A ceramic slurry mixing device

By combining the support base, cooling mechanism, water pump, cooling pipe and threaded heat dissipation pipe, the problem of excessive temperature after ceramic slurry treatment is solved, and effective cooling and improved device stability are achieved.

CN224425977UActive Publication Date: 2026-06-30LUZHOU MAOYUAN CERAMICS MFG CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
LUZHOU MAOYUAN CERAMICS MFG CO LTD
Filing Date
2025-06-16
Publication Date
2026-06-30

AI Technical Summary

Technical Problem

Excessive temperature after ceramic slurry treatment can affect subsequent ceramic processing.

Method used

The design employs a combination of support base, cooling mechanism, water pump, cooling pipe and threaded heat dissipation pipe, and reduces the temperature of the slurry through cooling water circulation and heat dissipation fins.

Benefits of technology

It effectively reduces the temperature of ceramic slurry, improving the stability and energy efficiency of the equipment.

✦ Generated by Eureka AI based on patent content.

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Abstract

This utility model discloses a ceramic slurry mixing device, relating to the technical field of mixing devices. After ceramic slurry processing, the slurry temperature may become excessively high, affecting subsequent ceramic processing. This utility model includes a support base and a cooling mechanism, with the cooling mechanism located at the top of the support base. The cooling mechanism includes a cooling tank located at the top of the support base. This utility model, by incorporating a support base, a cooling mechanism, a cooling pipe, and a water pump, utilizes the water pump to transport cooling water from inside the water tank to the cooling pipe via a water delivery pipe. The cooling water flows within the cooling pipe, carrying away heat from the mixing tank. Subsequently, the cooling water is transported to a threaded heat dissipation pipe, where the heat dissipation fins on the outside facilitate cooling of the water inside the threaded heat dissipation pipe. Finally, the cooled water is discharged back into the water tank, thereby conveniently cooling the ceramic slurry inside the device and improving the stability of the device.
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Description

Technical Field

[0001] This utility model relates to the technical field of mixing devices, specifically a ceramic slurry mixing device. Background Technology

[0002] In the field of ceramic production, the preparation of ceramic slurry is a crucial step, as its quality directly affects the performance and quality of the final ceramic product. Ceramics are typically made from clay and various natural minerals through a series of processes including crushing, mixing, molding, and firing. During the preparation of ceramic slurry, air bubbles can form, interfering with the molding process. Therefore, a ceramic slurry mixing device is needed to control these bubbles.

[0003] Regarding the aforementioned related technologies, the applicant believes that when a ceramic slurry mixing device is in operation, by placing the ceramic slurry inside the device and using the operation of the drive motor to drive the stirring rod to rotate, the ceramic slurry inside the device can be stirred. Then, by using the operation of the built-in heating tube, the ceramic slurry inside the device can be heated at a constant temperature, thereby reducing the surface tension of the slurry and promoting the escape of internal bubbles. However, the ceramic slurry will become too hot after processing, which will affect the subsequent ceramic processing. Utility Model Content

[0004] The purpose of this invention is to provide a ceramic slurry mixing device to solve the problem mentioned in the background art that the temperature of the ceramic slurry becomes too high after processing, thereby affecting the subsequent ceramic processing.

[0005] To achieve the above objectives, this utility model provides the following technical solution: a ceramic slurry mixing device, comprising a support base and a cooling mechanism, wherein the cooling mechanism is disposed at the top of the support base, and the cooling mechanism includes a cooling box disposed at the top of the support base, a water tank disposed at one end of the cooling box, a water pump disposed at the bottom of the water tank, a water delivery pipe disposed at the output end of the water pump, a cooling pipe disposed at the end of the water delivery pipe away from the water pump, and a threaded heat dissipation pipe disposed at the end of the cooling pipe away from the water delivery pipe, the end of the threaded heat dissipation pipe away from the cooling pipe being inserted into the interior of the water tank, and heat dissipation fins being uniformly disposed on the exterior of the threaded heat dissipation pipe.

[0006] By adopting the above technical solution, the cooling water inside the water tank can be transported to the cooling pipe through the water supply pipe using the operation of the water pump. The cooling water flows inside the cooling pipe, which can remove the heat inside the mixing tank. Then the cooling water is transported to the threaded heat dissipation pipe. The heat dissipation fins on the outside of the threaded heat dissipation pipe can easily cool the cooling water inside the threaded heat dissipation pipe. Finally, the cooled water is discharged into the water tank, which can facilitate the cooling of the ceramic slurry inside the device and improve the stability of the device.

[0007] Preferably, a mixing tank is provided through the interior of the support base, and a feeding port is provided at one end of the mixing tank.

