CN212484186U

CN212484186U - Intelligent positive and negative voltage system and intelligent positive and negative voltage electric appliance using same

Info

Publication number: CN212484186U
Application number: CN202020813036.2U
Authority: CN
Inventors: 郑伯昂
Original assignee: Individual
Current assignee: Individual
Priority date: 2020-05-15
Filing date: 2020-05-15
Publication date: 2021-02-05
Anticipated expiration: 2030-05-15

Abstract

The embodiment of the utility model provides a positive negative pressure system of intelligence and intelligent positive negative voltage electricity ware that uses this system is related to, wherein, positive negative voltage electricity ware includes: positive and negative pressure refrigerator, positive and negative pressure washing machine, vacuum dish washing fruit and vegetable cleaning machine, super oxygen washing fume exhauster, positive and negative pressure oven fryer microwave oven, positive and negative pressure fresh-keeping carriage, positive and negative pressure fresh-keeping warehouse and positive and negative pressure module cabinet. The technical principle of the positive and negative pressure system is as follows: the air flow is regulated and controlled by positive and negative pressure, or various effective loads such as ozone, gas catalyst, negative ions, gas-conditioned gas, water and the like are carried, so that the air flows in and out of the positive and negative pressure cabins in sequence or stay in the positive and negative pressure cabins, and the required influence is exerted on the articles in the positive and negative pressure cabins. Therefore, the utility model discloses regulate and control and integrate vacuum, high pressure, ozone, catalyst, gas conditioning fresh-keeping, cryopreservation, anion, disinfection purification, humidification and dehumidification and multiple technologies such as air system water with positive negative pressure system, the combination is applied to positive negative voltage electricity ware, gives electrical apparatus respiratory function, upgrades and renews to current electrical apparatus and traditional technology, has developed a positive negative voltage electricity ware segmentation field.

Description

Intelligent positive and negative voltage system and intelligent positive and negative voltage electric appliance using same

Technical Field

The embodiment of the utility model provides a belong to the electrical apparatus field, especially relate to an intelligence positive negative pressure system and use the positive negative voltage electricity ware of intelligence of this system.

Background

The field of production and living electric appliances is rapidly developed in recent decades, particularly, refrigerators, washing machines and the like are increasingly popularized, however, in recent years, the updating and updating of household electric appliances are unsatisfactory, for example, refrigerators have improved appearance and are very attractive since compression refrigeration type refrigerators appear for more than one hundred years in the first century, various auxiliary functions of the eight doors are added, and the basic storage method of bacteriostasis only by low temperature has no technical breakthrough. The characteristics of vacuum and high pressure are known for a long time, the fruit, vegetable, meat and fish cannot be preserved and are not easy to be rotten by bacterial microorganisms in the vacuum, people are always attracted to store food by using the vacuum, however, oxygen does not exist in the vacuum, the anaerobic respiration of the fruit and vegetable can damage the quality and freshness of the fruit and vegetable, the cell and tissue structure of the fruit, vegetable, meat and fish can be destroyed by too low vacuum pressure, the internal moisture of the fruit, vegetable, meat and fish can be accelerated to escape and dissipate, the quality is reduced, the flavor is lost, and the ginseng is not practically applied to household appliances such as refrigerators because of the advantages and; the high-pressure technology is applied to the fields of freezing and refrigeration and the like, and researches are conducted for many years to prove that the technical problem that the food cannot be reversely damaged due to the generation of the largest ice crystal zone in normal-pressure freezing, unfreezing and freezing preservation by adopting the high-pressure bacteriostasis, high-pressure freezing, high-pressure unfreezing and high-pressure unfreezing refrigeration technology and the coordination configuration of pressure and temperature can be solved, the high-pressure freezing and unfreezing speed is much higher than that under normal pressure, however, a high-level vacuum and ultrahigh-pressure space is manufactured in household appliances, the problems that the existing material and technical level are difficult to realize and the cost is too high to adapt to the household appliances are solved, and the vacuum and high-pressure technology is not practically applied to the production. Superoxide (ozone) can rapidly sterilize, disinfect and degrade pesticide residues and organic dirt, inhibit the activity of enzyme, keep fruits, vegetables, meat and fish fresh, purify air and the like, and attract people to apply the superoxide (ozone) to production and life, however, the contact with superoxide can harm human health, and no ideal solution is available for applying the superoxide to electric appliances, so that the superoxide is not actually applied to household appliances such as refrigerators, washing machines and the like; controlled atmosphere preservation is a relatively advanced fruit and vegetable preservation method at present, by regulating and controlling the concentration proportion of oxygen, nitrogen and carbon dioxide in a storage space, the respiration of fruits and vegetables is inhibited, the consumption of organic substances is reduced, the original excellent flavor and aromatic smell are kept, metabolism is delayed, the breeding and propagation of certain pathogenic bacteria and the occurrence of physiological diseases are controlled, the preservation effect is much better than that of common refrigeration, the preservation period is obviously prolonged, the power consumption is lower, however, the controlled atmosphere storage needs an airtight space capable of resisting a certain pressure, mixed gas with the optimal proportion and the optimal concentration is produced and input into the storage space, meanwhile, waste gas is discharged timely, and the expiration and storage of the controlled atmosphere gas needs the accurate maintenance of a circulating system, and the like, which cannot be done by common refrigerators; actually, the refrigerator in the prior art has a fatal defect influencing fresh keeping, which is not solved or found or regarded by people till now, namely, the refrigerator has no ventilation function, air in the refrigerator is polluted quickly, the fresh keeping effect is influenced, and the opening and closing of the refrigerator door has a certain ventilation effect but is not thorough and unreliable; all the above disadvantages are basically solved in the embodiments of the present invention. Washing machine, wash dishes and domestic appliance technologies such as fruit vegetables cleaning machine, smoke ventilator and microwave oven also all face the problem of upgrading and upgrading, the utility model aims at providing a novel technique and practical method, solve above problem, carry out technical renewal and upgrading for current some production life electrical apparatus especially domestic appliance.

SUMMERY OF THE UTILITY MODEL

The utility model discloses positive negative pressure system of intelligence and the positive negative pressure electricity ware of intelligence that uses this system regulate and control and integrate vacuum, high pressure, superoxide, catalyst, the multiple technologies such as fresh-keeping, anion, humidification, dehumidification, disinfection, air purification, air system water and cryopreservation with positive negative pressure system of intelligence, during the positive negative pressure electricity ware of intelligence is used in the combination, give electrical apparatus respiratory function, let electrical apparatus live, upgrade and upgrade to current electrical apparatus and traditional technique, developed a positive negative pressure electricity ware segmentation field. The embodiment of the utility model provides an in used intelligent positive negative pressure system's electrical equipment, transportation carriage container, storage warehouse, unified brief for short: an intelligent positive and negative piezoelectric device; this the embodiment of the utility model provides an in the embodiment positive negative voltage electricity ware of intelligence, include: the intelligent positive and negative pressure refrigerator, the intelligent positive and negative pressure washing machine, the intelligent vacuum dish washing fruit and vegetable cleaning machine, the intelligent super oxygen washing range hood, the intelligent positive and negative pressure oven fryer microwave oven, the intelligent positive and negative pressure fresh-keeping carriage, the intelligent positive and negative pressure fresh-keeping warehouse and the intelligent positive and negative pressure module cabinet. In order to achieve the above object, the embodiment of the present invention adopts the following technical solutions:

the embodiment of the utility model provides an intelligence positive negative pressure system and use intelligent positive negative pressure electric appliance of this system, positive negative pressure uses atmospheric pressure atm or local instant atmospheric pressure to make zero standard's positive atmospheric pressure and negative pressure promptly, in the embodiment of the utility model, positive atmospheric pressure is also known as: positive pressure or high pressure, negative pressure is also called: negative pressure or vacuum, positive and negative pressure is also called: ZhengFuYa or zheng negative pressure or + -atm or + -at, the related names mentioned above are the same and are common in the embodiments of the present invention.

According to the utility model discloses a first embodiment provides an intelligence positive negative pressure system, include: the device comprises a positive and negative pressure cabin 1, an air pump 2, an inflator pump 3, a positive and negative pressure intelligent regulation and control device 5 and a positive and negative pressure airflow carrying object generator; the positive and negative ballast 1 includes: the device comprises a cabin body 1.1, a cabin door 1.2, an airtight mechanism 1.3 and a cabin inside and outside communicating sealer 1.4; an airtight mechanism 1.3 is arranged between the cabin body 1.1 and the cabin door 1.2; the communication device 1.4 for the outside sealing in the cabin is fixedly arranged at the rear part of the positive and negative pressure cabin 1, and all pipelines and circuits which enter and exit the cabin are connected to and enter and exit through the communication device 1.4 for the outside sealing in the cabin so as to keep the sealing performance of the positive and negative pressure cabin 1; the outside of the positive and negative pressure cabin 1 is provided with an air pump 2, an inflator pump 3, a positive and negative pressure intelligent control device 5 and an air adjusting device 6.1 of a positive and negative pressure air flow carried object generator; an air suction pipeline A1 is installed at an air inlet a of the air suction pump 2, an electromagnetic valve B1 is installed in the middle of the air suction pipeline A1, the other end of the air suction pipeline A1 extends into the positive and negative pressure cabin 1 to form an air suction return port c, an air exhaust pipeline A2 is installed at an air outlet B of the air suction pump 2, and the other end of the air exhaust pipeline A2 is communicated with the atmosphere; an air inflation pipeline A3 is installed at an air outlet d of the air inflation pump 3, an electromagnetic valve B3 is installed in the middle of the air inflation pipeline A3, the other end of the air inflation pipeline A3 extends into the positive and negative pressure cabin 1 to form an air inflation inlet f of the air inflation pipeline, an air inlet pipeline A4 is installed at an air inlet e of the air inflation pump 5, an electromagnetic valve B4 is installed in the middle of the air inlet pipeline A4, and the other end of the air inlet pipeline; the electromagnetic valve B4 is also connected with a circulating pipeline A5, the middle part of the circulating pipeline A5 is provided with an electromagnetic valve B5, the other end of the circulating pipeline A is connected with an electromagnetic valve B3 and extends into the positive and negative pressure cabin 4 through an inflation pipeline A3 to form a circulating return air port j; an air-conditioned air inlet pipeline A6 is installed at an air inlet t of the air-conditioned device 6.1, an electromagnetic valve B6 is installed in the middle of the air-conditioned air inlet pipeline A6, the other end of the air-conditioned air inlet pipeline is connected to an air charging pipe A3 and then communicated with an air outlet d of an air charging pump 3, an air-conditioned air outlet pipeline A7 is installed at an air outlet s of the air-conditioned device 6.1, an electromagnetic valve B7 is installed in the middle of the air-conditioned air outlet pipeline A7, the other end of the air-conditioned air outlet pipeline extends into the positive and negative pressure cabins 1 to form an air-conditioned air inlet i thereof, and; the inside of positive negative pressure cabin 1 is also installed positive negative pressure air current and is carried thing generator, includes: 6.2 parts of a superoxide (ozone) generator, 6.3 parts of an anion generator, 6.4 parts of a gas catalyst release controller and 6.5 parts of a humidifier; the inside of positive negative pressure cabin 1 still installs the sensor, includes: a pressure sensor C1, a negative pressure sensor C2, a superoxide sensor C3, a negative oxygen ion sensor C4, a chlorine dioxide sensor C5, a humidity sensor C6, an oxygen sensor C7 and a nitrogen sensor C8; the air pump 2, the inflator pump 3, the air conditioning device 6.1, the superoxide generator 6.2, the anion generator 6.3, the gas catalyst controlled release device 6.4, the humidifier 6.5, all sensors C1-C8 and all electromagnetic valves B1-B7 are all connected to the positive and negative pressure intelligent control device 5.

According to a second embodiment of the utility model, an intelligent positive and negative pressure refrigerator is provided, which comprises a box body 7; an intelligent positive-negative pressure system, a refrigerating system 8, a common refrigerating chamber 9, a common freezing chamber 10, an air water making device 11 and a touch screen and mobile phone monitoring system 12 are arranged in the box body 7; the intelligent positive and negative pressure system comprises a positive and negative pressure cabin 1, an air pump 2, an inflator pump 3, a positive and negative pressure intelligent regulation and control device 5 and a positive and negative pressure airflow carried object generation processor; the positive and negative ballast 1 includes: the device comprises a cabin body 1.1, a cabin door 1.2, an in-cabin outer sealing communicating vessel 1.4, a pneumatic airtight mechanism 1.5, an electric airtight mechanism 1.6, a pneumatic cabin door switch 1.8 and an electric cabin door switch 1.9; the cabin door 1.2 is a cabin door of the positive and negative pressure refrigerator; the positive and negative pressure cabin 1 is designed into a vacuum high-pressure refrigerating cabin 1-1 and a vacuum high-pressure freezing cabin 1-2 according to the specific requirements of refrigeration and freezing of a refrigerator; a pneumatic airtight mechanism 1.5 is arranged between the cabin door 1.2 and the cabin body 1.1 of the vacuum high-pressure refrigerating cabin 1-1; the pneumatic airtight mechanism 1.5 comprises a pneumatic sealing bolt 1.51 and a sealing bolt telescopic air bag 1.52 integrally manufactured at the rear part of the sealing bolt 1.51; the sealing bolt 1.51 and the sealing bolt telescopic air bag 1.52 of the integrated structure are totally 4 and are all strip-shaped, and are respectively installed in 4 cabin body airtight grooves 1.11 arranged in 4 side frames of a door frame of a cabin body 1.1, the outer layer part of the cross section of the bolt body is sealing rubber, and the inner part of the cross section of the bolt body is a bending-resistant metal core; the sealing bolt folding telescopic air bag 1.52 is an inflatable folding rubber air bag, and an inflatable socket 1.53 is arranged at the rear part of the air bag; an inflation plug 1.54 is inserted into the inflation socket 1.53, 4 inflation plugs are arranged in the inflation plug 1.54, the inflation plugs are respectively installed and communicated at the middle points of the four side pipelines of the four sides of the square annular air-tight mechanism inflation branch pipeline A8.1, the bottom side pipeline of the square annular air-tight mechanism inflation branch pipeline A8.1 is vertically connected with the air-tight mechanism inflation pipeline A8, and is communicated with the air outlet d of the inflation pump 3 through an electromagnetic valve B8, a pipeline A3 and an electromagnetic valve B3; when the cabin door is closed, the cabin door 1.2 touches a pneumatic cabin door switch 1.8, the inflator pump 3 is started immediately to inflate the sealing bolt folding telescopic airbag 1.52 to extend, and pushes the sealing bolt 1.51 to extend out of the cabin body airtight groove 1.11 and extend into the cabin door airtight groove 1.21 arranged at the opposite corresponding position, so as to lock and seal the cabin door, when a user opens the cabin door, the sealing bolt folding telescopic airbag 1.52 is deflated through the pneumatic cabin door switch 1.8, so that the sealing bolt 1.51 retracts to open the cabin door; an electric airtight mechanism 1.6 is arranged between the cabin door 1.2 and the cabin body 1.1 of the vacuum high-pressure freezing cabin 1-2; the electric airtight mechanism 1.6 comprises an electric sealing bolt 1.61, an electromagnet 1.62 and a tension spring 1.63; the number of the sealing lock tongues 1.61 is 4, the sealing lock tongues are all strip-shaped, the sealing lock tongues are respectively and movably arranged in 4 cabin body airtight grooves 1.11 arranged in the periphery of a cabin body door frame and are hung on a tension spring 1.63, and the other end of the tension spring is fixedly hung at the bottom in the cabin body airtight grooves 1.11; the outer layer part of the cross section of the tongue body of the sealing bolt 1.61 is a sealing rubber layer, the interior of the tongue body is a bending-resistant and magnetic-attracting metal core, the sealing rubber layer facing one side of the electromagnet 1.62 is open, and the metal core in the interior is partially exposed so as to be attracted by the electromagnet 1.62; the electromagnet 1.62 is also a strip shape corresponding to the shape of the sealing bolt 1.61, and is fixedly arranged in the bottom of the cabin door air-tight groove 1.21 corresponding to the position of the cabin body air-tight groove 1.11, when the door needs to be sealed after being closed, the electric cabin door switch 1.9 energizes the electromagnet 1.62 to generate magnetic force, the sealing bolt 1.61 arranged in the opposite cabin body air-tight groove 1.11 is attracted into the cabin door air-tight groove 1.21, the power-off magnetic force of the electric cabin door switch 1.9 to the electromagnet 1.62 disappears when the door is opened, and the tension spring 1.63 pulls the sealing bolt 1.61 back into the cabin body air-tight groove 1.11 to open the cabin door; the communication device 1.4 for the outside sealing in the cabin is fixedly arranged at the rear part of the positive and negative pressure cabin 1, and all pipelines and circuits for entering and exiting the inside and outside of the cabin are connected to and enter and exit through the communication device 1.4 for the outside sealing in the cabin so as to keep the sealing performance of the positive and negative pressure cabin 1. An air pump 2, an inflator pump 3, a positive and negative pressure intelligent regulation and control device 5, an air conditioning device 6.1, a superoxide decomposer 6.7, an air filter 6.8, a refrigeration system 8, an air water making device 11, a filtering water tank 11.1, a touch screen and a mobile phone monitoring system 12 are arranged outside the positive and negative pressure cabin 1; an air suction pipeline A1 is installed at an air inlet a of the air suction pump 5, the air suction pipeline A1 is respectively connected with air suction branch pipelines A1.1 and A1.2, the middles of the air suction branch pipelines A1.1 and A1.2 are respectively provided with electromagnetic valves B1.1 and B1.2, and the other ends of the air suction branch pipelines respectively extend into the vacuum high-pressure refrigerating cabin 1-1 and the vacuum high-pressure freezing cabin 1-2 to form air suction return ports c1 and c 2; an air outlet B of the air pump 2 is provided with an air exhaust pipeline A2, the middle part of the air exhaust pipeline A2 is provided with a superoxide decomposer 6.7 and an electromagnetic valve B2, the other end of the air exhaust pipeline A2 is communicated with an air inlet h of the air water making device 11, and the air is communicated with the atmosphere through an air outlet n of the air water making device 11; an air charging pipeline A3 is installed at an air outlet d of the air charging pump 3, an electromagnetic valve B3 is installed in the middle of the air charging pipeline A3, the other end of the air charging pipeline A3 is connected with air charging branch pipelines A3.1, A3.2, A3.3 and A3.4 respectively, electromagnetic valves B3.1, B3.2, B3.3 and B3.4 are installed in the middle of the air charging branch pipelines A3.1, A3.2, A3.3 and A3.4 respectively, the other ends of the air charging branch pipelines extend into the vacuum high-pressure refrigeration cabin 1-1 and the vacuum high-pressure refrigeration cabin 1-2 respectively, and an air charging air inlet f1 of the vacuum high-pressure refrigeration cabin 1-1 is formed at the other end port of the A; the other end port of A3.2 forms an air charging inlet f2 of the vacuum high-pressure freezing chamber 1-2; the other end of the A3.3 is connected to an air inlet G of the ultrahigh pressure thawing compartment 1-3; the other end of A3.4 is connected to an air inlet Q of the ultrahigh pressure deep cooling cabin 1-4; an air inlet pipeline A4 is installed at an air inlet e of the inflator pump 3, an air filter 6.8 and an electromagnetic valve B4 are installed in the middle of the air inlet pipeline A4, and the other end of the air inlet pipeline is communicated with the atmosphere; the electromagnetic valve B4 is also connected with a circulating pipeline A5, the circulating pipeline A5 is connected to circulating branch pipelines A5.1 and A5.2, the middles of the circulating branch pipelines A5.1 and A5.2 are respectively provided with electromagnetic valves B5.1 and B5.2, and the other ends of the circulating branch pipelines respectively extend into the vacuum high-pressure refrigerating cabin 1-1 and the vacuum high-pressure freezing cabin 1-2 to form circulating air return ports j1 and j 2; the circulating pipeline A5 is also connected with an air-to-water inflation pipeline A9, the air-to-water inflation pipeline A9 is connected to a solenoid valve B2 and communicated with an air inlet h of the air-to-water device 11 through an exhaust pipeline A2, the air-to-water inflation pipeline A9 is connected with a circulating pipeline A5 and communicated with a solenoid valve B3, and then communicated with an air outlet d of the inflator pump 3 through an inflation pipeline A3; a modified atmosphere air inlet pipeline A6 is installed at an air inlet t of the modified atmosphere device 6.1, a solenoid valve B6 is installed in the middle of the modified atmosphere air inlet pipeline A6, the other end of the modified atmosphere air inlet pipeline A6 is connected to an air inflation pipeline A3, then the solenoid valve B3 is communicated with an air outlet d of the air inflation pump 3, modified atmosphere air outlet pipelines A7.1 and A7.2 are installed at air outlets s1 and s2 of the modified atmosphere device 6.1 respectively, solenoid valves B7.1 and B7.2 are installed in the middle of the modified atmosphere air outlet pipelines A7.1 and A7.2 respectively, and the other ends of the modified atmosphere air outlet pipelines extend into the vacuum high-pressure refrigerating compartment 1-1 and the vacuum high-pressure freezing compartment 1-2; the inflation pipeline A3 is also connected to an airtight mechanism inflation pipeline A8, the middle part of the airtight mechanism inflation pipeline A8 is provided with an electromagnetic valve B8, and the other end of the airtight mechanism inflation pipeline A is vertically connected to a bottom pipeline of a square annular airtight mechanism inflation branch pipeline A8.1; four side pipelines of the square annular air-tight mechanism inflation branch pipeline A8.1 are communicated with each other, the midpoint positions of the four side pipelines are provided with inflation plugs 1.54, and the four inflation plugs 1.54 are inserted into and connected to the inflation sockets 1.53; an air water making pipeline A10 is installed at the water outlet x of the air water making device 11, and the air water making pipeline A10 is communicated with the water inlet y of the filtering water tank 11.1; condensed water generated in the vacuum high-pressure refrigerating chamber 1-1 flows into a water inlet Y of a condensed water collecting box 11.2 arranged at the bottom in the vacuum high-pressure refrigerating chamber, a condensed water pipeline A11 is arranged at a water outlet M of the condensed water collecting box 11.2, an electromagnetic valve B11 is arranged in the middle of the condensed water pipeline A11 after extending out of the vacuum high-pressure refrigerating chamber 1-1, the other end of the condensed water pipeline is communicated with a water inlet v of a filter water tank 11.1, a humidifying water pipeline A12 is arranged at a water outlet o of the filter water tank 11.1, an electromagnetic valve B12 is arranged in the middle of the humidifying water pipeline A12, and the other end of the humidifying water pipeline extends into the vacuum; the refrigerating system 8 is provided with a refrigerating circulation pipeline A13, and the refrigerating circulation pipeline A13 extends into the vacuum high-pressure refrigerating chamber 1-1, the vacuum high-pressure freezing chamber 1-2, the common refrigerating chamber 9 and the common freezing chamber 10 respectively and is communicated with an evaporator air cooling combination 8.1 and an evaporator direct cooling combination 8.2 which are arranged in the refrigerating system respectively; the touch screen and mobile phone monitoring system 12 includes: the mobile phone comprises a box door touch screen 12.1, a mobile phone APP12.2 and a high-definition anti-fog camera 12.3, wherein the high-definition anti-fog camera 12.3 is arranged at a position to be monitored inside and outside the box body 7; positive negative pressure air current carry thing generation treater and sensor are installed in the inside setting of positive negative pressure ballast 1, include: the vacuum high-pressure refrigerating chamber 1-1 is provided with: 6.2 parts of an ultrasonic generator, 6.3 parts of an anion generator, 6.4 parts of a gas catalyst controlled release device, 6.5 parts of a humidifier, 11.2 parts of a condensed water collecting box, a pressure sensor C1, a negative pressure sensor C2, a superoxide sensor C3, a negative oxygen ion sensor C4, a chlorine dioxide sensor C5, a humidity sensor C6, an oxygen sensor C7, a nitrogen sensor C8 and a temperature sensor C9; the device is arranged and installed in a vacuum high-pressure freezing cabin 1-2 and comprises: 6.4 of a gas catalyst controlled release device, a pressure sensor C1, a negative pressure sensor C2, a chlorine dioxide sensor C5, an oxygen sensor C7, a nitrogen sensor C8 and a temperature sensor C9; all airflow carrying object generation processors, sensors, electromagnetic valves and equipment devices installed inside and outside the positive and negative pressure cabin 1 comprise: the device comprises an air extracting pump 2, an air charging pump 3, an air conditioning device 6.1, an ultra-oxygen generator 6.2, an anion generator 6.3, a gas catalyst controlled release device 6.4, a humidifier 6.5, an ultra-oxygen decomposer 6.7, a refrigeration system 8, an air water making device 11, a filter water tank 11.1, an ultra-high pressure thawing cabin 1-3, an ultra-high pressure deep cooling cabin 1-4, a touch screen and mobile phone monitoring system 12, a box door touch screen 12.1, a high-definition anti-fog camera device 12.3, a pressure sensor C1, a negative pressure sensor C2, an ultra-oxygen sensor C3, a negative oxygen ion sensor C4, a chlorine dioxide sensor C5, a humidity sensor C6, an oxygen sensor C7, a nitrogen sensor C8, a temperature sensing controller C9, a water level sensing controller C10 and electromagnetic valves B1-B12, and is connected to the positive and.

According to a third embodiment of the present invention, there is provided an intelligent positive and negative pressure washing machine, comprising a machine body 7; an intelligent positive-negative pressure system, an elution drying system 15, a touch screen and mobile phone monitoring system 12 are arranged in the machine body 7; the intelligent positive and negative pressure system comprises a positive and negative pressure cabin 1, an air pump 2, an inflator pump 3, a positive and negative pressure intelligent regulation and control device 5 and a positive and negative pressure airflow carried object generation processor; the positive and negative pressure cabin 1 is designed into a vacuum high-pressure roller outer cabin 1-5 according to the specific requirements of washing and drying; the vacuum high-pressure roller outer chamber 1-5 comprises: the device comprises a cabin body 1.1, a cabin door 1.2, a mechanical airtight mechanism 1.3 and an in-cabin outer sealing communicating vessel 1.4; the cabin door 1.2 is a machine door of the positive and negative pressure washing machine; a mechanical airtight mechanism 1.3 is arranged between the cabin door 1.2 of the vacuum high-pressure roller outer cabin 1-5 and the cabin body 1.1; the mechanical airtight mechanism 1.3 comprises a lock ring 1.31, a bolt 1.32, an airtight gasket 1.33 and a door edge gasket 1.34; the lock ring 1.31 is movably matched with the lock tongue 1.32, the lock tongue 1.32 extends into the lock ring 1.31 to lock the cabin door when the cabin door is closed, and the air-tight gasket 1.33 keeps sealing when positive and negative air pressure is formed in the vacuum high-pressure roller outer cabin 1-5; the intra-cabin outer sealing communicating vessel 1.4 is fixedly arranged at the rear part of the vacuum high-pressure roller outer cabin 1-5, and all pipelines and circuits which enter and exit the inside and outside of the cabin are connected to the intra-cabin outer sealing communicating vessel 1.4 and enter and exit through the intra-cabin outer sealing communicating vessel so as to keep the sealing performance of the vacuum high-pressure roller outer cabin 1-5; a roller mechanism 15.1, a water-drenching prevention air exhaust port 2.1, a roller sealing bearing seat 15.3, a pressure sensor C1 and a negative pressure sensor C2 are arranged in the vacuum high-pressure roller outer chamber 1-5; an air pump 2, an inflator pump 3, a positive and negative pressure intelligent regulation and control device 5, an elution and drying control mechanism 15.2, a large roller belt pulley 15.4, a motor combination 15.5, a drainage pump 16, a water inlet pump 17, a superoxide generation water mixer 6.6, a superoxide decomposer 6.7, a touch screen and mobile phone APP monitoring system 12 and a detergent pull box 18 are arranged outside the vacuum high-pressure roller outer chamber 1-5; an air suction pipeline A1 is installed at an air inlet a of the air suction pump 2, an electromagnetic valve B1 is installed in the middle of the air suction pipeline A1, the other end of the air suction pipeline A1 extends into the vacuum high-pressure roller outer chamber 1-5 and then is connected with a water-drenching prevention air suction opening 2.1 to form an air suction return opening c, and an air outlet B of the air suction pump 2 is communicated with the atmosphere; an air charging pipeline A3 is installed at the air outlet d of the air charging pump 3, an electromagnetic valve B3 is installed in the middle of the air charging pipeline A3, and the other end of the air charging pipeline extends into the vacuum high-pressure roller outer chamber 1-5 and extends to the lower part of the roller mechanism 15.1 to form an air charging air inlet f; an air inlet e of the inflator pump 3 is communicated with the atmosphere; a water inlet pipe A14 is installed at a water inlet r of the water inlet pump 17, a solenoid valve B14 is installed in the middle of the water inlet pipe A14, the other end of the water inlet pipe A14 is communicated with a tap water source, a washing machine water inlet pipe A15 is installed at a water outlet u of the water inlet pump 17, a solenoid valve B15 is installed in the middle of the water inlet pipe A15, the other end of the water inlet pipe A15 is communicated with a water inlet k of the superoxide generation water mixer 6.6, a washing machine water inlet pipe A16 is installed at a water outlet q of the superoxide generation water mixer 6.6, a solenoid valve B16 is installed in the middle of the water inlet pipe A16, the other end of the water inlet pipe A is communicated with a water inlet z of the detergent pulling box 18, a washing machine water inlet pipe A17 is installed at a water outlet l of the detergent pulling; the electromagnetic valve B14 is also provided with a water inlet pipeline A18 which is connected with an electromagnetic valve B16 in parallel, and water can be directly fed when the pressure of tap water reaches the standard without the need of super-oxygen water; the electromagnetic valve B15 is also provided with a water inlet pipeline A19, is connected to a water inlet pipeline A18 and is communicated with an electromagnetic valve B16, and water is directly fed by the water inlet pump 17 when the super oxygen water is not needed; a water inlet pipeline A20 is installed at a water inlet w of the drainage pump 16, a solenoid valve B20 is installed in the middle of the drainage pipeline A20, the other end of the drainage pipeline A20 extends into the vacuum high-pressure roller outer chamber 1-5 to form a drainage outlet L of the vacuum high-pressure roller outer chamber, a drainage pipeline A21 is installed at a water outlet p of the drainage pump 16, a solenoid valve B21 is installed in the middle of the drainage pipeline A21, the other end of the drainage pipeline A21 is communicated with a water inlet g of the superoxide decomposer 6.7, a drainage pipeline A22 is installed at a water outlet m of the superoxide decomposer 6.7; the electromagnetic valve B20 is also provided with a drainage pipeline A23 which is connected with an electromagnetic valve B22 in parallel, and can directly drain water when the super oxygen is not required to be decomposed and the water can be drained automatically; the electromagnetic valve B21 is also provided with a drainage pipeline A24 and is connected to a drainage pipeline A23 to be communicated with an electromagnetic valve B22, and drainage is directly carried out by the drainage pump 16 when superoxide does not need to be decomposed; the motor assembly 15.5 drives the large belt pulley 15.4, and the large belt pulley 15.4 drives the roller mechanism 15.1 connected with the large belt pulley to run; the device comprises an air pump 2, an inflator pump 3, a drainage pump 16, a water inlet pump 17, a superoxide generation water mixer 6.6, a superoxide decomposer 6.7, an elution drying control mechanism 15.2, a touch screen and mobile phone APP monitoring system 12, a pressure sensor C1, a negative pressure sensor C2 and electromagnetic valves B1-B22 which are all connected into a positive and negative pressure intelligent regulation and control device 5.

