CN105661410A - Potato chip production device - Google Patents

Abstract

The present invention discloses a potato chip production device which can avoid browning of potatoes during processing processes. The production device consists of a washing device, a peeling device, a slicing device, a curing device, a cooling device, a microwave drying device, an oil frying device and a seasoning device. Except the washing device, the oil-frying device and seasoning device, other devices all work in a sealed environment and each of the devices are connected in a sealed manner, so that except the washing process, the oil-frying process and the seasoning process, other processes are all conducted in the sealed environment. The potato chip production device can ensure the contact chances of the potato chips with oxygen during the entire processing processes to be greatly reduced, can effectively prevent the contact of polyphenol oxidase (PPO) in the potatoes with the oxygen in the air during the process, avoid the incidence of oxidative polymerization, can effectively prevent the browning of the potatoes, and thus ensure the final produced potato chips to have a relative high quality. The potato chip production device is suitable for the promotion and application in the potato processing technical field.

Description

A potato chip production device

technical field

The invention relates to the technical field of potato processing, in particular to a potato chip production device.

Background technique

Potato, a perennial herb belonging to the family Solanaceae, has edible tubers and is the third most important food crop in the world, second only to wheat and corn. Potatoes are also known as ground eggs, potatoes, Yang Yam, etc., the tubers of Solanaceae plants. Together with wheat, corn, rice, and sorghum, it has become the world's top five crops.

The processing of potato chips is usually divided into the following steps: cleaning-peeling-slicing-curing-cooling-drying-fried-seasoning. In the existing potato chip processing, most of the processes are directly in the air This causes the polyphenol oxidase (PPO) in the potato to easily contact with oxygen in the air, and oxidative polymerization will occur, resulting in browning. After the potato browns, it will not only make the potato black, but also destroy the potato. Lesions of amino acids, proteins, and ascorbic acid lead to a reduction in the nutritional value of potatoes. Furthermore, after potatoes are browned, their flavor is poor. The products of browning have antioxidant effects and will produce harmful components, such as acrylamide, which are harmful to the human body healthy.

Contents of the invention

The technical problem to be solved by the present invention is to provide a potato chip production device that avoids browning of potatoes during processing.

The technical solution adopted by the present invention to solve the technical problem is: the potato chip production device includes a cleaning device, a peeling device, a slicing device, a ripening device, a cooling device, a microwave drying device, a frying device, and a seasoning device arranged in sequence;

The cleaning device includes a conveyor belt A, a passive roller A, a driving roller A, a driving motor A, a primary cleaning tank A, and a secondary cleaning tank A. The passive roller A and the driving roller A tighten the conveyor belt A, and the driving motor A is used to rotate the driving drum A, the primary cleaning tank A and the secondary cleaning tank A are arranged along the running direction of the conveyor belt A in turn, the conveyor belt A is a mesh structure, and the primary cleaning tank A includes the first Water tank A, the first water tank A is located between the conveyor belt A of the upper layer and the conveyor belt A of the lower layer, and a plurality of first lower spray pipes A arranged in parallel to each other are arranged in the first water tank A, and the first lower spray pipes A A plurality of first lower nozzles A are arranged at intervals on the pipe A, and the first lower nozzles A face the upper conveyor belt A, and a plurality of first upper nozzles A are arranged above the first water tank A. A plurality of first upper nozzles A are arranged at intervals on the upper nozzle A, and the first upper nozzles A face the upper conveyor belt A, and the bottom of the first water tank A is connected with the first sewage pipe A communicating with it; The secondary cleaning tank A includes a second water tank A, the second water tank A is located between the upper conveyor belt A and the lower conveyor belt A, and a plurality of second lower spray pipes arranged parallel to each other are arranged in the second water tank A A, a plurality of second lower nozzles A are arranged at intervals on the second lower nozzle A, and the second lower nozzles A face the upper conveyor belt A, and a plurality of second lower nozzles A are arranged above the second water tank A. The upper nozzle A, the second upper nozzle A is provided with a plurality of second upper nozzles A at intervals, and the second upper nozzle A faces the upper conveyor belt A, the second upper nozzle A, the second lower nozzle The pipes A are all in communication with the high-pressure water pipes, the bottom of the second water tank A is connected with the second sewage pipe A connected with it, the end of the second sewage pipe A is connected with a pool A, and the pool A is provided with a water inlet A and an outlet. The water inlet A, the water inlet A is connected with the end of the second sewage pipe A, the water outlet A is connected with the water diversion pipe A, the water diversion pipe A is provided with a water pump A, and the ends of the water diversion pipe A are connected with the first upper sewage pipe A respectively. The nozzle A and the first lower nozzle A are connected;

The peeling device includes an airtight outer cylinder B and a drive motor B. A turntable B is arranged inside the outer cylinder B. The outer diameter of the turntable B matches the inner diameter of the outer cylinder B. The turntable B A shaft B is fixed at the center of the lower surface, the lower end of the shaft B extends outside the outer cylinder B, the output shaft of the drive motor B is connected to the lower end of the shaft B, the upper surface of the turntable B is wave-shaped, and the turntable B turns the outer cylinder The inside of the body B is divided into a peeling cavity B and a water storage cavity B. A water spray head B is arranged in the peeling cavity B. The water spray head B is located above the turntable B and faces the turntable B. The water spray head B is connected with a drainage pipe B, and the drainage pipe B is provided with a shut-off valve B. The drainage pipe B is connected with a high-pressure water pipe, and the wall of the outer cylinder B is provided with a discharge port B. The discharge port B is located above the horizontal plane where the turntable B is located. An annular sleeve B is arranged in the peeling cavity B. The outer diameter of the annular sleeve B matches the inner diameter of the outer cylinder B. The annular sleeve B The inner surface of the inner wall is a grinding surface, and the upper end of the annular sleeve B is provided with a lifting device B. When the lower end of the annular sleeve B is close to the turntable B, the annular sleeve B will block the discharge port B. When the annular sleeve B moves upward When reaching the highest point, the discharge port B communicates with the peeling cavity B, and the turntable B is provided with a plurality of water holes B, and the water holes B communicate the peeling cavity B with the water storage cavity B , the bottom of the outer cylinder B is provided with a drain port B, the drain port B is connected to the first sewage pipe B, the first sewage pipe B is provided with a first conduction valve B, and the end of the first sewage pipe B is connected to There is a closed transition water tank B, the bottom of the transition water tank B is connected with the second sewage pipe B communicating with it, the second sewage pipe B is provided with a second conduction valve B, and the top of the outer cylinder B A transition cylinder B is provided, the lower end of the transition cylinder B is in sealing connection with the upper end of the outer cylinder B and a first control valve B is arranged at the lower end of the transition cylinder B, and a second control valve B is arranged at the upper end of the transition cylinder B. control valve B;

