CN116268478A

CN116268478A - Hibiscus protein stir-frying device

Info

Publication number: CN116268478A
Application number: CN202310302238.9A
Authority: CN
Inventors: 田文硕; 康恩伟; 吴强
Original assignee: Houde Food Co Ltd
Current assignee: Houde Food Co Ltd
Priority date: 2023-03-27
Filing date: 2023-03-27
Publication date: 2023-06-23

Abstract

The invention discloses a cottonrose hibiscus protein stir-frying device which comprises a frame, wherein a raw material conveying mechanism, a spiral oil groove, a first rotary power source, an oil collecting groove and a water groove are sequentially arranged on the frame from top to bottom, a first rotating shaft is rotatably arranged on the oil collecting groove, a collecting cylinder is arranged on the first rotating shaft, a plurality of collecting cavities are arranged in the collecting cylinder, the upper end and the lower end of each collecting cavity are in an open structure, and a filter screen for opening and closing the bottom of each collecting cavity is hinged to the bottom of each collecting cavity; the spiral oil groove is provided with a channel which is in a spiral structure, an oil conveying pipe is arranged at the input end of the channel, a discharging pipe is connected at the output end of the channel, and the discharging pipe is positioned above the collecting cylinder and the oil collecting groove. According to the invention, the oil is circularly conveyed into the channel through the oil conveying pipe, and then the raw materials are conveyed into the channel, so that the raw materials are immersed into the oil and shaped along with the flowing of the oil, the mass and automatic preparation of the hibiscus protein is realized, the manual stir-frying is not needed, the unification of the taste and quality of the hibiscus protein product can be realized, and the market demand is met.

Description

Hibiscus protein stir-frying device

Technical Field

The invention relates to the technical field of food processing equipment, in particular to a cottonrose hibiscus protein stir-frying device.

Background

The hibiscus protein is a food prepared by stir-frying egg white as a main raw material, and is prepared by adding the raw material into low-temperature oil liquid for heating and shaping, and is fresh, tender and smooth, and is popular with consumers.

At present, the cottonrose hibiscus protein is fried in a restaurant on site, has strict requirements on raw material treatment, needs to master the heating time of oil temperature and the mode of mastering a manipulation, has higher requirements on chefs, is easy to cause accidents of poor quality of cottonrose hibiscus protein finished products, cannot realize automatic batch production with the same specification, and cannot meet market demands.

Disclosure of Invention

The invention aims to solve the problems and designs a cottonrose hibiscus protein stir-frying device.

The technical scheme includes that the cottonrose hibiscus protein stir-frying device comprises a frame, wherein a raw material conveying mechanism, a spiral oil groove, a first rotary power source, an oil collecting groove and a water groove are sequentially arranged on the frame from top to bottom, the water groove is arranged adjacent to the oil collecting groove, a first rotating shaft is rotatably arranged on the oil collecting groove, a collecting barrel is arranged on the first rotating shaft, an inner cavity of the collecting barrel is divided into a plurality of circumferentially distributed collecting cavities through a partition plate, the upper end and the lower end of the collecting cavity are in an open structure, a filter screen for opening and closing the bottom of the collecting cavity is hinged to the bottom of the collecting cavity, the first rotary power source is rotatably connected with the first rotating shaft so as to drive each collecting cavity to pass through the oil collecting groove and the upper part of the water groove, when the collecting cavity is positioned right above the oil collecting groove, the corresponding filter screen seals the bottom of the collecting cavity so as to drain oil to the oil groove, and when the collecting cavity is positioned right above the water groove, the corresponding filter screen opens the bottom of the collecting cavity so as to convey cottonrose hibiscus protein to the water groove; the spiral oil groove is provided with a channel with a spiral structure, the input end of the channel is provided with an oil delivery pipe, the output end of the channel is connected with a discharge pipe, and the discharge pipe is positioned above the collecting cylinder and the oil collecting groove; the output end of the raw material conveying mechanism is positioned above the input end of the channel, and the raw material conveying mechanism inputs raw materials to the channel.

Preferably, the oil collecting groove is fixedly provided with an annular track, and the bottom of the filter screen is fixedly provided with a universal ball which is in rolling connection with the annular track.

