CN104819514A - Intelligent air energy moisture absorption machine - Google Patents
Intelligent air energy moisture absorption machine Download PDFInfo
- Publication number
- CN104819514A CN104819514A CN201510205941.3A CN201510205941A CN104819514A CN 104819514 A CN104819514 A CN 104819514A CN 201510205941 A CN201510205941 A CN 201510205941A CN 104819514 A CN104819514 A CN 104819514A
- Authority
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- China
- Prior art keywords
- radiator
- moisture absorption
- air
- electrically operated
- exhaust outlet
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Granted
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- 238000010521 absorption reaction Methods 0.000 title claims abstract description 97
- XLYOFNOQVPJJNP-UHFFFAOYSA-N water Substances O XLYOFNOQVPJJNP-UHFFFAOYSA-N 0.000 claims abstract description 53
- 239000000463 material Substances 0.000 claims abstract description 46
- 239000012528 membrane Substances 0.000 claims description 36
- 238000001035 drying Methods 0.000 claims description 11
- 239000011148 porous material Substances 0.000 claims description 10
- 239000002250 absorbent Substances 0.000 claims description 8
- 230000002745 absorbent Effects 0.000 claims description 8
- 239000003507 refrigerant Substances 0.000 claims description 8
- OKTJSMMVPCPJKN-UHFFFAOYSA-N Carbon Chemical compound [C] OKTJSMMVPCPJKN-UHFFFAOYSA-N 0.000 claims description 3
- 229910052799 carbon Inorganic materials 0.000 claims description 3
- 239000011347 resin Substances 0.000 claims description 3
- 229920005989 resin Polymers 0.000 claims description 3
- 230000015572 biosynthetic process Effects 0.000 claims description 2
- 239000004744 fabric Substances 0.000 claims description 2
- 239000000835 fiber Substances 0.000 claims description 2
- 238000003786 synthesis reaction Methods 0.000 claims description 2
- 238000009833 condensation Methods 0.000 description 16
- 230000005494 condensation Effects 0.000 description 16
- 238000007791 dehumidification Methods 0.000 description 15
- 238000010438 heat treatment Methods 0.000 description 8
- 230000000694 effects Effects 0.000 description 4
- 230000018044 dehydration Effects 0.000 description 3
- 238000006297 dehydration reaction Methods 0.000 description 3
- 238000001704 evaporation Methods 0.000 description 3
- 230000008020 evaporation Effects 0.000 description 3
- 201000004792 malaria Diseases 0.000 description 3
- 238000000034 method Methods 0.000 description 3
- 238000000605 extraction Methods 0.000 description 2
- 229910000838 Al alloy Inorganic materials 0.000 description 1
- 230000009286 beneficial effect Effects 0.000 description 1
- 230000007812 deficiency Effects 0.000 description 1
- 238000010977 unit operation Methods 0.000 description 1
Classifications
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F24—HEATING; RANGES; VENTILATING
- F24F—AIR-CONDITIONING; AIR-HUMIDIFICATION; VENTILATION; USE OF AIR CURRENTS FOR SCREENING
- F24F3/00—Air-conditioning systems in which conditioned primary air is supplied from one or more central stations to distributing units in the rooms or spaces where it may receive secondary treatment; Apparatus specially designed for such systems
- F24F3/12—Air-conditioning systems in which conditioned primary air is supplied from one or more central stations to distributing units in the rooms or spaces where it may receive secondary treatment; Apparatus specially designed for such systems characterised by the treatment of the air otherwise than by heating and cooling
- F24F3/14—Air-conditioning systems in which conditioned primary air is supplied from one or more central stations to distributing units in the rooms or spaces where it may receive secondary treatment; Apparatus specially designed for such systems characterised by the treatment of the air otherwise than by heating and cooling by humidification; by dehumidification
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F24—HEATING; RANGES; VENTILATING
- F24F—AIR-CONDITIONING; AIR-HUMIDIFICATION; VENTILATION; USE OF AIR CURRENTS FOR SCREENING
- F24F11/00—Control or safety arrangements
- F24F11/30—Control or safety arrangements for purposes related to the operation of the system, e.g. for safety or monitoring
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F24—HEATING; RANGES; VENTILATING
- F24F—AIR-CONDITIONING; AIR-HUMIDIFICATION; VENTILATION; USE OF AIR CURRENTS FOR SCREENING
- F24F13/00—Details common to, or for air-conditioning, air-humidification, ventilation or use of air currents for screening
- F24F13/30—Arrangement or mounting of heat-exchangers
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F24—HEATING; RANGES; VENTILATING
- F24F—AIR-CONDITIONING; AIR-HUMIDIFICATION; VENTILATION; USE OF AIR CURRENTS FOR SCREENING
- F24F2110/00—Control inputs relating to air properties
- F24F2110/20—Humidity
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F24—HEATING; RANGES; VENTILATING
- F24F—AIR-CONDITIONING; AIR-HUMIDIFICATION; VENTILATION; USE OF AIR CURRENTS FOR SCREENING
- F24F3/00—Air-conditioning systems in which conditioned primary air is supplied from one or more central stations to distributing units in the rooms or spaces where it may receive secondary treatment; Apparatus specially designed for such systems
