Intelligent temperature control filling device for wolfberry raw pulp
By introducing a temperature sensor and a spiral regulating tube into the wolfberry pulp filling equipment, the problems of temperature fluctuation and viscosity adaptability of traditional equipment have been solved, achieving precise temperature control and temperature uniformity, and improving filling quality.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- NINGXIA ZHONGNING CHUNQI WOLFBERRY TECH CO LTD
- Filing Date
- 2025-07-10
- Publication Date
- 2026-07-14
AI Technical Summary
Traditional goji berry pulp filling equipment uses a jacketed heating structure, which results in large temperature fluctuations, easily leading to localized overheating and damage to nutrients. In addition, it lacks a real-time monitoring system and is difficult to adapt to the viscosity differences between different batches of pulp.
The temperature sensor inside the tank monitors the temperature of the raw pulp in real time. The processor calculates the deviation and controls the flow of the heat medium. Combined with the spiral regulating tube to increase the heat exchange area, precise temperature control is achieved. The drive shaft drives the fan blades to stir and ensure temperature uniformity.
It achieves precise temperature control and temperature uniformity of goji berry pulp, prevents nutrient loss, adapts to viscosity changes in different batches of pulp, and ensures filling quality.
Smart Images

Figure CN224491773U_ABST
Abstract
Description
Technical Field
[0001] This utility model belongs to the technical field of wolfberry filling equipment, and more specifically, it relates to an intelligent temperature-controlled filling device for wolfberry pulp. Background Technology
[0002] As a health food rich in heat-sensitive nutrients such as polysaccharides and carotenoids, wolfberry juice is more conducive to nutrient absorption in its liquid form compared to solid wolfberry granules. The temperature and uniformity of wolfberry juice must be strictly controlled during the filling process.
[0003] However, traditional goji berry pulp filling equipment still has the following problems:
[0004] First, the traditional tank heating method uses a jacketed heating structure, which causes large temperature fluctuations and can easily lead to local overheating that damages nutrients, thus affecting the quality of goji berries.
[0005] Secondly, the lack of a real-time monitoring system and reliance on manual experience for adjustment makes it difficult to adapt to viscosity differences between different batches of raw pulp. Utility Model Content
[0006] To address the aforementioned technical problems, this utility model provides an intelligent temperature-controlled filling device for wolfberry pulp, which solves the problems of existing tank heating methods using a jacketed heating structure, resulting in large temperature fluctuations that easily lead to local overheating and damage to nutrients, as well as the lack of a real-time monitoring system, reliance on manual experience for adjustment, and difficulty in adapting to the viscosity differences of different batches of pulp.
[0007] The purpose and effect of this utility model of a smart temperature-controlled filling device for wolfberry pulp are achieved by the following specific technical means: A smart temperature-controlled filling device for wolfberry pulp includes: a tank;
[0008] A discharge pipe is fixedly installed on the lower end face of the tank, a cavity is opened inside the side wall of the tank, and a cover plate is connected to the upper end face of the tank.
[0009] A drive motor is fixedly installed at the middle position of the upper end face of the cover plate, and a connecting shaft is connected to the lower end face of the drive motor. A first connecting groove is opened on the lower end face of the connecting shaft.
[0010] The drive shaft has three shafts. A connecting screw is fixedly installed on the upper end face of the drive shaft. The connecting screw on the surface of the uppermost drive shaft is threaded into the first connecting groove. A fan blade is fixedly installed on the outside of the drive shaft.
[0011] The processor is fixedly installed on the outer end face of the tank body, and a connecting pipe is fixedly installed on the lower end face of the processor. An adjusting pipe is fixedly installed at the end of the connecting pipe. The adjusting pipe is located inside the cavity and the end of the adjusting pipe is connected to the processor.
[0012] A probe rod is fixedly installed on the upper surface of the processor.
[0013] Furthermore, the main body of the regulating pipe has a spiral structure, and a regulating valve is fixedly installed on the surface of the connecting pipe.
