A cooling and conveying device for raw materials in edible oil production
By combining a dynamic water circulation system with turbulence effects, the problem of uneven temperature during the cooling process of edible oil is solved, achieving uniform cooling and efficient temperature reduction.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- XINJIANG TAIKUN GRP CO LTD
- Filing Date
- 2025-07-09
- Publication Date
- 2026-06-30
AI Technical Summary
The existing static water circulation system results in uneven temperature distribution of edible oil during the cooling process, with the part closer to the cooling water source cooling down quickly and the part farther away cooling down slowly.
A dynamic water circulation system is adopted, which, through the slow reciprocating motion of the circulator and inner plate, combined with the opening and closing of the heat dissipation mesh, forms dynamic cooling and turbulence effect, ensuring uniform contact between the grease and the cooling medium, and achieving dynamic cooling.
It achieves temperature uniformity during the cooling process of edible oil, avoids local overheating or overcooling, ensures that every drop of raw material is cooled in a stable cooling environment, and improves cooling efficiency and uniformity.
Smart Images

Figure CN224434833U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of edible oil technology, specifically to a cooling and conveying device for edible oil production raw materials. Background Technology
[0002] Cooking oil plays a variety of roles in cooking. It not only adds aroma and flavor to food, enriching its texture, but also acts as a heat transfer medium, helping food to be heated evenly during cooking for optimal results. Furthermore, cooking oil is an important source of nutrition, providing energy, essential fatty acids, and fat-soluble vitamins, playing a vital role in maintaining normal physiological functions.
[0003] In existing technologies, there are a wide variety of edible oils, mainly plant-based. Before plant-based oils can be made into edible oils, they need to be processed by pressing equipment. Pressing equipment can efficiently extract the oil from plant raw materials. By using physical extrusion, under mechanical pressure, the structure of plant cells is broken, causing the oil inside the cells to be released and separated, thereby converting the oil in the raw materials into crude oil that can be further processed.
[0004] However, after the oil is pressed again, it will have a certain temperature. Therefore, when cooling the oil, it needs to be cooled inside the cavity. A water circulation system may be used for cooling. This water circulation cooling is a static mode. Static water circulation is difficult to ensure a uniform decrease in the temperature of the oil inside the cavity because heat transfer is limited. The oil near the cooling water source or cooling pipe cools down faster, while the oil further away cools down slowly, resulting in an uneven temperature distribution of the oil inside the cavity. To address this, we propose a cooling and conveying device for edible oil production raw materials. Utility Model Content
[0005] One of the technical problems to be solved by this application is: cooling and reducing the temperature of grease through a dynamic water circulation system.
[0006] To solve the above-mentioned technical problems, this application provides a cooling and conveying device for edible oil production raw materials, including a cooling mechanism. The inner wall of the cooling mechanism is provided with an auxiliary mechanism. The cooling mechanism includes a main cavity, and the inner wall of the main cavity is provided with an inner plate. The inner wall of the main cavity is slidably connected to the outer side of the inner plate. The inner wall of the inner plate is provided with a transfer pipe, and the inner wall of the inner plate is fixedly connected to the outer side of the transfer pipe. A horizontal plate is provided on one side of the transfer pipe, and one side of the transfer pipe is rotatably connected to one side of the horizontal plate. A movable arm is provided on one side of the horizontal plate, and one side of the horizontal plate is rotatably connected to one end of the movable arm. A fixed plate is provided on the other end of the movable arm, and the other end of the movable arm is rotatably connected to the edge of the fixed plate.
[0007] In some embodiments, the auxiliary mechanism includes a closing plate, the bottom end of which is rotatably connected to the inner wall of the main cavity, and a heat dissipation mesh is provided on the inner surface of the main cavity, and the inner surface of the main cavity is fixedly connected to the outer side of the heat dissipation mesh.
