CN1601191A - Method for adjusting indoor air environment - Google Patents
Method for adjusting indoor air environment Download PDFInfo
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- CN1601191A CN1601191A CN 200410067424 CN200410067424A CN1601191A CN 1601191 A CN1601191 A CN 1601191A CN 200410067424 CN200410067424 CN 200410067424 CN 200410067424 A CN200410067424 A CN 200410067424A CN 1601191 A CN1601191 A CN 1601191A
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Abstract
The invention discloses a method for regulating the indoor air environment by regulating enthalpy value of indoor exhaust air, i.e. regulating the state of indoor exhaust air until its enthalpy value approaches to the enthalpy limit value. On the refrigerating condition, the state of the enthalpy limit value of the indoor exhaust air is that the wet ball temperature is equal to the highest dry ball temperature occurring in the regulating course; on the heating condition, the state is that the wet ball temperature is equal to the lowest dew point temperature. The invention has the technical effects of high efficiency and saving energy, and ability to provide new air and increase indoor net refrigeration quantity and simultaneously reduce energy consumption.
Description
Technical field
The present invention relates to field of heating ventilation air conditioning, especially, relate to a kind of method for adjusting indoor air environment.
Background technology
The method of regulating for indoor air environment is summarized the following several mode of having said at present:
First method is, the indoor circulation air reduces enthalpy during through refrigerant, and the method is widely used in the minitype air conditioner, but lacks new wind, and IAQ is bad.
Second method is outdoor new wind to be reduced enthalpy by refrigerant send into indoorly, and room air is discharged, and the method energy consumption is too high, does not utilize room air to come heat extraction.
The third method is that outdoor new wind is carried out heat exchange by sensible heat or total-heat exchanger and indoor exhaust wind, reduce enthalpy by refrigerant again after, send into indoorly, the method can reclaim a part of cold or heat by heat exchange, but still some loss.
The 4th kind of method is that the part that room air is discharged is mixed with outdoor new wind, again by refrigerant reduction enthalpy, sends into indoorly, and the method has also been lost cold.
Also do not have a kind of indoor exhaust wind that can effectively utilize to take away heat at present, make the enthalpy of indoor exhaust wind be higher than the air conditioning method of outdoor air enthalpy.
Summary of the invention
The method that provides a kind of indoor air environment to regulate is provided at the deficiencies in the prior art.
The objective of the invention is to be achieved through the following technical solutions: regulate indoor air environment by the enthalpy of regulating indoor exhaust wind.The status adjustment that is about to indoor exhaust wind arrives, its enthalpy should be as far as possible near the limit enthalpy of indoor exhaust wind.Cooling condition, the state of indoor exhaust wind limit enthalpy is, the highest dry-bulb temperature that its wet-bulb temperature equals in adjustment process to be occurred, heating condition, the state of indoor exhaust wind limit enthalpy is, the minimum dew-point temperature that its wet-bulb temperature equals in adjustment process to be occurred.
The present invention has following technique effect: energy-efficient, can when new wind being provided and increasing indoor clean refrigerating capacity, cut down the consumption of energy.
Description of drawings
Fig. 1 (a) is that one gas is by indirect evaporation cooling principle schematic diagram 1;
Fig. 1 (b) is that one gas is by indirect evaporation cooling principle schematic diagram 2;
Fig. 1 (c) is that gas passes through indirect evaporation cooling principle schematic diagram more than two strands or two strands;
Fig. 1 (d) is dehumidification by condensation and non-condensing dehumidifying schematic diagram;
Fig. 1 (e) is a passage dehumidifying, the dehumidifier principle schematic of another passage humidification;
Fig. 1 (f) is indirect evaporation cooler chilled water and hot water principle schematic;
Fig. 2 be behind the indoor air dehumidification thermal release refrigeration with heat principle schematic;
Fig. 3 is an indirect evaporation cooling refrigeration principle schematic 1 after room air partly dehumidifies;
Fig. 4 is an indirect evaporation cooling refrigeration principle schematic 2 after room air partly dehumidifies;
Fig. 5 be indoor-outdoor air all dehumidify back thermal release refrigeration with heat principle schematic;
Fig. 6 is air liquid dehumidifying back thermal release refrigeration and heats principle schematic;
Fig. 7 be behind the multistage liquid dehumidifying of air thermal release refrigeration with heat principle schematic;
Fig. 8 has the indoor air dehumidification refrigeration of recuperation of heat and heats principle schematic;
Fig. 9 separates the refrigeration principle schematic diagram that cools off with the outdoor air indirect evaporation behind the indoor air dehumidification;
Figure 10 utilizes outdoor air to reclaim the principle schematic that heats of dehumidifying liquid;
Figure 11 is that the portion gas that utilizes indirect evaporation cooler to discharge is produced cold (heat) water principle schematic;
Figure 12 utilizes the cold water of producing to come cooling and dehumidifying liquid principle schematic;
Figure 13 is the room air part desiccant cooling principle schematic 1 that has recuperation of heat;
Figure 14 is the room air part desiccant cooling principle schematic 2 that has recuperation of heat;
Figure 15 is the room air part desiccant cooling principle schematic 3 that has recuperation of heat;
Figure 16 is the room air part desiccant cooling principle schematic 4 that has recuperation of heat.
