Butter liquefaction and rapid and uniform spreading device
By using a pre-crushing, heating, and stirring design in the ghee liquefaction and rapid spreading device, the problems of uneven ghee liquefaction and stirring rod blockage are solved, achieving uniform and rapid ghee liquefaction and convenient maintenance.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- GUANGZHOU DANLE GREASE FOOD CO LTD
- Filing Date
- 2025-09-30
- Publication Date
- 2026-07-07
AI Technical Summary
Existing ghee liquefaction devices lack a pre-crushing mechanism, making it difficult to melt lumpy ghee evenly, and the stirring rod is prone to clogging, making maintenance inconvenient.
A device for rapid and even liquefaction of ghee was designed, comprising an annular box, a heat-conducting sleeve, an electric heater, a two-stage crushing and stirring assembly, and a lifting vertical guide drive support assembly. The device achieves uniform and rapid liquefaction of ghee by pre-crushing followed by heating and stirring, and allows for easy removal of the stirring assembly for cleaning.
It achieves uniform and rapid liquefaction of ghee, improves liquefaction efficiency, and facilitates quick cleaning and maintenance of the mixing components.
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Figure CN224462656U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of ghee processing technology, specifically to a ghee liquefaction and rapid spreading device. Background Technology
[0002] Butter is the essence of Tibetan food. It is a dairy product similar to butter, extracted from cow's milk and sheep's milk. Butter is one of the special oils used in the food industry. Solid butter has a certain degree of plasticity. Originally, butter referred to lard. Later, the consumption of butter made from hydrogenated vegetable oil or a small amount of other vegetable oils far exceeded that of lard.
[0003] Solid ghee is typically stored in small, cut pieces. When used in food processing, it generally needs to be liquefied by heating. During heating, the liquefied ghee must be stirred constantly; otherwise, uneven heating can cause carbonization or spoilage. Currently, the liquefaction of solid ghee often involves using a heating element in a stirring device, but this method has the following drawbacks:
[0004] 1. The lack of an integrated pre-crushing mechanism for small solid ghee blocks makes it difficult to melt the ghee evenly and easily causes it to jam the stirring rod, hindering rapid and uniform liquefaction and resulting in poor liquefaction uniformity and efficiency; 2. The internal encapsulation of structures such as the stirring rod within the stirring device makes it difficult to remove them quickly and easily for deep cleaning and maintenance, resulting in poor subsequent maintenance convenience; In view of this, this application proposes a rapid and uniform ghee liquefaction device to solve the above-mentioned problems. Utility Model Content
[0005] The purpose of this invention is to provide a device for rapidly spreading ghee liquefaction, in order to solve the problems mentioned in the background art.
[0006] To achieve the above objectives, this utility model provides the following technical solution: a ghee liquefaction and rapid spreading device, comprising:
[0007] An annular box body with an opening on its inner side and a heat-conducting sleeve fixedly connected thereto; the annular box body is filled with heat-conducting oil.
[0008] The U-shaped bracket is fixedly connected to the outside of the annular box.
[0009] Two sets of electric heaters are fixedly installed on both sides of the bottom of the annular box, with the heating end of the electric heaters extending into the annular box. The two electric heaters are used to heat the heat transfer oil, which in turn heats the heat transfer jacket.
[0010] The material collection and feeding assembly is connected and fixed to the bottom of the heat-conducting sleeve;
[0011] The shield seals the active contact at the top of the heat-conducting jacket. Its top is set as a circular tube structure, and its left top is connected to and fixed with an inclined L-shaped feed pipe.
[0012] A circular support is connected to the top of the inner side of the shield, and a rectangular perforation is opened on its front side;
[0013] A dual-stage crushing and mixing assembly is rotatably mounted on the bottom of a circular support, and a drive motor with its protruding end connected to the dual-stage crushing and mixing assembly is fixedly installed on the top of the circular support.
