CN218065177U - Dehumidification module, dehumidification device, bathroom heater - Google Patents

Abstract

The invention discloses a dehumidification module, a dehumidification device and a bath heater, which relate to the field of household equipment, and have the technical scheme that the dehumidification device comprises the following main points: having a dehumidification treatment zone adapted for the passage of an air stream; and the adsorption structure is positioned on the dehumidification processing area and is provided with a porous substrate structure and/or a porous honeycomb structure for the gas flow to pass through. Through adopting above-mentioned technical scheme, this dehumidification module compares in compressor scheme product, and no compressor sound, the noise is low, with low costs, can realize 24 hours incessant dehumidification, does not influence people's life, compares in solution scheme with low costs, and the product is small.

Description

Dehumidification module, dehumidification device, bathroom heater

Technical Field

The invention relates to the field of household equipment, in particular to a dehumidification module, a dehumidification device and a bath heater.

Background

Currently, dehumidification employed by ordinary households generally relies on dehumidification devices.

The existing dehumidifying device can be generally divided into a freezing dehumidifier and a solution adsorption dehumidifier according to different dehumidifying modes.

The working principle of the refrigeration dehumidifier is that moist air is pumped into the machine by a fan, water molecules in the air are condensed into water drops through a heat exchanger and flow into a water collecting tray, then the treated dry air is discharged, and the indoor humidity is kept at proper relative humidity through circulation.

The freezing dehumidifier is generally composed of a compressor, a fan, a heat exchanger, a water collecting tray, a sheet metal part shell and a controller. The principle of the solution adsorption type dehumidifier is that after moisture is adsorbed by the solution, the dry air is discharged.

The existing solution adsorption type dehumidifier is large in size, not suitable for civil use and cannot be applied to a wet toilet environment. The electrical appliance product of the freezing dehumidifier is provided with a refrigeration compressor, so that the problems of heavier product, high noise and high energy consumption generally exist.

Disclosure of Invention

The invention aims to provide a dehumidification module which has the advantages of no need of a compressor, small volume, low cost, low energy consumption and low noise.

The technical purpose of the invention is realized by the following technical scheme:

a dehumidification module, comprising:

having a dehumidification treatment zone adapted for the passage of an air stream;

and the adsorption structure is positioned on the dehumidification processing area and is provided with a porous substrate structure and/or a porous honeycomb structure for the gas flow to pass through.

Through adopting above-mentioned technical scheme, this dehumidification module compares in compressor scheme product, and no compressor sound, the noise is low, with low costs, can realize 24 hours incessant dehumidification, does not influence people's life, compares in solution scheme with low costs, and the product is small. The porous substrate structure and/or the porous honeycomb structure increases the contact area for air flow to pass through, and water vapor can adhere to the inside of the porous substrate structure and/or the porous honeycomb structure to remove moisture by utilizing the increase of the contact area.

Further setting: the adsorption structure further comprises an adsorption material arranged at least one position or at least one layer of the structure surface of the adsorption structure. The adsorbing material is silica gel.

Through adopting above-mentioned technical scheme, adopt silica gel to be adsorbing material, can utilize further moisture of getting rid of, increase the volume of adsorbed moisture, promote the moisture performance. In addition, the material is easy to remove moisture in the heating process, so that the aim of quick recycling is fulfilled.

Further setting: a heat source adapted to provide heat to the adsorbent structure is also included.

Through adopting above-mentioned technical scheme, utilize the heat like adsorption structure to provide the heat for the last moisture of adsorption structure takes off fast, promotes reuse's efficiency.

Further setting: the heat source is as follows:

located in the dehumidification treatment area and transferring heat to the adsorption structure;

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

is located upstream of the dehumidification treatment area and transfers heat to the air stream passing through the adsorption structure.

By adopting the technical scheme, the heat source can directly act on the adsorption structure to provide heat, and can also transfer the heat to the adsorption structure like air flow heat transfer through the adsorption structure.

Another object of the present invention is to provide a dehumidifying apparatus, which at least comprises the dehumidifying module.

Further setting: further comprising:

the air duct assembly is provided with an air inlet and a first air outlet;

a wind source adapted to output a flowing airflow to the air duct assembly.