According to a fourth embodiment of the utility model, an intelligent vacuum dish washing, fruit and vegetable cleaning machine is provided, which comprises a machine body 7; an intelligent positive-negative pressure system, a dish washing and drying system 19, a fruit and vegetable cleaning system 20 and a touch screen and mobile phone APP monitoring system 12 are arranged in the machine body 7; the intelligent positive and negative pressure system comprises a positive and negative pressure cabin 1, an air pump 2, a positive and negative pressure intelligent regulation and control device 5 and a positive and negative pressure airflow carried object generation processor; the positive and negative pressure cabin 1 is designed into a vacuum super-oxygen cabin 1-6 according to the special requirements of intelligent dish washing, drying and fruit and vegetable cleaning; the vacuum super-oxygen chamber 1-6 comprises: the device comprises a cabin body 1.1, a cabin door 1.2, a mechanical airtight mechanism 1.3 and an in-cabin outer sealing communicating vessel 1.4; the hatch door 1.2 is a machine door of the vacuum dish washing, fruit and vegetable cleaning machine; a mechanical airtight mechanism 1.3 is arranged between the cabin door 1.2 and the cabin body 1.1 of the vacuum super-oxygen cabin 1-6; the mechanical airtight mechanism 1.3 comprises a lock ring 1.31, a bolt 1.32 and an airtight gasket 1.33; the lock ring 1.31 is movably matched with the lock tongue 1.32, the lock tongue 1.32 extends into the lock ring 1.31 to lock the cabin door when the cabin door is closed, and the air-tight gasket 1.33 keeps sealing when positive and negative air pressure is formed in the vacuum super-oxygen cabin 1-6; the in-cabin and out-cabin pipeline joint controller 1.4 is fixedly arranged at the rear part of the vacuum super-oxygen cabin 1-6, and all pipelines and circuits which enter and exit from the cabin are connected to the in-cabin and out-cabin outer sealing communicating device 1.4 and enter and exit through the in-cabin and outer sealing communicating device so as to keep the sealing performance of the vacuum super-oxygen cabin 1-6. A dish washing and drying system 19, a fruit and vegetable cleaning system 20, a water-drenching prevention pumping hole 2.1, a negative pressure sensor C2, a superoxide sensor C3 and a temperature sensor C9 are arranged in the vacuum super-oxygen chamber 1-6; an air suction pump 2, a positive and negative pressure intelligent regulation and control device 5, a water discharge pump 16, a water inlet pump 17, a superoxide generation water mixer 6.6, a superoxide decomposer 6.7, a touch screen and mobile phone APP monitoring system 12 are arranged outside the vacuum super-oxygen chambers 1-6; an air suction pipeline A1 is installed at the air inlet a of the air suction pump 2, an electromagnetic valve B1 is installed in the middle of the air suction pipeline A1, and the other end of the air suction pipeline A extends into the vacuum super-oxygen chamber 1-6 and then is connected with a water-drenching prevention air suction opening 2.1 to form an air suction return opening c; the air outlet b of the air pump 2 is communicated with the atmosphere; a water inlet pipe A14 is installed at a water inlet r of the water inlet pump 17, a solenoid valve B14 is installed in the middle of the water inlet pipe A14, the other end of the water inlet pipe A14 is connected with a tap water source, a water inlet pipe A15 is installed at a water outlet u of the water inlet pump 17, a solenoid valve B15 is installed in the middle of the water inlet pipe A15, the other end of the water inlet pipe A15 is connected with a water inlet k of the superoxide generating water mixer 6.6, a water inlet pipe A16 is installed at a water outlet q of the superoxide generating water mixer 6.6, a solenoid valve B16 is installed in the middle of the water inlet pipe A16, the other end of the water inlet pipe A16 extends into the vacuum superoxide chamber 1-6 to be connected to the solenoid valve B25, the solenoid valve B25 is respectively connected with a; the water inlet pipeline A27 is connected to a water inlet G of the dish washing and drying system 19; the electromagnetic valve B15 is also provided with a water inlet pipeline A19 and is connected to an electromagnetic valve B16, and water is directly fed by a water inlet pump 17 when the super oxygen water is not needed; a water discharge pipeline A20 is installed at a water inlet w of the water discharge pump 16, an electromagnetic valve B20 is installed in the middle of the water discharge pipeline A20, the other end of the water discharge pipeline A20 extends into the vacuum super-oxygen chamber 1-6 and is respectively connected to a fruit and vegetable cleaning water discharge pipeline A26 and a dish washing and drying water discharge pipeline A28, and the water discharge pipeline A26 is connected to a water outlet F of the fruit and vegetable cleaning system 20; the drainage pipeline A28 is connected to a drainage port H of the dish washing and drying system 21; a drainage pipeline A21 is installed at a water outlet p of the drainage pump 16, an electromagnetic valve B21 is installed in the middle of the drainage pipeline A21, the other end of the drainage pipeline A21 is communicated with a water inlet g of the superoxide decomposer 6.7, a drainage pipeline A22 is installed at a water outlet m of the superoxide decomposer 6.7, an electromagnetic valve B22 is installed in the middle of the drainage pipeline A22, and the other end of the drainage pipeline A22 is communicated with a; the electromagnetic valve B21 is also provided with a drainage pipeline A24 and is connected to A23 to be communicated with the electromagnetic valve B22, and drainage is directly carried out by a drainage pump when superoxide does not need to be decomposed; the air pump 2, the drain pump 16, the water inlet pump 17, the superoxide generation water mixer 6.6, the superoxide decomposer 6.7, the dish washing and drying system 19, the fruit and vegetable cleaning system 20, the touch screen and mobile phone APP monitoring system 12, the negative pressure sensor C2, the superoxide sensor C3, the temperature sensor C9 and the electromagnetic valves B1 to B25 are all connected to the positive and negative pressure intelligent regulation and control device 5.

According to the fifth embodiment of the utility model, an intelligent superoxide washing range hood is provided, which comprises a body 7; the lower half part of the machine body 7 is a sealed waterproof super-oxygen cabin 1-7, and the upper half part is an equipment smoke pipe cabin 21; the sealed waterproof super oxygen cabin 1-7 includes: a triangular cabin body 1.1 and a sealed waterproof cabin door 1.2; the sealed waterproof cabin door 1.2 is a machine door of the superoxide water washing range hood, and a sealed waterproof mechanism 1.7 is arranged between the cabin door 1.2 and the cabin body 1.1; the waterproof sealing mechanism 1.7 comprises a lock ring 1.71, a lock tongue 1.72, an airtight gasket 1.73 and a cabin door hinge 1.74; the lock ring 1.71 is in movable fit with the lock tongue 1.72, the lock tongue 1.72 extends into the lock ring 1.71 to lock the cabin door 1.2 when the cabin door is closed, and the sealing is kept by the sealing washer 1.73 when the sealed waterproof superoxide cabin 1-7 is sprayed and cleaned; a motor and wind wheel combination 22, an automatic rotating spraying ball 23 and an oil and water collecting and draining groove 24 are arranged in the sealed waterproof super-oxygen cabin 1-7, and a touch screen and a mobile phone APP monitoring system 12 are also arranged on the front side; an intelligent superoxide cleaning system and an oil fume pumping control mechanism 26 are arranged in the smoke tube cabin 21 of the equipment; the intelligent superoxide cleaning system comprises: the device comprises an intelligent superoxide regulating and controlling device 5.1, a water inlet pump 17, a water discharge pump 16, a superoxide generating water mixer 6.6, a superoxide decomposer 2.1, a water heating device 27 and a degreasing agent adder 28; a water inlet pipe A14 is installed at a water inlet r of the water inlet pump 17 and is connected with a tap water source, a water inlet pipe A15 is installed at a water outlet u of the water inlet pump 17, a water heating device 27 and an electromagnetic valve B15 are installed in the middle of the water inlet pipe A15, the other end of the water inlet pipe A is divided into 3 paths through an electromagnetic valve B15, and the water inlet k of the superoxide generation water mixer 6.6, the water inlet z of the degreasing agent adder 28 and the electromagnetic valve B16 are respectively connected; a water inlet pipeline A16 is installed at a water outlet q of the superoxide generation water mixer 6.6, an electromagnetic valve B16 is installed in the middle of the water inlet pipeline A16, the other end of the water inlet pipeline A16 extends into the sealed waterproof superoxide cabin 1-7 and is connected to a spray pipeline A30, at least 1 automatic rotating spray ball 23 is installed on the spray pipeline A30, the axis of the spray ball and the axis of a middle circle of spray holes form an angle of 45 degrees, and the spray ball 23 automatically rotates when water flow is sprayed out; a water inlet pipeline A17 is installed at a water outlet I of the degreaser adder 28, a solenoid valve B17 is installed in the middle of the water inlet pipeline A17, and the other end of the water inlet pipeline A15 is communicated with the solenoid valve B16; a water inlet pipeline A20 is installed at the water inlet w of the drainage pump 16, an electromagnetic valve B20 is installed in the middle of the drainage pipeline A20, and the other end of the drainage pipeline A extends into the oil and water collecting and draining groove 24 at the bottom of the vacuum super-oxygen chamber 1-7 to form a water outlet L; a drainage pipeline A21 is installed at a water outlet p of the drainage pump 16, an electromagnetic valve B21 is installed in the middle of the drainage pipeline A21, the other end of the drainage pipeline A21 is communicated with a water inlet g of the superoxide decomposer 2.1, a drainage pipeline A22 is installed at a water outlet m of the superoxide decomposer 2.1, an electromagnetic valve B22 is installed in the middle of the drainage pipeline A22, and the other end of the drainage pipeline A22 is communicated with a; the electromagnetic valve B21 is also provided with a water discharge pipeline A24 and is connected to an electromagnetic valve B22, and water is directly discharged by a water discharge pump 16 when superoxide does not need to be decomposed; the water inlet pump 17, the water discharge pump 16, the superoxide generation water mixer 6.6, the superoxide decomposer 2.1, the water heating device 27, the degreasing agent adder 28, the oil pumping smoke control mechanism 26, the touch screen and mobile phone APP monitoring system 12 and the electromagnetic valves B1-B22 are all connected to the superoxide intelligent control device 5.1.

According to the utility model discloses a sixth embodiment provides an intelligence positive negative pressure oven air fryer microwave oven, including organism 7, be equipped with in the organism 7: the intelligent positive and negative pressure system, the barbecue system 30, the air fryer system 31, the microwave system 32 and the touch screen and mobile phone APP monitoring system 12; the intelligent positive and negative pressure system comprises a positive and negative pressure cabin 1, an air pump 2, an inflator pump 3 and a positive and negative pressure intelligent regulation and control device 5; the positive and negative pressure cabins 1 are designed into microwave vacuum high pressure cabins 1-8 according to the specific requirements of an oven air fryer and a microwave oven; the microwave vacuum hyperbaric chamber 1-8 comprises: the device comprises a cabin body 1.1, a cabin door 1.2, a mechanical airtight mechanism 1.3 and an in-cabin outer sealing communicating vessel 1.4; the hatch door 1.2 is a machine door of the positive and negative pressure oven air fryer microwave oven; a mechanical airtight mechanism 1.3 is arranged between the cabin door 1.2 and the cabin body 1.1 of the microwave vacuum high-pressure cabin 1-8; the mechanical airtight mechanism 1.3 comprises a lock ring 1.31, a bolt 1.32 and an airtight gasket 1.33; the lock ring 1.31 is movably matched with the bolt 1.32, the bolt 1.32 extends into the lock ring 1.31 to lock the hatch door when the hatch door is closed, and the sealing is kept by the airtight gasket 1.33 when positive and negative air pressure is formed in the microwave vacuum high-pressure cabin 1-8; the in-cabin and out-cabin pipeline joint controller 1.4 is fixedly arranged at the rear part of the microwave vacuum high-pressure cabin 1-8, and all pipelines and circuits which enter and exit the cabin are connected to the in-cabin and out-cabin sealing communicating device 1.4 and enter and exit through the same so as to keep the sealing performance of the microwave vacuum high-pressure cabin 1-8. The microwave vacuum high-pressure cabin 1-8 is internally provided with a barbecue system 30, an air fryer system 31, a microwave system 32, a pressure sensor C1 and a negative pressure sensor C2; an air pump 2, an inflator pump 3, a positive and negative pressure intelligent control device 5, a touch screen and a mobile phone APP monitoring system 12 are arranged outside the microwave vacuum high-pressure cabins 1-8; an air suction pipeline A1 is installed at an air inlet a of the air suction pump 2, an electromagnetic valve B1 is installed in the middle of the air suction pipeline A1, the other end of the air suction pipeline A1 extends into the microwave vacuum high-pressure cabin 1-8 to form an air suction return port c, and an air outlet B of the air suction pump 2 is provided with an air outlet pipeline A2 and is communicated with the atmosphere; an air inflation pipeline A3 is installed at an air outlet d of the air inflation pump 3, an electromagnetic valve B3 is installed in the middle of the air inflation pipeline A3, and the other end of the air inflation pipeline A extends into the microwave vacuum high-pressure cabin 1-8 to form an air inflation inlet f; an air inlet pipeline A4 is arranged at an air inlet e of the inflator pump 3 and is communicated with the atmosphere; air pump 2, pump 3, pressure sensor C1, negative pressure sensor C2, barbecue system 30, air fryer system 31, microwave system 32 and touch screen and cell-phone APP monitored control system 12 all insert positive negative pressure intelligent control device 5.

According to the seventh embodiment of the utility model, an intelligent positive and negative pressure fresh-keeping carriage (container) is provided, which comprises a carriage (container) body 7; an intelligent positive-negative pressure system, a refrigerating system 8, a touch screen and a mobile phone monitoring system 12 are arranged in the compartment (box) body 7; the intelligent positive and negative pressure system comprises a positive and negative pressure cabin 1, an air pump 2, an inflator pump 3, a positive and negative pressure intelligent regulation and control device 5 and a positive and negative pressure airflow carrying object generator; the positive and negative pressure cabin 1 is designed into a cabin (box) type vacuum high-pressure cabin 1-9 according to the specific requirements of the intelligent positive and negative pressure fresh-keeping cabin (container); the chamber (tank) type vacuum high-pressure cabin 1-9 includes: the device comprises a cabin body 1.1, a cabin door 1.2, a mechanical airtight mechanism 1.3 and an in-cabin outer sealing communicating vessel 1.4; the cabin door 1.2 is a carriage door of the positive and negative pressure fresh-keeping carriage; a mechanical airtight mechanism 1.3 is arranged between the cabin door 1.2 and the cabin body 1.1 of the chamber (box) type vacuum high-pressure cabin 1-9; the mechanical airtight mechanism 1.3 comprises a lock ring 1.31, a bolt 1.32 and an airtight gasket 1.33; the lock ring 1.31 is movably matched with the bolt 1.32, the bolt 1.32 extends into the lock ring 1.31 to lock the hatch door when the hatch door is closed, and the sealing is kept by the airtight gasket 1.33 when positive and negative air pressure is formed in the chamber (box) type vacuum high-pressure cabin 1-9; the in-cabin and out-cabin pipeline joint controller 1.4 is fixedly arranged at the rear part of the chamber (box) type vacuum high-pressure cabin 1-9, and all pipelines and circuits which enter and exit the chamber are connected to the in-cabin and out-cabin outer sealing communicator 1.4 and enter and exit through the in-cabin and outer sealing communicator so as to keep the sealing performance of the chamber (box) type vacuum high-pressure cabin 1-9. An air pump 2, an inflator pump 3, a positive and negative pressure intelligent regulation and control device 5, an air regulation device 6.1, a superoxide decomposer 2.1, an air water making device 11, a filtering water tank 11.1, a refrigerating system 8, an air filter 3.1, a touch screen and a mobile phone monitoring system 12 are arranged outside the box (box) type vacuum high-pressure cabin 1-9; an air suction pipeline A1 is installed at the air inlet a of the air suction pump 2, an electromagnetic valve B1 is installed in the middle of the air suction pipeline A1, and the other end of the air suction pipeline A extends into the chamber (box) type vacuum high-pressure cabin 1-9 to form an air suction return port c; an air outlet B of the air pump 2 is provided with an air exhaust pipeline A2, the middle part of the air exhaust pipeline A2 is provided with a superoxide decomposer 2.1 and an electromagnetic valve B2, the other end of the air exhaust pipeline A2 is communicated with an air inlet h of the air water making device 11, and air is introduced from an air outlet n of the air water making device 11; an air inflation pipeline A3 is arranged at an air outlet d of the air inflation pump 3, an electromagnetic valve B3 is arranged in the middle of the air inflation pipeline A3, and the other end of the air inflation pipeline A extends into the chamber (box) type vacuum high-pressure cabin 1-9 to form an air inflation inlet f; an air inlet pipeline A4 is installed at an air inlet e of the inflator pump 3, an electromagnetic valve B4 and an air filter 3.1 are installed in the middle of the air inlet pipeline A4, and the other end of the air inlet pipeline is communicated with the atmosphere; the electromagnetic valve B4 is also connected with a circulating pipeline A5, the middle part of the circulating pipeline A5 is provided with an electromagnetic valve B5, the other end of the circulating pipeline A5 is communicated with an electromagnetic valve B3, and the circulating pipeline A3 extends into the chamber (box) type vacuum high-pressure cabin 1-9 to form a circulating return air port j; the inflation pipeline A3 is also connected with an air-to-water inflation pipeline A9, and the air-to-water inflation pipeline A9 is connected to an electromagnetic valve B2 and communicated with an air inlet h of the air-to-water device 11 through an exhaust pipeline A2; an air-conditioned air inlet pipeline A6 is installed at the air inlet t of the air-conditioned device 6.1, an electromagnetic valve B6 is installed in the middle of the air-conditioned air inlet pipeline A6, the other end of the air-conditioned air inlet pipeline A3 is connected to an air inflation pipeline A3 and then is communicated with an air outlet d of the air inflation pump 3, an air-conditioned air outlet pipeline A7 is installed at the air outlet s of the air-conditioned device 6.1, an electromagnetic valve B7 is installed in the middle of the air-conditioned air outlet pipeline A7, and the other end of the air-conditioned air outlet pipeline extends; an air water making pipeline A10 is installed at a water outlet x of the air water making device 11, and the air water making pipeline A10 is communicated with a water inlet y of the filtering water tank 11-1; condensed water generated in the chamber (tank) type vacuum high-pressure cabin 1-9 flows into a water inlet Y of a condensed water collecting box 11.2 arranged at the bottom of the chamber, a condensed water pipeline A11 is arranged at a water outlet M of the condensed water collecting box 11.2, an electromagnetic valve B11 is arranged at the middle part of the condensed water pipeline A11 after extending out of the chamber (tank) type vacuum high-pressure cabin 1-9, the other end of the condensed water pipeline is communicated with a water inlet v of a filter water tank 11.1, a humidifying water pipeline A12 is arranged at a water outlet o of the filter water tank 11.1, an electromagnetic valve B12 is arranged at the middle part of the humidifying water pipeline A12, the other end of the condensed water pipeline extends into the chamber (tank) type vacuum high-pressure cabin 1-9; the refrigerating system 8 is provided with a refrigerating circulation pipeline A13, and the refrigerating circulation pipeline A13 extends into the compartment (box) type vacuum high-pressure cabin 1-9 and is communicated with an evaporator air cooling combination 8.1; the touch screen and mobile phone monitoring system 12 includes: the system comprises a touch screen 12.1, a mobile phone APP12.2 and a wireless anti-fog camera 12.4, wherein the wireless anti-fog camera 12.4 is arranged at a position to be monitored inside and outside a compartment (box) body 7; the interior of the chamber (box) type vacuum high-pressure chamber 1-9 is provided with a positive and negative pressure airflow carrying object generator and a sensor, comprising: 6.5 parts of a humidifier, 6.2 parts of an ultrasonic generator, 6.3 parts of negative ion generation, 6.4 parts of a gas catalyst controlled release device, 11.2 parts of a condensed water collecting box, a pressure sensor C1, a negative pressure sensor C2, a super oxygen sensor C3, a negative oxygen ion sensor C4, a chlorine dioxide sensor C5, a humidity sensor C6, an oxygen sensor C7, a nitrogen sensor C8 and a temperature sensor C9; all the airflow carrying generator, sensor, electromagnetic valve and equipment installed inside and outside the chamber type vacuum high-pressure chamber 1-9 include: the air extracting pump 2, the inflator pump 3, the air conditioning device 6.1, the superoxide generator 6.2, the anion generator 6.3, the gas catalyst controlled release device 6.4, the superoxide decomposer 2.1, the air water making device 11, the filter water tank 11.1, the refrigerating system 8, the humidifier 6.5, the touch screen and mobile phone monitoring system 12, the pressure sensor C1, the negative pressure sensor C2, the superoxide sensor C3, the negative oxygen ion sensor C4, the chlorine dioxide sensor C5, the humidity sensor C6, the oxygen sensor C7, the nitrogen sensor C8, the temperature sensor C9, the water level sensor C10 and the electromagnetic valves B1 to B12 are all connected with the positive and negative pressure intelligent regulation device 5.

According to the eighth embodiment of the utility model, an intelligent positive and negative pressure fresh-keeping warehouse is provided, which comprises a warehouse body 7; an intelligent positive-negative pressure system, a refrigerating system 8, a touch screen and a mobile phone monitoring system 12 are arranged in the storehouse body 7; the intelligent positive and negative pressure system comprises a positive and negative pressure cabin 1, an air pump 2, an inflator pump 3, a positive and negative pressure intelligent regulation and control device 5 and a positive and negative pressure airflow carrying object generator; the positive and negative pressure cabin 1 is designed into a storage type vacuum high-pressure cabin 1-10 according to the specific requirements of the intelligent positive and negative pressure fresh-keeping warehouse; the warehouse type vacuum high-pressure cabin 1-10 includes: the device comprises a cabin body 1.1, a cabin door 1.2, a mechanical airtight mechanism 1.3 and an in-cabin outer sealing communicating vessel 1.4; the hatch door 1.2 is a warehouse door of the positive and negative pressure fresh-keeping warehouse; a mechanical airtight mechanism 1.3 is arranged between the cabin door 1.2 and the cabin body 1.1 of the storage type vacuum high-pressure cabin 1-10; the mechanical airtight mechanism 1.3 comprises a lock ring 1.31, a bolt 1.32 and an airtight gasket 1.33; the lock ring 1.31 is movably matched with the bolt 1.32, the bolt 1.32 extends into the lock ring 1.31 to lock the cabin door when the cabin door is closed, and the cabin door is sealed by the airtight gasket 1.33 when positive and negative air pressure is formed in the storage type vacuum high-pressure cabin 1-10; the in-cabin and out-cabin pipeline connection controller 1.4 is fixedly arranged at the rear part of the storage type vacuum high-pressure cabin 1-10, and all pipelines and circuits which enter and exit the cabin are connected to the in-cabin and out-cabin sealing communicator 1.4 and enter and exit through the in-cabin and out-cabin sealing communicator so as to keep the sealing performance of the storage type vacuum high-pressure cabin 1-10. An air pump 2, an inflator pump 3, a positive and negative pressure intelligent regulation and control device 5, an air conditioning device 6.1, a superoxide decomposer 2.1, an air water production device 11, a filtering water tank 11.1, a refrigeration system 8, an air filter 3.1, a touch screen and a mobile phone monitoring system 12 are arranged outside the storage type vacuum high-pressure cabin 1-10; an air suction pipeline A1 is installed at the air inlet a of the air suction pump 2, an electromagnetic valve B1 is installed in the middle of the air suction pipeline A1, and the other end of the air suction pipeline A extends into the storage type vacuum high-pressure cabin 1-10 to form an air suction return port c; an air outlet B of the air pump 2 is provided with an air exhaust pipeline A2, the middle part of the air exhaust pipeline A2 is provided with a superoxide decomposer 6.7 and an electromagnetic valve B2, the other end of the air exhaust pipeline A2 is communicated with an air inlet h of the air water making device 11, and air is introduced from an air outlet n of the air water making device 11; an air inflation pipeline A3 is arranged at an air outlet d of the air inflation pump 3, an electromagnetic valve B3 is arranged in the middle of the air inflation pipeline A3, and the other end of the air inflation pipeline A extends into the storage type vacuum high-pressure cabin 1-10 to form an air inflation inlet f; an air inlet pipeline A4 is installed at an air inlet e of the inflator pump 3, an electromagnetic valve B4 and an air filter 3.1 are installed in the middle of the air inlet pipeline A4, and the other end of the air inlet pipeline is communicated with the atmosphere; the electromagnetic valve B4 is also connected with a circulating pipeline A5, the middle part of the circulating pipeline A5 is provided with an electromagnetic valve B5, the other end of the circulating pipeline A is communicated with an electromagnetic valve B3, and the circulating pipeline A3 extends into the storage type vacuum high-pressure cabin 1-10 to form a circulating return air port j; the inflation pipeline A3 is also connected with an air-to-water inflation pipeline A9, and the air-to-water inflation pipeline A9 is connected to an electromagnetic valve B2 and communicated with an air inlet h of the air-to-water device 11 through an exhaust pipeline A2; an air-conditioning air inlet pipeline A6 is installed at the air inlet t of the air-conditioning device 6.1, an electromagnetic valve B6 is installed in the middle of the air-conditioning air inlet pipeline A6, the other end of the air-conditioning air inlet pipeline A3 is connected to an air inflation pipeline A3 and then is communicated with an air outlet d of the air inflation pump 3, an air-conditioning air outlet pipeline A7 is installed at the air outlet s of the air-conditioning device 6.1, an electromagnetic valve B7 is installed in the middle of the air-conditioning air outlet pipeline A7, and the other end of the air-conditioning air outlet; an air water making pipeline A10 is installed at a water outlet x of the air water making device 11, and the air water making pipeline A10 is communicated with a water inlet y of the filtering water tank 11-1; condensed water generated in the bin type vacuum high-pressure cabin 1-10 flows into a water inlet Y of a condensed water collecting box 11.2 arranged at the bottom in the cabin, a condensed water pipeline A11 is arranged at a water outlet M of the condensed water collecting box 11.2, an electromagnetic valve B11 is arranged in the middle of the condensed water pipeline A11 after extending out of the bin type vacuum high-pressure cabin 1-10, the other end of the condensed water pipeline A3526 is communicated with a water inlet v of a filter water tank 11.1, a humidifying water pipeline A12 is arranged at a water outlet o of the filter water tank 11.1, an electromagnetic valve B12 is arranged in the middle of the humidifying water pipeline A12, the other end of the condensed water pipeline A11 extends into the bin type vacuum high-pressure cabin 1; the refrigerating system 8 is provided with a refrigerating circulation pipeline A13, and the refrigerating circulation pipeline A13 extends into the warehouse type vacuum hyperbaric chamber 1-10 and is communicated with an evaporator air cooling combination 8.1; the touch screen and mobile phone monitoring system 12 includes: the mobile phone comprises a touch screen 12.1, a mobile phone APP12.2 and an anti-fog camera 12.3, wherein the anti-fog camera 12.3 is arranged at a position to be monitored inside and outside the warehouse body 7; the inside setting of warehouse style vacuum hyperbaric chamber 1-10 is installed positive negative pressure air current and is taken up thing generator and sensor, includes: 6.5 parts of a humidifier, 6.2 parts of an ultrasonic generator, 6.3 parts of negative ion generation, 6.4 parts of a gas catalyst controlled release device, 11.2 parts of a condensed water collecting box, a pressure sensor C1, a negative pressure sensor C2, a super oxygen sensor C3, a negative oxygen ion sensor C4, a chlorine dioxide sensor C5, a humidity sensor C6, an oxygen sensor C7, a nitrogen sensor C8 and a temperature sensor C9; all the airflow carry generators, sensors, electromagnetic valves and equipment devices installed inside and outside the warehouse type vacuum high-pressure cabin 1-10 include: the air extracting pump 2, the inflator pump 3, the air conditioning device 6.1, the superoxide generator 6.2, the negative ion generator 6.3, the gas catalyst controlled release device 6.4, the superoxide decomposer 2.1, the air water making device 11, the filter water tank 11.1, the refrigerating system 8, the humidifier 6.5, the touch screen and mobile phone monitoring system 12, the pressure sensor C1, the negative pressure sensor C2, the superoxide sensor C3, the negative oxygen ion sensor C4, the chlorine dioxide sensor C5, the humidity sensor C6, the oxygen sensor C7, the nitrogen sensor C8, the temperature sensor C9, the water level sensor C10 and the electromagnetic valves B1 to B12 are all connected to the positive and negative pressure intelligent regulation device 5.

According to a ninth embodiment of the present invention, there is provided an intelligent positive and negative pressure module cabinet, comprising a cabinet body 7; an intelligent positive-negative pressure system, a refrigerating and heating system 8.3, a touch screen and a mobile phone monitoring system 12 are arranged in the cabinet body 7; the intelligent positive and negative pressure system comprises a positive and negative pressure cabin 1, an air pump 2, an inflator pump 3, a positive and negative pressure intelligent regulation and control device 5 and a positive and negative pressure airflow carried object generation processor; the positive and negative pressure cabin 1 is designed into a modular vacuum high-pressure cabin 1-11 according to the specific requirements of the intelligent positive and negative pressure module cabinet; the modular vacuum hyperbaric chamber 1-11 comprises: the device comprises a cabin body 1.1, a cabin door 1.2, a pneumatic airtight mechanism 1.5, an in-cabin outer sealing communicating vessel 1.4 and a pneumatic cabin door switch 1.8; the cabin door 1.2 is a cabinet door of the positive and negative pressure module cabinet; a pneumatic airtight mechanism 1.5 is arranged between the cabin door 1.2 and the cabin body 1.1 of the modular vacuum high-pressure cabin 1-11; the pneumatic airtight mechanism 1.5 comprises a pneumatic sealing bolt 1.51 and a sealing bolt telescopic air bag 1.52 integrally manufactured at the rear part of the sealing bolt 1.51; the sealing bolt 1.51 and the sealing bolt telescopic air bag 1.52 of the integrated mechanism are totally 4 and are all strip-shaped, the sealing bolts and the sealing bolt telescopic air bag are respectively installed in 4 cabin airtight grooves 1.11 arranged in 4 side frames of a door frame of a cabin 1.1, the outer layer part of the cross section of the bolt body is made of sealing rubber, and the inner part of the cross section of the bolt body is made of a bending-resistant metal core; the sealing bolt folding telescopic air bag 1.52 is an inflatable folding rubber air bag, and an inflatable socket 1.53 is arranged at the rear part of the air bag; an inflation plug 1.54 is inserted into the inflation socket 1.53, 4 inflation plugs 1.54 are arranged, the inflation plugs 1.54 are respectively installed and communicated with the middle points of the 4 side pipelines of the four sides of the square annular air-tight mechanism inflation branch pipeline A8.1, the top side pipeline of the pneumatic square annular inflation pipeline A8.1 is vertically connected with the inflation pipeline A8 and is communicated with the air outlet d of the inflator pump 3 through an electromagnetic valve B5, a pipeline A3 and an electromagnetic valve B3, when the cabin door is closed, the cabin door 1.2 touches the pneumatic cabin door switch 1.8, the inflator pump 3 is immediately started to inflate the sealing bolt folding telescopic airbag 1.52 to extend, and pushes the sealing bolt 1.51 to extend outwards from the air-tight groove 1.11 of the cabin body and extend into the air-tight cabin door groove 1.21 arranged at the corresponding position of the opposite side of the cabin door, so as to lock and seal the cabin door, when the cabin door is opened, the pneumatic cabin door folding telescopic airbag 1.52 is used as the sealing bolt folding airbag through the pneumatic cabin, retracting the sealing bolt 1.51 to open the hatch door; the communication device 1.4 for the inside and outside sealing is fixedly arranged at the rear part of the modular vacuum high-pressure cabin 1-11, and all pipelines and circuits for entering and exiting the inside and outside of the cabin are connected to and enter and exit through the communication device 1.4 for the outside and inside sealing so as to maintain the sealing performance of the modular vacuum high-pressure cabin 1-11. An air pump 2, an inflator pump 3, a positive and negative pressure intelligent regulation and control device 5, an air conditioning device 6.1, a superoxide decomposer 6.7, an air filter 6.8, a refrigeration and heating system 8.3, an air water production device 11, a filtering water tank 11.1, a pneumatic cabin door switch 1.8, a touch screen and a mobile phone monitoring system 12 are arranged outside the modular vacuum hyperbaric chamber 1-11; an air suction pipeline A1 is installed at the air inlet a of the air suction pump 2, an electromagnetic valve B1 is installed in the middle of the air suction pipeline A1, and the other end of the air suction pipeline A extends into the modular vacuum high-pressure cabin 1-11 to form an air suction return port c; an air outlet B of the air pump 2 is provided with an air exhaust pipeline A2, the middle part of the air exhaust pipeline A2 is provided with a superoxide decomposer 6.7 and an electromagnetic valve B2, the other end of the air exhaust pipeline A2 is communicated with an air inlet h of the air water making device 11, and air is introduced from an air outlet n of the air water making device 11; an air inflation pipeline A3 is installed at the air outlet d of the air inflation pump 3, an electromagnetic valve B3 is installed in the middle of the air inflation pipeline A3, and the other end of the air inflation pipeline A extends into the modular vacuum high-pressure cabin 1-11 to form an air inflation inlet f; an air inlet pipeline A4 is installed at an air inlet e of the inflator pump 3, an electromagnetic valve B4 and an air filter 6.8 are installed in the middle of the air inlet pipeline A4, and the other end of the air inlet pipeline is communicated with the atmosphere; the electromagnetic valve B4 is also connected with a circulating pipeline A5, the middle part of the circulating pipeline A5 is provided with an electromagnetic valve B5, the other end of the circulating pipeline A is communicated with an electromagnetic valve B3, and the circulating pipeline A3 extends into the modular vacuum high-pressure cabin 1-11 to form a circulating return air port j; the electromagnetic valve B5 is also connected with an airtight mechanism inflation pipeline A8, the airtight mechanism inflation pipeline A8 is communicated with an air outlet d of the inflator 3 through an electromagnetic valve B5 and an inflation pipeline A3, the other end of the inflation pipeline A8 is connected to a top side pipeline of a square annular inflation pipeline A8.1, four side pipelines of the square annular inflation pipeline A8.1 are communicated with each other, the middle point of the square annular inflation pipeline A8.1 is connected with an inflation plug 1.54, and the inflation plugs 1.54 are inserted into and connected to corresponding inflation sockets 1.53; the inflation pipeline A3 is also connected with an air-to-water inflation pipeline A9, and the air-to-water inflation pipeline A9 is connected to an electromagnetic valve B2 and communicated with an air inlet h of the air-to-water device 11 through an exhaust pipeline A2; an air-conditioned air inlet pipeline A6 is installed at the air inlet t of the air-conditioned device 6.1, an electromagnetic valve B6 is installed in the middle of the air-conditioned air inlet pipeline A6, the other end of the air-conditioned air inlet pipeline A3 is connected to an air inflation pipeline A3 and then is communicated with an air outlet d of the air inflation pump 3, an air-conditioned air outlet pipeline A7 is installed at the air outlet s of the air-conditioned device 6.1, an electromagnetic valve B7 is installed in the middle of the air-conditioned air outlet pipeline A7, and the other end of the air-conditioned; an air water making pipeline A10 is installed at a water outlet x of the air water making device 11, and the air water making pipeline A10 is communicated with a water inlet y of the filtering water tank 11-1; condensed water generated in the modular vacuum high-pressure cabin 1-11 flows into a water inlet Y of a condensed water collecting box 11.2 installed at the bottom of the cabin, a dehumidification condensed water pipeline A31 is installed at the other water inlet N of the condensed water collecting box 11.2, and the other end of the dehumidification condensed water pipeline A31 is connected at a condensed water outlet H of the dehumidification device; a condensed water pipeline A11 is installed at a water outlet M of the condensed water collecting box 11.2, the condensed water pipeline A11 extends out of the modular vacuum high-pressure cabin 1-11 and is provided with an electromagnetic valve B11 in the middle, the other end of the condensed water pipeline is communicated with a water inlet v of the filter water tank 11-1, a humidifying water pipeline A12 is installed at a water outlet o of the filter water tank 11.1, an electromagnetic valve B12 is installed in the middle of the humidifying water pipeline A12, and the other end of the condensed water pipeline extends into the modular vacuum high-pressure cabin 1-11 and is communicated with a water inlet R; the refrigerating and heating system 8.3 is provided with a circulating pipeline A13, and the circulating pipeline A13 extends into the modular vacuum high-pressure cabin 1-11 and is communicated with a heat exchanger 8.4; the touch screen and mobile phone monitoring system 12 includes: the mobile phone comprises a cabinet door touch screen 12.1, a mobile phone APP12.2 and a high-definition anti-fog camera 12.3, wherein the high-definition anti-fog camera 12.3 is arranged at a position needing to be monitored inside and outside a cabinet body 7; the inside setting of modular vacuum hyperbaric chamber 1-11 is installed positive negative pressure air current and is taken over thing and take place treater and sensor, includes: 6.5 of a humidifier, 6.9 of an air disinfection and sterilization device, 6.10 of an air filtration and refreshing device, 6.11 of a dehumidifying device, 11.2 of a condensed water collecting box, C1 of a pressure sensor, C2 of a negative pressure sensor, C3 of a super-oxygen sensor, C4 of a negative oxygen ion sensor, C5 of a chlorine dioxide sensor, C6 of a humidity sensor, C7 of an oxygen sensor, C8 of a nitrogen sensor, C9 of a temperature sensing controller, C10 of a water level sensing controller and C11 of air particulate matter sensors; all the airflow ballast generating processors, sensors, solenoid valves and equipment devices installed inside and outside the modular vacuum hyperbaric chambers 1-11 include: the air extracting pump 2, the inflator pump 3, the air conditioning device 6.1, the humidifier 6.5, the superoxide decomposer 6.7, the air sterilizing and disinfecting device 6.9, the air filtering and refreshing device 6.10, the dehumidifying device 6.11, the refrigerating and heating system 8.3, the heat exchanger 8.4, the air water making device 11, the filter water tank 11.1, the touch screen and mobile phone monitoring system 12, the cabinet door touch screen 12.1, the high-definition anti-fog camera 12.3, the pressure sensor C1, the negative pressure sensor C2, the superoxide sensor C3, the negative oxygen ion sensor C4, the chlorine dioxide sensor C5, the humidity sensor C6, the oxygen sensor C7, the nitrogen sensor C8, the temperature sensing controller C9, the water level sensing controller C10, the air particulate matter sensor C11 and the electromagnetic valves B1 to B12 are all connected to the positive and negative pressure intelligent control device 5.