- F24F3/12—Air-conditioning systems in which conditioned primary air is supplied from one or more central stations to distributing units in the rooms or spaces where it may receive secondary treatment; Apparatus specially designed for such systems characterised by the treatment of the air otherwise than by heating and cooling
- F24F3/14—Air-conditioning systems in which conditioned primary air is supplied from one or more central stations to distributing units in the rooms or spaces where it may receive secondary treatment; Apparatus specially designed for such systems characterised by the treatment of the air otherwise than by heating and cooling by humidification; by dehumidification
- F24F2003/144—Air-conditioning systems in which conditioned primary air is supplied from one or more central stations to distributing units in the rooms or spaces where it may receive secondary treatment; Apparatus specially designed for such systems characterised by the treatment of the air otherwise than by heating and cooling by humidification; by dehumidification by dehumidification only
Abstract
An intelligent air energy moisture absorption machine comprises a heat pump device, a dewatering device, a controller and a shell. The heat pump device comprises an evaporator, a left radiator, a right radiator, a fan and a water receiving tank, the dewatering device comprises a motor, a dewatering basket, a water absorption film and a dewatering tank, the shell is provided with an air outlet and an air inlet, the evaporator, the left radiator, the right radiator, the fan, the water receiving tank and the dewatering device are mounted between the air outlet and the air inlet, the left radiator is provided with a left moisture absorption gate, and the right radiator is provided with a right moisture absorption gate. When the intelligent air energy moisture absorption machine works, first dehumidifying is performed by the aid of the dewatering device, second dehumidifying is performed by the aid of the evaporator, third dehumidifying is performed by the aid of the left moisture absorption gate or the right moisture absorption gate, dehumidifying efficiency is improved, water of the water absorption film is removed by the aid of the dewatering device, moisture absorption materials of the left moisture absorption gate and the right moisture absorption gate are heated or dried by the aid of air energy of the left radiator or the right radiator, and the moisture absorption function of the moisture absorption materials is recovered.
Description
Technical field
The present invention relates to a kind of hygroscopic machine, particularly a kind of intelligent air energy hygroscopic machine.
Background technology
At present, common dehumidifier, mainly dehumidified by the evaporator condensation malaria of heat pump, dehumanization method is single, and effect on moisture extraction is not good; An intelligent air energy hygroscopic machine for multi-method dehumidifying, has become the needs that people improve dehumidifier dehumidification rate.
Summary of the invention
The object of the invention is to overcome the deficiencies in the prior art, providing a kind of intelligent air energy hygroscopic machine, for improving the dehumidification rate of hygroscopic machine.
Of the present invention taked technical scheme is: intelligent air energy hygroscopic machine, includes heat pump assembly, dewater unit, controller and shell, and heat pump assembly and dewater unit are installed on shell; Heat pump assembly includes evaporimeter, left radiator, right radiator, blower fan and water receiving tank, and dewater unit includes motor, dewatering basket, absorbing membrane and drench pit; The support of motor 11 is connected with shell, and dewatering basket is connected with the rotating shaft of motor, and absorbing membrane is located on dewatering basket; Shell is provided with exhaust outlet and air inlet, and exhaust outlet includes left dehumidifying exhaust outlet, left dry exhaust mouth, right dehumidifying exhaust outlet and right dry exhaust mouth; Evaporimeter, blower fan, water receiving tank and dewater unit are installed between exhaust outlet and air inlet, left radiator is located at left dehumidifying exhaust outlet and between left dry exhaust mouth and air inlet, and right radiator is located at right dehumidifying exhaust outlet and between right dry exhaust mouth and air inlet; Left radiator is provided with left moisture absorption grid, right radiator is provided with right moisture absorption grid, left moisture absorption grid and right moisture absorption grid are provided with moisture wicking material, and left moisture absorption grid and right moisture absorption grid are provided with through hole and have ventilative function, and moisture wicking material includes active carbon, NACF and water-absorbing resin; Controller is connected with heat pump assembly and dewater unit by control line; Left radiator and be provided with lower Electrically operated gate between right radiator and evaporimeter, lower Electrically operated gate is provided with air-guiding hole; Left dehumidifying exhaust outlet and left dry exhaust mouth are provided with left Electrically operated gate, and left Electrically operated gate is provided with left bank pore; Right dehumidifying exhaust outlet and right dry exhaust mouth are provided with right Electrically operated gate, and right Electrically operated gate is provided with right steam vent.
