WO2022252668A1 - 无水加湿装置、空调器 - Google Patents
无水加湿装置、空调器 Download PDFInfo
- Publication number
- WO2022252668A1 WO2022252668A1 PCT/CN2022/074857 CN2022074857W WO2022252668A1 WO 2022252668 A1 WO2022252668 A1 WO 2022252668A1 CN 2022074857 W CN2022074857 W CN 2022074857W WO 2022252668 A1 WO2022252668 A1 WO 2022252668A1
- Authority
- WO
- WIPO (PCT)
- Prior art keywords
- moisture absorption
- absorption module
- moisture
- regeneration
- module
- Prior art date
Links
- 238000010521 absorption reaction Methods 0.000 claims abstract description 244
- 230000008929 regeneration Effects 0.000 claims abstract description 82
- 238000011069 regeneration method Methods 0.000 claims abstract description 82
- 238000010438 heat treatment Methods 0.000 claims abstract description 62
- 230000007246 mechanism Effects 0.000 claims abstract description 57
- 238000002955 isolation Methods 0.000 claims abstract description 26
- 238000009434 installation Methods 0.000 claims description 18
- XLYOFNOQVPJJNP-UHFFFAOYSA-N water Substances O XLYOFNOQVPJJNP-UHFFFAOYSA-N 0.000 description 13
- 230000000694 effects Effects 0.000 description 10
- 239000000463 material Substances 0.000 description 6
- 238000010586 diagram Methods 0.000 description 5
- 239000000428 dust Substances 0.000 description 4
- 230000001172 regenerating effect Effects 0.000 description 4
- 238000000034 method Methods 0.000 description 3
- 241000894006 Bacteria Species 0.000 description 2
- 230000009286 beneficial effect Effects 0.000 description 2
- 238000005524 ceramic coating Methods 0.000 description 2
- 239000012535 impurity Substances 0.000 description 2
- 239000012774 insulation material Substances 0.000 description 2
- 238000009423 ventilation Methods 0.000 description 2
- VYPSYNLAJGMNEJ-UHFFFAOYSA-N Silicium dioxide Chemical compound O=[Si]=O VYPSYNLAJGMNEJ-UHFFFAOYSA-N 0.000 description 1
- 230000002745 absorbent Effects 0.000 description 1
- 239000002250 absorbent Substances 0.000 description 1
- 239000011358 absorbing material Substances 0.000 description 1
- 238000004378 air conditioning Methods 0.000 description 1
- 230000000903 blocking effect Effects 0.000 description 1
- 210000000476 body water Anatomy 0.000 description 1
- 239000000919 ceramic Substances 0.000 description 1
- 238000007791 dehumidification Methods 0.000 description 1
- 230000008021 deposition Effects 0.000 description 1
- 238000005485 electric heating Methods 0.000 description 1
- 238000005516 engineering process Methods 0.000 description 1
- 239000011152 fibreglass Substances 0.000 description 1
- 230000036541 health Effects 0.000 description 1
- 239000012621 metal-organic framework Substances 0.000 description 1
- 230000004048 modification Effects 0.000 description 1
- 238000012986 modification Methods 0.000 description 1
- 239000002808 molecular sieve Substances 0.000 description 1
- 239000000843 powder Substances 0.000 description 1
- 230000008569 process Effects 0.000 description 1
- 208000023504 respiratory system disease Diseases 0.000 description 1
- 239000000741 silica gel Substances 0.000 description 1
- 229910002027 silica gel Inorganic materials 0.000 description 1
- 230000009759 skin aging Effects 0.000 description 1
- URGAHOPLAPQHLN-UHFFFAOYSA-N sodium aluminosilicate Chemical compound [Na+].[Al+3].[O-][Si]([O-])=O.[O-][Si]([O-])=O URGAHOPLAPQHLN-UHFFFAOYSA-N 0.000 description 1
Images
Classifications
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F24—HEATING; RANGES; VENTILATING
- F24F—AIR-CONDITIONING; AIR-HUMIDIFICATION; VENTILATION; USE OF AIR CURRENTS FOR SCREENING
- F24F1/00—Room units for air-conditioning, e.g. separate or self-contained units or units receiving primary air from a central station
- F24F1/06—Separate outdoor units, e.g. outdoor unit to be linked to a separate room comprising a compressor and a heat exchanger
- F24F1/46—Component arrangements in separate outdoor units
-
- E—FIXED CONSTRUCTIONS
- E03—WATER SUPPLY; SEWERAGE
- E03B—INSTALLATIONS OR METHODS FOR OBTAINING, COLLECTING, OR DISTRIBUTING WATER
- E03B3/00—Methods or installations for obtaining or collecting drinking water or tap water
- E03B3/28—Methods or installations for obtaining or collecting drinking water or tap water from humid air
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F24—HEATING; RANGES; VENTILATING
- F24F—AIR-CONDITIONING; AIR-HUMIDIFICATION; VENTILATION; USE OF AIR CURRENTS FOR SCREENING
- F24F1/00—Room units for air-conditioning, e.g. separate or self-contained units or units receiving primary air from a central station
- F24F1/0007—Indoor units, e.g. fan coil units
- F24F1/0087—Indoor units, e.g. fan coil units with humidification means
Definitions
- the present application relates to the technical field of household appliances, for example, to a waterless humidifying device and an air conditioner.
- the traditional method uses a humidifier for humidification, but the humidification range of the traditional humidifier is small and uneven, and it is easy to produce white powder.
- the humidifier tank is easy to scale and breed bacteria. It is colder to open windows for ventilation in winter, and the indoor air is not circulated, which is easy to cause bacteria to breed, which is not conducive to health.
- the embodiment of the present disclosure provides a device and an air conditioner for anhydrous humidification.
- the moisture absorption module is set as a cylindrical structure, so that both the inner wall and the outer wall can absorb moisture in the air at room temperature, improve the moisture absorption efficiency, and maintain moisture absorption. While reducing the horizontal space occupation, it can be better combined with the outdoor unit of the air conditioner.
- the anhydrous humidification device includes: a moisture absorption module, an isolation component and a heating mechanism.
- the moisture absorption module is a cylindrical structure, and it can absorb moisture in the normal temperature airflow, and can release moisture after being heated;
- the isolation component is arranged along the axial direction of the moisture absorption module, and divides the moisture absorption module into a moisture absorption part and a regeneration unit along its circumference. part;
- the heating mechanism is connected with the isolation component and is set on one side of the regeneration part.
- the air conditioner includes: the above-mentioned anhydrous humidifying device.
- the moisture absorption module has a cylindrical structure, which can increase the contact area between the moisture absorption module and the air, and improve the moisture absorption efficiency of the moisture absorption module in the normal temperature air flow. Absorb moisture in normal temperature air to increase the moisture absorption efficiency of the moisture absorption module.
- the heating mechanism is connected with the isolation component and installed on one side of the regeneration part. After the moisture absorption module absorbs moisture, the moisture absorbed by the moisture absorption module is heated by the heating mechanism. The absorbed water is heated to become gaseous water vapor, and flows into the room through the regeneration part to humidify the room, so as to achieve the effect of anhydrous humidification.
- the moisture absorption module is set in a cylindrical structure so that both the inner and outer walls can be kept at room temperature. Absorbs moisture in the air, improves the moisture absorption efficiency, can reduce the horizontal space occupation while maintaining the moisture absorption area, and can be better combined with the outdoor unit of the air conditioner.
- Fig. 1 is a schematic structural diagram of a waterless humidifying device provided by an embodiment of the present disclosure
- Fig. 2 is a top view of a waterless humidifying device provided by an embodiment of the present disclosure
- FIG. 3 is a schematic structural diagram of a fixing bracket provided by an embodiment of the present disclosure.