Through adopting above-mentioned technical scheme, dehydrating unit can have wind channel subassembly and wind regime, utilizes the wind regime to form the air current with the air and inhales to the wind channel subassembly in for the air flow speed is handled the moisture in the air.

Further setting: further comprising:

the second air outlet is arranged on the air duct assembly;

and the air door structure is used for closing the second air outlet or the first air outlet.

Further setting: the damper structure includes:

a first damper having a first position closing the second air outlet and opening the first air outlet, and a second position opening the second air outlet and closing the first air outlet.

Through adopting above-mentioned technical scheme, first air outlet and second air outlet can arrange respectively at indoor and outdoor, take a breath, the switching of dehumidification, desorption state.

Further setting: the air duct assembly is as follows:

one end of the main air duct is communicated with an air source, and the other end of the main air duct is communicated with the first air outlet;

one end of the secondary air duct is connected to the main air duct and is positioned at the downstream position of the adsorption structure, and the other end of the secondary air duct is communicated with the second air outlet;

the first air door is arranged on the main air duct or the secondary air duct or at the joint of the main air duct and the secondary air duct.

Through adopting above-mentioned technical scheme, the air current in the main entrance can dehumidify the air current after adsorption structure, and the dehumidification in-process can communicate first air outlet and indoor air production circulation air current. Also can carry out the desorption to adsorption structure, get rid of the moisture in the adsorption structure, but the steam in the air current communicates the second air outlet and discharges to outdoor under this state.

Further setting: further comprising: one end of the acceleration air duct is connected to the main air duct and is positioned on an air flow path between the heat source and the adsorption structure, and the other end of the acceleration air duct is communicated with the second air outlet or the secondary air duct;

the damper structure further includes:

a second damper having a third position closing the acceleration passage and opening the main duct, and a fourth position opening the acceleration passage and closing the main duct.

By adopting the technical scheme, the air channel has the accelerating air channel, the accelerating air channel can be communicated to the outdoor through the second air outlet, no adsorption structure exists in the accelerating air channel, the accelerating air channel can be favorable for air exchange, and the air exchange efficiency is accelerated. Certainly, when the acceleration air duct is not provided, the air can be exchanged through the adsorption structure, and the secondary air duct is favorably exhausted outdoors.

Further setting: the air inlet or the position close to the air inlet in the air duct assembly is provided with a temperature sensor, and the air source, the heat source and the air door structure are in communication connection with the temperature sensor.

Through adopting above-mentioned technical scheme, according to the more accurate opening and closing of adjustment wind source, heat source and air door structure of temperature sensor, and then switch dehumidification, desorption, state of taking a breath.

Another object of the present invention is to provide a bathroom heater with the dehumidifying apparatus as described above. The dehumidifying device further includes at least:

the air inlet is positioned on the shell and is arranged towards the indoor;

the heat source is arranged on the path of the air source and the inner air outlet;

and the third air door is provided with a fifth position for closing the inner air outlet and opening the main air duct and a sixth position for opening the inner air outlet and closing the main air duct.

By adopting the technical scheme, the third air door closes the main air duct, and the air source conveys hot air flow passing through the heat source to the indoor space from the inner air outlet to provide heat for the toilet.

Drawings

FIG. 1 is a schematic structural view of a dehumidification module in a first preferred embodiment;

FIG. 2 is a schematic view of a porous honeycomb structure in accordance with a first preferred embodiment;

FIG. 3 is a schematic illustration of the structure of a porous substrate in a first preferred embodiment;

FIG. 4 is a schematic view of a dehumidifying state of the dehumidifying apparatus in the second preferred embodiment;

fig. 5 is a schematic view of a desorption state of the dehumidifying device in the second preferred embodiment;

fig. 6 is a schematic view of the ventilation state of the dehumidifying apparatus in the second preferred embodiment;

FIG. 7 is a schematic view of a dehumidifying state of a dehumidifying apparatus according to a third preferred embodiment;

fig. 8 is a schematic view of a desorption state of the dehumidifying apparatus in the third preferred embodiment;

fig. 9 is a schematic view illustrating a ventilating state of a dehumidifying apparatus according to a third preferred embodiment;

