CN217275042U - Storing device and dehumidification circulation assembly thereof - Google Patents

Abstract

The utility model discloses a storing device and dehumidification circulation subassembly thereof, include: the circulating air duct is divided into a chamber to be dried and a dehumidifying working chamber, the dehumidifying working chamber is communicated with the chamber to be dried through an air inlet and an air outlet, and gas discharged into the chamber to be dried from the dehumidifying working chamber through the air outlet passes through the chamber to be dried and then enters the dehumidifying working chamber through the air inlet; the refrigeration dehumidification subassembly, the refrigeration dehumidification unit mount is in the dehumidification studio, is used for to getting into the air in the dehumidification studio carries out the condensation dehumidification. The circulating air duct is divided into a dehumidifying working chamber and a chamber to be dried, and the dehumidifying working chamber and the chamber to be dried are communicated through the air inlet and the air outlet, so that a circulating channel of air is formed; and set up the refrigeration dehumidification subassembly that can condense the dehumidification in the dehumidification studio, condense the dehumidification to the air. The influence of the condensate water in the dehumidification working chamber on the drying chamber is avoided, and the dehumidification effect in the drying chamber is ensured.

Description

Storing device and dehumidification circulation assembly thereof

Technical Field

The utility model relates to a dehumidification technical field, in particular to storing device and dehumidification circulation subassembly thereof.

Background

With the development of society, the living standard of people is improved, more and more families seek higher living quality, and the requirements on storage and care of clothes are higher and higher.

The wardrobe is used for placing clean clothes so as to achieve dust prevention and neatness of the clothes. However, because the interior of the wardrobe is moist due to no illumination, no ventilation and the like, especially in the south return south and plum rain season, the humidity is higher, and therefore, the clothes are moldy due to the moist storage environment, and a large amount of bacteria are bred in the moist wardrobe, and the clothes are further moldy.

The existing dehumidification mode is based on the principle of condensation dehumidification to cool the wet air in the wardrobe, so that the water vapor is condensed, the water content of the air in the wardrobe is reduced, and the air is dried. However, when air in the wardrobe is condensed, condensed water droplets may exist in the wardrobe, which may increase the humidity of the dehumidified air, thereby affecting the dehumidification effect.

Therefore, how to ensure the dehumidification effect is a technical problem to be urgently solved by the technical personnel in the field.

SUMMERY OF THE UTILITY MODEL

In view of this, the utility model provides a dehumidification circulation subassembly of storing device to guarantee the dehumidification effect. Furthermore, the utility model also provides a storing device who has above-mentioned dehumidification circulation subassembly.

In order to achieve the above object, the utility model provides a following technical scheme:

a dehumidification cycle assembly of a storage device, comprising:

the device comprises a circulating air duct, a drying chamber and a dehumidifying working chamber, wherein the circulating air duct is divided into the drying chamber and the dehumidifying working chamber, the dehumidifying working chamber is communicated with the drying chamber through an air inlet and an air outlet, and gas discharged into the drying chamber from the dehumidifying working chamber through the air outlet passes through the drying chamber and then enters the dehumidifying working chamber through the air inlet;

the refrigeration dehumidification subassembly, the refrigeration dehumidification unit mount is in the dehumidification studio, be used for to getting into the air in the dehumidification studio carries out the condensation dehumidification.

Preferably, in the above-mentioned dehumidification circulation assembly, the circulation air duct is a chamber and is divided into a dehumidification working chamber and a chamber to be dried by a partition plate, and the air inlet and the air outlet are both provided on the partition plate.

Preferably, in the above dehumidification cycle assembly, the partition comprises:

a vertical partition plate is arranged on the upper surface of the frame,

the first inclined partition plate is connected with the first end of the vertical partition plate, the first inclined partition plate is obliquely arranged relative to the vertical partition plate, and the air outlet is formed in the first inclined partition plate;

and the second inclined partition plate is connected with the second end of the vertical partition plate and is positioned at the same side of the vertical partition plate as the first inclined partition plate, the second inclined partition plate is obliquely arranged relative to the vertical partition plate and is opposite to the inclination direction of the first inclined partition plate, and the air inlet is formed in the second inclined partition plate.