[0008] In some embodiments, a baffle is provided inside the diversion pipe, and the inside of the diversion pipe is fixedly connected to the outer top of the baffle. A drain pipe is provided on one side of the diversion pipe, and one side of the diversion pipe is fixedly connected to one end of the drain pipe. A water tank is provided at the other end of the drain pipe, and the other end of the drain pipe is fixedly connected to one side of the water tank.
[0009] In some embodiments, a water pump is provided on the inner wall of the water tank, and the inner wall of the water tank is fixedly connected to one side of the water pump. A sub-pipe is provided at the output end of the water pump, and the output end of the water pump is fixedly connected to one side of the sub-pipe.
[0010] In some embodiments, a conveying pipe is provided on one side of the sub-tube, one side of the sub-tube is fixedly connected to one end of the conveying pipe, and the other end of the conveying pipe is fixedly connected to one side of the transfer pipe.
[0011] In some embodiments, a bracket is provided at one end of the diversion pipe, one end of the diversion pipe is fixedly connected to one end of the bracket, the bottom side of the bracket is fixedly connected to the top side of the inner plate, and the other end of the bracket is fixedly connected to the bottom side of the water tank.
[0012] In some embodiments, a secondary cavity is provided inside the main cavity, the inner side of the main cavity is fixedly connected to the top end of the secondary cavity, an oil pump is provided on the inner wall of the secondary cavity, the inner wall of the secondary cavity is in through communication with the output end of the oil pump, and the bottom side of the oil pump is fixedly connected to one side of the main cavity.
[0013] In some embodiments, a motor is provided at one end of the side of the main cavity, the side of the main cavity is fixedly connected to the bottom of the motor, and the output end of the motor is fixedly connected to the center of the fixed disk.
[0014] This utility model has at least the following beneficial effects:
[0015] 1. The cooling medium in the water tank is fed into the transfer pipe by a water pump. The cooling medium will enter the drain pipe in a U-shaped loop, and then the drain pipe will guide the cooling medium back into the water tank, forming a circulation system. During this process, the fixed plate is started to rotate by starting the motor, and then the transfer pipe, inner plate and water tank will move slowly back and forth synchronously. This allows the raw material to come into contact with the transfer pipe in a dynamic manner. The low temperature on the surface of the transfer pipe will continuously remove the heat from the raw material through heat conduction, thus accelerating the cooling efficiency.
[0016] 2. By fastening the closing plate, the heat dissipation mesh on the main cavity is exposed, which increases the gas flow in the main cavity, thereby accelerating the heat exchange efficiency between the raw material and the transfer tube and the wall of the secondary cavity. This allows the raw material temperature to drop to the target range more quickly. The turbulence effect formed by forced convection effectively eliminates the temperature gradient in the secondary cavity, avoids local overheating or overcooling, and ensures that every drop of raw material can be cooled in a stable cooling environment. Attached Figure Description
[0017] Figure 1 This is a schematic diagram of the overall structure of this utility model;
[0018] Figure 2 This is a schematic diagram of the front end structure of the cooling mechanism component of this utility model;
[0019] Figure 3 This is a side sectional view of the cooling mechanism assembly of this utility model;
[0020] Figure 4 This is a cross-sectional structural diagram of the cooling mechanism assembly of this utility model;
[0021] Figure 5 This is a schematic diagram of the unfolded structure of the auxiliary mechanism components of this utility model;
[0022] In the diagram: 1. Cooling mechanism; 11. Main chamber; 12. Inner plate; 13. Transfer pipe; 14. Flow pipe; 15. Sub-pipe; 16. Drain pipe; 17. Water tank; 18. Partition plate; 19. Bracket; 110. Secondary chamber; 111. Oil pump; 112. Water pump; 113. Motor; 114. Fixed plate; 115. Movable arm; 116. Horizontal plate;
[0023] 2. Auxiliary mechanism; 21. Closing plate; 22. Heat dissipation mesh. Detailed Implementation
[0024] 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.