[0014] The lifting vertical guide drive support assembly is fixedly connected to the outside of the annular box and the outside of the shield. An L-shaped feed pipe allows personnel to add small pieces of solid ghee into the shield. The dual-stage crushing and mixing assembly crushes the added solid ghee in two stages when the drive motor starts, and also mixes the crushed ghee. A heat-conducting sleeve heats and melts the crushed ghee when heated. The combined action of mixing and melting achieves uniform and rapid liquefaction of the ghee. The lifting vertical guide drive support assembly drives the shield to move up and down. The upward movement of the shield allows the dual-stage crushing and mixing assembly to move upwards via a circular support. A material collection and discharge assembly allows personnel to discharge the liquefied ghee.
[0015] Preferably, the circular support is welded to the top of the inner side of the shield.
[0016] Preferably, the circular support is detachably connected to the top of the inner side of the shield.
[0017] Preferably, the outer side of the circular support is in movable contact with the top of the inner side of the shield. Threaded grooves are provided on the bottom right side, bottom front side, and bottom rear side of the circular support. A knob-type bolt is threaded into the threaded groove. Threaded holes are provided on the top right side, top front side, and top rear side of the shield. The threaded holes are threadedly connected to the corresponding knob-type bolts.
[0018] Preferably, the material collection and feeding assembly includes a feeding hood and a feeding valve. The feeding hood is welded and fixed to the bottom of the heat-conducting sleeve, and the inner side of the feeding hood is set with a conical structure. The feeding valve is connected and fixed to the bottom of the feeding hood.
[0019] Preferably, the dual-stage crushing and stirring assembly includes a rotating shaft, two sets of crushing blades, and multiple stirring rods. The rotating shaft is rotatably embedded in the bottom of a circular support, and the top of the rotating shaft extends into a rectangular through hole and is fixedly connected to the protruding end of the drive motor by a coupling. Both sets of crushing blades are fixedly connected to the outside of the rotating shaft. The two sets of crushing blades are located on the lower part of the inner side of the shield and the inner side of the circular tubular structure, respectively. Multiple stirring rods are fixedly connected to the bottom of the outer side of the rotating shaft and located inside the heat-conducting sleeve. Each set of crushing blades consists of eight blades, which are fixedly connected to the outside of the rotating shaft in two rows, with the four crushing blades in each row arranged in a ring at equal intervals.
[0020] Preferably, the lifting vertical guide drive support assembly includes two connecting seats, a multi-stage electric telescopic rod, two rectangular tubes, and two rectangular guide rods. The adjacent sides of the two connecting seats are fixedly connected to both sides of the shield, the two rectangular tubes are welded and fixed to both sides of the annular box, the two rectangular guide rods are slidably sleeved in the corresponding rectangular tubes, and the top ends of the two rectangular guide rods are fixedly connected to the bottom of the corresponding connecting seats. The multi-stage electric telescopic rod is fixedly installed on the top left side of the annular box, and the extended end of the multi-stage electric telescopic rod is fixedly connected to the bottom of the connecting seat on the left side.
[0021] Preferably, a liquid filling pipe is fixedly connected to the top right side of the annular box, and an external thread is provided on the top of the outer side of the liquid filling pipe and an internal threaded pipe cap is screwed on. A pressure relief and venting hole is provided on the front side of the liquid filling pipe.
[0022] Compared with the prior art, the beneficial effects of this utility model are:
[0023] 1. By combining the annular box, electric heater, heat transfer oil, heat transfer sleeve, shield, material collection and feeding assembly, dual-stage crushing and stirring assembly and round support, the small pieces of solid ghee added can be pre-crushed in a dual-stage process before heating and stirring. By crushing and then heating and stirring, the phenomenon of ghee clumping that is difficult to melt evenly or jams the stirring rod is avoided. This achieves the effect of uniform and rapid liquefaction of ghee, making the liquefaction work stable and efficient, with the advantages of rapid liquefaction and even spreading, improving the uniformity and efficiency of liquefaction.
[0024] 2. With the cooperation of the set shield and the lifting vertical guide drive support component, the dual-stage crushing and mixing component can be easily and quickly driven to move upward and unseal the heat conduction sleeve, which facilitates the subsequent deep cleaning and maintenance of the dual-stage crushing and mixing component and the heat conduction sleeve, and improves the convenience of subsequent cleaning and maintenance.
