CN109874957B - Gap type high-pressure cooking device for seed nut food - Google Patents

Abstract

The invention discloses a gap type high-pressure cooking device for nut foods, which comprises a frame, a rotary power mechanism A, a top cover lifting cylinder, a suspension arm, a rotary power mechanism B, a top cover rotating shaft, a top cover, a cooking pot body and a net material barrel, wherein the rotary power mechanism A is arranged at the top of the frame through a bracket, a driving gear A is arranged on the rotary power mechanism A, and a driven gear A is arranged on the top cover lifting cylinder; the lifting rod top of the top cover lifting cylinder is fixedly provided with a suspension arm, a rotary power mechanism B is arranged on the suspension arm, a driving gear A is arranged on the rotary power mechanism B, a top cover rotating shaft is rotatably arranged on the suspension arm, a driven gear B is arranged at the top end of the top cover rotating shaft, a cooking pot body is cooperatively arranged on the electric heating seat, and a net-shaped material barrel is arranged in the cooking pot body. The invention carries out high-pressure cooking treatment on the nut leisure food, and solves the problems of difficult taste of kernels, difficult shell knocking, high energy consumption, long baking time, low efficiency and the like.

Description

A gap type high-pressure cooking device for seed nut foods

Technical field

The present invention relates to the technical field of seed and nut food processing, and in particular to a gap type high-pressure cooking device for seed and nut food.

Background technique

With the development of social economy and the improvement of people's living standards, the food industry has achieved unprecedented development, and its total production value has exceeded 10 trillion, becoming the largest industry in the national economy. Especially in recent years, people have pursued material and cultural life. Increasingly, the snack food industry is developing more rapidly. Since 2010, it has been developing at an average annual growth rate of more than 10%, and has become a veritable dominant industry and pillar industry in the food industry, especially nuts in snack foods. Roasted seeds and nuts are developing rapidly with an average annual growth rate of 15%. It has become the fastest growing sunrise industry in the traditional food industry. Both its total production volume and processing technology level have developed rapidly. At the same time, various types of roasted nuts have always been loved by the public, and nuts produce various flavors through various processing methods, which can meet the needs of more people. Its annual production scale has exceeded 100 billion. Steaming is a common process in the processing of roasted nuts. However, during the cooking process, the upper or middle parts of the nuts cannot be soaked by water, and may be undercooked or too dry. In short, during the cooking process of nuts, uneven heating and uneven seasoning are prone to occur, making it impossible to guarantee the quality and flavor of nut cooking. And the biggest technical problems that have always plagued watermelon seeds and other seed nuts are the difficulty in shelling, difficulty in flavoring, and low intelligence. Most of the existing technologies only stick to simple baking and frying, with extremely low levels of intelligence and mechanization. It is impossible to fundamentally solve technical problems such as watermelon seeds that open when they are knocked open and flavor stability. Therefore, how to achieve green, intelligent, mechanized and standardized technological improvements in aspects such as shelling, flavor control and quality stability is a major technical issue currently facing the industry.

Seed nuts are generally cooked in a cooking pot. Traditional cooking pots can be used for cooking, steaming, boiling and other processes of food. The material of the cooking pot is usually iron, but it can also be made of aluminum, stainless steel and alloy materials. Its main components For the pot body and pot bottom. In the processing of nut foods, there is usually a cooking process; for example, in the processing of melon seeds, the soaked melon seeds are put into the material liquid for cooking. An ordinary food cooking pot is used, and the cooking method of one pot and one basket is low in efficiency and labor intensive. It is strong and a lot of heat is lost from the periphery of the pot, which not only wastes heat energy but also pollutes the environment, so the boiler needs to be improved.

Existing seed and nut cooking equipment cannot realize large-scale production in the production workshop. The degree of automation is not high and the labor intensity of workers is high. Moreover, the seed nuts produced by traditional cooking equipment are difficult to taste, crack the shell, and bake. Problems such as long time have seriously affected and restricted the healthy and rapid development of the industry.