The operation principle of intelligent air energy hygroscopic machine is: during work, intelligent air energy hygroscopic machine is placed in the indoor needing dehumidifying, utilizes controller to control heat pump assembly and dewater unit operation; Controller controls the absorbing membrane that malaria is pumped into dewater unit by blower fan, utilizes absorbing membrane to absorb the moisture of suction air; Suction air enters evaporimeter and carries out dehumidification by condensation after absorbing membrane absorption moisture, the air of dehumidification by condensation enters right radiator or left radiator, the left moisture absorption grid of the right moisture absorption grid of right radiator or left radiator are utilized to absorb the moisture of air, absorb the air after moisture through right moisture absorption grid or left moisture absorption grid, be discharged to indoor by left dehumidifying exhaust outlet or right dehumidifying exhaust outlet; So constantly circulation, utilizes multiple method constantly to absorb the moisture of room air.
During the work of intelligent air energy hygroscopic machine, after absorbing membrane absorbs the time that the moisture that enters air reaches setting, controller controls dewater unit dehydration, and the rotation of driven by motor dewatering basket, takes off drench pit by the water of absorbing membrane; Air after absorbing membrane dehumidifying enters evaporimeter and carries out dehumidification by condensation, and the condensation flow of evaporimeter is to water receiving tank; The water of drench pit and water receiving tank is collected by the water receiving case of shell; Air after dehumidification by condensation enters right radiator, utilizes right moisture absorption grid to absorb the moisture of air, and the air that the moisture wicking material through right moisture absorption grid absorbs moisture is discharged to indoor; Meanwhile, utilize the moisture wicking material of left radiators heat and dry left moisture absorption grid, the moisture of left moisture absorption grid moisture wicking material is evaporated and is discharged to outdoor, make the drying of left moisture absorption grid moisture wicking material and recover moisture absorption function; When after the drying of left moisture absorption grid moisture wicking material, or, the moisture wicking material of dry left moisture absorption grid reaches the time of setting, controller controls left radiator and stops heating, air after evaporator condensation dehumidifying enters left radiator, utilize the left moisture absorption grid of left radiator to absorb the moisture entering air, the air absorbing moisture through left moisture absorption grid is expelled back into indoor; Meanwhile, controller controls the moisture wicking material of the dry right moisture absorption grid of right radiators heat, and the evaporation of the moisture of right moisture absorption grid moisture wicking material is discharged to outdoor; Utilize right moisture absorption grid and left moisture absorption grid to replace the moisture absorption, utilize the dry moisture wicking material of left moisture absorption grid of left radiator and right radiators heat and the moisture wicking material of right moisture absorption grid; So constantly circulation, by indoor air dehumidification, improves the effect of the moisture absorption.
The invention has the beneficial effects as follows: intelligent air energy hygroscopic machine is provided with dewater unit and heat pump assembly, dewater unit is utilized to carry out first time dehumidifying, evaporimeter is utilized to carry out second time dehumidifying, utilize left moisture absorption grid or right moisture absorption grid to carry out third time dehumidifying, improve the effect on moisture extraction of intelligent air energy hygroscopic machine; Meanwhile, utilize dewater unit to be taken off by the water of absorbing membrane, utilize the air energy heat drying left moisture absorption grid of left radiator or right radiator or the moisture wicking material of right moisture absorption grid, recover the moisture absorption function of left moisture absorption grid and right moisture absorption grid moisture wicking material.
Accompanying drawing explanation
Fig. 1 is the structural representation of intelligent air energy hygroscopic machine.