The slicing device includes an airtight casing C, and the casing C is provided with a conveyor belt C, a driven roller C, a driving roller C, a first driving motor C, a driving roller C, and a second driving motor C. The drum C and the driving drum C tighten the conveyor belt C, the driving motor C is used to rotate the driving drum C, the driving roller C is located above the conveyor belt C, and the second driving motor C is used to rotate the driving roller C. A plurality of annular blades C are sheathed on the driving roller C, and the plurality of annular blades C are arranged parallel to each other. The surface of the conveyor belt C is provided with a layer of buffer pad C, and the surface of the buffer pad C is provided with a plurality of knife grooves C. , the number of the sipe C is the same as the number of the annular blade C and the positions correspond to each other, the cutting edge of the annular blade C is located in the sipe C, and the top of the housing C is provided with a feed port C, and the feed Port C and discharge port B are sealed and connected through material guide pipe C, and a material guide groove C is connected to the material inlet C, one end of the material guide groove C is connected to the material inlet C, and the other end extends to the conveyor belt C Above, the outer side of the passive drum C is provided with a discharge pipe C, one end of the discharge pipe C extends to the outside of the passive drum C and is in contact with the cushion C, and the other end extends to the outside of the housing C, the The end of the discharge pipe C is provided with a shut-off valve C;

The curing device includes a steam generator D, an inner cylinder D and an outer cylinder D, the inner cylinder D is arranged in the outer cylinder D, and a closed airtight chamber is formed between the outer cylinder D and the inner cylinder D In the interlayer space D, the inner cylinder wall is provided with a steam through hole D, the steam generator D communicates with the interlayer space D through a steam pipe D, and the upper end of the inner cylinder D is provided with a first stop valve D, The lower end of the inner cylinder D is provided with a second shut-off valve D, the upper end of the inner cylinder D is connected with a transition cylinder D, the upper end of the transition cylinder D is connected with a hopper D, and the discharge port of the hopper D is A third shut-off valve D is provided, and the feed port of the hopper D is sealedly connected with the end of the discharge pipe C;

The cooling device includes an airtight vacuum box E connected with a vacuum pump E, the bottom of the vacuum box E is provided with an outlet E, and the outlet E is sealed and connected with a first A transition cylinder E, the upper end of the first transition cylinder E is provided with a first shut-off valve E, the lower end of the first transition cylinder E is provided with a second shut-off valve E, and the upper end of the vacuum box E is provided There is a second transition cylinder E, the lower end of the second transition cylinder E is sealed and connected with the vacuum box E and communicated with the inside of the vacuum box E, and the lower end of the second transition cylinder E is provided with a third stop valve E, the upper end of the second transition cylinder E is in sealing connection with the lower end of the inner cylinder D;

The microwave drying device includes a closed box G, and the box G is provided with a microwave transmitter G, a microwave receiver G, and a heating cylinder G, and the upper end of the heating cylinder G is sealed and connected with a transition cylinder G , the upper end of the transition cylinder G extends out of the box G and is sealingly connected with the end of the first transition cylinder E, the lower end of the heating cylinder G extends out of the box G and is at the lower end of the heating cylinder G A second shut-off valve G is provided, and the microwave transmitter G and the microwave receiver G are respectively arranged on both sides of the heating cylinder G;

The frying device includes a box body E, which is filled with high-temperature edible oil, and the box body E is provided with a first conveyor belt E, a first driven roller E, a first driving roller E, a first The surface of the conveyor belt E is provided with a plurality of first scrapers, and the plurality of first scrapers are arranged parallel to each other and perpendicular to the conveying direction of the first conveyor belt E. The first conveyor belt E is arranged horizontally and the upper layer The first conveyor belt E is submerged in high-temperature edible oil, the lower end of the heating cylinder G faces the first conveyor belt E, the first passive roller E and the first driving roller E tighten the first conveyor belt E, and the first driving roller E is connected with a first driving motor E for making it rotate, and a second driving drum E and a second conveyor belt E are also arranged in the box body E, and a second driving motor E for making it rotate is connected on the second driving drum E. A drive motor E, a second driven roller E is arranged above the box E, the second driven roller E is arranged at the bottom right of the first driven roller E, and the second driven roller E is arranged at the bottom of the second driven roller E On the right side, the second passive roller E and the second driving roller E tighten the second conveyor belt E, and the surface of the second conveyor belt E is provided with multiple second scrapers, and multiple second scrapers The plates are arranged parallel to each other and perpendicular to the conveying direction of the second conveyor belt E, and the sum of the height of the first scraper and the height of the second scraper is equal to the distance between the first passive roller E and the second driving roller E. The minimum spacing, the third driving roller E is arranged on the lower right of the second passive roller E, the third passive roller E and the third conveyor belt E are arranged on the upper right of the box E, and the third conveyor belt E is horizontal Setting, the third driven roller E and the third driving roller E tighten the third conveyor belt E;

The seasoning device includes a seasoning drum, the third passive drum E is located in the seasoning drum, and the seasoning drum is arranged obliquely from left to right, and a funnel with seasoning is arranged on the left side of the seasoning drum, and The discharge port faces the third conveyor belt E.

Further, a plurality of filter screens A are arranged in the pool A, and the plurality of filter screens A are sequentially arranged between the water inlet A and the water outlet A; a hopper A is arranged above the conveyor belt A, and the outlet of the hopper A The feed port faces the conveyor belt A, the hopper A is located outside the primary cleaning tank A; the secondary cleaning tank A is provided with a receiving tank A outside, and the upper end of the transition cylinder B is sealed and connected with the lower end of the receiving tank A, so A material guide trough A is connected to the material receiving trough A, one end of the material guide trough A is connected to the material receiving trough A, and the other end extends to the outside of the driven roller A and contacts the conveyor belt A.

Further, the length of the blade C is the same as the width of the left space C.

Further, a collection groove is provided under the right end of the seasoning drum.

Further, the outer cylinder B is connected with a nitrogen pipe B for charging nitrogen into the outer cylinder B; the casing C is connected with a nitrogen pipe C for charging nitrogen into the casing C; The outer cylinder D is connected with a nitrogen pipe D for charging nitrogen into the outer cylinder D; the casing F is connected with a nitrogen pipe F for charging nitrogen into the casing F; the box G is connected with a nitrogen pipe G for charging nitrogen into the box G.

The beneficial effects of the present invention are: the potato chip production device is composed of cleaning device, peeling device, slicing device, ripening device, cooling device, microwave drying device, frying device and seasoning device arranged in sequence, except cleaning device, frying device Except for the seasoning device and seasoning device, other devices work in a closed environment, and each device is sealed and connected, so that except for the potato cleaning process, frying process, and seasoning process, other processes are carried out in a sealed environment. Ensure that the probability of potato chips being in contact with oxygen during the entire processing process is greatly reduced, which can effectively prevent the polyphenol oxidase (PPO) in the potato from contacting oxygen in the air during the processing process, avoid oxidative polymerization, and effectively prevent potato browning , so as to ensure that the quality of the final potato chips produced is high.

Description of drawings

In order to more clearly illustrate the technical solutions in the embodiments of the present invention or the prior art, the following will briefly introduce the drawings that need to be used in the description of the embodiments or the prior art. Obviously, the accompanying drawings in the following description are only It is an embodiment of the present invention, and those skilled in the art can also obtain other drawings according to the provided drawings without creative work.