Contents of the invention

In view of the shortcomings of the existing technology, the purpose of the present invention is to provide a gap type high-pressure cooking device for seed nut foods, which contains seed nut raw materials through a mesh material barrel, allowing the cooking liquid to pass through the mesh material The holes of the barrel are evenly surrounding the seed and nut raw materials. By rotating the power mechanism B, the top cover and the cooking pot body can be rotated, closed and opened. The top cover can be raised and lowered through the top cover lifting cylinder, and the top cover can also be lifted. The synchronous lifting and lowering of the cover and the cooking pot body can realize the rotation and displacement operation of the top cover and the cooking pot body as a whole through the rotating power mechanism A. Therefore, the present invention can realize the mechanization of nut food processing through the combination of multiple power equipment. Processed and standardized operations greatly reduce the labor intensity of workers. Compared with traditional cooking pots, the cooking device structure has a higher degree of automation. It can realize large-scale production of nut foods and improve the cooking efficiency and cooking quality of nut foods.

The object of the present invention is achieved through the following technical solutions:

A gap type high-pressure cooking device for seed nut foods, including a frame, a rotating power mechanism A, a top cover lifting cylinder, a boom, a rotating power mechanism B, a top cover rotating shaft, a top cover, a cooking pot body and Mesh material barrel, an electric heating seat is installed on the top of the frame, a rotary power mechanism A is installed on the top of the frame through a bracket, the rotary power mechanism A has a power output shaft, and the power output of the rotary power mechanism A A driving gear A is installed on the shaft. The top cover lifting cylinder has a lifting rod. A driven gear A that meshes with the driving gear A is installed on the top cover lifting cylinder. The top of the lifting rod of the top cover lifting cylinder is fixed. There is a boom. A rotating power mechanism B is installed on the boom. The rotating power mechanism B has a power output shaft. A driving gear B is installed on the power output shaft of the rotating power mechanism B. The rotating power mechanism B rotates on the boom. A top cover rotating shaft is installed, and a driven gear B that meshes with the driving gear B is installed on the top of the top cover rotating shaft. The driven gear B is located at the top of the boom, and the bottom end of the top cover rotating shaft is fixed on the top. The top of the cover; a cooking pot body is placed on the electric heating base. The top of the cooking pot body is rotationally engaged with the bottom of the top cover. The inner cavity of the cooking pot body and the inner cavity of the top cover are connected to each other. The cooking pot cavity is provided with a mesh material barrel inside the cooking pot body, and the mesh material barrel is fixed on the inner wall of the top cover through several hanging rods.

In order to better implement the present invention, the top of the top cover is provided with an air outlet connected to the inner cavity of the top cover, and a top cover air valve is installed at the air outlet of the top cover. A manual pressure reducing lever is installed, and the manual pressure reducing lever is used to control the opening and closing of the top cover air valve.

Preferably, several cooling spray openings are provided at the bottom of the boom toward the top of the top cover.

Preferably, the top cover is provided with a barometer, and the measurement probe of the barometer penetrates the top cover and is placed in the inner cavity of the top cover.

Preferably, the mesh material barrel is composed of a left half barrel and a right half barrel that are sealed and assembled with each other, and a barrel switch device is provided at the bottom of the mesh material barrel.

Preferably, the barrel switch device includes a third link A, a first link A, a third link B, a first link B, a second link A, a second link B, and a left half floor switch. The handle and the right half bottom plate switch handle, the middle part of the mesh material barrel is equipped with a vertical plate of the barrel, the bottom half of the left half barrel is fixed with the left half bottom plate of the barrel, and the bottom of the right half barrel is fixed with the right half bottom plate of the barrel , the left half bottom plate of the barrel and the right half bottom plate of the barrel are rotationally installed on the vertical plate of the barrel through the barrel bottom plate rotating shaft; the first end of the third link A is hinged away from the left half bottom plate of the barrel through the hinge D. One end of the barrel bottom plate rotating shaft, the second end of the third link A and the first end of the first connecting rod A are hinged to each other through a composite hinge A; the barrel bottom plate rotating shaft is located below the barrel bottom plate rotating shaft Hinge A and hinge B are installed in sequence from top to bottom. The second end of the first connecting rod A is installed on hinge A. The right end of the left half-floor switch handle is installed on hinge B. The second end of the first connecting rod A is installed on hinge A. The first end of the connecting rod A is installed on the composite hinge A, the second end of the second connecting rod A is hinged to the middle part of the left half-bottom switch handle through the hinge C; the first end of the third connecting rod B is connected through the hinge E is hinged to one end of the right half bottom plate of the barrel away from the rotation axis of the bottom plate of the barrel. The second end of the third link B and the first end of the first link B are hinged to each other through a composite hinge B; the first end The second end of the connecting rod B is installed on the hinge A, the left end of the right half-floor switch handle is installed on the hinge B, the first end of the second connecting rod B is installed on the composite hinge B, and the first end of the right half-floor switch handle is installed on the hinge B. The second end of the second link B is hinged to the middle part of the right half-floor switch handle through the hinge F.