Preferably, in the above dehumidification cycle assembly, the first inclined partition extends from the second end of the vertical partition toward the first end and is inclined toward one side of the vertical partition.

Preferably, the dehumidification cycle assembly further comprises a fan for providing power for air circulation in the dehumidification working chamber and the chamber to be dried.

Preferably, in the above dehumidification cycle assembly, the fan includes:

the first fan is arranged at the air inlet and used for sending the air in the chamber to be dried into the dehumidifying working chamber;

and/or the presence of a gas in the atmosphere,

and the second fan is arranged at the air outlet and used for sending the air in the dehumidifying working chamber into the chamber to be dried.

Preferably, in the above dehumidification circulation assembly, the air outlet and the air inlet are both grid openings, and the air outlet area of the air outlet is larger than the air outlet area of the air inlet.

Preferably, in the above-mentioned dehumidification cycle component, the dehumidification cycle component further comprises a water receiving component arranged in the dehumidification working chamber, and the water receiving component is used for collecting condensed water condensed by the refrigeration dehumidification component.

Preferably, in the above dehumidification circulation assembly, the water receiving assembly includes:

the water receiving box is arranged below the refrigerating and dehumidifying component;

and the water receiving box is communicated with the water discharging box through a pipeline.

Preferably, in the above dehumidification circulation assembly, the drainage box is a drawer-type drainage box;

and/or the presence of a gas in the gas,

and a heating component is arranged in the drainage box.

Preferably, in the above dehumidification cycle assembly, the refrigeration and dehumidification assembly includes:

semiconductor refrigeration piece and with the cold junction radiator of the cold junction laminating of semiconductor refrigeration piece, the water receiving subassembly sets up cold junction radiator below.

A storage device comprises a cabinet body and a dehumidification circulation assembly, wherein the dehumidification circulation assembly is any one of the dehumidification circulation assemblies;

the baffle of dehumidification circulation subassembly will the cabinet body is separated for the dehumidification studio and treats the drying chamber.

Preferably, in the storage device, the refrigeration and dehumidification assembly is located at the top of the cabinet body, the air outlet is formed in the top of the cabinet body, and the air inlet is formed in the bottom of the cabinet body.

The utility model provides a dehumidifying circulation component of a storage device, which divides a circulation air channel into a dehumidifying working chamber and a chamber to be dried, and communicates the dehumidifying working chamber and the chamber to be dried through an air inlet and an air outlet, thereby forming a circulation channel of air; and set up the refrigeration dehumidification subassembly that can condense the dehumidification in the dehumidification studio, condense the dehumidification to the air. The influence of the condensate water in the dehumidification working chamber on the drying chamber is avoided, and the dehumidification effect in the drying chamber is ensured.

Furthermore, the utility model also provides a storing device with above-mentioned dehumidification circulation subassembly, owing to contained the above-mentioned dehumidification circulation subassembly of disclosing, consequently, this storing device also has above-mentioned technological effect, and no longer the repeated description herein.

Drawings

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

Fig. 1 is a side view of a dehumidification cycle assembly as disclosed in an embodiment of the present disclosure;

fig. 2 is a schematic view of a partial structure of one end of a dehumidification cycle assembly disclosed in an embodiment of the present invention;

fig. 3 is a partial schematic structural view of the other end of the dehumidification cycle assembly disclosed in the embodiment of the present invention;

fig. 4 is a schematic structural diagram of a storage device with a dehumidification cycle assembly disclosed in an embodiment of the present invention;

fig. 5 is a schematic sectional view of a storage device disclosed in an embodiment of the present invention;

the refrigerator comprises a semiconductor refrigerating sheet 1, a cold-end radiator 2, a cabinet 3, an air outlet 4, an air inlet 5, a first fan 6, a water draining box 7, a water receiving box 8, a pipeline 9 and a support 10, wherein the semiconductor refrigerating sheet is arranged on the front end of the refrigerator body;

31 is a clapboard, 32 is a dehumidifying working chamber, and 33 is a chamber to be dried.

