CN212386974U - Maintenance storage device and humidification mechanism thereof - Google Patents

Abstract

The utility model relates to a maintenance storage device and humidification mechanism and humidification method thereof, maintenance storage device's humidification mechanism includes atomizing humidification subassembly, evaporation subassembly and humidification fan. The atomization humidification component is provided with a humidification airflow output end. The evaporation assembly comprises an evaporation shell and a water molecule attachment arranged in the evaporation shell. The air outlet of the humidifying fan is in butt joint with the first air inlet, and the humidifying fan is used for discharging the evaporation airflow in the evaporation shell into the maintenance box. The air current that utilizes the humidification fan to produce carries out the secondary evaporation to the adsorbed hydrone on the hydrone attachment to in the case is gone into along with the wind flow that the humidification fan produced, improve incasement humidity. In addition, the diameter of molecular groups in the air flow is effectively reduced while the humidity of the air flow in the curing box is improved, the diameter of water molecules in the air in the curing box is smaller, the water molecules are easy to uniformly diffuse into the curing box, the humidity in the curing box is more balanced, and the curing effect can be improved.

Description

Maintenance storage device and humidification mechanism thereof

Technical Field

The utility model relates to a storage facilities technical field especially relates to a maintain storage device and humidification mechanism thereof.

Background

Along with the improvement of living standard of people, the number of people who take tobacco products is more and more. Examples of tobacco products are cigars, cigarettes and the like, and cigars are used as examples herein. Generally, after the cigar is produced, the cigar needs to be maintained and cured for a period of time under the environment with proper temperature (16-20 ℃) and proper relative humidity (60-70%), and the cigar has mellow taste and is suitable for being smoked by people. And thus the demand for devices for storing cigars is increasing. The traditional cigar maintenance and storage device comprises a maintenance box and a humidifying mechanism arranged in the maintenance box. The humidifying mechanism can adjust the relative humidity of the environment in the curing box. However, the conventional cigar curing and storing device cannot achieve the effect of adjusting the relative humidity of the environment of each part in the curing box to be relatively balanced, and the cigar curing and storing effect is not good.

SUMMERY OF THE UTILITY MODEL

Therefore, the defects of the prior art need to be overcome, and the maintenance storage device and the humidifying mechanism thereof are provided, so that the relative humidity of the environment of each part in the maintenance box can be balanced, and the maintenance effect can be improved.

The technical scheme is as follows: a humidifying mechanism for a maintenance storage device, the humidifying mechanism for a maintenance storage device comprising: the atomization humidification component is provided with a humidification airflow output end; the evaporation assembly comprises an evaporation shell and a water molecule attachment arranged in the evaporation shell, the evaporation shell is provided with two first air inlets and two first air outlets, and one of the first air inlets is communicated with the humidifying airflow output end; and the air outlet of the humidifying fan is in butt joint with the other first air outlet, and the humidifying fan is used for discharging the evaporation airflow in the evaporation shell into the maintenance box through the first air outlet.

The humidifying mechanism of the maintenance storage device is characterized in that when the relative humidity in the maintenance box is judged to be low (specifically lower than 60%) and humidification treatment is needed, the atomization and humidification component is started, the atomization and humidification component sends humidified atomized water molecule airflow into the evaporation shell through the humidification airflow output end, atomized water molecules are attached to the water molecule attachment body, and the water molecule attachment body is used for absorbing atomized water molecules and blocking the atomized water molecules from directly entering the inner cavity of the maintenance box. After the atomization humidification component stops working, the humidification fan is started again, air flow generated by the humidification fan is used for carrying out secondary evaporation on water molecules adsorbed on the water molecule attachment body, and air flow generated along with the humidification fan flows into the box, so that the humidity in the box is improved. In addition, the diameter of molecular groups in the air flow is effectively reduced while the humidity of the air flow in the curing box is improved, the diameter of water molecules in the air in the curing box is smaller, the water molecules are easy to uniformly diffuse into the curing box, the humidity in the curing box is more balanced, and the curing effect can be improved.

In one embodiment, the atomization humidification assembly comprises a water box, a humidifier and a spray head; the humidifier comprises a humidifying shell, the humidifying shell is arranged on the water box and communicated with the water box, and the humidifying shell is connected with the spray head; the spray head is communicated with the first air inlet.

In one embodiment, the water molecule attachment is a silver ion or a nanomaterial.

In one embodiment, the water molecule attachments are silver ion particles or nanoparticles.

In one embodiment, the evaporation shell is a silver ion box or a nano material box.

In one embodiment, the humidifying mechanism of the maintenance storage device further includes a humidifying system cover, the atomizing and humidifying assembly, the evaporating assembly and the humidifying fan are all covered inside the humidifying system cover, the humidifying system cover is provided with a second air outlet and a second air inlet, the air inlet of the humidifying fan is arranged corresponding to the second air inlet, and the first air outlet is arranged corresponding to the second air outlet.

