CN117053463A

CN117053463A - Onion cold-stored fresh-keeping device

Info

Publication number: CN117053463A
Application number: CN202310935580.2A
Authority: CN
Inventors: 张永滔; 陈志军
Original assignee: Jiangsu Shengze Agricultural Development Co ltd
Current assignee: Jiangsu Shengze Agricultural Development Co ltd
Priority date: 2023-07-26
Filing date: 2023-07-26
Publication date: 2023-11-14

Abstract

The invention relates to the technical field of onion refrigeration, in particular to an onion refrigeration fresh-keeping device; the device comprises a machine body, a refrigerating system and a humidifying system at one side of the machine body, wherein the refrigerating system is used for controlling the temperature in the machine body, and the humidifying system is used for controlling the humidity in the machine body; according to the invention, through the mutual matching between the rotating cabin and the blade plate, on one hand, the blade plate can drive the moisture in the machine body to flow from bottom to top, so that the moisture in the height region of the machine body can be uniformly mixed, the humidity above and below the machine body is ensured to be in a relatively stable state, and on the other hand, the rotating cabin can stir the moisture flowing in the machine body, so that the uniformity of the humidity in the machine body is further improved, and condensed water which drops or is condensed on the inner wall of the machine body can be absorbed through the absorption module, the interference of the condensed water on the local humidity in the machine body is reduced, the stability of the humidity in the machine body is improved, and the refrigerating and fresh-keeping effects of onions in the machine body are further improved.

Description

Onion cold-stored fresh-keeping device

Technical Field

The invention relates to the technical field of onion refrigeration, in particular to an onion refrigeration fresh-keeping device.

Background

The onion storage methods are more, and the most common methods include stacking, hanging, refrigerating, modified atmosphere storage, radiation storage and the like; the onion is preserved and stored in a refrigerating way by using a preserving warehouse; because the low-temperature environment of the fresh-keeping warehouse can effectively control the respiration and water loss inside the onion; the onion can slow down the respiration process and the evaporation rate at low temperature, thereby slowing down the metabolism and the water loss of the onion and prolonging the fresh-keeping period;

generally, the preservation temperature of the onion preservation warehouse is about 0 ℃ to 3 ℃; if the temperature is lower than 0 ℃, the water in the onion can be frozen, so that the local tissue of the onion is damaged, and the onion is frostbitten; this temperature range of about 0 ℃ to 3 ℃ helps to inhibit bacterial growth and chemical reactions, reducing the potential for onion spoilage; meanwhile, the activity of enzymes in the onion can be slowed down, and the decomposition and quality loss of nutrient substances are reduced; when the onions are refrigerated, the humidity in the fresh-keeping warehouse is required to be ensured to be 60-70%, if the humidity in the fresh-keeping warehouse is lower than 60%, the onions are easy to dehydrate and germinate, and the humidity higher than 70% can accelerate the decay and mildew of the onions;

when the existing fresh-keeping warehouse is used, the humidity distribution in the fresh-keeping warehouse is not uniform; because the temperature in the fresh-keeping warehouse is low, condensed water can be formed when the wet air in the fresh-keeping warehouse contacts the cold surface of the fresh-keeping warehouse; the condensed water can increase the local humidity of the cold surface, so that the humidity near the cold surface in the fresh-keeping warehouse is relatively high, and the humidity is lower in the area far away from the cold surface; the moisture in the fresh-keeping warehouse can be directly converged in the air and condensed into water drops, and the water drops sink under the action of self gravity, so that the humidity above the fresh-keeping warehouse is reduced, and the humidity below the fresh-keeping warehouse is increased; thereby influencing the storage of the onions in the fresh-keeping warehouse and reducing the refrigerating and fresh-keeping effects of the onions;

in view of the above, the present invention provides an onion refrigeration and fresh-keeping device, which solves the above technical problems.

Disclosure of Invention

In order to make up the defects of the prior art, the invention provides the onion cold-storage fresh-keeping device, on one hand, the blades can drive the moisture in the machine body to flow from bottom to top through the mutual matching between the rotating cabin and the blades, so that the moisture in the height region of the machine body can be uniformly mixed, the humidity above and below the machine body is ensured to be in a relatively stable state, on the other hand, the rotating cabin can stir the moisture in the machine body, the uniformity of the humidity in the machine body is further improved, the condensed water which is dripped or condensed on the inner wall of the machine body can be absorbed through the absorption module, the interference of the condensed water on the local humidity in the machine body is reduced, the humidity stability in the machine body is improved, and the cold-storage fresh-keeping effect of the onion in the machine body is further improved.

The technical scheme adopted for solving the technical problems is as follows: the invention relates to an onion refrigerating and fresh-keeping device, which comprises:

the refrigerating system is used for controlling the temperature in the machine body, and the humidifying system is used for controlling the humidity in the machine body;

further comprises:

the heat preservation door is rotatably arranged at one end of the machine body; a driving motor is arranged at one end of the machine body, which is far away from the heat preservation door; the machine body is rotatably connected with a mounting rod; the mounting rod is fixedly connected with an output shaft of the driving motor; a rotating cabin is arranged in the machine body; the rotating cabin is fixedly connected to the mounting rod; the rotating cabin is in sliding contact with the inner wall of the machine body; an absorption module is arranged between the rotary cabin and the machine body and used for absorbing condensed water on the inner wall of the machine body;

the wind power circulation module is arranged in the machine body; the wind power circulation module is used for driving airflow in the machine body to flow.