Detailed Description

The utility model discloses a dehumidification circulation subassembly of storing device to guarantee the dehumidification effect. Furthermore, the utility model also discloses a storing device of having above-mentioned dehumidification circulation subassembly.

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

In the following, the terms "first", "second" are used for descriptive purposes only and are not to be understood 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 one or more of that feature.

The application discloses storing device for guarantee the dry environment of cabinet body inside to guarantee the safety of article in the locker, prevent to influence the problem of use because of the humidity, need dehumidify the operation to locker inside.

As shown in fig. 1, a specific structure of a dehumidification circulation assembly is disclosed, wherein the dehumidification circulation assembly includes a partition plate 31, a semiconductor refrigeration sheet 1, a cold-end radiator 2, a cabinet 3, an air outlet 4, an air inlet 5, a fan, a water receiving box 8, a pipeline 9 and a water discharging box 7, and with reference to fig. 2, the cabinet 3 is divided into a dehumidification working chamber 32 and a chamber to be dried 33 by the partition plate 31, wherein the dehumidification working chamber 32, the air inlet 5, the air outlet 4 and the chamber to be dried 33 form a circulation air duct.

The semiconductor refrigeration piece 1 and the cold end radiator 2 form a refrigeration and dehumidification assembly, are positioned in the dehumidification working chamber 32 and are used for condensing and dehumidifying air in the dehumidification working chamber 32. The air outlet 4 is arranged at one end close to the semiconductor refrigerating sheet 1, air after condensation and dehumidification can be discharged into the chamber 33 to be dried, and the dehumidified air enters the dehumidifying working chamber 32 through the air inlet 5 after being disturbed in the chamber 33 to be dried, so that air circulation is realized.

It should be noted that a hot-end heat sink (not shown in the figure) may be disposed at the hot end of the semiconductor cooling plate 1, and the specific form of the hot-end heat sink may be a fan heat sink or a phase-change heat sink, etc. to achieve heat dissipation.

The water receiving box 8 is positioned below the cold end radiator 2 and is communicated with the drainage box 7 through a pipeline 9. In practice, when the semiconductor refrigeration piece 1 works, the cold-end radiator 2 at the cold end of the semiconductor refrigeration piece 1 collects condensed water drops, and the water drops fall into the water receiving box 8 under the action of gravity and enter the water drainage box 7 through the pipeline 9.

The air is dehumidified by circulating condensation through the circulating air duct, the circulating air duct is separated, the refrigeration and dehumidification assembly is arranged in the dehumidification working chamber 32, the influence of condensate water in the dehumidification working chamber 32 on the drying chamber 33 is avoided, and the dehumidification effect in the drying chamber 33 is guaranteed.

In a specific embodiment, the circulating air duct is a chamber and is divided into a dehumidifying chamber 32 and a chamber to be dried 33 by a partition plate 31, and the air inlet 5 and the air outlet 4 are both formed on the partition plate 31. In practice, the circulation duct may be provided as two separate chambers, one of which is the dehumidifying working chamber 32 and the other of which is the chamber to be dried 33, and the two chambers may be communicated through the pipeline 9 for gas circulation therebetween. The specific structure and form of the circulating air duct can be selected according to different application scenarios.

As shown in fig. 1 and 2, for the form of the partition 31 in the present application, in particular, the partition 31 includes a vertical partition, a first inclined partition, and a second inclined partition. The partition plate 31 divides the circulating air duct into two relatively sealed spaces, and the air inlet 5 and the air outlet 4 are formed in the partition plate 31 to communicate the two sealed spaces.