In one embodiment, the humidifying mechanism of the maintenance storage device further comprises a first sensor and an alarm; the first sensor is arranged at the second air outlet and used for acquiring the relative humidity at the second air outlet, and the alarm is used for giving an alarm when the difference value of the relative humidity acquired by the first sensor is smaller than a preset value.

A maintenance storage device comprises a humidifying mechanism of the maintenance storage device, a maintenance box, a controller and a second sensor; the humidifying mechanism, the controller and the second sensor of the maintenance storage device are all arranged on the maintenance box; the controller is electrically connected with the atomization humidification component, the humidification fan and the second sensor respectively; the humidifying fan is used for pumping and discharging the evaporation airflow in the evaporation shell into the maintenance box; the second sensor is used for acquiring the relative humidity of the environment in the curing box.

Foretell maintenance storage device, if the relative humidity that the second sensor acquireed the environment in the curing box is lower (specifically for example be less than 60%) when needing to carry out humidification treatment, atomizing humidification subassembly is opened to the controller, and atomizing humidification subassembly sends into the evaporation casing with the atomizing hydrone air current of humidification through humidifying air output end, attaches to the atomizing hydrone on the hydrone attachment body, and the hydrone attachment body effect lies in absorbing atomizing hydrone, blocks that atomizing hydrone directly gets into the inner chamber of curing box through the air outlet. After atomizing humidification subassembly stop work, the controller restarts the humidification fan, utilizes the air current that the humidification fan produced to carry out the secondary evaporation to the adsorbed hydrone on the hydrone attachment to in the wind flow income incasement that the humidification fan produced, improve incasement humidity. In addition, the diameter of molecular groups in the air flow is effectively reduced while the humidity of the air flow in the curing box is improved, the diameter of water molecules in the air in the curing box is smaller, the water molecules are easy to uniformly diffuse into the curing box, the humidity in the curing box is more balanced, and the curing effect can be improved.

In one embodiment, the dehumidifying mechanism further comprises a dehumidifying mechanism, and the dehumidifying mechanism comprises a dehumidifying box and a dehumidifying fan; the dehumidifying box is internally provided with a dehumidifying object, the dehumidifying box is provided with a third air inlet and a third air outlet, the air outlet of the dehumidifying fan is in butt joint with the third air inlet, and the dehumidifying fan is used for sucking the air flow in the curing box into the dehumidifying box; the dehumidification fan is electrically connected with the controller.

In one embodiment, the maintenance and storage device further includes a dehumidification system cover and a third sensor, the dehumidification system cover is connected to the inner wall of the maintenance box, the dehumidification box and the dehumidification fan are both disposed in the dehumidification system cover, the dehumidification system cover is provided with a fourth air inlet and a fourth air outlet, the third sensor is disposed at the fourth air outlet and is used for acquiring the relative humidity at the fourth air outlet, and the third sensor is electrically connected to the controller.

In one embodiment, the maintenance storage device further comprises a circulation fan disposed in the maintenance box, and the circulation fan is electrically connected to the controller.

Drawings

The accompanying drawings, which are incorporated in and constitute a part of this application, are included to provide a further understanding of the invention, and are incorporated in and constitute a part of this specification.

In order to more clearly illustrate the technical solutions in the embodiments of the present invention, the drawings needed to be used in the description of the embodiments will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art to obtain other drawings without creative efforts.

Fig. 1 is a view showing a structure of a maintenance storage device according to an embodiment of the present invention after a cover is opened;

fig. 2 is an exploded view of a humidifying mechanism of a maintenance storage device according to an embodiment of the present invention;

fig. 3 is a schematic structural view of a humidifying mechanism of a maintenance storage device according to an embodiment of the present invention;

fig. 4 is an exploded view of a dehumidifying mechanism of a maintenance storage device according to an embodiment of the present invention;

fig. 5 is a schematic view of a dehumidifying mechanism of a maintenance storage device according to an embodiment of the present invention;

fig. 6 is a schematic view of another perspective structure of a dehumidifying mechanism for a maintenance storage device according to an embodiment of the present invention.

10. A humidifying mechanism; 11. an atomization humidification component; 111. a water box; 112. a humidifying housing; 113. a spray head; 114. a blocking member; 12. an evaporation assembly; 121. an evaporation housing; 122. a first air inlet; 13. a humidifying fan; 14. a humidification system cover; 141. a second air outlet; 142. a second air inlet; 15. a first sensor; 20. a curing box; 21. a box body; 22. a cover body; 40. a dehumidification mechanism; 41. a dehumidification box; 411. a third air inlet; 412. a third air outlet; 42. a dehumidifying fan; 43. a dehumidification system housing; 431. a fourth air inlet; 432. a fourth air outlet; 433. a fifth air inlet; 434. a fifth air outlet; 435. a wind-proof plate; 46. a third sensor; 50. a circulating fan.