Preferably, a sliding lock block A corresponding to the switch handle of the left half of the bottom plate is installed on the left side of the bottom of the vertical plate of the barrel, and a sliding and telescopic lock block A corresponding to the switch handle of the right half of the bottom plate is installed on the right side of the bottom of the vertical plate of the barrel. Corresponding sliding lock block B.

Preferably, the number of cooling spray ports is two. The two cooling spray ports are cooling spray port A and cooling spray port B. The cooling spray port A corresponds to the left half of the top of the top cover. The cooling spray port B corresponds to the right half of the top of the top cover.

Preferably, the top end of the boom is hinged to the inner wall of the top cover, and the bottom end of the boom is hinged to the top of the mesh material bucket; the rotary power mechanism A is a motor or cylinder base servo, and the rotary power mechanism B is Cover the servo for the motor or switch.

Preferably, the boom has a rotation axis hole through it, a bearing is fixedly installed in the rotation axis hole of the boom, and the top cover rotation axis is installed in the bearing in a rotational fit; the rotation power mechanism B is installed through a bracket Fixed above the boom; a cylinder rotating base is fixed on the top of the frame, a rotating chamber is opened in the cylinder rotating base, and the bottom of the top cover lifting cylinder is rotatably installed in the rotating chamber of the cylinder rotating base; the electric motor The heating base has a heating accommodating cavity. The heating accommodating cavity of the electric heating base matches the bottom of the cooking pot body. A heating device is installed in the heating accommodating cavity of the electric heating base.

Compared with the prior art, the present invention has the following advantages and beneficial effects:

(1) The present invention provides a high-pressure cooking device that can realize mechanized full-process operation of seed nut foods and has high cooking effect. The seed nut raw materials are contained in a mesh material barrel, so that the cooking liquid can pass through the mesh material barrel. The holes are evenly surrounding the seed nut raw materials. By rotating the power mechanism B, the top cover and the cooking pot body can be rotated, closed and opened. The top cover can be raised and lowered through the top cover lifting cylinder, and the top cover and the cooking pot can also be realized. The synchronous lifting and lowering of the cooking pot body can realize the rotation and displacement operation of the top cover and the cooking pot body as a whole through the rotating power mechanism A. Therefore, the present invention can realize the mechanization and process flow of nut food processing through the combination of multiple power equipment. , standardized operations, greatly reducing the labor intensity of workers. Compared with traditional cooking pots, the cooking device structure has a higher degree of automation, can realize large-scale production of nut foods, and improves the cooking efficiency and cooking quality of nut foods.

(2) The mesh material barrel of the present invention is assembled by splicing and assembling the left half of the barrel and the right half of the barrel. It can be rotated and opened through the barrel switch device to facilitate installation, assembly, disassembly, cleaning and other operations. At the same time, the material The barrel switch device is equipped with a sliding lock block, which improves the overall stability of the mesh material barrel after the left half of the barrel and the right half of the barrel are spliced and assembled.

(3) The present invention is equipped with several cooling spray ports at the bottom of the boom corresponding to the top cover. Through the cooling spray ports, cooling water is sprayed on the top cover, which can quickly force and cool down the top cover and the cooking pot body. Pressure operation shortens the depressurization time of the cooking pot cavity.