The vertical partition board is a main partition board and is arranged along the vertical direction, the first inclined partition board is connected with the first end of the vertical partition board, and the second inclined partition board is connected with the second end of the vertical partition board. The air outlet 4 is arranged on the first inclined partition plate, and the air inlet 5 is arranged on the second inclined partition plate. In order to realize that the drying air blown into the chamber to be dried 33 from the air outlet 4 can smoothly enter the air inlet 5 after passing through the chamber to be dried 33, the first inclined partition and the second inclined partition can be arranged on the same side of the vertical partition, and the inclination directions of the first inclined partition and the second inclined partition are opposite, as shown in fig. 1, the plane on which the first inclined partition is arranged and the plane on which the second inclined partition is arranged are symmetrically.

Specifically, the first inclined partition extends from the second end of the vertical partition to the first end and inclines to one side of the vertical partition, and correspondingly, the second inclined partition extends from the first end of the vertical partition to the second end and inclines to the same side of the vertical partition, so that the first inclined partition and the second inclined partition are formed into a gradually expanding shape. The arrangement can make the air blown out from the air outlet 4 firstly blow to the side wall of the chamber to be dried 33 (the side wall is arranged side by side with the vertical partition plate), and the air continuously diffuses downwards until reaching the air inlet 5 by the action of the rebounding and turbulence of the side wall. The drying air and the moist air can be fully fused by adding turbulence, and the uniformity of the drying air in the chamber 33 to be dried is ensured. Since the air inlet 5 is also directed towards the side wall, the air is easily absorbed.

In practice, the first inclined partition and the second inclined partition may be arranged in a structure perpendicular to the vertical partition, but the turbulence may affect the uniformity of the drying in the drying chamber 33.

In order to increase the flow rate of the air circulation, a fan is further provided in the circulation duct to power the flow of the air in the chamber to be dried 33 and the dehumidifying working chamber 32. The installation positions and the number of the fans can be set according to different requirements.

Preferably, the fans may include a first fan 6 disposed at the air inlet 5 for sending the air in the chamber to be dried 33 into the dehumidifying work chamber 32, and/or a second fan (not shown) disposed at the air outlet 4 for sending the air in the dehumidifying work chamber 32 into the chamber to be dried 33. The flow of air is increased by the action of the first fan 6 and the second fan, providing power for the circulation of air. In practice, both the first fan 6 and the second fan may be installed in the dehumidifying working chamber 32.

It will be appreciated by those skilled in the art that, in order to achieve the above-mentioned object, a fan may be further installed in the chamber to be dried 33 at a position away from the inlet 5 and the outlet 4.

As shown in fig. 3 to 5, the air outlet 4 and the air inlet 5 disclosed in the present application are both grid openings, and the area of the air outlet 4 is larger than that of the air inlet 5. By providing the grid form, it is possible to prevent the items in the chamber to be dried 33 from falling into the dehumidifying work chamber 32 and to ensure the aesthetic appearance of the structure. The specific sizes of the air outlet 4 and the air inlet 5 can be set according to different requirements, and setting the area of the air outlet 4 to be larger than that of the air inlet 5 can prolong the stay time of the drying air in the chamber 33 to be dried.

As shown in fig. 1, 3 and 4, the water receiving box 8 is located right below the cold end radiator 2, the lower surface of the water receiving box 8 is connected with a pipeline 9, and the pipeline 9 continuously extends downwards and is communicated with the drainage box 7 at the bottom. When water drops condensed on the surface of the cold-end radiator 2 fall, the water drops are collected by the water receiving box 8, and the collected condensed water is drained downwards into the drainage box 7 through the pipeline 9.

The shape and size of the water receiving box 8 and the drain box 7 are not particularly limited. The water receiving box 8 and the drainage box 7 are arranged up and down along the vertical direction, so that the water collected by the water receiving box 8 can flow into the drainage box 7 under the action of gravity, and the structure is simplified.