Detailed Description

In order to make the above objects, features and advantages of the present invention more comprehensible, embodiments of the present invention are described in detail below with reference to the accompanying drawings. In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present invention. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein, as those skilled in the art will be able to make similar modifications without departing from the spirit and scope of the present invention.

Because the relative humidity in the curing box is smaller in the adjusting process, the smaller the diameter of the atomized water molecular group is, the more balanced the relative humidity of the environment at each part in the curing box is adjusted, and the curing box inner cavity environment with uniformly distributed humidity is more beneficial to the cigar storage and curing process.

Referring to fig. 1 and 2, fig. 1 is a schematic structural view of the maintenance storage device according to an embodiment of the present invention after the cover 22 is opened; fig. 2 shows a schematic structural diagram of the humidifying mechanism 10 for the maintenance storage device in an embodiment of the present invention, and the humidifying mechanism 10 for the maintenance storage device provided in an embodiment of the present invention includes an atomizing and humidifying component 11, an evaporating component 12 and a humidifying fan 13. The atomizing humidification module 11 is provided with a humidified airflow output end. The evaporation assembly 12 includes an evaporation housing 121 and a water molecule attachment disposed in the evaporation housing 121. The evaporation housing 121 is provided with two first air inlets 122 and two first air outlets. One of the first inlet vents 122 is in communication with the humidified gas stream output. An air outlet of the humidifying fan 13 is connected to another first air inlet 122, and the humidifying fan 13 is used for discharging the evaporated air flow in the evaporation casing 121 to the curing box 20 through the first air outlet.

When the humidification mechanism 10 of the maintenance storage device determines that the relative humidity in the maintenance box 20 is low (specifically, for example, lower than 60%) and humidification processing is required, the atomizing and humidifying component 11 is turned on, the atomizing and humidifying component 11 sends the humidified atomized water molecule airflow into the evaporation shell 121 through the humidified airflow output end, and attaches the atomized water molecules to the water molecule attachment, which is used for absorbing the atomized water molecules and blocking the atomized water molecules from directly entering the inner cavity of the maintenance box 20. After the atomization humidification component 11 stops working, the humidification fan 13 is started again, air flow generated by the humidification fan 13 is used for carrying out secondary evaporation on water molecules adsorbed on the water molecule attachment body, and the air flow generated by the humidification fan 13 flows into the box, so that the humidity in the box is improved. In addition, the diameter of molecular groups in the air flow is effectively reduced while the humidity of the air flow in the curing box 20 is improved, the diameter of water molecules in the air in the curing box 20 is smaller, the water molecules are easy to uniformly diffuse into the curing box 20, the humidity in the curing box 20 is more balanced, and the curing effect can be improved.

Referring to fig. 2 and 3, fig. 3 is a schematic structural diagram of a humidifying mechanism of a maintenance storage device according to an embodiment of the present invention. Further, the atomizing and humidifying assembly 11 includes a water box 111, a humidifier and a spray head 113. The humidifier includes a humidifying enclosure 112. The humidifying casing 112 is disposed on the water box 111 and communicated with the water box 111, and the humidifying casing 112 is connected with the spray head 113. The nozzle 113 is connected to the first air inlet 122. Specifically, the humidifier is an ultrasonic humidifier, and the ultrasonic humidifier further includes an ultrasonic generator, and the ultrasonic generator is, for example, integrally provided in the controller, but may be separately provided. The atomization plate generates high-frequency oscillation by using the ultrasonic generator, water guided into the atomization plate from the water box 111 is thrown away from the water surface in the high-frequency oscillation process of the atomization plate to generate elegant water mist, and the water mist is sprayed into the evaporation shell 121 through the spray head 113.

Evaporation shell

In one embodiment, the water molecule attachment is a silver ion or a nanomaterial. The silver ion substance and the nano material body have better functions of adsorbing atomized water molecules and realizing secondary evaporation. In this embodiment, the water molecule attachment is silver ion, which not only can effectively adsorb atomized water molecules, but also has the function of sterilization.

Referring to fig. 2 and 3, further, the water molecule attachment is silver ion particles or nanoparticles. Therefore, when the silver ion particles or the nanoparticles are arranged in the evaporation shell 121, airflow gaps are formed among the particles, and after humidified airflow of atomized water molecules enters the evaporation shell 121, on one hand, the atomized water molecules can be favorably contacted with and adsorbed by the outer surfaces of the particles; on the other hand, the water molecule attachment installed in the evaporation casing 121 has a certain blocking effect on the atomized water molecule airflow, but can be discharged to the inside of the curing box 20 through the first outlet of the evaporation casing 121 by the pressurization of the exhaust air of the humidifying fan 13.

Referring to fig. 2 and 3, in one embodiment, the evaporation housing 121 is a silver ion box or a nano-material box. Thus, after the atomized water molecules enter the evaporation casing 121, the atomized water molecules can be adsorbed by not only the water molecule attachment but also the inner wall of the evaporation casing 121. In this embodiment, the evaporation housing 121 is a silver ion box.