It must be emphasized that: the positive negative pressure system of above-mentioned intelligence and a plurality of intelligent positive negative pressure electrical apparatus that uses this system are only the utility model discloses a plurality of preferred embodiments in the numerous schemes of embodiment have, and be not used for the restriction the utility model discloses the embodiment, the fan is in within the spirit and the principle of the utility model discloses any modification, equivalent replacement, improvement etc. of doing all should be contained within the scope of protection of the embodiment of the utility model.

Compared with the prior art, the embodiment of the utility model provides an intelligence positive and negative voltage system and the positive and negative voltage electricity ware of intelligence that uses this system's advantage lies in:

first, the current refrigerator basically only depends on the bacteriostatic storage method of low temperature and has not had technical breakthrough all the time, the embodiment of the utility model provides an intelligence positive negative pressure system and operation method and application intelligence positive negative pressure technique and operation method regulate and control and integrate vacuum, high pressure, superoxide, catalyst, multiple technological combinations such as vacuum, high pressure, air purification, air system water and low temperature storage and use to the electrical apparatus intelligently, just study out in the scientific research process of solving and better applying technologies such as vacuum, high pressure, superoxide, air-conditioned fresh-keeping to the refrigerator and having the technological problem at present in discussing the solution the utility model discloses an. The characteristics of vacuum and high pressure are known for a long time, the fruit, vegetable, meat and fish cannot be preserved and are not easy to be rotten by bacterial microorganisms in the vacuum, people are always attracted to store food by using the vacuum, however, oxygen does not exist in the vacuum, the anaerobic respiration of the fruit and vegetable can damage the quality and freshness of the fruit and vegetable, the cell and tissue structure of the fruit, vegetable, meat and fish can be destroyed by too low vacuum pressure, the internal moisture of the fruit, vegetable, meat and fish can be accelerated to escape and dissipate, the quality is reduced, the flavor is lost, and the ginseng is not practically applied to household appliances such as refrigerators because of the advantages and; the high-pressure technology is applied to the fields of freezing and refrigeration and the like, and researches are conducted for many years to prove that the technical problem that the food cannot be reversely damaged due to the generation of the largest ice crystal zone in normal-pressure freezing, unfreezing and freezing preservation by adopting the high-pressure bacteriostasis, high-pressure freezing, high-pressure unfreezing and high-pressure unfreezing refrigeration technology and the coordination configuration of pressure and temperature can be solved, the high-pressure freezing and unfreezing speed is much higher than that under normal pressure, however, a high-level vacuum and ultrahigh-pressure space is manufactured in the household appliance, the problems that the existing material and technical level are difficult to realize and the cost is too high to adapt to the household appliance are solved, and the vacuum and high-pressure technology is not practically applied to. The embodiment of the utility model provides a positive negative pressure technique and positive negative pressure system and operation method thereof uses atmospheric pressure or local instant atmospheric pressure as zero standard initial point, applies vacuum and high pressure of appropriate pressure to household appliances on the existing material and technical level, and along with the development of scientific technology, gradually develop and develop to superhigh pressure and ultralow pressure; the advantages of the superoxide that the superoxide can quickly sterilize, disinfect and degrade pesticide residues and organic dirt, inhibit the activity of enzyme, keep fruits, vegetables, meat and fish fresh and purify air and the like are always attracting people to apply the superoxide to production and life, however, the contact with the superoxide can harm the health of human bodies, and no ideal solution is always available when the superoxide is applied to electric appliances, so that the superoxide is not actually applied to refrigerators; controlled atmosphere preservation is a relatively advanced fruit and vegetable fresh-keeping storage method at present, by regulating and controlling the concentration proportion of oxygen, carbon dioxide and nitrogen in a storage space, the respiration of fruits and vegetables is inhibited, the consumption of organic substances is reduced, the original excellent flavor and aromatic smell are kept, metabolism is delayed, the breeding and propagation of certain pathogenic bacteria and the occurrence of physiological diseases are controlled, the fresh-keeping effect is much better than that of common refrigeration, the fresh-keeping period is obviously prolonged, the power consumption is relatively low, however, the controlled atmosphere storage needs an airtight space capable of resisting a certain pressure, mixed gas with the optimal matching ratio and the optimal concentration is produced and input into the storage space, meanwhile, waste gas is discharged timely, the discharging of the controlled atmosphere gas newly needs the accurate maintenance of a circulating system, and the like, which can not be done by common refrigerators; the refrigerator in the prior art has a fatal defect influencing fresh keeping, which is not solved or discovered or valued by people till now, namely, the refrigerator has no ventilation function, air in the refrigerator is polluted quickly, the fresh keeping effect is influenced, and the opening and closing of the refrigerator door has a little ventilation effect but is not thorough and unreliable; above all kinds of regrets are all in the embodiment of the utility model provides an solve basically, positive negative pressure system regulation and control air current, perhaps carry on multiple payload such as superoxide, gas catalyst, anion, gas conditioning gas, water, positive negative pressure cabin is passed in and out in order, just as people's breathing, exhale useless turbid gas, inhale fresh air, just can maintain vital energy, positive negative pressure system's accurate regulation and control makes the living fresh goods of positive negative pressure under-deck storage be in optimum atmospheric pressure scope, optimum gas composition, best humidity temperature, among the best storage environment, can be as long as possible keep fresh. Therefore, the embodiment of the utility model provides an integrate vacuum, high pressure, super oxygen, catalyst, gas conditioning fresh-keeping, anion, humidification, dehumidification, disinfection, air purification, air system water and multiple technologies such as low temperature storage with positive negative pressure system regulation and control, during the positive negative voltage electricity ware is used in the combination, give electrical apparatus respiratory function, let electrical apparatus live, upgrade and upgrade to current electrical apparatus and traditional technology, developed a positive negative voltage electricity ware segmentation field. Along with the rapid development of science and technology, the embodiment of the utility model provides a positive negative pressure that relates to use can be progressively to the vacuum and the superhigh pressure continuation of more degree of depth extend, including positive negative pressure cabin and hardware equipment such as the aerator of bleeding can be more economical suitable usefulness, software and hardware such as chip treater including positive negative pressure intelligent control device can progressively upgrade and upgrade, positive negative pressure technique can be perfect day by day, positive negative pressure electric appliance can give people and bring more beautiful life (the technical principle in the fresh-keeping carriage of intelligence positive negative pressure and intelligent positive negative pressure warehouse is the same with intelligent positive negative pressure refrigerator basic, its advantage does not describe in addition again).

Secondly, the existing washing machine only depends on the mechanical motion of a wave wheel or a rotary drum and is assisted by detergent to wash clothes, so that the washing efficiency is low due to large abrasion. The embodiment of the utility model provides an intelligent positive negative pressure washing machine intelligent control and integration technologies such as high pressure, vacuum, super oxygen combine the combination to use to the laundry, dehydration, stoving in-process, have reduced clothing wearing and tearing, have improved clothing cleanliness factor and fluffy degree, have increased super oxygen disinfection procedure, have effectively reduced the laundry time moreover.

Thirdly, the oil dirt cleaning problem of the existing range hood has no ideal solution all the time. The embodiment of the utility model provides a become all the other totally enclosed super oxygen cabins that are except that upper portion oil extraction smoke vent with smoke ventilator's organism global design, oil absorption smoke vent apron designs simultaneously for sealed hatch door, hatch door locking is sealed when starting self-cleaning, the top of machine case all is equipped with a plurality of autogiration shower heads with weight point greasy dirt department such as spiral case impeller, spray earlier that super oxygen water is high-efficient to decompose and get rid of the greasy dirt, reuse degreasing agent and clean hot water spray all around all cleanings to each position of quick-witted incasement, blow dry and discharge waste gas to the flue with quick-witted incasement portion is automatic with hot-blast at last. When the user starts the range hood, negative pressure is formed in the range hood, and air flows into the range hood from the side of the range hood, so that the range hood does not contact any superoxide at all. The sewage after washing the whole case flows down and is collected in the oil collecting long groove at the lowest part of the triangular case and is discharged to a sewer through an oil discharge outlet, so that the problem of automatic cleaning is thoroughly solved.

Fourth, the embodiment of the utility model provides an intelligence positive negative pressure oven air fryer microwave oven mainly is fried pot and microwave system setting with oven air in vacuum hyperbaric chamber, has really realized vacuum cooking and high-pressure cooking, so the peculiar smell of cooking food because of eating the material inflation in vacuum, especially the air is fried pot and is baked chips, cake etc. more soft delicious in suitable vacuum, cooks food because of condiment permeates easily in the high pressure so tasty very much. When the electric oven is not used, the positive and negative pressure cabins can be pumped into proper vacuum, the barbecue microwave system and the circuit system are in a vacuum state, and the electric oven is sterile, dust-free, pollution-free, clean, beneficial to health, free of oxidation, rusty and loss, and can be stored for prolonging the service life of an electric appliance.

Fifth, the utility model discloses positive negative pressure module cabinet of intelligence is provided with positive negative pressure system, possesses vacuum, high pressure, constant temperature, constant humidity, constant voltage, aseptic, dustless environment, can place the functional system design setting of various electrical apparatus and equipment in positive negative pressure module cabinet or direct mount wherein, include: the positive and negative pressure disinfection cabinet, the positive and negative pressure kitchen ware and tableware cabinet, the positive and negative pressure wine and fruit product display and refrigeration cabinet, the positive and negative pressure air conditioner indoor unit, the positive and negative pressure humidifier, the positive and negative pressure dehumidifier, the positive and negative pressure air purifier, the positive and negative pressure coffee and fruit juice small household electrical cabinet, the positive and negative pressure clothing bookcase, the positive and negative pressure painting and calligraphy and ancient and playing literature and material cabinet, the positive and negative pressure safe box and the positive and negative pressure material display cabinet with various functions; in addition, the intelligent positive and negative pressure system and the operation method thereof can be applied to the functional use, the disinfection storage and the placement of various electrical equipment and articles and tools and the nondestructive storage during the pause of the work.

Sixth, current domestic appliance designs alone basically, exclusive use, puts alone, the utility model discloses positive negative pressure intelligent electric appliance and positive negative pressure module cabinet are according to modular design, and outward appearance shape and color are unified basically, neatly close harmoniously and accord with fashion trend with advancing, and accessible touch screen and cell-phone APP are controld and discernment monitored control system and other positive negative pressure intelligent electric appliances and positive negative pressure module cabinet are organic to be combined for the whole combination house of intelligence that multiple functional not only can the exclusive use but also. Various kinds of positive and negative pressure module cabinets organically combine various kinds of related electrical equipment and article appliances in different categories, are placed in a concentrated mode, are tidy and attractive, share resources such as an air pump and an air pump of a smart positive and negative pressure system, save energy consumption, reduce noise and very conveniently and naturally integrate various kinds of related electrical equipment and article appliances into the same smart home system.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings needed to be used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to these drawings without inventive exercise.

Fig. 1 is a schematic diagram of a technical principle of an intelligent positive and negative pressure system provided by an embodiment of the present invention;

fig. 2 is a side view of the technical principle of the intelligent positive and negative pressure refrigerator provided by the embodiment of the present invention;

FIG. 3 is an enlarged view of the pneumatic sealing mechanism of the intelligent positive and negative pressure refrigerator according to the embodiment of the present invention;

FIG. 4 is an enlarged view of the pneumatic sealing mechanism of the intelligent positive and negative pressure refrigerator according to the embodiment of the present invention;

fig. 5 is a schematic front view of the intelligent positive and negative pressure refrigerator provided by the embodiment of the present invention;

FIG. 6 is a schematic diagram of the technical principle of the intelligent positive and negative pressure washing machine and an enlarged view of the mechanical airtight mechanism provided by the embodiment of the present invention;

FIG. 7 is a schematic diagram of the technical principle of the intelligent positive and negative pressure dish washing and fruit and vegetable washing machine and an enlarged view of a mechanical airtight mechanism provided by the embodiment of the utility model;

FIG. 8 is a schematic diagram of the technical principle of the intelligent superoxide water-washing range hood provided by the embodiment of the utility model, a side-view and bottom-view cross-sectional view of the automatic rotary spray ball and an enlarged view of the sealing waterproof mechanism;

FIG. 9 is a schematic diagram of the technical principle of an intelligent positive and negative pressure oven air fryer microwave oven and an enlarged view of a mechanical airtight mechanism provided by an embodiment of the present invention;

fig. 10 is a technical schematic diagram of an intelligent positive and negative pressure fresh-keeping carriage provided by the embodiment of the utility model;

fig. 11 is a schematic diagram of the technical principle of the intelligent positive and negative pressure fresh-keeping warehouse provided by the embodiment of the invention;

fig. 12 is a schematic diagram of a technical principle of an intelligent positive-negative pressure module cabinet provided by an embodiment of the present invention.

In the figure: the pipeline A1-A29, the electromagnetic valves B1-B23, the sensors C1-10 (a pressure sensor C1, a negative pressure sensor C2, a super oxygen sensor C3, a negative oxygen ion sensor C4, a chlorine dioxide sensor C5, a humidity sensor C6, an oxygen sensor C7, a nitrogen sensor C8, a temperature sensor C9, a water level sensor C10 and an air particulate sensor C11), the positive and negative ballast 1 (a cabin 1.1, a cabin airtight groove 1.11, a cabin reinforcement 1.12, a cabin door 1.2, a cabin airtight groove 1.21, a mechanical airtight mechanism 1.3, a lock ring 1.31, a lock tongue 1.32, an airtight gasket 1.33, a door edge gasket 1.34, an cabin internal external sealed communicated device 1.4, a pneumatic airtight mechanism 1.5, a pneumatic sealed lock tongue 1.51, a sealed lock tongue telescopic air bag 1.52, an inflatable bolt 1.53, an inflatable airtight plug 1.54, an electric airtight mechanism plug 1.61, an electric sealed bolt 1.62, a sealed spring 1.7, a waterproof spring 1.71, a waterproof lock ring mechanism, 1.72 of bolt, 1.73 of sealing washer, 1.74 of cabin door hinge, 1.8 of pneumatic cabin door switch, 1.9 of electric cabin door switch (vacuum high-pressure refrigeration cabin 1-1, vacuum high-pressure refrigeration cabin 1-2, ultra-high pressure deep cooling cabin 1-3, ultra-high pressure unfreezing cabin 1-4, vacuum high-pressure roller outer cabin 1-5, vacuum ultra-oxygen cabin 1-6, sealed waterproof ultra-oxygen cabin 1-7, microwave vacuum high-pressure cabin 1-8, chamber (box) type vacuum high-pressure cabin 1-9, storage type vacuum high-pressure cabin 1-10, modular vacuum high-pressure cabin 1-11), air pump 2 (anti-drenching negative air pumping port 2.1), air pump 3, positive and negative pressure intelligent regulation device 5 (ultra-oxygen intelligent regulation device 5.1), positive and negative pressure air flow carrying generation processor (air regulation device 6.1, ultra-oxygen generator 6.2, oxygen ion generator 6.3, catalyst controlled release device 6.4, 6.5 of humidifier, 6.6 of superoxide generation water mixer, 6.7 of superoxide decomposer, 6.8 of air filter, 6.9 of air disinfection and sterilization device, 6.10 of air filtration and refreshing device, 6.11 of dehumidifying device, 7 of box (machine) body, 8 of refrigerating system (8.1 of evaporator air cooling combination, 8.2 of evaporator direct cooling combination, 8.3 of refrigerating and heating system, 8.4 of heat exchanger), 9 of common refrigerating chamber, 10 of common refrigerating chamber, 11 of air water making device (11.1 of filter water tank, 11.2 of condensed water collecting box), 12 of touch screen and mobile phone monitoring system (12.1 of box door touch screen, 12.2 of mobile phone, 12.3 of high-definition anti-fog camera, 12.4 of wireless anti-fog camera), 15 of drying system (15.1 of roller mechanism, 15.2 of elution and drying control mechanism, 15.3 of roller sealing bearing seat, 15.4 of big belt pulley, 15.5 of motor combination), 16 of drainage pump, 17 of water pump, 18 of detergent, 19 of dish washing system, 20 of washing system, The device comprises an equipment smoke pipe cabin 21, a motor and wind wheel combination 22, an automatic rotating spray ball 23, an oil and water collecting and draining groove 24, a smoke exhaust control mechanism 26, a water heating device 27, a degreasing agent adding device 28, a smoke exhaust pipe 29, a barbecue system 30, an air fryer system 31 and a microwave system 32.

Detailed Description

The following is a detailed description of embodiments of the present invention, and further describes technical solutions of embodiments of the present invention, but the embodiments of the present invention are not limited to these embodiments and implementations.

In a first specific embodiment, the intelligent positive and negative pressure system includes: a positive and negative pressure cabin 1 (also known as a vacuum hyperbaric cabin), an air pump 2, an inflator pump 3, a positive and negative pressure intelligent regulation and control device 5 and a positive and negative pressure air flow carried object generation processor; the positive and negative ballast 1 includes: the device comprises a cabin body 1.1, a cabin door 1.2, an airtight mechanism 1.3 and a cabin inside and outside communicating sealer 1.4; an airtight mechanism 1.3 is arranged between the cabin body 1.1 and the cabin door 1.2; the communication device 1.4 for the outside sealing in the cabin is fixedly arranged at the rear part of the positive and negative pressure cabin 1, and all pipelines and circuits which enter and exit the cabin are connected to and enter and exit through the communication device 1.4 for the outside sealing in the cabin so as to keep the sealing performance of the positive and negative pressure cabin 1; the outside of the positive and negative pressure cabin 1 is provided with an air pump 2, an inflator pump 3, a positive and negative pressure intelligent regulation and control device 5 and an air conditioning device 6.1 of a positive and negative pressure airflow carried object generating processor; an air suction pipeline A1 is installed at an air inlet a of the air suction pump 2, an electromagnetic valve B1 is installed in the middle of the air suction pipeline A1, the other end of the air suction pipeline A1 extends into the positive and negative pressure cabin 1 to form an air suction return port c, an air exhaust pipeline A2 is installed at an air outlet B of the air suction pump 2, and the other end of the air exhaust pipeline A2 is communicated with the atmosphere; an air inflation pipeline A3 is installed at an air outlet d of the air inflation pump 3, an electromagnetic valve B3 is installed in the middle of the air inflation pipeline A3, the other end of the air inflation pipeline A3 extends into the positive and negative pressure cabin 1 to form an air inflation inlet f of the air inflation pipeline, an air inlet pipeline A4 is installed at an air inlet e of the air inflation pump 5, an electromagnetic valve B4 is installed in the middle of the air inlet pipeline A4, and the other end of the air inlet pipeline; the electromagnetic valve B4 is also connected with a circulating pipeline A5, the middle part of the circulating pipeline A5 is provided with an electromagnetic valve B5, the other end of the circulating pipeline A is connected with an electromagnetic valve B3 and extends into the positive and negative pressure cabin 4 through an inflation pipeline A3 to form a circulating return air port j; an air-conditioned air inlet pipeline A6 is installed at the air inlet t of the air-conditioned device 6.1, an electromagnetic valve B6 is installed in the middle of the air-conditioned air inlet pipeline A6, the other end of the air-conditioned air inlet pipeline is connected to an air charging pipeline A3 and then communicated with an air outlet d of the air charging pump 3, an air-conditioned air outlet pipeline A7 is installed at the air outlet s of the air-conditioned device 6.1, an electromagnetic valve B7 is installed in the middle of the air-conditioned air outlet pipeline A7, the other end of the air-conditioned air outlet pipeline extends into the positive and negative pressure cabin 1 to form an air-conditioned air inlet i thereof, and when the; positive negative pressure air current carry thing generation treater is also installed to the inside of positive negative pressure cabin 1, includes: 6.2 parts of a superoxide (ozone) generator, 6.3 parts of an anion generator, 6.4 parts of a gas catalyst release controller and 6.5 parts of a humidifier; the inside of positive negative pressure cabin 1 still installs the sensor, includes: a pressure sensor C1, a negative pressure sensor C2, a superoxide sensor C3, a negative oxygen ion sensor C4, a chlorine dioxide sensor C5, a humidity sensor C6, an oxygen sensor C7 and a nitrogen sensor C8; the air pump 2, the inflator pump 3, the air conditioning device 6.1, the superoxide generator 6.2, the anion generator 6.3, the gas catalyst controlled release device 6.4, the humidifier 6.5, all sensors C1-C8 and all electromagnetic valves B1-B7 are all connected to the positive and negative pressure intelligent control device 5.

The technical principle and the basic operation method of the intelligent positive and negative pressure system are as follows: the air flow is intelligently regulated and controlled by positive and negative pressure, or various effective loads such as superoxide, gas catalyst, negative ions, gas-regulated gas, water and the like are carried, and the air flow orderly enters or stays in a specific space (positive and negative ballast) and exerts required influence on articles in the space; the specific operation method of the intelligent positive and negative pressure system comprises the following steps: the positive and negative pressure intelligent regulation and control device 5 sends specific opening or closing instructions to the air pump 2, the inflator pump 3, the positive and negative pressure air flow carrying object generating processor and the electromagnetic valve in real time after calculation processing according to a built-in program, pre-stored data and real-time feedback information of each sensor C1-C8, controls and adjusts the opening, closing and conversion of each air suction pipeline, each air inflation pipeline and each circulating pipeline, and intelligently regulates the level of positive and negative pressure in the positive and negative pressure cabin 1 and the inflow, the residence or the outflow of the carrying objects, and the specific operation method comprises the following steps: (1) the operation method for regulating the inside of the positive and negative pressure cabin 1 to negative pressure (vacuum) comprises the following steps: the positive and negative pressure intelligent control device 5 sends out an instruction to enable the electromagnetic valve B1 to open an air suction pipeline A1 and an air suction pipeline A2 (the air suction return port c of the positive and negative pressure cabin → an air suction pipeline A1 → the electromagnetic valve B1 → A1 → the air suction pump air inlet a → the air suction pump air outlet B → A2 → air discharge) (when any pipeline is open, all other irrelevant electromagnetic valves are closed, which is not described again later), and the air suction pump 2 is opened to suck air in the positive and negative pressure cabin 1 to set negative pressure (vacuum); (2) the operation method for regulating the pressure in the positive and negative ballast 1 to be positive pressure (high pressure) comprises the following steps: the positive and negative pressure intelligent control device 5 sends out instructions to enable the electromagnetic valves B3 and B4 to open the air charging pipelines A3 and A4 (air charging from atmosphere → A4 → B4 → A4 → the air inlet e of the inflator → the air outlet d of the inflator → A3 → B3 → A3 → the air inlet f of the positive and negative ballast), and the inflator 3 is started to charge the positive and negative ballast 1 to set positive pressure (high pressure); and (3) the operation method for regulating the air flow and the inflow, residence or outflow of the carried substances of the air flow into the positive and negative ballast 1 comprises the following steps: firstly, flowing out: pumping the air flow and the carried objects thereof out of the positive and negative pressure cabins through an air pumping pipeline by using an air pumping pump 2 according to the concrete method (1); and secondly, flowing into: inflating the air flow and the carried objects thereof into the positive and negative pressure cabins through an inflation pipeline by using an inflator pump 3 according to the specific method (2); thirdly, staying: when positive and negative pressure air flow or carried objects thereof need to be resided in the positive and negative pressure cabins, the positive and negative pressure intelligent control device 5 sends an instruction to open the air pump 2 and the air pumping pipeline or open the inflator 3 and the air charging pipeline or open the positive and negative pressure air flow carried object generation processor in the positive and negative pressure cabins, and close other irrelevant electromagnetic valves until the values of the positive and negative pressure or air flow carried objects in the cabins and the residence time reach the standards; fourthly, circulation: the air flow or its carried objects such as air-conditioned gas need to circularly flow through the positive and negative ballast 1 and the air-conditioned device 6.1 to make the concentration of the air in the positive and negative ballast reach the standard, the intelligent positive and negative pressure control device 5 sends out a command to open the solenoid valves B6 and B7 on the air-conditioned air charging pipelines A6 and A7 (air pump air outlet d → A3 → A6 → B6 → A6 → air inlet t → air outlet → A7 → B7 → A7 → positive and negative ballast air-conditioned air inlet i), and simultaneously open the solenoid valves B3, B4 and B5 on the air-conditioned air charging pipelines A3, A5 and A4 (positive and negative ballast air-circulating air returning j → A3 → B3 → A5 → B5 → A5 → B4 → A4 → air inlet e of the air-charging pump), and open the air-charging pump 3 to make the air-conditioned air circularly flow until the concentration, the positive and negative; the intelligent positive and negative pressure system uses the method, intelligently regulates and integrates various technologies such as vacuum, high pressure, superoxide, catalyst, air conditioning preservation, negative ion, humidification, dehumidification, disinfection, air purification, air water production, low-temperature storage and the like, and multiple combinations or single items are applied to electrical equipment, transport carriage containers, storage warehouses and the like, and the intelligent positive and negative pressure system is used due to the arrangement, and is uniformly and simply called as follows: an intelligent positive and negative piezoelectric device; the intelligent positive and negative piezoelectric device in the embodiment of the invention comprises: the intelligent positive and negative pressure refrigerator, the intelligent positive and negative pressure washing machine, the intelligent vacuum dish washing fruit and vegetable cleaning machine, the intelligent super oxygen washing range hood, the intelligent positive and negative pressure oven fryer microwave oven, the intelligent positive and negative pressure fresh-keeping carriage, the intelligent positive and negative pressure fresh-keeping warehouse and the intelligent positive and negative pressure module cabinet.