- Fig. 4 is an exploded schematic diagram of a driving mechanism and a fan provided by an embodiment of the present disclosure
- Fig. 5 is a schematic structural diagram of an air conditioner provided by an embodiment of the present disclosure.
- Fig. 6 is a schematic structural diagram of another air conditioner provided by an embodiment of the present disclosure.
- Fig. 7 is a top view of an air conditioner provided by an embodiment of the present disclosure.
- 100 moisture absorption module; 101, moisture absorption part; 102, regeneration part; 103, regeneration channel; 104, moisture absorption channel; 105, fixed bracket; 106, ring part; 200, isolation component; 201, built-in part; 203, heating installation area; 204, first baffle part; 205, second baffle part; 300, heating mechanism; 400, driving mechanism; 401, driving motor; 402, gear; 403, ring gear; 404, Fan; 500, outdoor unit shell; 501, compressor compartment; 502, compressor; 503, main body; 504, cover plate; 505, opening; 506, first vent; 507, isolation plate; 508, second Air vent; 509, filter grille.
- orientations or positional relationships indicated by the terms “upper”, “lower”, “inner”, “middle”, “outer”, “front”, “rear” etc. are based on the orientations or positional relationships shown in the drawings. Positional relationship. These terms are mainly used to better describe the embodiments of the present disclosure and their implementations, and are not used to limit that the indicated devices, elements or components must have a specific orientation, or be constructed and operated in a specific orientation. Moreover, some of the above terms may be used to indicate other meanings besides orientation or positional relationship, for example, the term “upper” may also be used to indicate a certain attachment relationship or connection relationship in some cases. Those skilled in the art can understand the specific meanings of these terms in the embodiments of the present disclosure according to specific situations.
- connection can be a fixed connection, a detachable connection, or an integral structure; it can be a mechanical connection, or an electrical connection; it can be a direct connection, or an indirect connection through an intermediary, or two devices, components or Internal connectivity between components.
- A/B means: A or B.
- a and/or B means: A or B, or, A and B, these three relationships.
- an embodiment of the present disclosure provides a waterless humidifier comprising: a moisture absorption module 100 , an isolation assembly 200 and a heating mechanism 300 .
- the moisture absorption module 100 is a cylindrical structure, and it can absorb moisture in the normal temperature airflow, and can release moisture after being heated;
- the isolation assembly 200 is arranged along the axial direction of the moisture absorption module 100, and divides the moisture absorption module 100 along its circumference into The moisture absorbing part 101 and the regenerating part 102 ;
- the heating mechanism 300 is connected with the isolation assembly 200 and arranged on one side of the regenerating part 102 .
- the moisture absorption module 100 has a cylindrical structure, which can increase the contact area between the moisture absorption module 100 and the air, and improve the moisture absorption efficiency of the moisture absorption module 100 in the normal temperature airflow.
- the inner wall of the moisture absorption module 100 can also absorb the moisture in the normal temperature air, so as to increase the moisture absorption efficiency of the moisture absorption module 100.
- the heating mechanism 300 is connected with the isolation assembly 200, and is arranged on one side of the regeneration part 102. After the moisture absorption module 100 completes the moisture absorption, it passes The heating mechanism 300 heats the moisture absorbed by the moisture absorption module 100, so that the absorbed moisture is heated to become gaseous water vapor, and flows into the room to humidify the room, so as to achieve the effect of anhydrous humidification.
- the moisture absorption module 100 is set in a circular shape
- the cylinder structure enables both the inner wall and the outer wall to absorb moisture in normal temperature air, improves the moisture absorption efficiency, can reduce the horizontal space occupation while maintaining the moisture absorption area, and can be better combined with the outdoor unit of the air conditioner.
- the moisture absorption module 100 includes: a base and moisture absorption materials.
- the base is cylindrical; moisture-absorbing material is filled in the base.
- the moisture absorption material is filled in the base, and the moisture in the normal temperature airflow is filled in when the normal temperature airflow passes through the base.
- the hygroscopic material in the base absorbs or releases the absorbed moisture in the hygroscopic material into the airflow, so as to better humidify the room.
- the base consists of fiberglass or ceramic fibres.
- the structure of the base is stable and lightweight, which facilitates the rotation of the moisture absorption module 100 and improves the stability of the moisture absorption module 100 .
- the hygroscopic material includes: one or more of silica gel, MOF, and molecular sieve.
- one or more of the above materials can efficiently absorb moisture in the airflow at normal temperature, and can efficiently release moisture under heating.
- the isolation assembly 200 includes: an internal part 201 and an external part 202 .
- the built-in part 201 is arranged inside the cylindrical structure of the moisture absorption module 100, and divides the interior of the cylindrical structure of the moisture absorption module 100 into the regeneration channel 103 and the moisture absorption channel 104; A movable gap is defined therebetween, and the moisture absorption module 100 can rotate through the movable gap.
- the moisture absorption module 100 is separated into the regeneration channel 103 and the moisture absorption channel 104 by the isolation component 200, and the interior of the cylindrical structure of the moisture absorption module 100 is separated by the built-in part 201, so that the interior can be divided into a moisture absorption zone and a regeneration zone, Both the inner wall and the outer wall of the moisture absorption module 100 can absorb moisture from the normal temperature airflow, improve the moisture absorption efficiency of the moisture absorption module 100, and define a movable gap between the inner part 201 and the outer part 202, and the moisture absorbent module 100 can be carried out in the movable gap.
- the moisture absorption module 100 Rotate, when the moisture absorption module 100 is working, the normal temperature airflow flows through the outer surface of the moisture absorption module 100 and the inner surface of the moisture absorption module 100 located in the moisture absorption channel 104, so that the moisture absorption module 100 absorbs moisture, and through the rotation of the moisture absorption module 100, the absorbed moisture
- the last moisture absorption module 100 rotates into the regeneration channel 103, and then it is heated by the heating mechanism 300 to regenerate the moisture absorbed on the surface of the moisture absorption module 100 to form gaseous water vapor, which flows into the room through the regeneration channel 103 and passes through the built-in part 201
- the moisture absorption module 100 is reasonably partitioned to maintain a sufficient moisture absorption area of the moisture absorption module 100, thereby improving the effect of anhydrous humidification.
- the isolation component 200 is made of thermal insulation material.
- the isolation assembly 200 is set as a thermal insulation material, which reduces heat loss in the regeneration channel 103, better heats the regeneration part 102, and improves the efficiency of moisture regeneration.
- a heating installation area 203 is defined between the external part 202 and the outer wall of the moisture absorption module 100 , the heating installation area 203 corresponds to the position of the regeneration channel 103 , and the heating mechanism 300 is arranged in the heating installation area 203 . In this way, the heating installation area 203 is set at a position corresponding to the regeneration channel 103.
- the moisture absorption module 100 can absorb moisture from the normal temperature airflow, and the moisture absorption module 100 can be rotated so that the moisture absorption module 100 enters regeneration.
- the moisture absorption module 100 entering the regeneration passage 103 is heated by the heating mechanism 300 arranged in the heating installation area 203, so that the absorbed moisture is regenerated to form gaseous water vapor, which flows into the regeneration passage 103 Indoors, humidify the room, and install the heating mechanism 300 at a position corresponding to the regeneration channel 103, so that the heating mechanism 300 can heat the regeneration channel 103 in real time, improve the efficiency of moisture regeneration into gaseous water vapor, and further improve the overall air-free Efficiency of water humidification.