Detailed description of the invention
Below in conjunction with accompanying drawing and specific embodiment, the present invention is further detailed:
The structural representation of the intelligent air energy hygroscopic machine shown in Fig. 1, intelligent air energy hygroscopic machine, includes heat pump assembly 1, dewater unit 2, controller 3 and shell 4, and heat pump assembly 1 and dewater unit 2 are installed on shell 4; Heat pump assembly 1 includes evaporimeter 5, left radiator 7, right radiator 8, blower fan 9 and water receiving tank 10, dewater unit 2 includes motor 11, dewatering basket 12, absorbing membrane 13 and drench pit 14, the support of motor 11 is connected with shell 5, dewatering basket 12 is connected with the rotating shaft of motor 11, and absorbing membrane 13 is located on dewatering basket 12; Shell 4 is provided with exhaust outlet 15 and air inlet 16, and exhaust outlet 15 includes left dehumidifying exhaust outlet 17, left dry exhaust mouth 18, right dehumidifying exhaust outlet 19 and right dry exhaust mouth 20; Evaporimeter 5, blower fan 9, water receiving tank 10 and dewater unit 2 are installed between exhaust outlet 15 and air inlet 16, left radiator 7 is located at left dehumidifying exhaust outlet 17 and between left dry exhaust mouth 18 and air inlet 16, and right radiator 8 is located at right dehumidifying exhaust outlet 19 and between right dry exhaust mouth 20 and air inlet 16; Left radiator 7 is provided with left moisture absorption grid 21, and right radiator 8 is provided with right moisture absorption grid 22; Left moisture absorption grid 21 and right moisture absorption grid 22 are provided with moisture wicking material, and left moisture absorption grid 21 and right moisture absorption grid 22 are provided with through hole and have ventilative function, and moisture wicking material includes active carbon, NACF and water-absorbing resin; Controller 3 is connected with heat pump assembly 1 and dewater unit 2 by control line; Left radiator 7 and be provided with lower Electrically operated gate 23 between right radiator 8 and evaporimeter 5, lower Electrically operated gate 23 is provided with air-guiding hole 24; Left dehumidifying exhaust outlet 17 and left dry exhaust mouth 18 are provided with left Electrically operated gate 25, and left Electrically operated gate 25 is provided with left bank pore 26; Right dehumidifying exhaust outlet 19 and right dry exhaust mouth 20 are provided with right Electrically operated gate 27, and right Electrically operated gate 27 is provided with right steam vent 28.
The operation principle of intelligent air energy hygroscopic machine is: during work, intelligent air energy hygroscopic machine is placed in the indoor needing dehumidifying, utilizes controller 3 to control heat pump assembly 1 and run and dewater unit 2; Controller 3 controls the absorbing membrane 13 that malaria is pumped into dewater unit 2 by blower fan 9, utilizes absorbing membrane 13 to absorb the moisture of suction air; Suction air absorbs through absorbing membrane 13 and enters evaporimeter 5 after moisture and carry out dehumidification by condensation, the air of dehumidification by condensation enters right radiator 8 or left radiator 7, the right moisture absorption grid 22 of right radiator 8 or the left moisture absorption grid 21 of left radiator 7 are utilized to absorb the moisture of air, absorb the air after moisture through right moisture absorption grid 22 or left moisture absorption grid 21, be discharged to indoor by left dehumidifying exhaust outlet 17 or right dehumidifying exhaust outlet 19; So constantly circulation.
During the work of intelligent air energy hygroscopic machine, after absorbing membrane 13 absorbs the time that the moisture that enters air reaches setting, controller 3 controls dewater unit 2 and dewaters, and motor 11 drives dewatering basket 12 to rotate, and the water of absorbing membrane 13 is taken off drench pit 14; Air after absorbing membrane 13 dehumidifies enters evaporimeter 5 and carries out dehumidification by condensation, and the condensation flow of evaporimeter 5 is to water receiving tank 10; Air after dehumidification by condensation enters right radiator 8, utilizes right moisture absorption grid 22 to absorb the moisture of air, and the air that the moisture wicking material through right moisture absorption grid 22 absorbs moisture is discharged to indoor; Meanwhile, utilize left radiator 7 to heat and the moisture wicking material of dry left moisture absorption grid 21, the moisture of left moisture absorption grid 21 moisture wicking material is evaporated and is discharged to outdoor, make left moisture absorption grid 21 moisture wicking material dry and recover moisture absorption function; When after the drying of left moisture absorption grid 21 moisture wicking material, or, the moisture wicking material of dry left moisture absorption grid 21 reaches the time of setting, controller 3 controls left radiator 7 and stops heating, air after evaporimeter 5 dehumidification by condensation enters left radiator 7, utilize the left moisture absorption grid 21 of left radiator 7 to absorb the moisture entering air, the air absorbing moisture through left moisture absorption grid 21 is expelled back into indoor; Meanwhile, controller 3 controls the moisture wicking material of the right moisture absorption grid 22 of right radiator 8 heat drying, and the evaporation of the moisture of right moisture absorption grid 22 moisture wicking material is discharged to outdoor; Utilize right moisture absorption grid 22 to replace the moisture absorption with left moisture absorption grid 21, utilize the moisture wicking material of left radiator 7 and right radiator 8 heat drying left moisture absorption grid 21 and the moisture wicking material of right moisture absorption grid 22; So constantly circulation, by indoor air dehumidification, improves the effect of the moisture absorption.