Can specifically see from fig. 3, water receiving box 8 in this application is the rectangle box body, and bottom and pipeline 9 intercommunication, cold junction radiator 2 fall into water receiving box 8 in the projection of water receiving box 8 direction completely to guarantee that the comdenstion water of cold junction radiator 2 can be caught by water receiving box 8 completely. Four top angles of the water receiving box 8 are provided with connecting columns, and the water receiving box 8 can be fixedly installed through the four connecting columns in practice, for example, the water receiving box can be installed on the inner wall of the circulating air duct.

As can be specifically seen from fig. 4, the top end of the drainage box 7 in the present application is communicated with the pipe 9, the drainage box 7 has a rectangular box structure, in practice, the drainage box 7 can be set as a drawer-type push-pull drainage box, that is, the drainage box 7 is slidably connected with the bracket 10, and the sliding direction of the drainage box 7 is a horizontal direction, and the drainage box 7 can be pulled out through the partition 31 into the chamber to be dried 33, so as to facilitate the treatment of the collected condensed water by the operator. In practice, the drain box 7 may be pulled out from the wall surface of the circulation duct, and may be pulled out from the dehumidification operation chamber 32.

The drainage box 7 is set to be a drawer type drainage box so that an operator can conveniently process collected condensed water, and in practice, a heating assembly can be arranged in the drainage box 7 to dry moisture in the drainage box 7 through the heating effect of the heating assembly. However, since the present application aims to reduce moisture in the air, the manner of heating the drain box 7 using the heating assembly may be used only when there is a small amount of water in the drain box 7.

The heating element may be an electrical heating element or other means of achieving heating.

In addition, this application has still disclosed a storing device, including the cabinet body and dehumidification circulation subassembly, wherein, this dehumidification circulation subassembly is the dehumidification circulation subassembly that discloses in the above-mentioned embodiment, consequently, the storing device who has this dehumidification circulation subassembly also has above-mentioned all technological effects, and the repeated description is no longer given here.

The application scene of the dehumidification circulation assembly is provided, and particularly, the storage device can be equipment with dehumidification requirements, such as a wardrobe, an air conditioner and a refrigerator. In use, the circulation duct may be the cabinet 3, and the partition 31 of the dehumidification circulation assembly divides the cabinet 3 into a dehumidification working chamber 32 and a chamber to be dried 33. Taking a wardrobe as an example, the drying chamber 33 is a space for containing clothes, and the dehumidifying chamber 32 can be a sealed chamber between a back plate of the wardrobe and the space for containing the clothes.

As shown in fig. 5, in combination with the application of the dehumidifying cycle assembly, the air outlet 4 may be disposed at the top of the cabinet 3, the air inlet 5 may be disposed at the bottom of the cabinet 3, the water discharging box 7 may be disposed at the bottom of the cabinet 3, and in addition, the refrigerating dehumidifying assembly may be mounted at the top of the cabinet 3 to prolong the staying time of the dried air in the chamber 33 to be dried.

The purpose of this application lies in separating cabinet body 3 to set up the installation space of solitary refrigeration dehumidification subassembly, and the recovery space of comdenstion water, avoid treating the problem that the article in the drying chamber 33 was drenched by the comdenstion water. Therefore, in practice, the specific structure of the refrigeration and dehumidification assembly can be set according to different requirements, and for example, the refrigeration and dehumidification assembly can also be a water cooling assembly.

As used in this application and the appended claims, the terms "a," "an," "the," and/or "the" are not intended to be inclusive in the singular, but rather are intended to be inclusive in the plural unless the context clearly dictates otherwise. In general, the terms "comprises" and "comprising" merely indicate that steps and elements are included which are explicitly identified, that the steps and elements do not form an exclusive list, and that a method or apparatus may include other steps or elements. An element defined by the phrase "comprising an … …" does not exclude the presence of other identical elements in the process, method, article, or apparatus that comprises the element.

The embodiments in the present description are described in a progressive manner, each embodiment focuses on differences from other embodiments, and the same and similar parts among the embodiments are referred to each other.