Fig. 1 is the structural representation of potato chip production device of the present invention;

Fig. 2 is a partial cross-sectional schematic view of the slicing device of the present invention;

Explanation of marks in the figure: cleaning device 1, including conveyor belt A101, passive roller A102, driving roller A103, driving motor A104, primary cleaning tank A105, first water tank A1051, first lower nozzle A1052, first lower nozzle A1053, first The first upper nozzle A1054, the first upper nozzle A1055, the first sewage pipe A1056, the second cleaning tank A106, the second water tank A1061, the second lower nozzle A1062, the second lower nozzle A1063, the second upper nozzle A1064, the second The second upper nozzle A1065, the second sewage pipe A1066, the pool A1067, the water diversion pipe A1068, the water pump A1069, the filter screen A107, the hopper A108, the receiving trough A109, the guide trough A110; the peeling device 2, the outer cylinder B201, peeling Cavity B2011, water storage cavity B2012, driving motor B202, turntable B203, rotating shaft B204, sprinkler head B205, drainage tube B206, stop valve B207, discharge port B208, annular sleeve B209, lifting device B210, water hole B211, drain port B212, first sewage pipe B213, first pilot valve B214, transition water tank B215, second sewage pipe B216, second pilot valve B217, transition cylinder B218, first control valve B219, second control valve Valve B220, nitrogen pipe B221; slicing device 3, housing C301, conveyor belt C302, passive roller C303, driving roller C304, first driving motor C305, driving roller C306, second driving motor C307, ring blade C308, buffer pad C309 , Cutter groove C310, material inlet C311, material guide pipe C312, discharge pipe C313, stop valve C314, nitrogen pipe C315, material guide groove C316, scraper plate C317; aging device 4, steam generator D401, inner cylinder D402, outer cylinder D403, interlayer space D404, steam hole D405, first stop valve D406, second stop valve D407, transition cylinder D408, hopper D409, third stop valve D410, nitrogen pipe D411; cooling device 5, Vacuum box E501, vacuum pump E502, outlet E503, first transition cylinder E504, first stop valve E505, second stop valve E506, second transition cylinder E507, third stop valve E508; frying device 6, Box E601, first conveyor belt E602, first driven roller E603, first driving roller E604, first scraper 605, first driving motor E606, second driving roller E607, second conveyor belt E608, second driving Motor E609, second passive roller E610, second scraper 611, third driving roller E612, third passive roller E613, third conveyor belt E614; microwave drying device 7, box G701, microwave transmitter G702, microwave receiver Device G703, heating cylinder G704, transition cylinder G70 5. Second stop valve G707, nitrogen pipe G714; seasoning device 8, seasoning drum 801, funnel 802, collection tank 803.

detailed description

In order to make the purpose, technical solutions and advantages of the embodiments of the present invention clearer, the technical solutions in the embodiments of the present invention will be clearly and completely described below in conjunction with the drawings in the embodiments of the present invention. Obviously, the described embodiments It is a part of embodiments of the present invention, but not all embodiments. Based on the embodiments of the present invention, all other embodiments obtained by persons of ordinary skill in the art without creative efforts fall within the protection scope of the present invention.

As shown in Figures 1 and 2, the potato chip production device includes a cleaning device 1, a peeling device 2, a slicing device 3, a ripening device 4, a cooling device 5, a microwave drying device 7, a frying device 6, a seasoning device, and a cleaning device 1 arranged in sequence. device 8;

The cleaning device 1 includes a conveyor belt A101, a driven roller A102, a driving roller A103, a driving motor A104, a primary cleaning tank A105, and a secondary cleaning tank A106. The passive roller A102 and the driving roller A103 tighten the conveyor belt A101 and drive The motor A104 is used to rotate the driving drum A103. The primary cleaning tank A105 and the secondary cleaning tank A106 are arranged along the running direction of the conveyor belt A101 in sequence. The conveyor belt A101 has a mesh structure, and the primary cleaning tank A105 includes a second A water tank A1051, the first water tank A1051 is located between the upper conveyer belt A101 and the lower conveyer belt A101, the first water tank A1051 is provided with a plurality of first lower nozzles A1052 parallel to each other, the first lower A plurality of first lower nozzles A1053 are arranged at intervals on the nozzle A1052, and the first lower nozzles A1053 face the upper conveyor belt A101, and a plurality of first upper nozzles A1054 are arranged above the first water tank A1051. A plurality of first upper nozzles A1055 are arranged at intervals on the first upper nozzle A1054, and the first upper nozzles A1055 face the upper conveyor belt A101, and the bottom of the first water tank A1051 is connected with the first sewage pipe A1056 communicating with it; The secondary cleaning tank A106 includes a second water tank A1061, the second water tank A1061 is located between the upper conveyor belt A101 and the lower conveyor belt A101, and the second water tank A1061 is provided with a plurality of second lower nozzles arranged parallel to each other. Pipe A1062, the second lower nozzle A1062 is provided with a plurality of second lower nozzles A1063 at intervals, the second lower nozzles A1063 face the upper conveyor belt A101, and above the second water tank A1061 are arranged a plurality of second Two upper nozzles A1064, a plurality of second upper nozzles A1065 are arranged at intervals on the second upper nozzles A1064, and the second upper nozzles A1065 face the upper conveyor belt A101, the second upper nozzles A1064, the second lower The spray pipes A1062 are all in communication with the high-pressure water pipes, the bottom of the second water tank A1061 is connected with the second sewage pipe A1066 connected with it, the end of the second sewage pipe A1066 is connected with a pool A1067, and the water pool A1067 is provided with a water inlet A and The water outlet A, the water inlet A is connected with the end of the second sewage pipe A1066, the water outlet A is connected to the water diversion pipe A1068, the water diversion pipe A1068 is provided with a water pump A1069, and the ends of the water diversion pipe A1068 are respectively connected to the first The upper nozzle A1054 and the first lower nozzle A1052 are connected;

The peeling device 2 includes an airtight outer cylinder B201 and a drive motor B202. A turntable B203 is arranged inside the outer cylinder B201. The outer diameter of the turntable B203 matches the inner diameter of the outer cylinder B201. The turntable The center position of the lower surface of B203 is fixed with a rotating shaft B204. The lower end of the rotating shaft B204 extends outside the outer cylinder B201. The output shaft of the driving motor B202 is connected with the lower end of the rotating shaft B204. The inside of the barrel B201 is divided into a peeling cavity B2011 and a water storage cavity B2012. The peeling cavity B2011 is provided with a water spray head B205, and the water spray head B205 is located above the turntable B203 and faces the turntable B203. The water spray head B205 is connected with a drainage pipe B206, the drainage pipe B206 is provided with a shut-off valve B207, the drainage pipe B206 is connected with a high-pressure water pipe, and the wall of the outer cylinder B201 is provided with a discharge port B208. The discharge port B208 is located above the horizontal plane of the turntable B203, and the peeling cavity B2011 is provided with an annular sleeve B209, the outer diameter of the annular sleeve B209 matches the inner diameter of the outer cylinder B201, and the annular sleeve B209 The inner wall surface of B209 is a grinding surface, and the upper end of the annular sleeve B209 is provided with a lifting device B210. When the lower end of the annular sleeve B209 is close to the turntable B203, the annular sleeve B209 will block the discharge port B208. When the annular sleeve B209 goes up When moving to the highest point, the discharge port B208 communicates with the peeling cavity B2011, and the turntable B203 is provided with a plurality of water holes B211, and the water holes B211 connect the peeling cavity B2011 with the water storage cavity B2012. The bottom of the outer cylinder B201 is provided with a drain port B212, the drain port B212 is connected with the first sewage pipe B213, the first sewage pipe B213 is provided with a first conduction valve B214, and the end of the first sewage pipe B213 A closed transition water tank B215 is connected, and the bottom of the transition water tank B215 is connected with a second sewage pipe B216 communicating with it. The second sewage pipe B216 is provided with a second conduction valve B217. The outer cylinder B201 A transition cylinder B218 is arranged above, the lower end of the transition cylinder B218 is in sealing connection with the upper end of the outer cylinder B201 and a first control valve B219 is arranged at the lower end of the transition cylinder B218, and a first control valve B219 is arranged at the upper end of the transition cylinder B218. Two control valves B220;