(4) The barometer of the present invention monitors the air pressure value inside the cooking pot in real time, which improves the safety performance. At the same time, when the top cover is opened, the barometer also monitors the air pressure to prevent the danger of high-pressure opening; The top cover is equipped with a top cover air valve and a manual pressure reduction lever, which facilitates the use of the manual pressure reduction lever to open the top cover air valve within a safe pressure range to release the air pressure in the cooking pot cavity, further shortening the pressure drop in the cooking pot cavity. Pressure time.

(5) The present invention performs high-pressure cooking on seed nut snack foods to solve the problems of difficulty in flavoring the kernels, difficulty in cracking the shell, and long baking time.

(6) The present invention can also be equipped with a cooking liquid control system, which can realize fully automatic control of temperature, pressure, time control, material loading, unloading and stirring during the material processing process, thereby improving work efficiency.

Description of the drawings

Figure 1 is a schematic structural diagram of the present invention;

Figure 2 is a partially enlarged schematic diagram of Figure 1.

Among them, the names corresponding to the reference signs in the accompanying drawings are:

1 - frame, 2 - driving gear A, 3 - rotating power mechanism A, 4 - top cover lifting cylinder, 5 - boom, 6 - air pressure gauge, 7 - cooling spray port A, 8 - rotating power mechanism B, 81 - driving gear B, 9 - driven gear B, 10 - top cover rotating shaft, 11 - cooling spray port B, 12 - top cover air valve, 13 - manual pressure reducing lever, 14 - top cover, 15 - hanging Rod, 16 - mesh material barrel, 17 - cooking pot body, 18 - barrel switch device, 19 - electric heating seat, 20 - barrel bottom plate rotating shaft, 21 - barrel vertical plate, 22 - hinge A, 23 - Hinge B, 24-sliding lock block A, 25-first link A, 26-hinge C, 27-second link A, 28-composite hinge A, 29-left half floor switch handle, 30-third link Rod A, 31 - hinge D, 32 - left half bottom plate of the barrel, 33 - right half bottom plate of the barrel, 34 - hinge E, 35 - third link B, 36 - composite hinge B, 37 - first link B ,38-Second link B, 39-Hinge F, 40-Right half bottom plate switch handle, 41-Sliding lock block B.

Detailed ways

The present invention will be further described in detail below in conjunction with the examples:

Example

As shown in Figures 1 and 2, a gap type high-pressure cooking device for seed nut foods includes a frame 1, a rotating power mechanism A3, a top cover lifting cylinder 4, a boom 5, a rotating power mechanism B8, a top Cover rotating shaft 10, top cover 14, cooking pot body 17 and mesh material barrel 16. An electric heating base 19 is installed on the top of the frame 1. A rotary power mechanism A3 is installed on the top of the frame 1 through a bracket. The rotary power mechanism A3 is preferably It is a motor or a cylinder base steering gear. The rotating power mechanism A3 has a power output shaft. A driving gear A2 is installed on the power output shaft of the rotating power mechanism A3. The top cover lifting cylinder 4 has a lifting rod. The top cover lifting cylinder 4 is equipped with a The driving gear A2 meshes with the driven gear A. A boom 5 is fixed on the top of the lifting rod of the top cover lifting cylinder 4. A rotary power mechanism B8 is installed on the boom 5. The rotary power mechanism B8 is preferably a motor or a switch cover servo. The rotary power mechanism B8 has a power output shaft, and the rotary power mechanism B8 has a power output shaft. A driving gear B81 is installed on the power output shaft of the mechanism B8, a top cover rotating shaft 10 is installed on the boom 5 for rotation, and a driven gear B9 that meshes with the driving gear B81 is installed on the top of the top cover rotating shaft 10. The driven gear B9 Located at the top of the boom 5, the bottom end of the top cover rotating shaft 10 is fixed to the top of the top cover 14. A cooking pot body 17 is placed on the electric heating base 19. The top of the cooking pot body 17 is rotatably connected to the bottom of the top cover 14. The inner cavity of the cooking pot body 17 and the inner cavity of the top cover 14 are interconnected to form a cooking pot cavity. The cooking pot body 17 is provided with a mesh material barrel 16 inside. The mesh material barrel 16 is fixed on the inner side wall of the top cover 14 through several suspenders 15. The top of the preferred suspension rod 15 of the present invention is hinged to the inner side of the top cover 14. On the wall, the bottom end of the boom 15 is hinged to the top of the mesh material barrel 16.