In a second specific embodiment, the intelligent positive and negative pressure refrigerator comprises a refrigerator body 7; an intelligent positive-negative pressure system, a refrigerating system 8, a common refrigerating chamber 9, a common freezing chamber 10, an air water making device 11 and a touch screen and mobile phone monitoring system 12 are arranged in the box body 7; the intelligent positive and negative pressure system comprises a positive and negative pressure cabin 1, an air pump 2, an inflator pump 3, a positive and negative pressure intelligent regulation and control device 5 and a positive and negative pressure airflow carried object generation processor; the positive and negative ballast 1 includes: the device comprises a cabin body 1.1, a cabin door 1.2, an in-cabin outer sealing communicating vessel 1.4, a pneumatic airtight mechanism 1.5, an electric airtight mechanism 1.6, a pneumatic cabin door switch 1.8 and an electric cabin door switch 1.9; the cabin door 1.2 is a cabin door of the positive and negative pressure refrigerator; the positive and negative pressure cabin 1 is designed into a vacuum high-pressure refrigerating cabin 1-1 and a vacuum high-pressure freezing cabin 1-2 according to the specific requirements of refrigeration and freezing of a refrigerator; a pneumatic airtight mechanism 1.5 is arranged between the cabin door 1.2 and the cabin body 1.1 of the vacuum high-pressure refrigerating cabin 1-1; the pneumatic airtight mechanism 1.5 comprises a pneumatic sealing bolt 1.51 and a sealing bolt telescopic air bag 1.52 integrally manufactured at the rear part of the sealing bolt 1.51; the sealing bolt 1.51 and the sealing bolt telescopic air bag 1.52 of the integrated structure are totally 4 and are all strip-shaped, and are respectively installed in 4 cabin body airtight grooves 1.11 arranged in 4 side frames of a door frame of a cabin body 1.1, the outer layer part of the cross section of the bolt body is sealing rubber, and the inner part of the cross section of the bolt body is a bending-resistant metal core; the sealing bolt folding telescopic air bag 1.52 is an inflatable folding rubber air bag, and an inflatable socket 1.53 is arranged at the rear part of the air bag; an inflation plug 1.54 is inserted into the inflation socket 1.53, 4 inflation plugs are arranged in the inflation plug 1.54, the inflation plugs are respectively installed and communicated at the middle points of the four side pipelines of the four sides of the square annular air-tight mechanism inflation branch pipeline A8.1, the bottom side pipeline of the square annular air-tight mechanism inflation branch pipeline A8.1 is vertically connected with the air-tight mechanism inflation pipeline A8, and is communicated with the air outlet d of the inflation pump 3 through an electromagnetic valve B8, a pipeline A3 and an electromagnetic valve B3; when the cabin door is closed, the cabin door 1.2 touches a pneumatic cabin door switch 1.8, the inflator pump 3 is started immediately to inflate the sealing bolt folding telescopic airbag 1.52 to extend, and pushes the sealing bolt 1.51 to extend out of the cabin body airtight groove 1.11 and extend into the cabin door airtight groove 1.21 arranged at the opposite corresponding position, so as to lock and seal the cabin door, when a user opens the cabin door, the sealing bolt folding telescopic airbag 1.52 is deflated through the pneumatic cabin door switch 1.8, so that the sealing bolt 1.51 retracts to open the cabin door; an electric airtight mechanism 1.6 is arranged between the cabin door 1.2 and the cabin body 1.1 of the vacuum high-pressure freezing cabin 1-2; the electric airtight mechanism 1.6 comprises an electric sealing bolt 1.61, an electromagnet 1.62 and a tension spring 1.63; the number of the sealing lock tongues 1.61 is 4, the sealing lock tongues are all strip-shaped, the sealing lock tongues are respectively and movably arranged in 4 cabin body airtight grooves 1.11 arranged in the periphery of a cabin body door frame and are hung on a tension spring 1.63, and the other end of the tension spring is fixedly hung at the bottom in the cabin body airtight grooves 1.11; the outer layer part of the cross section of the tongue body of the sealing bolt 1.61 is a sealing rubber layer, the interior of the tongue body is a bending-resistant and magnetic-attracting metal core, the sealing rubber layer facing one side of the electromagnet 1.62 is open, and the metal core in the interior is partially exposed so as to be attracted by the electromagnet 1.62; the electromagnet 1.62 is also a strip shape corresponding to the shape of the sealing bolt 1.61, and is fixedly arranged in the bottom of the cabin door air-tight groove 1.21 corresponding to the position of the cabin body air-tight groove 1.11, when the door needs to be sealed after being closed, the electric cabin door switch 1.9 energizes the electromagnet 1.62 to generate magnetic force, the sealing bolt 1.61 arranged in the opposite cabin body air-tight groove 1.11 is attracted into the cabin door air-tight groove 1.21, the power-off magnetic force of the electric cabin door switch 1.9 to the electromagnet 1.62 disappears when the door is opened, and the tension spring 1.63 pulls the sealing bolt 1.61 back into the cabin body air-tight groove 1.11 to open the cabin door; the communication device 1.4 for the outside sealing in the cabin is fixedly arranged at the rear part of the positive and negative pressure cabin 1, and all pipelines and circuits for entering and exiting the inside and outside of the cabin are connected to and enter and exit through the communication device 1.4 for the outside sealing in the cabin so as to keep the sealing performance of the positive and negative pressure cabin 1. An air pump 2, an inflator pump 3, a positive and negative pressure intelligent regulation and control device 5, an air conditioning device 6.1, a superoxide decomposer 6.7, an air filter 6.8, a refrigeration system 8, an air water making device 11, a filtering water tank 11.1, a touch screen and a mobile phone monitoring system 12 are arranged outside the positive and negative pressure cabin 1; an air suction pipeline A1 is installed at an air inlet a of the air suction pump 5, the air suction pipeline A1 is respectively connected with air suction branch pipelines A1.1 and A1.2, the middles of the air suction branch pipelines A1.1 and A1.2 are respectively provided with electromagnetic valves B1.1 and B1.2, and the other ends of the air suction branch pipelines respectively extend into the vacuum high-pressure refrigerating cabin 1-1 and the vacuum high-pressure freezing cabin 1-2 to form air suction return ports c1 and c 2; an air outlet B of the air pump 2 is provided with an air exhaust pipeline A2, the middle part of the air exhaust pipeline A2 is provided with a superoxide decomposer 6.7 and an electromagnetic valve B2, the other end of the air exhaust pipeline A2 is communicated with an air inlet h of the air water making device 11, and the air is communicated with the atmosphere through an air outlet n of the air water making device 11; an air charging pipeline A3 is installed at an air outlet d of the air charging pump 3, an electromagnetic valve B3 is installed in the middle of the air charging pipeline A3, the other end of the air charging pipeline A3 is connected with air charging branch pipelines A3.1, A3.2, A3.3 and A3.4 respectively, electromagnetic valves B3.1, B3.2, B3.3 and B3.4 are installed in the middle of the air charging branch pipelines A3.1, A3.2, A3.3 and A3.4 respectively, the other ends of the air charging branch pipelines extend into the vacuum high-pressure refrigeration cabin 1-1 and the vacuum high-pressure refrigeration cabin 1-2 respectively, and an air charging air inlet f1 of the vacuum high-pressure refrigeration cabin 1-1 is formed at the other end port of the A; the other end port of A3.2 forms an air charging inlet f2 of the vacuum high-pressure freezing chamber 1-2; the other end of the A3.3 is connected to an air inlet G of the ultrahigh pressure thawing compartment 1-3; the other end of A3.4 is connected to an air inlet Q of the ultrahigh pressure deep cooling cabin 1-4; an air inlet pipeline A4 is installed at an air inlet e of the inflator pump 3, an air filter 6.8 and an electromagnetic valve B4 are installed in the middle of the air inlet pipeline A4, and the other end of the air inlet pipeline is communicated with the atmosphere; the electromagnetic valve B4 is also connected with a circulating pipeline A5, the circulating pipeline A5 is connected to circulating branch pipelines A5.1 and A5.2, the middles of the circulating branch pipelines A5.1 and A5.2 are respectively provided with electromagnetic valves B5.1 and B5.2, and the other ends of the circulating branch pipelines respectively extend into the vacuum high-pressure refrigerating cabin 1-1 and the vacuum high-pressure freezing cabin 1-2 to form circulating air return ports j1 and j 2; the circulating pipeline A5 is also connected with an air-to-water inflation pipeline A9, the air-to-water inflation pipeline A9 is connected to a solenoid valve B2 and communicated with an air inlet h of the air-to-water device 11 through an exhaust pipeline A2, the air-to-water inflation pipeline A9 is connected with a circulating pipeline A5 and communicated with a solenoid valve B3, and then communicated with an air outlet d of the inflator pump 3 through an inflation pipeline A3; a modified atmosphere air inlet pipeline A6 is installed at an air inlet t of the modified atmosphere device 6.1, a solenoid valve B6 is installed in the middle of the modified atmosphere air inlet pipeline A6, the other end of the modified atmosphere air inlet pipeline A6 is connected to an air inflation pipeline A3, then the solenoid valve B3 is communicated with an air outlet d of the air inflation pump 3, modified atmosphere air outlet pipelines A7.1 and A7.2 are installed at air outlets s1 and s2 of the modified atmosphere device 6.1 respectively, solenoid valves B7.1 and B7.2 are installed in the middle of the modified atmosphere air outlet pipelines A7.1 and A7.2 respectively, and the other ends of the modified atmosphere air outlet pipelines extend into the vacuum high-pressure refrigerating compartment 1-1 and the vacuum high-pressure freezing compartment 1-2; the inflation pipeline A3 is also connected to an airtight mechanism inflation pipeline A8, the middle part of the airtight mechanism inflation pipeline A8 is provided with an electromagnetic valve B8, and the other end of the airtight mechanism inflation pipeline A is vertically connected to a bottom pipeline of a square annular airtight mechanism inflation branch pipeline A8.1; four side pipelines of the square annular air-tight mechanism inflation branch pipeline A8.1 are communicated with each other, the midpoint positions of the four side pipelines are provided with inflation plugs 1.54, and the four inflation plugs 1.54 are inserted into and connected to the inflation sockets 1.53; an air water making pipeline A10 is installed at the water outlet x of the air water making device 11, and the air water making pipeline A10 is communicated with the water inlet y of the filtering water tank 11.1; condensed water generated in the vacuum high-pressure refrigerating chamber 1-1 flows into a water inlet Y of a condensed water collecting box 11.2 arranged at the bottom in the vacuum high-pressure refrigerating chamber, a condensed water pipeline A11 is arranged at a water outlet M of the condensed water collecting box 11.2, an electromagnetic valve B11 is arranged in the middle of the condensed water pipeline A11 after extending out of the vacuum high-pressure refrigerating chamber 1-1, the other end of the condensed water pipeline is communicated with a water inlet v of a filter water tank 11.1, a humidifying water pipeline A12 is arranged at a water outlet o of the filter water tank 11.1, an electromagnetic valve B12 is arranged in the middle of the humidifying water pipeline A12, and the other end of the humidifying water pipeline extends into the vacuum; the refrigerating system 8 is provided with a refrigerating circulation pipeline A13, and the refrigerating circulation pipeline A13 extends into the vacuum high-pressure refrigerating chamber 1-1, the vacuum high-pressure freezing chamber 1-2, the common refrigerating chamber 9 and the common freezing chamber 10 respectively and is communicated with an evaporator air cooling combination 8.1 and an evaporator direct cooling combination 8.2 which are arranged in the refrigerating system respectively; the touch screen and mobile phone monitoring system 12 includes: the mobile phone comprises a box door touch screen 12.1, a mobile phone APP12.2 and a high-definition anti-fog camera 12.3, wherein the high-definition anti-fog camera 12.3 is arranged at a position to be monitored inside and outside the box body 7; positive negative pressure air current carry thing generation treater and sensor are installed in the inside setting of positive negative pressure ballast 1, include: the vacuum high-pressure refrigerating chamber 1-1 is provided with: 6.2 parts of an ultrasonic generator, 6.3 parts of an anion generator, 6.4 parts of a gas catalyst controlled release device, 6.5 parts of a humidifier, 11.2 parts of a condensed water collecting box, a pressure sensor C1, a negative pressure sensor C2, a superoxide sensor C3, a negative oxygen ion sensor C4, a chlorine dioxide sensor C5, a humidity sensor C6, an oxygen sensor C7, a nitrogen sensor C8 and a temperature sensor C9; the device is arranged and installed in a vacuum high-pressure freezing cabin 1-2 and comprises: 6.4 of a gas catalyst controlled release device, a pressure sensor C1, a negative pressure sensor C2, a chlorine dioxide sensor C5, an oxygen sensor C7, a nitrogen sensor C8 and a temperature sensor C9; all airflow carrying object generation processors, sensors, electromagnetic valves and equipment devices installed inside and outside the positive and negative pressure cabin 1 comprise: the device comprises an air extracting pump 2, an air charging pump 3, an air conditioning device 6.1, an ultra-oxygen generator 6.2, an anion generator 6.3, a gas catalyst controlled release device 6.4, a humidifier 6.5, an ultra-oxygen decomposer 6.7, a refrigeration system 8, an air water making device 11, a filter water tank 11.1, an ultra-high pressure thawing cabin 1-3, an ultra-high pressure deep cooling cabin 1-4, a touch screen and mobile phone monitoring system 12, a box door touch screen 12.1, a high-definition anti-fog camera device 12.3, a pressure sensor C1, a negative pressure sensor C2, an ultra-oxygen sensor C3, a negative oxygen ion sensor C4, a chlorine dioxide sensor C5, a humidity sensor C6, an oxygen sensor C7, a nitrogen sensor C8, a temperature sensing controller C9, a water level sensing controller C10 and electromagnetic valves B1-B12, and is connected to the positive and.

The operation method of the intelligent positive and negative pressure refrigerator comprises the following steps: (1) and vacuum pest and heat removing cleaning procedure: closing the vacuum high-pressure refrigerating cabin door 1.2 of the positive and negative pressure refrigerator, touching the cabin door switch 1.8, the positive and negative pressure intelligent regulation and control device 5 sends out an instruction: the electromagnetic valves B3 and B8 open the inflation pipelines of the A3, A8 and A8.1 airtight mechanisms (the inflator outlet d → A3 → B3 → A3 → A8 → B8 → A8 → A8.1 → the inflation plug 1.54 → the inflation socket 1.53 → the sealed bolt telescopic air bag 1.52), and the inflator 3 is started to inflate the pneumatic airtight mechanism 1.5 and lock the cabin door 1.2; simultaneously, the electromagnetic valves B1.1 and B2 are opened with air suction pipelines A1, A1.1 and A2 (air suction return air port c1 → A1.1 → B1.1 → A1.1 → A1 → air suction pump air inlet a → air outlet B → A2 → superoxide decomposer air inlet g → air outlet m → A2 → B2 → A2 → air water making device air inlet h → air outlet n → A2 → air exhaust into the atmosphere), the air suction pump 2 is started to suck the vacuum high-pressure refrigerating cabin 1-1 to moderate vacuum (-0.01KPa to-0.1 MPa) (the local instant air pressure is zero standard, the instant air pressure is the same in the text, the vacuum degree can be increased according to the specific requirements and the configuration of the refrigerator), the fruit and vegetable flesh fish with heat, part of the bacteria microorganism and the dirty air in the cabin are removed, the vacuum promotes the volatile metabolite ethylene and acetaldehyde in the tissue to escape and the harmful gas is pumped away, and the propagation of the bacteria is inhibited by the negative pressure, the hidden danger of disease and aging of the fruits and the vegetables is reduced; (2) and a reduced-pressure humidification storage procedure: the positive and negative pressure intelligent control device 5 maintains a proper negative pressure low oxygen low temperature environment in the vacuum high pressure refrigeration cabin 1-1 by opening or closing the air pump 2 according to the pressure standard of a preset program and the real-time feedback of the negative pressure sensor C2, reduces the respiration intensity of fruits and vegetables, inhibits the biosynthesis of ethylene, delays the decomposition of chlorophyll, inhibits the synthesis of carotenoid and lycopene, slows down the hydrolysis of starch, the increase of sugar, the consumption of acid and other processes, thereby delaying the maturation and aging of the fruits and vegetables, simultaneously opens the humidifier 6.5 to improve the humidity in the cabin, prevents the moisture of the fruits and vegetables from escaping, and maintains the fresh state of the fruits and vegetables for a longer time; (3) and the superoxide pressure sterilization degradation program: the positive and negative pressure intelligent control device 5 timely sends out instructions to start the superoxide generator 6.2, the negative oxygen ion generator 6.3 and the humidifier 6.5 according to program setting and feedback of sensors C3, C4 and C6 to enable the superoxide, humidity and negative oxygen ions in the vacuum high-pressure refrigeration cabin 1-1 to reach the required standards, meanwhile, electromagnetic valves B3, B3.1 and B4 are enabled to open air charging pipelines A3, A3.1 and A4 (air charging → A4 → B4 → A4 → air cleaner → A4 → air charging pump air inlet e → air outlet d → A3 → B3 → A3 → A3.1 → B3.1 → A3.1 → vacuum high-pressure refrigeration cabin 1-1 air charging inlet f1), the air charging pump 3 is started, the vacuum high-pressure refrigeration cabin 1-1 is properly pressurized to 0.01 KPa-10 MPa (the local instant air pressure is zero standard, the vacuum high-pressure refrigeration cabin is configured to improve the pressure sterilization and sterilization of the residual fish in the vacuum high-pressure sterilization and sterilization) are properly pressurized to suck out the superoxide, and sterilize the residual fish The gas such as ethylene influences the activity of enzyme in fruits and vegetables, prevents browning and softening of the fruits and vegetables, delays the aging of the fruits and vegetables, prevents moisture in the flesh and fish of the fruits and vegetables from escaping under proper high pressure, and the moisture is easier to permeate and supplement the moisture lost due to refrigeration, negative pressure and the like to the flesh and fish of the fruits and vegetables under positive pressure, and negative oxygen ions enable the size of water molecular groups of the moisture to be smaller and the moisture to be more convenient for the flesh and fish of the fruits and vegetables to absorb, and the gas has the functions of inhibiting biological tissue metabolism, reducing respiratory strength, slowing down the activity of enzyme and certain sterilization and purification, and the super oxygen can permeate into the deeper inner part of the flesh and fish of the fruits and vegetables under positive pressure to better play the sterilization and disinfection functions (the super oxygen can be automatically decomposed and reduced into oxygen in air and water within about 30 minutes, but the very long stable half-life; (4) controlled atmosphere pressurized storage procedure: the positive negative pressure intelligent control device 5 timely opens an air suction pipeline and opens the air suction pump 2 and the superoxide decomposer 6.7 according to program setting or sensor feedback, the decomposed, sterilized and degraded dirty air is sucked out of the cabin, then the electromagnetic valves B3, B6 and B7.1 open the air inlet A3, A6, A7.1 air-conditioning inflation pipeline (the air outlet d of the air suction pump → A3 → B3 → A3 → A6 → B6 → A6 → the air inlet t of the air-conditioning device → the air outlet s1 → A7.1 → B7.1 → A7.1 → the vacuum high-pressure refrigeration cabin 1-1 air-conditioning air inlet 1) is opened, the air suction pump 3 is driven to pass through the hollow fiber membrane of the air-conditioning device 8.1, oxygen is separated out, high-nitrogen hypoxic gas enters the air inlet 1-1 of the vacuum high-pressure refrigeration cabin, and the electromagnetic valves B5.1, B6866 open the air-conditioning circulation pipeline (the vacuum high-pressure air inlet 351-5 → A → B → 5.4642 → A → B → 42 → A4 → A3), meanwhile, the humidifier 6.5 is started until the concentration of the modified atmosphere gas, the air humidity and the positive air pressure in the cabin reach the modified atmosphere pressurized storage standard, a nitrogen-rich oxygen-poor environment with a proper proportion is formed in the vacuum high-pressure cabin, a proper positive pressure and a proper humidity are kept, the respiration rate of the stored fruits and vegetables is effectively controlled, anaerobic respiration and carbon dioxide poisoning are prevented, the aging process is delayed, the quality reduction and flavor loss of the stored fruits and vegetables are prevented, the moisture of the fruits and vegetables is kept and supplemented by positive pressure, and the freshness of the fruits and vegetables is maintained to the maximum extent; (5) and the leftovers food pressurized preservation program: the method comprises the steps that leftovers are placed in a vacuum high-pressure refrigerating chamber 1-1, an air suction pump 2 and an air suction pipeline are started by a regulating device 5, smell emitted by the leftovers and foul air in the chamber are sucked out of the chamber and then closed, an air pump 3 and an air charging pipeline are started to be properly pressurized and stored, excessive loss of smell and moisture is prevented, deterioration and corrosion are inhibited, meanwhile, a humidifier 6.5 is started timely to supplement moisture in the air according to feedback information of a humidity sensor, or an ultra-oxygen generator 6.2 is started timely to kill bacteria in the air in the chamber to prevent food from being damaged; (6) low-temperature auxiliary fresh-keeping procedure: after the refrigerator is started, the positive and negative pressure intelligent control device 5 starts the refrigerating system 8, is communicated with the evaporator air cooling combination 8.1 and the evaporator direct cooling combination 8.2 through a refrigerating pipeline A13, provides corresponding low temperature for each cabin through the feedback and control of a temperature sensing controller C9, and assists the positive and negative pressure system to keep the stored articles fresh; (7) high-pressure quick freezing and unfreezing and high-pressure unfreezing storage procedures: the ultrahigh pressure deep cooling cabin 1-3 is arranged in the freezing area of a positive and negative pressure refrigerator, the ultrahigh pressure unfreezing cabin 1-4 is arranged in the cold storage area and is specially used for high-quality freezing preservation, unfreezing preservation and high-pressure unfreezing storage of meat, fish and seafood and the like, the air pump 3 is used for pressurizing the high-pressure deep cooling cabin, certain ultrahigh pressure can influence the freezing point, the crystallization process and the size and shape of ice crystals of meat, fish tissues and water in cells, the freezing point of water is reduced along with the increase of the pressure in the range of 0 to 209.9MPa, the fish can be frozen at the lowest temperature of-21.99 ℃ under the pressure of 209.9MPa, by utilizing the principle, the largest ice crystals in normal-temperature freezing can be avoided to form a maximum zone, the problem that the largest ice crystal zone stays for a long time to damage fish tissues and cells in the conventional normal-pressure freezing and unfreezing is solved to a certain extent, and the quality, flavor, although the prior art and materials have not been able to provide the inventive hyperbaric chamber in a refrigerator at a suitably low cost, it is rapidly becoming more and more practical with technological advances; (8) and the protection function is arranged when the door is opened: if someone opens the refrigerator door during the superoxide sterilization or air-conditioned storage, the door switch feeds back immediately, the positive and negative pressure intelligent control device 5 operates immediately to stop the superoxide or air-conditioned program, simultaneously opens the air extraction pipeline and starts the air extraction pump 2, the superoxide or high-nitrogen low-oxygen gas is quickly extracted to the superoxide decomposer 6.7 at the rear side of the refrigerator to be decomposed and then discharged, and because the air is supplemented with the air extraction negative pressure from the side of the human body to the vacuum high-pressure refrigerating chamber, the user can not contact the superoxide and high-nitrogen low-oxygen gas and is prevented from being damaged. (9) The air water making program is that moist waste gas pumped out from the vacuum high-pressure cabin by the air pump 2 enters the superoxide decomposer 6.7 to decompose superoxide and then enters the air water making device 11, the water is condensed and filtered into drinking standard purified water to provide an uninterrupted water source for the humidifier 6.5, and when the inflator pump 3 is idle, the intelligent control device 5 can also start the inflator pump 3 and enable the electromagnetic valves B3 and B2 to open an air water making inflation pipeline (the air outlet d → A3 → B3 → A5 → A9 → B2 → A2 → the air inlet h of the air water making device) to drive indoor air to enter the air water making device 11 to make water; (10) and remote and near range operation monitoring function: the touch screen and mobile phone monitoring system 12 can control and monitor the refrigerator, other positive and negative voltage devices and the positive and negative voltage module cabinets in real time through WIFI and mobile phone APP far and near ranges, so that the refrigerator, all other positive and negative voltage devices and the module cabinets can intelligently realize various functions with high efficiency and low consumption according to set programs and instant instructions; the high-definition anti-fog camera device 12.3 shoots the conditions of articles in the refrigerator in real time, the refrigerator door touch screen 12.1 or the mobile phone APP12.2 can display and remind commodity information such as production time, price, quality guarantee period, manufacturers and the like and information of purchasers and online stores, automatically records, analyzes and collates big data such as time, quantity and frequency preference of the refrigerator for taking out articles, and carries out intelligent analysis, and then reminds in time on the mobile phone APP12.2 or directly pushes recommended commodities to be purchased to the mobile phone APP12.2 and the refrigerator door touch screen 12.1 for a user to conveniently select and purchase; the high-definition anti-fog camera device 12.3 is used for monitoring and recording in real time, and particularly, starting from a position far away from a refrigerator body in the closing process of the refrigerator door, automatically continuously shooting a plurality of panoramic photos of articles in the refrigerator along with the closing movement of the refrigerator door 1.2, or automatically recording small videos at the same time, so that a user can check the panoramic photos or videos of the articles in the refrigerator with good light and large visual field in the last closing process and the closing process of the refrigerator door in a touch screen of the refrigerator door at any time without opening the refrigerator door, vacuumizing and reducing the temperature in a short range; (11) the positive and negative pressure module combined intelligent home mode: the intelligent positive and negative pressure refrigerator can be manufactured according to module function design, not only is used as an independent invention right for independent production and use, but also can be organically combined with other positive and negative voltage electric appliances and module cabinets under the control of the touch screen and the mobile phone APP monitoring system 12 to form an intelligent positive and negative pressure module combined home with complete functions, not only can share a positive and negative pressure system, a refrigerating system and an air water making device, but also has basically uniform appearance and color and is in order and harmonious fit with the popular trend. In summary, the specific operation method of the intelligent positive and negative pressure refrigerator can intelligently regulate and integrate multiple technologies such as vacuum, high pressure, superoxide, air-conditioned fresh keeping, low-temperature storage, negative oxygen ions, gas catalysts, humidification and air water production, and the like, and the technologies are alternately or circularly applied by different combinations of single item, double item or multiple items, and a plurality of vacuum high-pressure cabins of different types can be arranged in one refrigerator, so that the stored fruit, vegetable and meat fish can maintain the quality and flavor of moist and fresh for a long time due to cabin planning and classification regulation, and the refrigerator is higher in energy, higher in efficiency, lower in consumption and suitable for use.

In a third specific embodiment, the intelligent positive and negative pressure washing machine comprises a machine body 7; an intelligent positive-negative pressure system, an elution drying system 15, a touch screen and mobile phone monitoring system 12 are arranged in the machine body 7; the intelligent positive and negative pressure system comprises a positive and negative pressure cabin 1, an air pump 2, an inflator pump 3, a positive and negative pressure intelligent regulation and control device 5 and a positive and negative pressure airflow carried object generation processor; the positive and negative pressure cabin 1 is designed into a vacuum high-pressure roller outer cabin 1-5 according to the specific requirements of washing and drying; the vacuum high-pressure roller outer chamber 1-5 comprises: the device comprises a cabin body 1.1, a cabin door 1.2, a mechanical airtight mechanism 1.3 and an in-cabin outer sealing communicating vessel 1.4; the cabin door 1.2 is a machine door of the positive and negative pressure washing machine; a mechanical airtight mechanism 1.3 is arranged between the cabin door 1.2 of the vacuum high-pressure roller outer cabin 1-5 and the cabin body 1.1; the mechanical airtight mechanism 1.3 comprises a lock ring 1.31, a bolt 1.32, an airtight gasket 1.33 and a door edge gasket 1.34; the lock ring 1.31 is movably matched with the lock tongue 1.32, the lock tongue 1.32 extends into the lock ring 1.31 to lock the cabin door when the cabin door is closed, and the air-tight gasket 1.33 keeps sealing when positive and negative air pressure is formed in the vacuum high-pressure roller outer cabin 1-5; the in-cabin outer sealing communicating vessel 1.4 is fixedly arranged at the rear part of the vacuum high-pressure roller outer cabin 1-5, and all pipelines and circuits which enter and exit the cabin are connected to the in-cabin outer sealing communicating vessel 1.4 and enter and exit through the in-cabin outer sealing communicating vessel 1.4 so as to keep the sealing performance of the vacuum high-pressure roller outer cabin 1-5; a roller mechanism 15.1, a water-drenching prevention air exhaust port 2.1, a roller sealing bearing seat 15.3, a pressure sensor C1 and a negative pressure sensor C2 are arranged in the vacuum high-pressure roller outer chamber 1-5; an air pump 2, an inflator pump 3, a positive and negative pressure intelligent regulation and control device 5, an elution and drying control mechanism 15.2, a large roller belt pulley 15.4, a motor combination 15.5, a drainage pump 16, a water inlet pump 17, a super oxygen ml water mixer 6.6, a super oxygen decomposer 6.7, a touch screen and mobile phone APP monitoring system 12 and a detergent pull box 18 are arranged outside the vacuum high-pressure roller outer chamber 1-5; an air suction pipeline A1 is installed at an air inlet a of the air suction pump 2, an electromagnetic valve B1 is installed in the middle of the air suction pipeline A1, the other end of the air suction pipeline A1 extends into the vacuum high-pressure roller outer chamber 1-5 and then is connected with a water-drenching prevention air suction opening 2.1 to form an air suction return opening c, and an air outlet B of the air suction pump 2 is communicated with the atmosphere; an air charging pipeline A3 is installed at the air outlet d of the air charging pump 3, an electromagnetic valve B3 is installed in the middle of the air charging pipeline A3, and the other end of the air charging pipeline extends into the vacuum high-pressure roller outer chamber 1-5 and extends to the lower part of the roller mechanism 15.1 to form an air charging air inlet f; an air inlet e of the inflator pump 3 is communicated with the atmosphere; a water inlet pipe A14 is installed at a water inlet r of the water inlet pump 17, a solenoid valve B14 is installed in the middle of the water inlet pipe A14, the other end of the water inlet pipe A14 is communicated with a tap water source, a washing machine water inlet pipe A15 is installed at a water outlet u of the water inlet pump 17, a solenoid valve B15 is installed in the middle of the water inlet pipe A15, the other end of the water inlet pipe A15 is communicated with a water inlet k of the superoxide generation water mixer 6.6, a washing machine water inlet pipe A16 is installed at a water outlet q of the superoxide generation water mixer 6.6, a solenoid valve B16 is installed in the middle of the water inlet pipe A16, the other end of the water inlet pipe A is communicated with a water inlet z of the detergent pulling box 18, a washing machine water inlet pipe A17 is installed at a water outlet l of the detergent pulling; the electromagnetic valve B14 is also provided with a water inlet pipeline A18 which is connected with an electromagnetic valve B16 in parallel, and water can be directly fed when the pressure of tap water reaches the standard without the need of super-oxygen water; the electromagnetic valve B15 is also provided with a water inlet pipeline A19, is connected to a water inlet pipeline A18 and is communicated with an electromagnetic valve B16, and water is directly fed by the water inlet pump 17 when the super oxygen water is not needed; a water inlet pipeline A20 is installed at a water inlet w of the drainage pump 16, a solenoid valve B20 is installed in the middle of the drainage pipeline A20, the other end of the drainage pipeline A20 extends into the vacuum high-pressure roller outer chamber 1-5 to form a drainage outlet L of the vacuum high-pressure roller outer chamber, a drainage pipeline A21 is installed at a water outlet p of the drainage pump 16, a solenoid valve B21 is installed in the middle of the drainage pipeline A21, the other end of the drainage pipeline A21 is communicated with a water inlet g of the superoxide decomposer 6.7, a drainage pipeline A22 is installed at a water outlet m of the superoxide decomposer 6.7; the electromagnetic valve B20 is also provided with a drainage pipeline A23 which is connected with an electromagnetic valve B22 in parallel, and can directly drain water when the super oxygen is not required to be decomposed and the water can be drained automatically; the electromagnetic valve B21 is also provided with a drainage pipeline A24 and is connected to a drainage pipeline A23 to be communicated with an electromagnetic valve B22, and drainage is directly performed by the drainage pump 16 when superoxide is not decomposed; the motor assembly 15.5 drives the large belt pulley 15.4, and the large belt pulley 15.4 drives the roller mechanism 15.1 connected with the large belt pulley to run; the air pump 2, the inflator pump 3, the drain pump 16, the water inlet pump 17, the superoxide milliliter water mixer 6.6, the superoxide decomposer 6.7, the eluting and drying control mechanism 15.2, the touch screen and mobile phone APP monitoring system 12, the pressure sensor C1, the negative pressure sensor C2 and the electromagnetic valves B1 to B22 are all connected to the positive and negative pressure intelligent control device 5.

The operation method of the intelligent positive and negative pressure washing machine comprises the following steps: (1) and a water inlet procedure: the clothes are put into the roller 15.1, the door, namely the vacuum high-pressure cabin door 1.2, is closed, then the vacuum high-pressure roller outer cabin 1-5 is locked in a sealing way, the positive and negative pressure intelligent control device 5 sends a command to open corresponding water inlet pipelines (the direct water inlet pipeline of the solenoid valves B, B and B is A → B → A → A → the detergent drawer water inlet z → the water outlet l → A → B → A → A → A → the outer cabin water inlet T; the water inlet pipeline of the water inlet pump is A → B → A → the water inlet r → the water outlet u → A → B → A → the superoxide water mixer water inlet k → the water outlet q → A → B → A → A → the detergent drawer z → the water outlet l → A → A → B → the roller → the outer cabin water inlet T when the superoxide water is not needed to be washed, the water inlet pipeline of the water inlet pump is A → B → A → A → the water inlet r → U → A → B → A → the water outlet → A → B → the detergent drawer water inlet z → the → B17 → A17 → the water inlet T of the outer chamber of the roller), and the water intake pump 17 is started, the tap water directly enters along with the tap water or the super oxygen produced by the water intake mixer 6.6 is rapidly mixed with the super oxygen to form the super oxygen water with proper concentration and enters the outer chamber of the vacuum high-pressure roller 1-5, the super oxygen water can accelerate the decomposition of organic dirt on clothes to facilitate the rapid cleaning, the intelligent positive and negative pressure control device 5 can lead the electromagnetic valve B1 to open the air suction pipeline A1 (the air inlet a → A1 → B1 → A1 → the air suction return port c of the outer chamber of the roller 1-5) after the water intake begins, and the air suction pump 2 is started to lead the outer chamber of the vacuum high-pressure roller 1-5 to be in moderate negative pressure, thus accelerating; (2) and a vacuum washing program: after water enters, the positive and negative pressure intelligent control device 5 starts the motor combination 15.5 to drive the roller mechanism 15.1 to rotate to start washing, meanwhile, the electromagnetic valve B1 is enabled to open an A1 air suction pipeline (an air suction pump air inlet a → A1 → B1 → A1 → a roller outer chamber 1-5 air suction return air inlet c), the air suction pump 2 is started to pump the vacuum high-pressure roller outer chamber 1-5 to be moderate vacuum, clothes fibers and dirt expand in vacuum, air in the clothes fibers and the dirt escapes to weaken or fall off the adhesive force of the dirt, the washing efficiency is improved, the washing time is shortened, the bacteria, viruses and microorganisms on the clothes are directly killed by the super-oxygen water in the washing process, organic matters in the dust and the dirt on the clothes are decomposed to be dissolved in the water, the decontamination capability of the detergent is enhanced, the cleaning degree is improved, the washing process is accelerated, and the sterilization and deodorization; (3) and a high-pressure washing program: after the vacuum washing is carried out for a proper time, the positive and negative pressure intelligent control device 5 closes the electromagnetic valve B1 and the air pump 2, so that the electromagnetic valve B3 opens an A3 inflation pipeline (an air outlet d of the inflator pump 6 → A3 → B3 → A3 → an inflation air inlet f of the roller outer chamber 1-5), and opens the inflator pump 3, high-pressure air flow enters the vacuum high-pressure roller outer chamber 1-5 through an A3 inflation pipeline, strong bubble torrent is formed below the roller mechanism 15.1 to participate in the washing, and meanwhile, high pressure formed in the vacuum high-pressure roller outer chamber 1-5 is favorable for the detergent to permeate into clothes to be washed, so that the air suction and inflation cycle is repeated, the fiber expansion and torrent rubbing are carried out alternately, the washing degree and the washing efficiency are greatly improved, and the washing and rinsing; (4) and a drainage dehydration procedure: the positive and negative pressure intelligent control device 5 sends out a command when water needs to be drained, so that the solenoid valves B20, B21 and B22 open corresponding water drainage pipelines (firstly, when the super oxide needs not to be decomposed by a drainage pump, the direct water drainage pipeline is a drum outer chamber drainage port L → A20 → B20 → A23 → B22 → A22 → a sewer; when the super oxide needs to be decomposed by a drainage pump, the water drainage pipeline is a drum outer chamber drainage port L → A20 → B20 → A20 → a drainage pump water inlet w → a water outlet p → A21 → B21 → A21 → the super oxide decomposer water inlet g → a water outlet m → A22 → B22 → A22 → the sewer, when the super oxide needs not to be decomposed by the drainage pump, the drum outer chamber drainage port L → A20 → B20 → A20 → the drainage pump water inlet w → a water outlet → a21 → A3646 → B21 → the water pump 16 → the water drainage pump is opened, and the water drainage pump is opened as the high-pressure air-charging and the high-pressure air-charging pump is opened, the water drainage speed can be increased, and the positive and negative pressure intelligent control device 5 sends an instruction to start dewatering after the water drainage is finished; during dehydration, air inflation and pressurization can force moisture to be quickly separated from clothes, then the air suction pump 2 is alternately started to pump negative pressure, so that clothes fibers in the outer chambers 1-5 of the vacuum high-pressure roller are expanded, the moisture in the clothes escapes to a negative pressure space and is pumped out of the chambers, and meanwhile, the clothes hardened on the inner wall of the roller during dehydration and high pressure are fluffy to prevent the clothes from being wrinkled, so that air suction and inflation are repeated in a circulating manner, the moisture is forced out and the clothes are pumped out of the chambers alternately, the clothes dehydration efficiency is greatly improved, and the water drainage and dehydration time is shortened; (5) and a vacuum high-pressure drying program: when a drying program starts, the positive and negative pressure intelligent control device 5 instructs to start the inflator pump 3 and open the inflation pipeline to inflate and pressurize the vacuum high-pressure roller outer chamber 1-5 to facilitate hot gas to enter clothes fibers to vaporize water, then instructs to start the air pump 2 and open the air pumping pipeline to pump air, and pumps water vapor and simultaneously causes negative pressure to expand the clothes fibers to facilitate water vapor to be diffused and quickly dried, so that the air pumping and inflating cycle is repeated, heating gasification and water vapor pumping are alternately carried out, the clothes drying process is greatly accelerated, clothes are fluffy, the clothes drying quality is improved, and the clothes drying time is effectively shortened; (6) vacuum self-cleaning aseptic placing procedure: after washing, the machine door 1.2 is closed, the positive and negative pressure intelligent control device 5 operates the elution and drying control mechanism to open drying hot air, the interior of the washing machine, particularly the roller mechanism 15.1, is dried, then the air pump 2 is opened and an air pumping pipeline is opened to pump air, superoxide residual air in the vacuum high-pressure roller outer chamber 1-5 is pumped out, the roller mechanism 15.1 and equipment in the chamber are both in proper vacuum, the washing machine is sterile, dust-free, pollution-free, clean, free of oxidation, rust and free of damage, and the service life of the washing machine is prolonged. In conclusion, the positive and negative pressure washing machine greatly accelerates each process of washing, dewatering and drying clothes, shortens the working time of each program, improves the cleanliness and the drying quality of the clothes, and the superoxide can thoroughly sterilize, disinfect and remove peculiar smell of the clothes to be washed. Meanwhile, the concentration and the working time of the superoxide are intelligently controlled to be in a proper area for sterilization, degradation and washing assistance, and the critical point that the dark-colored clothes are oxidized and faded as far as possible is not reached or is reached as little as possible; (7) the positive and negative pressure module combined intelligent home mode: the intelligent positive and negative pressure washing machine can be manufactured according to module function design, not only is used as an independent invention right for independent production and use, but also can be organically combined with other positive and negative piezoelectric devices and module cabinets under the control of a touch screen and a mobile phone APP monitoring system 12 to form an intelligent positive and negative pressure module combined home with complete functions, so that the intelligent positive and negative pressure washing machine not only can share the intelligent positive and negative pressure system, but also is basically uniform in appearance shape and color, and is neatly matched to accord with a popular trend. In conclusion, the intelligent positive-negative pressure system makes the clothes washing, dehydrating and drying faster, more efficient and less consuming, and the clothes washed are less worn, cleaner, bulkier and more sanitary.