Preferably, the annular track comprises a horizontal section, an inclined downward section and an inclined upward section, and when the universal ball moves on the horizontal section, the filter screen seals the bottom of the collecting cavity; when the universal ball moves on the inclined downward section, the filter screen gradually opens the bottom of the collecting cavity; when the universal ball moves on the inclined upper section, the filter screen gradually seals the bottom of the collecting cavity; vibration patterns are arranged on the inclined downward section.

Preferably, the raw material conveying mechanism comprises a raw material storage tank, a raw material conveying pipe and a first electromagnetic valve, wherein the raw material storage tank is fixedly arranged at the top of the frame, the bottom of the raw material storage tank is connected with the raw material conveying pipe, the lower end of the raw material conveying pipe extends to the feeding end of the channel, and the first electromagnetic valve is arranged on the raw material conveying pipe.

Preferably, a baffle is fixed in the storage cavity, the bottom of the baffle is flush with the bottom of the collecting cylinder, and the baffle is positioned on one side, away from the first rotating shaft, of the universal ball.

Preferably, the frame is also provided with an oil filtering device and a power pump, the oil filtering device is positioned below the oil collecting tank, the oil filtering device is communicated with the oil collecting tank through an oil filtering pipe, the oil filtering pipe is provided with a second electromagnetic valve, the output end of the oil filtering device is connected with the input end of the power pump, and the output end of the power pump is connected with the oil conveying pipe.

Preferably, a first heating device is arranged in the oil collecting groove, a second heating device is arranged on the oil conveying pipe, and an oil temperature sensor is arranged at the output end of the channel.

Preferably, the water tank is internally provided with a mesh belt conveyor which is obliquely arranged, the feeding end of the mesh belt conveyor is positioned in the water tank, and the discharging end of the mesh belt conveyor is obliquely upwards and extends out of the water tank.

Preferably, the protein cutting mechanism further comprises a protein cutting mechanism, the protein cutting mechanism comprises a second rotary power source, a fixed seat, a second rotating shaft, a mounting seat and a cutting needle, the second rotary power source is fixedly arranged on the frame, the fixed seat is fixed at a position, close to the output end, of the spiral oil groove, the second rotating shaft is rotatably arranged on the fixed seat, a plurality of mounting seats are fixed on the second rotating shaft, the cutting needle is arranged on the mounting seat, and the second rotary power source drives the second rotating shaft to swing in a reciprocating manner so that the cutting needle cuts shaped protein in a channel.

Preferably, the protein cutting mechanism further comprises a crank, a connecting rod and a rocker, wherein the crank is arranged at the output end of the second rotary power source, the connecting rod is hinged to the other end of the crank, the rocker is hinged to the other end of the connecting rod, and the other end of the rocker is hinged to the second rotating shaft.

The invention has the beneficial effects that:

the method can realize the large-batch and automatic preparation of the hibiscus protein, does not need manual stir-frying, can realize the unification of the taste of the hibiscus protein product, ensures the unification of the quality of the product, and meets the market demand;

2. the oil is circularly conveyed into the channel through the oil conveying pipe, then the raw materials are conveyed into the channel, the raw materials are immersed in the oil and move along with the flow of the oil, move towards the discharging end of the channel with the spiral structure, the raw materials are heated by the oil to realize shaping in the process of flowing in the channel with the spiral structure, the moving time of the raw materials in the channel is uniform, the raw materials cannot adhere to the inner wall of the spiral oil groove due to the flowing scouring property of the oil, the uniformity of the heating time of the raw materials is ensured, the hibiscus proteins with the same taste quality can be rapidly obtained, and the product quality is ensured;

3. the protein cutting mechanism swings back and forth in the channel through the cutting needle, and cuts the passed protein into pieces, so that the protein is prevented from agglomerating, and the beauty of the hibiscus protein is ensured;

4. the protein that gets into the collection chamber is collected through the filter screen to drip oil to the oil collecting groove, thereby can automatic down revolve when the filter screen removes to the basin and open collection chamber bottom, export protein to the basin in, the protein contacts with water in the basin, the fluid diffusion on protein surface is in water, further reduces the fluid on the protein, avoids the cottonrose hibiscus protein too greasy, and the guipure conveyer exports cottonrose hibiscus protein basin, can be convenient for collect cottonrose hibiscus protein finished product.