The previous description of the disclosed embodiments is provided to enable any person skilled in the art to make or use the present invention. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the spirit or scope of the invention. Thus, the present invention is not intended to be limited to the embodiments shown herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.

Claims (13)

1. A dehumidification cycle assembly for a storage device, comprising:

the device comprises a circulating air duct, a drying chamber and a dehumidifying working chamber, wherein the circulating air duct is divided into the drying chamber and the dehumidifying working chamber, the dehumidifying working chamber is communicated with the drying chamber through an air inlet and an air outlet, and gas discharged into the drying chamber from the dehumidifying working chamber through the air outlet passes through the drying chamber and then enters the dehumidifying working chamber through the air inlet;

the refrigeration dehumidification subassembly, the refrigeration dehumidification unit mount is in the dehumidification studio, be used for to getting into the air in the dehumidification studio carries out the condensation dehumidification.

2. The dehumidification cycle assembly according to claim 1, wherein the circulation air duct is a chamber and is divided into a dehumidification working chamber and a chamber to be dried by a partition plate, and the air inlet and the air outlet are both provided on the partition plate.

3. The dehumidification cycle assembly of claim 2, wherein the partition comprises:

the vertical partition board is arranged on the upper portion of the frame,

the first inclined partition plate is connected with the first end of the vertical partition plate, the first inclined partition plate is obliquely arranged relative to the vertical partition plate, and the air outlet is formed in the first inclined partition plate;

and the second inclined partition plate is connected with the second end of the vertical partition plate and is positioned on the same side of the vertical partition plate as the first inclined partition plate, the second inclined partition plate is obliquely arranged relative to the vertical partition plate and is opposite to the inclination direction of the first inclined partition plate, and the air inlet is formed in the second inclined partition plate.

4. The dehumidification cycle assembly of claim 3, wherein the first sloped partition extends from the second end of the vertical partition in a direction of the first end and slopes to one side of the vertical partition.

5. The dehumidification cycle assembly of claim 2, further comprising a fan for powering air circulation within the dehumidification working chamber and the chamber to be dried.

6. The dehumidification cycle assembly of claim 5, wherein the fan comprises:

the first fan is arranged at the air inlet and used for sending the air in the chamber to be dried into the dehumidifying working chamber;

and/or the presence of a gas in the gas,

and the second fan is arranged at the air outlet and used for sending the air in the dehumidifying working chamber into the chamber to be dried.

7. The dehumidification cycle assembly of claim 1, wherein the air outlet and the air inlet are both grid-openings, and wherein an air outlet area of the air outlet is larger than an air outlet area of the air inlet.

8. The dehumidification cycle assembly of any one of claims 1-7, further comprising a water collection assembly disposed within the dehumidification working chamber, the water collection assembly configured to collect condensed water condensed by the refrigeration dehumidification assembly.

9. The dehumidification cycle assembly of claim 8, wherein the water receiving assembly comprises:

the water receiving box is arranged below the refrigerating and dehumidifying component;

and the water receiving box is communicated with the water discharging box through a pipeline.

10. The dehumidification cycle assembly of claim 9, wherein the drain box is a drawer drain box;

and/or the presence of a gas in the gas,

and a heating component is arranged in the drainage box.

11. The dehumidification cycle assembly of claim 8, wherein the refrigeration dehumidification assembly comprises:

semiconductor refrigeration piece and with the cold junction radiator of the cold junction laminating of semiconductor refrigeration piece, the water receiving subassembly sets up cold junction radiator below.

12. A storage device comprising a cabinet and a dehumidifying cycle assembly, wherein the dehumidifying cycle assembly is the dehumidifying cycle assembly according to any one of claims 1-11;

the cabinet body is divided into a dehumidifying working chamber and a chamber to be dried by the partition plate of the dehumidifying circulation assembly.

13. The storage device according to claim 12, wherein the cooling and dehumidifying assembly is located at a top of the cabinet body, the air outlet is formed at the top of the cabinet body, and the air inlet is formed at a bottom of the cabinet body.

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