During the work of intelligent air energy hygroscopic machine, controller 3 controls left radiator 7 and right radiator 8 carries out circulating-heating work, and when left radiator 7 heats, right radiator 8 stops heating, and when left radiator 7 stops heating, right radiator 8 heats, so constantly circulation; When right radiator 8 heats, the refrigerant of heat pump assembly 1 is by right radiator 8, and when right radiator 8 stops heating, refrigerant is not by right radiator 8; Left radiator 7 heats, and the refrigerant of heat pump assembly 1 is by left radiator 7, and when left radiator 7 stops heating, refrigerant is not by left radiator 7.
The original state of lower Electrically operated gate 23 is: the air-guiding hole 24 of lower Electrically operated gate 23 is positioned at the right air intake vent 29 of right radiator 8, and air-guiding hole 24 is communicated with right air intake vent 29, and the left air intake vent 30 of left radiator 7 is closed by lower Electrically operated gate 23; The original state of left Electrically operated gate 25 is: the left bank pore 26 of left Electrically operated gate 25 is positioned at left dry exhaust mouth 18, and left bank pore 26 is communicated with left dry exhaust mouth 18, and left dehumidifying exhaust outlet 17 is closed by left Electrically operated gate 25; The original state of right Electrically operated gate 27 is: the right steam vent 28 of right Electrically operated gate 27 is positioned at right dehumidifying exhaust outlet 19, and right steam vent 28 is communicated with right dehumidifying exhaust outlet 19, and right dry exhaust mouth 20 is closed by right Electrically operated gate 27.
After the drying of left moisture absorption grid 21 moisture wicking material, or, after the time that the moisture wicking material of the dry left moisture absorption grid 21 of left radiator 7 reaches setting, controller 3 controls lower Electrically operated gate 23 and rotates, make the left air intake vent 30 of air-guiding hole 24 facing to left radiator 7 of lower Electrically operated gate 23, meanwhile, the right air intake vent 29 of right radiator 8 is closed by lower Electrically operated gate 23; And controller 3 controls left Electrically operated gate 25 and rotates, make the left bank pore 26 of left Electrically operated gate 25 turn to the position of left dehumidifying exhaust outlet 17, left bank pore 26 is communicated with left dehumidifying exhaust outlet 17, meanwhile, left dry exhaust mouth 18 is closed by left Electrically operated gate 25; Enter left radiator 7 by evaporimeter 5 air out by air-guiding hole 24 and left air intake vent 30, the air entering left radiator 7, after the moisture wicking material moisture absorption of left moisture absorption grid 21, is discharged to indoor by left bank pore 26 and left dehumidifying exhaust outlet 17; After the right air intake vent 29 of right radiator 8 is closed by lower Electrically operated gate 23, controller 3 controls right Electrically operated gate 27 and rotates, and makes the right steam vent 28 of right Electrically operated gate 27 turn to the position of right dry exhaust mouth 20, and meanwhile, right dehumidifying exhaust outlet 19 is closed by right Electrically operated gate 27; The moisture wicking material of the right moisture absorption grid 22 of right radiator 8 heat drying, the steam of heating evaporation is discharged to outdoor by right dry exhaust mouth 20; So constantly circulation.
Heat pump assembly 1 includes compressor 31 and expansion valve 32, the refrigerant out splice going splice 33 of compressor 31 is connected with left radiator 7 and right radiator 8, left radiator 7 and right radiator 8 are connected with expansion valve 32, and expansion valve 32 is connected with evaporimeter 5, and evaporimeter 5 is connected with compressor 31; Shell 4 is provided with water receiving case 35, and water receiving tank 10 and drench pit 14 are connected with water receiving case 35; Drench pit 14 is provided with low groove 36 and lower convex platform 37, and lower convex platform 37 is provided with lower air-vent 38; Water receiving tank 10 is provided with upper groove 39 and convex platform 40, and convex platform 40 is provided with air-vent 41; Lower air-vent 38 and upper air-vent 41 are communicated with exhaust outlet 17 and air inlet 16.
During the work of intelligent air energy hygroscopic machine, indoor humid air enters absorbing membrane 13 moisture absorption through the lower air-vent 38 of drench pit 14, after the time that absorbing membrane 13 moisture absorption reaches setting, controller 3 controls motor 11 and drives dewatering basket 12 to rotate, utilize centrifugal force that the water of absorbing membrane 13 is thrown away drench pit 14, the water of drench pit 14 flows to water receiving case 35; Motor 11 drives dewatering basket 12 to rotate the time reaching setting, and controller 3 controls motor 11 to be stopped, so constantly circulation; Absorb the air after moisture through absorbing membrane 13, air enters evaporimeter 5 by the upper air-vent 41 of water receiving tank 14, and the air entered to be lowered the temperature dehumidification by condensation by evaporimeter 5, and the condensation flow of evaporimeter 5 is to water receiving tank 10, and the water of water receiving tank 10 flows to water receiving case 35; Air after dehumidification by condensation enters left radiator 7 or right radiator 8, after the moisture wicking material of left moisture absorption grid 21 or the moisture wicking material of right moisture absorption grid 22 absorb moisture, is discharged to indoor by left dehumidifying exhaust outlet 17 or right dehumidifying exhaust outlet 19; So constantly circulation.