Drawings

FIG. 1 is a schematic diagram of the structure of the present invention;

FIG. 2 is a top view of the spiral oil sump;

FIG. 3 is a partial cross-sectional view of the spiral oil sump of FIG. 1;

FIG. 4 is a partial top view of the present invention;

FIG. 5 is a schematic illustration of FIG. 4 with the collection canister omitted;

FIG. 6 is a schematic view of the structure of the trough and the belt conveyor;

FIG. 7 is a top view of the endless track;

in the figure, 1, a rack; 2. a spiral oil groove; 3. a first rotary power source; 4. an oil sump; 5. a water tank; 6. a first rotating shaft; 7. a collection cylinder; 8. a partition plate; 9. a collection chamber; 10. a filter screen; 11. a channel; 12. an oil delivery pipe; 13. a discharge pipe; 14. an endless track; 15. a universal ball; 16. a horizontal section; 17. a sloping downward section; 18. tilting the upper section; 19. vibration patterns; 20. a raw material storage tank; 21. a raw material conveying pipe; 22. a first electromagnetic valve; 23. a baffle; 24. an oil filtering device; 25. a power pump; 26. an oil filtering pipe; 27. a second electromagnetic valve; 28. a first heating device; 29. a second heating device; 30. an oil temperature sensor; 31. a mesh belt conveyor; 32. a second rotary power source; 33. a fixing seat; 34. a second rotating shaft; 35. a mounting base; 36. a cutting needle; 37. a crank; 38. a connecting rod; 39. and (5) a rocker.

Detailed Description

The present invention will be further described in detail with reference to the drawings and the detailed description, in order to make the objects, technical solutions and advantages of the present invention more apparent. It should be understood that the detailed description and specific examples are intended for purposes of illustration only and are not intended to limit the scope of the invention.

In one embodiment, please refer to fig. 1-7: a stir-frying device of cottonrose hibiscus protein comprises a frame 1, wherein a raw material conveying mechanism, a spiral oil groove 2, a first rotary power source 3, an oil collecting groove 4 and a water groove 5 are sequentially arranged on the frame 1 from top to bottom, the water groove 5 is adjacent to the oil collecting groove 4, a first rotating shaft 6 is rotatably arranged on the oil collecting groove 4 through a bearing, a collecting cylinder 7 is arranged on the first rotating shaft 6, an inner cavity of the collecting cylinder 7 is divided into a plurality of circumferentially distributed collecting cavities 9 through a partition plate 8, the upper end and the lower end of the collecting cavities 9 are in an open structure, a filter screen 10 for opening and closing the bottoms of the collecting cavities 9 is hinged to the bottoms of the collecting cavities 9 through hinges, the first rotary power source 3 is rotatably connected with the first rotating shaft 6 to drive each collecting cavity 9 to pass through the upper part of the oil collecting groove 4 and the water groove 5, a worm gear speed reducing motor is selected for the first rotary power source 3, and other speed reducing motors are convenient for driving the collecting cylinders 7 to rotate slowly; when the collecting cavity 9 is positioned right above the oil collecting groove 4, the corresponding filter screen 10 seals the bottom of the collecting cavity 9 to drain oil to the oil collecting groove 4, and when the collecting cavity 9 is positioned right above the water tank 5, the corresponding filter screen 10 opens the bottom of the collecting cavity 9 to convey hibiscus protein to the water tank 5; the spiral oil groove 2 is provided with a channel 11 with a spiral structure, the spiral structure is specifically an Archimedes spiral structure, an oil delivery pipe 12 is arranged at the input end of the channel 11, the output end of the channel 11 is connected with a discharge pipe 13, and the discharge pipe 13 is positioned above the collecting cylinder 7 and the oil collecting groove 4; the output end of the raw material conveying mechanism is positioned above the input end of the channel 11, and the raw material conveying mechanism inputs raw materials to the channel 11.