[0025] 3. By using a combination of threaded grooves, threaded holes, and knob-type bolts, the circular support can be disassembled and locked, which facilitates the removal of the two-stage crushing and mixing assembly from the shield, thereby further facilitating subsequent deep cleaning and maintenance by personnel and improving the flexibility of use.
[0026] This invention features a series of structures that facilitate the pre-processing of small, solid ghee pieces into a two-stage crushing stage before heating and stirring. By crushing before heating and stirring, the ghee clumps are prevented from causing uneven melting or jamming of the stirring rod, thus achieving uniform and rapid liquefaction of the ghee. This improves liquefaction uniformity and efficiency. Furthermore, it allows for convenient and quick movement of the two-stage crushing and stirring components upwards and unsealing of the heat-conducting sleeve, facilitating subsequent deep cleaning and maintenance of the internal structure and improving the ease of cleaning and maintenance. Attached Figure Description
[0027] Figure 1 This is a schematic diagram of the structure of a ghee liquefaction and rapid spreading device according to Embodiment 1 of this utility model;
[0028] Figure 2 This is a front cross-sectional view of a ghee liquefaction and rapid spreading device according to Embodiment 1 of this utility model.
[0029] Figure 3 This is a schematic diagram of the structure of a ghee liquefaction and rapid spreading device according to Embodiment 2 of this utility model;
[0030] Figure 4 This is a front cross-sectional view of a ghee liquefaction and rapid spreading device according to Embodiment 2 of this utility model.
[0031] In the diagram: 1. Annular box; 101. Heat-conducting sleeve; 102. Electric heater; 103. Discharge hood; 104. Discharge valve; 2. U-shaped bracket; 3. Shielding cover; 301. L-shaped feed pipe; 302. Knob bolt; 4. Connecting seat; 401. Rectangular tube; 402. Rectangular guide rod; 403. Multi-stage electric telescopic rod; 5. Circular support; 501. Rotating shaft; 502. Crushing blade; 503. Agitating rod; 504. Drive motor. Detailed Implementation
[0032] 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.
[0033] Example 1
[0034] like Figures 1 to 2 As shown, the ghee liquefaction and rapid spreading device proposed in this embodiment includes:
[0035] An annular box 1 has an opening on its inner side and a heat-conducting sleeve 101 is fixedly connected to it. The annular box 1 is filled with heat-conducting oil. A liquid filling pipe is fixedly connected to the top right side of the annular box 1. An external thread is opened on the top of the outer side of the liquid filling pipe and an internal threaded pipe cap is screwed on. A pressure relief and exhaust hole is opened on the front side of the liquid filling pipe.
[0036] U-shaped bracket 2 is fixedly connected to the outside of the annular box 1;
[0037] Two sets of electric heaters 102 are fixedly installed on both sides of the bottom of the annular housing 1, and the heating ends of the electric heaters 102 extend into the annular housing 1. The two electric heaters 102 are used to heat the heat transfer oil, and the heat transfer oil is used to heat the heat transfer sleeve 101.
[0038] The material collection and feeding assembly is connected and fixed to the bottom of the heat-conducting sleeve 101;
[0039] The shield 3 is in sealing contact with the top of the heat-conducting sleeve 101. The top of the shield 3 is a cylindrical structure, and the left side of the top is connected to and fixed with an inclined L-shaped feed pipe 301. The bottom of the shield 3 is bonded and fixed with a sealing ring. The bottom of the sealing ring is pressed tightly against the top of the heat-conducting sleeve 101, which achieves the effect of movable sealing between the shield 3 and the heat-conducting sleeve 101.
[0040] A circular support 5 is connected to the top of the inner side of the shield 3, and a rectangular perforation is provided on its front side.
[0041] A dual-stage crushing and mixing component is rotatably embedded in the bottom of a circular support 5, and a drive motor 504 with its protruding end connected to the dual-stage crushing and mixing component is fixedly installed on the top of the circular support 5.