[0025] Example 1: Please refer to Figures 1-5This utility model provides a technical solution: a cooling and conveying device for edible oil production raw materials, including a cooling mechanism 1, an auxiliary mechanism 2 provided on the inner wall of the cooling mechanism 1, a main cavity 11, an inner plate 12 provided on the inner wall of the main cavity 11, the inner wall of the main cavity 11 and the outer side of the inner plate 12 being slidably connected through, a transfer pipe 13 provided on the inner wall of the inner plate 12, the inner wall of the inner plate 12 and the outer side of the transfer pipe 13 being fixedly connected through, a horizontal plate 116 provided on one side of the transfer pipe 13, one side of the transfer pipe 13 being rotatably connected to one side end of the horizontal plate 116, and one side of the horizontal plate 116 being... A movable arm 115 is provided at one end of a horizontal plate 116. One side of the horizontal plate 116 is rotatably connected to one end of the movable arm 115. A fixed plate 114 is provided at the other end of the movable arm 115, and the other end of the movable arm 115 is rotatably connected to the edge of the fixed plate 114. A baffle 18 is provided inside the diversion pipe 13, and the inside of the diversion pipe 13 is fixedly connected to the outer top of the baffle 18. A drain pipe 16 is provided on one side of the diversion pipe 13, and one side of the diversion pipe 13 is fixedly connected to one end of the drain pipe 16. A water tank 17 is provided at the other end of the drain pipe 16, and the other end of the drain pipe 16 is fixedly connected to one side of the water tank 17. A water pump 112 is fixedly connected to the inner wall of the water tank 17. One side of the water pump 112 is fixedly connected to the inner wall of the water tank 17. A sub-pipe 15 is provided at the output end of the water pump 112, and one side of the sub-pipe 15 is fixedly connected to the output end of the sub-pipe 12. A delivery pipe 14 is provided at one side of the sub-pipe 15, and one end of the delivery pipe 14 is fixedly connected to the output end of the delivery pipe 14. The other end of the delivery pipe 14 is fixedly connected to one side of the transfer pipe 13. A bracket 19 is provided at one end of the transfer pipe 13, and one end of the transfer pipe 13 is fixedly connected to one end of the bracket 19. The bottom side of the bracket 19 is connected to the top side of the inner plate 12. The bracket 19 is fixedly connected to the bottom of the water tank 17. A secondary cavity 110 is provided inside the main cavity 11. The inner side of the main cavity 11 is fixedly connected to the top of the secondary cavity 110. An oil pump 111 is provided on the inner wall of the secondary cavity 110. The inner wall of the secondary cavity 110 is in through communication with the output end of the oil pump 111. The bottom of the oil pump 111 is fixedly connected to one side of the main cavity 11. A motor 113 is provided on one side of the main cavity 11. The bottom of the motor 113 is fixedly connected to the output end of the motor 113. The output end of the motor 113 is fixedly connected to the center of the fixed plate 114.
[0026] In operation, this type of edible oil production raw material cooling and conveying device first features a main chamber 11, inside which a secondary chamber 110 is installed. To allow the raw material to be cooled dynamically, an inner plate 12 is installed on the inner wall of the main chamber 11. A transfer pipe 13 is fixed through the middle of the inner wall of the inner plate 12, located in the hollow space of the secondary chamber 110. At this time, the pressed raw material is conveyed to the secondary chamber 110 by an oil pump 111. However, after entering the secondary cavity 110, the raw material will come into contact with the transfer pipe 13. The cooling medium in the water tank 17 is input into the sub-pipe 15 by the water pump 112, and then distributed into the delivery pipe 14 by the sub-pipe 15. Under the continuous action of pressure, the cooling medium will enter the transfer pipe 13. The transfer pipe 13 is a vertical cylindrical tube and has a baffle 18 installed inside. The bottom end of the baffle 18 has a certain gap with the top surface of the inner side of the transfer pipe 13, thus dividing the transfer pipe 13 into two spaces.