In a fourth specific embodiment, the intelligent vacuum dish-washing fruit and vegetable cleaning machine comprises a machine body 7; an intelligent positive-negative pressure system, a dish washing and drying system 19, a fruit and vegetable cleaning system 20 and a touch screen and mobile phone APP monitoring system 12 are arranged in the machine body 7; the intelligent positive and negative pressure system comprises a positive and negative pressure cabin 1, an air pump 2, a positive and negative pressure intelligent regulation and control device 5 and a positive and negative pressure airflow carried object generation processor; the positive and negative pressure cabin 1 is designed into a vacuum super-oxygen cabin 1-6 according to the special requirements of intelligent dish washing, drying and fruit and vegetable cleaning; the vacuum super-oxygen chamber 1-6 comprises: the device comprises a cabin body 1.1, a cabin door 1.2, a mechanical airtight mechanism 1.3 and an in-cabin outer sealing communicating vessel 1.4; the hatch door 1.2 is a machine door of the vacuum dish washing, fruit and vegetable cleaning machine; a mechanical airtight mechanism 1.3 is arranged between the cabin door 1.2 and the cabin body 1.1 of the vacuum super-oxygen cabin 1-6; the mechanical airtight mechanism 1.3 comprises a lock ring 1.31, a bolt 1.32 and an airtight gasket 1.33; the lock ring 1.31 is movably matched with the lock tongue 1.32, the lock tongue 1.32 extends into the lock ring 1.31 to lock the cabin door when the cabin door is closed, and the air-tight gasket 1.33 keeps sealing when positive and negative air pressure is formed in the vacuum super-oxygen cabin 1-6; the in-cabin and out-cabin pipeline joint controller 1.4 is fixedly arranged at the rear part of the vacuum super-oxygen cabin 1-6, and all pipelines and circuits which enter and exit from the cabin are connected to the in-cabin and out-cabin outer sealing communicating device 1.4 and enter and exit through the in-cabin and outer sealing communicating device so as to keep the sealing performance of the vacuum super-oxygen cabin 1-6. A dish washing and drying system 19, a fruit and vegetable cleaning system 20, a water-drenching prevention pumping hole 2.1, a negative pressure sensor C2, a superoxide sensor C3 and a temperature sensor C9 are arranged in the vacuum super-oxygen chamber 1-6; an air suction pump 2, a positive and negative pressure intelligent regulation and control device 5, a water discharge pump 16, a water inlet pump 17, a superoxide generation water mixer 6.6, a superoxide decomposer 6.7, a touch screen and mobile phone APP monitoring system 12 are arranged outside the vacuum super-oxygen chambers 1-6; an air suction pipeline A1 is installed at the air inlet a of the air suction pump 2, an electromagnetic valve B1 is installed in the middle of the air suction pipeline A1, and the other end of the air suction pipeline A extends into the vacuum super-oxygen chamber 1-6 and then is connected with a water-drenching prevention air suction opening 2.1 to form an air suction return opening c; the air outlet b of the air pump 2 is communicated with the atmosphere; a water inlet pipe A14 is installed at a water inlet r of the water inlet pump 17, a solenoid valve B14 is installed in the middle of the water inlet pipe A14, the other end of the water inlet pipe A14 is connected with a tap water source, a water inlet pipe A15 is installed at a water outlet u of the water inlet pump 17, a solenoid valve B15 is installed in the middle of the water inlet pipe A15, the other end of the water inlet pipe A15 is connected with a water inlet k of the superoxide generating water mixer 6.6, a water inlet pipe A16 is installed at a water outlet q of the superoxide generating water mixer 6.6, a solenoid valve B16 is installed in the middle of the water inlet pipe A16, the other end of the water inlet pipe A16 extends into the vacuum superoxide chamber 1-6 to be connected to the solenoid valve B25, the solenoid valve B25 is respectively connected with a; the water inlet pipeline A27 is connected to a water inlet G of the dish washing and drying system 19; the electromagnetic valve B15 is also provided with a water inlet pipeline A19 and is connected to an electromagnetic valve B16, and water is directly fed by a water inlet pump 17 when the super oxygen water is not needed; a water discharge pipeline A20 is installed at a water inlet w of the water discharge pump 16, an electromagnetic valve B20 is installed in the middle of the water discharge pipeline A20, the other end of the water discharge pipeline A20 extends into the vacuum super-oxygen chamber 1-6 and is respectively connected to a fruit and vegetable cleaning water discharge pipeline A26 and a dish washing and drying water discharge pipeline A28, and the water discharge pipeline A26 is connected to a water outlet F of the fruit and vegetable cleaning system 20; the drainage pipeline A28 is connected to a drainage port H of the dish washing and drying system 21; a drainage pipeline A21 is installed at a water outlet p of the drainage pump 16, an electromagnetic valve B21 is installed in the middle of the drainage pipeline A21, the other end of the drainage pipeline A21 is communicated with a water inlet g of the superoxide decomposer 6.7, a drainage pipeline A22 is installed at a water outlet m of the superoxide decomposer 6.7, an electromagnetic valve B22 is installed in the middle of the drainage pipeline A22, and the other end of the drainage pipeline A22 is communicated with a; the electromagnetic valve B21 is also provided with a drainage pipeline A24 and is connected to A23 to be communicated with the electromagnetic valve B22, and drainage is directly carried out by a drainage pump when superoxide does not need to be decomposed; the air pump 2, the drain pump 16, the water inlet pump 17, the superoxide generation water mixer 6.6, the superoxide decomposer 6.7, the dish washing and drying system 19, the fruit and vegetable cleaning system 20, the touch screen and mobile phone APP monitoring system 12, the negative pressure sensor C2, the superoxide sensor C3, the temperature sensor C9 and the electromagnetic valves B1 to B25 are all connected to the positive and negative pressure intelligent regulation and control device 5.

The operation method of the intelligent vacuum dish-washing fruit and vegetable cleaning machine comprises the following steps: (1) dish washing water inlet and cleaning procedures: after the machine door is closed, the positive and negative pressure intelligent control device 5 sends out a command to enable the electromagnetic valves B14, B15, B16 and B25 to open corresponding water inlet pipelines (when the super oxygen water is needed for washing dishes, the water inlet pipeline of the water inlet pump is A14 → B14 → A14 → the water inlet of the water inlet pump r → the water outlet u → A15 → B15 → A15 → the water inlet k → the water outlet q → A16 → B16 → A16 → B25 → A27 → the water inlet G of the dish washing and drying system; when the super oxygen water is not needed for washing dishes, the water inlet pipeline of the water inlet pump is A14 → B14 → A14 → the water inlet r → the water outlet u → A15 → B15 → A19 → B16 → A16 → B25 → A27 → the water inlet G of the dish washing and drying system), and opens the water inlet pump 17, so that the tap water can be rapidly mixed with the super oxygen water produced by the super oxygen generator 6.6 to enter the vacuum super oxygen water with the super oxygen water to be rapidly decomposed in the, the positive and negative pressure control device 5 starts the dish washing and drying system 19 to spray and wash dishes after water inflow is finished, the electromagnetic valve B1 is enabled to open an A1 air suction pipeline (air suction pump air inlet a → A1 → B1 → A1 → vacuum super oxygen cabin air suction and return air inlet c), the air suction pump 2 is simultaneously started to vacuumize, dirt stained on the tableware of bowls and chopsticks can expand in vacuum and negative pressure, air in the dirt escapes, the adhesion force of the dirt is weakened or the dirt falls off from the tableware of bowls and chopsticks, the cleaning efficiency is improved, the washing process is shortened, the bacterial virus microorganisms on the tableware of bowls and chopsticks are directly killed by the super oxygen water in the dish washing process, organic matters in the dirt on the tableware of bowls and chopsticks are decomposed to be dissolved into water, the dirt removing capability of a detergent can be enhanced, the cleaning degree is improved, the washing process is accelerated, and the sterilization and; (2) dish washing, draining and drying disinfection procedures: when the water needs to be drained at a proper time, the positive and negative pressure intelligent control device 5 sends an instruction to open corresponding water drainage pipelines of the electromagnetic valves B20, B21 and B22 (firstly, when the super oxygen does not need to be decomposed by a water discharge pump, the direct water drainage pipeline is the water outlet of the dish washing and drying system H → A28 → A20 → B20 → A23 → B22 → A22 → sewer → secondly, when the super oxygen does not need to be decomposed by a water discharge pump, the water outlet of the dish washing and drying system H → A28 → A20 → B20 → A20 → the water inlet of the water discharge pump w → the water outlet p → A21 → B21 → A21 → the water inlet of the super oxygen decomposer → the water outlet m → A22 → B22 → A22 → B20 → B20 → A23 → B22 → A22) or directly or when the super oxygen does not need to be decomposed by the water discharge pump, the water discharge pump → 16 is opened again, and the water discharge pump is further, the super oxygen decomposer is decomposed, meanwhile, the tableware is sprayed and cleaned by clean water again, when in a drying procedure, the positive and negative pressure regulating and controlling device 5 starts the air extracting pump 2 again to quickly extract water vapor, so that the drying process is accelerated, the whole dish washing process is greatly accelerated by vacuum super oxygen, and the super oxygen can thoroughly sterilize, disinfect and remove peculiar smell of the dish-washed chopsticks and tableware; (3) and washing and water feeding and washing procedures of fruits and vegetables: after the machine door is closed, the positive and negative pressure intelligent control device 5 sends out an instruction to enable the electromagnetic valves B14, B15, B16 and B25 to open corresponding water inlet pipelines (firstly, when fruits and vegetables need to be cleaned by super oxygen water, the water inlet pipeline of the water inlet pump is A14 → B14 → A14 → the water inlet of the water inlet pump r → the water outlet u → A15 → B15 → A15 → the water inlet k of the super oxygen generating water mixer → the water outlet q → A16 → B16 → A16 → B25 → A25 → the water inlet E of the fruit and vegetable cleaning system; secondly, when fruits and vegetables do not need to be cleaned by super oxygen water, the water inlet pipeline of the water inlet pump is A14 → B14 → A14 → the water inlet of the water pump r → the water outlet u → A15 → B15 → A19 → B16 → A16 → B25 → A25 → the water inlet E of the fruit and vegetable cleaning system), and then the water inlet pump 17 is started, tap water enters the super oxygen spraying and the super oxygen cleaning system for fruit and vegetable cleaning system 20, and the electromagnetic valve B1 is enabled to open an A1 air suction pipeline (air suction pump air inlet a → A1 → B1 → A1 → vacuum super oxygen cabin air suction return port c), the air suction pump 2 is started to vacuumize to moderate negative pressure, dirt on fruits and vegetables can expand in the negative pressure, air in the dirt escapes, so that the adhesion force of the dirt is weakened or the dirt falls off from the fruits and vegetables, the cleaning efficiency is improved, the washing process is shortened, the super oxygen water directly kills bacteria and virus microorganisms on the surfaces of the fruits and vegetables in the cleaning process, organic matters in the dirt on the surfaces are decomposed to be dissolved in water, the cleaning degree is improved, the cleaning process is accelerated, the negative pressure promotes residues of pesticide heavy metals and the like in the tissues of the fruits and vegetables and harmful gases such as ethylene acetaldehyde to escape, a favorable environment is created for quick cleaning of the super oxygen water and deep degradation of pesticide residues and decomposition of the harmful gases such as ethylene, the positive and negative pressure intelligent control device 5 sends an instruction after the super, and (5) spraying clear water to clean the fruits and vegetables. (4) And draining after cleaning the fruits and vegetables: when the water needs to be drained after cleaning for a proper time, the positive and negative pressure intelligent control device 5 sends out an instruction to enable the electromagnetic valves B20 and B21, b22 opens corresponding drainage pipeline (the direct drainage pipeline is F → A26 → A20 → B20 → A23 → B22 → A22 → sewer when the water discharge pump does not need to decompose the superoxide; the drainage pipeline is F → A26 → A20 → B20 → A20 → water inlet w → water outlet p → A21 → B21 → A21 → water inlet g → water outlet m → A22 → B22 → A22 → sewer when the water discharge pump needs to discharge without decomposition), the drainage pipeline is F → A26 → A20 → B20 → A23 → B22 → A22 → sewer), the drainage pump 16 is directly opened or the water discharge pump is opened or the superoxide decomposer 6.7 is opened, the water is discharged into the sewer after decomposition. (5) Vacuum self-cleaning aseptic placing procedure: after the use, the machine door 1.2 is closed, the positive and negative pressure intelligent control device 5 opens drying hot air to blow dry the interior of the vacuum super-oxygen chamber 1-6, particularly the dish washing and drying system 19 and the fruit and vegetable cleaning system 20, then the air pump 2 is opened and the air extraction pipeline is opened to extract air, the super-oxygen residual air in the vacuum super-oxygen chamber 1-6 is extracted, the dish washing and drying system 19, the fruit and vegetable cleaning system 20 and equipment in the chamber are all in proper vacuum, the room is sterile, dust-free, pollution-free, clean, favorable for health, free of oxidation, rust and free of damage, and the service life of an electric. (6) The positive and negative pressure module combined intelligent home mode: the intelligent positive-negative pressure dish washing and fruit and vegetable cleaning machine can be manufactured according to module function design, not only can be independently produced and used as an independent invention right, but also can be organically combined with other positive-negative voltage electric devices and module cabinets under the control of a touch screen and a mobile phone APP monitoring system 12 to form an intelligent positive-negative pressure module combined household with complete functions, not only can share a common water inlet pump 17, a water discharge pump 16, a superoxide generation water mixer 6.6 and a superoxide decomposer 6.7 with a superoxide washing range hood, but also has basically uniform appearance and color, is orderly matched with the popular trend, and is higher in energy, higher in efficiency, lower in consumption and suitable for use.

In a fifth specific embodiment, the intelligent superoxide washing range hood comprises a body 7; the lower half part of the machine body 7 is a sealed waterproof super-oxygen cabin 1-7, and the upper half part is an equipment smoke pipe cabin 21; the sealed waterproof super oxygen cabin 1-7 includes: a triangular cabin body 1.1 and a sealed waterproof cabin door 1.2; the sealed waterproof cabin door 1.2 is a machine door of the superoxide water washing range hood, and a sealed waterproof mechanism 1.7 is arranged between the cabin door 1.2 and the cabin body 1.1; the waterproof sealing mechanism 1.7 comprises a lock ring 1.71, a lock tongue 1.72, an airtight gasket 1.73 and a cabin door hinge 1.74; the lock ring 1.71 is in movable fit with the lock tongue 1.72, the lock tongue 1.72 extends into the lock ring 1.71 to lock the cabin door 1.2 when the cabin door is closed, and the sealing is kept by the sealing washer 1.73 when the sealed waterproof superoxide cabin 1-7 is sprayed and cleaned; a motor and wind wheel combination 22, an automatic rotating spraying ball 23 and an oil and water collecting and draining groove 24 are arranged in the sealed waterproof super-oxygen cabin 1-7, and a touch screen and a mobile phone APP monitoring system 12 are also arranged on the front side; an intelligent superoxide cleaning system and an oil fume pumping control mechanism 26 are arranged in the smoke tube cabin 21 of the equipment; the intelligent superoxide cleaning system comprises: the device comprises an intelligent superoxide regulating and controlling device 5.1, a water inlet pump 17, a water discharge pump 16, a superoxide generating water mixer 6.6, a superoxide decomposer 6.7, a water heating device 27 and a degreasing agent adder 28; a water inlet pipe A14 is installed at a water inlet r of the water inlet pump 17 and is connected with a tap water source, a water inlet pipe A15 is installed at a water outlet u of the water inlet pump 17, a water heating device 27 and an electromagnetic valve B15 are installed in the middle of the water inlet pipe A15, the other end of the water inlet pipe A is divided into 3 paths through an electromagnetic valve B15, and the water inlet k of the superoxide generation water mixer 6.6, the water inlet z of the degreasing agent adder 28 and the electromagnetic valve B16 are respectively connected; a water inlet pipeline A16 is installed at a water outlet q of the superoxide generation water mixer 6.6, an electromagnetic valve B16 is installed in the middle of the water inlet pipeline A16, the other end of the water inlet pipeline A16 extends into the sealed waterproof superoxide cabin 1-7 and is connected to a spray pipeline A30, at least 1 automatic rotating spray ball 23 is installed on the spray pipeline A30, the axis of the spray ball and the axis of a middle circle of spray holes form an angle of 45 degrees, and the spray ball 23 automatically rotates when water flow is sprayed out; a water inlet pipeline A17 is installed at a water outlet I of the degreaser adder 28, a solenoid valve B17 is installed in the middle of the water inlet pipeline A17, and the other end of the water inlet pipeline A15 is communicated with the solenoid valve B16; a water inlet pipeline A20 is installed at the water inlet w of the drainage pump 16, an electromagnetic valve B20 is installed in the middle of the drainage pipeline A20, and the other end of the drainage pipeline A extends into the oil and water collecting and draining groove 24 at the bottom of the vacuum super-oxygen chamber 1-7 to form a water outlet L; a drainage pipeline A21 is installed at a water outlet p of the drainage pump 16, an electromagnetic valve B21 is installed in the middle of the drainage pipeline A21, the other end of the drainage pipeline A21 is communicated with a water inlet g of the superoxide decomposer 6.7, a drainage pipeline A22 is installed at a water outlet m of the superoxide decomposer 6.7, an electromagnetic valve B22 is installed in the middle of the drainage pipeline A22, and the other end of the drainage pipeline A22 is communicated with a; the electromagnetic valve B21 is also provided with a water discharge pipeline A24 and is connected to an electromagnetic valve B22, and water is directly discharged by a water discharge pump 16 when superoxide does not need to be decomposed; the water inlet pump 17, the water discharge pump 16, the superoxide generation water mixer 6.6, the superoxide decomposer 6.7, the water heating device 27, the degreasing agent adder 28, the oil pumping smoke control mechanism 26, the touch screen and mobile phone APP monitoring system 12 and the electromagnetic valves B1-B22 are all connected to the superoxide intelligent control device 5.1.

The operation method of the intelligent super-oxygen water-washing range hood comprises the following steps: (1) and (3) oil smoke extraction procedures: when the range hood is started, the air inlet of the sealed waterproof cabin door 1.2 is opened for smoke extraction, and when the range hood stops working, the sealed cabin door 1.2 is closed; (2) and a self-cleaning program: the intelligent control device 5.1 sends out instructions to open corresponding water inlet pipelines of the solenoid valves B15, B16 and B17 (the water inlet pipeline is A14 → the water inlet of the water inlet pump r → the water outlet u → A14 → the water heating device → A14 → B14 → A14 → the water inlet of the water mixer k → the water outlet q → A14 → B14 → A14 → A14 → A14 → the automatic rotary spray ball 23, the water inlet pipeline is A14 → the water inlet of the water inlet pump r → the water outlet u → A14 → the water heating device → A14 → B14 → A14 → A14 → B → a → 14 → B → a → 14 → a → B → a → 14 → B → a → 14 → a → B → a → 14 → a → B → a → 14 → a → B → a → B → a →, and a water inlet pump 17 is started, tap water is quickly mixed with superoxide produced by the water heating device 27 and the superoxide generating water mixer 6.6 into superoxide water with proper concentration, the superoxide water enters the vacuum super-oxygen chamber 1-6, the motor and wind wheel combination 22 in each part of the machine case is comprehensively sprayed and cleaned by automatically rotating the spraying ball 23, the super-oxygen hot water with proper temperature is firstly sprayed to efficiently decompose and remove oil stains, then the degreasing agent is sprayed with mixed hot water, then the clean hot water is sprayed until the sewage is completely cleaned, the cleaned sewage flows downwards and is collected into an oil collecting and water draining groove 24 at the lowest part of the machine case, and the superoxide intelligent control device 5.1 sends an instruction when water drainage is needed, so that the electromagnetic valves B20, B21 and B22 open corresponding water draining pipelines (when the super-oxygen is needed to be decomposed, the water draining pipeline is an oil collecting and water draining groove water draining hole L → A20 → B20 → A20 → water inlet of a draining pump → w → water outlet hole → p → A21 → B → 4 → A → B → A3874 → When the superoxide needs to be decomposed, the drainage pipeline comprises: the oil collecting and water draining tank water draining port L → A20 → B20 → A20 → the water draining pump water inlet w → the water outlet p → A21 → B21 → A24 → B22 → A22 → sewer), and the water draining pump 16 is started to drain the water to the sewer; (3) a drying and placing program, wherein after cleaning, the superoxide intelligent control device 5.1 instructs to open the range hood to completely dry the interior of the case, and then the case is placed in a shutdown mode to prevent rusting; (4) starting up protection function: when the user starts the machine, the air flows into the vacuum super oxygen chamber from the side of the body and is discharged from the smoke exhaust pipe 29, so that the air can not contact any super oxygen at all; (5) the module combination intelligent home mode comprises: the intelligent super-oxygen washing range hood can be manufactured according to module function design, not only is used as an independent invention right for independent production and use, but also can be organically combined with other electric appliances and module cabinets under the control of a touch screen and a mobile phone APP monitoring system 12 to form an intelligent module combined home with complete functions, and not only can share a water inlet pump 17, a water discharge pump 16, a super-oxygen generation water mixer 6.6 and a super-oxygen decomposer 6.7 with a dish washing fruit and vegetable cleaning machine, but also has basically uniform appearance shape and color, and is neatly harmonious to accord with the popular trend, so that the intelligent range hood is higher in energy, higher in efficiency, lower in consumption and suitable for use.

In a sixth specific embodiment, the intelligent microwave oven with the positive and negative pressure oven and the air fryer comprises an oven body 7, wherein the oven body 7 is internally provided with: the intelligent positive and negative pressure system, the barbecue system 30, the air fryer system 31, the microwave system 32 and the touch screen and mobile phone APP monitoring system 12; the intelligent positive and negative pressure system comprises a positive and negative pressure cabin 1, an air pump 2, an inflator pump 3 and a positive and negative pressure intelligent regulation and control device 5; the positive and negative pressure cabins 1 are designed into microwave vacuum high pressure cabins 1-8 according to the specific requirements of an oven air fryer and a microwave oven; the microwave vacuum hyperbaric chamber 1-8 comprises: the device comprises a cabin body 1.1, a cabin door 1.2, a mechanical airtight mechanism 1.3 and an in-cabin outer sealing communicating vessel 1.4; the hatch door 1.2 is a machine door of the positive and negative pressure oven air fryer microwave oven; a mechanical airtight mechanism 1.3 is arranged between the cabin door 1.2 and the cabin body 1.1 of the microwave vacuum high-pressure cabin 1-8; the mechanical airtight mechanism 1.3 comprises a lock ring 1.31, a bolt 1.32 and an airtight gasket 1.33; the lock ring 1.31 is movably matched with the bolt 1.32, the bolt 1.32 extends into the lock ring 1.31 to lock the hatch door when the hatch door is closed, and the sealing is kept by the airtight gasket 1.33 when positive and negative air pressure is formed in the microwave vacuum high-pressure cabin 1-8; the in-cabin and out-cabin pipeline joint controller 1.4 is fixedly arranged at the rear part of the microwave vacuum high-pressure cabin 1-8, and all pipelines and circuits which enter and exit the cabin are connected to the in-cabin and out-cabin sealing communicating device 1.4 and enter and exit through the same so as to keep the sealing performance of the microwave vacuum high-pressure cabin 1-8. The microwave vacuum high-pressure cabin 1-8 is internally provided with a barbecue system 30, an air fryer system 31, a microwave system 32, a pressure sensor C1 and a negative pressure sensor C2; an air pump 2, an inflator pump 3, a positive and negative pressure intelligent control device 5, a touch screen and a mobile phone APP monitoring system 12 are arranged outside the microwave vacuum high-pressure cabins 1-8; an air suction pipeline A1 is installed at an air inlet a of the air suction pump 2, an electromagnetic valve B1 is installed in the middle of the air suction pipeline A1, the other end of the air suction pipeline A1 extends into the microwave vacuum high-pressure cabin 1-8 to form an air suction return port c, and an air outlet B of the air suction pump 2 is provided with an air outlet pipeline A2 and is communicated with the atmosphere; an air inflation pipeline A3 is installed at an air outlet d of the air inflation pump 3, an electromagnetic valve B3 is installed in the middle of the air inflation pipeline A3, and the other end of the air inflation pipeline A extends into the microwave vacuum high-pressure cabin 1-8 to form an air inflation inlet f; an air inlet pipeline A4 is arranged at an air inlet e of the inflator pump 3 and is communicated with the atmosphere; air pump 2, pump 3, pressure sensor C1, negative pressure sensor C2, barbecue system 30, air fryer system 31, microwave system 32 and touch screen and cell-phone APP monitored control system 12 all insert positive negative pressure intelligent control device 5.

The operation method of the intelligent positive and negative pressure oven air fryer microwave oven comprises the following steps: (1) and a vacuum cooking procedure: the positive and negative pressure intelligent control device 5 opens the electromagnetic valve B1 and the air extraction pump 2, the microwave vacuum high-pressure cabin 1-8 is pumped to moderate vacuum through the air extraction pipeline A1, food is cooked in vacuum, and the food is unique in flavor because of expansion of food materials, for example, an air fryer system is opened to bake chips, cakes and the like in proper vacuum, so that the chips, cakes and the like are softer and more delicious; (2) high pressure cooking procedure; the positive and negative pressure intelligent control device 5 opens the electromagnetic valve B3 and the inflator pump 3, high-pressure airflow enters the microwave vacuum high-pressure cabin 1-8 through the inflation pipeline A3, and the food cooked in high pressure is particularly tasty and special in flavor because the seasoning is easy to permeate into the food, and is easy to cook and save energy; (3) and a vacuum placing procedure: when the microwave vacuum high-pressure cabin is not used, the microwave vacuum high-pressure cabin 1-8 is pumped to be in proper vacuum, a barbecue microwave system and circuit parts are in a vacuum state, and the microwave vacuum high-pressure cabin is sterile, dust-free, pollution-free, clean, beneficial to health, free of oxidation, rusty and loss, and capable of prolonging the service life of an electric appliance; (4) the positive and negative pressure module combined intelligent home mode: the positive and negative pressure oven air fryer microwave oven can be manufactured according to module function design, not only can be independently produced and used as an independent invention right, but also can be organically combined with other electric appliances and module cabinets into an intelligent module combined home with complete functions under the control of a touch screen and a mobile phone APP monitoring system 12, not only can share a shared intelligent positive and negative pressure system, but also has basically uniform appearance shape and color, is tidy and harmonious and accords with the popular trend, so that the intelligent oven air fryer microwave oven is higher in energy, higher in efficiency, lower in consumption and suitable for use.