[0014] Furthermore, the front end of the probe is located inside the tank, and a temperature sensor is fixedly installed at the end of the probe, with the temperature sensor located in the middle of the tank.
[0015] Furthermore, the first connecting groove has a thread inside, and the connecting screw at the upper end of the drive shaft is threaded into the first connecting groove.
[0016] Furthermore, a second connecting groove is provided on the lower end face of the drive shaft, and the interior of the second connecting groove is threaded.
[0017] Furthermore, three support legs are installed in a ring shape below the outer end face of the tank body, threaded holes are opened on the upper end face of the tank body, threaded holes are opened on the surface of the cover plate, and the cover plate is connected to the tank body by bolts.
[0018] Compared with the prior art, the present invention has the following beneficial effects:
[0019] 1. A probe rod is fixedly installed on the upper surface of the processor. The front end of the probe rod is inside the tank, and a temperature sensor is fixedly installed at the end of the probe rod. The temperature sensor can monitor the temperature of the raw pulp inside the tank in real time, and the data is transmitted to the processor in real time for further processing.
[0020] 2. After receiving the temperature data, the processor calculates the deviation through an algorithm and controls the regulating valve to adjust the flow rate of the heat medium inside the connecting pipe. The regulating pipe is located in the cavity inside the side wall of the tank and has a spiral structure, which can increase the heat exchange area. The heat medium passes through the connecting pipe and enters the spiral regulating pipe, where it indirectly exchanges heat with the original slurry inside the tank, thus achieving the purpose of precise temperature control.
[0021] 3. The connecting screw on the surface of the uppermost drive shaft is threaded into the first connecting groove on the lower surface of the connecting shaft, and the connecting screw on the upper end of the middle drive shaft is threaded into the second connecting groove on the lower end of the uppermost drive shaft. In actual operation, the worker can increase or decrease the number of drive shafts according to the height of the tank, thereby improving the practicality of this device.
[0022] 4. When the drive shaft drives the fan blades at the outer end to rotate, it can mix and stir the solution inside the tank, ensuring that the temperature of the upper and lower layers of the pulp is uniform and preventing protein coagulation and meat precipitation. A discharge pipe is installed in the middle of the lower end face of the tank. A peristaltic pump or piston filling head can be connected to the discharge port at the bottom of the discharge pipe to facilitate the filling of wolfberry pulp. Attached Figure Description
[0023] Figure 1 This is a schematic diagram of the overall device structure of this utility model.
[0024] Figure 2 This is a schematic diagram of the internal structure of the tank body of this utility model.
[0025] Figure 3 This is a schematic diagram of the processor, regulating tube, and connecting tube structure of this utility model.
[0026] Figure 4 This is an exploded view and structural diagram of the coupling and drive shaft of this utility model.
[0027] Figure 5 This is a utility model Figure 4 A magnified schematic diagram of the structure at point A in the middle.
[0028] Figure 6 This is an exploded structural diagram of the cover plate and tank body of this utility model.
[0029] In the diagram, the correspondence between component names and drawing numbers is as follows:
[0030] 1. Tank body; 101. Support leg; 102. Cover plate; 103. Cavity; 104. Discharge pipe; 2. Drive motor; 201. Coupling; 2011. First connecting groove; 3. Drive shaft; 301. Connecting screw; 302. Fan blade; 303. Second connecting groove; 4. Processor; 401. Connecting pipe; 4011. Regulating valve; 402. Regulating pipe; 5. Detector rod. Detailed Implementation
[0031] 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.
[0032] Example:
[0033] As attached Figure 1 To be continued Figure 6 As shown:
[0034] This utility model provides an intelligent temperature-controlled filling device for wolfberry pulp, including a tank 1;
[0035] A discharge pipe 104 is fixedly installed on the lower end face of the tank body 1, a cavity 103 is opened inside the side wall of the tank body 1, and a cover plate 102 is connected to the upper end face of the tank body 1.