FIG. 10 is a bottom view of the bathroom warmer;

FIG. 11 is a cross-sectional view of the super bath;

in the figure, 100, a dehumidification module; 101. an adsorption structure; 102. an air duct; 103. a porous honeycomb structure; 104. a porous substrate structure; 105. a partition plate; 106. a channel;

200. a heat source;

300. an air duct assembly; 301. an air inlet; 302. an inner air outlet; 303. a first air outlet; 304. a second air outlet; 310. a first damper; 311. a second damper; 312. a third damper; 320. a main air duct; 321. a secondary air duct; 322. an acceleration air duct;

400. a source of wind; 401. a motor; 402. a wind wheel; 403. a body;

500. a housing; 501. a temperature sensor.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

First preferred embodiment:

a dehumidification module, as shown in fig. 1, includes a dehumidification process area adapted for passage of an air stream and an adsorption structure 101 located within the dehumidification process area. The dehumidification process area is carried by a carrier forming a space, which may be a pipe, a duct 102, or a housing, box with at least one inlet. Gas flow can enter and pass through the adsorption structure 101. In the present embodiment, the air duct 102 is preferably described as an example, and when the air duct 102 is circular, the air duct has both radial and axial directions, and the axial direction has an inlet and an outlet.

The adsorption structure 101 in the dehumidification treatment area has a porous honeycomb structure 103 for passing the air flow, and referring to a, b and c in fig. 2, one embodiment of the porous honeycomb structure 103 is illustrated, and the air duct 102 has a plurality of holes in the axial direction, and the holes are arranged in the radial direction, and may be arranged regularly or in disorder. The presence of the plurality of holes forms a pair of hole walls within the air chute 102, the area of the hole walls increasing the contact area with the air flow. The different forms of the holes increase the area of the hole wall. Such as: as shown in fig. 2a, a plurality of partitions 105 forming holes are provided in the air duct 102, the partitions 105 extend in the axial direction, each partition 105 has a plurality of bent portions, and the inner wall area of the hole is increased. Strip-shaped holes are formed between the adjacent partition plates 105, and the quantity of air which can pass through the strip-shaped holes is relatively large. The flow efficiency can be better ensured under the condition of ensuring a certain area.

As shown in fig. 2b, a plurality of partition plates 105 forming holes are provided in the air duct 102, the partition plates 105 extend axially, and the plurality of partition plates 105 form a polygonal shape, such as a hexagonal shape in the drawing. The axial ends of the partition plates 105 are additionally fixed, and a plurality of hexagons are fixed in series. Since the inner and outer sides of the polygon form an area in contact with the air flow, the surface capable of removing moisture is increased. The inner sides of the hexagons form channels 106 for the passage of an air flow, and between adjacent hexagons channels 106 for the passage of an air flow can also be formed.

As shown in fig. 2c, a plurality of partitions 105 forming holes are disposed in the air duct 102, the partitions 105 are connected to form a honeycomb structure, the partitions 105 are formed in a polygonal shape, and the inner sides of the hexagonal shape, for example, form passages 106 through which air flows, and the surfaces of the inner sides are areas in contact with the air flows. Unlike in fig. 2b, the plurality of hexagons do not have an outer wall.

As still another embodiment of the adsorption structure 101, referring to fig. 3, the adsorption structure 101 may also be a porous substrate structure 104, and the porous substrate structure 104 is different from the porous honeycomb structure 103 in that the pores of the porous honeycomb structure 103 are axial, and the porous substrate may be composed of pores in axial and radial directions or inclined to the axial direction. Referring to FIG. 3e, there are a plurality of axial channels 106 within the air chute 102, as well as a plurality of radial channels 106, with the axial channels 106 and the radial channels 106 communicating with each other to form a staggered series of channels 106. The wind flows from the inlet side to the outlet side in disorder.

Referring to fig. 3f, unlike fig. 3e, the radial passage 106 and the axial passage 106 are continuously connected from the inlet side to the outlet side to form one passage 106, and a plurality of the passages 106 are arranged in parallel in the air path 102.