[0042] The lifting vertical guide drive support assembly is fixedly connected to the outside of the annular box 1 and the outside of the shield 3; the L-shaped feed pipe 301 is provided for personnel to add small pieces of solid ghee into the shield 3; the dual-stage crushing and stirring assembly is used to crush the added small pieces of solid ghee in two stages when the drive motor 504 is started, and to stir the crushed ghee; the heat-conducting sleeve 101 is provided to heat and melt the crushed ghee when heated, and the synergistic effect of stirring and heating and melting is used to achieve the effect of uniform and rapid liquefaction of ghee; the lifting vertical guide drive support assembly is used to drive the shield 3 to move up and down, and the upward movement of the shield 3 enables the dual-stage crushing and stirring assembly to move upward through the circular support 5; the material collection and discharge assembly is used for personnel to discharge the liquefied ghee.
[0043] It should be noted that the electric heater 102 uses its heating end to heat the heat transfer oil, which is a very common application in heating applications.
[0044] Furthermore, the circular support 5 is welded to the top of the inner side of the shield 3.
[0045] Furthermore, such as Figure 2 As shown, the material collection and feeding assembly includes a feeding cover 103 and a feeding valve 104. The feeding cover 103 is welded and fixed to the bottom of the heat-conducting sleeve 101. The inner side of the feeding cover 103 is set as a conical structure. The feeding valve 104 is connected and fixed to the bottom of the feeding cover 103.
[0046] In this embodiment, by cooperating with the discharge hood 103 and the discharge valve 104, the personnel open the discharge valve 104, and the liquefied ghee in the heat-conducting jacket 101 enters the discharge hood 103 and is then discharged downward through the discharge valve 104. A collection box for receiving liquid is placed below the discharge valve 104 to facilitate the discharge of the liquefied ghee by the personnel.
[0047] Furthermore, such as Figure 2 As shown, the dual-stage crushing and mixing assembly includes a rotating shaft 501, two sets of crushing blades 502, and multiple stirring rods 503. The rotating shaft 501 is rotatably embedded in the bottom of the circular support 5. The top of the rotating shaft 501 extends into the rectangular through hole and is fixedly connected to the protruding end of the drive motor 504 by a coupling. The two sets of crushing blades 502 are fixedly connected to the outside of the rotating shaft 501. The two sets of crushing blades 502 are located in the lower part of the inner side of the shield 3 and the inner side of the circular tube structure, respectively. The multiple stirring rods 503 are fixedly connected to the bottom of the outer side of the rotating shaft 501 and are located in the heat-conducting sleeve 101. Each set of crushing blades 502 consists of eight blades, which are fixedly connected to the outside of the rotating shaft 501 in two rows. The four crushing blades 502 in each row are arranged in a ring with equal spacing.
[0048] In this embodiment, the bottom of the circular support 5 is provided with a circular through hole, and two bearings are fixedly sleeved in the circular through hole. The inner ring of the bearing is fixedly sleeved with the outer side of the rotating shaft 501, so as to achieve the effect of rotating the rotating shaft 501.
[0049] In this embodiment, a rotating shaft 501, two sets of crushing blades 502, and multiple stirring rods 503 work together. A drive motor 504 drives the rotating shaft 501 to rotate via a coupling. The rotating shaft 501 drives the multiple crushing blades 502 and multiple stirring rods 503 to rotate. The small pieces of solid ghee added are crushed in two stages by the rotation of the multiple crushing blades 502 in the upper and lower sets. The crushed ghee falls into the heat-conducting sleeve 101. The heat-conducting sleeve 101 heats and melts the crushed ghee. The rotating stirring rods 503 stir the crushed ghee. The stirring and heating melting work together to achieve the effect of uniform and rapid liquefaction of ghee. By crushing and then heating and stirring, the phenomenon of lumpy ghee that is difficult to melt evenly or jams the stirring rods 503 is avoided. This makes the liquefaction work stable and efficient, with the advantages of rapid and even liquefaction.