The intelligent positive and negative pressure fresh-keeping carriage (container) comprises a carriage (container) body 7; an intelligent positive-negative pressure system, a refrigerating system 8, a touch screen and a mobile phone monitoring system 12 are arranged in the compartment (box) body 7; the intelligent positive and negative pressure system comprises a positive and negative pressure cabin 1, an air pump 2, an inflator pump 3, a positive and negative pressure intelligent regulation and control device 5 and a positive and negative pressure airflow carried object generation processor; the positive and negative pressure cabin 1 is designed into a cabin (box) type vacuum high-pressure cabin 1-9 according to the specific requirements of the intelligent positive and negative pressure fresh-keeping cabin (container); the chamber (tank) type vacuum high-pressure cabin 1-9 includes: the device comprises a cabin body 1.1, a cabin door 1.2, a mechanical airtight mechanism 1.3 and an in-cabin outer sealing communicating vessel 1.4; the cabin door 1.2 is a carriage door of the positive and negative pressure fresh-keeping carriage; a mechanical airtight mechanism 1.3 is arranged between the cabin door 1.2 and the cabin body 1.1 of the chamber (box) type vacuum high-pressure cabin 1-9; the mechanical airtight mechanism 1.3 comprises a lock ring 1.31, a bolt 1.32 and an airtight gasket 1.33; the lock ring 1.31 is movably matched with the bolt 1.32, the bolt 1.32 extends into the lock ring 1.31 to lock the hatch door when the hatch door is closed, and the sealing is kept by the airtight gasket 1.33 when positive and negative air pressure is formed in the chamber (box) type vacuum high-pressure cabin 1-9; the in-cabin and out-cabin pipeline joint controller 1.4 is fixedly arranged at the rear part of the chamber (box) type vacuum high-pressure cabin 1-9, and all pipelines and circuits which enter and exit the chamber are connected to the in-cabin and out-cabin outer sealing communicator 1.4 and enter and exit through the in-cabin and outer sealing communicator so as to keep the sealing performance of the chamber (box) type vacuum high-pressure cabin 1-9. An air pump 2, an inflator pump 3, a positive and negative pressure intelligent regulation and control device 5, an air regulation device 6.1, a superoxide decomposer 6.7, an air filter 6.8, a refrigerating system 8, an air water production device 11, a filtering water tank 11.1, a touch screen and a mobile phone monitoring system 12 are arranged outside the box (box) type vacuum high-pressure cabin 1-9; an air suction pipeline A1 is installed at the air inlet a of the air suction pump 2, an electromagnetic valve B1 is installed in the middle of the air suction pipeline A1, and the other end of the air suction pipeline A extends into the chamber (box) type vacuum high-pressure cabin 1-9 to form an air suction return port c; an air outlet B of the air pump 2 is provided with an air exhaust pipeline A2, the middle part of the air exhaust pipeline A2 is provided with a superoxide decomposer 6.7 and an electromagnetic valve B2, the other end of the air exhaust pipeline A2 is communicated with an air inlet h of the air water making device 11, and air is introduced from an air outlet n of the air water making device 11; an air inflation pipeline A3 is arranged at an air outlet d of the air inflation pump 3, an electromagnetic valve B3 is arranged in the middle of the air inflation pipeline A3, and the other end of the air inflation pipeline A extends into the chamber (box) type vacuum high-pressure cabin 1-9 to form an air inflation inlet f; an air inlet pipeline A4 is installed at an air inlet e of the inflator pump 3, an electromagnetic valve B4 and an air filter 6.8 are installed in the middle of the air inlet pipeline A4, and the other end of the air inlet pipeline is communicated with the atmosphere; the electromagnetic valve B4 is also connected with a circulating pipeline A5, the middle part of the circulating pipeline A5 is provided with an electromagnetic valve B5, the other end of the circulating pipeline A5 is communicated with an electromagnetic valve B3, and the circulating pipeline A3 extends into the chamber (box) type vacuum high-pressure cabin 1-9 to form a circulating return air port j; the inflation pipeline A3 is also connected with an air-to-water inflation pipeline A9, and the air-to-water inflation pipeline A9 is connected to an electromagnetic valve B2 and communicated with an air inlet h of the air-to-water device 11 through an exhaust pipeline A2; an air-conditioned air inlet pipeline A6 is installed at the air inlet t of the air-conditioned device 6.1, an electromagnetic valve B6 is installed in the middle of the air-conditioned air inlet pipeline A6, the other end of the air-conditioned air inlet pipeline A3 is connected to an air inflation pipeline A3 and then is communicated with an air outlet d of the air inflation pump 3, an air-conditioned air outlet pipeline A7 is installed at the air outlet s of the air-conditioned device 6.1, an electromagnetic valve B7 is installed in the middle of the air-conditioned air outlet pipeline A7, and the other end of the air-conditioned air outlet pipeline extends; an air water making pipeline A10 is installed at a water outlet x of the air water making device 11, and the air water making pipeline A10 is communicated with a water inlet y of the filtering water tank 11-1; condensed water generated in the chamber (tank) type vacuum high-pressure cabin 1-9 flows into a water inlet Y of a condensed water collecting box 11.2 arranged at the bottom of the chamber, a condensed water pipeline A11 is arranged at a water outlet M of the condensed water collecting box 11.2, an electromagnetic valve B11 is arranged at the middle part of the condensed water pipeline A11 after extending out of the chamber (tank) type vacuum high-pressure cabin 1-9, the other end of the condensed water pipeline is communicated with a water inlet v of a filter water tank 11.1, a humidifying water pipeline A12 is arranged at a water outlet o of the filter water tank 11.1, an electromagnetic valve B12 is arranged at the middle part of the humidifying water pipeline A12, the other end of the condensed water pipeline extends into the chamber (tank) type vacuum high-pressure cabin 1-9; the refrigerating system 8 is provided with a refrigerating circulation pipeline A13, and the refrigerating circulation pipeline A13 extends into the compartment (box) type vacuum high-pressure cabin 1-9 and is communicated with an evaporator air cooling combination 8.1; the touch screen and mobile phone monitoring system 12 includes: the system comprises a touch screen 12.1, a mobile phone APP12.2 and a wireless anti-fog camera 12.4, wherein the wireless anti-fog camera 12.4 is arranged at a position to be monitored inside and outside a compartment (box) body 7; the inside of the chamber (box) type vacuum high-pressure chamber 1-9 is provided with a positive and negative pressure airflow carrying object generation processor and a sensor, and the chamber (box) type vacuum high-pressure chamber comprises: 6.5 parts of a humidifier, 6.2 parts of an ultrasonic generator, 6.3 parts of negative ion generation, 6.4 parts of a gas catalyst controlled release device, 11.2 parts of a condensed water collecting box, a pressure sensor C1, a negative pressure sensor C2, a super oxygen sensor C3, a negative oxygen ion sensor C4, a chlorine dioxide sensor C5, a humidity sensor C6, an oxygen sensor C7, a nitrogen sensor C8 and a temperature sensor C9; all the airflow carrying load generation processors, sensors, electromagnetic valves and equipment devices installed inside and outside the box-type vacuum high-pressure cabins 1-9 include: the air extracting pump 2, the inflator pump 3, the air conditioning device 6.1, the superoxide generator 6.2, the anion generator 6.3, the gas catalyst controlled release device 6.4, the humidifier 6.5, the superoxide decomposer 6.7, the refrigeration system 8, the air water making device 11, the filter water tank 11.1, the touch screen and mobile phone monitoring system 12, the touch screen 12-1, the wireless anti-fog camera device 12-4, the pressure sensor C1, the negative pressure sensor C2, the superoxide sensor C3, the negative oxygen ion sensor C4, the chlorine dioxide sensor C5, the humidity sensor C6, the oxygen sensor C7, the nitrogen sensor C8, the temperature sensor C9, the water level sensor C10 and the electromagnetic valves B1 to B12 are all connected to the positive and negative pressure intelligent regulation device 5. The operation method of the intelligent positive and negative pressure fresh-keeping carriage (container) comprises the following steps: (1) and vacuum pest and heat removing cleaning procedure: fresh goods to be transported in a fresh-keeping mode are loaded into the compartment (box) type vacuum high-pressure cabin 1-9, the cabin door 1.2 is closed, the cabin door switch 1.8 is touched or is manually opened by a driver, and the positive and negative pressure intelligent control device 5 sends an instruction: the electromagnetic valves B1 and B2 are communicated with air suction pipelines A1 and A2 (air suction return air port c → A1 → B1 → A1 → air suction pump 5 air inlet a → air outlet B → A2-superoxide decomposer air inlet g → air outlet m → A2 → B2 → A2 → air water preparation device air inlet h → air outlet n → A2 → air discharge), and the air suction pump 2 is started to suck the box type vacuum high-pressure cabin 1-9 to moderate vacuum (-0.01 KPa-0.09 MPa), so that heat, bacterial microorganisms and dirty air in the fruit and vegetable are sucked away, the vacuum promotes harmful gases such as volatile metabolites ethylene acetaldehyde ethanol in the fruit and vegetable tissues to escape and be sucked away, and the negative pressure is used for inhibiting the propagation of residual bacteria, thereby reducing the hidden danger of fruit and vegetable disease aging; (2) and a reduced-pressure humidification storage procedure: the positive and negative pressure intelligent control device 5 maintains a proper negative pressure low-oxygen low-temperature environment in the chamber (box) type vacuum high-pressure chambers 1-9 by opening or closing the air pump 2 according to the pressure standard of a preset program and the real-time feedback of the negative pressure sensor C2, reduces the respiration intensity of fruits and vegetables, inhibits the biosynthesis of ethylene, delays the decomposition of chlorophyll, inhibits the synthesis of carotenoid and lycopene, and slows down the hydrolysis of starch, the increase of sugar, the consumption of acid and other processes, thereby delaying the maturation and aging of the fruits and vegetables, and simultaneously opens the humidifier 6.5 to improve the humidity in the chamber, prevent the moisture of the fruits and vegetables from escaping, and maintain the fresh state of the fruits and vegetables for a longer time; (3) and the superoxide pressure sterilization degradation program: the positive and negative pressure intelligent control device 5 timely sends out instructions to start the superoxide generator 6.2, the negative oxygen ion generator 6.3 and the humidifier 6.5 according to program setting and feedback of sensors C3, C4 and C6, so that superoxide, humidity and negative oxygen ions in the chamber (box) type vacuum high-pressure cabin 1-9 reach the required standards, meanwhile, the electromagnetic valve B3 and the electromagnetic valve B4 are enabled to open an A3 and an A4 inflation pipeline (atmospheric air intake → A4 → air filter → A4 → B4 → A4 → air inlet e → air outlet d → A3 → B3 → A3 → the air inlet f of the vacuum high-pressure cabin), and the air pump 3 is started to appropriately pressurize the chamber (box) type vacuum high-pressure cabin 1-9 to between 0.01KPa and 10MPa, the superoxide in the chamber (box) type vacuum high-pressure cabin 1-9 with appropriate positive pressure is used for sterilizing, disinfecting, anti-mildew, degrading pesticide residue, fruit and vegetable metabolism and the like gas sucked out, the activity of enzymes in fruits and vegetables is influenced, browning and softening of the fruits and vegetables are prevented, the fruit and vegetable aging is delayed, the moisture in the fruit and vegetable flesh fish is prevented from escaping under proper high pressure, the moisture is easier to permeate and supplement the water lost due to refrigeration, negative pressure and the like to the fruit and vegetable flesh fish under positive pressure, the size of water molecular groups of the moisture is smaller due to negative oxygen ions, the water molecular groups are more convenient for the fruit and vegetable flesh fish to absorb, the biological tissue metabolism is inhibited, the respiratory strength is reduced, the activity of the enzyme is slowed down, a certain sterilization and purification effect is achieved, and the super-oxygen can permeate into the deeper inner part of the fruit and vegetable flesh fish under positive pressure; (4) and air-conditioned pressurized storage procedure: the positive negative pressure intelligent control device 5 timely opens the air suction pipeline and opens the air suction pump 2 and the superoxide decomposer 6.7 according to the program setting or sensor feedback, the decomposed and sterilized and degraded dirty air is pumped out of the cabin, then the solenoid valves B3, B6, B7 and B2 are opened A3, A9, A6 and A7 air-conditioned air inflation pipeline (air pump air outlet d → A3 → A9 → A6 → B6 → A6 → air-conditioned device air inlet t → air outlet s → A7 → B7 → A7 → vacuum high pressure cabin air inlet i) is opened and the air pump 3 is started, the air flow is driven to pass through the hollow fiber membrane of the air-conditioned device 8.1, the oxygen is separated out, the high nitrogen hypoxia air enters the vacuum high pressure cabin air inlet 1-9, and simultaneously the solenoid valves B3, B5 and B387 open the circulating pipeline (the vacuum high pressure ballast 1-9 circulating air inlet 36j → A3646 → B5 → A5 → B5), meanwhile, the humidifier 6.5 is started until the concentration of the atmosphere-modified gas, the air humidity and the positive air pressure in the cabin reach the atmosphere-modified pressurized storage standard, a nitrogen-rich oxygen-poor environment with a proper proportion is formed in the chamber (box) type vacuum hyperbaric chamber 1-9, and proper positive pressure and proper humidity are kept, so that the respiration rate of the stored fruits and vegetables is effectively controlled, anaerobic respiration and carbon dioxide poisoning are prevented, the aging process is delayed, the quality reduction and flavor loss of the stored fruits and vegetables are prevented, the moisture of the fruits and vegetables is kept under positive pressure, and the freshness of the fruits and vegetables is maintained to the maximum extent; (5) and (3) opening the door to immediately arrange a protection program: if someone opens the carriage door during the superoxide sterilization or the air-conditioned storage, the cabin door switch immediately feeds back, the positive and negative pressure intelligent control device 5 immediately operates to stop the superoxide or air-conditioned procedure, simultaneously opens the air extraction pipeline and starts the air extraction pump 2 to quickly extract the superoxide or high-nitrogen hypoxia gas to the superoxide decomposer 6.7 for decomposition and then discharge, and because the air is supplemented with the air extraction negative pressure from the side of the human body to the carriage (box) type vacuum hyperbaric chamber 1-9, the user can not contact the superoxide and high-nitrogen hypoxia gas to avoid the damage. (6) The air water making program is that moist waste gas pumped by the air pump 2 from the compartment (box) type vacuum high-pressure cabin 1-9 enters the superoxide decomposer 6.7 to decompose superoxide and then enters the air water making device 11, the water is condensed and filtered into drinking standard purified water to provide an uninterrupted water source for the humidifier 6.5, when the air pump 3 is idle, the intelligent control device 5 can also start the air pump 3 and enable the electromagnetic valves B3 and B2 to open an air water making inflation pipeline (the air outlet d → A3 → A9 → B2 → A2 → the air inlet h → the air outlet n → A2 → is discharged into the atmosphere) to drive air outside the compartment to enter the air water making device 11 to make water; (7) low-temperature storage auxiliary fresh-keeping procedure: after the refrigerator is started, the positive and negative pressure intelligent control device 5 starts the refrigerating system 8, is communicated with the evaporator air cooling combination 8.1 through a refrigerating pipeline A13, provides corresponding low temperature for the compartment (box) type vacuum high-pressure cabin 1-9 through the feedback and control of the temperature sensing controller C9, and assists the positive and negative pressure system to keep the stored articles fresh. (8) remote and near manipulation monitoring function: the touch screen and mobile phone monitoring system 12 can control and monitor the real-time state of the positive-negative pressure fresh-keeping carriage (container) in real time through the touch screen 12.1 and the mobile phone APP12.2, so that the fresh-keeping carriage (container) can intelligently realize functions of high efficiency, low consumption and safety according to a set program and an instant instruction; the touch screen 12.1 or the mobile phone APP12.2 can display and remind information such as temperature, humidity, gas concentration, storage article loading time and quality guarantee period in the compartment, a user can remotely monitor and operate the compartment or the outside of the compartment, and the compartment is very convenient to use; the above programs are automatically controlled by the positive and negative pressure system and set to be controlled in a shortcut key mode in the touch screen and the mobile phone monitoring system 12.

In an eighth specific embodiment, the intelligent positive and negative pressure freshness preservation warehouse comprises a warehouse body 7; an intelligent positive and negative pressure system, a refrigerating system 8, a touch screen and a mobile phone monitoring system 12 are arranged in the storehouse body 7; the intelligent positive and negative pressure system comprises a positive and negative pressure cabin 1, an air pump 2, an inflator pump 3, a positive and negative pressure intelligent regulation and control device 5 and a positive and negative pressure airflow carried object generation processor; the positive and negative pressure cabin 1 is designed into a storage type vacuum high-pressure cabin 1-10 according to the specific requirements of the intelligent positive and negative pressure fresh-keeping warehouse; the warehouse type vacuum high-pressure cabin 1-10 includes: the device comprises a cabin body 1.1, a cabin door 1.2, a mechanical airtight mechanism 1.3 and an in-cabin outer sealing communicating vessel 1.4; the hatch door 1.2 is a warehouse door of the positive and negative pressure fresh-keeping warehouse; a mechanical airtight mechanism 1.3 is arranged between the cabin door 1.2 and the cabin body 1.1 of the storage type vacuum high-pressure cabin 1-10; the mechanical airtight mechanism 1.3 comprises a lock ring 1.31, a bolt 1.32 and an airtight gasket 1.33; the lock ring 1.31 is movably matched with the bolt 1.32, the bolt 1.32 extends into the lock ring 1.31 to lock the cabin door when the cabin door is closed, and the cabin door is sealed by the airtight gasket 1.33 when positive and negative air pressure is formed in the storage type vacuum high-pressure cabin 1-10; the in-cabin and out-cabin pipeline connection controller 1.4 is fixedly arranged at the rear part of the storage type vacuum high-pressure cabin 1-10, and all pipelines and circuits which enter and exit the cabin are connected to the in-cabin and out-cabin sealing communicator 1.4 and enter and exit through the in-cabin and out-cabin sealing communicator so as to keep the sealing performance of the storage type vacuum high-pressure cabin 1-10. An air pump 2, an inflator pump 3, a positive and negative pressure intelligent regulation and control device 5, an air conditioning device 6.1, a superoxide decomposer 6.7, an air filter 6.8, a refrigeration system 8, an air water production device 11, a filtering water tank 11.1, a touch screen and a mobile phone monitoring system 12 are arranged outside the storage type vacuum hyperbaric chamber 1-10; an air suction pipeline A1 is installed at the air inlet a of the air suction pump 2, an electromagnetic valve B1 is installed in the middle of the air suction pipeline A1, and the other end of the air suction pipeline A extends into the storage type vacuum high-pressure cabin 1-10 to form an air suction return port c; an air outlet B of the air pump 2 is provided with an air exhaust pipeline A2, the middle part of the air exhaust pipeline A2 is provided with a superoxide decomposer 6.7 and an electromagnetic valve B2, the other end of the air exhaust pipeline A2 is communicated with an air inlet h of the air water making device 11, and air is introduced from an air outlet n of the air water making device 11; an air inflation pipeline A3 is arranged at an air outlet d of the air inflation pump 3, an electromagnetic valve B3 is arranged in the middle of the air inflation pipeline A3, and the other end of the air inflation pipeline A extends into the storage type vacuum high-pressure cabin 1-10 to form an air inflation inlet f; an air inlet pipeline A4 is installed at an air inlet e of the inflator pump 3, an electromagnetic valve B4 and an air filter 6.8 are installed in the middle of the air inlet pipeline A4, and the other end of the air inlet pipeline is communicated with the atmosphere; the electromagnetic valve B4 is also connected with a circulating pipeline A5, the middle part of the circulating pipeline A5 is provided with an electromagnetic valve B5, the other end of the circulating pipeline A is communicated with an electromagnetic valve B3, and the circulating pipeline A3 extends into the storage type vacuum high-pressure cabin 1-10 to form a circulating return air port j; the inflation pipeline A3 is also connected with an air-to-water inflation pipeline A9, and the air-to-water inflation pipeline A9 is connected to an electromagnetic valve B2 and communicated with an air inlet h of the air-to-water device 11 through an exhaust pipeline A2; an air-conditioning air inlet pipeline A6 is installed at the air inlet t of the air-conditioning device 6.1, an electromagnetic valve B6 is installed in the middle of the air-conditioning air inlet pipeline A6, the other end of the air-conditioning air inlet pipeline A3 is connected to an air inflation pipeline A3 and then is communicated with an air outlet d of the air inflation pump 3, an air-conditioning air outlet pipeline A7 is installed at the air outlet s of the air-conditioning device 6.1, an electromagnetic valve B7 is installed in the middle of the air-conditioning air outlet pipeline A7, and the other end of the air-conditioning air outlet; an air water making pipeline A10 is installed at a water outlet x of the air water making device 11, and the air water making pipeline A10 is communicated with a water inlet y of the filtering water tank 11-1; condensed water generated in the bin type vacuum high-pressure cabin 1-10 flows into a water inlet Y of a condensed water collecting box 11.2 arranged at the bottom in the cabin, a condensed water pipeline A11 is arranged at a water outlet M of the condensed water collecting box 11.2, an electromagnetic valve B11 is arranged in the middle of the condensed water pipeline A11 after extending out of the bin type vacuum high-pressure cabin 1-10, the other end of the condensed water pipeline A3526 is communicated with a water inlet v of a filter water tank 11.1, a humidifying water pipeline A12 is arranged at a water outlet o of the filter water tank 11.1, an electromagnetic valve B12 is arranged in the middle of the humidifying water pipeline A12, the other end of the condensed water pipeline A11 extends into the bin type vacuum high-pressure cabin 1; the refrigerating system 8 is provided with a refrigerating circulation pipeline A13, and the refrigerating circulation pipeline A13 extends into the warehouse type vacuum hyperbaric chamber 1-10 and is communicated with an evaporator air cooling combination 8.1; the touch screen and mobile phone monitoring system 12 includes: the mobile phone comprises a touch screen 12.1, a mobile phone APP12.2 and an anti-fog camera 12.3, wherein the anti-fog camera 12.3 is arranged at a position to be monitored inside and outside the warehouse body 7; the inside setting of warehouse style vacuum hyperbaric chamber 1-10 is installed positive negative pressure air current and is taken thing and take place treater and sensor, includes: 6.5 parts of a humidifier, 6.2 parts of an ultrasonic generator, 6.3 parts of negative ion generation, 6.4 parts of a gas catalyst controlled release device, 11.2 parts of a condensed water collecting box, a pressure sensor C1, a negative pressure sensor C2, a super oxygen sensor C3, a negative oxygen ion sensor C4, a chlorine dioxide sensor C5, a humidity sensor C6, an oxygen sensor C7, a nitrogen sensor C8 and a temperature sensor C9; all the airflow carry generation processors, sensors, electromagnetic valves and equipment devices installed inside and outside the warehouse type vacuum high-pressure cabins 1 to 10 include: the air extracting pump 2, the inflator pump 3, the air conditioning device 6.1, the superoxide generator 6.2, the anion generator 6.3, the gas catalyst controlled release device 6.4, the humidifier 6.5, the superoxide decomposer 6.7, the refrigeration system 8, the air water making device 11, the filter water tank 11.1, the touch screen and mobile phone monitoring system 12, the touch screen 12.1, the high-definition anti-fog camera device 12.3, the pressure sensor C1, the negative pressure sensor C2, the superoxide sensor C3, the negative oxygen ion sensor C4, the chlorine dioxide sensor C5, the humidity sensor C6, the oxygen sensor C7, the nitrogen sensor C8, the temperature sensor C9, the water level sensor C10 and the electromagnetic valves B1 to B12 are all connected to the positive and negative pressure intelligent regulation device 5.

The operation method of the intelligent positive and negative pressure fresh-keeping warehouse comprises the following steps: (1) and vacuum pest and heat removing cleaning procedure: after fresh goods to be stored are transported into the warehouse type vacuum high-pressure cabin 1-10, the cabin door 1.2 is closed, the cabin door switch 1.8 is touched or manually opened by a warehouse keeper, and the positive and negative pressure intelligent control device 5 sends an instruction: the electromagnetic valves B1 and B2 are communicated with air suction pipelines A1 and A2 (air suction return air port c → A1 → B1 → A1 → air suction pump 5 air inlet a → air outlet B → A2-superoxide decomposer air inlet g → air outlet m → A2 → B2 → A2 → air water making device air inlet h → air outlet n → A2 → air discharge), and the air suction pump 2 is started to pump the storage type vacuum high-pressure cabin 1-10 to moderate vacuum (-0.01 KPa-0.09 MPa), so that the heat, bacterial microorganisms and the dirty air in the cabin of the fruits and vegetables are sucked away, the vacuum promotes the volatile metabolites ethylene-acetaldehyde-ethanol and other harmful gases in the fruit and vegetable tissues to escape and be pumped away, and the negative pressure is used for inhibiting the propagation of residual bacteria, thereby reducing the aging of the fruits and vegetables; (2) and a reduced-pressure humidification storage procedure: the positive and negative pressure intelligent control device 5 maintains a proper negative pressure low-oxygen low-temperature environment in the storage type vacuum high-pressure cabin 1-10 by opening or closing the air pump 2 according to the pressure standard of a preset program and the real-time feedback of the negative pressure sensor C2, reduces the respiration intensity of fruits and vegetables, inhibits the biosynthesis of ethylene, delays the decomposition of chlorophyll, inhibits the synthesis of carotenoid and lycopene, and slows down the processes of hydrolysis of starch, increase of sugar, consumption of acid and the like, so that the ripening and aging of the fruits and vegetables are delayed, meanwhile, the humidifier 6.5 is opened to improve the humidity in the cabin, prevent the moisture of the fruits and vegetables from escaping, and maintain the fresh state of the fruits and vegetables for a longer time; (3) and the superoxide pressure sterilization degradation program: the positive and negative pressure intelligent control device 5 timely sends out instructions to start the superoxide generator 6.2, the negative oxygen ion generator 6.3 and the humidifier 6.5 according to program setting and feedback of sensors C3, C4 and C6 to enable the superoxide, humidity and negative oxygen ions in the storage type vacuum high-pressure cabin 1-10 to reach the required standards, simultaneously enables the electromagnetic valves B3 and B4 to open an A3 and A4 inflation pipeline (air intake → A4 → air filter → A4 → B4 → A4 → air inlet e → air outlet d → A3 → B3 → A3 → air inlet f) and starts the inflation pump 3 to properly pressurize the vacuum high-pressure cabin 1-10 to 0.01 KPa-10 MPa), the superoxide with proper positive pressure is used for sterilizing, disinfecting, sterilizing, resisting mildew and degrading ethylene and metabolizing gases of residual fruits and vegetables in the storage type vacuum high-pressure cabin 1-10 to affect the activity of enzymes in the fruits and vegetables, the fruit and vegetable browning and softening are prevented, the fruit and vegetable aging is delayed, the moisture in the fruit and vegetable flesh fish is prevented from escaping under proper high pressure, the moisture is easier to permeate and supplement the water lost due to refrigeration, negative pressure and the like to the fruit and vegetable flesh fish under positive pressure, the size of water molecular groups of the moisture is smaller due to negative oxygen ions, the water molecular groups are more convenient to absorb by the fruit and vegetable flesh fish, the biological tissue metabolism is inhibited, the respiratory intensity is reduced, the activity of enzyme is slowed down, a certain sterilization and purification effect is achieved, and the super-oxygen can permeate into the deeper inner part of the fruit and vegetable flesh fish under the positive pressure to better play a sterilization; (4) and air-conditioned pressurized storage procedure: the positive negative pressure intelligent control device 5 timely opens an air suction pipeline and opens the air suction pump 2 and the superoxide decomposer 6.7 according to program setting or sensor feedback, the decomposed, sterilized and degraded dirty air is sucked out of the cabin, then the solenoid valves B3, B6, B7 and B2 are opened A3, A9, A6 and A7 air-conditioning inflation pipelines (the air outlet of the air suction pump d → A3 → A9 → A6 → B6 → A6 → the air inlet of the air-conditioning device t → the air outlet s → A7 → B7 → A7 → the air inlet of the vacuum high-pressure cabin) are opened, the air pump 3 is started, the air flow is driven to pass through the hollow fiber membrane of the air-conditioning device 6.1, the oxygen is separated out, the high-nitrogen low-oxygen gas enters the vacuum high-pressure cabin 1-10, and the air inlet of the solenoid valves B3, B5 and B387 is opened a circulating air-conditioning pipeline (the air inlet of the vacuum high-pressure cabin is circulated back j → A3B 3646 → B5 → A → 5 → 46 → A5 → 38, meanwhile, the humidifier 8.5 is started until the concentration of the modified atmosphere gas, the air humidity and the positive air pressure in the cabin reach the modified atmosphere pressurization storage standard, a nitrogen-rich oxygen-poor environment with a proper proportion is formed in the storage type vacuum high-pressure cabin 1-10, and proper positive pressure and proper humidity are kept, so that the respiration rate of the stored fruits and vegetables is effectively controlled, anaerobic respiration and carbon dioxide poisoning are prevented, the aging process is delayed, the quality reduction and flavor loss of the stored fruits and vegetables are prevented, the moisture of the fruits and vegetables is kept and supplemented by positive pressure, and the freshness of the fruits and vegetables is maintained to the maximum extent; (5) and (3) opening the door to immediately arrange a protection program: if someone opens the warehouse door during the superoxide sterilization or air-conditioned storage, the door switch immediately feeds back, the positive and negative pressure intelligent control device 5 immediately operates to stop the superoxide or air-conditioned procedure, simultaneously opens the air extraction pipeline and starts the air extraction pump 2 to quickly extract the superoxide or high-nitrogen hypoxia gas to the superoxide decomposer 6.7 for decomposition and then discharge, and because the air is supplemented with the air extraction negative pressure from the side of the human body to the warehouse type vacuum hyperbaric chamber 1-10, the user can not contact the superoxide and high-nitrogen hypoxia gas to avoid the harm. (6) an air water making program, wherein moist waste gas pumped by the air pump 2 from the storage type vacuum hyperbaric chamber 1-10 enters the superoxide decomposer 6.7 to decompose superoxide and then enters the air water making device 11, the water is condensed and filtered into drinking standard purified water to provide an uninterrupted water source for the humidifier 6.5, and when the air pump 3 is idle, the intelligent control device 5 can also start the air pump 3 to enable the electromagnetic valves B3 and B2 to open an air water making inflation pipeline (the air outlet d → A3 → A9 → B2 → A2 → the air inlet h → the air outlet n → A2 → atmospheric air), so as to drive the outside air of the warehouse to enter the air water making device 11 to make water; (7) low-temperature storage auxiliary fresh-keeping procedure: after the machine is started, the positive and negative pressure intelligent control device 5 starts the refrigerating system 8, is communicated with the evaporator air cooling combination 8.1 through a refrigerating pipeline A13, provides corresponding low temperature for the warehouse type vacuum high-pressure cabin 1-10 through the feedback and control of a temperature sensing controller C9, and assists the positive and negative pressure system to keep the stored articles fresh; (8) and remote and near range operation monitoring function: the touch screen and mobile phone monitoring system 12 can control and monitor the real-time state of the positive and negative pressure fresh-keeping warehouse in real time through the touch screen and the mobile phone APP, so that the fresh-keeping warehouse can intelligently realize functions of high efficiency, low consumption and safety according to a set program and an instant instruction; the touch screen 12.1 or the mobile phone APP12.2 can display and remind information such as temperature, humidity, gas concentration, storage article loading time and quality guarantee period in the storage, and a user can monitor and operate the mobile phone in a far and near range, so that the mobile phone is very convenient; the above programs are automatically controlled by the positive and negative pressure system and set to be controlled in a shortcut key mode in the touch screen and the mobile phone monitoring system 12.

In a ninth specific embodiment, the intelligent positive and negative pressure module cabinet comprises a cabinet body 7; an intelligent positive-negative pressure system, a refrigerating and heating system 8.3, a touch screen and a mobile phone monitoring system 12 are arranged in the cabinet body 7; the intelligent positive and negative pressure system comprises a positive and negative pressure cabin 1, an air pump 2, an inflator pump 3, a positive and negative pressure intelligent regulation and control device 5 and a positive and negative pressure airflow carried object generation processor; the positive and negative pressure cabin 1 is designed into a modular vacuum high-pressure cabin 1-11 according to the specific requirements of the intelligent positive and negative pressure module cabinet; the modular vacuum hyperbaric chamber 1-11 comprises: the device comprises a cabin body 1.1, a cabin door 1.2, a pneumatic airtight mechanism 1.5, an in-cabin outer sealing communicating vessel 1.4 and a pneumatic cabin door switch 1.8; the cabin door 1.2 is a cabinet door of the positive and negative pressure module cabinet; a pneumatic airtight mechanism 1.5 is arranged between the cabin door 1.2 and the cabin body 1.1 of the modular vacuum high-pressure cabin 1-11; the pneumatic airtight mechanism 1.5 comprises a pneumatic sealing bolt 1.51 and a sealing bolt telescopic air bag 1.52 integrally manufactured at the rear part of the sealing bolt 1.51; the sealing bolt 1.51 and the sealing bolt telescopic air bag 1.52 of the integrated mechanism are totally 4 and are all strip-shaped, the sealing bolts and the sealing bolt telescopic air bag are respectively installed in 4 cabin airtight grooves 1.11 arranged in 4 side frames of a door frame of a cabin 1.1, the outer layer part of the cross section of the bolt body is made of sealing rubber, and the inner part of the cross section of the bolt body is made of a bending-resistant metal core; the sealing bolt folding telescopic air bag 1.52 is an inflatable folding rubber air bag, and an inflatable socket 1.53 is arranged at the rear part of the air bag; an inflation plug 1.54 is inserted into the inflation socket 1.53, 4 inflation plugs 1.54 are arranged, the inflation plugs 1.54 are respectively installed and communicated with the middle points of the 4 side pipelines of the four sides of the square annular air-tight mechanism inflation branch pipeline A8.1, the top side pipeline of the pneumatic square annular inflation pipeline A8.1 is vertically connected with the inflation pipeline A8 and is communicated with the air outlet d of the inflator pump 3 through an electromagnetic valve B5, a pipeline A3 and an electromagnetic valve B3, when the cabin door is closed, the cabin door 1.2 touches the pneumatic cabin door switch 1.8, the inflator pump 3 is immediately started to inflate the sealing bolt folding telescopic airbag 1.52 to extend, and pushes the sealing bolt 1.51 to extend outwards from the air-tight groove 1.11 of the cabin body and extend into the air-tight cabin door groove 1.21 arranged at the corresponding position of the opposite side of the cabin door, so as to lock and seal the cabin door, when the cabin door is opened, the pneumatic cabin door folding telescopic airbag 1.52 is used as the sealing bolt folding airbag through the pneumatic cabin, retracting the sealing bolt 1.51 to open the hatch door; the communication device 1.4 for the inside and outside sealing is fixedly arranged at the rear part of the modular vacuum high-pressure cabin 1-11, and all pipelines and circuits for entering and exiting the inside and outside of the cabin are connected to and enter and exit through the communication device 1.4 for the outside and inside sealing so as to maintain the sealing performance of the modular vacuum high-pressure cabin 1-11. An air pump 2, an inflator pump 3, a positive and negative pressure intelligent regulation and control device 5, an air conditioning device 6.1, a superoxide decomposer 6.7, an air filter 6.8, a refrigeration and heating system 8.3, an air water production device 11, a filtering water tank 11.1, a pneumatic cabin door switch 1.8, a touch screen and a mobile phone monitoring system 12 are arranged outside the modular vacuum hyperbaric chamber 1-11; an air suction pipeline A1 is installed at the air inlet a of the air suction pump 2, an electromagnetic valve B1 is installed in the middle of the air suction pipeline A1, and the other end of the air suction pipeline A extends into the modular vacuum high-pressure cabin 1-11 to form an air suction return port c; an air outlet B of the air pump 2 is provided with an air exhaust pipeline A2, the middle part of the air exhaust pipeline A2 is provided with a superoxide decomposer 6.7 and an electromagnetic valve B2, the other end of the air exhaust pipeline A2 is communicated with an air inlet h of the air water making device 11, and air is introduced from an air outlet n of the air water making device 11; an air inflation pipeline A3 is installed at the air outlet d of the air inflation pump 3, an electromagnetic valve B3 is installed in the middle of the air inflation pipeline A3, and the other end of the air inflation pipeline A extends into the modular vacuum high-pressure cabin 1-11 to form an air inflation inlet f; an air inlet pipeline A4 is installed at an air inlet e of the inflator pump 3, an electromagnetic valve B4 and an air filter 6.8 are installed in the middle of the air inlet pipeline A4, and the other end of the air inlet pipeline is communicated with the atmosphere; the electromagnetic valve B4 is also connected with a circulating pipeline A5, the middle part of the circulating pipeline A5 is provided with an electromagnetic valve B5, the other end of the circulating pipeline A is communicated with an electromagnetic valve B3, and the circulating pipeline A3 extends into the modular vacuum high-pressure cabin 1-11 to form a circulating return air port j; the electromagnetic valve B5 is also connected with an airtight mechanism inflation pipeline A8, the airtight mechanism inflation pipeline A8 is communicated with an air outlet d of the inflator 3 through an electromagnetic valve B5 and an inflation pipeline A3, the other end of the inflation pipeline A8 is connected to a top side pipeline of a square annular inflation pipeline A8.1, four side pipelines of the square annular inflation pipeline A8.1 are communicated with each other, the middle point of the square annular inflation pipeline A8.1 is connected with an inflation plug 1.54, and the inflation plugs 1.54 are inserted into and connected to corresponding inflation sockets 1.53; the inflation pipeline A3 is also connected with an air-to-water inflation pipeline A9, and the air-to-water inflation pipeline A9 is connected to an electromagnetic valve B2 and communicated with an air inlet h of the air-to-water device 11 through an exhaust pipeline A2; an air-conditioned air inlet pipeline A6 is installed at the air inlet t of the air-conditioned device 6.1, an electromagnetic valve B6 is installed in the middle of the air-conditioned air inlet pipeline A6, the other end of the air-conditioned air inlet pipeline A3 is connected to an air inflation pipeline A3 and then is communicated with an air outlet d of the air inflation pump 3, an air-conditioned air outlet pipeline A7 is installed at the air outlet s of the air-conditioned device 6.1, an electromagnetic valve B7 is installed in the middle of the air-conditioned air outlet pipeline A7, and the other end of the air-conditioned; an air water making pipeline A10 is installed at a water outlet x of the air water making device 11, and the air water making pipeline A10 is communicated with a water inlet y of the filtering water tank 11-1; condensed water generated in the modular vacuum high-pressure cabin 1-11 flows into a water inlet Y of a condensed water collecting box 11.2 installed at the bottom of the cabin, a dehumidification condensed water pipeline A31 is installed at the other water inlet N of the condensed water collecting box 11.2, and the other end of the dehumidification condensed water pipeline A31 is connected at a condensed water outlet H of the dehumidification device; a condensed water pipeline A11 is installed at a water outlet M of the condensed water collecting box 11.2, the condensed water pipeline A11 extends out of the modular vacuum high-pressure cabin 1-11 and is provided with an electromagnetic valve B11 in the middle, the other end of the condensed water pipeline is communicated with a water inlet v of the filter water tank 11-1, a humidifying water pipeline A12 is installed at a water outlet o of the filter water tank 11.1, an electromagnetic valve B12 is installed in the middle of the humidifying water pipeline A12, and the other end of the condensed water pipeline extends into the modular vacuum high-pressure cabin 1-11 and is communicated with a water inlet R; the refrigerating and heating system 8.3 is provided with a circulating pipeline A13, and the circulating pipeline A13 extends into the modular vacuum high-pressure cabin 1-11 and is communicated with a heat exchanger 8.4; the touch screen and mobile phone monitoring system 12 includes: the mobile phone comprises a cabinet door touch screen 12.1, a mobile phone APP12.2 and a high-definition anti-fog camera 12.3, wherein the high-definition anti-fog camera 12.3 is arranged at a position needing to be monitored inside and outside a cabinet body 7; the inside setting of modular vacuum hyperbaric chamber 1-11 is installed positive negative pressure air current and is taken over thing and take place treater and sensor, includes: 6.5 of a humidifier, 6.9 of an air disinfection and sterilization device, 6.10 of an air filtration and refreshing device, 6.11 of a dehumidifying device, 11.2 of a condensed water collecting box, C1 of a pressure sensor, C2 of a negative pressure sensor, C3 of a super-oxygen sensor, C4 of a negative oxygen ion sensor, C5 of a chlorine dioxide sensor, C6 of a humidity sensor, C7 of an oxygen sensor, C8 of a nitrogen sensor, C9 of a temperature sensing controller, C10 of a water level sensing controller and C11 of air particulate matter sensors; all the airflow ballast generating processors, sensors, solenoid valves and equipment devices installed inside and outside the modular vacuum hyperbaric chambers 1-11 include: the air extracting pump 2, the inflator pump 3, the air conditioning device 6.1, the humidifier 6.5, the superoxide decomposer 6.7, the air sterilizing and disinfecting device 6.9, the air filtering and refreshing device 6.10, the dehumidifying device 6.11, the refrigerating and heating system 8.3, the heat exchanger 8.4, the air water making device 11, the filter water tank 11.1, the touch screen and mobile phone monitoring system 12, the cabinet door touch screen 12.1, the high-definition anti-fog camera 12.3, the pressure sensor C1, the negative pressure sensor C2, the superoxide sensor C3, the negative oxygen ion sensor C4, the chlorine dioxide sensor C5, the humidity sensor C6, the oxygen sensor C7, the nitrogen sensor C8, the temperature sensing controller C9, the water level sensing controller C10, the air particulate matter sensor C11 and the electromagnetic valves B1 to B12 are all connected to the positive and negative pressure intelligent control device 5.