Referring to fig. 3g, fig. 3f is different in that the channel 106 extending from the inlet to the outlet is an oblique channel 106 inclined to the axis, and the oblique channel 106 may be continuous to form an oblique channel 106, or a plurality of oblique channels 106 may be jointly communicated to form one channel 106. A plurality of passages 106 are provided in parallel.

Further, the dehumidification module 100 further comprises an adsorption material disposed on the surface of the adsorption structure 101, and the adsorption material is disposed at least at one position or one layer position on the adsorption structure 101. In this embodiment, it is preferable that the adsorbing material is arranged on the surface of the adsorbing structure 101 in one layer. The adsorbing material can be fixed on the adsorption structure 101 in a spraying mode, a casting molding mode in advance and a bonding mode in the later period. In the present embodiment, the adsorbent is preferably silica gel. The silica gel has good water absorption and heat resistance. Can utilize the body of self to adsorb steam when getting rid of the moisture to, usable heating lets the quick desorption of steam on the body.

Furthermore, the material properties of the adsorption structure 101 of the dehumidification module 100 may be provided with a heat source 200 in the dehumidification processing area or at a position upstream of the dehumidification processing area, and the heat source 200 may be a heating member that is electrically heated or heated by other means, or a heat transfer member that can perform heat exchange, and can supply heat to the adsorption structure 101. And removing the moisture in the adsorbing material by using heat, and recycling the water again.

Referring to fig. 3e, a heat source 200 may be disposed at the inlet of the air duct 102, i.e., at a position upstream of the adsorption structure 101, where the heat source 200 heats the air flow and delivers the heated air flow into the adsorption structure 101, where the air flow is used to transfer heat to the adsorbent material and remove the moisture from the adsorbent material.

Referring to fig. 3f, the heat source 200 may also be arranged outside the air duct 102, or outside the adsorption structure 101. Heat adsorption structure 101 body, let adsorption structure 101 body have the heat, and then get rid of the moisture of adsorbing material.

Referring to fig. 3g, the heat source 200 may be disposed at the inlet side of the wind tunnel 102 and the outer side of the wind tunnel 102 at the same time, and together constitute the heated heat source 200 in conjunction with the principles in fig. 3e and 3 f.

First preferred embodiment:

a dehumidification apparatus includes the dehumidification module 100 of the first embodiment. The dehumidifying device can be a bath heater, can be a part of a fresh air system, can also be a part of an air conditioner, or independently form an independent moisture absorber. Typically a home dehydrating breather.

The dehumidification device in the present embodiment is specially designed for wet bathroom environment, especially for non-ventilated and non-daylighting bathroom environment, and may be understood as a part connected to the bathroom heater, or directly configured as a part of the bathroom heater.

Referring to fig. 4, a layout view of the dehumidifying apparatus after installation is shown. Such as on the ceiling of a toilet. The dehumidifying device comprises an air duct assembly 300, the air duct assembly 300 is provided with an air inlet 301 and a first air outlet 303, the air inlet 301 and the first air outlet 303 are communicated to the indoor, and the dehumidifying module 100 is located between the air inlet 301 and the first air outlet 303.

An air source 400 is disposed at the position of the air inlet 301, in this embodiment, the air source 400 is preferably a fan assembly, and the air source 400 may be other negative pressure devices or wind pressure machines capable of forming flowing air flow. It is sufficient that a flowing gas stream can be generated. When the air source 400 is provided, the indoor air can flow into the air duct assembly 300.

The fan assembly is disposed at the air inlet 301, or disposed within the air duct assembly 300 proximate to the air inlet 301. The fan subassembly includes: the wind tunnel assembly comprises a machine body 403, a motor 401 and a wind wheel 402 which are arranged in the machine body 403, wherein the motor 401 drives the wind wheel 402 to rotate, and wind flow generated by the wind wheel 402 is conveyed into the wind tunnel assembly 300.

Specifically, the air duct assembly 300 includes a main air duct 320, one end of the main air duct 320 is communicated with the air source 400, and the other end is communicated with the first air outlet 303. The adsorption structure 101 of the dehumidification module 100 is disposed in the main air duct 320. And is located between the air source 400 and the first air outlet 303. The air source 400 rotates to send indoor air flow into the main air duct 320, and dehumidifies the air flow through the adsorption structure 101.