[0050] Furthermore, such as Figure 1 and 2As shown, the lifting vertical guide drive support assembly includes two connecting seats 4, a multi-stage electric telescopic rod 403, two rectangular tubes 401, and two rectangular guide rods 402. The two connecting seats 4 are fixedly connected to the two sides of the shield 3 respectively. The two rectangular tubes 401 are welded and fixed to the two sides of the annular box 1 respectively. The two rectangular guide rods 402 are slidably sleeved in the corresponding rectangular tubes 401 respectively. The top ends of the two rectangular guide rods 402 are fixedly connected to the bottom of the corresponding connecting seats 4 respectively. The multi-stage electric telescopic rod 403 is fixedly installed on the top left side of the annular box 1. The extended end of the multi-stage electric telescopic rod 403 is fixedly connected to the bottom of the connecting seat 4 on the left side.
[0051] In this implementation scheme, two connecting seats 4, a multi-stage electric telescopic rod 403, two rectangular tubes 401, and two rectangular guide rods 402 work together. The multi-stage electric telescopic rod 403 drives the left connecting seat 4 to move up and down. The connecting seat 4 drives the shield 3 to move up and down. The shield 3 drives the right connecting seat 4 to move up and down. The connecting seat 4 drives the corresponding rectangular guide rod 402 to slide vertically inside the rectangular tube 401 to perform vertical guiding work. When the shield 3 moves upward, it drives the circular support 5 to move upward, thereby driving the double-stage crushing and mixing component to move upward. This achieves the effect of conveniently and quickly driving the double-stage crushing and mixing component to move upward, which facilitates the subsequent deep cleaning and maintenance of the component and the heat-conducting sleeve 101, and improves the convenience of subsequent cleaning.
[0052] It should be noted that switches are fixedly mounted on the rear side of both the multi-stage electric telescopic pole 403 and the drive motor 504, and each switch is electrically connected to its corresponding component via wires. Regarding power supply, given that the ghee liquefaction processing site is a ghee production and processing site with sufficient power supply measures and conditions, all electrical components of this device are connected to the on-site mains power and connected to the power input interface of each device through conventional power distribution devices such as circuit breakers, contactors, and power modules (not marked in the figure), forming a complete power supply circuit. This power supply scheme is a conventional power distribution method for industrial equipment and is a mature and well-known technical means, which will not be elaborated here.
[0053] It should be further noted that the heat-conducting sleeve 101 is preferably made of copper, while the feeding cover 103, rotating shaft 501, crushing blade 502, stirring rod 503, connecting seat 4, rectangular tube 401 and rectangular guide rod 402 are preferably made of stainless steel. The advantages of stainless steel, such as high hardness, high wear resistance and good corrosion resistance, are utilized to ensure long-term application and support stability.
[0054] This embodiment facilitates the pre-treatment of small, solid ghee pieces into a single, two-stage process before heating and stirring. By crushing the ghee before heating and stirring, the phenomenon of ghee clumping, which makes it difficult to melt evenly or jams the stirring rod 503, is avoided. This achieves a uniform and rapid liquefaction of the ghee, improving liquefaction uniformity and efficiency. It also allows for convenient and quick movement of the two-stage crushing and stirring assembly upwards and unsealing of the heat-conducting sleeve 101, facilitating subsequent deep cleaning and maintenance of the internal structure and improving the convenience of subsequent cleaning and maintenance.
[0055] The usage method of this embodiment is as follows: When using the ghee liquefaction and rapid spreading device, two electric heaters 102 are started to heat the heat transfer oil, which in turn heats the heat transfer sleeve 101. The drive motor 504 is started to drive the rotating shaft 501 to rotate via the coupling. The rotating shaft 501 drives multiple crushing blades 502 and multiple stirring rods 503 to rotate. Small pieces of solid ghee are added through the L-shaped feed pipe 301. The added small pieces of solid ghee are crushed in two stages by the rotation of the multiple crushing blades 502 in the upper and lower sets. The crushed ghee falls into the heat transfer sleeve 101 and is then spread out. The heat-conducting sleeve 101 heats and melts the crushed ghee when it is heated, and multiple rotating stirring rods 503 stir the crushed ghee. By combining stirring and heating and melting, the ghee is liquefied evenly and quickly. By crushing and then heating and stirring, the phenomenon of lumpy ghee that is difficult to melt evenly or jams the stirring rods 503 is avoided, making the liquefaction work stable and efficient. When applying the liquefaction method, the liquid can be spread evenly based on the principle of self-leveling, which has the advantages of rapid liquefaction and spreading, improving the uniformity and efficiency of liquefaction.