As shown in Figure 1, the top of the top cover 14 has an air outlet connected to the inner cavity of the top cover 14. The top cover air valve 12 is installed at the air outlet of the top cover 14. The top cover air valve 12 is equipped with a manual Pressure reduction lever 13, the manual pressure reduction lever 13 is used to control the opening and closing of the top cover air valve 12. When in use, the opening and closing of the top cover air valve 12 can be controlled by the manual pressure reducing lever 13, thereby realizing the cooking pot cavity (the inner cavity of the cooking pot body 17 and the inner cavity of the top cover 14 are interconnected to form a cooking pot cavity). ) high-pressure deflation or high-pressure air-holding operation.

There are several cooling spray ports at the bottom of the boom 5 toward the top of the top cover 14. As shown in Figure 1, there are two cooling spray ports. The two cooling spray ports are the cooling spray port A7 and the cooling spray port. Port B11, cooling spray port A7 corresponds to the left half of the top of the top cover 14, and cooling spray port B11 corresponds to the right half of the top of the top cover 14.

As shown in Figure 1, a barometer 6 is provided on the top cover 14. The measurement probe of the barometer 6 penetrates the top cover 14 and is placed in the inner cavity of the top cover 14; during use, the pressure gauge 6 can be used to measure the cooking pot in real time. The air pressure inside the cavity.

The preferred mesh material barrel 16 of the present invention is composed of a left half barrel body and a right half barrel body that are sealed and assembled with each other. The bottom of the mesh material barrel 16 is provided with a barrel switching device 18. The barrel switching device 18 includes a left half The barrel opening device and the right half barrel opening device, through the left half barrel opening device, the left half barrel can be rotated in a direction away from the right half barrel to rotate and open the left half barrel; through the right half barrel opening device The half barrel opening device can rotate the right half barrel away from the left half barrel to rotate and open the right half barrel. As shown in Figure 2, the barrel switch device 18 includes a third link A30, a first link A25, a third link B35, a first link B37, a second link A27, a second link B38, a left half The bottom plate switch handle 29 and the right half bottom plate switch handle 40 are provided with a bucket vertical plate 21 in the middle of the mesh material bucket 16, a left half bottom plate 32 of the bucket is fixed at the bottom of the left half of the bucket, and a right half of the bucket is fixed at the bottom of the right half of the bucket. The bottom plate 33, the left half bottom plate 32 of the barrel, and the right half bottom plate 33 of the barrel are rotatably installed on the vertical plate 21 of the barrel through the barrel bottom plate rotating shaft 20. The first end of the third link A30 is hinged to the end of the left half bottom plate 32 of the barrel away from the barrel bottom plate rotation axis 20 through the hinge D31. The second end of the third link A30 is connected to the first end of the first link A25. Hinged to each other through composite hinge A28. A hinge A22 and a hinge B23 are installed in sequence from top to bottom on the bottom of the barrel bottom plate rotating shaft 20. The second end of the first connecting rod A25 is installed on the hinge A22. The right end of the left half bottom plate switch handle 29 It is installed on the hinge B23, the first end of the second link A27 is installed on the composite hinge A28, and the second end of the second link A27 is hinged to the middle part of the left half-floor switch handle 29 through the hinge C26. The first end of the third link B35 is hinged to the end of the right half bottom plate 33 of the barrel away from the barrel bottom plate rotation axis 20 through the hinge E34. The second end of the third link B35 is connected to the first end of the first link B37. Hinged to each other via composite hinge B36. The second end of the first connecting rod B37 is installed on the hinge A22, the left end of the right half-floor switch handle 40 is installed on the hinge B23, the first end of the second connecting rod B38 is installed on the composite hinge B36, and the second connecting rod The second end of B38 is hinged to the middle part of the right half-bottom switch handle 40 through hinge F39.

As shown in Figure 2, a sliding lock block A24 corresponding to the switch handle 29 of the left half floor plate is installed on the left side of the bottom of the barrel vertical plate 21, and a sliding lock block A24 corresponding to the switch handle 29 of the left half floor plate is installed on the left side of the bottom of the barrel vertical plate 21. A switch corresponding to the right half floor switch is installed on the right side of the bottom of the barrel vertical plate 21. The handle 40 corresponds to the sliding lock block B41.