Preferably, the wind circulation module comprises a blade; the lower end of the machine body is provided with a cavity communicated with the machine body; the blade plate is rotationally connected in the cavity; the lower end of the blade plate is provided with a turbine and a worm; the turbine is fixedly connected with the blade plate; one end of the worm is in transmission connection with the output end of the driving motor through the acceleration module, and the other end of the worm is meshed with the turbine; the upper end of the machine body is provided with an air passage communicated with the cavity.

Preferably, the acceleration module comprises a driving gear and an acceleration gear which are meshed with each other; the driving gear is fixedly connected with an output shaft of the driving motor, and the accelerating gear is fixedly connected with the worm; the rotating cabin is fan-shaped; and a supporting plate is connected in the rotating cabin in a sliding way.

Preferably, the absorption module comprises a foam cushion, and the foam cushion is arranged on one surface of the rotating cabin, which is close to the inner wall of the machine body; a groove is formed in the rotating cabin; a metal ball is arranged in the groove; the metal balls are connected with the foam-rubber cushion through steel wire ropes; an extrusion unit is arranged in the groove; the squeezing unit is used for squeezing and atomizing the condensed water absorbed by the sponge.

Preferably, the pressing unit includes:

the baffle is fixedly connected to the inner wall of the groove; the partition board is used for separating the foam cushion and the metal balls; the steel wire rope is in sliding sealing connection with the partition plate; a sealing plate is arranged above the metal ball; the sealing plate is fixedly connected with the steel wire rope; the sealing plate is in sliding contact with the inner wall of the groove;

an atomizing nozzle; a liquid inlet channel and a liquid outlet channel are formed in the inner wall of the groove; the atomizing nozzle is arranged at one end of the liquid outlet channel far away from the groove; check valves are arranged in the liquid inlet channel and the liquid outlet channel; and one ends of the liquid inlet channel and the liquid outlet channel, which are communicated with the grooves, are positioned between the partition plate and the sealing plate.

Preferably, a chute is formed in the inner wall of the groove; a sliding rod is connected in a sliding manner in the sliding groove; a pressing sheet is arranged between the rotating cabin and the foam cushion; the pressing piece is rotationally connected with the sliding rod through a torsion spring; one end of the steel wire rope is fixedly connected with the metal ball, and the other end of the steel wire rope is fixedly connected with one end of the pressing piece, which is far away from the sliding rod.

Preferably, wave plates are arranged on two sides of the metal ball; the wave plate is fixedly connected with the inner wall of the groove.

Preferably, the glass plate is composed of an S-shaped sheet and a knocking hammer; one end of the S-shaped sheet is fixedly connected with the inner wall of the groove, and the other end of the S-shaped sheet is fixedly connected with the knocking hammer; the S-shaped sheet is made of spring steel materials.

The beneficial effects of the invention are as follows:

1. according to the invention, through the mutual matching between the rotating cabin and the blade plate, on one hand, the blade plate can drive the moisture in the machine body to flow from bottom to top, so that the moisture in the height region of the machine body can be uniformly mixed, the humidity above and below the machine body is ensured to be in a relatively stable state, and on the other hand, the rotating cabin can stir the moisture flowing in the machine body, so that the uniformity of the humidity in the machine body is further improved, and condensed water which drops or is condensed on the inner wall of the machine body can be absorbed through the absorption module, the interference of the condensed water on the local humidity in the machine body is reduced, the stability of the humidity in the machine body is improved, and the refrigerating and fresh-keeping effects of onions in the machine body are further improved.

2. According to the invention, through the arrangement of the knocking hammer, the metal ball can drive the knocking hammer to continuously knock the inner wall of the groove through the knocking hammer by impacting the S-shaped sheet, so that the condensed water on the outer wall of the rotating cabin is continuously subjected to the action of vibration force to accelerate falling, and the moisture on the surface of the rotating cabin is vibrated due to the action of vibration force transmitted to the surface of the rotating cabin, so that the moisture is not beneficial to stay contact on the surface of the rotating cabin for a long time, condensation of the moisture on the surface of the rotating cabin is reduced, the local humidity of the surface of the rotating cabin is reduced, and the practical application effect of the invention is further improved.

Drawings

The invention will be further described with reference to the drawings and embodiments.