The air duct assembly 300 further includes a second air outlet 304, and the second air outlet 304 is connected to the outside. The air duct assembly 300 has a secondary air duct 321 communicated with the main air duct 320, one end of the secondary air duct 321 is connected to the main air duct 320 and located at a downstream position of the adsorption structure 101, and the other end is communicated with the second air outlet 304. The second outlet 304 is equivalent to a ventilation opening connected to the outside, and when the dehumidification is not performed, the ventilation is performed by using the second outlet 304.

In order to switch the second outlet mouth 304 and the first outlet mouth 303. A damper structure is disposed in the air duct assembly 300, and is used for sealing the second air outlet 304 or the first air outlet 303. The damper structure includes a first damper 310, and the first damper 310 is disposed on the main air duct 320 or the secondary air duct 321 or at a connection position of the main air duct 320 and the secondary air duct 321. The first damper 310 has a first position closing the second outlet port 304 and opening the first outlet port 303, and a second position opening the second outlet port 304 and closing the first outlet port 303.

Further, a temperature sensor 501 is arranged on the air inlet 301 or in the air duct assembly 300 near the air inlet 301, and the air source 400, the heat source 200 and the air door structure are all in communication connection with the temperature sensor 501.

In the present embodiment, the heat source 200 is described in the first embodiment, the heat source 200 is installed and disposed at an upstream position of the adsorption structure 101, according to fig. 4, 10 and 11, the heat source 200 may be disposed at an outlet of a fan assembly, the fan assembly is installed at a position in a bathroom heater, the bathroom heater has a cabinet 500, the cabinet 500 is a part of the air duct assembly 300, the air inlet 301 is located at a lower side of the cabinet 500, and an inner air outlet 302 is additionally provided at a lower side of the cabinet 500. In this embodiment, the heat source 200 is preferably disposed inside the cabinet 500, that is, a portion of the super bath, and the heat source 200 is disposed on the path of the air source 400 and the inner air outlet 302. The bathroom heater is also provided with a third air door 311, the third air door 311 is provided with a fifth position for closing the inner air outlet 302 and opening the main air duct 320, and a sixth position for opening the inner air outlet 302 and closing the main air duct 320.

The bath heater is in a normal heating working state. The third damper 311 closes the main duct 320 and opens the inner outlet 302. The fan assembly and the heat source 200 work, wind flow is sucked from the air inlet 301, and hot air flow is discharged from the inner air outlet 302 after heat transfer of the heat source 200, so that bathing and heating in a toilet are realized.

Referring to fig. 4, the dehumidifying device may be present alone, may be a part of the bathroom heater, or may be a dehumidifying function of the bathroom heater in a dehumidifying state of the dehumidifying device.

The humidity sensor detects the air humidity, and when the room environment humidity is in an interval of 70% -90% and the outdoor humidity is high, the state is applicable.

During dehumidification, the third damper 311 closes the inner outlet 302 and opens the main duct 320. The first damper 310 opens the first outlet port 303 and closes the second outlet port 304. The fan assembly and the dehumidification module 100 are started, moisture enters from the air inlet 301, passes through the fan assembly, the heat source 200 and passes through the dehumidification module 100, and at the moment, the heat source 200 is not started. Realize the air at indoor circulation, indoor air current blows the moisture of room bottom from the air outlet air-out, plays the effect of even dehumidification, wholly reduces room humidity. After passing through the dehumidification module 100, the indoor air is dehumidified by the dehumidification module 100.

Then the dehumidification state is operated for a certain time, the time is determined according to the dehumidification performance of the dehumidification module 100, and the dehumidification module 100 is switched to the desorption state after reaching the saturation state.

In the desorption state, referring to fig. 5, the third damper 311 closes the inner air outlet 302 and opens the main air duct 320. The first damper 310 opens the second outlet 304 and closes the first outlet 303. At this time, the heat source 200 and the air source 400 are started, so that the temperature of the air flow passing through the heat source 200 is increased to 40-50 ℃, and the hot air is driven by the air source 400 to rapidly take away the moisture absorbed in the dehumidification module 100 through the dehumidification module 100 and is discharged to the outside through the second air outlet 304. The desorption state also lasts for a certain time to allow the dehumidification module 100 to reach a dry state, so that the dehumidification module 100 recovers to an unsaturated state.