- one side of the heating mechanism 300 is open, so that the air at normal temperature enters the regeneration channel 103 through the heating mechanism 300 , or one side of the heating mechanism 300 is closed, and the air at normal temperature enters the regeneration channel 103 through one end of the cylindrical structure of the moisture absorption module 100 .
- the air flow first passes through the heating mechanism 300 and then enters the regeneration channel 103, the heat released by the heating mechanism 300 can heat the air flow to form a high-temperature air flow, and then make the high-temperature air flow pass through the moisture absorption module 100 to improve the moisture regeneration efficiency of the moisture absorption module 100, and Enlarging the air inlet area can blow the regeneration part 102 of the moisture absorption module 100 more comprehensively, so that the moisture can be better released from the moisture absorption module 100, and the humidification effect can be improved; the airflow enters the regeneration channel 103 through one end of the cylindrical structure, so that The regeneration channel 103 and the moisture absorption channel 104 can simultaneously enter the air from one end of the cylindrical structure, simplify the air intake structure, and the air intake is more concentrated, easy to realize, and the demand for the air intake position is small, which is beneficial to the outdoor of integrated installation and air conditioning inside the plane.
- one side of the heating mechanism 300 is open, so that the normal-temperature airflow can enter the regeneration passage 103 through the heating mechanism 300 , and the normal-temperature airflow can also enter the regeneration passage 103 from one end of the cylindrical structure of the moisture absorption module 100 .
- two forms of air intake to the regeneration channel 103 are adopted at the same time to maintain sufficient air volume, better promote the release of moisture from the regeneration part 102 of the moisture absorption module 100, and improve the humidification efficiency.
- a ceramic coating is provided on the side of the external part 202 close to the heating installation area 203 .
- a ceramic coating is provided on the side of the external part 202 near the heating installation area 203. layer, reducing heat damage to the external part 202 and improving its service life.
- the inner part 201 is a V-shaped structure, and the apex of the V-shaped structure is located on the axis of the moisture absorption module 100, and the outer part 202 includes a first baffle part 204 and a second baffle part 205, wherein the first baffle part The plate part 204 is located on the same plane as one side of the V-shaped structure, and the second baffle part 205 is located on the same plane as the other side of the V-shaped structure.
- the built-in part 201 is set to a V-shaped structure, and the regeneration channel 103 and the moisture absorption channel 104 can be divided into fan-shaped structures, and the flow surface ratio of the regeneration channel 103 and the moisture absorption channel 104 can be controlled more reasonably.
- first baffle part 204 and a second baffle part 205 There is a first baffle part 204 and a second baffle part 205, and the first baffle part 204 and the second baffle part 205 are located on the same plane as the two ends of the V-shaped structure, so that the entire isolation assembly 200 is integrated
- the V-shape is better for isolating the regenerative channel 103.
- the heating mechanism 300 is disposed between the first baffle part 204 and the second baffle part 205 .
- the heating mechanism 300 is arranged between the first baffle part 204 and the second baffle part 205, and the heat generated when the heating mechanism 300 works can be reduced by the first baffle part 204 and the second baffle part 205. It is better to heat the moisture absorption module 100, improve the efficiency of moisture regeneration into gaseous water vapor, and then improve the humidification efficiency.
- the angle of the V-shaped vertex is greater than or equal to 90 degrees and less than or equal to 120 degrees.
- the speed of moisture regeneration on the moisture absorption module 100 is greater than the speed of moisture absorption by the moisture absorption module 100.
- Setting the area of the moisture absorption channel 104 to be larger than the area of the regeneration channel 103 can increase the contact area between the moisture absorption module 100 and the normal temperature airflow, thereby improving The moisture absorption effect of the moisture absorption part 101 of the moisture absorption module 100 .
- the V-shaped top angle is 120 degrees
- the flow area of the regeneration channel 103 is one-third of the flow area of the humidification channel.
- the moisture absorption module 100 when the moisture absorption module 100 rotates, it first passes through the first baffle part 204 and then passes through the second baffle part 205 , and the distance between the heating mechanism 300 and the first baffle part 204 is smaller than the distance between the heating mechanism 300 and the second baffle part 205 . In this way, when the moisture absorption module 100 rotates to the regeneration channel 103, since the heating mechanism 300 is closer to the first baffle part 204, the moisture absorption module 100 can be quickly heated to make it quickly release moisture.
- the heating effect of the heating mechanism 300 on the moisture absorption module 100 is reduced at this time, which can reduce the temperature of the moisture absorption module 100 itself, and can quickly cool down after re-entering the moisture absorption channel 104, which is beneficial for the moisture absorption module 100 to continue to cool to normal temperature.
- the moisture in the airflow is absorbed to improve the moisture absorption efficiency of the moisture absorption module 100 .
- the heating mechanism 300 is an arc structure, the radian of which is the same as that of the outer wall of the moisture absorption module 100 , and is arranged parallel to one side of the outer wall of the moisture absorption module 100 .
- the curvature of the heating mechanism 300 is the same as the curvature of the outer wall of the moisture absorption module 100, so that the heating mechanism 300 can better fit the moisture absorption module 100, keep a uniform distance from the moisture absorption module 100, and more evenly heat the moisture absorption module 100. Heating is performed to improve heating efficiency and improve the efficiency of moisture regeneration.
- the heating mechanism 300 may adopt a common electric heating structure.
- the anhydrous humidifying device further includes: a fixing bracket 105 .
- the fixing bracket 105 is provided with a ring portion 106 , the moisture absorption module 100 is connected to the ring portion 106 in rotation, and the isolation assembly 200 is fixedly connected to the fixing bracket 105 .
- the isolation assembly 200 and the moisture absorption module 100 are supported and fixed by the fixing bracket 105, the stability of the overall structure is maintained, and the moisture absorption module 100 can rotate stably and smoothly, and the moisture absorption module 100 containing moisture is rotated into the regeneration channel 103,
- the moisture absorption module 100 entering the regeneration channel 103 is heated by the heating mechanism 300 to regenerate the moisture to form gaseous water vapor, which enters the room through the humidifying component to humidify the room.
- annular parts 106 which are sleeved on both ends of the moisture absorption module 100 respectively.
- the two ends of the moisture absorption module 100 are respectively provided with a ring part 106, which can better fix and support the moisture absorption module 100, make the moisture absorption module 100 more stable during the rotation process, and reduce shaking.
- both ends of the moisture absorption module 100 are provided with connection bearings, and are rotatably connected to the ring portion 106 through the connection bearings.
- the connection bearings can fix the moisture absorption module 100 and improve the rotation stability of the moisture absorption module 100 when it rotates.
- the anhydrous humidifier further includes: a driving mechanism 400 .
- the driving mechanism 400 is connected with the moisture absorption module 100 and can drive the moisture absorption module 100 to rotate along its axis. In this way, the drive mechanism 400 is connected to the moisture absorption module 100, so that the drive mechanism 400 can drive the moisture absorption module 100 to rotate along its axis.
- the moisture absorption part 101 of the moisture absorption module 100 absorbs the moisture in the normal temperature airflow
- the moisture absorption module 100 is rotated by the driving mechanism 400, and the moisture absorption module 100 containing moisture is rotated into the regeneration channel 103, and the moisture absorption module 100 entering the regeneration channel 103 is heated by the heating mechanism 300, so that the moisture on the moisture absorption module 100 is regenerated And enter the regeneration channel 103, and then enter the room through the regeneration channel 103, humidify the room, connect the moisture absorption module 100 through the driving mechanism 400, drive the moisture absorption module 100 to rotate, and make the moisture absorption module 100 continue to absorb moisture and then enter the regeneration channel 103 to release moisture , can be uninterrupted for humidification operation.
- the driving mechanism 400 includes: a driving motor 401 , a gear 402 and a ring tooth 403 .