FIG. 1 is a perspective view of the present invention;

FIG. 2 is a schematic diagram of the structure of the present invention;

FIG. 3 is an enlarged view at A in FIG. 2;

FIG. 4 is a perspective view of a wave plate used in the present invention;

fig. 5 is an enlarged view at B in fig. 4;

FIG. 6 is a rear view of the present invention;

in the figure: 1. a body; 11. a thermal insulation door; 12. a driving motor; 13. a mounting rod; 14. a cavity; 141. a blade; 142. a turbine; 143. a worm; 15. an airway; 16. a drive gear; 161. an acceleration gear; 2. rotating the cabin; 21. a supporting plate; 22. a sponge cushion; 23. a groove; 231. a metal ball; 232. a wire rope; 233. a partition plate; 234. a sealing plate; 235. a chute; 236. a slide bar; 237. tabletting; 24. an atomizing nozzle; 25. a liquid inlet channel; 26. a liquid outlet channel; 261. a one-way valve; 27. a wave plate; 271. s-shaped sheets; 272. knocking a hammer.

Detailed Description

The invention is further described in connection with the following detailed description in order to make the technical means, the creation characteristics, the achievement of the purpose and the effect of the invention easy to understand.

As shown in fig. 1 to 6, the onion refrigeration and fresh-keeping device of the invention comprises:

the refrigerator comprises a machine body 1, a refrigerating system and a humidifying system at one side of the machine body 1, wherein the refrigerating system is used for controlling the temperature in the machine body 1, and the humidifying system is used for controlling the humidity in the machine body 1;

further comprises:

the heat preservation door 11 is rotatably arranged at one end of the machine body 1; a driving motor 12 is arranged at one end of the machine body 1 far away from the heat preservation door 11; a mounting rod 13 is rotatably connected with the machine body 1; the mounting rod 13 is fixedly connected with an output shaft of the driving motor 12; a rotating cabin 2 is arranged in the machine body 1; the rotating cabin 2 is fixedly connected to the mounting rod 13; the rotating cabin 2 is in sliding contact with the inner wall of the machine body 1; an absorption module is arranged between the rotary cabin 2 and the machine body 1 and used for absorbing condensed water on the inner wall of the machine body 1;

the wind power circulation module is arranged inside the machine body 1; the wind power circulation module is used for driving airflow in the machine body 1 to flow.

As an embodiment of the present invention, the wind circulation module includes a blade 141; the lower end of the machine body 1 is provided with a cavity 14 communicated with the machine body 1; the blade 141 is rotatably connected in the cavity 14; the lower end of the blade 141 is provided with a turbine 142 and a worm 143; the turbine 142 is fixedly connected with the blade plate 141; one end of the worm 143 is in transmission connection with the output end of the driving motor 12 through an acceleration module, and the other end of the worm is meshed with the turbine 142; the upper end of the machine body 1 is provided with an air passage 15 communicated with the cavity 14.

As one embodiment of the present invention, the acceleration module includes a driving gear 16 and an acceleration gear 161 that are engaged with each other; the driving gear 16 is fixedly connected with the output shaft of the driving motor 12, and the accelerating gear 161 is fixedly connected with the worm 143; the rotating cabin 2 is fan-shaped; a supporting plate 21 is connected in a sliding way in the rotating cabin 2;

when in operation, each rotating cabin 2 is connected with a supporting plate 21 in a sliding way, wherein the supporting plates are parallel to each other; one side of the rotating cabin 2 is connected with a cabin door in a sliding manner; the rotary cabin 2 is made of a metal mesh plate, so that the rotary cabin 2 has good air permeability, a user pulls out the supporting plate 21 in the rotary cabin 2 after opening the heat-insulating door 11, and places the onion on the supporting plate 21, then inserts the supporting plate 21 filled with the onion into the rotary cabin 2, so that the rotary cabin 2 is filled with the onion, then closes the heat-insulating door 11, and controls the operation of the refrigerating system and the humidifying system, so that the refrigerating system controls the temperature in the machine body 1 to be maintained at 0 ℃ to 3 ℃; the humidifying system controls the humidity in the machine body 1 to be kept at 60-70%, controls the driving motor 12 to drive the mounting rod 13 to rotate, so that the mounting rod 13 can drive the rotating cabin 2 to rotate, and the rotating cabin 2 can stir air in the machine body 1 and enable the air in the machine body 1 to flow and mix mutually in the rotating cabin 2 in the rotating process, so that the humidity in the machine body 1 is improved to be uniform, and on the other hand, the rotating cabin 2 can drive the absorption module to absorb condensed water condensed on the inner wall of the machine body 1, and the condensed water condensed on the inner wall of the rotating cabin 2 can rotate along with the rotating cabin 2 and is thrown on the inner wall of the machine body 1 under the action of centrifugal force and absorbed by the water absorption module; the condensed water in the machine body 1 near the cold surface is reduced, so that the humidity of the area in the machine body 1 near the cold surface and the principle cold surface is in a relatively stable state, the reduction of the humidity in the machine body 1 can be increased by controlling a humidifying system, and the increased humidity can be rapidly and uniformly mixed with the humid air in the machine body 1 under the stirring of the rotating cabin 2; further, the moisture increased in the machine body 1 is prevented from accumulating at the position of the humidifying system, the problem that onions in the region with overlarge humidity are rotten due to overlarge local humidity in the machine body 1 is prevented, the uniformity of the humidity in the machine body 1 is improved, and the refrigerating and fresh-keeping effects on the onions are further improved; in the process that the driving motor 12 drives the mounting rod 13 to rotate, the driving motor 12 can drive the driving gear 16 to synchronously rotate, so that the driving gear 16 can drive the accelerating gear 161 to rotate, the diameter and the number of teeth of the driving gear 16 are larger than those of the accelerating gear 161, the rotating speed of the accelerating gear 161 is increased, the accelerating gear 161 can drive the turbine 142 in the cavity 14 to rotate through the worm 143, the worm 143 can drive the blade 141 to synchronously rotate, the rotating speed of the blade 141 is increased, after the rotating speed of the blade 141 is increased, the blade 141 can blow the air flow in the machine body 1 to rise, on one hand, the humidity of the air flow above the machine body 1 is lower due to the fact that the humidity air flow can be converged and sunk, so that the air flow with low humidity can be pushed into and flow to the cavity 14 below from the upper air channel 15 through the rising air flow, and the air flow with high humidity can be blown into the cavity 14 from the mouth of the cavity 14, the air flow with low humidity can be mutually mixed, the air humidity in the machine body 1 is lifted, on the other hand, the moisture in the rising air flow can be blocked from the rising air flow with high humidity uniformity, and the humidity in the air flow can be pushed out of the air channel 1 from the air channel 1 under the effect of the high humidity can be guaranteed, and the humidity in the air flow can be pushed out of the air flow 1 at the same time, and the humidity can be pushed out from the air channel 1; the onion between the upper layer and the lower layer can be separated by the arrangement of the supporting plate 21; the onions stacked up and down are prevented from being mutually extruded, the rotating cabin 2 is provided with a fan shape, on one hand, the storage capacity of the onions in the rotating cabin 2 can be increased, on the other hand, when the rotating cabin 2 rotates, the supporting plates 21 are perpendicular to the ground, onions on the same supporting plate 21 are stacked, at the moment, the inclined inner wall of the rotating cabin 2 can be used for carrying out inclined support on the onions, so that the onions stacked on the same layer can be dependent on the baffle 233 on one side of the same layer, and the mutual extrusion force among the onions is reduced;