Referring to fig. 2 and 3, in one embodiment, the humidifying mechanism 10 of the maintenance storage device further includes a humidifying system cover 14. The atomizing and humidifying assembly 11, the evaporating assembly 12 and the humidifying fan 13 are all covered inside the humidifying system cover 14, and the humidifying system cover 14 is provided with a second air outlet 141 and a second air inlet 142. Specifically, the number and the position of the second outlets 141 are the same as those of the first outlets. In addition, the air inlet of the humidifying fan 13 is disposed corresponding to the second air inlet 142.

Referring to fig. 2 and 3, in addition, specifically, the silver ion box of the evaporation assembly 12 is detachably installed inside the humidification system cover 14, so that the silver ion box can be conveniently taken out to replace silver ion particles. Of course, the silver ion box may be integrated with the humidification system cover 14, or may be separately designed and placed inside the humidification system cover 14, which is not limited herein.

Referring to fig. 2 and 3, in addition, the water box 111 may be designed independently, for example, fastened to the humidification system cover 14 by a snap-fit manner, or integrated with the humidification system cover 14 directly. In this embodiment, water box 111 can independent design, convenient dismantlement, removal and water injection. The upper portion of water box 111 is provided with the water filling port for water box 111 adds water, has shutoff piece 114 on the water filling port, like the plug for water box 111's is sealed after the water injection is accomplished, satisfies the humidification mechanism 10 that adds the maintenance storage device and in portable removal process water seal requirement. In order to improve the water atomization effect and prolong the service life of the atomization sheet, the water in the water box 111 is preferably purified water or distilled water.

Referring to fig. 2 and 3, the humidifying mechanism 10 of the maintenance storage device further includes a first sensor 15 and an alarm. The first sensor 15 is disposed at the second air outlet 141, the first sensor 15 is configured to acquire relative humidity at the second air outlet 141, and the alarm is configured to perform an alarm operation when a difference between the relative humidity acquired by the first sensor 15 and the relative humidity is smaller than a preset value. Specifically, the first sensor 15 and the alarm are both electrically connected to the controller, the controller receives the relative humidity sensed by the first sensor 15 at the second air outlet 141, and if the relative humidity change value at the preset time interval (for example, 60S) is determined to be smaller than a preset value (for example, 10%), the water shortage of the water box 111 or the fault of the atomizing and humidifying component 11 is prompted, and at this time, the atomizing and humidifying component 11 is controlled to stop working to replenish the water source or maintain the atomizing and humidifying component 11, so that the worker can be timely reminded. If it is determined that the value of the change in relative humidity is greater than the predetermined value for the predetermined time interval (e.g., 60S), the humidifying fan 13 is turned on to circulate the humidified flow into the entire curing box 20 by the humidifying fan 13 to lower the relative humidity in the entire curing box 20.

It should be noted that the relative humidity change value of the preset time interval (for example, 60S) is a difference between the relative humidity acquired by the first sensor 15 at the second outlet 141 at, for example, 0S and the relative humidity acquired at the second outlet 141 at, for example, 60S.

Referring to fig. 2 and fig. 3, specifically, the first sensor 15 is a temperature and humidity probe, and the first sensor 15 can not only acquire the relative humidity at the second air outlet 141, but also be used to acquire the ambient temperature at the second air outlet 141.

Referring to fig. 1, fig. 2 and fig. 4, fig. 4 is an exploded view illustrating a dehumidifying structure of a maintenance storage device according to an embodiment of the present invention. In one embodiment, a maintenance storage device includes the humidifying mechanism 10 of any one of the above embodiments, and further includes a maintenance box 20, a controller (not shown), and a second sensor (not shown). The humidifying mechanism 10, the controller and the second sensor of the curing storage device are all arranged on the curing box 20. The controller is electrically connected with the atomizing and humidifying component 11, the humidifying fan 13 and the second sensor respectively. The humidifying fan 13 is used to draw and discharge the evaporation air flow in the evaporation case 121 into the curing box 20. The second sensor is used to obtain the relative humidity of the environment within the curing box 20.

Above-mentioned maintenance storage device, if the relative humidity that the second sensor obtained the environment in maintenance box 20 is lower (specifically for example be less than 60%) when needing to carry out humidification, atomizing humidification subassembly 11 is opened to the controller, and atomizing humidification subassembly 11 sends into evaporation casing 121 with the atomizing hydrone air current of humidification through humidifying airflow output end, attaches atomizing hydrone on the hydrone attachment body, and the hydrone attachment body effect lies in absorbing atomizing hydrone, blocks that atomizing hydrone directly gets into the inner chamber of maintenance box 20 through the air outlet. After the atomization humidification component 11 stops working, the controller restarts the humidification fan 13, air flow generated by the humidification fan 13 is used for carrying out secondary evaporation on water molecules adsorbed on the water molecule attachment body, and air flow generated by the humidification fan 13 flows into the box, so that humidity in the box is improved. In addition, the diameter of molecular groups in the air flow is effectively reduced while the humidity of the air flow in the curing box 20 is improved, the diameter of water molecules in the air in the curing box 20 is smaller, the water molecules are easy to uniformly diffuse into the curing box 20, the humidity in the curing box 20 is more balanced, and the curing effect can be improved.