In order to implement to dehumidify to the humid air of indoor, when blower fan 9 runs, in shell 4, the flow direction of air points to exhaust outlet 15 by air inlet 16; The wet channel that removes of humid air is: air inlet 16 → lower air-vent 41 → absorbing membrane 13 → upper air-vent 27 → evaporimeter 5 → left radiator 7 → left moisture absorption grid 21 → left dehumidifying exhaust outlet 17; Or the wet channel that removes of humid air is: air inlet 16 → lower air-vent 41 → absorbing membrane 13 → upper air-vent 27 → evaporimeter 5 → right radiator 8 → right moisture absorption grid 22 → right dehumidifying exhaust outlet 19.
In order to the moisture wicking material of the moisture wicking material and right moisture absorption grid 22 that utilize air energy heat drying left moisture absorption grid 21; Left radiator 7 is provided with left magnetic valve 42 and left check valve 43, and right radiator 8 is provided with right magnetic valve 44 and right check valve 45; The syndeton of the refrigerant passage of left radiator 7 and right radiator 8 is: the input adapter of left radiator 7 is connected with left magnetic valve 42, and the out splice going splice of left radiator 7 is connected with left check valve 43; The input adapter of right radiator 8 is connected with right magnetic valve 44, and the out splice going splice of right radiator 8 is connected with right check valve 45; Left magnetic valve 42 is connected in parallel with right magnetic valve 44, and the right check valve 45 of left check valve 43 is connected in parallel; The conducting direction of left check valve 43 points to expansion valve 34 by the out splice going splice of left radiator 7, not conducting in the other direction; Right check valve 45 conducting direction points to expansion valve 34 by the out splice going splice of right radiator 8, not conducting in the other direction.
In order to implement the Based Intelligent Control of intelligent air energy hygroscopic machine, controller 3 is provided with lower humidity sensor 46, upper left humidity sensor 47, upper right humidity sensor 48 and control panel 49, and control panel 49 is provided with automatic control switch 50, shutdown switch 51 and wetness display unit 52; Lower humidity sensor 46 is installed on air inlet 16, and upper left humidity sensor 47 is installed on left dehumidifying exhaust outlet 17, and upper right humidity sensor 48 is installed on right dehumidifying exhaust outlet 19; Lower humidity sensor 46, upper left humidity sensor 47 and upper right humidity sensor 48 are connected with controller 3 by sense line; When controller 3 works, the moisture signal of air inlet 16 is transferred to controller 3 by lower humidity sensor 46, and controller 3 controlled humidity display 52 shows the humidity of air inlet 16; The moisture signal of exhaust outlet 15 is transferred to controller 3 by upper left humidity sensor 47 and upper right humidity sensor 48, and controller 3 controlled humidity display 52 shows the humidity of exhaust outlet 15; User, can observe the change of air inlet 16 and exhaust outlet 15 humidity in wetness display unit 52.
In order to by the moisture collection of room air in water receiving case 35, blower fan 9 is located between air inlet 16 and drench pit 14, evaporimeter 5 is located at left radiator 7 and between right radiator 8 and water receiving tank 10, dewatering basket 12 is located between water receiving tank 10 and drench pit 14, drench pit 14 is located between dewatering basket 12 and blower fan 9, and blower fan 9 is located between drench pit 14 and air inlet 16; Dewatering basket 12 is positioned within drench pit 14; Drench pit 14 is provided with lower drainage joint 54, and water receiving tank 10 is provided with drainage joint 55, and lower drainage joint 54 and upper drainage joint 55 are communicated with water receiving case 35.During dewatering basket 12 rotary dehydration, absorbing membrane 13 is followed dewatering basket 12 and is rotated, and the water that absorbing membrane 13 absorbs is thrown to drench pit 12, flows to water receiving case 35 by drench pit 12 through lower drainage joint 54.During the dehumidifying of evaporimeter 5 changes in temperature, the condensed water of evaporimeter 5 drips to water receiving tank 10 by evaporimeter 5, is discharged to water receiving case 35 by water receiving tank 10 through upper drainage joint 55; Water receiving tank 10 and drench pit 14 are made up of aluminium alloy plate.