The slicing device 3 includes an airtight casing C301, and the casing C301 is provided with a conveyor belt C302, a driven roller C303, a driving roller C304, a first driving motor C305, a driving roller C306, and a second driving motor C307. The passive drum C303 and the driving drum C304 tighten the conveyor belt C302, the driving motor C305 is used to rotate the driving drum C304, the driving roller C306 is located above the conveyor belt C302, and the second driving motor C307 is used to rotate the driving roller C306. A plurality of annular blades C308 are sheathed on the drive roller C306, and the plurality of annular blades C308 are arranged parallel to each other. The surface of the conveyor belt C302 is provided with a layer of buffer pad C309, and the surface of the buffer pad C309 is provided with a plurality of knife grooves. C310, the number of the sipe C310 is the same as the number of the annular blade C308 and the positions correspond to each other. The blade of the annular blade C308 is located in the sipe C310, and the top of the housing C301 has a feed port C311. The feed port C311 and the discharge port B208 are sealed and connected through the feed pipe C312. The feed port C311 is connected with a guide groove C316. One end of the feed guide groove C316 is connected to the feed port C311, and the other end extends to the conveyor belt Above C302, a discharge pipe C313 is provided on the outside of the passive roller C303, one end of the discharge pipe C313 extends to the outside of the passive roller C303 and is in contact with the buffer pad C309, and the other end extends to the outside of the housing C301. The end of the discharge pipe C313 is provided with a shut-off valve C314;

The curing device 4 includes a steam generator D401, an inner cylinder D402 and an outer cylinder D403, the inner cylinder D402 is arranged in the outer cylinder D403, and a closed airtight space is formed between the outer cylinder D403 and the inner cylinder D402. The interlayer space D404, the inner cylinder wall is provided with a steam hole D405, the steam generator D401 communicates with the interlayer space D404 through a steam pipe D, and the upper end of the inner cylinder D402 is provided with a first stop valve D406 , the lower end of the inner cylinder D402 is provided with a second stop valve D407, the upper end of the inner cylinder D402 is connected with a transition cylinder D408, the upper end of the transition cylinder D408 is connected with a hopper D409, and the discharge of the hopper D409 The mouth is provided with a third stop valve D410, and the feed port of the hopper D409 is sealed with the end of the discharge pipe C313;

The cooling device 5 includes an airtight vacuum box E501, a vacuum pump E502 is connected to the vacuum box E501, a discharge port E503 is arranged at the bottom of the vacuum box E501, and a discharge port E503 is sealed and connected with a The first transition cylinder E504, the upper end of the first transition cylinder E504 is provided with a first shut-off valve E505, the lower end of the first transition cylinder E504 is provided with a second shut-off valve E506, above the vacuum box E501 A second transition cylinder E507 is provided, the lower end of the second transition cylinder E507 is sealingly connected with the vacuum box E501 and communicated with the inside of the vacuum box E501, and the lower end of the second transition cylinder E507 is provided with a third cut-off Valve E508, the upper end of the second transition cylinder E507 is in sealing connection with the lower end of the inner cylinder D402;

The microwave drying device 7 includes a closed box G701, in which a microwave transmitter G702, a microwave receiver G703, and a heating cylinder G704 are arranged, and the upper end of the heating cylinder G704 is sealed and connected with a transition cylinder G705, the upper end of the transition cylinder G705 extends out of the box G701 and is sealed and connected with the end of the first transition cylinder E504, the lower end of the heating cylinder G704 extends outside the box G701 and is in the heating cylinder The lower end of G704 is provided with a second cut-off valve G707, and the microwave transmitter G702 and microwave receiver G703 are respectively arranged on both sides of the heating cylinder G704;

The frying device 6 includes a box body E601 containing high-temperature cooking oil. The box body E601 is provided with a first conveyor belt E602, a first passive roller E603, a first driving roller E604, and a first conveyor belt E602. The surface of a conveyor belt E602 is provided with a plurality of first scraper plates 605, and the plurality of first scraper plates 605 are arranged parallel to each other and perpendicular to the conveying direction of the first conveyor belt E602, and the first conveyor belt E602 is arranged horizontally And the first conveyor belt E602 on the upper layer is submerged in high-temperature edible oil, the lower end of the heating cylinder G704 faces the first conveyor belt E602, the first passive roller E603 and the first driving roller E604 tighten the first conveyor belt E602, and the second A driving roller E604 is connected with a first driving motor E606 for making it rotate. A second driving roller E607 and a second conveyor belt E608 are also arranged in the box E601. The second driving roller E607 is connected with a The second drive motor E609, the second driven roller E610 is arranged above the box E601, the second driven roller E607 is arranged at the bottom right of the first driven roller E603, and the second driven roller E610 is arranged on the second drive On the right side of the roller E607, the second passive roller E610 and the second driving roller E607 tighten the second conveyor belt E608, and the surface of the second conveyor belt E608 is provided with multiple second scrapers 611. The second scraper 611 is arranged parallel to each other and is perpendicular to the conveying direction of the second conveyor belt E608. The sum of the height of the first scraper 605 and the height of the second scraper 611 is equal to the first driven roller E603 and the height of the second scraper 611. The minimum distance between the second driving rollers E607, the third driving roller E612 is arranged on the lower right of the second driven roller E610, the third driven roller E613 and the third conveyor belt E614 are arranged on the upper right of the box E601 , the third conveyor belt E614 is arranged horizontally, and the third driven roller E613 and the third driving roller E612 tighten the third conveyor belt E614;

The seasoning device 8 includes a seasoning drum 801, the third passive drum E613 is located in the seasoning drum 801, the seasoning drum 801 is arranged obliquely from left to right, and the left side of the seasoning drum 801 is provided with a funnel for seasoning 802, the outlet of the funnel 802 faces the third conveyor belt E614.

The potato chip production device consists of a cleaning device 1, a peeling device 2, a slicing device 3, a ripening device 4, a cooling device 5, a microwave drying device 7, a frying device 6, and a seasoning device 8, which are arranged in sequence. Except seasoning device 8, other devices all work in the airtight environment, and are all sealed connection between each device, make potato except cleaning process, frying process, seasoning process, other processes are all carried out in the sealed environment, from Ensure that the probability of potato chips being in contact with oxygen during the entire processing process is greatly reduced, which can effectively prevent the polyphenol oxidase (PPO) in the potato from contacting oxygen in the air during the processing process, avoid oxidative polymerization, and effectively prevent potato browning , so as to ensure that the quality of the final potato chips produced is high.