according to the invention, through the mutual matching between the rotating cabin 2 and the blade plate 141, on one hand, the blade plate 141 can drive moisture in the machine body 1 to flow from bottom to top, so that the moisture in the height region of the machine body 1 can be uniformly mixed, the humidity above and below the machine body 1 is ensured to be in a relatively stable state, and on the other hand, the rotating cabin 2 can stir the moisture flowing in the machine body 1, so that not only is the uniformity of the humidity in the machine body 1 further improved, but also condensed water which drops or is condensed on the inner wall of the machine body 1 can be absorbed through the absorption module, the interference of the condensed water on the local humidity in the machine body 1 is reduced, the humidity stability in the machine body 1 is improved, and the refrigerating and fresh-keeping effects of onions in the machine body 1 are further improved.

As one embodiment of the present invention, the absorption module comprises a foam-rubber cushion 22, wherein the foam-rubber cushion 22 is installed on one surface of the rotating cabin 2 near the inner wall of the machine body 1; a groove 23 is formed in the rotating cabin 2; a metal ball 231 is arranged in the groove 23; the metal balls 231 are connected with the foam cushion 22 through steel wire ropes 232; an extrusion unit is arranged in the groove 23; the squeezing unit is used for squeezing and atomizing the condensed water absorbed by the sponge.

As an embodiment of the present invention, the pressing unit includes:

the partition plate 233, the partition plate 233 is fixedly connected to the inner wall of the groove 23; the separator 233 serves to separate the sponge mat 22 from the metal balls 231; the steel wire rope 232 is in sliding sealing connection with the partition 233; a sealing plate 234 is arranged above the metal ball 231; the sealing plate 234 is fixedly connected with the steel wire rope 232; the sealing plate 234 is in sliding contact with the inner wall of the groove 23;

an atomizer head 24; the inner wall of the groove 23 is provided with a liquid inlet channel 25 and a liquid outlet channel 26; the atomizing nozzle 24 is arranged at one end of the liquid outlet channel 26 far away from the groove 23; check valves 261 are arranged in the liquid inlet channel 25 and the liquid outlet channel 26; the ends of the liquid inlet channel 25 and the liquid outlet channel 26, which are communicated with the groove 23, are positioned between the partition plate 233 and the sealing plate 234.

As an embodiment of the present invention, a sliding groove 235 is formed on the inner wall of the groove 23; a sliding rod 236 is slidably connected to the sliding groove 235; a pressing sheet 237 is arranged between the rotating cabin 2 and the foam cushion 22; the pressing piece 237 is rotationally connected with the slide rod 236 through a torsion spring; one end of the steel wire rope 232 is fixedly connected with the metal ball 231, and the other end of the steel wire rope is fixedly connected with one end of the pressing piece 237 away from the slide rod 236;