As shown in Figure 1, the boom 5 has a rotation axis hole through it, a bearing is fixedly installed in the rotation axis hole of the boom 5, and the top cover rotation axis 10 is installed in the bearing in a rotational fit. The rotating power mechanism B8 is installed and fixed above the boom 5 through a bracket. A cylinder rotating seat is fixed on the top of the frame 1, and a rotating chamber is opened in the cylinder rotating seat. The bottom of the top cover lifting cylinder 4 is rotatably installed in the rotating chamber of the cylinder rotating seat. As shown in Figure 1, the electric heating base 19 has a heating accommodation cavity. The heating accommodation cavity of the electric heating base 19 matches the bottom of the cooking pot body 17. A heating device is installed in the heating accommodation cavity of the electric heating base 19.

The gap type high-pressure cooking device of the present invention can also realize automated and intelligent operation control. The gap type high-pressure cooking device also includes a cooking control system. The cooking control system includes a heating control module, a spray control module, a top cover switch control module, and a cooking time. Monitoring module, cooking pressure monitoring module, cooking pot lifting control module and cooking pot movement control module, the heating control module is electrically connected to the heating device of the electric heating base 19, and the heating control module is used to control the heating device of the electric heating base 19 Heating time and heating power. All cooling spray ports are equipped with spray solenoid valves. The spray control module is electrically connected to the spray solenoid valves of all cooling spray ports. The spray control module is used to control the opening of the spray solenoid valves of all cooling spray ports. and close operations. The switch top cover control module is electrically connected to the rotary power mechanism B8. The switch top cover control module is used to control the switching operation and running time of the rotary power mechanism B8 to realize the driving top cover 14 to rotate and snap on the cooking pot body 17 or Turn open. The cooking time monitoring module is used to set the cooking time of the entire high-pressure cooking device. The cooking pressure monitoring module is electrically connected to the air pressure gauge 6. The cooking pressure monitoring module is used to monitor the air pressure value inside the cooking pot cavity in real time. The cooking pot body lifting control module is electrically connected to the top cover lifting cylinder 4, and the cooking pot body lifting control module is used to control the lifting movement of the top cover lifting cylinder 4 to drive the lifting rod. The cooking pot movement control module is electrically connected to the rotary power mechanism A3. The cooking pot movement control module is used to control the switching operation and running time of the rotary power mechanism A3.

The working principle of the gap type high-pressure cooking device of the present invention is as follows:

The left half barrel and the right half barrel of the mesh material barrel 16 are sealed and spliced to each other through the barrel switch device 18. The seed nut raw materials that need to be cooked are loaded into the mesh material barrel 16, and then the mesh material is The barrel 16 is hoisted below the top cover 14 through two booms 15 . The cooking liquid is filled inside the cooking pot body 17, and the rotating power mechanism B8 is started. The rotating power mechanism B8 drives the top cover 14 to seal and rotate the clamping cover to the top of the cooking pot body 17. The top cover lifting cylinder 4 is started, and the top cover lifting cylinder is started. 4 drives the lifting rod to move up and down, and the lifting rod of the top cover lifting cylinder 4 drives the boom 5 and the top cover 14 to move up and down synchronously to lift to a suitable height position. Start the rotating power mechanism A3. The rotating power mechanism A3 drives the driving gear A2 to rotate. The driving gear A2 drives the driven gear A and the top cover lifting cylinder 4 to rotate and synchronize the top cover 14, the mesh material barrel 16, and the cooking pot body 17 as a whole. Rotate to the top of the electric heating base 19, and then use the top cover lifting cylinder 4 to place the top cover 14, the mesh material barrel 16, and the cooking pot body 17 in the heating accommodation cavity of the electric heating base 19. Start the heating device of the electric heating base 19 to heat the cooking pot body 17. The internal air pressure of the cooking pot body 17 rises to form a high pressure and performs high-pressure cooking operation on the seed nut raw materials in the mesh material barrel 16. The air pressure gauge 6 is on The air pressure value inside the cooking pot body 17 is monitored in real time. After the cooking is completed, start the top cover lifting cylinder 4 to lift the top cover 14, the mesh material barrel 16, and the cooking pot body 17 by a portion, and then start the rotating power mechanism A3 to lift the top cover 14, the mesh material barrel 16, and the cooking pot. The pot body 17 rotates as a whole and moves into the cooling area, and sprays cooling water on the top cover 14 through all the cooling spray ports A7 to achieve rapid forced cooling and pressure reduction operations on the top cover 14 and the cooking pot body 17. Barometer 6. Monitor the air pressure value inside the cooking pot body 17 in real time. After the cooling and pressure reduction operations are completed, control the top cover air valve 12 to open and release the pressure through the manual pressure reduction lever 13; then drive the top cover 14 through the rotating power mechanism B8 Rotate and open from the top of the cooking pot body 17, so that the top cover 14 and the cooking pot body 17 are separated from each other. The left half of the barrel and the right half of the mesh material barrel 16 are separated through the barrel switch device 18. And let the seed nut food in the mesh material bucket 16 be released, or directly dump the mesh material bucket 16 to release the seed nut food. After the barrel switch device 18 separates the left half barrel and the right half barrel of the mesh material barrel 16, the left half barrel and the right half barrel of the mesh material barrel 16 can be cleaned respectively. Prepare for the next seed and nut food cooking operation.