When cleaning potatoes, you only need to place the potatoes to be processed on the conveyor belt A101, and the conveyor belt A101 drives the potatoes to move along the conveyor belt A101 during the moving process. The secondary cleaning tank A106, when the potatoes pass through the primary cleaning tank A105, the high-pressure water in the first lower spray pipe A1052 below the potatoes is sprayed upwards from the first lower nozzle A1053 and sprayed on the potatoes, and the first upper spray tube located above the potatoes The high-pressure water in the pipe A1054 is sprayed downward from the first upper nozzle A1055 onto the potatoes, so that the whole potatoes can be sprayed and cleaned, and the potatoes after the first cleaning then enter the secondary cleaning tank A106. At this time, The high-pressure water in the second lower nozzle A1062 below the potato is sprayed upwards from the second lower nozzle A1063 and sprayed on the potato, and the high-pressure water in the second upper nozzle A1064 above the potato is downward from the second upper nozzle A1065 Spray on the potatoes, so that the whole potatoes can be sprayed and cleaned. After the second washing, the potatoes become very clean. At the same time, the water after the first washing falls into the first water tank A1051. Most of the soil residues on the potato skin are washed and dropped into the first water tank A1051, so the water in the first water tank A1051 is relatively turbid, and it is directly discharged from the first sewage pipe A1056, and the water after the second washing falls into the The second water tank A1061, due to the second cleaning, the potato skin only remains a little soil residue after the first cleaning, so the water in the second water tank A1061 is also relatively clear and can also be used to clean the potatoes once. Therefore, the second The water in the tank A1061 is discharged into the pool A1067 through the second sewage pipe A1066 connected at the bottom, and then the water in the pool A1067 is sent into the first upper nozzle A1054 and the first lower nozzle A1052 through the water diversion pipe A1068 by the water pump A1069, In this way, the potatoes are washed once, which reduces water consumption and saves costs.

In order to prevent the residual soil in the pool A1067 from blocking the water pump A1069 or the water diversion pipe A1068, multiple filter screens A107 are arranged in the pool A1067, and the multiple filter screens A107 are sequentially arranged between the water inlet A and the water outlet A. In this way, The water in the pool A1067 is first filtered by multiple filter screens A107, and then the water in the pool A1067 is sent to the first upper nozzle A1054 and the first lower nozzle A1052 through the water diversion pipe A1068 by the water pump A1069, so that the water in the pool A1067 can be effectively avoided. The residue soil inside will block the water pump A1069 or the water diversion pipe A1068 to ensure the smooth progress of the cleaning process.

In addition, in order to ensure the filtering effect, the mesh sizes of the plurality of filter screens A107 are successively reduced. The filter screen A107 with the largest mesh size is located at the water inlet A, and the filter screen A107 with the smallest mesh size is located at the water outlet A.

In order to facilitate feeding, a hopper A108 is arranged above the conveyor belt A101, and the outlet of the hopper A108 faces the conveyor belt A101, and the hopper A108 is located outside the primary cleaning tank A105, so that only the potatoes that need to be cleaned are dropped into the hopper A108 The operation is very convenient; at the same time, in order to facilitate the material receiving, the outer side of the secondary cleaning tank A106 is provided with a material receiving tank A109, and the upper end of the transition cylinder B218 is sealed and connected with the lower end of the material receiving tank A109. A material guide trough A110 is connected to the material trough A109, one end of the material guide trough A110 is connected with the material receiving trough A109, and the other end extends to the outside of the passive roller A102 and contacts the conveyor belt A101, and the cleaned potatoes are transported along the conveyor belt. When A101 moves to the end of the material guide trough A110, it will fall into the material receiving trough A109 along the material guide trough A110. The whole process is automatically carried out without manual handling, saving time and effort.

When performing peeling treatment, first open the second control valve B220 set on the upper end of the transition cylinder B218, at this time, the cleaned potatoes in the receiving tank A109 fall into the transition cylinder B218, then close the second control valve B220, and then Open the first control valve B219 arranged at the lower end of the transition cylinder B218, so that the potatoes in the transition cylinder B218 fall into the peeling cavity B2011. Blocked by the ring sleeve B209, the drive motor B202 drives the rotating shaft B204 to rotate and then drives the turntable B203 to rotate. Since the upper surface of the turntable B203 is wave-shaped, the turntable B203 will throw up the potatoes and contact the inner surface of the ring sleeve B209 during the rotation. and friction, because the inner wall surface of the annular sleeve B209 is a grinding surface, in the process of the contact friction between the potato and the annular sleeve B209, the skin of the potato will be rubbed off, and at the same time, the water spray head B205 provided in the peeling cavity B2011 will spray A high-pressure water flow is used to rinse the potatoes, and the wiped potato skins are washed off the surface of the potatoes, and then flow into the water storage cavity B2012 through the multiple water holes B211 provided on the turntable B203. When the water storage cavity B2012 When there is too much water in the tank, open the first conduction valve B214 on the first sewage pipe B213, the water in the water storage cavity B2012 flows into the transition water tank B215 along the first sewage pipe, and then close the first conduction valve B214 , open the second conduction valve B217 provided on the second sewage pipe B216, the water in the transition water tank B215 is discharged along the second sewage pipe B216, and when the potato skin is removed, use the lifting device B210 to raise the annular sleeve B209, Make the discharge port B208 communicate with the peeling cavity B2011. At this time, if the turntable B203 continues to rotate, the peeled potatoes will be thrown out from the discharge port B208 and fall into the housing C301 along the feed pipe C306. Device 2 has a good peeling effect, and at the same time, the potatoes can be separated from the skin. Furthermore, by setting the transition cylinder B218 and the transition water tank B215, the feed port C304 and the discharge port B208 are sealed and connected through the feed pipe C306, so that The inside of the outer cylinder B201 is hardly in contact with the outside air, which can effectively prevent the polyphenol oxidase (PPO) in the potato from contacting the oxygen in the air during the peeling process, avoid oxidative polymerization, and effectively prevent the potato from browning, thus ensuring The resulting potato chips are of higher quality.

In order to further prevent the polyphenol oxidase (PPO) in the potato from being in contact with the oxygen in the air in the peeling process, and to avoid oxidative polymerization, the outer cylinder B201 is connected with nitrogen gas for charging nitrogen into the outer cylinder B201 Tube B221; During the peeling process, using nitrogen as a protective gas can effectively prevent potato browning, thereby ensuring that the final potato chips produced are of high quality. At the same time, because nitrogen contains the most proportion in the air, it is easy to obtain and low in cost.