Specifically, the second sensor is a temperature and humidity probe, and the second sensor can not only acquire the relative humidity in the curing box 20, but also can be used for acquiring the ambient temperature in the curing box 20.

Referring to fig. 4 to 6, fig. 5 and 6 respectively illustrate structural diagrams of a dehumidifying structure of a maintenance storage device according to an embodiment of the present invention from different viewing angles. Further, the maintenance storage device further includes a dehumidifying mechanism 40. The dehumidifying mechanism 40 includes a dehumidifying box 41 and a dehumidifying fan 42. The dehumidifying box 41 is provided with dehumidifiers therein, and the dehumidifying box 41 is provided with a third air inlet 411 and a third air outlet 412. An air outlet of the dehumidifying fan 42 is connected to the third air inlet 411, and the dehumidifying fan 42 is used for drawing the air flow in the curing box 20 into the dehumidifying box 41. The dehumidifying fan 42 is electrically connected to the controller. When the controller determines that the relative humidity in the curing box 20 is relatively high (for example, the relative humidity is greater than 80%), the controller controls the dehumidifying fan 42 to operate accordingly, so that the dehumidifying fan 42 draws the air with relatively high humidity in the curing box 20 into the dehumidifying box 41, dehumidifies the air by the dehumidifying box 41, and discharges the air into the curing box 20, thereby reducing the relative humidity in the curing box 20. Specifically, the dehumidification material is dry particles, dry powder, or the like, and may also be hydrophilic particles such as activated alumina spheres, molecular sieves, or the like.

Referring to fig. 1, 4 and 5, the curing box 20 further includes a box body 21 and a cover 22 rotatably and openably disposed on the box body 21. The humidifying mechanism 10 and the dehumidifying mechanism 40 are respectively disposed on two opposite inner sidewalls of the case 21. Thus, the arrangement positions of the humidifying mechanism 10 and the dehumidifying mechanism 40 are reasonable, and the volume size of the maintenance storage device can be reduced.

Referring to fig. 1, 4 and 6, in one embodiment, the dehumidifying mechanism 40 further includes a dehumidifying system cover 43 and a third sensor 46. The dehumidifying system cover 43 is connected to the inner wall of the curing box 20, the dehumidifying box 41 and the dehumidifying fan 42 are both disposed in the dehumidifying system cover 43, and the dehumidifying system cover 43 is provided with a fourth air inlet 431 and a fourth air outlet 432. The third sensor 46 is disposed at the fourth air outlet 432 for obtaining the relative humidity at the fourth air outlet 432, and the third sensor 46 is electrically connected to the controller. Thus, the third sensor 46 can sense the humidity of the air processed by the dehumidifying box 41, and is mainly used for determining whether the adsorption capacity of the dehumidified objects in the dehumidifying box 41 is disabled. One specific judgment method is as follows: judging the change of the two humidity sensing values in a preset time interval (for example, 60s), namely the difference value of the two humidity values, and when the change is smaller than a certain value (for example, 10 percent, the value depends on the precision of a humidity sensor), determining that the water absorption characteristic of the dehumidified object in the dehumidification box 41 is invalid, controlling the action of an alarm by the controller, and alarming to replace the dehumidified object in the dehumidification box 41. Alternatively, in order to facilitate replacement of the dehumidified contents in the dehumidification cassette 41, the dehumidification cassette 41 may be detachably fixed to the dehumidification system cover 43 using, for example, a snap-fit structure. When the space of the inner cavity of the curing box 20 is large, the flow of the air flow on each inner wall and space is enhanced in order to ensure the uniformity of the temperature and humidity distribution inside the whole curing box 20. In one embodiment, the maintenance storage device further includes a circulation fan 50, the circulation fan 50 is disposed in the maintenance box 20, and the circulation fan 50 is electrically connected to the controller. Thus, the controller controls the circulating fan 50 to work, so that the airflow in the curing box 20 circularly flows to fill the whole curing box 20, and the relative humidity in the curing box 20 is balanced.

It should be noted that the third sensor 46 may also be disposed at other positions, for example, at the side adjacent to the circulating fan 50 as illustrated in fig. 5, and after the circulating fan 50 sucks the dehumidified air into the dehumidification system cover 43, the third sensor 46 senses the humidity of the air processed by the dehumidification box 41, so as to determine whether the adsorption capacity of the dehumidified object in the dehumidification box 41 is disabled.