The above are only preferred embodiments of the present invention and are not intended to limit the present invention. Any modifications, equivalent substitutions and improvements made within the spirit and principles of the present invention shall be included in the protection of the present invention. within the range.

Claims (7)

1. A gap type high-pressure cooking device for seed nut foods, which is characterized by: including a frame (1), a rotating power mechanism A (3), a top cover lifting cylinder (4), a boom (5), Rotating power mechanism B (8), top cover rotating shaft (10), top cover (14), cooking pot body (17) and mesh material barrel (16). Electric heating is installed on the top of the frame (1) The base (19) has a rotary power mechanism A (3) installed on the top of the frame (1) through a bracket. The rotary power mechanism A (3) has a power output shaft. The power of the rotary power mechanism A (3) A driving gear A (2) is installed on the output shaft. The top cover lifting cylinder (4) has a lifting rod. A driven gear meshing with the driving gear A (2) is installed on the top cover lifting cylinder (4). A; A boom (5) is fixed on the top of the lifting rod of the top cover lifting cylinder (4), and a rotating power mechanism B (8) is installed on the boom (5). The rotating power mechanism B (8) It has a power output shaft. A driving gear B (81) is installed on the power output shaft of the rotating power mechanism B (8). A top cover rotation shaft (10) is rotatably installed on the boom (5). A driven gear B (9) that meshes with the driving gear B (81) is installed on the top of the cover rotating shaft (10). The bottom end of the top cover rotating shaft (10) is fixed on the top of the top cover (14); the electric motor A cooking pot body (17) is placed on the heating base (19). The top of the cooking pot body (17) is rotatably connected with the bottom of the top cover (14). There is a cooking pot body (17) inside. Mesh material bucket (16), the mesh material bucket (16) is fixed on the inner wall of the top cover (14) through several booms (15); the bottom of the boom (5) faces the top cover (14) There are several cooling spray openings on the top; the mesh material barrel (16) is assembled by the left half barrel and the right half barrel being sealed and assembled with each other. The mesh material barrel (16) is provided with materials at the bottom. Barrel switch device (18); the barrel switch device (18) includes a third link A (30), a first link A (25), a third link B (35), a first link B ( 37), the second link A (27), the second link B (38), the left half bottom plate switch handle (29) and the right half bottom plate switch handle (40). The mesh material barrel (16) is equipped with a There is a bucket vertical plate (21), the left half of the bucket is fixed with the bottom half of the bucket (32), the bottom of the right half of the bucket is fixed with the right half of the bucket (33), the left half of the bucket is The bottom plate (32) and the right half bottom plate (33) of the barrel are rotatably installed on the vertical plate (21) of the barrel through the barrel bottom plate rotating shaft (20); the first end of the third link A (30) passes through the hinge D (31) is hinged to the end of the left half bottom plate (32) of the barrel away from the rotating shaft (20) of the bottom plate of the barrel. The second end of the third link A (30) and the first link A (25) The first ends are hinged to each other through composite hinges A (28); the barrel bottom plate rotating shaft (20) is equipped with hinges A (22) and hinges B (23) from top to bottom below the barrel bottom plate rotating shaft (20). , the second end of the first link A (25) is installed on the hinge A (22), the right end of the left half-floor switch handle (29) is installed on the hinge B (23), and the second end of the first link A (25) is installed on the hinge B (23). The first end of the connecting rod A (27) is installed on the composite hinge A (28), and the second end of the second connecting