in the initial state, the metal ball 231 in the rotating cabin 2 which is in a parallel state with the ground is positioned between the partition plate 233 and the bottom of the groove 23 and is close to the partition plate 233; the foam-rubber cushion 22 is fixedly connected to one end of the partition plate 233 far away from the metal ball 231, and in the process that the driving motor 12 drives the rotating cabin 2 to rotate through the mounting rod 13, the rotating cabin 2 which is in a parallel state with the ground at the moment rotates upwards along the axis of the mounting rod 13, so that the rotating cabin 2 drives the foam-rubber cushion 22 to be in sliding contact with the inner wall of the machine body 1; the condensed water on the inner wall of the machine body 1 is absorbed by the foam-rubber cushion 22, at the moment, along with the upward rotation of the rotating cabin 2, the metal ball 231 in the groove 23 can slide downwards along the inner wall of the groove 23 under the action of self gravity, so that the metal ball 231 can pull the steel wire rope 232 to synchronously move until the steel wire rope 232 is stretched to a straightened state, at the moment, the metal ball 231 continues to move along the inner wall of the groove 23 towards the bottom of the groove 23, so that the metal ball 231 pulls the two pressing sheets 237 to overturn towards the direction approaching each other by overcoming the torsion force of the torsion spring through the steel wire rope 232, so that the pressing sheets 237 squeeze and push the foam-rubber cushion 22 connected with the pressing sheets 237 to approach each other, until the pressing sheets 237 overturn to be in the same plane with the sliding grooves 235, the metal ball 231 can pull the sliding rod 236 to slide downwards along the sliding grooves 235 by the steel wire rope 232, so that the pressing sheets 237 drive the upper ends of the foam-rubber cushion 22 to move downwards, in the process of downwards moving the foam-rubber cushion 22, the foam-rubber cushion 22 is extruded and compressed, at the moment, water in the upper end of the foam-rubber cushion 22 is extruded and continuously wets to one end of the foam-rubber cushion 22 close to the baffle 233 under the action of gravity until the sliding rod 236 reaches the bottom of the chute 235, at the moment, the foam-rubber cushion 22 completely enters the groove 23, at the moment, the metal ball 231 pulls the pressing sheet 237 to continuously overcome the torsion rotation of the torsion spring through the steel wire rope 232, the pressing sheet 237 extrudes the foam-rubber cushion 22 entering the groove 23, so that the water in the foam-rubber cushion 22 is extruded and flows out, so that the flowing water can flow between the baffle 233 and the sealing plate 234 from the liquid inlet channel 25, and as the metal ball 231 pulls the sealing plate 234 to move towards the direction close to the bottom of the groove 23 through the steel wire rope 232, the space between the sealing plate 234 and the baffle 233 is increased, at this time, the external air enters from the notch of the groove 23 and flows between the baffle plate 233 and the sealing plate 234 through the check valve 261 of the liquid inlet channel 25, so that the air entering the groove 23 can blow the water in the foam-rubber cushion 22 to flow to the baffle plate 233, until the water in the foam-rubber cushion 22 is extruded, the water enters between the sealing plate 234 and the baffle plate 233 through the liquid inlet channel 25 until the pressing piece 237 cannot rotate, at this time, the rotating cabin 2 is in a vertical state with the ground, while the metal ball 231 is suspended in the groove 23, rotates along with the rotating cabin 2 and rotates downwards beyond the position parallel to the ground, at this time, the metal ball 231 in the rotating cabin 2 moves along the inner wall of the groove 23 towards the direction close to the baffle plate 233, the sealing plate 234 is close to the baffle 233 under the pushing of the metal ball 231 and the air pressure at the bottom of the groove 23, so that water between the baffle 233 and the sealing plate 234 can flow from the one-way valve 261 of the liquid outlet 26 to the atomizing nozzle 24, the atomizing nozzle 24 can atomize and spray water, and at the moment, the air flow blown out from the opening of the cavity 14 can blow off mist sprayed by the atomizing nozzle 24, so that condensed water on the wall of the machine body 1 can be atomized again, the humidity in the machine body 1 is improved, the reduction of the humidity in the machine body 1 caused by condensation of the condensed water is avoided, the stable circulation of the humidity in the machine body 1 is ensured, the use of a humidifying system can be reduced, and the waste of electric energy is reduced; the practical application effect of the invention is effectively improved.

As an embodiment of the present invention, the metal balls 231 are provided with wave plates 27 at both sides thereof; the wave plate 27 is fixedly connected with the inner wall of the groove 23.

As an embodiment of the present invention, the glass plate is composed of an S-shaped piece 271 and a knocking hammer 272; one end of the S-shaped piece 271 is fixedly connected with the inner wall of the groove 23, and the other end of the S-shaped piece is fixedly connected with the knocking hammer 272; the S-shaped piece 271 is made of spring steel material;