[0027] After the cooling medium enters, it flows through the gap into another space. Simultaneously, a drain pipe 16 is designed at the top side of this other space. The cooling medium then enters the drain pipe 16 in a U-shaped loop, and is subsequently guided back into the water tank 17 by the drain pipe 16, forming a circulation system. During this process, a horizontal plate 116 is provided on one side of the diversion pipe 13. A movable arm 115 is rotatably connected to one side of the horizontal plate 116. The other end of the movable arm 115 is installed at the edge of the fixed plate 114. Starting the motor 113 causes the fixed plate 114 to rotate. The reciprocating motion of the transfer tube 13, inner plate 12, and water tank 17 causes the raw material to come into contact with the transfer tube 13 in a dynamic manner. The low temperature on the surface of the transfer tube 13 continuously removes heat from the raw material through heat conduction, accelerating the cooling efficiency. The reciprocating motion of the inner plate 12 causes the contact position between the transfer tube 13 and the raw material to change, avoiding uneven local temperature and achieving a more uniform cooling effect. After the raw material cooling is completed, a valve is designed at one end of the secondary cavity 110. By opening the liquid passage of the valve, the liquid in the secondary cavity 110 is discharged.
[0028] Example 2: Please refer to Figures 1-5 The auxiliary mechanism 2 includes a closing plate 21, the bottom end of which is rotatably connected to the inner wall of the main cavity 11. A heat dissipation mesh 22 is provided on the inner surface of the main cavity 11, and the inner surface of the main cavity 11 is fixedly connected to the outer side of the heat dissipation mesh 22.
[0029] To improve the heat dissipation of the raw material, a closed plate 21 is provided on the inner wall of the main cavity 11. During the cooling process, the closed plate 21 is fastened to expose the heat dissipation mesh 22 on the main cavity 11. This increases the gas flow in the main cavity 11, thereby accelerating the heat exchange efficiency between the raw material and the heat exchange tube 13 and the wall of the secondary cavity 110. This allows the raw material temperature to drop to the target range more quickly. The turbulence effect formed by forced convection effectively eliminates the temperature gradient in the secondary cavity 110, avoiding local overheating or overcooling. This ensures that every drop of raw material can be cooled in a stable cooling environment, improving cooling uniformity. Furthermore, the heat dissipation mesh 22 can prevent impurities from the surrounding environment from entering the main cavity 11 during the gas flow process.
[0030] Please see Figures 1-5 The pressed raw material is transported to the secondary chamber 110 by the oil pump 111. After entering the secondary chamber 110, the raw material will come into contact with the transfer pipe 13. The cooling medium in the water tank 17 is input into the sub-pipe 15 by the water pump 112. The sub-pipe 15 distributes the cooling medium into the delivery pipe 14. Under the continuous action of pressure, the cooling medium will enter the transfer pipe 13. The cooling medium will enter the drain pipe 16 in a U-shaped loop. Then the drain pipe 16 will guide the cooling medium back into the water tank 17 to form a circulation system. During this process, since there is a horizontal plate 116 on one side of the transfer pipe 13, and a movable arm 115 is rotatably connected to one side of the horizontal plate 116, and the other end of the movable arm 115 is installed at the edge of the fixed plate 114, the fixed plate 114 is started by starting the motor 113, and then the transfer pipe 13, the inner plate 12 and the water tank 17 move slowly back and forth synchronously, so that the raw material comes into contact with the transfer pipe 13 in a dynamic manner.
[0031] A closing plate 21 is provided on the inner wall of the main cavity 11. Then, during the cooling operation, the closing plate 21 is fastened to expose the heat dissipation mesh 22 on the main cavity 11. This increases the gas flow in the main cavity 11, thereby accelerating the heat exchange efficiency between the raw material and the heat exchange tube 13 and the wall of the secondary cavity 110, so that the raw material temperature can drop to the target range more quickly. The turbulence effect formed by forced convection effectively eliminates the temperature gradient in the secondary cavity 110 and avoids local overheating or overcooling.