[0056] Afterwards, the personnel open the discharge valve 104, and the liquefied ghee in the heat-conducting sleeve 101 enters the discharge hood 103, and then discharges downward through the discharge valve 104. A collection box for receiving liquid can be placed below the discharge valve 104 to facilitate the discharge of the liquefied ghee.
[0057] When it is necessary to unseal the top of the heat-conducting sleeve 101 and remove it from its internal structure, the multi-stage electric telescopic rod 403 is activated in the forward direction to drive the connecting seat 4 on the left to move upward. The connecting seat 4 drives the shield 3 to move upward, and the shield 3 drives the connecting seat 4 on the right to move upward. The connecting seat 4 drives the corresponding rectangular guide rod 402 to slide vertically inside the rectangular tube 401 to perform vertical guiding work. When the shield 3 moves upward, it drives the circular support 5 to move upward, thereby driving the internal double-stage crushing and stirring component to move upward. This achieves the effect of conveniently and quickly driving the double-stage crushing and stirring component to move upward and unseal the heat-conducting sleeve 101, which facilitates the subsequent deep cleaning and maintenance of the double-stage crushing and stirring component and the interior of the heat-conducting sleeve 101, and improves the convenience of subsequent cleaning and maintenance.
[0058] Example 2
[0059] like Figures 3 to 4 As shown, this embodiment differs from Embodiment 1 in that: the circular support 5 is detachably connected to the top of the inner side of the shield 3, the outer side of the circular support 5 is in movable contact with the top of the inner side of the shield 3, the bottom right side, the bottom front side, and the bottom rear side of the circular support 5 are all provided with threaded grooves, and a knob bolt 302 is threadedly screwed into the threaded grooves. The top right side, the top front side, and the top rear side of the shield 3 are all provided with threaded holes, and the threaded holes are threadedly connected to the corresponding knob bolt 302.
[0060] This embodiment allows for the disassembly and locking of the circular support 5, thereby facilitating the removal of the dual-stage crushing and mixing assembly from the shield 3. This further facilitates subsequent deep cleaning and maintenance by personnel, improving the flexibility of use.
[0061] The usage method of this embodiment is as follows: Unlike Embodiment 1, it also has the following functions: Utilizing the provided threaded groove, threaded hole, and knob bolt 302, the knob bolt 302 is screwed into the threaded groove to fix and support the circular support 5. Reversing the knob bolt 302 separates it from the corresponding threaded groove, thus releasing the fixation of the circular support 5. Subsequently, after the shield 3 rises and moves the circular support 5 and rotating shaft 501 out, unlocking the circular support 5 allows it to be moved downwards from inside the shield 3. This enables the removal of the rotating shaft 501, crushing blade 502, and stirring rod 503, facilitating the removal of the dual-stage crushing and stirring assembly from inside the shield 3. This further facilitates subsequent deep cleaning and maintenance, improving the flexibility of use.
[0062] Finally, it should be noted that the above description is merely a preferred embodiment of this utility model and is not intended to limit the utility model. Although the utility model has been described in detail with reference to the foregoing embodiments, those skilled in the art can still modify the technical solutions described in the foregoing embodiments or make equivalent substitutions for some of the technical features. Any modifications, equivalent substitutions, improvements, etc., made within the spirit and principles of this utility model should be included within the protection scope of this utility model.