Referring to fig. 1, 4 and 6, further, the circulation fan 50 has an independent air inlet and an independent air outlet. The circulation fan 50 may be disposed at a front end or a rear end of the dehumidification system cover 43, which is not limited herein. The circulating fan 50 is not controlled by the relative humidity parameter in the curing box 20, and always keeps a constant pressure working state, and functions to enhance the flow of the air flow in the inner cavity of the curing box 20. In the non-dehumidification mode, since the dehumidification fan 42 does not operate, the air flow in the curing box 20 does not pass through the dehumidifiers of the dehumidification box 41, and the humidity of the air flow in the curing box 20 is not changed; when the dehumidification mode is activated, the dehumidification fan 42 is operated, and the air flow passes through the dehumidification box 41, so as to reduce the relative humidity of the air flow, thereby achieving the purpose of changing the humidity. Furthermore, the humidification system cover 14 and the dehumidification system cover 43 are plastic covers, and are fixed on the inner wall of the box 21 by using tapping screws or a snap structure, and the humidification system cover 14 and the dehumidification system cover 43 may be made of other materials or may be fixed on the inner wall of the curing box 20 by other methods.

Referring to fig. 1, 4 and 6, further, an air partition 435 is disposed in the dehumidification system cover 43, the air partition 435 divides the dehumidification system cover 43 into two spaces, the dehumidification box 41 and the dehumidification fan 42 are disposed in one of the two spaces, and the fourth air inlet 431 and the fourth air outlet 432 of the dehumidification system cover 43 are communicated with the one space. The circulating fan 50 is disposed in another space, the dehumidifying system cover 43 is further provided with a fifth air inlet 433 and a fifth air outlet 434 communicated with the another space, when the circulating fan 50 works, the air flow in the curing box 20 enters through the fifth air inlet 433 and is discharged from the fifth air outlet 434, so that the air flow in the curing box 20 can be driven to circularly flow.

Referring to fig. 1, 2 and 4, in one embodiment, a humidifying method for maintaining a storage device according to any one of the above embodiments includes the following steps:

s10, acquiring the relative humidity in the curing box 20;

s20, when the relative humidity in the curing box 20 is judged to be lower than the first preset value, the atomizing and humidifying component 11 is started to enable humidifying and atomizing water molecules to enter the evaporation shell 121;

and S30, closing the humidifying component, starting the humidifying fan 13 to evaporate the water molecules adsorbed on the water molecule attachment for the second time, and discharging the water molecules into the curing box 20. The first preset value is, for example, 60%.

In the humidifying method of the maintenance storage device, when humidification is required, the atomizing and humidifying component 11 is turned on, the atomizing and humidifying component 11 sends the humidified atomized water molecule airflow into the evaporation shell 121 through the humidified airflow output end, and the atomized water molecules are attached to the water molecule attachment body, and the water molecule attachment body is used for absorbing the atomized water molecules and preventing the atomized water molecules from directly entering the inner cavity of the maintenance box 20. After the atomization humidification component 11 stops working, the humidification fan 13 is started again, air flow generated by the humidification fan 13 is used for carrying out secondary evaporation on water molecules adsorbed on the water molecule attachment body, and the water molecules flow into the box along with air flow generated by the humidification fan 13, so that the humidity in the box is improved, and the relative humidity in the maintenance box 20 is controlled to be 60% -70%.

Referring to fig. 1, fig. 2 and fig. 4, before turning on the humidifying/atomizing assembly 11, the method further includes step S12: acquiring the relative humidity in the humidification system cover 14, and recording as a first detection value;

after the humidifying device 11 is turned on, and before the humidifying device is turned off, the method further comprises the following steps:

s22, when the atomizing and humidifying component 11 is turned on for a first preset operating time, acquiring the relative humidity inside the humidifying system cover 14, recording the relative humidity as a second detection value, and determining whether the relative humidity inside the humidifying system cover 14 (the second detection value) is higher than a first preset value;

the first preset working time is set according to actual conditions, is related to the humidifying capacity of the atomizing and humidifying assembly 11, and is not limited. The first default value is, for example, 80% and is not limited.

If the relative humidity in the humidification system cover 14 is higher than the first preset value, the process proceeds to step S30; if the relative humidity in the humidification system cover 14 is lower than the first preset value, the process proceeds to step S24.

Further, the humidifying method for the maintenance storage device further includes:

step S24, continuing to delay the work of the atomization humidification component 11 for a second preset work time, and obtaining the relative humidity in the humidification system cover 14 again, and recording the relative humidity as a third detection value;

the second preset working time is, for example, 2S to 4S, specifically, for example, 3S.

Step S25, obtaining a relative humidity change value in the humidification system cover 14 based on the third detection value and the first detection value;

and step S26, judging whether the water box 111 is lack of water or the atomizing humidification assembly 11 is in failure according to the relative humidity change value.