- the driving motor 401 is arranged on one side of the moisture absorption module 100; the gear 402 is arranged on the output end of the driving motor 401; In this way, through the gear 402 meshing with the ring gear 403, the driving motor 401 can drive the ring gear 403 to rotate, and then drive the moisture absorption module 100 to rotate, so that the moisture absorption part 101 of the moisture absorption module 100 can rotate into the regeneration channel 103, and through heating
- the mechanism 300 regenerates the absorbed moisture to form gaseous water vapor to humidify the room.
- the driving motor 401 By setting the driving motor 401, the moisture regeneration efficiency of the regeneration part 102 of the moisture absorption module 100 can be improved, thereby improving the overall humidification efficiency.
- the fan 404 is arranged at one end of the cylindrical structure of the moisture absorption module 100 .
- the blower 404 is arranged at one end of the moisture absorption module 100, the blower 404 can suck the ambient temperature airflow into the moisture absorption module 100, and at the same time generate airflow in the moisture absorption channel 104 and the regeneration channel 103, the airflow can better contact the moisture absorption module 100,
- the moisture absorption efficiency of the moisture absorption part 101 of the moisture absorption module 100 and the moisture regeneration efficiency of the regeneration part 102 of the moisture absorption module 100 are improved, thereby improving the overall humidification efficiency.
- the anhydrous humidifying device further includes: the air intake end of the fan 404 communicates with the interior of the moisture absorption module 100 .
- the air intake end of the fan 404 communicates with the interior of the moisture absorption module 100 .
- a negative pressure can be generated inside the moisture absorption module 100, and the external airflow can be sucked into the moisture absorption channel 104 and the regeneration channel 103, so that the airflow can pass through the moisture absorption module
- the outer wall of 100 passes through the moisture absorption module 100 and enters the regeneration channel 103 and the moisture absorption channel 104, and then enters the regeneration channel 103 and the moisture absorption channel 104 from the other end of the moisture absorption module 100, so that the airflow can better contact the moisture absorption module 100, thereby improving moisture absorption.
- the moisture absorption efficiency of the moisture absorption part 101 of the module 100 and the moisture regeneration efficiency of the regeneration part 102 of the moisture absorption module 100 further improve the overall humidification efficiency.
- multiple air inlets are provided on the surface of the gear 402 .
- the air inlet is provided on the surface of the gear 402, so that air at normal temperature can enter the moisture absorption module 100 smoothly through the air inlet, prevent the gear 402 from blocking the air flow, improve the ventilation effect, and further improve the dehumidification efficiency.
- an embodiment of the present disclosure provides an air conditioner including the above-mentioned anhydrous humidifying device.
- the anhydrous humidification device is installed in the air conditioner, and cooperates with the air conditioner to adjust the indoor temperature and humidity at the same time, and the moisture absorption module of the above anhydrous humidification device 100 is a cylindrical structure, which can increase the contact area between the moisture absorption module 100 and the air, and improve the moisture absorption efficiency of the moisture absorption module 100 in the normal temperature air flow.
- the inner wall of 100 can also absorb the moisture in the air at normal temperature to increase the moisture absorption efficiency of the moisture absorption module 100.
- the heating mechanism 300 is connected with the isolation assembly 200 and is arranged on one side of the regeneration part 102.
- the heating mechanism 300 300 heats the moisture absorption module 100 so that the absorbed water is heated to become gaseous water vapor, and flows into the room to humidify the room, so as to achieve the effect of anhydrous humidification.
- the moisture absorption module 100 is set as a cylindrical structure, so that the inner wall Both the outer wall and the outer wall can absorb moisture in the air at normal temperature, improve the moisture absorption efficiency, reduce the horizontal space occupation while maintaining the moisture absorption area, and can be better combined with the outdoor unit of the air conditioner.
- the air conditioner includes: an outdoor unit casing 500 .
- the outdoor unit casing 500 is provided with a compressor compartment 501 inside, and a compressor 502 is arranged under the interior of the compressor compartment 501.
- a part of the moisture absorption module 100 protrudes from the outdoor unit casing 500 , or the moisture absorption module 100 is entirely disposed inside the outdoor unit casing 500 .
- the anhydrous humidifying device cooperates with the compressor 502. While the compressor 502 cools the room, the anhydrous humidifying device humidifies the room to prevent the room from being too dry.
- the moisture absorption module 100 extends out of the outdoor unit casing 500 , can increase the contact area between the moisture absorption module 100 and the normal temperature airflow, improve its moisture absorption efficiency, and then improve the overall humidification effect, and occupy less space in the press chamber 501; It can better protect the moisture absorption module 100, prevent the moisture absorption module 100 from being damaged by force, and reduce the dust deposition and other problems caused by the direct exposure of the moisture absorption module 100, and the overall integrity of the outdoor unit of the air conditioner can be better maintained.
- the heating mechanism 300 and the regenerating part 102 of the moisture absorption module 100 are placed in the casing 500 of the outdoor machine, and the moisture absorption part 101 of the moisture absorption module 100 extends out of the casing 500 of the outdoor machine.
- setting the heating mechanism 300 and the regeneration part 102 of the moisture absorption module 100 in the outdoor unit housing 500 can reduce the heat loss of the heating mechanism 300, better heat the regeneration part 102 of the moisture absorption module 100, and improve the performance of the moisture absorption module 100.
- the moisture regeneration efficiency of the regeneration part 102 is improved, and the moisture absorption part 101 of the moisture absorption module 100 is extended out of the outdoor unit casing 500, so that the regeneration part 102 of the moisture absorption module 100 can be in better contact with the outdoor normal temperature airflow, so that it can be more fully
- the moisture in the outdoor normal-temperature airflow can be absorbed to improve the moisture absorption efficiency of the regeneration part 102 of the moisture absorption module 100, and further improve the overall humidification efficiency of the anhydrous humidifier.
- the top angle of the V-shaped structure of the built-in part 201 is 90 degrees, and the two sides of the V-shaped structure overlap with two adjacent sides of the outdoor unit housing 500 .
- the moisture absorption part 101 and the entire moisture absorption passage 104 of the moisture absorption module 100 can be better placed outside the outdoor unit casing 500, and the regeneration part 102 and the entire regeneration passage 103 of the moisture absorption module 100 can be placed outside the outdoor unit casing 500.
- the inner side, and the use of the outdoor unit casing 500 can better separate the moisture absorption channel 104 and the regeneration channel 103 to reduce the mutual influence between the two.
- the outdoor unit housing 500 is provided with an installation groove matching the thickness of the moisture absorption module 100 .
- the moisture absorption module 100 passes through the outdoor machine casing 500 through the installation slot, and the normal rotation of the moisture absorption module 100 can be maintained, so that the non-water humidifying device and the outdoor machine casing 500 can be installed in combination.
- the outdoor unit casing 500 includes a main body 503 and a cover plate 504, the main body 503 has an upward opening 505, the cover plate 504 can cover the opening 505, and the installation groove communicates with the edge of the main body 503 provided with the opening 505 .
- the moisture absorption module 100 when installed, the moisture absorption module 100 can be inserted into the installation groove from the edge of the opening 505, and the built-in part 201 is fixedly connected with the outdoor unit casing 500, and then the cover plate 504 is covered on the opening 505, It is more convenient to install the anhydrous humidifier and the outdoor unit housing 500 in combination.
- the outdoor unit casing 500 is provided with a first vent 506 corresponding to the regeneration channel 103 .
- the air flow can flow into the outdoor unit casing 500 through the first vent 506 and enter the regeneration channel 103, so that an air flow is generated in the regeneration channel 103, and the regenerated moisture is taken away from the regeneration channel 103 and discharged into the room, which is better for Humidify indoors.