When slicing, the potatoes thrown out from the discharge port B208 enter the casing C301 from the feed port C311 along the feed pipe C312, and then slide down to the conveyor belt C302 along the feed guide C316, and the first drive motor C305 makes The driving drum C304 rotates to make the conveyor belt C302 move, and the conveyor belt C302 drives the potatoes to move during the moving process. When the potatoes pass under the driving roller C306, the second driving motor C307 makes the driving roller C306 rotate at a high speed, and then the driving roller C306 goes up. The set of multiple ring blades C308 rotates at high speed. When the ring blade C308 rotates at high speed, it will cut the passing potatoes into slices. The sliced potato slices continue to move under the drive of the conveyor belt C302, and then fall into the discharge pipe. In C313, the whole slicing process can be carried out continuously, and the slicing effect is better at the same time. In addition, since the feed port C311 and the discharge port B208 are sealed and connected through the feed pipe C312, the end of the discharge pipe C313 is provided with a stop valve C314, which can make The inside of the shell C301 is hardly in contact with the outside air, which can effectively prevent the polyphenol oxidase (PPO) in the potato from contacting the oxygen in the air during the slicing process, avoid oxidative polymerization, and effectively prevent the potato from browning, thus ensuring the final production The quality of the potato chips is higher.

Further, in order to prevent the potato slices from being stuck between the annular blades C308, a scraper C317 is arranged on the inner wall of the housing C301, one end of the scraper C317 is fixed on the inner wall of the housing C301, and the other end There are multiple gaps, the number of the gaps is the same as the number of the ring blades C308 and the positions correspond to each other. The blades of the ring blades C308 are located in the gaps, so that even if the potato slices are stuck between the ring blades C308, they can be scraped. The material plate C317 scrapes it off to prevent the potato slices from being stuck between the annular blades C308 and affecting production.

In addition, in order to further prevent the polyphenol oxidase (PPO) in the potato from contacting with the oxygen in the air during the slicing process and avoid oxidative polymerization, the housing C301 is connected with nitrogen gas for filling the housing C301 with nitrogen. Tube C315; During the slicing process, using nitrogen as a protective gas can effectively prevent potato browning, thereby ensuring that the final potato chips produced are of high quality. At the same time, because nitrogen contains the most proportion in the air, it is easy to obtain and low in cost.

When potatoes are ripened, first open the cut-off valve C314, so that the potato slices in the discharge pipe C313 fall into the hopper D409, then close the stop valve C314, and open the third cut-off valve D410 arranged at the discharge port of the hopper D409, so that The potato slices in the hopper D409 fall into the transition cylinder D408, then close the third shut-off valve D410, and then open the first shut-off valve D406, so that the potato slices in the transition cylinder D408 fall into the inner cylinder D402, and close the first shut-off valve D406. Stop valve D406, at this time, the steam generator D401 works to generate high-temperature water vapor, which flows into the interlayer space D404 along the steam pipe D, and then the high-temperature steam enters the inner cylinder D402 through the steam through hole D405 to contact the potato chips and The potato slices are heated and ripened. When the potato slices are heated to ripen, the second shut-off valve D407 provided at the lower end of the inner cylinder D402 is opened, and the ripened potato slices fall into the second transition cylinder E507. The ripening device 4 utilizes The steam ripens the potatoes, which can make the potatoes ripen quickly and the ripening effect is high. At the same time, the whole ripening process is carried out automatically without manual handling of the potatoes. In addition, by setting the transition cylinder D408, the inside of the outer cylinder D403 can hardly be in contact with the outside air. , can effectively prevent the polyphenol oxidase (PPO) in the potato from contacting with the oxygen in the air during the ripening process, avoid oxidative polymerization, and effectively prevent the browning of the potato, so as to ensure that the quality of the final potato chips produced is high.

In addition, in order to further prevent the polyphenol oxidase (PPO) in the potato from contacting the oxygen in the air during the ripening process and avoid oxidative polymerization, the outer cylinder D403 is connected with a device for charging nitrogen into the outer cylinder D403. Nitrogen pipe D411: During the curing process, using nitrogen as a protective gas can effectively prevent potatoes from browning, thus ensuring that the final potato chips produced are of high quality. At the same time, because nitrogen contains the most proportion in the air, it is easy to obtain and low in cost.

When cooling the potatoes, first open the third cut-off valve E508 arranged at the lower end of the second transition cylinder E507, so that the cooked high-temperature potato slices fall into the vacuum box E501, then close the third cut-off valve, and turn on the vacuum pump E502, Vacuum the inside of the vacuum box E501, and the high-temperature potato slices are rapidly cooled in a vacuum environment. When the potato slices are cooled to room temperature, the first stop valve E is opened to make the potato slices in the vacuum box E501 fall into the first transition Inside the barrel E504, then close the first shut-off valve E, and then open the second shut-off valve, the potato slices fall into the material guide trough F612, and the cooling device 5 cools the potatoes in a vacuum environment, because the temperature is very low in a vacuum environment , can make the potatoes cool quickly, and the cooling effect is good. At the same time, in a vacuum environment, it can effectively prevent the polyphenol oxidase (PPO) in the potatoes from contacting the oxygen in the air during the cooling process, avoid oxidative polymerization, and effectively prevent the potato Browning, so as to ensure that the final potato chips produced are of high quality.

When microwave heating and drying potato chips, first open the second cut-off valve E506, so that the potato chips in the first transition cylinder E504 fall into the transition cylinder G705 and then fall into the heating cylinder G704, and then close the second cut-off valve. Valve E506, open the microwave transmitter G702 and the microwave receiver G703 at this time, the microwave passes through the heating cylinder G704, and heats and dries the potato slices in the heating cylinder G704. Device 7 uses microwaves to dry and heat potato slices, which can quickly remove the moisture contained in potato slices, and the drying effect is good. At the same time, by setting the transition cylinder G705, the entire drying and heating process can be carried out in a closed environment, which can effectively Preventing the polyphenol oxidase (PPO) in the potato from contacting the oxygen in the air during the drying and heating process, avoiding oxidative polymerization, can effectively prevent the browning of the potato, so as to ensure the high quality of the final potato chips produced.

In addition, in order to further prevent the polyphenol oxidase (PPO) in the potato from contacting with the oxygen in the air during the drying process and avoid oxidative polymerization, the box G701 is connected with a nitrogen pipe for charging nitrogen into the box G701 G714, in the microwave heating and drying process, using nitrogen as a protective gas can effectively prevent potato browning, thereby ensuring that the final potato chips produced are of high quality. At the same time, because nitrogen contains the most proportion in the air, it is easy to obtain and low in cost.

When the drying is finished, fry the dried potato chips. When frying the potato chips, first open the second shut-off valve G707 to make the dried potato chips in the heating cylinder G704 fall to the first conveyor belt E602 In the gap between the first scrapers 605 arranged above, because the first conveyor belt E602 on the upper layer is submerged by high-temperature cooking oil, the dried potato chips fall on the first conveyor belt E602 and start to be fried, and at the same time, The first driving motor E606 drives the first driving drum E604 to rotate, and the first driving drum E604 drives the first conveyor belt E602 to rotate and at the same time conveys the potato chips to the second conveyor belt E608, and the potato chips are gradually fried to golden yellow during the conveying process , when the potato slices move to the right end of the first conveyor belt E602, they drop from the first conveyor belt E602 to the gap of the second scraper 611 provided on the second conveyor belt E608, and then the potato slices are transported on the inclined second conveyor belt. The high-temperature cooking oil is gradually separated from the conveying belt E608, and the excess cooking oil on the surface of the potato chips is drained. When the potato chips move to the right end of the second conveyor belt E608, they fall from the second conveyor belt E608 to the third conveyor belt E614 On the top, the potatoes move into the seasoning drum 801 under the conveyance of the third conveyor belt E614. At the same time, when the potatoes move on the third conveyor belt E614, the funnel 802 equipped with seasoning continuously sprinkles seasoning on the passing potato slices, and the potato slices are seasoned. Finish seasoning treatment after drum 801 and can be packed into bag.

