank body (1) and a cooling assembly (4), characterized in that: The cooling tank (1) is equipped with a support frame (2) at the bottom, and a fixed base (3) is provided at the bottom of the support frame (2). The cooling component (4) is located on the rear side of the upper surface of the fixed base (3), and the cooling component (4) includes a pre-cooling tank (401), a servo motor (402), a stirring paddle (403), a transition cooling tank (404), a cooling conveying pipe (405), a water inlet (406), a cold air jacket (407), an exhaust valve (408), and a cooler. (409) and cold air pipe (410), the pre-cooling box (401) is located on the left side of the upper surface of the fixed base (3), and a servo motor (402) is installed on the left surface of the pre-cooling box (401), and the output end of the servo motor (402) is connected to the stirring paddle (403) through a coupling. A transition cooling box (404) is installed at the front end of the upper surface of the pre-cooling box (401), and a cooling conveying pipe (405) is provided inside the transition cooling box (404).
2. The cooling tank for rapid cooling in nutritional product production according to claim 1, characterized in that, A water inlet (406) is installed at the upper front end of the transition cooling box (404), and a cold air jacket (407) is provided on the side wall surface of both the transition cooling box (404) and the pre-cooling box (401). An exhaust valve (408) is installed on the left side of the cold air jacket (407).
3. The cooling tank for rapid cooling in nutritional product production according to claim 1, characterized in that, A cooler (409) is installed on the right side of the precooling box (401), and a cooler pipe (410) is provided on the upper side of the cooler (409). There are two sets of cooler pipes (410), and the upper end of the cooler pipe (410) is connected to the inner side of the cooler jacket (407).
4. A cooling tank for rapid cooling in nutritional product production according to claim 1, characterized in that, The cooling tank (1) is provided with a feed inlet (5) on the upper side, and a rotating motor (6) is installed on the right side of the cooling tank (1). The output end of the rotating motor (6) is connected to a stirring impeller (7) through a coupling. A CNC discharge valve (8) is installed on the lower side of the cooling tank (1).
5. A cooling tank for rapid cooling in nutritional product production according to claim 1, characterized in that, A cooling mechanism (9) is installed on the upper left side of the support frame (2), and a CNC device (10) is provided on the right front end of the cooling mechanism (9).
6. A cooling tank for rapid cooling in nutritional product production according to claim 1, characterized in that, A high-pressure liquid pump (11) is installed at the front right side of the precooling tank (401), and a high-pressure liquid delivery pipe (12) is connected to the right end of the high-pressure liquid pump (11). The upper end of the high-pressure liquid delivery pipe (12) is connected to the feed inlet (5).
7. A cooling tank for rapid cooling in nutritional product production according to claim 4, characterized in that, The bottom of the CNC discharge valve (8) is provided with a filter assembly (13) for filtration, and the filter assembly (13) includes a fixed box (1301), a movable box (1302), an auxiliary handle (1303) and a discharge port (1304). The fixed box (1301) is located at the bottom of the CNC discharge valve (8), and the movable box (1302) is slidably connected to the inside of the fixed box (1301). An auxiliary handle (1303) is installed on the upper right side of the movable box (1302), and a discharge port (1304) is provided on the lower right side of the movable box (1302).
8. A cooling tank for rapid cooling in nutritional product production according to claim 7, characterized in that, The filter assembly (13) further includes a coarse-pore filter (1305), a fine-pore filter (1306), and a filter membrane (1307). The coarse-pore filter (1305) is installed on the upper inner side of the movable housing (1302), the fine-pore filter (1306) is arranged below the coarse-pore filter (1305), and the filter membrane (1307) is installed below the fine-pore filter (1306).