During the work of intelligent air energy hygroscopic machine, press automatic control switch 50, controller 3 enters and automatically controls duty, when the air humidity of air inlet 16 reaches the top limit of humidity value of setting, its moisture signal is transferred to controller 3 by lower humidity sensor 46, controller 3 controls heat pump assembly 1 and dewater unit 2 runs, and utilizes heat pump assembly 1 and dewater unit 2 to dehumidify; Along with the air humidity of indoor constantly reduces, when the humidity of room air reduces the humidity lower limit of setting, its moisture signal is transferred to controller 3 by lower humidity sensor 46, and controller 3 controls heat pump assembly 1 and dewater unit 2 stops.
In order to implement water suction and the dehydration of absorbing membrane 13, absorbing membrane 13 has water suction and ventilative function, and absorbing membrane 13 is provided with passage 56, and absorbing membrane 13 is made up of absorbent material, and absorbent material includes natural absorbent material and synthesis absorbent material; Absorbing membrane 13 includes sponge, fiber and cloth.
In order to reduce the interference of compressor 31 pairs of air inlets 16, shell 4 is provided with control room 34, and control room 34 is positioned at the below of air inlet 16, and control room 34 is provided with dividing plate 53, and control room 34 and air inlet 16 are separated, compressor 31 is installed in control room 34; Shell 4 is provided with hook 6, and water receiving case 35 hangs on hook 6; Shell 4 is provided with blast pipe 57, blast pipe 57 and left dry exhaust mouth 18 and right dry exhaust mouth 20) be connected; Utilize blast pipe 57 that the moisture that drying is evaporated is discharged to outdoor.
Claims (10)
1. intelligent air energy hygroscopic machine, it is characterized in that: described intelligent air energy hygroscopic machine, include heat pump assembly (1), dewater unit (2), controller (3) and shell (4), heat pump assembly (1) and dewater unit (2) are installed on shell (4); Heat pump assembly (1) includes evaporimeter (5), left radiator (7), right radiator (8), blower fan (9) and water receiving tank (10), dewater unit (2) includes motor (11), dewatering basket (12), absorbing membrane (13) and drench pit (14), the support of motor (11) is connected with shell (5), dewatering basket (12) is connected with the rotating shaft of motor (11), and absorbing membrane (13) is located on dewatering basket (12); Shell (4) is provided with exhaust outlet (15) and air inlet (16), and exhaust outlet (15) includes left dehumidifying exhaust outlet (17), left dry exhaust mouth (18), right dehumidifying exhaust outlet (19) and right dry exhaust mouth (20); Evaporimeter (5), blower fan (9), water receiving tank (10) and dewater unit (2) are installed between exhaust outlet (15) and air inlet (16), left radiator (7) is located at left dehumidifying exhaust outlet (17) and between left dry exhaust mouth (18) and air inlet (16), and right radiator (8) is located at right dehumidifying exhaust outlet (19) and between right dry exhaust mouth (20) and air inlet (16); Left radiator (7) is provided with left moisture absorption grid (21), and right radiator (8) is provided with right moisture absorption grid (22); Controller (3) is connected with heat pump assembly (1) and dewater unit (2) by control line; Left radiator (7) and be provided with lower Electrically operated gate (23) between right radiator (8) and evaporimeter (5), lower Electrically operated gate (23) is provided with air-guiding hole (24); Left dehumidifying exhaust outlet (17) and left dry exhaust mouth (18) are provided with left Electrically operated gate (25), and left Electrically operated gate (25) is provided with left bank pore (26); Right dehumidifying exhaust outlet (19) and right dry exhaust mouth (20) are provided with right Electrically operated gate (27), and right Electrically operated gate (27) is provided with right steam vent (28).
2. intelligent air energy hygroscopic machine according to claim 1, it is characterized in that: the original state of described lower Electrically operated gate (23) is: the air-guiding hole (24) of lower Electrically operated gate (23) is positioned at the right air intake vent (29) of right radiator (8), air-guiding hole (24) is communicated with right air intake vent (29), and the left air intake vent (30) of left radiator (7) is closed by lower Electrically operated gate (23); The original state of left Electrically operated gate (25) is: the left bank pore (26) of left Electrically operated gate (25) is positioned at left dry exhaust mouth (18), left bank pore (26) is communicated with left dry exhaust mouth (18), and left dehumidifying exhaust outlet (17) is closed by left Electrically operated gate (25); The original state of right Electrically operated gate (27) is: the right steam vent (28) of right Electrically operated gate (27) is positioned at right dehumidifying exhaust outlet (19), right steam vent (28) is communicated with right dehumidifying exhaust outlet (19), and right dry exhaust mouth (20) is closed by right Electrically operated gate (27).