[0008] By adopting the above technical solution, ceramic slurry can be put into the interior of the mixing tank through the feeding port.

[0009] Preferably, a drive motor is provided in the middle part of the top of the mixing tank, and a stirring rod is provided at the output end of the drive motor.

[0010] By adopting the above technical solution, the operation of the drive motor can drive the stirring rod to rotate, thereby stirring the ceramic slurry inside the mixing tank.

[0011] Preferably, heating tubes are provided at both ends inside the mixing tank.

[0012] By adopting the above technical solution, the ceramic slurry inside the mixing tank can be heated at a constant temperature using the heating tube, thereby reducing the surface tension of the slurry and promoting the escape of internal bubbles.

[0013] Preferably, a discharge hopper is provided at the bottom of the mixing tank, and a discharge pipe is provided through the bottom of the discharge hopper.

[0014] By adopting the above technical solution, the cooled ceramic slurry can be easily discharged.

[0015] Preferably, a viewing window is provided on one side of the cooling box, and the viewing window is made of transparent acrylic sheet.

[0016] By adopting the above technical solution, it is convenient for staff to observe the cooling box.

[0017] Preferably, a cooling fan is provided at the bottom of the cooling box near the threaded heat dissipation pipe, and heat dissipation holes are evenly distributed at the top of the cooling box near the cooling fan.

[0018] By adopting the above technical solution, the cooling fan can blow air onto the cooling fins on the outside of the threaded cooling tube, and the cooling fins can quickly dissipate the heat carried by the cooling water to the surrounding environment, thereby effectively reducing the temperature of the cooling water.

[0019] Preferably, an air inlet is provided at the bottom of the cooling box near the heat dissipation fan, and a dustproof screen is installed inside the air inlet.

[0020] By adopting the above technical solution, the intake air can be easily filtered, minimizing the intake of impurities into the cooling box.

[0021] Compared with the prior art, the beneficial effects of this utility model are:

[0022] The device is equipped with a support base, a cooling mechanism, cooling pipes, and a water pump. The water pump delivers cooling water from the water tank to the cooling pipes via a water pipe. The cooling water flows inside the cooling pipes, carrying away heat from the mixing tank. The cooling water is then delivered to the threaded heat dissipation pipes, where the heat dissipation fins on the outside facilitate cooling. Finally, the cooled water is discharged back into the water tank, thus effectively cooling the ceramic slurry inside the device and improving its stability. Attached Figure Description

[0023] Figure 1 This is a schematic diagram of the overall three-dimensional structure of the present invention;

[0024] Figure 2 This is a schematic diagram of the overall front view of the present invention;

[0025] Figure 3 This is a three-dimensional structural diagram of the cooling box of this utility model;

[0026] Figure 4 This is a schematic diagram of the internal structure of the cooling box of this utility model.

[0027] In the diagram: 1. Feeding port; 2. Mixing tank; 3. Support base; 4. Cooling mechanism; 401. Cooling box; 402. Cooling pipe; 403. Heat dissipation hole; 404. Viewing window; 405. Water supply pipe; 406. Threaded heat dissipation pipe; 407. Heat dissipation fins; 408. Heat dissipation fan; 409. Air inlet; 410. Water pump; 411. Water tank; 5. Drive motor; 6. Heating pipe; 7. Stirring rod; 8. Discharge hopper; 9. Discharge pipe. Detailed Implementation

[0028] 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.

[0029] Example 1

[0030] Please see Figures 1 to 4This embodiment provides a technical solution: a ceramic slurry mixing device, including a support base 3 and a cooling mechanism 4. The cooling mechanism 4 is located at the top of the support base 3 and includes a cooling box 401 fixedly connected to the top of the support base 3. One end of the cooling box 401 is fixedly connected to a water tank 411, which can conveniently store cooling water. A water pump 410 is installed at the bottom of the water tank 411, and a water delivery pipe 405 is installed at the output end of the water pump 410. The water pump 410 drives the cooling cycle based on the centrifugal force principle. When the water pump 410 starts, the internal impeller rotates at high speed, causing the cooling water in the pump chamber to gain kinetic energy and be thrown out along the tangential direction of the blades. It is then transported to the outside through the water delivery pipe 405. When selecting the appropriate model, it should be selected according to the actual needs. All the components required in the water pump 410 are existing technologies and will not be described in detail below.