Referring to fig. 1 and 7, in order to guide the universal balls 15, so that the filter screen 10 opens and closes the collecting chamber 9 at a corresponding position, an annular track 14 is fixedly installed on the oil collecting tank 4, the universal balls 15 are fixed at the bottom of the filter screen 10, and the universal balls 15 are in rolling connection with the annular track 14. The annular track 14 comprises a horizontal section 16, an inclined downward section 17 and an inclined upward section 18, and when the universal ball 15 moves on the horizontal section 16, the filter screen 10 seals the bottom of the collecting cavity 9; when the universal ball 15 moves on the inclined downward section 17, the filter screen 10 gradually opens the bottom of the collecting cavity 9; when the universal ball 15 moves on the inclined upper section 18, the filter screen 10 gradually seals the bottom of the collecting cavity 9; the vibration patterns 19 are arranged on the inclined downward section 17, the vibration patterns 19 are of a corrugated structure, so that the universal balls 15 can bump and move up and down when moving on the inclined downward section 17, the filter screen 10 can vibrate, and protein blanking is promoted.

Referring to fig. 1 and 3, in order to facilitate the feeding of the raw materials to the feeding end of the channel 11, a raw material feeding mechanism is provided, which comprises a raw material storage tank 20, a raw material conveying pipe 21 and a first electromagnetic valve 22, wherein the raw material storage tank 20 is fixedly installed at the top of the frame 1, the bottom of the raw material storage tank 20 is connected with the raw material conveying pipe 21, the lower end of the raw material conveying pipe 21 extends to the feeding end of the channel 11, and the first electromagnetic valve 22 is installed on the raw material conveying pipe 21.

Referring to fig. 1 and 4, in order to avoid that the oil in the storage cavity moves to above the universal ball 15, so that the universal ball 15 contacts with the oil, a baffle plate 23 is fixed in the storage cavity, the bottom of the baffle plate 23 is level with the bottom of the collecting cylinder 7, and the baffle plate 23 is located at one side of the universal ball 15 away from the first rotating shaft 6. The baffle 23 can block the oil, prevents the oil from moving to the position right above the universal ball 15, thereby ensuring that the oil is collected by the oil collecting groove 4 and cannot be polluted in the oil draining process.

Referring to fig. 1, in order to convey oil to the oil delivery pipe 12, an oil filtering device 24 and a power pump 25 are further installed on the frame 1, the oil filtering device 24 is located below the oil collecting tank 4, the oil filtering device 24 is communicated with the oil collecting tank 4 through an oil filtering pipe 26, a second electromagnetic valve 27 is installed on the oil filtering pipe 26, an output end of the oil filtering device 24 is connected with an input end of the power pump 25, and an output end of the power pump 25 is connected with the oil delivery pipe 12. The oil filtering device 24 can filter the oil output by the oil collecting tank 4 through the filtering component in the oil filtering device, so that the quality of oil circulation is ensured.

Referring to fig. 1, in order to heat the oil and keep the temperature of the oil at about 20 degrees, a first heating device 28 is installed in the oil collecting tank 4, a second heating device 29 is installed on the oil delivery pipe 12, and an oil temperature sensor 30 is installed at the output end of the channel 11. The first heating device 28 and the second heating device 29 are both electric heating devices, the first heating device 28 directly heats the oil collected in the oil collecting tank 4 to ensure the temperature of the oil conveyed to the oil conveying pipe 12 after the oil is recovered, and the second heating device 29 carries out heat exchange through the oil conveying pipe 12 to heat the oil in the oil conveying pipe 12 to ensure the temperature of the oil output by the oil conveying pipe 12 to be about 20 ℃, so that the protein is conveniently heated and shaped; in other embodiments, the heating device can be installed at the bottom of the spiral oil groove 2 to heat the spiral oil groove 2, so that the situation that the temperature of the oil at the conveying end of the channel 11 is too low to heat and fix the protein due to too fast temperature reduction in the oil flowing process is avoided.