- the compressor chamber 501 is located between the compressor 502 and the anhydrous humidification device with an isolation plate 507 .
- the compressor 502 can be better protected, preventing the dust, foreign matter and moisture entering through the first vent 506 from affecting the normal operation of the compressor 502, and maintaining the overall stability of the compressor 502.
- the anhydrous humidifier is arranged in the outdoor unit housing 500, and the outdoor unit housing 500 is provided with a first vent 506 at a position corresponding to the regeneration channel 103, and a second vent 508 is provided at a position corresponding to the moisture absorption channel 104. .
- the airflow outside the outdoor unit casing 500 can flow into the anhydrous humidifier through the air holes, and absorb the moisture in the normal temperature airflow through the moisture absorption part 101 of the moisture absorption module 100, and release the moisture through the regeneration part 102 of the moisture absorption module 100.
- the first vent 506 and the second vent 508 are provided to better allow the airflow outside the outdoor unit casing 500 to enter the outdoor unit casing 500 and contact the moisture absorption module 100 to improve the overall humidification efficiency .
- filter grills 509 are provided on the first vent 506 and the second vent 508 .
- some dust, impurities, etc. can be filtered, and the influence of dust, impurities, etc. deposited on the moisture absorption module 100 on the moisture absorption efficiency of the moisture absorption module 100 can be reduced.
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- Air Humidification (AREA)
Abstract
本申请涉及家用电器技术领域,公开一种无水加湿装置。包括:吸湿模块、隔离组件和加热机构。吸湿模块为圆筒结构,且其能够在常温气流中吸收水分,并经过加热后可释放水分;隔离组件沿吸湿模块的轴向设置,且并将吸湿模块沿其周向分隔为吸湿部和再生部;加热机构与隔离组件连接,且设置于再生部的一侧。在本申请中,将吸湿模块设置为圆筒结构,使其内壁和外壁都能够在常温空气中吸收水分,在提高吸湿效率,能够在保持吸湿面积的同时减小横向的空间占用,可更好的与空调器室外机进行结合。本申请还公开一种空调器。
Description
本申请基于申请号为202110620287.8、申请日为2021年6月3日的中国专利申请提出,并要求该中国专利申请的优先权,该中国专利申请的全部内容在此引入本申请作为参考。
本申请涉及家用电器技术领域,例如涉及一种无水加湿装置、空调器。
目前,我国大部分地区冬季干燥寒冷,空气含湿量低。室内空气含湿量低,会加速身体水分流失,加速皮肤衰老,引起呼吸道疾病。传统方式采用加湿器进行加湿,但传统加湿器的加湿范围小,不均匀,易产生白粉现象,加湿器水槽存在易结垢,滋生细菌等问题。冬季开窗换气较冷,室内空气不流通,易引起细菌滋生,不利于身体健康。
相关技术中存在一种采用吸湿转盘进行吸取室外的湿气对室内进行加湿的技术,但是吸湿转盘工作过程中需要气流的接触面积比较小,造成水分吸收能力较低,如需增加与气流的接触面积则需要扩大横向尺寸,造成安装空间占用过大。
因此,如何增加吸湿模块与气流的接触面积,并且降低其安装空间,成为本领域技术人员亟待解决的问题。
发明内容
为了对披露的实施例的一些方面有基本的理解,下面给出了简单的概括。所述概括不是泛泛评述,也不是要确定关键/重要组成元素或描绘这些实施例的保护范围,而是作为后面的详细说明的序言。
本公开实施例提供一种用于无水加湿的装置、空调器,将吸湿模块设置为圆筒结构,使其内壁和外壁都能够在常温空气中吸收水分,在提高吸湿效率,能够在保持吸湿面积的同时减小横向的空间占用,可更好的与空调器室外机进行结合。
在一些实施例中,所述无水加湿装置包括:吸湿模块、隔离组件和加热机构。吸湿模块为圆筒结构,且其能够在常温气流中吸收水分,并经过加热后可释放水分;隔离组件沿吸湿模块的轴向设置,且并将吸湿模块沿其周向分隔为吸湿部和再生部;加热机构 与隔离组件连接,且设置于再生部的一侧。
在一些实施例中,所述一种空调器包括:上述的无水加湿装置。
本公开实施例提供的用于无水加湿的装置、空调器,可以实现以下技术效果:
吸湿模块为圆筒结构,能够增大吸湿模块与空气的接触面积,提高吸湿模块在常温气流中的吸湿效率,通过设置隔离组件,将吸湿部和再生部进行隔离,使吸湿模块的内壁也能够吸收常温空气中的水分,增加吸湿模块的吸湿效率,加热机构与隔离组件连接,并设置于再生部的一侧,在吸湿模块吸湿完成后,通过加热机构对吸湿模块所吸收的水分进行加热,使其所吸收的水分加热成为气态水蒸气,并通过再生部流入室内,对室内进行加湿,从而达到无水加湿的效果,将吸湿模块设置为圆筒结构,使其内壁和外壁都能够在常温空气中吸收水分,在提高吸湿效率,能够在保持吸湿面积的同时减小横向的空间占用,可更好的与空调器室外机进行结合。
以上的总体描述和下文中的描述仅是示例性和解释性的,不用于限制本申请。
一个或多个实施例通过与之对应的附图进行示例性说明,这些示例性说明和附图并不构成对实施例的限定,附图中具有相同参考数字标号的元件示为类似的元件,附图不构成比例限制,并且其中:
图1是本公开实施例提供的一个无水加湿装置的结构示意图;
图2是本公开实施例提供的一个无水加湿装置的俯视图;
图3是本公开实施例提供的一个固定支架的结构示意图;
图4是本公开实施例提供的一个驱动机构以及风机的爆炸示意图;
图5是本公开实施例提供的一个空调器的结构示意图;
图6是本公开实施例提供的另一个空调器的结构示意图;
图7是本公开实施例提供的一个空调器的俯视图。
附图标记:
100、吸湿模块;101、吸湿部;102、再生部;103、再生通道;104、吸湿通道;105、固定支架;106、圆环部;200、隔离组件;201、内置部;202、外置部;203、加热安装区;204、第一挡板部;205、第二挡板部;300、加热机构;400、驱动机构;401、驱动电机;402、齿轮;403、环形齿;404、风机;500、室外机壳体;501、压机仓; 502、压缩机;503、主体部;504、盖板;505、开口;506、第一通风口;507、隔离板;508、第二通风口;509、过滤格栅。
为了能够更加详尽地了解本公开实施例的特点与技术内容,下面结合附图对本公开实施例的实现进行详细阐述,所附附图仅供参考说明之用,并非用来限定本公开实施例。在以下的技术描述中,为方便解释起见,通过多个细节以提供对所披露实施例的充分理解。然而,在没有这些细节的情况下,一个或多个实施例仍然可以实施。在其它情况下,为简化附图,熟知的结构和装置可以简化展示。
本公开实施例的说明书和权利要求书及上述附图中的术语“第一”、“第二”等是用于区别类似的对象,而不必用于描述特定的顺序或先后次序。应该理解这样使用的数据在适当情况下可以互换,以便这里描述的本公开实施例的实施例。此外,术语“包括”和“具有”以及他们的任何变形,意图在于覆盖不排他的包含。
本公开实施例中,术语“上”、“下”、“内”、“中”、“外”、“前”、“后”等指示的方位或位置关系为基于附图所示的方位或位置关系。这些术语主要是为了更好地描述本公开实施例及其实施例,并非用于限定所指示的装置、元件或组成部分必须具有特定方位,或以特定方位进行构造和操作。并且,上述部分术语除了可以用于表示方位或位置关系以外,还可能用于表示其他含义,例如术语“上”在某些情况下也可能用于表示某种依附关系或连接关系。对于本领域普通技术人员而言,可以根据具体情况理解这些术语在本公开实施例中的具体含义。
另外,术语“设置”、“连接”、“固定”应做广义理解。例如,“连接”可以是固定连接,可拆卸连接,或整体式构造;可以是机械连接,或电连接;可以是直接相连,或者是通过中间媒介间接相连,又或者是两个装置、元件或组成部分之间内部的连通。对于本领域普通技术人员而言,可以根据具体情况理解上述术语在本公开实施例中的具体含义。
除非另有说明,术语“多个”表示两个或两个以上。
本公开实施例中,字符“/”表示前后对象是一种“或”的关系。例如,A/B表示:A或B。
术语“和/或”是一种描述对象的关联关系,表示可以存在三种关系。例如,A和/或B,表示:A或B,或,A和B这三种关系。
需要说明的是,在不冲突的情况下,本公开实施例中的实施例及实施例中的特征可以相互组合。
结合图1-3所示,本公开实施例提供一种无水加湿装置包括:吸湿模块100、隔离组件200和加热机构300。吸湿模块100为圆筒结构,且其能够在常温气流中吸收水分,并经过加热后可释放水分;隔离组件200沿吸湿模块100的轴向设置,且并将吸湿模块100沿其周向分隔为吸湿部101和再生部102;加热机构300与隔离组件200连接,且设置于再生部102的一侧。
吸湿模块100为圆筒结构,能够增大吸湿模块100与空气的接触面积,提高吸湿模块100在常温气流中的吸湿效率,通过设置隔离组件200,将吸湿部101和再生部102进行隔离,使吸湿模块100的内壁也能够吸收常温空气中的水分,增加吸湿模块100的吸湿效率,加热机构300与隔离组件200连接,并设置于再生部102的一侧,在吸湿模块100吸湿完成后,通过加热机构300对吸湿模块100所吸收的水分进行加热,使其所吸收的水分加热成为气态水蒸气,并流入室内,对室内进行加湿,从而达到无水加湿的效果,将吸湿模块100设置为圆筒结构,使其内壁和外壁都能够在常温空气中吸收水分,在提高吸湿效率,能够在保持吸湿面积的同时减小横向的空间占用,可更好的与空调器室外机进行结合。
可选地,吸湿模块100包括:基座和吸湿材料。基座为圆柱体;吸湿材料填充在基座内。这样,通过设置基座,可提高吸湿模块100整体结构的稳定性,防止吸湿模块100的损坏,将吸湿材料填充在基座内,在常温气流穿过基座时常温气流中的水分被填充在基座内的吸湿材料吸收,或将吸湿材料中的吸收的水分释放带气流中,从而更好的对室内进行加湿。
可选地,基座由玻璃纤维或陶瓷纤维组成。这样,使基座的结构稳定且轻巧,便于吸湿模块100的旋转,提高了吸湿模块100的稳定性。
可选地,吸湿材料包括:硅胶、MOF、分子筛中的一个或多个。这样,上述材料中的一个或多个可在常温下高效的吸收气流中的水分,且在加热情况下可高效的释放水分。
可选地,隔离组件200包括:内置部201和外置部202。内置部201设置于吸湿模块100的圆筒结构内部,且将吸湿模块100的圆筒结构内部分隔出再生通道103和吸湿通道104;外置部202与内置部201对应设置,且与内置部201之间限定出活动间隙,吸湿模块100可穿过活动间隙旋转。这样,通过隔离组件200使吸湿模块100分隔出再 生通道103和吸湿通道104,并且通过内置部201在吸湿模块100的圆筒结构内部进行分隔,使其内部即可分为吸湿区和再生区,使吸湿模块100的内壁和外壁均能从常温气流中吸收水分,提高吸湿模块100的吸湿效率,在内置部201与外置部202之间限定出活动间隙,吸湿模块100可以在活动间隙内进行转动,在吸湿模块100工作时,常温气流流过吸湿模块100的外表面和吸湿模块100位于吸湿通道104部分的内表面,使吸湿模块100吸取水分,并通过吸湿模块100的旋转,将吸收水分后的吸湿模块100转动至再生通道103内,后通过加热机构300对其进行加热,使吸湿模块100表面所吸收的水分再生,形成气态水蒸气,通过再生通道103后流入室内,通过内置部201和外置部202的配合对吸湿模块100进行合理的分区,保持吸湿模块100有足够的吸湿面积,进而提高无水加湿的效果。
可选地,隔离组件200为保温材质。这样,将隔离组件200设置为保温材质,减少再生通道103内的热量流失,更好的对再生部102进行加热,提高水分再生的效率。
可选地,外置部202与吸湿模块100的外侧壁之间限定出加热安装区203,加热安装区203与再生通道103位置对应,加热机构300设置于加热安装区203内。这样,加热安装区203设置于与再生通道103对应的位置,在常温气流流经吸湿模块100时,吸湿模块100能够从常温气流中吸收水分,并通过吸湿模块100旋转,使吸湿模块100进入再生通道103内,后通过设置在加热安装区203内的加热机构300,对进入再生通道103内的吸湿模块100进行加热,使其所吸收的水分再生,形成气态水蒸气,并通过再生通道103流入室内,对室内进行加湿,将加热机构300设置在与再生通道103相对应的位置,能够使加热机构300实时对再生通道103进行加热,提高水分再生为气态水蒸气的效率,进而提高整体的无水加湿的效率。
可选地,加热机构300的一侧开放,使常温气流经过加热机构300进入再生通道103,或者加热机构300的一侧封闭,常温气流通过吸湿模块100的圆筒结构的一端进入再生通道103。这样,气流先经过加热机构300在进入再生通道103,可由加热机构300释放的热量对气流进行加热,形成高温气流,进而使高温气流穿过吸湿模块100,提高吸湿模块100的水分再生效率,并且扩大进风面积,可更全面的对吸湿模块100的再生部102进行吹拂,使水分更好的从吸湿模块100上释放出来,提高加湿效果;气流通过圆筒结构的一端进入再生通道103,使再生通道103和吸湿通道104可同步由圆筒结构的一端进风,简化进风结构,并且进风更集中,便于实现,且对进风位置的需求较小,有利于集成安装与空调的室外机内。
可选地,加热机构300的一侧开放,使常温气流经过加热机构300进入再生通道103的同时,常温气流也可由吸湿模块100的圆筒结构的一端进入再生通道103。这样,同时采用两种向再生通道103进风的形式,保持足够的风量,更好的促进吸湿模块100的再生部102释放水分,提高加湿效率。