In addition, in order to collect processed fried potato chips conveniently, a collecting tank 803 is provided under the right end of the seasoning drum 801 .

Claims (5)

1. A potato chip production device, characterized in that: comprise a cleaning device (1), a peeling device (2), a slicing device (3), a ripening device (4), a cooling device (5), a microwave drying device arranged in sequence Device (7), frying device (6), seasoning device (8); The cleaning device (1) comprises a conveyor belt A (101), a driven drum A (102), a driving drum A (103), a driving motor A (104), a primary cleaning tank A (105), a secondary cleaning tank A ( 106), the passive drum A (102) and the driving drum A (103) tighten the conveyor belt A (101), the driving motor A (104) is used to rotate the driving drum A (103), and the primary cleaning tank A (105) and secondary cleaning tank A (106) are set along the running direction of the conveyor belt A (101) in sequence, the conveyor belt A (101) is a mesh structure, and the primary cleaning tank A (105) includes the first cleaning tank A (105) A water tank A (1051), the first water tank A (1051) is located between the upper conveyor belt A (101) and the lower conveyor belt A (101), the first water tank A (1051) is provided with a plurality of mutual The first lower nozzle A (1052) arranged in parallel, the first lower nozzle A (1052) is provided with a plurality of first lower nozzles A (1053) at intervals, and the first lower nozzle A (1053) faces Conveyor belt A (101) on the upper layer, a plurality of first upper nozzles A (1054) are arranged above the first water tank A (1051), and multiple first upper nozzles A (1054) are arranged at intervals. A first upper nozzle A (1055), the first upper nozzle A (1055) faces the upper conveyor belt A (101), and the bottom of the first water tank A (1051) is connected with the first sewage pipe A ( 1056); the secondary cleaning tank A (106) includes a second water tank A (1061), and the second water tank A (1061) is located between the conveyor belt A (101) on the upper floor and the conveyor belt A (101) on the lower floor In the second water tank A (1061), there are multiple second lower nozzles A (1062) arranged parallel to each other, and a plurality of second lower nozzles A are arranged at intervals on the second lower nozzles A (1062). (1063), the second lower nozzle A (1063) faces the upper conveyor belt A (101), and a plurality of second upper nozzles A (1064) are arranged above the second water tank A (1061), so A plurality of second upper nozzles A (1065) are arranged at intervals on the second upper nozzle A (1064), and the second upper nozzles A (1065) face the upper conveyor belt A (101). Both A (1064) and the second lower spray pipe A (1062) are in communication with the high-pressure water pipe, and the bottom of the second water tank A (1061) is connected with a second sewage pipe A (1066) communicating with it. The second sewage pipe A The end of (1066) is connected with a pool A (1067), the pool A (1067) is provided with a water inlet A and a water outlet A, the water inlet A communicates with the end of the second sewage pipe A (1066), and the outlet A water diversion pipe A (1068) is connected to the water outlet A, and a water pump A (1069) is arranged on the water diversion pipe A (1068). one The lower nozzle A (1052) is connected; The peeling device (2) includes an airtight outer cylinder B (201), a drive motor B (202), and a turntable B (203) is arranged inside the outer cylinder B (201), and the turntable B (203 ) matches the inner diameter of the outer cylinder B (201), the center of the lower surface of the turntable B (203) is fixed with a rotating shaft B (204), and the lower end of the rotating shaft B (204) extends to the outer cylinder B ( 201), the output shaft of the drive motor B (202) is connected to the lower end of the rotating shaft B (204), the upper surface of the turntable B (203) is wave-shaped, and the turntable B (203) connects the outer cylinder B (201) The interior of the peeling cavity B (2011) is divided into a water storage cavity B (2012), the peeling cavity B (2011) is provided with a water spray head B (205), and the water spray head B ( 205) Located above the turntable B (203) and facing the turntable B (203), the water spray head B (205) is connected with a drainage pipe B (206), and the drainage pipe B (206) is provided with a shut-off valve B (207 ), the drainage pipe B (206) is connected to the high-pressure water pipe, and the wall of the outer cylinder B (201) is provided with a discharge port B (208), and the discharge port B (208) is located on the turntable B (203) above the horizontal plane, the peeling cavity B (2011) is provided with an annular sleeve B (209), and the outer diameter of the annular sleeve B (209) is the same as that of the outer cylinder B (201). The inner diameter is matched, the inner wall surface of the annular sleeve B (209) is a grinding surface, the upper end of the annular sleeve B (209) is provided with a lifting device B (210), when the lower end of the annular sleeve B (209) is close to the turntable B (203), the annular sleeve B (209) blocks the discharge port B (208), and when the annular sleeve B (209) moves up to the highest point, the discharge port B (208) and the peeling cavity B (2011) is connected, and the turntable B (203) is provided with a plurality of water holes B (211), and the water holes B (211) connect the peeling cavity B (2011) with the water storage cavity B ( 2012), the bottom of the outer cylinder B (201) is provided with a drain port B (212), and the drain port B (212) is connected with a first sewage pipe B (213), and the first sewage pipe B (213) A first pilot valve B (214) is arranged on the top, and the end of the first sewage pipe B (213) is connected with a closed transition water tank B (215), and the bottom of the transition water tank B (215) is connected with a The second blowdown pipe B (216), the second blowdown pipe B (216) is provided with a second pilot valve B (217), and the transition cylinder B (218) is provided above the outer cylinder B (201). ), the lower end of the transition cylinder B (218) is sealingly connected with the upper end of the outer cylinder B (201) and a first control valve B (219) is arranged at the lower end of the transition cylinder B (218), the transition cylinder The upper end of B (218) is provided with a second control valve B (220); The slicing device (3) includes an airtight casing C (301), and the casing C (301) is provided with a conveyor belt C (302), a driven roller C (303), a driving roller C (304), a second A driving motor C (305), a driving roller C (306), a second driving motor C (307), and the driven drum C (303) and the driving drum C (304) tighten the conveyor belt C (302) to drive The motor C (305) is used to rotate the driving drum C (304), the driving roller C (306) is located above the conveyor belt C (302), and the second driving motor C (307) is used to make the driving roller C (306) Rotate, said drive roller C (306) is sheathed with a plurality of annular blades C (308), and a plurality of annular blades C (308) are arranged in parallel with each other, and the surface of described conveyer belt C (302) is provided with one deck buffer pad C (309), the surface of the buffer pad C (309) is provided with a plurality of sipe C (310), the number of the sipe C (310) is the same as that of the annular blade C (308) and the positions are one by one Correspondingly, the knife tip of the annular blade C (308) is located in the knife groove C (310), and the top of the housing C (301) has a feed port C (311), and the feed port C (311) is connected to the The discharge port B (208) is sealed and connected by the feed pipe C (312), and the feed port C (311) is connected with a guide groove C (316), and one end of the feed guide groove C (316) is connected to the The feed port C (311), the other end extends to the top of the conveyor belt C (302), and the outside of the passive drum C (303) is provided with a discharge