Claims
1. A cooling and conveying device for raw materials in edible oil production, characterized in that: The system includes a cooling mechanism (1), an auxiliary mechanism (2) on the inner wall of the cooling mechanism (1), a main cavity (11), an inner plate (12) on the inner wall of the main cavity (11), the inner wall of the main cavity (11) and the outer side of the inner plate (12) being slidably connected through the inner wall, a flow-transfer pipe (13) on the inner wall of the inner plate (12), the inner wall of the inner plate (12) and the outer side of the flow-transfer pipe (13) being fixedly connected through the inner wall, ... A horizontal plate (116) is provided on one side of the tube (13). One side of the tube (13) is rotatably connected to one side end of the horizontal plate (116). A movable arm (115) is provided at one side end of the horizontal plate (116). One side end of the horizontal plate (116) is rotatably connected to one end of the movable arm (115). A fixed plate (114) is provided at the other end of the movable arm (115). The other end of the movable arm (115) is rotatably connected to the edge of the fixed plate (114).
2. The edible oil production raw material cooling and conveying device according to claim 1, characterized in that: The auxiliary mechanism (2) includes a closing plate (21), the bottom end of which is rotatably connected to the inner wall of the main cavity (11), and a heat dissipation mesh (22) is provided on the inner surface of the main cavity (11), and the inner surface of the main cavity (11) is fixedly connected to the outer side of the heat dissipation mesh (22).
3. The edible oil production raw material cooling and conveying device according to claim 1, characterized in that: The inside of the diversion pipe (13) is provided with a partition (18), and the inside of the diversion pipe (13) is fixedly connected to the outer top of the partition (18). A drain pipe (16) is provided on one side of the diversion pipe (13), and one side of the diversion pipe (13) is fixedly connected to one end of the drain pipe (16). A water tank (17) is provided at the other end of the drain pipe (16), and the other end of the drain pipe (16) is fixedly connected to one side of the water tank (17).
4. The edible oil production raw material cooling and conveying device according to claim 3, characterized in that: The inner wall of the water tank (17) is provided with a water pump (112), and the inner wall of the water tank (17) is fixedly connected to one side of the water pump (112). The output end of the water pump (112) is provided with a sub-pipe (15), and the output end of the water pump (112) is fixedly connected to one side of the sub-pipe (15).
5. The edible oil production raw material cooling and conveying device according to claim 4, characterized in that: A conveying pipe (14) is provided on one side of the sub-pipe (15). One side of the sub-pipe (15) is fixedly connected to one end of the conveying pipe (14), and the other end of the conveying pipe (14) is fixedly connected to one side of the transfer pipe (13).
6. The edible oil production raw material cooling and conveying device according to claim 5, characterized in that: One end of the transfer pipe (13) is provided with a bracket (19), one end of the transfer pipe (13) is fixedly connected to one end of the bracket (19), the bottom side of the bracket (19) is fixedly connected to the top side of the inner plate (12), and the other end of the bracket (19) is fixedly connected to the bottom side of the water tank (17).
7. The edible oil production raw material cooling and conveying device according to claim 1, characterized in that: The main cavity (11) has a secondary cavity (110) on its inner side. The inner side of the main cavity (11) is fixedly connected to the top end of the secondary cavity (110). The inner wall of the secondary cavity (110) is provided with an oil pump (111). The inner wall of the secondary cavity (110) is connected to the output end of the oil pump (111). The bottom side of the oil pump (111) is fixedly connected to one side of the main cavity (11).
8. The edible oil production raw material cooling and conveying device according to claim 7, characterized in that: A motor (113) is provided at one side end of the main cavity (11). The side end of the main cavity (11) is fixedly connected to the bottom side of the motor (113). The output end of the motor (113) is fixedly connected to the center of the fixed disk (114).