Referring to fig. 1, 4 to 6, in order to collect the cottonrose hibiscus protein in the water tank 5, a mesh belt conveyor 31 is installed in the water tank 5, a feeding end of the mesh belt conveyor 31 is located in the water tank 5, and a discharging end of the mesh belt conveyor 31 is inclined upwards and extends out of the water tank 5. The hibiscus protein can be carried on the net belt of the net belt conveyor 31, and is conveyed out of the water tank 5 by the net belt conveyor 31.

Referring to fig. 1 to 3, in order to avoid the aggregation of the protein output by the channel 11, a protein cutting mechanism is further provided, wherein the protein cutting mechanism comprises a second rotary power source 32, a crank 37, a connecting rod 38, a rocker 39, a fixing seat 33, a second rotating shaft 34, a mounting seat 35 and a cutting needle 36, the second rotary power source 32 is fixedly installed on the frame 1, the fixing seat 33 is fixed at a position, close to the output end, of the spiral oil groove 2, on the spiral oil groove 2, the second rotating shaft 34 is rotatably installed on the fixing seat 33, a plurality of mounting seats 35 are fixedly arranged on the second rotating shaft 34, the cutting needle 36 is installed on the mounting seat 35, the output end of the second rotary power source 32 is provided with the crank 37, the other end of the crank 37 is hinged with the connecting rod 38, the other end of the connecting rod 38 is hinged with the rocker 39, the other end of the rocker 39 is hinged with the second rotating shaft 34, the second rotary power source 32 is driven to rotate by the crank 37, and then the rocker 39 is driven to swing by the connecting rod 38, so that the second rotating shaft 34 is driven to swing reciprocally, so that the cutting needle 36 cuts the shaped protein in the channel 11. In this embodiment, the second rotary power source 32 is a motor, which may be a pneumatic motor or a hydraulic motor; the number of the mounting seats 35 is three, and two cutting needles 36 are arranged on each mounting seat 35, so that the protein can be fully cut, and the agglomerated protein can be cut into slices.

The working principle of the embodiment is as follows:

adding the prepared raw materials into a storage tank, adding edible oil into an oil collecting tank 4, starting a first heating device 28, heating the edible oil, starting a second electromagnetic valve 27, a power pump 25 and a second heating device 29, enabling oil in the oil collecting tank 4 to enter an oil filtering device 24 through a filtering oil pipe 26, enabling the power pump 25 to pump the oil filtered by the oil filtering device 24 to a spiral oil groove 2 through an oil conveying pipe 12, enabling the second heating device 29 to heat the oil again, enabling an oil temperature sensor 30 to detect the temperature of the oil output by the oil conveying pipe 12, enabling the first heating device 28 and the second heating device 29 to stop heating or to be adjusted to a low-power mode for heating when the temperature of the oil reaches a preset temperature interval, flexibly adjusting power according to the oil detected by the oil temperature sensor 30, and guaranteeing the temperature of the oil output by the oil conveying pipe 12 to be in the preset temperature interval;

then the first electromagnetic valve 22, the first rotary power source 3 and the second rotary power source 32 are opened, raw materials in the raw material storage tank 20 are conveyed to the feeding end of the channel 11 through the raw material conveying pipe 21, are immersed in oil and move towards the discharging end of the channel 11 along with the flow of the oil, the discharging end of the channel 11 is the center position of the spiral oil groove 2, the raw materials are heated by the oil to realize semi-solidification and shaping in the flowing process of the spiral oil groove 11, and the raw materials cannot adhere to the inner wall of the spiral oil groove 2 due to the flowing scouring property of the oil;

when the protein moves to the protein cutting mechanism, the second rotary power source 32 drives the crank 37 to rotate, the crank 37 drives the rocker 39 to swing through the connecting rod 38, and then drives the second rotating shaft 34 to rotate reciprocally, the second rotating shaft 34 drives the mounting seat 35 and the cutting needle 36 to swing reciprocally in the channel 11, the cutting needle 36 cuts the passing protein into pieces, the protein is prevented from agglomerating, and the cut protein moves to the blanking end of the channel 11 and the discharging pipe 13 along with the oil; the discharging pipe 13 conveys protein and oil downwards into the collecting cavity 9 at the inner side of the collecting cylinder 7, the protein is intercepted by the filter screen 10, and the oil is collected by the oil collecting groove 4 after passing through the filtering holes of the filter screen 10;