[0031] A cooling pipe 402 is provided at the end of the water supply pipe 405 away from the water pump 410. The cooling pipe 402 adopts a serpentine layout and is tightly fitted to the inner wall of the mixing tank 2. A threaded heat dissipation pipe 406 is provided at the end of the cooling pipe 402 away from the water supply pipe 405. The threaded heat dissipation pipe 406 is located inside the cooling box 401. The end of the threaded heat dissipation pipe 406 away from the cooling pipe 402 is inserted into the water tank 411. Heat dissipation fins 407 are evenly arranged on the outside of the threaded heat dissipation pipe 406. The heat dissipation fins 407 can quickly dissipate the heat carried by the cooling water inside the threaded heat dissipation pipe 406 to the surrounding environment. A viewing window 404 is provided on one side of the cooling box 401. The viewing window 404 is made of transparent acrylic sheet, which allows the staff to easily observe the cooling box 401.

[0032] The overall effect of Embodiment 1 is as follows: by starting the water pump 410 with the control switch, the cooling water in the water tank 411 can be directionally transported through the water pipe 405 to the cooling pipe 402 inside the mixing tank 2. The cooling pipe 402 adopts a serpentine layout and fits tightly against the inner wall of the mixing tank 2, which greatly increases the heat exchange area. When the low-temperature cooling water flows in the pipe, it quickly absorbs the excess heat generated in the mixing tank 2 due to continuous stirring and heating through heat conduction and convection heat exchange mechanisms, thereby achieving the initial cooling of the ceramic slurry.

[0033] Example 2

[0034] A mixing tank 2 is installed inside the support base 3. A feeding port 1 is located at one end of the mixing tank 2. A drive motor 5 is located in the middle of the top of the mixing tank 2. The drive motor 5 converts energy based on the principle of electromagnetic induction and its internal structure includes two core components: a stator and a rotor. When the drive motor 5 is powered on, three-phase alternating current is applied to the stator windings, generating a rotating magnetic field in space. This magnetic field cuts the rotor conductors, generating an induced electromotive force and induced current in the rotor conductors according to the law of electromagnetic induction. The current-carrying rotor conductors are subjected to electromagnetic force in the rotating magnetic field. According to the left-hand rule, this electromagnetic force forms an electromagnetic torque, driving the rotor to rotate along the direction of the magnetic field rotation. This efficiently converts electrical energy into mechanical energy, providing stable power output for mechanical actions such as mold separation. When selecting the drive motor 5, an appropriate model should be chosen based on actual needs. All components required within the drive motor 5 are existing technologies and will not be described further below.

[0035] The output end of the drive motor 5 is equipped with a stirring rod 7, which can stir the ceramic slurry inside the mixing tank 2. Both ends of the mixing tank 2 are equipped with heating tubes 6. The working principle of the heating tubes 6 is to generate Joule heat when current passes through a heating element with resistive characteristics, directly converting electrical energy into heat energy and transferring it to the surrounding medium. The core component inside is a resistance wire, which is wrapped with high-temperature resistant insulating material and a metal sleeve. After being energized, the resistance wire generates heat due to the work done by the current, which is evenly conducted to the metal shell through the insulating material, and then heats the air, liquid or solid through heat conduction, convection or radiation. It is equipped with a temperature control component. After the set temperature is reached, the heating tube 6 will stop working. When selecting it, the appropriate model should be selected according to the actual needs. All the components required in the heating tube 6 are existing technologies and will not be described in detail below.

[0036] A discharge hopper 8 is provided at the bottom of the mixing tank 2, and a discharge pipe 9 is provided through the bottom of the discharge hopper 8 to facilitate the discharge of the cooled ceramic slurry.

[0037] The effect achieved by the entire second embodiment is as follows: ceramic slurry is put into the interior of mixing tank 2 through feeding port 1, drive motor 5 is started by control switch, and the operation of drive motor 5 can drive stirring rod 7 to rotate, which can stir the ceramic slurry inside mixing tank 2. Then, the operation of heating tube 6 inside mixing tank 2 can keep the ceramic slurry inside mixing tank 2 heated at a constant temperature, thereby reducing the surface tension of the slurry and promoting the escape of internal bubbles.

[0038] Example 3

[0039] A cooling fan 408 is installed at the bottom of the cooling box 401, near the threaded heat dissipation pipe 406. The cooling fan 408 works by using wing-like blades that rotate at high speed to drive the gas axially using the lift principle of aerodynamics. When selecting a fan, an appropriate model should be chosen according to actual needs. All components required within the cooling fan 408 are existing technologies and will not be described in detail below.

[0040] The cooling box 401 has heat dissipation holes 403 evenly distributed at the top end near the cooling fan 408, and an air inlet 409 is provided at the bottom end near the cooling fan 408. The air inlet 409 is equipped with a dustproof screen.