in operation, in an initial state, the wave plate 27 is composed of a plurality of S-shaped pieces 271 and a knocking hammer 272; one end of the concave surface of the S-shaped piece 271 is fixedly connected with the inner wall of the groove 23, and one end of the convex surface of the S-shaped piece 271 is fixedly connected with the knocking hammer 272; during the rotation of the rotary cabin 2, the metal ball 231 reciprocates along the inner wall of the groove 23 in the groove 23, that is, when the rotary cabin 2 rotates upwards from a state parallel to the ground to a state perpendicular to the ground, the metal ball 231 moves towards the direction close to the bottom of the groove 23 under the action of gravity, at this time, the metal ball 231 contacts with the S-shaped piece 271 close to the partition 233, so that the metal ball 231 enters the concave surface of the S-shaped piece 271 close to the partition 233, at this time, the metal ball 231 presses the concave surface of the S-shaped piece 271 to contact with the inner wall of the groove 23, so that the S-shaped piece 271 drives the knocking hammer 272 to strike the inner wall of the groove 23, so that the oscillating force between the knocking hammer 272 and the inner wall of the groove 23 is transferred to the outer wall of the rotary cabin 2, the condensed water condensed on the outer wall of the rotary cabin 2 is vibrated to be accelerated to be separated from the outer wall of the rotary cabin 2, and as the rotary cabin 2 continues to rotate, so that the rotary cabin 2 drives the S-shaped piece 271 to tilt continuously, the angle of the concave surface to the metal ball 231 is continuously changed, the metal ball 231 can slide to the convex surface of the S-shaped piece 271 along the concave surface of the S-shaped piece 271 under the action of self gravity, the metal ball 231 can be separated from the S-shaped piece 271 along the convex surface of the S-shaped piece 271 and falls onto the next S-shaped piece 271 under the action of gravity, the next S-shaped piece 271 drives the knocking hammer 272 to continuously strike the inner wall of the groove 23 under the impact of the metal ball 231, the S-shaped piece 271 is made of spring steel material, the previous S-shaped piece 271 is not extruded by the metal ball 231 any more and is reset under the action of self elastic restoring force, so that the metal ball 231 repeatedly moves in the groove 23 in the rotating process of the rotating cabin 2, the metal ball 231 can drive the knocking hammer 272 to continuously knock the inner wall of the groove 23 through striking the S-shaped piece 271, therefore, the condensed water on the outer wall of the rotating cabin 2 is accelerated to fall under the action of the vibration force, the residual condensed water on the outer wall of the rotating cabin 2 is reduced, the vibration force is transmitted to the surface of the rotating cabin 2, so that the moisture on the surface of the rotating cabin 2 is vibrated under the action of the vibration force, the moisture is not beneficial to stay in contact with the surface of the rotating cabin 2 for a long time, the condensed water formed by the condensation of the moisture on the surface of the rotating cabin 2 is reduced, the local humidity of the surface of the rotating cabin 2 is reduced, and the practical application effect of the invention is further improved.

The specific working procedure is as follows:

wherein, in the initial state, the metal ball 231 in the rotary cabin 2 which is in parallel with the ground is positioned between the baffle plate 233 and the bottom of the groove 23 and is close to the baffle plate 233; the foam-rubber cushion 22 is fixedly connected to one end of the partition plate 233 far away from the metal ball 231, and in the process that the driving motor 12 drives the rotating cabin 2 to rotate through the mounting rod 13, the rotating cabin 2 which is in a parallel state with the ground at the moment rotates upwards along the axis of the mounting rod 13, so that the rotating cabin 2 drives the foam-rubber cushion 22 to be in sliding contact with the inner wall of the machine body 1; the condensed water on the inner wall of the machine body 1 is absorbed by the foam-rubber cushion 22, at the moment, along with the upward rotation of the rotating cabin 2, the metal ball 231 in the groove 23 can slide downwards along the inner wall of the groove 23 under the action of self gravity, so that the metal ball 231 can pull the steel wire rope 232 to synchronously move until the steel wire rope 232 is stretched to a straightened state, at the moment, the metal ball 231 continues to move along the inner wall of the groove 23 towards the bottom of the groove 23, so that the metal ball 231 pulls the two pressing sheets 237 to overturn towards the direction approaching each other by overcoming the torsion force of the torsion spring through the steel wire rope 232, so that the pressing sheets 237 squeeze and push the foam-rubber cushion 22 connected with the pressing sheets 237 to approach each other, until the pressing sheets 237 overturn to be in the same plane with the sliding grooves 235, the metal ball 231 can pull the sliding rod 236 to slide downwards along the sliding grooves 235 by the steel wire rope 232, so that the pressing sheets 237 drive the upper ends of the foam-rubber cushion 22 to move downwards, in the process of downwards moving the foam-rubber cushion 22, the foam-rubber cushion 22 is extruded and compressed, at the moment, water in the upper end of the foam-rubber cushion 22 is extruded and continuously wets to one end of the foam-rubber cushion 22 close to the baffle 233 under the action of gravity until the sliding rod 236 reaches the bottom of the chute 235, at the moment, the foam-rubber cushion 22 completely enters the groove 23, at the moment, the metal ball 231 pulls the pressing sheet 237 to continuously overcome the torsion rotation of the torsion spring through the steel wire rope 232, the pressing sheet 237 extrudes the foam-rubber cushion 22 entering the groove 23, so that the water in the foam-rubber cushion 22 is extruded and flows out, so that the flowing water can flow between the baffle 233 and the sealing plate 234 from the liquid inlet channel 25, and as the metal ball 231 pulls the sealing plate 234 to move towards the direction close to the bottom of the groove 23 through the steel wire rope 232, the space between the sealing plate 234 and the baffle 233 is increased, at this time, the external air enters from the notch of the groove 23 and flows between the baffle plate 233 and the sealing plate 234 through the check valve 261 of the liquid inlet channel 25, so that the air entering the groove 23 can blow the water in the foam-rubber cushion 22 to flow to the baffle plate 233, until the water in the foam-rubber cushion 22 is extruded, the water enters between the sealing plate 234 and the baffle plate 233 through the liquid inlet channel 25 until the pressing piece 237 cannot rotate, at this time, the rotating cabin 2 is in a vertical state with the ground, while the metal ball 231 is suspended in the groove 23, rotates along with the rotating cabin 2 and rotates downwards beyond the position parallel to the ground, at this time, the metal ball 231 in the rotating cabin 2 moves along the inner wall of the groove 23 towards the direction close to the baffle plate 233, the sealing plate 234 is close to the baffle 233 under the pushing of the metal ball 231 and the air pressure at the bottom of the groove 23, so that water between the baffle 233 and the sealing plate 234 can flow from the one-way valve 261 of the liquid outlet 26 to the atomizing nozzle 24, the atomizing nozzle 24 can atomize and spray water, and at the moment, the air flow blown out from the opening of the cavity 14 can blow off mist sprayed by the atomizing nozzle 24, so that condensed water on the wall of the machine body 1 can be atomized again, the humidity in the machine body 1 is improved, the reduction of the humidity in the machine body 1 caused by condensation of the condensed water is avoided, the stable circulation of the humidity in the machine body 1 is ensured, the use of a humidifying system can be reduced, and the waste of electric energy is reduced; the practical application effect of the invention is effectively improved; in the initial state, the wave plate 27 is composed of a plurality of S-shaped pieces 271 and a knocking hammer 272; one end of the concave surface of the S-shaped piece 271 is fixedly connected with the inner wall of the groove 23, and one end of the convex surface of the S-shaped piece 271 is fixedly connected with the knocking hammer 272; during the rotation of the rotary cabin 2, the metal ball 231 reciprocates along the inner wall of the groove 23 in the groove 23, that is, when the rotary cabin 2 rotates upwards from a state parallel to the ground to a state perpendicular to the ground, the metal ball 231 moves towards the direction close to the bottom of the groove 23 under the action of gravity, at this time, the metal ball 231 contacts with the S-shaped piece 271 close to the partition 233, so that the metal ball 231 enters the concave surface of the S-shaped piece 271 close to the partition 233, at this time, the metal ball 231 presses the concave surface of the S-shaped piece 271 to contact with the inner wall of the groove 23, so that the S-shaped piece 271 drives the knocking hammer 272 to strike the inner wall of the groove 23, so that the oscillating force between the knocking hammer 272 and the inner wall of the groove 23 is transferred to the outer wall of the rotary cabin 2, the condensed water condensed on the outer wall of the rotary cabin 2 is vibrated to be accelerated to be separated from the outer wall of the rotary cabin 2, and as the rotary cabin 2 continues to rotate, so that the rotary cabin 2 drives the S-shaped piece 271 to tilt continuously, the angle of the concave surface to the metal ball 231 is continuously changed, the metal ball 231 can slide to the convex surface of the S-shaped piece 271 along the concave surface of the S-shaped piece 271 under the action of self gravity, the metal ball 231 can be separated from the S-shaped piece 271 along the convex surface of the S-shaped piece 271 and falls onto the next S-shaped piece 271 under the action of gravity, the next S-shaped piece 271 drives the knocking hammer 272 to continuously strike the inner wall of the groove 23 under the impact of the metal ball 231, the S-shaped piece 271 is made of spring steel material, the previous S-shaped piece 271 is not extruded by the metal ball 231 any more and is reset under the action of self elastic restoring force, so that the metal ball 231 repeatedly moves in the groove 23 in the rotating process of the rotating cabin 2, the metal ball 231 can drive the knocking hammer 272 to continuously knock the inner wall of the groove 23 through striking the S-shaped piece 271, therefore, the condensed water on the outer wall of the rotating cabin 2 is accelerated to fall under the action of the vibration force, the residual condensed water on the outer wall of the rotating cabin 2 is reduced, the vibration force is transmitted to the surface of the rotating cabin 2, so that the moisture on the surface of the rotating cabin 2 is vibrated under the action of the vibration force, the moisture is not beneficial to stay in contact with the surface of the rotating cabin 2 for a long time, the condensed water formed by the condensation of the moisture on the surface of the rotating cabin 2 is reduced, the local humidity of the surface of the rotating cabin 2 is reduced, and the practical application effect of the invention is further improved.

In the description of the present invention, it should be noted that the terms "center", "longitudinal", "lateral", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", etc. indicate orientations or positional relationships based on the orientations or positional relationships shown in fig. 1, are merely for convenience in describing the present invention and simplifying the description, and do not indicate or imply that the apparatus or element in question must have a specific orientation, be configured and operated in a specific orientation, and thus should not be construed as limiting the scope of the present invention, and furthermore, the terms "first", "second", "third", etc. are merely used for distinguishing the description, and should not be construed as indicating or implying relative importance.