rod A (27) is hinged to the left half-floor switch handle (29) through the hinge C (26). The middle part; the first end of the third connecting rod B (35) is hinged to the end of the right half bottom plate (33) of the barrel away from the rotating shaft (20) of the barrel bottom plate through the hinge E (34). The second end of rod B (35) and the first end of first connecting rod B (37) are hinged to each other through composite hinge B (36); the second end of first connecting rod B (37) is installed on hinge A (22), the left end of the right half-floor switch handle (40) is installed on the hinge B (23), and the first end of the second connecting rod B (38) is installed on the composite hinge B (36) , the second end of the second link B (38) is hinged to the middle part of the right half-floor switch handle (40) through the hinge F (39). 2. A gap-type high-pressure cooking device for seed nut foods according to claim 1, characterized in that: the top of the top cover (14) has an opening connected to the inner cavity of the top cover (14). The air outlet, the air outlet of the top cover (14) is equipped with a top cover air valve (12), and a manual pressure reduction rod (13) is installed on the top cover air valve (12). The manual pressure reduction lever The lever (13) is used to control the opening and closing of the top cover air valve (12). 3. A gap type high-pressure cooking device for seed nut foods according to claim 1, characterized in that: the top cover (14) is provided with a barometer (6), and the barometer (6) )'s measuring probe penetrates the top cover (14) and is placed in the inner cavity of the top cover (14). 4. A gap type high-pressure cooking device for seed nut foods according to claim 1, characterized in that: the left side of the bottom of the barrel vertical plate (21) is slidably telescopically installed with a switch handle connected to the left half of the bottom plate. (29) Corresponding sliding lock block A (24). A sliding lock block B (41) corresponding to the right half bottom plate switch handle (40) is installed on the right side of the bottom of the barrel vertical plate (21). 5. A gap type high-pressure cooking device for seed nut food according to claim 1, characterized in that: the number of the cooling spray ports is two, and the two cooling spray ports are cooling sprays respectively. The cooling spray port A (7) and the cooling spray port B (11) correspond to the left half of the top of the top cover (14), and the cooling spray port B (11) corresponds to the top left half of the top cover (14). (14) The top right half corresponds. 6. A gap type high-pressure cooking device for seed nut foods according to claim 1, characterized in that: the top end of the boom (15) is hinged to the inner wall of the top cover (14), and the hanging rod (15) is hinged to the inner wall of the top cover (14). The bottom end of the rod (15) is hinged to the top of the mesh material barrel (16); the rotary power mechanism A (3) is a motor or a cylinder base servo, and the rotary power mechanism B (8) is a motor or a switch cover servo. . 7. A gap type high-pressure cooking device for seed and nut foods according to claim 1, characterized in that: the boom (5) has a rotation axis hole through it, and the boom (5) A bearing is fixedly installed in the rotating shaft hole, and the top cover rotating shaft (10) is installed in the bearing in a rotational fit; the rotating power mechanism B (8) is installed and fixed above the boom (5) through a bracket; the frame (1) A cylinder rotating seat is fixed on the top, and a rotating chamber is opened in the cylinder rotating seat. The bottom of the top cover lifting cylinder (4) is rotated and installed in the rotating chamber of the cylinder rotating seat; the electric heating seat (19 ) has a heating accommodation cavity. The heating accommodation cavity of the electric heating base (19) matches the bottom of the cooking pot body (17). A heating device is installed in the heating accommodation cavity of the electric heating base (19).