[0036] The drive motor 2 is fixedly installed in the middle of the upper end face of the cover plate 102. The lower end face of the drive motor 2 is connected to the connecting shaft 201, and the lower end face of the connecting shaft 201 is provided with a first connecting groove 2011.
[0037] Drive shaft 3, there are three drive shafts 3. A connecting screw 301 is fixedly installed on the upper end face of the drive shaft 3. The connecting screw 301 on the surface of the uppermost drive shaft 3 is threaded into the first connecting groove 2011. A fan blade 302 is fixedly installed on the outside of the drive shaft 3.
[0038] Processor 4 is fixedly installed on the outer end face of tank 1. A connecting pipe 401 is fixedly installed on the lower end face of processor 4. An adjusting pipe 402 is fixedly installed at the end of the connecting pipe 401. The adjusting pipe 402 is located inside the cavity 103 and the end of the adjusting pipe 402 is connected to processor 4.
[0039] The probe rod 5 is fixedly installed on the upper surface of the processor 4.
[0040] The regulating pipe 402 has a spiral structure, and the regulating valve 4011 is fixedly installed on the surface of the connecting pipe 401. In use, the regulating pipe 402 is located in the cavity 103 inside the side wall of the tank 1. The spiral structure of the regulating pipe 402 can increase the heat exchange area. The heat medium passes through the connecting pipe 401 and enters the spiral regulating pipe 402, and indirectly exchanges heat with the raw slurry inside the tank 1 to achieve the purpose of precise temperature control.
[0041] The front end of the probe rod 5 is located inside the tank 1, and a temperature sensor is fixedly installed at the end of the probe rod 5. The temperature sensor is located in the middle of the tank 1. During use, the probe rod 5 is fixedly installed on the upper surface of the processor 4. The front end of the probe rod 5 is inside the tank 1, and a temperature sensor is fixedly installed at the end of the probe rod 5. The temperature sensor can monitor the temperature of the raw slurry in the tank in real time, and the data is transmitted to the processor 4 in real time. After receiving the temperature data, the processor 4 calculates the deviation through an algorithm and controls the regulating valve 4011 to adjust the flow rate of the heat medium inside the connecting pipe 401.
[0042] The first connecting groove 2011 has a thread inside, and the connecting screw 301 at the upper end of the drive shaft 3 is threaded into the first connecting groove 2011. The lower end face of the drive shaft 3 has a second connecting groove 303, which has a thread inside. In use, the connecting screw 301 on the surface of the lowermost drive shaft 3 is threaded into the second connecting groove 303 at the lower end of the middle drive shaft 3. In actual operation, the worker can increase or decrease the number of drive shafts 3 according to the height of the tank 1.
[0043] The tank body 1 has three support legs 101 installed in a ring shape below the outer end face. The upper end face of the tank body 1 has threaded holes, and the surface of the cover plate 102 has threaded holes. The cover plate 102 is connected to the tank body 1 by bolts. In use, the support legs 101 can improve the stability of the tank body 1. The cover plate 102 is connected to the tank body 1 by bolts, which facilitates the disassembly and maintenance of the cover plate 102.