In addition, the heat source 200 is opened in the desorption state, the dehumidification is rapid, and the rapid dehumidification of the room can be realized. Can be set as a function of strong dehumidification or rapid dehumidification.

Referring to fig. 6, the air exchange state of the bath heater or the air exchange state of the dehumidifier is shown.

When ventilation is required, the air source 400 is operated and the dehumidification module 100 and the heat source 200 are turned off. The third damper 311 closes the inner outlet 302 and opens the main duct 320. The first damper 310 opens the second outlet 304 and closes the first outlet 303. The air source 400 discharges the indoor air flow to the outside through the second air outlet 304, and performs ventilation.

Referring to fig. 7, in the third embodiment, unlike the second embodiment, the main duct 320 is used in common for the dehumidification operation, the desorption operation, and the ventilation operation in the second embodiment, and the ventilation operation does not require the dehumidification module 100 to be involved, and instead, the dehumidification module 100 reduces the air output in the ventilation operation. Therefore, an acceleration air duct 322 is added, one end of the acceleration air duct 322 is connected to the main air duct 320, the connection position is located on the air flow path between the heat source 200 and the adsorption structure 101, that is, the upstream position of the adsorption structure 101, and the other end is communicated with the secondary air duct 321, or directly connected to the second air outlet 304.

Further, a second damper 312 is disposed on the main air duct 320 or the acceleration air duct 322, or at the connection between the main air duct 320 and the acceleration air duct 322, and the second damper 312 has a third position for closing the acceleration air duct 322 and opening the main air duct 320, and a fourth position for opening the acceleration air duct 322 and closing the main air duct 320.

Referring to fig. 7, in a state where the acceleration duct 322 is provided, the third damper 311 closes the inner outlet 302 and opens the main duct 320 during dehumidification according to the dehumidification principle. The second damper 312 opens the main duct 320 and closes the acceleration duct 322. The first damper 310 opens the first outlet port 303 and closes the second outlet port 304. The fan assembly and the dehumidification module 100 are started, moisture enters from the air inlet 301, passes through the fan assembly, the heat source 200 and passes through the dehumidification module 100, and at the moment, the heat source 200 is not started. Realize the air at indoor circulation, indoor air current blows the moisture of room bottom from the air outlet air-out, plays the effect of even dehumidification, wholly reduces room humidity. After passing through the dehumidification module 100, the indoor air is dehumidified by the dehumidification module 100.

Then the dehumidification state is operated for a certain time, the time is determined according to the dehumidification performance of the dehumidification module 100, and the dehumidification module 100 is switched to the desorption state after reaching the saturation state.

In the desorption state, referring to fig. 8, the third damper 311 closes the inner outlet 302 and opens the main duct 320. The second damper 312 opens the main duct 320 and closes the acceleration duct 322. The first damper 310 opens the second outlet 304 and closes the first outlet 303.

At this time, the heat source 200 and the air source 400 are started, so that the temperature of the air flow passing through the heat source 200 is increased to 40-50 ℃, and the hot air is driven by the air source 400 to rapidly take away the moisture absorbed in the dehumidification module 100 through the dehumidification module 100 and is discharged to the outside through the second air outlet 304. The desorption state also lasts for a certain time to allow the dehumidification module 100 to reach a dry state, so that the dehumidification module 100 recovers to an unsaturated state.

In addition, the heat source 200 is opened in the desorption state, so that the dehumidification is fast, and the room can be dehumidified fast. Can be set as a function of strong dehumidification or rapid dehumidification.

Referring to fig. 9, the air exchange state of the bathroom heater or the air exchange state of the dehumidifier is shown.

When ventilation is required, the air source 400 is operated and the dehumidification module 100 and the heat source 200 are turned off. The third damper 311 closes the inner outlet 302 and opens the main duct 320. The second damper 312 closes the main duct 320 and opens the acceleration duct 322. The first damper 310 opens the second outlet vent 304 and closes the first outlet vent 303. The air source 400 discharges the indoor air flow to the outside through the second air outlet 304, and performs ventilation.

