CN204849419U - Hot -blast dryer that declines absorbs water - Google Patents
Hot -blast dryer that declines absorbs water Download PDFInfo
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- CN204849419U CN204849419U CN201520449240.XU CN201520449240U CN204849419U CN 204849419 U CN204849419 U CN 204849419U CN 201520449240 U CN201520449240 U CN 201520449240U CN 204849419 U CN204849419 U CN 204849419U
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- 206010037660 Pyrexia Diseases 0.000 claims description 28
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- CBENFWSGALASAD-UHFFFAOYSA-N ozone Chemical compound 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- 238000007906 compression Methods 0.000 claims description 4
- 239000007921 spray Substances 0.000 claims description 4
- 230000001154 acute Effects 0.000 claims description 3
- 239000003507 refrigerant Substances 0.000 abstract description 3
- 238000004134 energy conservation Methods 0.000 abstract 1
- 238000007602 hot air drying Methods 0.000 abstract 1
- 238000001035 drying Methods 0.000 description 15
- 239000003595 mist Substances 0.000 description 4
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- 239000012535 impurity Substances 0.000 description 3
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- 238000005755 formation reaction Methods 0.000 description 2
- 238000000034 method Methods 0.000 description 2
- 230000001954 sterilising Effects 0.000 description 2
- 238000004659 sterilization and disinfection Methods 0.000 description 2
- 238000005406 washing Methods 0.000 description 2
- 238000007605 air drying Methods 0.000 description 1
- 230000036760 body temperature Effects 0.000 description 1
- 238000005516 engineering process Methods 0.000 description 1
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Abstract
The utility model discloses a hot -blast dryer that declines absorbs water, it includes, the cavity has been offered to the organism in, be equipped with the opening of this cavity in the organism one side, baffle, baffle be used for opening / seal the opening, locate the storage device in the cavity, locate the interior refrigerant cycle system by motor drive of cavity, this refrigerant cycle system includes compressor, condenser, flow controller and evaporimeter, locate the interior through -flow fan by motor drive of cavity, the through -flow fan is simultaneously supply air along the cavity and is makeed the inside gas of cavity circulate, the condenser is the contained angle setting with the evaporimeter, and this contained angle forms the hybrid chamber, the through -flow fan is arranged in this hybrid chamber, all offer the runner that is used for gas to pass through on condenser and the evaporimeter, the through -flow fan will be flowed through the wind of condenser and evaporimeter runner and mixed the back and continue simultaneously to blow along the cavity, the utility model has the characteristics of utilize little hot air drying clothing and energy -conservation etc.
Description
Technical field
The utility model relates to household appliance technical field, specifically refers to a kind of water absorption type low-grade fever air laundry dryer.
Background technology
Southern spring and summer, rainwater is various, and air humidity is larger.And in this season, this kind of article of sheet, clothing need often washing; Although the sheet after washing, clothing can remove a large amount of moisture by laundry machine dehydration, even if the sheet of process dehydration, clothing are also difficult to dry in this season.So just occurred a large amount of dryers on the market, the principle that this kind of dryer mainly utilizes is heated to air by heater or condenser, then blows sheet by high temperature air, clothing carries out drying; This kind of dryer exist power consumption large, there is potential safety hazard and high temperature causes damage to clothing.
Utility model content
The technical problem that the utility model mainly solves is to provide a kind of low-grade fever wind that utilizes and carries out dry dryer to clothing.
The utility model discloses a kind of water absorption type low-grade fever air laundry dryer, it comprises body, offers cavity in body, and body one side is provided with the opening of this cavity; Baffle plate, baffle plate is used for opening/closing openings; Be located at the storage device in cavity; Be located at by motor-driven refrigerant-cycle systems in cavity, this refrigerant-cycle systems comprises compressor, condenser, flow controller and evaporimeter; Compressor carries out compression feeding condenser for being extracted from evaporimeter by cold-producing medium; Condenser is used for the cold-producing medium after cooled compressed; Flow controller is used for high pressure and the decompression of cooled cold-producing medium sprays in evaporimeter; The post-decompression cold-producing medium heat drawn in evaporimeter in ambient gas makes the moisture in the gas of evaporimeter periphery condense at evaporator surface; Wherein, also comprise and be located at by motor-driven axial-flow fan in cavity, axial-flow fan makes the gas of cavity inside circulate along the air-supply of cavity one side; Condenser and evaporimeter are that angle is arranged, and this angle forms mixing chamber; Axial-flow fan is arranged in this mixing chamber; The runner passed through for gas all offered by condenser and evaporimeter, and axial-flow fan continues to blow along cavity one side by flowing through after condenser mixes with the wind of evaporator channels.