Specifically, if the change value of the relative humidity at the preset time interval (for example, 60S) is determined to be smaller than the preset value (for example, 10%), it is prompted that the water tank 111 is short of water or the atomizing and humidifying assembly 11 is in a fault, at this time, the atomizing and humidifying assembly 11 is controlled to stop working, so as to replenish the water source or maintain the atomizing and humidifying assembly 11, and thus, the worker can be reminded in time. If it is judged that the value of the change in relative humidity for the preset time interval (for example, 60S) is greater than the preset value, the humidifying fan 13 is turned on, and the humidified airflow is circulated into the entire curing box 20 by the humidifying fan 13 to lower the relative humidity in the entire curing box 20, and the process proceeds to step S12.

Further, the following steps are also included after step S30: the humidifying fan 13 is turned off after being turned on for the third preset operation time, and returns to step S10. The third preset operation time is, for example, 25S to 35S, specifically, 30S.

Further, the humidifying method for maintaining the storage device further comprises the following steps: when it is judged that the relative humidity inside the curing box 20 is higher than the second preset value, the dehumidifying fan 42 is turned on to increase the relative humidity inside the curing box 20. The second preset value is, for example, 75%, that is, when it is determined that the relative humidity in the curing box 20 is higher than 75%, a dehumidifying operation is performed to control the relative humidity in the curing box 20 to be 60% to 70%.

Along with the increase of the volume of the inner cavity of the curing box 20 and the position difference between the second air outlet 141 of the humidifying system cover 14 and the fourth air outlet 432 of the dehumidifying system cover 43 and the second sensor, when the humidifying or dehumidifying mode is started, the humidity in the curing box 20 can be dynamically distributed and non-uniformly distributed along with the change of the air flow in the inner cavity of the curing box 20, until the humidifying or dehumidifying mode is stopped for a certain time, the humidity in the curing box 20 can gradually tend to be uniformly and statically balanced and distributed, namely, a delay balancing process exists from the start of humidifying or dehumidifying to the final static and balanced distribution of the humidity. Since the humidity to be finally achieved is the humidity in the curing box 20 which is finally statically balanced, it is necessary to accurately identify whether the humidity sensing value in the curing box 20 is a statically balanced value or a dynamically changing value, so as to correctly apply the humidification/dehumidification mode. Based on this, further, the humidifying method for maintaining the storage device further comprises the following steps:

when the humidity of the inner cavity of the curing box 20 is greatly different from the set value, a continuous humidifying or dehumidifying mode is adopted;

when the humidity value in the curing box 20 is close to the set value (for example, within 2%), the intermittent humidification or intermittent dehumidification, and the delay balance mode are adopted.

Specifically, the humidification or dehumidification operation 5S, the equalization 30S, and the re-humidification or dehumidification operation are repeated to gradually reach the set humidity in the curing box 20.

In order to avoid overshoot of humidity adjustment when the humidity value is close to the set humidity value, which causes alternate work of dehumidification and humidification, namely, immediately after humidification is finished, the humidity adjustment system is switched to a dehumidification mode when the humidity exceeds the set value, and the overshoot of dehumidification humidity enters humidification again, so that vicious circle is formed in the inner cavity of the box body 21 by humidification and dehumidification, and finally, water in the humidification water box 111 is exhausted and dehumidification adsorption substances are invalid. Based on this, further, the humidifying method for maintaining the storage device further comprises the following steps:

if the difference between the upper and lower limits of humidification and dehumidification is increased, that is, if the humidity value is set to RHset, the humidification limit is RHset- Δ RH (from low humidity humidification to the end of the value, the upper limit of starting humidification is set at the same time, and the humidification is started up below the value), the dehumidification limit is RHset + Δ RH (from high humidity dehumidification to the end of the value, the lower limit of starting dehumidification is set at the same time, and the dehumidification is started up above the value), Δ RH (which is related to the required humidity control accuracy) is increased, the switching value between the two different modes of humidification and dehumidification is increased, and the risk of forming a vicious cycle of dehumidification-humidification is reduced.

Furthermore, time delay is added when the dehumidification mode and the humidification mode are switched, namely, the humidification mode or the dehumidification mode is switched to the other mode, the mode is firstly stopped to work for a period of time (for example, 5min), and whether the mode is switched is determined according to the humidity parameter in the box, so that the humidity in the curing box 20 is fully ensured to be in a stable state, and the vicious cycle problem of the dehumidification and the humidification is effectively solved.

The technical features of the above embodiments can be arbitrarily combined, and for the sake of brevity, all possible combinations of the technical features in the above embodiments are not described, but should be considered as the scope of the present specification as long as there is no contradiction between the combinations of the technical features.

The above examples only represent some embodiments of the present invention, and the description thereof is more specific and detailed, but not to be construed as limiting the scope of the present invention. It should be noted that, for those skilled in the art, without departing from the spirit of the present invention, several variations and modifications can be made, which are within the scope of the present invention. Therefore, the protection scope of the present invention should be subject to the appended claims.