Claims
1. A device for rapidly spreading ghee liquefaction, comprising an annular housing (1), characterized in that: include: An annular box (1) with an opening on its inner side and a heat-conducting sleeve (101) fixedly connected thereto, the annular box (1) being filled with heat-conducting oil; U-shaped bracket (2) is fixedly connected to the outside of the annular box (1); Two sets of electric heaters (102) are fixedly installed on both sides of the bottom of the annular box (1), with the heating end of the electric heater (102) extending into the annular box (1). The material collection and feeding assembly is connected and fixed to the bottom of the heat-conducting sleeve (101); The shield (3) seals the active contact at the top of the heat-conducting sleeve (101), and its top is set as a round tube structure. The left top is connected to an inclined L-shaped feed pipe (301). A circular support (5) is connected to the top of the inner side of the shield (3), and a rectangular perforation is provided on its front side; The dual-stage crushing and mixing assembly is rotatably embedded in the bottom of the circular support (5), and the top of the circular support (5) is fixedly equipped with a drive motor (504) whose protruding end is connected to the dual-stage crushing and mixing assembly; The lifting vertical guide drive support assembly is fixedly connected to the outside of the annular box (1) and the outside of the shield (3).
2. The ghee liquefaction and rapid spreading device according to claim 1, characterized in that: The circular support (5) is welded to the top of the inner side of the shield (3).
3. The ghee liquefaction and rapid spreading device according to claim 1, characterized in that: The circular support (5) is detachably connected to the top of the inner side of the shield (3).
4. The ghee liquefaction and rapid spreading device according to claim 1, characterized in that: The outer side of the circular support (5) is in contact with the top of the inner side of the shield (3). The bottom right side, the bottom front side and the bottom rear side of the circular support (5) are all provided with threaded grooves. A knob bolt (302) is threaded into the threaded groove. The top right side, the top front side and the top rear side of the shield (3) are all provided with threaded holes. The threaded holes are threadedly connected to the corresponding knob bolt (302).
5. The ghee liquefaction and rapid spreading device according to claim 1, characterized in that: The material collection and feeding assembly includes a feeding cover (103) and a feeding valve (104). The feeding cover (103) is welded and fixed to the bottom of the heat-conducting sleeve (101). The inner side of the feeding cover (103) is set as a conical structure. The feeding valve (104) is connected and fixed to the bottom of the feeding cover (103).
6. The ghee liquefaction and rapid spreading device according to claim 1, characterized in that: The dual-stage crushing and stirring assembly includes a rotating shaft (501), two sets of crushing blades (502), and multiple stirring rods (503). The rotating shaft (501) is rotatably embedded in the bottom of the circular support (5). The top of the rotating shaft (501) extends into the rectangular through hole and is fixedly connected to the protruding end of the drive motor (504) by a coupling. The two sets of crushing blades (502) are fixedly connected to the outside of the rotating shaft (501). The two sets of crushing blades (502) are located in the lower part of the inner side of the shield (3) and the inner side of the circular tube structure, respectively. The multiple stirring rods (503) are fixedly connected to the bottom of the outside of the rotating shaft (501) and located in the heat-conducting sleeve (101). Each set of crushing blades (502) consists of eight blades, which are fixedly connected to the outside of the rotating shaft (501) in two rows. The four crushing blades (502) in each row are arranged in a ring with equal spacing.
7. The ghee liquefaction and rapid spreading device according to claim 1, characterized in that: The lifting vertical guide drive support assembly includes two connecting seats (4), a multi-stage electric telescopic rod (403), two rectangular tubes (401) and two rectangular guide rods (402). The two connecting seats (4) are fixedly connected to the two sides of the shield (3) respectively. The two rectangular tubes (401) are welded and fixed to the two sides of the annular box (1) respectively. The two rectangular guide rods (402) are slidably sleeved in the corresponding rectangular tubes (401) respectively. The top of the two rectangular guide rods (402) is fixedly connected to the bottom of the corresponding connecting seat (4) respectively. The multi-stage electric telescopic rod (403) is fixedly installed on the top left side of the annular box (1). The extended end of the multi-stage electric telescopic rod (403) is fixedly connected to the bottom of the connecting seat (4) on the left side.
8. The ghee liquefaction and rapid spreading device according to claim 1, characterized in that: The top right side of the annular box (1) is connected to a liquid filling pipe. The top of the outer side of the liquid filling pipe is threaded with an external thread and threaded with an internal thread pipe cap. The front side of the liquid filling pipe is provided with a pressure relief and exhaust hole.