The operation method of the intelligent positive and negative pressure module cabinet has the advantages that the intelligent positive and negative pressure module cabinet has vacuum, high pressure, constant temperature, constant humidity, constant pressure, sterility and dustless environment, various articles and equipment such as tableware, kitchen ware, household appliances and the like can be placed and installed, and the operation method comprises the following steps: (1) and vacuum pest-removing cleaning procedure: after tableware, kitchen ware, small household appliances and small articles are put into the modular vacuum high-pressure cabin 1-11, the cabin door switch 1.8 is touched when the cabin door 1.2 is closed, and the positive and negative pressure intelligent control device 5 sends an instruction: the electromagnetic valves B1 and B2 open the air suction pipelines A1 and A2 (the air suction return air port c → A1 → B1 → A1 → the air suction pump 5 air inlet a → air outlet B → A2 → the air inlet g of the superoxide decomposer → air outlet m → A2 → B2 → A2 → the air water preparation device air inlet h → air outlet n → air outlet for discharging to the atmosphere), and the air suction pump 2 is started to suck the modular vacuum high-pressure cabin 1-11 to moderate vacuum (-0.01KPa to-0.09 MPa), so as to suck partial bacterial microorganisms and dirty air in the cabin, and clean the air and the space; (2) and a disinfection and sterilization program: the positive and negative pressure intelligent control device 5 sends out an instruction to open and open the air disinfection and sterilization device 6.9, the air disinfection and sterilization device 6.9 includes: the ultrasonic generator, the ultraviolet disinfection lamp and the like can be arranged and selected according to different disinfection requirements to disinfect and sterilize the environment and articles in the cabin; (3) specific condition sterile nondestructive storage procedure: the modular cabinets with different types and different configurations can provide specific storage environments such as vacuum, high pressure, constant temperature, constant humidity, constant pressure, sterility, dustless and the like, and meet various different storage requirements, for example, small tableware, kitchen ware, household appliances and small articles can be stored in vacuum after being subjected to super-oxygen sterilization, and high-grade clothes of calligraphy and painting documents and antique cultural relics can be stored in vacuum, low oxygen and dustless or stored in specific modified atmosphere or stored in constant temperature, constant humidity and constant pressure; (4) and multipurpose exhibition refrigeration of the wine bar: various food articles such as food, beverage and wine, dried fruits, candies, cakes and the like can be packaged and stored by adopting the expicity refrigeration of a transparent cabinet door; (5) and remote and near range operation monitoring function: the touch screen and mobile phone monitoring system 12 can control and monitor the real-time state of the positive and negative pressure module cabinet in real time through the WIFI and the mobile phone APP in a long and short distance manner, so that the module cabinet can realize functions of high efficiency and low consumption intelligently according to a set program and an instant instruction; the high-definition anti-fog camera device 12.3 shoots the conditions of articles in the refrigerator in real time, the refrigerator door touch screen 12.1 or the mobile phone APP12.2 can display and remind commodity information such as production time, price, quality guarantee period, manufacturers and the like and information of purchasers and online stores, automatically records, analyzes and collates big data such as time, quantity and frequency preference of the refrigerator for taking out articles, and carries out intelligent analysis, and then reminds in time on the mobile phone APP12.2 or directly pushes recommended commodities to be purchased to the mobile phone APP12.2 and the refrigerator door touch screen 12.1 for a user to conveniently select and purchase; the high-definition anti-fog camera device 12.3 is used for monitoring and recording in real time, and particularly, starting from a position far away from a refrigerator body in the closing process of the refrigerator door, automatically continuously shooting a plurality of panoramic photos of articles in the refrigerator along with the closing movement of the refrigerator door 1.2, or automatically recording small videos at the same time, so that a user can check the panoramic photos or videos of the articles in the refrigerator with good light and large visual field in the last closing process and the closing process of the refrigerator door in a touch screen of the refrigerator door at any time without opening the refrigerator door, vacuumizing and reducing the temperature in a short range; (6) the positive and negative pressure module combined intelligent home mode: the intelligent positive and negative pressure module cabinet is manufactured according to module function design, not only is independently produced and used as an independent invention right, but also can be organically combined with other positive and negative piezoelectric devices and the module cabinet under the control of the touch screen and the mobile phone APP monitoring system 12 to form an intelligent positive and negative pressure module combined home with complete functions, the module cabinet is high in energy, efficient, low in consumption and suitable for use, an intelligent positive and negative pressure system, a refrigerating system and an air water making device which share other positive and negative piezoelectric devices and the module cabinet can be shared, and the appearance shape and the color are basically uniform, and the appearance is neat and harmonious and accords with the popular trend.

Claims

1. An intelligent positive and negative pressure system, comprising: the device comprises a positive and negative pressure cabin (1), an air pump (2), an inflator pump (3), a positive and negative pressure intelligent regulation and control device (5) and a positive and negative pressure airflow carrying object generation processor; the positive and negative pressure cabin (1) comprises: the cabin comprises a cabin body (1.1), a cabin door (1.2), an airtight mechanism (1.3) and a cabin inner and outer communicating sealer (1.4); an airtight mechanism (1.3) is arranged between the cabin body (1.1) and the cabin door (1.2); the cabin internal and external sealed communicating vessel (1.4) is fixedly arranged at the rear part of the positive and negative pressure cabin (1), and all pipelines and circuits which enter and exit the cabin internal and external are connected to the cabin internal and external sealed communicating vessel (1.4) and pass through the cabin internal and external sealed communicating vessel to keep the sealing performance of the positive and negative pressure cabin (1); an air-conditioning device (6.1) which is provided with an air pump (2), an air pump (3), a positive and negative pressure intelligent regulation and control device (5) and a positive and negative pressure airflow carried object generation processor is arranged outside the positive and negative pressure cabin (1); an air suction pipeline (A1) is installed at an air inlet (a) of the air suction pump (2), an electromagnetic valve (B1) is installed in the middle of the air suction pipeline (A1), the other end of the air suction pipeline extends into the positive and negative pressure cabin (1) to form an air suction return port (c), an air exhaust pipeline (A2) is installed at an air outlet (B) of the air suction pump (2), and the other end of the air exhaust pipeline (A2) is communicated with the atmosphere; an air inflation pipeline (A3) is installed at an air outlet (d) of the air inflation pump (3), an electromagnetic valve (B3) is installed in the middle of the air inflation pipeline (A3), the other end of the air inflation pipeline extends into the positive and negative pressure cabin (1) to form an air inflation inlet (f), an air intake pipeline (A4) is installed at an air inlet (e) of the air inflation pump (5), an electromagnetic valve (B4) is installed in the middle of the air intake pipeline (A4), and the other end of the air intake pipeline is communicated with the atmosphere; the electromagnetic valve (B4) is also connected with a circulating pipeline (A5), the middle part of the circulating pipeline (A5) is provided with the electromagnetic valve (B5), the other end of the circulating pipeline is connected with the electromagnetic valve (B3) and extends into the positive and negative pressure cabin (4) through an inflation pipeline (A3) to form a circulating air return port (j) of the positive and negative pressure cabin; an air-conditioned air inlet pipeline (A6) is installed at an air inlet (t) of the air-conditioned device (6.1), an electromagnetic valve (B6) is installed in the middle of the air-conditioned air inlet pipeline (A6), the other end of the air-conditioned air inlet pipeline is connected to an air inflation pipeline (A3) and then communicated with an air outlet (d) of the air inflation pump (3), an air-conditioned air outlet pipeline (A7) is installed at an air outlet(s) of the air-conditioned device (6.1), an electromagnetic valve (B7) is installed in the middle of the air-conditioned air outlet pipeline (A7), the other end of the air-conditioned air outlet pipeline extends into the positive and negative ballast (1) to form an air-conditioned air inlet (i), and when the air-conditioned air entering the positive and negative; the inside of positive negative pressure cabin (1) is also installed positive negative pressure air current and is carried thing and take place the treater, includes: an ultrasonic generator (6.2), a negative ion generator (6.3), a gas catalyst controlled release device (6.4) and a humidifier (6.5); the inside of positive negative pressure cabin (1) still installs the sensor, includes: a pressure sensor (C1), a negative pressure sensor (C2), a superoxide sensor (C3), a negative oxygen ion sensor (C4), a chlorine dioxide sensor (C5), a humidity sensor (C6), an oxygen sensor (C7) and a nitrogen sensor (C8); the air pump (2), the inflator pump (3), the air conditioning device (6.1), the superoxide generator (6.2), the negative ion generator (6.3), the gas catalyst controlled release device (6.4), the humidifier ((6.5)) (6.5), all sensors (C1) - (C8) and all electromagnetic valves (B1) - (B7) are connected to the positive and negative pressure intelligent regulation and control device (5).

2. An intelligent positive and negative pressure refrigerator is characterized by comprising a refrigerator body (7); an intelligent positive-negative pressure system, a refrigerating system (8), a common refrigerating chamber (9), a common freezing chamber (10), an air water making device (11) and a touch screen and mobile phone monitoring system (12) are arranged in the box body (7); the intelligent positive and negative pressure system comprises a positive and negative pressure cabin (1), an air pump (2), an inflator pump (3), a positive and negative pressure intelligent regulation and control device (5) and a positive and negative pressure airflow carried object generation processor; the positive and negative ballast (1) comprises: the device comprises a cabin body (1.1), a cabin door (1.2), an in-cabin outer sealing communicating device (1.4), a pneumatic airtight mechanism (1.5), an electric airtight mechanism (1.6), a pneumatic cabin door switch (1.8) and an electric cabin door switch (1.9); the door (1.2) is the door of the positive and negative pressure refrigerator; the positive and negative pressure cabins (1) are designed into a vacuum high-pressure refrigerating cabin (1-1) and a vacuum high-pressure freezing cabin (1-2) according to the refrigerating and freezing requirements of a refrigerator; a pneumatic airtight mechanism (1.5) is arranged between the cabin door (1.2) and the cabin body (1.1) of the vacuum high-pressure refrigerating cabin (1-1); the pneumatic airtight mechanism (1.5) comprises a pneumatic sealing bolt (1.51) and a sealing bolt telescopic air bag (1.52) integrally manufactured at the rear part of the sealing bolt (1.51); the sealing bolt (1.51) and the sealing bolt telescopic air bag (1.52) of the integrated structure are totally 4 and are all strip-shaped, and are respectively installed in 4 cabin body airtight grooves (1.11) arranged in 4 side frames of a door frame of a cabin body (1.1), the outer layer part of the cross section of the bolt body is made of sealing rubber, and the inner part of the cross section of the bolt body is made of a bending-resistant metal core; the sealing bolt folding telescopic air bag (1.52) is an inflatable folding rubber air bag, namely, an extensible folding rubber air bag, and an inflatable socket (1.53) is arranged at the rear part of the air bag; an inflation plug (1.54) is inserted into the inflation socket (1.53), 4 inflation plugs (1.54) are arranged, the inflation plugs are respectively arranged at the middle points of the 4 side pipelines of the four sides of the square annular air-tight mechanism inflation branch pipeline (A8.1) in a communicated mode, the bottom side pipeline of the square annular air-tight mechanism inflation branch pipeline (A8.1) is vertically connected with the air-tight mechanism inflation pipeline (A8), and the bottom side pipeline is communicated with the air outlet (d) of the inflation pump (3) through an electromagnetic valve (B8), a pipeline (A3) and an electromagnetic valve (B3); an electric airtight mechanism (1.6) is arranged between the cabin door (1.2) and the cabin body (1.1) of the vacuum high-pressure freezing cabin (1-2); the electric airtight mechanism 1.6 comprises an electric sealing bolt 1.61, an electromagnet 1.62 and a tension spring 1.63; the sealing lock bolts (1.61) are all long-strip-shaped and are respectively movably arranged in 4 cabin body airtight grooves (1.11) formed in the periphery of a cabin body door frame and are hung on a tension spring (1.63), and the other end of the tension spring is fixedly hung at the bottom in the cabin body airtight grooves (1.11); the outer layer part of the cross section of the tongue body of the sealing lock tongue (1.61) is a sealing rubber layer, the interior of the tongue body is a bending-resistant and magnetic-attracting metal core, the sealing rubber layer facing one side of the electromagnet (1.62) is open, and the part of the sealing rubber layer is exposed out of the interior of the metal core so as to be attracted by the electromagnet (1.62); the electromagnet (1.62) is also in a long strip shape corresponding to the shape of the sealing bolt (1.61), and is fixedly installed in the bottom of a cabin door airtight groove (1.21) corresponding to the position of a cabin body airtight groove (1.11), the cabin interior external sealing communicator (1.4) is fixedly arranged at the rear part of the positive and negative pressure cabin (1), all pipelines and circuits which enter and exit the cabin interior and exterior are connected to the cabin interior external sealing communicator (1.4) and pass through the cabin interior and exterior sealing communicator to keep the sealing performance of the positive and negative pressure cabin (1), and an air pump (2), an air pump (3), a positive and negative pressure intelligent regulation and control device (5), an air regulation device (6.1), a superoxide decomposer (6.7), an air filter (6.8), a refrigeration system (8), an air water production device (11), a filter water tank (11.1), a touch screen and a mobile phone monitoring system (12) are installed outside the positive and negative pressure cabin (1); an air suction pipeline (A1) is installed at an air inlet (a) of the air suction pump (5), the air suction pipeline (A1) is connected with air suction branch pipelines (A1.1) and (A1.2) respectively, the middle parts of the air suction branch pipelines (A1.1) and (A1.2) are respectively provided with electromagnetic valves (B1.1) and (B1.2), and the other ends of the air suction branch pipelines extend into the vacuum high-pressure refrigeration cabin (1-1) and the vacuum high-pressure refrigeration cabin (1-2) respectively to form air suction return ports (C1) and (C2) thereof; an air outlet (B) of the air pump (2) is provided with an air exhaust pipeline (A2), the middle part of the air exhaust pipeline (A2) is provided with a superoxide decomposer (6.7) and an electromagnetic valve (B2), the other end of the air exhaust pipeline is communicated with an air inlet (h) of an air water making device (11), and the air exhaust pipeline is communicated with the atmosphere through an air outlet (n) of the air water making device (11); an air inflation pipeline (A3) is installed at an air outlet (d) of the air inflation pump (3), an electromagnetic valve (B3) is installed in the middle of the air inflation pipeline (A3), the other end of the air inflation pipeline (A3) is connected with an air inflation branch pipeline (A3.1), (A3.2), (A3.3) and (A3.4) respectively, the middle parts of the air inflation branch pipeline (A3.1), (A3.2), (A3.3) and (A3.4) are all provided with electromagnetic valves (B3.1), (B3.2), (B3.3) and (B3.4), the other end of the air inflation branch pipeline (A3.1) extends into the vacuum high-pressure refrigeration cabin (1-1) and the vacuum high-pressure refrigeration cabin (1-2), and an air inflation air inlet (f1) of the vacuum high-pressure refrigeration cabin; the other end port of (A3.2) forms an air charging inlet (f2) of the vacuum high-pressure freezing chamber (1-2); the other end of the (A3.3) is connected to an air inlet (G) of the ultrahigh pressure thawing compartment (1-3); the other end of the (A3.4) is connected to an air inlet (Q) of the ultrahigh pressure deep cooling cabin (1-4); an air inlet pipeline (A4) is installed at an air inlet (e) of the inflator pump (3), an air filter (6.8) and an electromagnetic valve (B4) are installed in the middle of the air inlet pipeline (A4), and the other end of the air inlet pipeline is communicated with the atmosphere; the electromagnetic valve (B4) is also connected with a circulating pipeline (A5), the circulating pipeline (A5) is connected with circulating branch pipelines (A5.1) and (A5.2), the middles of the circulating branch pipelines (A5.1) and (A5.2) are respectively provided with the electromagnetic valves (B5.1) and (B5.2), and the other ends of the circulating branch pipelines respectively extend into the vacuum high-pressure refrigerating cabin (1-1) and the vacuum high-pressure refrigerating cabin (1-2) to form circulating air return ports (j1) and (j2) thereof; the circulating pipeline (A5) is also connected with an air-to-water inflation pipeline (A9), the air-to-water inflation pipeline (A9) is connected to an electromagnetic valve (B2) and communicated with an air inlet (h) of the air-to-water device (11) through an exhaust pipeline (A2), the air-to-water inflation pipeline (A9) is connected with the circulating pipeline (A5) and communicated with an electromagnetic valve (B3), and then communicated with an air outlet (d) of the inflator pump (3) through an inflation pipeline (A3); a modified atmosphere air inlet pipeline (A6) is installed at an air inlet (t) of the modified atmosphere device (6.1), a solenoid valve (B6) is installed in the middle of the modified atmosphere air inlet pipeline (A6), the other end of the modified atmosphere air inlet pipeline is connected to an air inflation pipeline (A3), then the modified atmosphere air inlet pipeline (A7.1) and the air inflation pipeline (A7.2) are communicated through a solenoid valve (B3), the air outlet (s1) and the air outlet (s2) of the modified atmosphere device (6.1) are respectively provided with a modified atmosphere air outlet pipeline (A7.1) and a modified atmosphere air outlet pipeline (A7.2), the middle of the modified atmosphere air outlet pipeline (A7.1) and the middle of the modified atmosphere air outlet pipeline (A7.2) are respectively provided with a solenoid valve (B7.1) and a solenoid valve (B7.2), and the other end of the modified atmosphere air inlet pipeline; the inflation pipeline (A3) is also connected to an airtight mechanism inflation pipeline (A8), the middle part of the airtight mechanism inflation pipeline (A8) is provided with an electromagnetic valve (B8), and the other end of the airtight mechanism inflation pipeline is vertically connected to a bottom pipeline of a square annular airtight mechanism inflation branch pipeline (A8.1); four side pipelines of the square annular air-tight mechanism inflation branch pipeline (A8.1) are communicated with each other, the middle points of the four side pipelines are provided with inflation plugs (1.54), and the four inflation plugs (1.54) are inserted into and connected to inflation sockets (1.53); an air water making pipeline (A10) is installed at a water outlet (x) of the air water making device (11), and the air water making pipeline (A10) is communicated with a water inlet (y) of the filtering water tank (11.1); condensed water generated in the vacuum high-pressure refrigerating cabin (1-1) flows into a water inlet (Y) of a condensed water collecting box (11.2) arranged at the bottom in the vacuum high-pressure refrigerating cabin, a condensed water pipeline (A11) is arranged at a water outlet (M) of the condensed water collecting box (11.2), a solenoid valve (B11) is arranged in the middle of the condensed water pipeline (A11) after extending out of the vacuum high-pressure refrigerating cabin (1-1), the other end of the condensed water pipeline is communicated with a water inlet (v) of a filtering water tank (11.1), a humidifying water pipeline (A12) is arranged at a water outlet (o) of the filtering water tank (11.1), a solenoid valve (B12) is arranged in the middle of the humidifying water pipeline (A12), and the other end of the humidifying water pipeline (A12) extends into the vacuum; the refrigeration system (8) is provided with a refrigeration circulating pipeline (A13), and the refrigeration circulating pipeline (A13) respectively extends into the vacuum high-pressure refrigeration cabin (1-1), the vacuum high-pressure refrigeration cabin (1-2), the common refrigeration chamber (9) and the common refrigeration chamber (10) and is communicated with an evaporator air cooling combination (8.1) and an evaporator direct cooling combination (8.2) which are respectively arranged in the refrigeration circulating pipeline; the touch screen and mobile phone monitoring system (12) comprises: the mobile phone comprises a box door touch screen (12.1), a mobile phone APP (12.2) and a high-definition anti-fog camera device (12.3), wherein the high-definition anti-fog camera device (12.3) is arranged at a position to be monitored inside and outside a box body (7); positive negative pressure air current carry thing generation treater and sensor are installed in the inside setting of positive negative pressure ballast (1), include: the device is arranged and installed in a vacuum high-pressure refrigerating chamber (1-1) and comprises: the device comprises an ultrasonic generator (6.2), a negative ion generator (6.3), a gas catalyst controlled release device (6.4), a humidifier (6.5), a condensed water collecting box (11.2), a pressure sensor (C1), a negative pressure sensor (C2), an ultrasonic sensor (C3), a negative oxygen ion sensor (C4), a chlorine dioxide sensor (C5), a humidity sensor (C6), an oxygen sensor (C7), a nitrogen sensor (C8) and a temperature sensor (C9); the device is arranged and installed in a vacuum high-pressure freezing chamber (1-2) and comprises: the gas catalyst controlled release device (6.4), a pressure sensor (C1), a negative pressure sensor (C2), a chlorine dioxide sensor (C5), an oxygen sensor (C7), a nitrogen sensor (C8) and a temperature sensor (C9); all airflow ballast thing generation treater, sensor, solenoid valve and equipment arrangement of positive negative pressure cabin (1) inside and outside installation include: an air pump (2), an inflator pump (3), an air conditioning device (6.1), an superoxide generator (6.2), a negative ion generator (6.3), a gas catalyst controlled release device (6.4), a humidifier (6.5), a superoxide decomposer (6.7), a refrigeration system (8), an air water making device (11), a filter water tank (11.1), an ultrahigh pressure unfreezing cabin (1-3), an ultrahigh pressure deep cooling cabin (1-4), a touch screen and mobile phone monitoring system (12), a box door touch screen (12.1), a high-definition anti-fog camera device (12.3), a pressure sensor (C1), a negative pressure sensor (C2), a superoxide sensor (C3), a negative oxygen ion sensor (C4), a chlorine dioxide sensor (C5), a humidity sensor (C6), an oxygen sensor (C7), a nitrogen sensor (C8), a temperature sensing controller (C9), a water level sensing controller (C10) and electromagnetic valves (B1) to B12), are all connected into a positive and negative pressure intelligent regulation and control device (5).

3. An intelligent positive and negative pressure washing machine is characterized by comprising a machine body (7); an intelligent positive and negative pressure system, an elution drying system (15), a touch screen and mobile phone monitoring system (12) are arranged in the machine body (7); the intelligent positive and negative pressure system comprises a positive and negative pressure cabin (1), an air pump (2), an inflator pump (3), a positive and negative pressure intelligent regulation and control device (5) and a positive and negative pressure airflow carried object generation processor; the positive and negative pressure cabin (1) is designed into a vacuum high-pressure roller outer cabin (1-5) according to the requirements of washing and drying clothes; the vacuum high-pressure roller outer chamber (1-5) comprises: the cabin comprises a cabin body (1.1), a cabin door (1.2), a mechanical airtight mechanism (1.3) and an in-cabin outer sealing communicating device (1.4); the cabin door (1.2) is a machine door of the positive and negative pressure washing machine; a mechanical airtight mechanism (1.3) is arranged between the cabin door (1.2) of the vacuum high-pressure roller outer cabin (1-5) and the cabin body (1.1); the mechanical airtight mechanism (1.3) comprises a lock ring (1.31), a lock tongue (1.32), an airtight gasket (1.33) and a door edge sealing gasket (1.34); the lock ring (1.31) is movably matched with the lock tongue (1.32), the lock tongue (1.32) extends into the lock ring (1.31) to lock the cabin door when the cabin door is closed, and the air-tight gasket (1.33) keeps sealing when positive and negative air pressure is formed in the vacuum high-pressure roller outer cabin (1-5); the communication device (1.4) for sealing and communicating the inside and outside of the cabin is fixedly arranged at the rear part of the outer cabin (1-5) of the vacuum high-pressure roller, and all pipelines and circuits for entering and exiting the inside and outside of the cabin are connected to the communication device (1.4) for sealing and communicating the inside and outside of the cabin so as to keep the sealing performance of the outer cabin (1-5) of the vacuum high-pressure roller; a roller mechanism (15.1), a water drenching prevention air extraction opening (2.1), a roller sealing bearing seat (15.3), a pressure sensor (C1) and a negative pressure sensor (C2) are arranged in the vacuum high-pressure roller outer chamber (1-5); an air pump (2), an air pump (3), a positive and negative pressure intelligent regulation and control device (5), an eluting and drying control mechanism (15.2), a large roller belt pulley (15.4), a motor assembly (15.5), a drainage pump (16), a water inlet pump (17), a superoxide generation water mixer (6.6), a superoxide decomposer (6.7), a touch screen and mobile phone APP monitoring system (12) and a detergent pull box (18) are arranged outside the vacuum high-pressure roller outer chamber (1-5); an air suction pipeline (A1) is installed at an air inlet (a) of the air suction pump (2), an electromagnetic valve (B1) is installed in the middle of the air suction pipeline (A1), the other end of the air suction pipeline extends into the vacuum high-pressure roller outer chamber (1-5) and then is connected with a water-drenching prevention air suction opening (2.1) to form an air suction return opening (c), and an air outlet (B) of the air suction pump (2) is communicated with the atmosphere; an air inflation pipeline (A3) is installed at an air outlet (d) of the air inflation pump (3), an electromagnetic valve (B3) is installed in the middle of the air inflation pipeline (A3), and the other end of the air inflation pipeline extends into the vacuum high-pressure roller outer chamber (1-5) and extends to the lower side of the roller mechanism (15.1) to form an air inflation inlet (f); an air inlet (e) of the inflator pump (3) is communicated with the atmosphere; a water inlet pipeline (A14) is installed at a water inlet (r) of the water inlet pump (17), a solenoid valve (B14) is installed in the middle of the water inlet pipeline (A14), the other end of the water inlet pipeline is connected with a tap water source, a washing machine water inlet pipeline (A15) is installed at a water outlet (u) of the water inlet pump (17), a solenoid valve (B15) is installed in the middle of the water inlet pipeline (A15), the other end of the water inlet pipeline is connected with a water inlet (k) of the superoxide generating water mixer (6.6), a washing machine water inlet pipeline (A16) is installed at a water outlet (q) of the superoxide generating water mixer (6.6), a solenoid valve (B16) is installed in the middle of the water inlet pipeline (A16), the other end of the water inlet (z) of the detergent drawer box (18) is connected with the water inlet (I) of the detergent drawer box (18), a washing machine water inlet pipeline (A46, the other end extends into the outer chamber (1-5) of the vacuum high-pressure roller to form a water inlet (T) thereof; the electromagnetic valve (B14) is also provided with a water inlet pipeline (A18) and is connected with an electromagnetic valve (B16) in parallel, and water is directly fed when the pressure of tap water reaches the standard without the need of super-oxygen water; the electromagnetic valve (B15) is also provided with a water inlet pipeline (A19) and is connected to a water inlet pipeline (A18) and then communicated with the electromagnetic valve (B16), and water is directly fed by the water inlet pump (17) when the super-oxygen water is not needed; a water inlet pipeline (A20) is installed at a water inlet (w) of the drainage pump (16), a solenoid valve (B20) is installed in the middle of the drainage pipeline (A20), the other end of the drainage pipeline extends into the vacuum high-pressure roller outer chamber (1-5) to form a drainage outlet (L) of the vacuum high-pressure roller outer chamber, a drainage pipeline (A21) is installed at a water outlet (p) of the drainage pump (16), a solenoid valve (B21) is installed in the middle of the drainage pipeline (A21), the other end of the drainage pipeline is communicated with a water inlet (g) of the superoxide decomposer (6.7), a drainage pipeline (A22) is installed at a water outlet (m) of the superoxide decomposer (6.7), a solenoid valve (B36; the electromagnetic valve (B20) is also provided with a drainage pipeline (A23) and is connected with the electromagnetic valve (B22) in parallel, and water can be drained directly when super oxygen decomposition is not needed and automatic drainage is available; the electromagnetic valve (B21) is also provided with a drainage pipeline (A24) and is connected to a drainage pipeline (A23) to be communicated with the electromagnetic valve (B22), and the water is directly drained by the drainage pump (16) when the super oxygen is not decomposed; the motor assembly (15.5) drives a large belt pulley (15.4), and the large belt pulley (15.4) drives a roller mechanism (15.1) connected with the large belt pulley to operate; air pump (2), pump (3), drain pump (16), intake pump (17), super oxygen generation water mixer (6.6), super oxygen decomposer (6.7), elution are dried by fire control mechanism (15.2), touch screen and cell-phone APP monitored control system (12), pressure sensor (C1), negative pressure sensor (C2) and solenoid valve (B1) to (B22), all insert positive negative pressure intelligent control device (5).

4. An intelligent vacuum dish-washing fruit and vegetable cleaning machine is characterized by comprising a machine body (7); an intelligent positive-negative pressure system, a dish washing and drying system (19), a fruit and vegetable cleaning system (20) and a touch screen and mobile phone APP monitoring system (12) are arranged in the machine body (7); the intelligent positive and negative pressure system comprises a positive and negative pressure cabin (1), an air pump (2), a positive and negative pressure intelligent regulation and control device (5) and a positive and negative pressure airflow carried object generation processor; the positive and negative pressure cabin (1) is designed into a vacuum super-oxygen cabin (1-6) according to the requirements of intelligent dish washing, drying and fruit and vegetable cleaning; the vacuum super-oxygen chamber (1-6) comprises: the cabin comprises a cabin body (1.1), a cabin door (1.2), a mechanical airtight mechanism (1.3) and an in-cabin outer sealing communicating device (1.4); the hatch door (1.2) is a door of the vacuum dish washing, fruit and vegetable cleaning machine; a mechanical airtight mechanism (1.3) is arranged between the cabin door (1.2) and the cabin body (1.1) of the vacuum super-oxygen cabin (1-6); the mechanical airtight mechanism (1.3) comprises a lock ring (1.31), a lock tongue (1.32) and an airtight gasket (1.33); the lock ring (1.31) is movably matched with the lock tongue (1.32), the lock tongue (1.32) extends into the lock ring (1.31) to lock the cabin door when the cabin door is closed, and the air-tight gasket (1.33) keeps sealing when positive and negative air pressure is formed in the vacuum super-oxygen cabin (1-6); the in-cabin and out-cabin pipeline online controller (1.4) is fixedly arranged at the rear part of the vacuum super-oxygen cabin (1-6), all pipelines and circuits inside and outside the in-cabin are connected to the in-cabin and outside sealed communicating device (1.4) and come in and go out through the in-cabin and outside sealed communicating device to keep the sealing performance of the vacuum super-oxygen cabin (1-6), and a dish washing and drying system (19), a fruit and vegetable cleaning system (20), a drenching prevention air suction port (2.1), a negative pressure sensor (C2), a super-oxygen sensor (C3) and a temperature sensor (C9) are arranged in the vacuum super-oxygen cabin (1-6); an air suction pump (2), a positive and negative pressure intelligent regulation and control device (5), a drainage pump (16), a water inlet pump (17), a superoxide generation water mixer (6.6), a superoxide decomposer (6.7), a touch screen and a mobile phone APP monitoring system (12) are arranged outside the vacuum super-oxygen chamber (1-6); an air suction pipeline (A1) is installed at an air inlet (a) of the air suction pump (2), an electromagnetic valve (B1) is installed in the middle of the air suction pipeline (A1), and the other end of the air suction pipeline extends into the vacuum super-oxygen chamber (1-6) and is connected with a water-drenching prevention air suction opening (2.1) to form an air suction return opening (c); an air outlet (b) of the air pump (2) is communicated with the atmosphere; a water inlet pipeline (A14) is arranged at the water inlet (r) of the water inlet pump (17), the middle part of the water inlet pipeline (A14) is provided with an electromagnetic valve (B14), the other end is communicated with a tap water source, a water inlet pipeline (A15) is arranged at the water outlet (u) of the water inlet pump (17), the middle part of the water inlet pipeline (A15) is provided with an electromagnetic valve (B15), the other end of the water inlet pipeline is communicated with a water inlet (k) of the superoxide generation water mixer (6.6), a water inlet pipeline (A16) is arranged at a water outlet (q) of the superoxide generation water mixer (6.6), the middle part of the water inlet pipeline (A16) is provided with an electromagnetic valve (B16), the other end of the water inlet pipeline (A16) extends into the vacuum super-oxygen chamber (1-6) and is connected to an electromagnetic valve (B25), the electromagnetic valve (B25) is respectively connected with a fruit and vegetable cleaning water inlet pipeline (A25) and a dish washing and drying water inlet pipeline (A27), the water inlet pipeline (A25) is connected to a water inlet (E) of the fruit and vegetable cleaning system (20); the water inlet pipeline (A27) is connected to a water inlet (G) of the dish washing and drying system (19); the electromagnetic valve (B15) is also provided with a water inlet pipeline (A19) and is connected to the electromagnetic valve (B16), and water is directly fed by a water inlet pump (17) when the super oxygen water is not needed; a water discharge pipeline (A20) is installed at a water inlet (w) of the water discharge pump (16), an electromagnetic valve (B20) is installed in the middle of the water discharge pipeline (A20), the other end of the water discharge pipeline extends into the vacuum super-oxygen chamber (1-6) and is respectively connected to a fruit and vegetable cleaning water discharge pipeline (A26) and a dish washing and drying water discharge pipeline (A28), and the water discharge pipeline (A26) is connected to a water outlet (F) of the fruit and vegetable cleaning system (20); the drainage pipeline (A28) is connected to a drainage outlet (H) of the dish washing and drying system (21); a drainage pipeline (A21) is installed at a water outlet (p) of the drainage pump (16), an electromagnetic valve (B21) is installed in the middle of the drainage pipeline (A21), the other end of the drainage pipeline is communicated with a water inlet (g) of the superoxide decomposer (6.7), a drainage pipeline (A22) is installed at a water outlet (m) of the superoxide decomposer (6.7), an electromagnetic valve (B22) is installed in the middle of the drainage pipeline (A22), and the other end of the drainage pipeline is communicated with a sewer; the electromagnetic valve (B21) is also provided with a drainage pipeline (A24) and is connected to (A23) and then communicated with the electromagnetic valve (B22), and the water is directly drained by a drainage pump when the super oxygen is not decomposed; air pump (2), drain pump (16), intake pump (17), super oxygen generation water mixer (6.6), super oxygen decomposer (6.7), the drying system that washes the dishes (19), fruit vegetables cleaning system (20), touch screen and cell-phone APP monitored control system (12), negative pressure sensor (C2), super oxygen sensor (C3), temperature sensor (C9) and solenoid valve (B1) to (B25), all insert positive negative pressure intelligent control device (5).