In the description of the present invention, it is to be understood that the terms "center", "longitudinal", "lateral", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "clockwise", "counterclockwise", "axial", "radial", "circumferential", and the like, indicate the orientation or positional relationship based on the orientation or positional relationship shown in the drawings, and are only for convenience of description and simplicity of description, and do not indicate or imply that the device or element referred to must have a particular orientation, be constructed and operated in a particular orientation, and therefore, should not be construed as limiting the present invention.

Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include at least one such feature. In the description of the present invention, "a plurality" means at least two, e.g., two, three, etc., unless specifically limited otherwise.

In the present invention, unless otherwise expressly stated or limited, the terms "mounted," "connected," and "fixed" are to be construed broadly and may, for example, be fixedly connected, detachably connected, or integrally formed; can be mechanically or electrically connected; they may be directly connected or indirectly connected through intervening media, or they may be connected internally or in any other suitable relationship, unless expressly stated otherwise. The specific meaning of the above terms in the present invention can be understood according to specific situations by those skilled in the art.

In the present application, unless expressly stated or limited otherwise, the first feature may be directly on or directly under the second feature or indirectly via intermediate members. Also, a first feature "on," "over," and "above" a second feature may be directly or diagonally above the second feature, or may simply indicate that the first feature is at a higher level than the second feature. A first feature being "under," "below," and "beneath" a second feature may be directly under or obliquely under the first feature, or may simply mean that the first feature is at a lesser elevation than the second feature.

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

Claims (11)

1. The utility model provides a maintenance storage device's humidification mechanism which characterized in that, maintenance storage device's humidification mechanism includes:

the atomization humidification component is provided with a humidification airflow output end;

the evaporation assembly comprises an evaporation shell and a water molecule attachment arranged in the evaporation shell, the evaporation shell is provided with two first air inlets and two first air outlets, and one of the first air inlets is communicated with the humidifying airflow output end; and

and the air outlet of the humidifying fan is in butt joint with the other first air outlet, and the humidifying fan is used for discharging the evaporation airflow in the evaporation shell into the maintenance box through the first air outlet.

2. The maintenance storage device humidifying mechanism of claim 1, wherein the atomizing and humidifying assembly comprises a water box, a humidifier and a spray head; the humidifier comprises a humidifying shell, the humidifying shell is arranged on the water box and communicated with the water box, and the humidifying shell is connected with the spray head; the spray head is communicated with the first air inlet.

3. The humidification mechanism for maintenance storage device of claim 1, wherein the water molecule attachment is silver ion or nano material.

4. The humidification mechanism for maintenance and storage device of claim 3, wherein the water molecule attachment is silver ion particles or nanoparticles.

5. The humidification mechanism for a curing storage device according to claim 1, wherein the evaporation case is a silver ion case or a nano material case.

6. The humidification mechanism for a maintenance storage device according to claim 1, further comprising a humidification system cover, wherein the atomization and humidification assembly, the evaporation assembly and the humidification fan are all covered inside the humidification system cover, the humidification system cover is provided with a second air outlet and a second air inlet, the air inlet of the humidification fan is arranged corresponding to the second air inlet, and the first air outlet is arranged corresponding to the second air outlet.

7. The maintenance storage device humidifying mechanism of claim 6, further comprising a first sensor and an alarm; the first sensor is arranged at the second air outlet and used for acquiring the relative humidity at the second air outlet, and the alarm is used for giving an alarm when the difference value of the relative humidity acquired by the first sensor is smaller than a preset value.

8. A maintenance storage device, comprising the humidifying mechanism of the maintenance storage device as claimed in any one of claims 1 to 7, further comprising a maintenance box, a controller and a second sensor; the humidifying mechanism, the controller and the second sensor of the maintenance storage device are all arranged on the maintenance box; the controller is electrically connected with the atomization humidification component, the humidification fan and the second sensor respectively; the humidifying fan is used for pumping and discharging the evaporation airflow in the evaporation shell into the maintenance box; the second sensor is used for acquiring the relative humidity of the environment in the curing box.

9. The maintenance storage device according to claim 8, further comprising a dehumidifying mechanism including a dehumidifying box and a dehumidifying fan; the dehumidifying box is internally provided with a dehumidifying object, the dehumidifying box is provided with a third air inlet and a third air outlet, the air outlet of the dehumidifying fan is in butt joint with the third air inlet, and the dehumidifying fan is used for sucking the air flow in the curing box into the dehumidifying box; the dehumidification fan is electrically connected with the controller.

10. The curing storage device of claim 9, wherein the dehumidifying mechanism further comprises a dehumidifying system cover and a third sensor, the dehumidifying system cover is connected to the inner wall of the curing box, the dehumidifying box and the dehumidifying fan are both disposed in the dehumidifying system cover, the dehumidifying system cover is provided with a fourth air inlet and a fourth air outlet, the third sensor is disposed at the fourth air outlet and used for acquiring the relative humidity at the fourth air outlet, and the third sensor is electrically connected to the controller.

11. The maintenance storage device of claim 9, further comprising a circulation fan disposed in the maintenance box, the circulation fan being electrically connected to the controller.

Images