3. intelligent air energy hygroscopic machine according to claim 1, it is characterized in that: described heat pump assembly (1) includes compressor (31) and expansion valve (32), the refrigerant out splice going splice (33) of compressor (31) is connected with left radiator (7) and right radiator (8), left radiator (7) and right radiator (8) are connected with expansion valve (32), expansion valve (32) is connected with evaporimeter (5), and evaporimeter (5) is connected with compressor (31); Shell (4) is provided with water receiving case (35), and water receiving tank (10) and drench pit (14) are connected with water receiving case (35); Drench pit (14) is provided with low groove (36) and lower convex platform (37), and lower convex platform (37) is provided with lower air-vent (38); Water receiving tank (10) is provided with upper groove (39) and convex platform (40), and convex platform (40) is provided with air-vent (41); Lower air-vent (38) and upper air-vent (41) are communicated with exhaust outlet (17) and air inlet (16).
4. intelligent air energy hygroscopic machine according to claim 1, is characterized in that: described left radiator (7) is provided with left magnetic valve (42) and left check valve (43), and right radiator (8) is provided with right magnetic valve (44) and right check valve (45); The syndeton of the refrigerant passage of left radiator (7) and right radiator (8) is: the input adapter of left radiator (7) is connected with left magnetic valve (42), and the out splice going splice of left radiator (7) is connected with left check valve (43); The input adapter of right radiator (8) is connected with right magnetic valve (44), and the out splice going splice of right radiator (8) is connected with right check valve (45); Left magnetic valve (42) and right magnetic valve (44) are connected in parallel, and left check valve (43) right check valve (45) is connected in parallel.
5. intelligent air energy hygroscopic machine according to claim 4, is characterized in that: the conducting direction of described left check valve (43) points to expansion valve (34) by the out splice going splice of left radiator (7), not conducting in the other direction; Right check valve (45) conducting direction points to expansion valve (34) by the out splice going splice of right radiator (8), not conducting in the other direction.
6. intelligent air energy hygroscopic machine according to claim 1, it is characterized in that: described controller (3) is provided with lower humidity sensor (46), upper left humidity sensor (47), upper right humidity sensor (48) and control panel (49), control panel (49) is provided with automatic control switch (50), shutdown switch (51) and wetness display unit (52); Lower humidity sensor (46) is installed on air inlet (16), and upper left humidity sensor (47) is installed on left dehumidifying exhaust outlet (17), and upper right humidity sensor (48) is installed on right dehumidifying exhaust outlet (19); Lower humidity sensor (46), upper left humidity sensor (47) and upper right humidity sensor (48) are connected with controller (3) by sense line.
7. intelligent air energy hygroscopic machine according to claim 1, it is characterized in that: described blower fan (9) is located between air inlet (16) and drench pit (14), evaporimeter (5) is located at left radiator (7) and between right radiator (8) and water receiving tank (10), dewatering basket (12) is located between water receiving tank (10) and drench pit (14), drench pit (14) is located between dewatering basket (12) and blower fan (9), and blower fan (9) is located between drench pit (14) and air inlet (16); Dewatering basket (12) is positioned within drench pit (14).
8. intelligent air energy hygroscopic machine according to claim 1, it is characterized in that: described left moisture absorption grid (21) and right moisture absorption grid (22) are provided with moisture wicking material, left moisture absorption grid (21) and right moisture absorption grid (22) are provided with through hole and have ventilative function, and moisture wicking material includes active carbon, NACF and water-absorbing resin.
9. intelligent air energy hygroscopic machine according to claim 1, it is characterized in that: described absorbing membrane (13) has water suction and ventilative function, absorbing membrane (13) is provided with passage (56), absorbing membrane (13) is made up of absorbent material, and absorbent material includes natural absorbent material and synthesis absorbent material; Absorbing membrane (13) includes sponge, fiber and cloth.
10. intelligent air energy hygroscopic machine according to claim 1, is characterized in that: described shell (4) is provided with blast pipe (57), and blast pipe (57) is connected with left dry exhaust mouth (18) and right dry exhaust mouth (20); Utilize blast pipe (57) that the moisture that drying is evaporated is discharged to outdoor.
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| Publication number | Priority date | Publication date | Assignee | Title |
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| CN105713455A (en) * | 2016-01-25 | 2016-06-29 | 中山昊天节能科技有限公司 | Indoor air-energy moisture absorber |
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| CN204016195U (en) * | 2014-08-25 | 2014-12-17 | 蒋钱 | A kind of moisture absorption apparatus of centrifugal accumulation |
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