the first rotary power source 3 drives the first rotating shaft 6 and the collecting cylinder 7 to rotate, and drives each collecting cavity 9 to turn around along the center of the first rotating shaft 6; in the process that the protein-loaded filter screen 10 moves above the oil collecting groove 4, the universal ball 15 is always in rolling connection with the horizontal section 16, and the horizontal section 16 supports the universal ball 15 and the filter screen 10, so that the filter screen 10 stably seals the collecting cavity 9, the protein is prevented from separating from the collecting cavity 9, and during the period, the filter screen 10 continuously drips out oil liquid, and oil liquid attached to the protein is reduced; when the filter screen 10 is completely moved to the position right above the water tank 5, the universal ball 15 moves to the inclined downward section 17 and moves downward along the track of the inclined downward section 17, the height gradually decreases to drive the filter screen 10 to rotate downwards, proteins carried on the filter screen 10 slide down into the water tank 5 obliquely under the gravity and fall on the mesh belt of the mesh belt conveyor 31, and the universal ball 15 jolts and vibrates when moving on the vibration patterns 19 to promote the protein blanking on the filter screen 10; then the universal ball 15 moves to the inclined upward section 18 and moves upward along the track of the inclined upward section 18, the height gradually rises, and the filter screen 10 is driven to rotate upwards; when the universal ball 15 moves to the horizontal section 16, the filter screen 10 re-seals the collecting cavity 9, then the filter screen 10 rotates to be right above the oil collecting groove 4 and right below the discharging pipe 13 again, and protein collection and oil leaching operations are performed again;

the protein contacts with water in the water tank 5, and the oil on the surface of the protein diffuses in the water, so that the oil on the protein is further reduced, the phenomenon that the hibiscus protein is too greasy is avoided, the hibiscus protein is conveyed to the discharging end of the hibiscus protein by the mesh belt conveyor 31, and the collecting device is arranged at the discharging end of the mesh belt conveyor 31, so that the hibiscus protein can be collected.

The above technical solution only represents the preferred technical solution of the present invention, and some changes that may be made by those skilled in the art to some parts of the technical solution represent the principles of the present invention, and the technical solution falls within the scope of the present invention.

It will be understood that when an element is referred to as being "fixed to" another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present. The terms "vertical," "horizontal," "left," "right," and the like are used herein for illustrative purposes only and are not meant to be the only embodiment.

The terms "first" and "second" in this specification do not denote a particular quantity or order, but rather are used for distinguishing between similar or identical items.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. The terminology used herein in the description of the invention is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention.

Claims

1. The utility model provides a cottonrose hibiscus protein's stir-fry system device, which comprises a frame (1), a serial communication port, install raw materials conveying mechanism from top to bottom on frame (1) in proper order, spiral oil groove (2), first rotary power source (3), oil collecting groove (4), basin (5) and oil collecting groove (4) are adjacent to be set up, install first pivot (6) on oil collecting groove (4), install collecting cylinder (7) on first pivot (6), collecting cylinder (7) inner chamber separates into a plurality of collecting chambers (9) that are circumference distribution through baffle (8), collecting chamber (9) upper and lower both ends are open structure, collecting chamber (9) bottom articulates there is filter screen (10) that are used for opening and close collecting chamber (9) bottom, first rotary power source (3) and first pivot (6) rotate to drive each collecting chamber (9) through oil collecting groove (4) and basin (5) top, when collecting chamber (9) are located oil collecting groove (4) directly over, corresponding filter screen (10) bottom in order to open collecting chamber (9) to drain oil to place on water trough (5) when collecting chamber (9) are located on collecting chamber (5); the spiral oil groove (2) is provided with a channel (11) with a spiral structure, an oil delivery pipe (12) is arranged at the input end of the channel (11), the output end of the channel (11) is connected with a discharge pipe (13), and the discharge pipe (13) is positioned above the collecting cylinder (7) and the oil collecting groove (4); the output end of the raw material conveying mechanism is positioned above the input end of the channel (11), and the raw material conveying mechanism inputs raw materials to the channel (11).