5. An intelligent super-oxygen water-washing range hood is characterized by comprising a body (7); the lower half part of the machine body (7) is a sealed waterproof super-oxygen chamber (1-7), and the upper half part is an equipment smoke tube chamber (21); the sealed waterproof super-oxygen chamber (1-7) comprises: a triangular cabin body (1.1) and a sealed waterproof cabin door (1.2); the sealed waterproof cabin door (1.2) is a machine door of the superoxide water washing range hood, and a sealed waterproof mechanism (1.7) is arranged between the cabin door (1.2) and the cabin body (1.1); the waterproof sealing mechanism (1.7) comprises a lock ring (1.71), a lock tongue (1.72), an airtight gasket (1.73) and a cabin door hinge (1.74); the lock ring (1.71) is movably matched with the lock tongue (1.72), the lock tongue (1.72) extends into the lock ring (1.71) to lock the cabin door (1.2) when the cabin door is closed, and the sealing is kept by the sealing washer (1.73) when the sealed waterproof superoxide cabin (1-7) is sprayed and cleaned; a motor and wind wheel combination (22), an automatic rotating spraying ball (23) and an oil and water collecting and draining tank (24) are arranged in the sealed waterproof super-oxygen chamber (1-7), and a touch screen and a mobile phone APP monitoring system (12) are also arranged on the front side of the sealed waterproof super-oxygen chamber; an intelligent superoxide cleaning system and a fume exhaust control mechanism (26) are arranged in the smoke tube cabin (21) of the device; the intelligent superoxide cleaning system comprises: the device comprises an intelligent superoxide regulating and controlling device (5.1), a water inlet pump (17), a water discharge pump (16), a superoxide generating water mixer (6.6), a superoxide decomposer (6.7), a water heating device (27) and a degreasing agent adder (28); a water inlet pipeline (A14) is installed at a water inlet (r) of the water inlet pump (17) and is connected with a tap water source, a water inlet pipeline (A15) is installed at a water outlet (u) of the water inlet pump (17), a water heating device (27) and an electromagnetic valve (B15) are installed in the middle of the water inlet pipeline (A15), the other end of the water inlet pipeline is divided into 3 paths through the electromagnetic valve (B15), and the water inlet (k) of the superoxide generation water mixer (6.6), the water inlet (z) of the degreasing agent adder (28) and the electromagnetic valve (B16) are respectively connected; a water inlet pipeline (A16) is installed at a water outlet (q) of the superoxide generation water mixer (6.6), an electromagnetic valve (B16) is installed in the middle of the water inlet pipeline (A16), the other end of the water inlet pipeline extends into the sealed waterproof superoxide cabin (1-7) to be connected to a spray pipeline (A30), at least 1 automatic rotating spray ball (23) is installed on the spray pipeline (A30), the axis of the spray ball and the axis of a middle circle of spray holes form an angle of 45 degrees, and the spray ball (23) automatically rotates when water flow is sprayed out; a water inlet pipeline (A17) is installed at a water outlet (l) of the degreaser adder (28), an electromagnetic valve (B17) is installed in the middle of the water inlet pipeline (A17), and the other end of the water inlet pipeline (A15) is communicated with the electromagnetic valve (B16); a water inlet pipeline (A20) is installed at the water inlet (w) of the drainage pump (16), an electromagnetic valve (B20) is installed in the middle of a drainage pipeline (A20), and the other end of the drainage pipeline extends into an oil collecting and drainage groove (24) at the bottom of the vacuum super-oxygen chamber (1-7) to form a drainage outlet (L); a drainage pipeline (A21) is installed at a water outlet (p) of the drainage pump (16), an electromagnetic valve (B21) is installed in the middle of the drainage pipeline (A21), the other end of the drainage pipeline is communicated with a water inlet (g) of the superoxide decomposer (6.7), a drainage pipeline (A22) is installed at a water outlet (m) of the superoxide decomposer (6.7), an electromagnetic valve (B22) is installed in the middle of the drainage pipeline (A22), and the other end of the drainage pipeline is communicated with a sewer; the electromagnetic valve (B21) is also provided with a drainage pipeline (A24) and is connected to an electromagnetic valve (B22), and drainage is directly carried out by a drainage pump (16) when superoxide does not need to be decomposed; the device comprises a water inlet pump (17), a drainage pump (16), a superoxide generation water mixer (6.6), a superoxide decomposer (6.7), a water heating device (27), a degreasing agent adder (28), a cooking fume extraction control mechanism (26), a touch screen, a mobile phone APP monitoring system (12) and electromagnetic valves (B1) to (B22), and the superoxide intelligent regulation and control device (5.1) is connected.

6. The utility model provides an intelligence positive negative pressure oven air fryer microwave oven, its characterized in that, includes organism (7), be equipped with in organism (7): the intelligent barbecue system comprises an intelligent positive and negative pressure system, a barbecue system (30), an air fryer system (31), a microwave system (32) and a touch screen and mobile phone APP monitoring system (12); the intelligent positive and negative pressure system comprises a positive and negative pressure cabin (1), an air pump (2), an air pump (3) and an intelligent positive and negative pressure regulating and controlling device (5); the positive and negative pressure cabins (1) are designed into microwave vacuum high pressure cabins (1-8) according to the requirements of an oven air fryer and a microwave oven; the microwave vacuum hyperbaric chamber (1-8) comprising: the cabin comprises a cabin body (1.1), a cabin door (1.2), a mechanical airtight mechanism (1.3) and an in-cabin outer sealing communicating device (1.4); the hatch door (1.2) is a door of the positive and negative pressure oven air fryer microwave oven; a mechanical airtight mechanism (1.3) is arranged between the cabin door (1.2) and the cabin body (1.1) of the microwave vacuum high-pressure cabin (1-8); the mechanical airtight mechanism (1.3) comprises a lock ring (1.31), a lock tongue (1.32) and an airtight gasket (1.33); the lock ring (1.31) is movably matched with the lock bolt (1.32), the lock bolt (1.32) extends into the lock ring (1.31) to lock the cabin door when the cabin door is closed, and the microwave vacuum high-pressure cabin (1-8) is kept sealed by the airtight gasket (1.33) when positive and negative air pressure is formed; the in-cabin and out-cabin pipeline joint controller (1.4) is fixedly arranged at the rear part of the microwave vacuum high-pressure cabin (1-8), all pipelines and circuits which enter and exit the cabin are connected to the in-cabin and out-cabin outer sealing communicating device (1.4) and enter and exit through the in-cabin and outer sealing communicating device to keep the sealing performance of the microwave vacuum high-pressure cabin (1-8), and a barbecue system (30), an air fryer system (31), a microwave system (32), a pressure sensor (C1) and a negative pressure sensor (C2) are arranged in the microwave vacuum high-pressure cabin (1-8); an air pump (2), an air pump (3), a positive and negative pressure intelligent regulation and control device (5), a touch screen and a mobile phone APP monitoring system (12) are arranged outside the microwave vacuum high-pressure cabin (1-8); an air suction pipeline (A1) is installed at an air inlet (a) of the air suction pump (2), an electromagnetic valve (B1) is installed in the middle of the air suction pipeline (A1), the other end of the air suction pipeline extends into the microwave vacuum high-pressure cabin (1-8) to form an air suction return port (c), and an air outlet pipeline (A2) is installed at an air outlet (B) of the air suction pump (2) and is communicated with the atmosphere; an air inflation pipeline (A3) is installed at an air outlet (d) of the air inflation pump (3), an electromagnetic valve (B3) is installed in the middle of the air inflation pipeline (A3), and the other end of the air inflation pipeline extends into the microwave vacuum high-pressure cabin (1-8) to form an air inflation inlet (f); an air inlet pipeline (A4) is arranged at an air inlet (e) of the inflator pump (3) and is communicated with the atmosphere; air pump (2), pump (3), pressure sensor (C1), negative pressure sensor (C2), barbecue system (30), air fryer system (31), microwave system (32) and touch screen and cell-phone APP monitored control system (12), all insert positive negative pressure intelligent control device (5).

7. An intelligent positive and negative pressure fresh-keeping carriage is characterized by comprising a carriage body (7); an intelligent positive and negative pressure system, a refrigerating system (8), a touch screen and a mobile phone monitoring system (12) are arranged in the carriage body (7); the intelligent positive and negative pressure system comprises a positive and negative pressure cabin (1), an air pump (2), an inflator pump (3), a positive and negative pressure intelligent regulation and control device (5) and a positive and negative pressure airflow carried object generation processor; the positive and negative pressure cabin (1) is designed into a van-type vacuum high-pressure cabin (1-9) according to the requirements of an intelligent positive and negative pressure fresh-keeping carriage; the chamber vacuum hyperbaric chamber (1-9) comprises: the cabin comprises a cabin body (1.1), a cabin door (1.2), a mechanical airtight mechanism (1.3) and an in-cabin outer sealing communicating device (1.4); the cabin door (1.2) is a carriage door of the positive and negative pressure fresh-keeping carriage; a mechanical airtight mechanism (1.3) is arranged between the cabin door (1.2) and the cabin body (1.1) of the van-type vacuum high-pressure cabin (1-9); the mechanical airtight mechanism (1.3) comprises a lock ring (1.31), a lock tongue (1.32) and an airtight gasket (1.33); the lock ring (1.31) is movably matched with the bolt (1.32), the bolt (1.32) extends into the lock ring (1.31) to lock the cabin door when the cabin door is closed, and the air-tight gasket (1.33) keeps sealing when positive and negative air pressure is formed in the chamber type vacuum high-pressure cabin (1-9); the in-cabin and out-cabin pipeline online control device (1.4) is fixedly arranged at the rear part of a chamber type vacuum hyperbaric chamber (1-9), all pipelines and circuits which enter and exit the chamber are connected to the in-cabin and out-cabin outer sealing communicating device (1.4) and enter and exit through the in-cabin and outer sealing communicating device to keep the sealing performance of the chamber type vacuum hyperbaric chamber (1-9), and an air suction pump (2), an air charging pump (3), a positive and negative pressure intelligent control device (5), an air conditioning device (6.1), an superoxide decomposer (6.7), an air filter (6.8), a refrigeration system (8), an air water production device (11), a filter water tank (11.1) and a touch screen and mobile phone monitoring system (12) are arranged outside the chamber type vacuum hyperbaric chamber (1-9); an air suction pipeline (A1) is installed at an air inlet (a) of the air suction pump (2), an electromagnetic valve (B1) is installed in the middle of the air suction pipeline (A1), and the other end of the air suction pipeline extends into the van-type vacuum high-pressure cabin (1-9) to form an air suction return port (c) of the van-type vacuum high-pressure cabin; an air outlet (B) of the air pump (2) is provided with an air exhaust pipeline (A2), the middle part of the air exhaust pipeline (A2) is provided with a superoxide decomposer (6.7) and an electromagnetic valve (B2), the other end of the air exhaust pipeline is communicated with an air inlet (h) of an air water making device (11), and the air exhaust pipeline is communicated with the atmosphere from an air outlet (n) of the air water making device (11); an air inflation pipeline (A3) is installed at the air outlet (d) of the air inflation pump (3), an electromagnetic valve (B3) is installed in the middle of the air inflation pipeline (A3), and the other end of the air inflation pipeline extends into the van-type vacuum high-pressure cabin (1-9) to form an air inflation inlet (f) of the van-type vacuum high-pressure cabin; an air inlet pipeline (A4) is installed at an air inlet (e) of the inflator pump (3), an electromagnetic valve (B4) and an air filter (6.8) are installed in the middle of the air inlet pipeline (A4), and the other end of the air inlet pipeline is communicated with the atmosphere; the electromagnetic valve (B4) is also connected with a circulating pipeline (A5), the middle part of the circulating pipeline (A5) is provided with the electromagnetic valve (B5), the other end of the circulating pipeline is communicated with the electromagnetic valve (B3), and the circulating pipeline (A3) extends into the van-type vacuum high-pressure cabin (1-9) to form a circulating return air port (j) of the cabin-type vacuum high-pressure cabin; the aeration pipeline (A3) is also connected with an air-to-water aeration pipeline (A9), and the air-to-water aeration pipeline (A9) is connected with an electromagnetic valve (B2) and is communicated with an air inlet (h) of the air-to-water device (11) through an exhaust pipeline (A2); an air-conditioned air inlet pipeline (A6) is installed at an air inlet (t) of the air-conditioned device (6.1), an electromagnetic valve (B6) is installed in the middle of the air-conditioned air inlet pipeline (A6), the other end of the air-conditioned air inlet pipeline is connected to an air charging pipeline (A3), then the air outlet (d) of an air charging pump (3) is communicated, an air-conditioned air outlet pipeline (A7) is installed at an air outlet(s) of the air-conditioned device (6.1), an electromagnetic valve (B7) is installed in the middle of the air-conditioned air outlet pipeline (A7), and the other end of the air-conditioned air outlet pipeline extends into the chamber; an air water making pipeline (A10) is installed at a water outlet (x) of the air water making device (11), and the air water making pipeline (A10) is communicated with a water inlet (y) of the filtering water tank (11-1); condensed water generated in the chamber type vacuum high-pressure cabin (1-9) flows into a water inlet (Y) of a condensed water collecting box (11.2) arranged at the bottom of the chamber, a condensed water pipeline (A11) is arranged at a water outlet (M) of the condensed water collecting box (11.2), the condensed water pipeline (A11) extends out of the chamber type vacuum high-pressure cabin (1-9) and is provided with an electromagnetic valve (B11) at the back, the other end of the condensed water pipeline is communicated with a water inlet (v) of a filter water tank (11.1), a humidifying water pipeline (A12) is arranged at a water outlet (o) of the filter water tank (11.1), the electromagnetic valve (B12) is arranged at the middle of the humidifying water pipeline (A12), and the other end of the condensed water pipeline extends into the chamber type vacuum high-pressure cabin (1-9) and is; the refrigerating system (8) is provided with a refrigerating circulation pipeline (A13), and the refrigerating circulation pipeline (A13) extends into the van-type vacuum high-pressure cabin (1-9) and is communicated with the evaporator air-cooling combination (8.1); the touch screen and mobile phone monitoring system (12) comprises: the system comprises a touch screen (12.1), a mobile phone APP (12.2) and a wireless anti-fog camera device (12.4), wherein the wireless anti-fog camera device (12.4) is arranged at a position to be monitored inside and outside a carriage body (7); the inside setting of van-type vacuum hyperbaric chamber (1-9) is installed positive negative pressure air current and is taken thing and take place treater and sensor, includes: the device comprises a humidifier (6.5), an ultrasonic generator (6.2), a negative ion generator (6.3), a gas catalyst controlled release device (6.4), a condensed water collecting box (11.2), a pressure sensor (C1), a negative pressure sensor (C2), a superoxide sensor (C3), a negative oxygen ion sensor (C4), a chlorine dioxide sensor (C5), a humidity sensor (C6), an oxygen sensor (C7), a nitrogen sensor (C8) and a temperature sensor (C9); all airflow carrying object generation processors, sensors, electromagnetic valves and equipment devices which are arranged inside and outside the van-type vacuum high-pressure cabins (1-9) comprise: the air extraction pump (2), the inflator pump (3), the air conditioning device (6.1), the superoxide generator (6.2), the negative ion generator (6.3), the gas catalyst controlled release device (6.4), the humidifier (6.5), the superoxide decomposer (6.7), the refrigeration system (8), the air water making device (11), the filter water tank (11.1), the touch screen and mobile phone monitoring system (12), the touch screen (12-1), the wireless anti-fog camera device (12-4), the pressure sensor (C1), the negative pressure sensor (C2), the superoxide sensor (C3), the negative oxygen ion sensor (C4), the chlorine dioxide sensor (C5), the humidity sensor (C6), the oxygen sensor (C7), the nitrogen sensor (C8), the temperature sensor (C9), the water level sensor (C10) and the electromagnetic valves (B1) to B12) are all connected with the positive and negative pressure intelligent regulation device (5).

8. An intelligent positive and negative pressure fresh-keeping warehouse is characterized by comprising a warehouse body (7); an intelligent positive and negative pressure system, a refrigerating system (8), a touch screen and a mobile phone monitoring system (12) are arranged in the storehouse body (7); the intelligent positive and negative pressure system comprises a positive and negative pressure cabin (1), an air pump (2), an inflator pump (3), a positive and negative pressure intelligent regulation and control device (5) and a positive and negative pressure airflow carried object generation processor; the positive and negative pressure cabin (1) is designed into a storage type vacuum high-pressure cabin (1-10) according to the requirements of an intelligent positive and negative pressure fresh-keeping warehouse; the storage type vacuum high-pressure cabin (1-10) comprises: the cabin comprises a cabin body (1.1), a cabin door (1.2), a mechanical airtight mechanism (1.3) and an in-cabin outer sealing communicating device (1.4); the hatch door (1.2) is a warehouse door of the positive and negative pressure fresh-keeping warehouse; a mechanical airtight mechanism (1.3) is arranged between the cabin door (1.2) and the cabin body (1.1) of the storage type vacuum high-pressure cabin (1-10); the mechanical airtight mechanism (1.3) comprises a lock ring (1.31), a lock tongue (1.32) and an airtight gasket (1.33); the lock ring (1.31) is movably matched with the lock bolt (1.32), the lock bolt (1.32) extends into the lock ring (1.31) to lock the cabin door when the cabin door is closed, and the cabin door is kept sealed by the airtight gasket (1.33) when positive and negative air pressure is formed in the storage type vacuum high-pressure cabin (1-10); the in-cabin and out-cabin pipeline integrated controller (1.4) is fixedly arranged at the rear part of the storage type vacuum high-pressure cabin (1-10), all pipelines and circuits which enter and exit the cabin are connected to the in-cabin and out-cabin outer sealing communicator (1.4) and enter and exit through the in-cabin and outer sealing communicator to keep the sealing performance of the storage type vacuum high-pressure cabin (1-10), and an air suction pump (2), an air pump (3), a positive and negative pressure intelligent regulation and control device (5), an air conditioning device (6.1), an superoxide decomposer (6.7), an air filter (6.8), a refrigeration system (8), an air water preparation device (11), a filter water tank (11.1) and a touch screen and mobile phone monitoring system (12) are arranged outside the storage type vacuum high-pressure cabin (1-10); an air suction pipeline (A1) is installed at the air inlet (a) of the air suction pump (2), an electromagnetic valve (B1) is installed in the middle of the air suction pipeline (A1), and the other end of the air suction pipeline extends into the storage type vacuum high-pressure cabin (1-10) to form an air suction return port (c); an air outlet (B) of the air pump (2) is provided with an air exhaust pipeline (A2), the middle part of the air exhaust pipeline (A2) is provided with a superoxide decomposer (6.7) and an electromagnetic valve (B2), the other end of the air exhaust pipeline is communicated with an air inlet (h) of an air water making device (11), and the air exhaust pipeline is communicated with the atmosphere from an air outlet (n) of the air water making device (11); an air inflation pipeline (A3) is arranged at an air outlet (d) of the air inflation pump (3), an electromagnetic valve (B3) is arranged in the middle of the air inflation pipeline (A3), and the other end of the air inflation pipeline extends into the storage type vacuum high-pressure cabin (1-10) to form an air inflation inlet (f) of the air inflation pipeline; an air inlet pipeline (A4) is installed at an air inlet (e) of the inflator pump (3), an electromagnetic valve (B4) and an air filter (6.8) are installed in the middle of the air inlet pipeline (A4), and the other end of the air inlet pipeline is communicated with the atmosphere; the electromagnetic valve (B4) is also connected with a circulating pipeline (A5), the middle part of the circulating pipeline (A5) is provided with the electromagnetic valve (B5), the other end of the circulating pipeline is communicated with the electromagnetic valve (B3), and the circulating pipeline (A3) extends into the storage type vacuum high-pressure cabin (1-10) to form a circulating return air port (j) of the storage type vacuum high-pressure cabin; the aeration pipeline (A3) is also connected with an air-to-water aeration pipeline (A9), and the air-to-water aeration pipeline (A9) is connected with an electromagnetic valve (B2) and is communicated with an air inlet (h) of the air-to-water device (11) through an exhaust pipeline (A2); an air-conditioned air inlet pipeline (A6) is installed at an air inlet (t) of the air-conditioned device (6.1), an electromagnetic valve (B6) is installed in the middle of the air-conditioned air inlet pipeline (A6), the other end of the air-conditioned air inlet pipeline is connected to an air charging pipeline (A3), then the air outlet (d) of an air charging pump (3) is communicated, an air-conditioned air outlet pipeline (A7) is installed at an air outlet(s) of the air-conditioned device (6.1), an electromagnetic valve (B7) is installed in the middle of the air-conditioned air outlet pipeline (A7), and the other end of the air-conditioned air outlet pipeline extends into a storage type; an air water making pipeline (A10) is installed at a water outlet (x) of the air water making device (11), and the air water making pipeline (A10) is communicated with a water inlet (y) of the filtering water tank (11-1); condensed water generated in the bin type vacuum high-pressure cabin (1-10) flows into a water inlet (Y) of a condensed water collecting box (11.2) arranged at the bottom of the bin type vacuum high-pressure cabin, a condensed water pipeline (A11) is arranged at a water outlet (M) of the condensed water collecting box (11.2), the condensed water pipeline (A11) extends out of the bin type vacuum high-pressure cabin (1-10) and is provided with an electromagnetic valve (B11) at the back, the other end of the condensed water pipeline is communicated with a water inlet (v) of a filter water tank (11.1), a humidifying water pipeline (A12) is arranged at a water outlet (o) of the filter water tank (11.1), the electromagnetic valve (B12) is arranged at the middle of the humidifying water pipeline (A12), the other end of the condensed water pipeline extends into the bin type vacuum high-pressure cabin (1-10); the refrigerating system (8) is provided with a refrigerating circulation pipeline (A13), and the refrigerating circulation pipeline (A13) extends into the storage type vacuum high-pressure cabin (1-10) and is communicated with the evaporator air-cooling combination (8.1); the touch screen and mobile phone monitoring system (12) comprises: the mobile phone comprises a touch screen (12.1), a mobile phone APP (12.2) and an anti-fog camera device (12.3), wherein the anti-fog camera device (12.3) is arranged at a position to be monitored inside and outside a warehouse body (7); the inside setting of warehouse style vacuum hyperbaric chamber (1-10) is installed positive negative pressure air current and is taken thing and take place treater and sensor, includes: the device comprises a humidifier (6.5), an ultrasonic generator (6.2), a negative ion generator (6.3), a gas catalyst controlled release device (6.4), a condensed water collecting box (11.2), a pressure sensor (C1), a negative pressure sensor (C2), a superoxide sensor (C3), a negative oxygen ion sensor (C4), a chlorine dioxide sensor (C5), a humidity sensor (C6), an oxygen sensor (C7), a nitrogen sensor (C8) and a temperature sensor (C9); all airflow ballast generating processors, sensors, solenoid valves and equipment installed inside and outside the warehouse-type vacuum hyperbaric chambers (1-10) include: the air extraction pump (2), the inflator pump (3), the air conditioning device (6.1), the superoxide generator (6.2), the negative ion generator (6.3), the gas catalyst controlled release device (6.4), the humidifier (6.5), the superoxide decomposer (6.7), the refrigeration system (8), the air water making device (11), the filter water tank (11.1), the touch screen and mobile phone monitoring system (12), the touch screen (12.1), the high-definition anti-fog camera device (12.3), the pressure sensor (C1), the negative pressure sensor (C2), the superoxide sensor (C3), the negative oxygen ion sensor (C4), the chlorine dioxide sensor (C5), the humidity sensor (C6), the oxygen sensor (C7), the nitrogen sensor (C8), the temperature sensor (C9), the water level sensor (C10) and the electromagnetic valves (B1) to B12) are all connected with the positive and negative pressure intelligent regulation device (5).

9. An intelligent positive-negative pressure module cabinet is characterized by comprising a cabinet body (7); an intelligent positive-negative pressure system, a refrigerating and heating system (8.3), a touch screen and a mobile phone monitoring system (12) are arranged in the cabinet body (7); the intelligent positive and negative pressure system comprises a positive and negative pressure cabin (1), an air pump (2), an inflator pump (3), a positive and negative pressure intelligent regulation and control device (5) and a positive and negative pressure airflow carried object generation processor; the positive and negative pressure cabin (1) is designed into a modular vacuum high-pressure cabin (1-11) according to the requirements of the intelligent positive and negative pressure module cabinet; the modular vacuum hyperbaric chamber (1-11) comprises: the device comprises a cabin body (1.1), a cabin door (1.2), a pneumatic airtight mechanism (1.5), an in-cabin outer sealing communicating device (1.4) and a pneumatic cabin door switch (1.8); the cabin door (1.2) is a cabinet door of the positive and negative pressure module cabinet; a pneumatic airtight mechanism (1.5) is arranged between the cabin door (1.2) and the cabin body (1.1) of the modular vacuum high-pressure cabin (1-11); the pneumatic airtight mechanism (1.5) comprises a pneumatic sealing bolt (1.51) and a sealing bolt telescopic air bag (1.52) integrally manufactured at the rear part of the sealing bolt (1.51); the sealing bolt (1.51) and the sealing bolt telescopic air bag (1.52) of the integrated mechanism are totally provided with 4 strips, the strips are respectively installed in 4 cabin body airtight grooves (1.11) arranged in 4 side frames of a door frame of a cabin body (1.1), the outer layer part of the cross section of the bolt body is made of sealing rubber, and the inner part of the cross section of the bolt body is provided with a bending-resistant metal core; the sealing bolt folding telescopic air bag (1.52) is an inflatable folding rubber air bag, namely, an extensible folding rubber air bag, and an inflatable socket (1.53) is arranged at the rear part of the air bag; an inflation plug (1.54) is inserted into the inflation socket (1.53), 4 inflation plugs (1.54) are arranged, the inflation plugs are respectively installed and communicated at the middle points of the 4 side pipelines of the four sides of the square annular air-tight mechanism inflation branch pipeline (A8.1), the top side pipeline of the pneumatic square annular inflation pipeline (A8.1) is vertically connected with the inflation pipeline (A8) and is communicated with the air outlet (d) of the inflation pump (3) through the electromagnetic valve (B5), the pipeline (A3) and the electromagnetic valve (B3), when the cabin door is closed, the cabin door (1.2) touches the pneumatic cabin door switch (1.8), the inflation pump (3) is started immediately to inflate the sealing bolt folding telescopic airbag (1.52) to extend, and pushes the sealing bolt (1.51) to extend outwards from the air-tight groove (1.11) of the cabin body and extend into the air-tight groove (1.21) arranged at the corresponding position of the opposite side of the cabin door to lock and seal the cabin door, when a user opens the cabin door, the pneumatic cabin door switch (1.8) is used for deflating the sealing bolt folding telescopic air bag (1.52) so as to retract the sealing bolt (1.51) to open the cabin door; the communication device (1.4) is fixedly arranged at the rear part of the modular vacuum high-pressure cabin (1-11), all pipelines and circuits which enter and exit the cabin are connected to the communication device (1.4) and enter and exit through the communication device to keep the sealing performance of the modular vacuum high-pressure cabin (1-11), and an air pump (2), an air pump (3), a positive and negative pressure intelligent control device (5), an air conditioning device (6.1), an superoxide decomposer (6.7), an air filter (6.8), a refrigerating and heating system (8.3), an air water making device (11), a filter water tank (11.1), a pneumatic cabin door switch (1.8), a touch screen and a mobile phone monitoring system (12) are arranged outside the modular vacuum high-pressure cabin (1-11); an air suction pipeline (A1) is installed at the air inlet (a) of the air suction pump (2), an electromagnetic valve (B1) is installed in the middle of the air suction pipeline (A1), and the other end of the air suction pipeline extends into the modular vacuum high-pressure cabin (1-11) to form an air suction return port (c) of the modular vacuum high-pressure cabin; an air outlet (B) of the air pump (2) is provided with an air exhaust pipeline (A2), the middle part of the air exhaust pipeline (A2) is provided with a superoxide decomposer (6.7) and an electromagnetic valve (B2), the other end of the air exhaust pipeline is communicated with an air inlet (h) of an air water making device (11), and the air exhaust pipeline is communicated with the atmosphere from an air outlet (n) of the air water making device (11); an air inflation pipeline (A3) is installed at the air outlet (d) of the air inflation pump (3), an electromagnetic valve (B3) is installed in the middle of the air inflation pipeline (A3), and the other end of the air inflation pipeline extends into the modular vacuum high-pressure cabin (1-11) to form an air inflation inlet (f) of the modular vacuum high-pressure cabin; an air inlet pipeline (A4) is installed at an air inlet (e) of the inflator pump (3), an electromagnetic valve (B4) and an air filter (6.8) are installed in the middle of the air inlet pipeline (A4), and the other end of the air inlet pipeline is communicated with the atmosphere; the electromagnetic valve (B4) is also connected with a circulating pipeline (A5), the middle part of the circulating pipeline (A5) is provided with the electromagnetic valve (B5), the other end of the circulating pipeline is communicated with the electromagnetic valve (B3), and the circulating pipeline (A3) extends into the modular vacuum high-pressure cabin (1-11) to form a circulating return air port (j) of the modular vacuum high-pressure cabin; the electromagnetic valve (B5) is also connected with an airtight mechanism inflation pipeline (A8), the airtight mechanism inflation pipeline (A8) is communicated with an air outlet (d) of the inflator pump (3) through the electromagnetic valve (B5) and an inflation pipeline (A3), the other end of the inflation pipeline (A8) is connected to a top side pipeline of a square annular inflation pipeline (A8.1), four side pipelines of the square annular inflation pipeline (A8.1) are communicated with each other, the middle point of the square annular inflation pipeline is connected with inflation plugs (1.54), and the inflation plugs (1.54) are inserted into and connected to corresponding inflation sockets (1.53); the inflation pipeline (A3) is also connected with an air-to-water inflation pipeline (A9), and the air-to-water inflation pipeline (A9) is connected to an electromagnetic valve (B2) and is communicated with an air inlet (h) of the air-to-water device (11) through an exhaust pipeline (A2); an air-conditioned air inlet pipeline (A6) is installed at an air inlet (t) of the air-conditioned device (6.1), an electromagnetic valve (B6) is installed in the middle of the air-conditioned air inlet pipeline (A6), the other end of the air-conditioned air inlet pipeline is connected to an air charging pipeline (A3), and then the air outlet (d) of an air charging pump (3) is communicated, an air-conditioned air outlet pipeline (A7) is installed at an air outlet(s) of the air-conditioned device (6.1), an electromagnetic valve (B7) is installed in the middle of the air-conditioned air outlet pipeline (A7), and the other end of the air-conditioned air outlet pipeline extends into; an air water making pipeline (A10) is installed at a water outlet (x) of the air water making device (11), and the air water making pipeline (A10) is communicated with a water inlet (y) of the filtering water tank (11-1); condensed water generated in the modular vacuum high-pressure cabin (1-11) flows into a water inlet (Y) of a condensed water collecting box (11.2) arranged at the bottom of the cabin, a dehumidification condensed water pipeline (A31) is arranged at the other water inlet (N) of the condensed water collecting box (11.2), and the other end of the dehumidification condensed water pipeline (A31) is connected at a condensed water outlet (H) of the dehumidification device; a condensed water pipeline (A11) is installed at a water outlet (M) of the condensed water collecting box (11.2), the condensed water pipeline (A11) extends out of the modular vacuum hyperbaric chamber (1-11) and is provided with an electromagnetic valve (B11) at the back, the other end of the condensed water pipeline is communicated with a water inlet (v) of the filter water tank (11-1), a humidifying water pipeline (A12) is installed at a water outlet (o) of the filter water tank (11.1), an electromagnetic valve (B12) is installed at the middle of the humidifying water pipeline (A12), and the other end of the condensed water pipeline extends into the modular vacuum hyperbaric chamber (1-11) and is communicated with a water inlet (R) of the humidifier; the refrigerating and heating system (8.3) is provided with a circulating pipeline (A13), and the circulating pipeline (A13) extends into the modular vacuum high-pressure cabin (1-11) and is communicated with a heat exchanger (8.4); the touch screen and mobile phone monitoring system (12) comprises: the mobile phone comprises a cabinet door touch screen (12.1), a mobile phone APP (12.2) and a high-definition anti-fog camera device (12.3), wherein the high-definition anti-fog camera device (12.3) is arranged at a position which needs to be monitored inside and outside a cabinet body 7; the inside setting of modular vacuum hyperbaric chamber (1-11) is installed positive negative pressure air current and is taken up thing and take place treater and sensor, includes: the air purifier comprises a humidifier (6.5), an air disinfection and sterilization device (6.9), an air filtering and refreshing device (6.10), a dehumidifying device (6.11), a condensed water collecting box (11.2), a pressure sensor (C1), a negative pressure sensor (C2), a superoxide sensor (C3), a negative oxygen ion sensor (C4), a chlorine dioxide sensor (C5), a humidity sensor (C6), an oxygen sensor (C7), a nitrogen sensor (C8), a temperature sensing controller (C9), a water level sensing controller (C10) and an air particulate matter sensor (C11); all airflow ballast generating processors, sensors, solenoid valves and equipment devices installed inside and outside the modular vacuum hyperbaric chamber (1-11) include: an air pump (2), an inflator pump (3), an air conditioning device (6.1), a humidifier (6.5), a superoxide decomposer (6.7), an air sterilizing device (6.9), an air filtering and refreshing device (6.10), a dehumidifying device (6.11), a refrigerating and heating system (8.3), a heat exchanger (8.4), an air water making device (11), a filtering water tank (11.1), a touch screen and a mobile phone monitoring system (12), the cabinet door comprises a cabinet door touch screen (12.1), a high-definition anti-fog camera device (12.3), a pressure sensor (C1), a negative pressure sensor (C2), a superoxide sensor (C3), a negative oxygen ion sensor (C4), a chlorine dioxide sensor (C5), a humidity sensor (C6), an oxygen sensor (C7), a nitrogen sensor (C8), a temperature sensing controller (C9), a water level sensing controller (C10), an air particulate matter sensor (C11) and electromagnetic valves (B1) to (B12) which are all connected to a positive and negative pressure intelligent regulation device (5).