可选地,外置部202靠近加热安装区203的一侧设有陶瓷涂层。这样,在加热机构300工作时,会产生大量热量,为防止热量过高对其附近的机构以及外置部202自身造成损坏,将外置部202靠近加热安装区203的一侧设有陶瓷涂层,减少热量对外置部202的损坏,提高其使用寿命。
可选地,内置部201为V形结构,且V形结构的顶角位于吸湿模块100的轴线上,外置部202包括第一挡板部204和第二挡板部205,其中第一挡板部204与V形结构的一侧边位于同一平面上,第二挡板部205与V形结构的另一侧边位于同一平面上。这样,将内置部201设置为V形结构,可将再生通道103和吸湿通道104均分割为扇形结构,可更合理的控制再生通道103和吸湿通道104的通流面比例,外置部202设有第一挡板部204和第二挡板部205,且第一挡板部204和第二挡板部205分别与V形结构的两端位于同一平面上,使整个隔离组件200呈一个整体的V形,更好的隔离出再生通道103。
可选地,加热机构300设置于第一挡板部204和第二挡板部205之间。这样,将加热机构300设置于第一挡板部204和第二挡板部205之间,通过第一挡板部204和第二挡板部205能够减少加热机构300工作时,所产生的热量散失,更好的对吸湿模块100进行加热,提高水分再生为气态水蒸气的效率,进而提高加湿效率。
可选地,V形顶角的角度为大于或等于90度,且小于或等于120度。这样,一般情况吸湿模块100上水分再生的速度大于吸湿模块100吸收水分的速度,将吸湿通道104的面积设置为大于再生通道103的面积,能够增加吸湿模块100与常温气流的接触面积,进而提高吸湿模块100的吸湿部101的吸湿效果。例如,V形顶角的角度为120度,则再生通道103的通流面积为加湿通道的通流面积的三分之一。
可选地,吸湿模块100旋转时先经过第一挡板部204再经过第二挡板部205,加热机构300距离第一挡板部204的距离小于其距离第二挡板部205的距离。这样,在吸湿模块100旋转至再生通道103时,由于加热机构300距离第一挡板部204较近,可快速对吸湿模块100进行加热,使其快速释放水分,当吸湿模块100旋转接近第二挡板部205的情况下,此时加热机构300对吸湿模块100的加热效果下降,可使吸湿模块100自身的温度下降,在重新进入吸湿通道104后能够快速降温,利于吸湿模块100继续对常温 气流内的水分进行吸收,提高吸湿模块100的吸湿效率。
可选地,加热机构300为弧形结构,其弧度与吸湿模块100外侧壁的弧度相同,且平行设置于吸湿模块100外侧壁的一侧。这样,加热机构300的弧度与吸湿模块100的外侧壁弧度相同,使加热机构300能够更好贴合吸湿模块100,保持与吸湿模块100之间的距离均匀,进而能够更均匀的对吸湿模块100进行加热,提高加热效率,提高水分再生的效率。
可以理解地,加热机构300采用普通的电加热结构即可。
可选地,无水加湿装置还包括:固定支架105。固定支架105设有圆环部106,吸湿模块100与圆环部106旋转连接,隔离组件200与固定支架105固定连接。这样,利用固定支架105对隔离组件200以及吸湿模块100进行支撑固定,保持整体结构的稳定性,且使吸湿模块100能够稳定顺畅的旋转,将含有水分的吸湿模块100旋转至再生通道103内,通过加热机构300对进入再生通道103内的吸湿模块100进行加热,使水分再生,形成气态水蒸气,并通过加湿组件进入室内,对室内进行加湿。
可选地,圆环部106设有两个,且分别套设于吸湿模块100的两端。这样,在吸湿模块100的两端分别设有一圆环部106,可更好的对吸湿模块100进行固定支撑,使吸湿模块100在转动过程中更加平稳,减少晃动。
可选地,吸湿模块100的两端均设有连接轴承,且通过连接轴承与圆环部106之间转动连接。这样,在吸湿模块100的两端通过连接轴承与圆环部106转动连接,连接轴承能够对吸湿模块100进行固定,同时能够在吸湿模块100选转时提高其转动的稳定性。
结合图4所示,在一些可选地实施例中,无水加湿装置还包括:驱动机构400。驱动机构400与吸湿模块100连接,能够驱动吸湿模块100沿其轴线旋转。这样,通过驱动机构400与吸湿模块100连接,使驱动机构400能够带动吸湿模块100沿其轴线进行旋转,在无水加湿装置进行工作时,吸湿模块100的吸湿部101吸收常温气流内的水分,通过驱动机构400使吸湿模块100进行转动,将含有水分的吸湿模块100旋转至再生通道103内,通过加热机构300对进入再生通道103内的吸湿模块100进行加热,使吸湿模块100上的水分再生并进入再生通道103,后通过再生通道103进入室内,对室内进行加湿,通过驱动机构400与吸湿模块100连接,驱动吸湿模块100进行转动,使吸湿模块100持续的吸湿后进入再生通道103释放水分,可不间断的进行加湿操作。
可选地,驱动机构400包括:驱动电机401、齿轮402和环形齿403。驱动电机401设置于吸湿模块100的一侧;齿轮402设置于驱动电机401的输出端上;环形齿403固 定设置于吸湿模块100的内壁上,且与齿轮402啮合。这样,通过齿轮402与环形齿403啮合,使驱动电机401能够带动环形齿403进行转动,进而带动吸湿模块100进行转动,使吸湿模块100的吸湿部101能够转动至再生通道103内,并通过加热机构300使其所吸收的水分再生,形成气态水蒸气,对室内进行加湿,通过设置驱动电机401,可提高吸湿模块100的再生部102的水分再生效率,进而提高整体的加湿效率。
可选地,风机404设置于吸湿模块100的圆筒结构的一端。这样,风机404设置于吸湿模块100的一端,风机404能够将外界的常温气流吸入吸湿模块100内部,同时在吸湿通道104和再生通道103内产生气流,气流能够更好的与吸湿模块100接触,提高吸湿模块100的吸湿部101的吸湿效率以及吸湿模块100的再生部102的水分再生效率,进而提高整体的加湿效率。
可选地,无水加湿装置还包括:风机404的进气端与吸湿模块100内部连通。这样,在风机404的进风端与吸湿模块100内部连通的情况下,可在吸湿模块100内部产生负压,将外界的气流吸入吸湿通道104和再生通道103内部,使气流即可通过吸湿模块100的外侧壁穿过吸湿模块100进入再生通道103以及吸湿通道104内,又可由吸湿模块100的另一端进入再生通道103以及吸湿通道104,气流能够更好的与吸湿模块100接触,进而提高吸湿模块100的吸湿部101的吸湿效率以及吸湿模块100的再生部102的水分再生效率,进而提高整体的加湿效率。
可选地,齿轮402表面设有多个进风口。这样,在齿轮402表面设置进风口,能够使常温气流通过进风口顺利进入吸湿模块100的内部,防止齿轮402对气流形成阻挡,提高通风效果,进而提高除湿效率。
结合图5-7所示,本公开实施例提供一种空调器包括上述的无水加湿装置。
采用本公开实施例提供的空调器,将无水加湿装置设置在空调器内,与空调器相互配合,对室内进行温度调节的同时对其湿度也进行调节,且上述无水加湿装置的吸湿模块100为圆筒结构,能够增大吸湿模块100与空气的接触面积,提高吸湿模块100在常温气流中的吸湿效率,通过设置隔离组件200,将吸湿部101和再生部102进行隔离,使吸湿模块100的内壁也能够吸收常温空气中的水分,增加吸湿模块100的吸湿效率,加热机构300与隔离组件200连接,并设置于再生部102的一侧,在吸湿模块100吸湿完成后,通过加热机构300对吸湿模块100进行加热,使其所吸收的水分加热成为气态水蒸气,并流入室内,对室内进行加湿,从而达到无水加湿的效果,将吸湿模块100设置为圆筒结构,使其内壁和外壁都能够在常温空气中吸收水分,在提高吸湿效率,能够 在保持吸湿面积的同时减小横向的空间占用,可更好的与空调器室外机进行结合。