[0044] The specific usage and function of this embodiment are as follows:
[0045] In this invention, a probe rod 5 is fixedly installed on the upper surface of the processor 4. The front end of the probe rod 5 is inside the tank 1, and a temperature sensor is fixedly installed at the end of the probe rod 5. The temperature sensor can monitor the temperature of the raw slurry inside the tank in real time, and the data is transmitted to the processor 4 in real time. After receiving the temperature data, the processor 4 calculates the deviation through an algorithm and controls the regulating valve 4011 to regulate the flow rate of the heat medium inside the connecting pipe 401. The regulating pipe 402 is located in the cavity 103 inside the side wall of the tank 1, and the regulating pipe 402 has a spiral structure, which can increase the heat exchange area. The heat medium passes through the connecting pipe 401 and enters the spiral regulating pipe 402, and indirectly exchanges heat with the raw slurry inside the tank 1 to achieve precise temperature control. A drive motor 2 is fixedly installed on the upper surface of the cover plate 102, and the lower surface of the drive motor 2 is connected to the driving shaft 201. The connecting screw 301 on the surface of the drive shaft 3 is threaded into the first connecting groove 2011 on the lower end surface of the connecting shaft 201. The connecting screw 301 on the upper end of the middle drive shaft 3 is threaded into the second connecting groove 303 at the lower end of the uppermost drive shaft 3. The connecting screw 301 on the surface of the lowermost drive shaft 3 is threaded into the second connecting groove 303 at the lower end of the middle drive shaft 3. In actual operation, the number of drive shafts 3 can be increased or decreased according to the height of the tank 1. When the drive shaft 3 drives the fan blade 302 at the outer end to rotate, it can mix and stir the solution inside the tank 1 to ensure that the temperature of the upper and lower layers of the pulp is uniform and to prevent protein coagulation and meat precipitation. A discharge pipe 104 is installed in the middle of the lower end face of the tank 1. A peristaltic pump or a piston filling head can be connected to the discharge port at the bottom of the discharge pipe 104 to facilitate the filling of the wolfberry pulp.
Claims
1. A smart temperature-controlled filling device for wolfberry pulp, characterized in that: include: Tank body (1), a discharge pipe (104) is fixedly installed on the lower end face of the tank body (1), a cavity (103) is opened inside the side wall of the tank body (1), and a cover plate (102) is connected to the upper end face of the tank body (1); drive motor (2), the drive motor (2) is fixedly installed in the middle position of the upper end face of the cover plate (102), a connecting shaft (201) is connected to the lower end face of the drive motor (2), and a first connecting groove (2011) is opened on the lower end face of the connecting shaft (201); drive shaft (3), there are three drive shafts (3), a connecting screw (301) is fixedly installed on the upper end face of the drive shaft (3), the uppermost one is the connecting screw (301) of the drive shaft (3). The connecting screw (301) on the surface of the drive shaft (3) is threaded into the first connecting groove (2011), and the fan blade (302) is fixedly installed on the outside of the drive shaft (3); the processor (4) is fixedly installed on the outer end face of the tank (1), the lower end face of the processor (4) is fixedly installed with a connecting pipe (401), the end of the connecting pipe (401) is fixedly installed with an adjusting pipe (402), the adjusting pipe (402) is located inside the cavity (103), and the end of the adjusting pipe (402) is connected to the processor (4); the probe (5) is fixedly installed on the upper end face of the processor (4).
2. The intelligent temperature-controlled filling device for wolfberry pulp as described in claim 1, characterized in that: The main body of the regulating pipe (402) has a spiral structure, and the regulating valve (4011) is fixedly installed on the surface of the connecting pipe (401).
3. The intelligent temperature-controlled filling device for wolfberry pulp as described in claim 1, characterized in that: The front end of the probe (5) is located inside the tank (1), and a temperature sensor is fixedly installed at the end of the probe (5). The temperature sensor is located in the middle of the tank (1).
4. The intelligent temperature-controlled filling device for wolfberry pulp as described in claim 1, characterized in that: The first connecting groove (2011) has a thread inside, and the connecting screw (301) at the upper end of the drive shaft (3) is threaded into the first connecting groove (2011).
5. The intelligent temperature-controlled filling device for wolfberry pulp as described in claim 1, characterized in that: The lower end face of the drive shaft (3) is provided with a second connecting groove (303), and the interior of the second connecting groove (303) is provided with threads.
6. The intelligent temperature-controlled filling device for wolfberry pulp as described in claim 1, characterized in that: The tank (1) has three support legs (101) installed in a ring below the outer end face. The upper end face of the tank (1) has a threaded hole, and the surface of the cover plate (102) has a threaded hole. The cover plate (102) is connected to the tank (1) by bolts.