Adopt said structure, utilize axial-flow fan that cavity inside gas is circulated, gas takes away moisture in clothing then through condenser and evaporimeter through clothing to be dried, gas through condenser portion is high-temperature gas, gas through evaporator section forms low temperature drying gas, and because refrigerant-cycle systems is in sealing and circulating, therefore condenser is equal with the heat of evaporimeter to GAS ABSORPTION to the heat of air release; Utilize the mist that the gas and vapor permeation formation humidity through evaporator and condenser is less than 40% by axial-flow fan, and convert heat energy (electric energy have when converting the mechanical energy of axial-flow fan and refrigerant-cycle systems to few part can convert heat energy to) to due to electrical power part, and this part heat energy is in low-grade fever state when mist can be made to blow out, and mist is in and can accelerates the moisture evaporation in clothing to be dried after low-grade fever state is sent by axial-flow fan and take away moisture and can not be damaged to clothing.Therefore with utilize heater in prior art or directly utilize condenser heated air to dry up compared with clothing, this kind of dryer greatly reduces the temperature of cavity inside gas, in cavity, maximum temperature is that about 40 DEG C (heat energy changed out due to electrical power makes gas slowly heat) level off to body temperature and can not cause damage to clothing, has the features such as low consumption simultaneously.
Wherein, described flow controller is capillary or expansion valve.Utilize capillary or expansion valve by high pressure and cooled cold-producing medium decompression spray in evaporimeter.
Wherein, filter is provided with in described capillary.The setting of employing filter filters out the impurity in cold-producing medium, prevents impurity from entering in evaporimeter.
Wherein, the width of the outlet air surface of axial-flow fan is slightly less than the width of cavity.Adopt such arranging to ensure that air-out area is large, ventilate without dead angle in cavity.
Wherein, also comprise frame, axial-flow fan and refrigerant-cycle systems are loaded in frame; Frame is positioned at below evaporimeter and is provided with delivery port, and the moisture that delivery port is used for evaporator surface absorption is discharged; Frame offers air outlet, and air outlet is near a sidewall of cavity; Axial-flow fan driving gas is from this air outlet.
Wherein, described frame is provided with wind deflector, and described wind deflector is positioned near air outlet.Under the gas of wind deflector to air outlet place plays guide effect.
Wherein, described storage device is peg or the dividing plate offering air-vent.Adopt hook rail structure mainly clothes can be got up by hanger; Adopt dividing plate then clothing can be overlayed on dividing plate.
Wherein, cavity inside is also provided with ozone generator.
Ozone generator is utilized to carry out sterilization to clothing.
Wherein, the angle between evaporimeter and condenser is be not less than the acute angle of 35 °, and condenser is positioned at the top of axial-flow fan, evaporimeter be positioned at axial-flow fan sidepiece.The water that evaporator surface condensation is convenient in the such setting of evaporimeter can drip.
Accompanying drawing explanation
Fig. 1 is the left apparent direction structural representation of the utility model embodiment 1.
Fig. 2 is the partial enlarged drawing of A in Fig. 1.
Fig. 3 is the main apparent direction structural representation of the utility model embodiment 1.
Fig. 4 is the structural representation of the utility model refrigerant-cycle systems.
Fig. 5 is the left apparent direction structural representation of the utility model embodiment 2.