可选地,空调器包括:室外机壳体500。室外机壳体500内部设有压机仓501,压机仓501内部下方设置有压缩机502,无水加湿装置的吸湿模块100竖直设置于压机仓501内,且设置于压缩机502的上方,吸湿模块100的部分伸出室外机壳体500,或者吸湿模块100全部设置于室外机壳体500内部。这样,通过无水加湿装置与压缩机502配合工作,在压缩机502对室内制冷的同时,通过无水加湿装置对室内进行加湿,防止室内过于干燥,其中吸湿模块100伸出室外机壳体500,能够增大吸湿模块100与常温气流的接触面积,提高其吸湿效率,进而提高整体的加湿效果,并且对压机仓501的空间占用更小;而将吸湿模块100设置在室外机壳体500内,可更好的保护吸湿模块100,防止吸湿模块100受力损坏,且可降低吸湿模块100直接暴露造成的灰尘沉积等问题,空调器室外机整体能够更好的保持一体性。
可选地,加热机构300及吸湿模块100的再生部102置于室外机壳体500内,吸湿模块100的吸湿部101伸出室外机壳体500。这样,将加热机构300和吸湿模块100的再生部102设置在室外机壳体500内,能够减少加热机构300的热量流失,更好的对吸湿模块100的再生部102进行加热,提高吸湿模块100的再生部102的水分再生效率,将吸湿模块100的吸湿部101伸出室外机壳体500,能够使吸湿模块100的再生部102与更好的与室外的常温气流接触,使其能够更充分的对室外常温气流中的水分进行吸收,提高吸湿模块100的再生部102的吸湿效率,进而提高无水加湿装置整体的加湿效率。
可选地,内置部201的V形结构的顶角为90度,且V形结构的两侧面与室外机壳体500的相邻两个侧面重叠。这样,可更好的将吸湿模块100的吸湿部101以及整个吸湿通道104置于室外机壳体500的外侧,将吸湿模块100的再生部102以及整个再生通道103置于室外机壳体500的内侧,并且利用室外机壳体500能够更好的对吸湿通道104和再生通道103进行分隔,降低二者之间的相互影响。
可选地,室外机壳体500上设有与吸湿模块100厚度相适配的安装槽。这样,吸湿模块100通过安装槽穿过室外机壳体500,并且可保持吸湿模块100的正常转动,更好的将无水加湿装置与室外机壳体500组合安装。
可选地,室外机壳体500包括主体部503和盖板504,主体部503具有向上的开口505,盖板504可覆盖于开口505上,安装槽与主体部503设有开口505的边缘连通。这样,在对吸湿模块100进行安装时,可由开口505的边缘将吸湿模块100插入安装槽 内,并将内置部201与室外机壳体500固定连接,然后将盖板504覆盖于开口505出,能够更方便的将无水加湿装置与室外机壳体500组合安装。
可选地,室外机壳体500上设有与再生通道103对应的第一通风口506。这样,气流可通过第一通风口506流入室外机壳体500并进入再生通道103,使再生通道103内产生气流,将再生出来的水分带离再生通道103,并排放至室内,更好的对室内进行加湿。
可选地,压机仓501位于压缩机502与无水加湿装置之间设有隔离板507。这样,能够更好的对压缩机502进行防护,防止通过第一通风口506进入的灰尘、异物以及水分等对压缩机502的正常工作造成影响,保持压缩机502整体的稳定性。
可选地,无水加湿装置设置于室外机壳体500内,且室外机壳体500对应再生通道103的位置设有第一通风口506,对应吸湿通道104的位置设有第二通风口508。这样,室外机壳体500外部的气流通过气孔可流入无水加湿装置内,并通过吸湿模块100的吸湿部101对常温气流内的水分进行吸收,通过吸湿模块100的再生部102将水分释放出来对室内进行加湿,设置第一通风口506和第二通风口508,能够更好的使室外机壳体500外部的气流进入室外机壳体500,与吸湿模块100进行接触,提高整体的加湿效率。
可选地,第一通风口506和第二通风口508上均设有过滤格栅509。这样,可对一些灰尘、杂质等进行过滤,降低灰尘、杂质等沉积在吸湿模块100上对吸湿模块100吸收水分效率的影响。
以上描述和附图充分地示出了本公开的实施例,以使本领域的技术人员能够实践它们。其他实施例可以包括结构的以及其他的改变。实施例仅代表可能的变化。除非明确要求,否则单独的部件和功能是可选的,并且操作的顺序可以变化。一些实施例的部分和特征可以被包括在或替换其他实施例的部分和特征。本公开的实施例并不局限于上面已经描述并在附图中示出的结构,并且可以在不脱离其范围进行各种修改和改变。本公开的范围仅由所附的权利要求来限制。
Claims (10)
- 一种无水加湿装置,其特征在于,包括:吸湿模块(100),为圆筒结构,且其能够在常温气流中吸收水分,并经过加热后可释放水分;隔离组件(200),沿所述吸湿模块(100)的轴向设置,且并将所述吸湿模块(100)沿其周向分隔为吸湿部(101)和再生部(102);加热机构(300),与所述隔离组件(200)连接,且设置于所述再生部(102)的一侧。
- 根据权利要求1所述的无水加湿装置,其特征在于,所述隔离组件(200)包括:内置部(201),设置于所述吸湿模块(100)的圆筒结构内部,且将所述吸湿模块(100)的圆筒结构内部分隔出再生通道(103)和吸湿通道(104);外置部(202),与所述内置部(201)对应设置,且与所述内置部(201)之间限定出活动间隙,所述吸湿模块(100)可穿过所述活动间隙旋转。
- 根据权利要求2所述的无水加湿装置,其特征在于,所述外置部(202)与所述吸湿模块(100)的外侧壁之间限定出加热安装区(203),所述加热安装区(203)与所述再生通道(103)位置对应,所述加热机构(300)设置于所述加热安装区(203)内。
- 根据权利要求2所述的无水加湿装置,其特征在于,所述内置部(201)为V形结构,且V形结构的顶角位于所述吸湿模块(100)的轴线上,所述外置部(202)包括第一挡板部(204)和第二挡板部(205),其中所述第一挡板部(204)与所述V形结构的一侧边位于同一平面上,所述第二挡板部(205)与所述V形结构的另一侧边位于同一平面上。
- 根据权利要求1至4任一项所述的无水加湿装置,其特征在于,所述加热机构(300)为弧形结构,其弧度与所述吸湿模块(100)外侧壁的弧度相同,且平行设置于所述吸湿模块(100)外侧壁的一侧。
- 根据权利要求1至4任一项所述的无水加湿装置,其特征在于,还包括:固定支架(105),设有圆环部(106),所述吸湿模块(100)与所述圆环部(106)旋转连接,所述隔离组件(200)与所述固定支架(105)固定连接。
- 根据权利要求1至4任一项所述的无水加湿装置,其特征在于,还包括:驱动机构(400),与所述吸湿模块(100)连接,能够驱动所述吸湿模块(100)沿其轴线旋转。
- 根据权利要求1至4任一项所述的无水加湿装置,其特征在于,还包括:风机(404),设置于所述吸湿模块(100)的圆筒结构的一端。
- 一种空调器,其特征在于,包括如权利要求1至8任一项所述的无水加湿装置。
- 根据权利要求9所述的空调器,其特征在于,所述空调器还包括:室外机壳体(500),内部设有压机仓(501),所述压机仓(501)内部下方设置有压缩机(502),所述无水加湿装置的吸湿模块(100)竖直设置于所述压机仓(501)内,且设置于所述压缩机(502)的上方,所述吸湿模块(100)的部分伸出所述室外机壳体(500),或者所述吸湿模块(100)全部设置于所述室外机壳体(500)内部。
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CN112747384A (zh) * | 2019-10-29 | 2021-05-04 | 青岛海尔空调器有限总公司 | 用于加湿的装置、空调 |
CN113418242A (zh) * | 2021-06-03 | 2021-09-21 | 重庆海尔空调器有限公司 | 无水加湿装置、空调器 |
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