[0041] The overall effect of Embodiment 3 is as follows: The cooling fan 408 blows air onto the cooling fins 407 outside the threaded cooling pipe 406, causing the cooling fins 407 to quickly dissipate the heat carried by the cooling water into the surrounding environment, effectively reducing the cooling water temperature. Finally, the cooled water flows back into the water tank 411, facilitating the recycling of the cooling water and improving the energy efficiency and environmental friendliness of the device.

[0042] Working principle: The ceramic slurry is put into the mixing tank 2 through the feeding port 1. The drive motor 5 is started by the control switch. The operation of the drive motor 5 can drive the stirring rod 7 to rotate, which can stir the ceramic slurry inside the mixing tank 2. Then, the heating tube 6 inside the mixing tank 2 can be used to heat the ceramic slurry inside the mixing tank 2 at a constant temperature, thereby reducing the surface tension of the slurry and promoting the escape of internal air bubbles.

[0043] Secondly, after the ceramic slurry is mixed, the water pump 410 is started using a control switch, which can directionally transport the cooling water in the water tank 411 to the cooling pipe 402 inside the mixing tank 2 through the water supply pipe 405. The cooling pipe 402 adopts a serpentine layout and fits tightly against the inner wall of the mixing tank 2, which greatly increases the heat exchange area. When the low-temperature cooling water flows in the pipe, it quickly absorbs the excess heat generated in the mixing tank 2 due to continuous mixing and heating through heat conduction and convection heat exchange mechanisms, thereby achieving the initial cooling of the ceramic slurry.

[0044] Finally, the cooled water that has absorbed heat flows into the threaded heat dissipation tube 406. The cooling fan 408 then blows air onto the heat dissipation fins 407 on the outside of the threaded heat dissipation tube 406, rapidly dissipating the heat carried by the cooling water into the surrounding environment, effectively lowering the cooling water temperature. Finally, the cooled water flows back into the water tank 411, facilitating the recycling of cooling water and improving the energy efficiency and environmental friendliness of the device.

[0045] In the description of this utility model, it should be noted that, unless otherwise explicitly specified and limited, the terms "installed," "equipped with," "connected," etc., should be interpreted broadly. For example, "connection" can be a fixed connection, a detachable connection, or an integral connection; it can be a mechanical connection or an electrical connection; it can be a direct connection or an indirect connection through an intermediate medium; it can be a connection within two components. For those skilled in the art, the specific meaning of the above terms in this utility model can be understood according to the specific circumstances.

[0046] Although embodiments of the present invention have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made to these embodiments without departing from the principles and spirit of the present invention, the scope of which is defined by the appended claims and their equivalents.

Claims

1. A ceramic slurry mixing device, characterized in that: include: Support base (3); Cooling mechanism (4), the cooling mechanism (4) is set at the top of support base (3), the cooling mechanism (4) includes a cooling box (401) set at the top of support base (3), a water tank (411) is set at one end of the cooling box (401), a water pump (410) is set at the bottom of the water tank (411), a water pipe (405) is set at the output end of the water pump (410), a cooling pipe (402) is set at the end of the water pipe (405) away from the water pump (410), a threaded heat dissipation pipe (406) is set at the end of the cooling pipe (402) away from the water pipe (405), the end of the threaded heat dissipation pipe (406) away from the cooling pipe (402) is inserted into the interior of the water tank (411), and heat dissipation fins (407) are evenly arranged on the outside of the threaded heat dissipation pipe (406).

2. The ceramic slurry mixing device according to claim 1, characterized in that: The support base (3) has a through-hole mixing tank (2), and a feeding port (1) is provided at one end of the mixing tank (2).

3. The ceramic slurry mixing device according to claim 2, characterized in that: The middle part of the top of the mixing tank (2) is provided with a drive motor (5), and the output end of the drive motor (5) is provided with a stirring rod (7).

4. The ceramic slurry mixing device according to claim 2, characterized in that: Heating tubes (6) are provided at both ends inside the mixing tank (2).

5. A ceramic slurry mixing device according to claim 2, characterized in that: The bottom of the mixing tank (2) is provided with a discharge hopper (8), and a discharge pipe (9) is provided through the bottom of the discharge hopper (8).

6. The ceramic slurry mixing device according to claim 1, characterized in that: A viewing window (404) is provided on one side of the cooling box (401), which is made of transparent acrylic sheet.

7. The ceramic slurry mixing device according to claim 1, characterized in that: A cooling fan (408) is provided at the bottom of the cooling box (401) near the threaded heat dissipation pipe (406), and heat dissipation holes (403) are evenly opened at the top of the cooling box (401) near the cooling fan (408).

8. A ceramic slurry mixing device according to claim 7, characterized in that: The cooling box (401) has an air inlet (409) at the bottom end near the heat dissipation fan (408), and the air inlet (409) is equipped with a dustproof net.