Detailed description of the invention
Below in conjunction with specific embodiments and the drawings, the utility model is described in further detail:
Embodiment 1:
Shown in accompanying drawing 1-Fig. 3, a kind of water absorption type low-grade fever air laundry dryer, comprising shape is the body 1 being similar to wardrobe, and body 1 inside offers cavity 2 and in body one side, offers the opening of this cavity 2; Baffle plate (not shown in FIG.) is flexibly connected with body 1 and is used for opening/closing openings; Cavity 2 is divided into drying chamber and installation cavity by air-permeable partitioning plate 16, and installation cavity is positioned at the below of drying chamber; Be provided with the peg 3 be connected with body 1 in the middle part of drying chamber, this peg 3 is used for matching coat rack and hangs clothing to be dried; Be provided with ventilative frame 4 in installation cavity, be provided with axial-flow fan 5 and refrigerant-cycle systems in frame 4, axial-flow fan 5 and refrigerant-cycle systems are by motor (not shown in FIG.); Frame 4 is provided with air outlet 6 towards cavity 2 one side, width due to the outlet air surface of axial-flow fan 5 is slightly less than the width (as can be seen from Fig. 3) of cavity 2, therefore along with the rotation gas of axial-flow fan 5 moves along air outlet 6, the gas of cavity 2 inside is circulated in cavity 2 without dead angle; Frame 4 is positioned near air outlet 6 and is provided with wind deflector 7, and wind deflector 7 plays guide effect to the gas through air outlet 6.
Refrigerant-cycle systems comprises compressor 9, condenser 10, capillary 11 and evaporimeter 12; One end of compressor 9 is by pipeline and evaporimeter 12, and the other end is connected with condenser 10 by pipeline; One end of capillary 11 is connected with condenser 10, and the other end is connected with evaporimeter 12.Cold-producing medium extracts and carries out compression feeding condenser 10 by compressor 9 from evaporimeter 12; Condenser 10 is by the refrigerant cools after compression; Capillary 11 for by high pressure and cooled cold-producing medium decompression spray in evaporimeter 12; Post-decompression cold-producing medium heat drawn in ambient gas in evaporimeter 12 makes moisture in the gas of evaporimeter 12 periphery in evaporimeter 12 surface condensation; Being provided with filter (not shown in FIG.) in capillary 11 prevents impurity from entering in evaporimeter 12.
Condenser 10 is arranged in angle with evaporimeter 12, and this angle is be not less than the acute angle of 35 °, this angle formation mixing chamber 13, and axial-flow fan 5 is positioned at mixing chamber 13; Condenser 10 is positioned at the top of axial-flow fan 5, evaporimeter 12 be positioned at axial-flow fan 5 right side; The runner 14 passed through for gas all offered by condenser 10 and evaporimeter 12, gas fraction through clothing forms low temperature drying gas through evaporator 12, another part becomes high-temperature gas after condenser 10, forms mist that humidity is less than 40% and sent by air outlet 6 and circulate after low temperature drying gas mixes with high-temperature gas by axial-flow fan 5; Due to the circulatory system that refrigerant-cycle systems is airtight, therefore the heat that absorbs of evaporimeter 12 and the heat that discharges of condenser 10 are equal, therefore in mixing chamber 13 low temperature drying gas mix with high-temperature gas both heat cancel out each other.
The below that frame 4 is positioned at evaporimeter 12 is provided with delivery port 8, when gas is through evaporator 12 due to the cold-producing medium heat absorption in evaporimeter 12, cause hydrogenesis in the gas of evaporator 12 on the surface of evaporimeter 12, because gravity moisture is dropped in delivery port 8.
Cavity 2 inside is also provided with ozone generator 15, and ozone generator 15 is located near frame 4, and ozone generator 15 carries out sterilization for treating drying clothes.
Because electric current (also known as electrical power) in the process of acting can not change the mechanical energy of axial-flow fan and refrigerant-cycle systems completely, a little part can convert heat energy to, this heat energy can heat slowly to the gas of air outlet blowout makes gas reach low-grade fever state, the gas of low-grade fever state can impel the moisture in clothing to be dried to evaporate, due to gas is only low-grade fever state therefore can not damaging laundry; It is higher 1 ~ 3 DEG C than entering the gas temperature mixed in mixing chamber that low-grade fever state refers to the gas temperature that air outlet 6 sends; Use because this dryer is used for family, temperature during startup in cavity is in normal temperature state, along with the drying of clothing, a small amount of heat energy that gas in cavity is changed out due to electrical power slowly increases, when reaching the temperature in cavity and reaching about 40 DEG C clothing just drying therefore can not cause damage to clothing, thus achieve the effect of micro-heated-air drying clothing.