pipe C (313), and the discharge pipe C (313) One end extends to the outside of the passive drum C (303) and is in contact with the buffer pad C (309), the other end extends to the outside of the casing C (301), and the end of the discharge pipe C (313) is provided with a stop valve C (314); The curing device (4) includes a steam generator D (401), an inner cylinder D (402) and an outer cylinder D (403), and the inner cylinder D (402) is arranged in the outer cylinder D (403) , an airtight interlayer space D (404) is formed between the outer cylinder D (403) and the inner cylinder D (402), and steam holes D (405) are arranged on the cylinder wall of the inner cylinder, The steam generator D (401) communicates with the interlayer space D (404) through the steam pipe D, and the upper end of the inner cylinder D (402) is provided with a first stop valve D (406), and the inner cylinder D (402) The lower end is provided with a second cut-off valve D (407), the upper end of the inner cylinder D (402) is connected with a transition cylinder D (408), and the upper end of the transition cylinder D (408) is connected with a hopper D (409 ), the discharge port of the hopper D (409) is provided with a third stop valve D (410), and the feed port of the hopper D (409) is sealed with the end of the discharge pipe C (313); The cooling device (5) includes an airtight vacuum box E (501), the vacuum pump E (502) is connected to the vacuum box E (501), and the bottom of the vacuum box E (501) is provided with an outlet The material outlet E (503), the first transition cylinder E (504) is sealingly connected to the material outlet E (503), and the upper end of the first transition cylinder E (504) is provided with a first cut-off valve E (505), the lower end of the first transition cylinder E (504) is provided with a second shut-off valve E (506), and the top of the vacuum box E (501) is provided with a second transition cylinder E (507), The lower end of the second transition cylinder E (507) is sealingly connected with the vacuum box E (501) and communicated with the inside of the vacuum box E (501), and the lower end of the second transition cylinder E (507) is provided with The third cut-off valve E (508), the upper end of the second transition cylinder E (507) is in sealing connection with the lower end of the inner cylinder D (402); The microwave drying device (7) comprises an airtight casing G (701), in which a microwave transmitter G (702), a microwave receiver G (703), a heating cylinder G ( 704), the upper end of the heating cylinder G (704) is sealed with a transition cylinder G (705), and the upper end of the transition cylinder G (705) extends outside the box G (701) and is connected with the first transition The end of the cylinder E (504) is sealed and connected, the lower end of the heating cylinder G (704) extends out of the box G and a second shut-off valve G (707) is arranged at the lower end of the heating cylinder G (704), The microwave transmitter G (702) and the microwave receiver G (703) are respectively arranged on both sides of the heating cylinder G (704); The frying device (6) includes a box body E (601), the box body E (601) is filled with high-temperature edible oil, and the box body E (601) is provided with a first conveyor belt E (602) , the first passive drum E (603), the first driving drum E (604), the surface of the first conveyor belt E (602) is provided with a plurality of first scrapers (605), and a plurality of first scrapers ( 605) are arranged parallel to each other and perpendicular to the conveying direction of the first conveyor belt E (602), the first conveyor belt E (602) is horizontally arranged and the first conveyor belt E (602) on the upper layer is submerged by high-temperature cooking oil, The lower end of the heating cylinder G (704) faces the first conveyor belt E (602), and the first driven roller E (603) and the first driving roller E (604) tighten the first conveyor belt E (602), The first driving drum E (604) is connected with a first driving motor E (606) for making it rotate, and the second driving drum E (607) and the second conveyor belt E are also arranged in the box body E (601). (608), the second driving drum E (607) is connected with a second driving motor E (609) for making it rotate, and a second passive drum E (610) is arranged above the box body E (601), The second driving roller E (607) is arranged on the lower right side of the first driven roller E (603), and the second driven roller E (610) is arranged on the right side of the second driving roller E (607). The passive roller E (610) and the second driving roller E (607) tighten the second conveyor belt E (608), and the surface of the second conveyor belt E (608) is provided with multiple second scrapers (611 ), a plurality of second scraper plates (611) are arranged parallel to each other and perpendicular to the conveying direction of the second conveyor belt E (608), the height of the first scraper plate (605) is the same as that of the second scraper plate ( The sum of the heights of 611) is equal to the minimum distance between the first passive roller E (603) and the second driving roller E (607), and the third driving roller E is arranged on the lower right side of the second passive roller E (610) (612), the upper right of the box E (601) is provided with a third passive roller E (613), a third conveyor belt E (614), the third conveyor belt E (614) is horizontally arranged, and the third The third conveyor belt E (614) is tightened by the passive drum E (613) and the third driving drum E (612); The seasoning device (8) includes a seasoning drum (801), the third passive drum E (613) is located in the seasoning drum (801), and the seasoning drum (801) is arranged obliquely from left to right, and the seasoning drum The left side of (801) is provided with the funnel (802) that condiment is housed, and the discharge port of described funnel (802) faces the third conveyor belt E (614). 2. The potato chip production device according to claim 1, characterized in that: multiple filter screens A (107) are arranged in the pool A (1067), and multiple filter screens A (107) are sequentially arranged at the water inlet Between A and water outlet A; a hopper A (108) is arranged above the conveyor belt A (101), and the discharge port of the hopper A (108) faces the conveyor belt A (101), and the hopper A (108) is located in a cleaning The outside of the tank A (105); the outside of the secondary cleaning tank A (106) is provided with a receiving tank A (109), and the upper end of the transition cylinder B (218) is sealed with the lower end of the receiving tank A (109) connected, the feed chute A (109) is connected with a feed chute A (110), one end of the feed chute A (110) is connected with the feed trough A (109), and the other end extends to the passive drum A (102) outside and in contact with conveyor belt A (101). 3. The potato chip production device according to claim 1, characterized in that: a scraper C (317) is arranged on the inner wall of the housing C (301), and one end of the scraper C (317) Fixed on the inner wall of the housing C (301), the other end has a plurality of notches, the number of the notches is the same as the number of the annular blade C (308) and the positions correspond to each other, the tip of the annular blade C (308) inside the notch. 4. The potato chip production device according to claim 1, characterized in that: a collecting tank (803) is provided under the right end of the seasoning drum (801). 5. The potato chip production device according to claim 1, characterized in that: the outer cylinder B (201) is connected with a nitrogen pipe B (221) for charging nitrogen into the outer cylinder B (201) ; The housing C (301) is connected with a nitrogen pipe C (315) for charging nitrogen into the housing C (301); the outer cylinder D (403) is connected with a cylinder D (403) A nitrogen pipe D (411) filled with nitrogen; the box G (701) is connected with a nitrogen pipe G (714) for filling nitrogen into the box G (701).