The foregoing has shown and described the basic principles, principal features and advantages of the invention. It will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, and that the above embodiments and descriptions are merely illustrative of the principles of the present invention, and various changes and modifications may be made without departing from the spirit and scope of the invention, which is defined in the appended claims. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims

1. An onion cold-storage fresh-keeping device, comprising:

the device comprises a machine body (1), and a refrigerating system and a humidifying system at one side of the machine body (1), wherein the refrigerating system is used for controlling the temperature in the machine body (1), and the humidifying system is used for controlling the humidity in the machine body (1);

the method is characterized in that: further comprises:

the heat preservation door (11) is rotatably arranged at one end of the machine body (1); one end of the machine body (1) far away from the heat preservation door (11) is provided with a driving motor (12); the machine body (1) is rotationally connected with a mounting rod (13); the mounting rod (13) is fixedly connected with an output shaft of the driving motor (12); a rotating cabin (2) is arranged in the machine body (1); the rotating cabin (2) is fixedly connected to the mounting rod (13); the rotating cabin (2) is in sliding contact with the inner wall of the machine body (1); an absorption module is arranged between the rotary cabin (2) and the machine body (1) and used for absorbing condensed water on the inner wall of the machine body (1);

the wind power circulation module is arranged inside the machine body (1); the wind power circulation module is used for driving airflow in the machine body (1) to flow.

2. The onion cold-storage and fresh-keeping device of claim 1, wherein: the wind circulation module comprises a blade (141); the lower end of the machine body (1) is provided with a cavity (14) communicated with the machine body (1); the blade plate (141) is rotationally connected in the cavity (14); the lower end of the blade plate (141) is provided with a turbine (142) and a worm (143); the turbine (142) is fixedly connected with the blade plate (141); one end of the worm (143) is in transmission connection with the output end of the driving motor (12) through the acceleration module, and the other end of the worm is meshed with the turbine (142); an air passage (15) communicated with the cavity (14) is formed in the upper end of the machine body (1).

3. The onion cold-storage and fresh-keeping device of claim 2, wherein: the acceleration module comprises a driving gear (16) and an acceleration gear (161) which are meshed with each other; the driving gear (16) is fixedly connected with an output shaft of the driving motor (12), and the accelerating gear (161) is fixedly connected with the worm (143); the rotating cabin (2) is fan-shaped; and a supporting plate (21) is connected in the rotating cabin (2) in a sliding way.

4. A refrigerated onion fresh-keeping device as claimed in claim 3, wherein: the absorption module comprises a foam-rubber cushion (22), and the foam-rubber cushion (22) is arranged on one surface of the rotating cabin (2) close to the inner wall of the machine body (1); a groove (23) is formed in the rotating cabin (2); a metal ball (231) is arranged in the groove (23); the metal balls (231) are connected with the foam-rubber cushion (22) through steel wire ropes (232); an extrusion unit is arranged in the groove (23); the squeezing unit is used for squeezing and atomizing the condensed water absorbed by the sponge.

5. The onion cold-storage and fresh-keeping device of claim 4, wherein: the pressing unit includes:

the baffle plate (233), the said baffle plate (233) links fixedly to the inner wall of the recess (23); the partition plate (233) is used for separating the foam cushion (22) and the metal balls (231); the steel wire rope (232) is in sliding sealing connection with the partition plate (233); a sealing plate (234) is arranged above the metal ball (231); the sealing plate (234) is fixedly connected with the steel wire rope (232); the sealing plate (234) is in sliding contact with the inner wall of the groove (23);

an atomizer (24); the inner wall of the groove (23) is provided with a liquid inlet channel (25) and a liquid outlet channel (26); the atomizing nozzle (24) is arranged at one end of the liquid outlet channel (26) far away from the groove (23); check valves (261) are arranged in the liquid inlet channel (25) and the liquid outlet channel (26); one ends of the liquid inlet channel (25) and the liquid outlet channel (26) which are communicated with the groove (23) are positioned between the partition plate (233) and the sealing plate (234).

6. The onion cold-storage and fresh-keeping device of claim 5, wherein: a sliding groove (235) is formed in the inner wall of the groove (23); a sliding rod (236) is connected in a sliding way in the sliding groove (235); a tabletting (237) is arranged between the rotating cabin (2) and the foam cushion (22); the pressing piece (237) is rotationally connected with the sliding rod (236) through a torsion spring; one end of the steel wire rope (232) is fixedly connected with the metal ball (231), and the other end of the steel wire rope is fixedly connected with one end of the pressing piece (237) far away from the sliding rod (236).

7. The onion cold-storage and fresh-keeping device of claim 6, wherein: wave plates (27) are arranged on two sides of the metal ball (231); the wave plate (27) is fixedly connected with the inner wall of the groove (23).

8. The onion cold-storage and fresh-keeping device of claim 7, wherein: the glass plate consists of an S-shaped sheet (271) and a knocking hammer (272); one end of the S-shaped piece (271) is fixedly connected with the inner wall of the groove (23), and the other end of the S-shaped piece is fixedly connected with the knocking hammer (272); the S-shaped piece (271) is made of spring steel material.