2. The device for stir-frying hibiscus protein according to claim 1, wherein the oil collecting groove (4) is fixedly provided with an annular track (14), the bottom of the filter screen (10) is fixedly provided with a universal ball (15), and the universal ball (15) is in rolling connection with the annular track (14).

3. The device for frying hibiscus protein according to claim 2, wherein the annular track (14) comprises a horizontal section (16), an inclined downward section (17) and an inclined upward section (18), and the filter screen (10) seals the bottom of the collecting cavity (9) when the universal ball (15) moves on the horizontal section (16); when the universal ball (15) moves on the inclined downward section (17), the filter screen (10) gradually opens the bottom of the collecting cavity (9); when the universal ball (15) moves on the inclined upward section (18), the filter screen (10) gradually seals the bottom of the collecting cavity (9); vibration patterns (19) are arranged on the inclined downward section (17).

4. The device for stir-frying hibiscus protein according to claim 1, wherein the raw material conveying mechanism comprises a raw material storage tank (20), a raw material conveying pipe (21) and a first electromagnetic valve (22), the raw material storage tank (20) is fixedly arranged at the top of the frame (1), the raw material conveying pipe (21) is connected to the bottom of the raw material storage tank (20), the lower end of the raw material conveying pipe (21) extends to the feeding end of the channel (11), and the first electromagnetic valve (22) is arranged on the raw material conveying pipe (21).

5. The device for stir-frying the hibiscus protein according to claim 1, wherein a baffle plate (23) is fixed in the storage cavity, the bottom of the baffle plate (23) is flush with the bottom of the collecting cylinder (7), and the baffle plate (23) is positioned on one side of the universal ball (15) far away from the first rotating shaft (6).

6. The device for stir-frying hibiscus protein according to claim 1, wherein the rack (1) is further provided with an oil filtering device (24) and a power pump (25), the oil filtering device (24) is located below the oil collecting tank (4), the oil filtering device (24) is communicated with the oil collecting tank (4) through an oil filtering pipe (26), the oil filtering pipe (26) is provided with a second electromagnetic valve (27), the output end of the oil filtering device (24) is connected with the input end of the power pump (25), and the output end of the power pump (25) is connected with the oil conveying pipe (12).

7. The device for stir-frying the hibiscus protein according to claim 6, wherein a first heating device (28) is arranged in the oil collecting tank (4), a second heating device (29) is arranged on the oil conveying pipe (12), and an oil temperature sensor (30) is arranged at the output end of the channel (11).

8. The device for stir-frying the hibiscus protein according to claim 1, wherein a mesh belt conveyor (31) which is obliquely arranged is arranged in the water tank (5), the feeding end of the mesh belt conveyor (31) is positioned in the water tank (5), and the discharging end of the mesh belt conveyor (31) is obliquely upwards and extends out of the water tank (5).

9. The device for stir-frying hibiscus protein according to any one of claims 1 to 8, further comprising a protein cutting mechanism, wherein the protein cutting mechanism comprises a second rotary power source (32), a fixed seat (33), a second rotating shaft (34), a mounting seat (35) and a cutting needle (36), the second rotary power source (32) is fixedly arranged on the frame (1), the fixed seat (33) is fixed on the spiral oil groove (2) at a position close to the output end of the spiral oil groove, the second rotating shaft (34) is rotatably arranged on the fixed seat (33), a plurality of mounting seats (35) are fixed on the second rotating shaft (34), the cutting needle (36) is arranged on the mounting seat (35), and the second rotating power source (32) drives the second rotating shaft (34) to swing reciprocally so as to cut the shaped protein in the channel (11).

10. The device for stir-frying hibiscus protein according to claim 9, wherein the protein cutting mechanism further comprises a crank (37), a connecting rod (38) and a rocker (39), the crank (37) is arranged at the output end of the second rotary power source (32), the connecting rod (38) is hinged to the other end of the crank (37), the rocker (39) is hinged to the other end of the connecting rod (38), and the other end of the rocker (39) is hinged to the second rotary shaft (34).