The workflow of above-mentioned water absorption type low-grade fever air laundry dryer is: hang on peg 3 by clothing to be dried by clothes hanger, closes overhead gage; Start axial-flow fan 5 and refrigerant-cycle systems, the gas of cavity 2 inside is circulated until cloth drying in cavity 2; The dry run of clothing is make machine air outlet blow out the gas of low-grade fever because electrical power part converts heat energy fortune to, the moisture evaporation in when this gas makes clothing and being taken away by moisture; Gas fraction through clothing forms low temperature drying gas through evaporator 12, another part becomes high-temperature gas after condenser 10, and the gas that low temperature drying gas and high-temperature gas are mixed to form humidity 40% by axial-flow fan 5 in mixing chamber 13 is sent by air outlet 6 and continued to circulate in cavity 2.
The direction of arrow in Fig. 1, Fig. 3 is gas motion direction, and in Fig. 4, the direction of arrow is the loop direction of cold-producing medium.
Embodiment 2:
As shown in Figure 5, embodiment 2 is to utilize the dividing plate 17 offering air-vent to replace peg with the difference of embodiment 1, and dividing plate 17 is connected with body 1, the clothing that band is dry can be contained on dividing plate 17 and carry out drying.
The direction of arrow in Fig. 5 is gas motion direction.
Claims (9)
1. a water absorption type low-grade fever air laundry dryer, it comprises, body, offers cavity in body, and body one side is provided with the opening of this cavity; Baffle plate, baffle plate is used for opening/closing openings; Be located at the storage device in cavity; Be located at by motor-driven refrigerant-cycle systems in cavity, this refrigerant-cycle systems comprises compressor, condenser, flow controller and evaporimeter; Compressor carries out compression feeding condenser for being extracted from evaporimeter by cold-producing medium; Condenser is used for the cold-producing medium after cooled compressed; Flow controller is used for high pressure and the decompression of cooled cold-producing medium sprays in evaporimeter; The post-decompression cold-producing medium heat drawn in evaporimeter in ambient gas makes the moisture in the gas of evaporimeter periphery condense at evaporator surface; It is characterized in that: also comprise and be located at by motor-driven axial-flow fan in cavity, axial-flow fan makes the gas of cavity inside circulate along the air-supply of cavity one side; Condenser and evaporimeter are that angle is arranged, and this angle forms mixing chamber; Axial-flow fan is arranged in this mixing chamber; The runner passed through for gas all offered by condenser and evaporimeter, and axial-flow fan continues to blow along cavity one side by flowing through after condenser mixes with the wind of evaporator channels.
2. water absorption type low-grade fever air laundry dryer according to claim 1, is characterized in that: described flow controller is capillary or expansion valve.
3. water absorption type low-grade fever air laundry dryer according to claim 2, is characterized in that: be provided with filter in described capillary.
4. water absorption type low-grade fever air laundry dryer according to claim 1, is characterized in that: the width of the outlet air surface of axial-flow fan is slightly less than the width of cavity.
5. water absorption type low-grade fever air laundry dryer according to claim 1, it is characterized in that: also comprise frame, axial-flow fan and refrigerant-cycle systems are loaded in frame; Frame is positioned at below evaporimeter and is provided with delivery port, and the moisture that delivery port is used for evaporator surface absorption is discharged; Frame offers air outlet, and air outlet is near a sidewall of cavity; Axial-flow fan driving gas is from this air outlet.
6. water absorption type low-grade fever air laundry dryer according to claim 5, it is characterized in that: described frame is provided with wind deflector, described wind deflector is positioned near air outlet.
7. water absorption type low-grade fever air laundry dryer according to claim 1, is characterized in that: described storage device is peg or the dividing plate offering air-vent.
8. water absorption type low-grade fever air laundry dryer according to claim 1, is characterized in that: cavity inside is also provided with ozone generator.
9. water absorption type low-grade fever air laundry dryer according to claim 1, is characterized in that: the angle between evaporimeter and condenser is be not less than the acute angle of 35 °, and condenser is positioned at the top of axial-flow fan, evaporimeter be positioned at axial-flow fan sidepiece.
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| CN201520449240.XU CN204849419U (en) | 2015-06-26 | 2015-06-26 | Hot -blast dryer that declines absorbs water |
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| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN104894824A (en) * | 2015-06-26 | 2015-09-09 | 王招杰 | Water-absorbing type warm air clothes drying machine and clothes drying method |
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Cited By (1)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN104894824A (en) * | 2015-06-26 | 2015-09-09 | 王招杰 | Water-absorbing type warm air clothes drying machine and clothes drying method |
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