The above-mentioned embodiments are merely illustrative and not restrictive, and those skilled in the art can modify the embodiments without inventive contribution as required after reading this specification, but only fall within the scope of the claims of the present invention.

Claims (14)

1. A dehumidification module, comprising:

having a dehumidification treatment zone adapted for the passage of an air stream;

and an adsorption structure (101) located on the dehumidification treatment area and having a porous substrate structure (104) and/or a porous honeycomb structure (103) through which the gas flow passes.

2. The dehumidification module of claim 1, wherein: the adsorption structure further comprises an adsorption material arranged at least one position or at least one layer of the structure surface of the adsorption structure (101).

3. The dehumidification module of claim 2, wherein: the adsorbing material is silica gel.

4. The dehumidification module of claim 1, wherein: further comprising a heat source (200) adapted to provide heat to the adsorption structure (101).

5. Dehumidification module according to claim 4, wherein the heat source (200):

is positioned in the dehumidification treatment area and transfers heat to the adsorption structure (101);

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

is located upstream of the dehumidification treatment zone and transfers heat to the air flow passing through the adsorption structure (101).

6. Dehumidification plant, characterized in that it comprises at least a dehumidification module (100) according to any one of claims 1 to 5.

7. A dehumidifying device as claimed in claim 6 further comprising:

the air duct assembly (300) is provided with an air inlet (301) and a first air outlet (303);

a wind source (400) adapted to output a flowing airflow to the air duct assembly (300).

8. The dehumidification apparatus according to claim 7, further comprising:

the second air outlet (304) is arranged on the air duct assembly (300);

-a damper structure for closing the second outlet opening (304) or the first outlet opening (303).

9. A dehumidifying device as claimed in claim 8, wherein: the damper structure includes:

a first damper (310), the first damper (310) having a first position closing the second outlet vent (304) and opening the first outlet vent (303), and a second position opening the second outlet vent (304) and closing the first outlet vent (303).

10. A dehumidifying device as claimed in claim 9, wherein: the air duct assembly (300):

one end of the main air duct (320) is communicated with the air source (400), and the other end of the main air duct is communicated with the first air outlet (303);

one end of the secondary air duct (321) is connected to the main air duct (320) and is positioned at the downstream position of the adsorption structure (101), and the other end of the secondary air duct is communicated with the second air outlet (304);

the first air door (310) is arranged on the main air duct (320) or the secondary air duct (321) or the connecting position of the main air duct (320) and the secondary air duct (321).

11. A dehumidifying device as claimed in claim 10, wherein: further comprising: one end of the acceleration air duct (322) is connected to the main air duct (320) and is positioned on an air flow path between the heat source (200) and the adsorption structure (101), and the other end of the acceleration air duct is communicated with the second air outlet (304) or the secondary air duct (321);

the damper structure further includes:

a second damper (312), the second damper (312) having a third position closing the acceleration air duct (322) and opening the main air duct (320), and a fourth position opening the acceleration air duct (322) and closing the main air duct (320).

12. A dehumidifying device as claimed in any one of claims 8 to 11, wherein: the air inlet (301) or the air duct assembly (300) is internally provided with a temperature sensor (501) at a position close to the air inlet (301), and the air source (400), the heat source (200) and the air door structure are in communication connection with the temperature sensor (501).

13. A bathroom heater, which is characterized in that; with a dehumidifying device according to any one of claims 7 to 11.

14. The super bath of claim 13, further comprising at least:

the air duct assembly (300) comprises a machine shell (500), an air inlet (301) and an air outlet (302), wherein the machine shell (500) is a part of the air duct assembly (300) and is provided with an inner air outlet (302) facing indoors, and the air inlet (301) is positioned on the machine shell (500) and is arranged facing indoors;

the heat source (200) is arranged on a path of the air source (400) and the inner air outlet (302);

a third damper (311), the third damper (311) having a fifth position closing the inner air outlet (302) and opening the main air duct (320), and a sixth position opening the inner air outlet (302) and closing the main air duct (320).

Images