The specific embodiment
Describe the present invention below with reference to the accompanying drawings in detail.
As shown in Figure 1, indirect evaporation cooler comprises does wet two passages, when one gas flows into indirect evaporation cooler, a part gas at wet channel by humidification, the liquid evaporation absorbs the gas heat in the dry passage, gas quilts in the dry passage etc. are but clammy, and the gas wet-bulb temperature in the wet channel can equal the initial dry-bulb temperature of gas in the dry passage in theory.Gas dry-bulb temperature in the dry passage has two kinds of situations, a kind of situation, and its dry-bulb temperature can reach the wet-bulb temperature of the gas of sending into wet channel, in theory shown in Fig. 1 (a); Another kind of situation, its dry-bulb temperature can reach the dew-point temperature of the gas of sending into wet channel, in theory shown in Fig. 1 (b); When gas was sent into indirect evaporation cooler more than two strands or two strands, the gas temperature in the dry passage can be near the minimum dew-point temperature that enters the gas of wet channel, shown in Fig. 1 (c).
Shown in Fig. 1 (d), dehumidification by condensation is to be cooled to below the dew-point temperature by the dry-bulb temperature of any method with gas, and condensed water appears, thereby reduce the process of gas water capacity, the non-condensing dehumidifying is by any method, dry-bulb temperature at gas is not less than under the condition of its dew-point temperature, makes the water capacity of gas reduce, and dry-bulb temperature can raise, reduction or constant.
The non-condensing dehumidifying can be carried out in the dehumidifier of single channel or two passages.For the dehumidifier of two passages, a passage is for removing wet channel, and another passage is the cooling duct.Fig. 1 (e) shows a kind of typical form.
Shown in Fig. 1 (a), the part of gas 1 is sent into the dry passage of indirect evaporation cooler, another part gas at wet channel by humidification, the liquid evaporation absorbs the gas heat in the dry passage, wet being cooled near the wet-bulb temperature of sending into gas 1 such as the gas quilt in the dry passage, the wet-bulb temperature of the gas 3 in the wet channel can equal the initial dry-bulb temperature of gas in the dry passage in theory.
Shown in Fig. 1 (b), one gas a1 is by behind the dry passage of indirect evaporation cooler, a part is discharged, a part is sent into wet channel again, the wet dry-bulb temperatures that are cooled to such as the gas quilt that dry passage is discharged are near the dew-point temperature of sending into gas a1, state variation is to a2, and the wet-bulb temperature that wet channel is discharged gas is increased near the dry-bulb temperature of sending into gas a1, and state variation is to a3.
Shown in Fig. 1 (c), two gangs of gas a4, a8 sends into the dry passage of indirect evaporation cooler, the gas a4 that dew-point temperature is lower sends constantly into wet channel, by the saturated reduction temperature of humidification, formation temperature gradient, gas a6 and the a7 different as temperature, gas a8 is cooled, and state variation is to a9.When multiply gas entered indirect evaporation cooler, then the gas temperature in the dry passage can be near the minimum dew-point temperature that enters the gas of wet channel.
Shown in Fig. 1 (d), dehumidification by condensation is to be cooled to below the dew-point temperature by the dry-bulb temperature of any method with gas, and condensed water appears, thereby reduce the process of gas water capacity, the non-condensing dehumidifying is by any method, dry-bulb temperature at gas is not less than under the condition of its dew-point temperature, makes the water capacity of gas reduce, and dry-bulb temperature can raise, reduction or constant.
Shown in Fig. 1 (e), one gas a11 is by the solution and the Air mixing passage of indirect evaporation cooler, by solution dehumidification, and heat passed to gas in another passage by heat conductive wall, state variation is to a12, and another strand gas a13 is by a passage that empty G﹠W mixes of indirect evaporation cooler, by humidification, and absorbing the heat of gas in another passage by heat conductive wall, state variation is to a14.
Shown in Fig. 1 (f), when producing cold water, gas a15 sends into the dry passage of indirect evaporation cooler, send into wet channel after being cooled in dry passage, gas temperature is constantly to reduce the minimum dew-point temperature a16 that reaches in the dry passage, the gas of water and wet channel is realized countercurrent flow, temperature constantly is reduced to a16, and gas temperature in wet channel constantly raises, the highest can be to a17.The water of heat is sent into from a section of heat, and cold water is sent from colder one section.
When producing hot water, gas a18 sends into the dry passage of indirect evaporation cooler, send into wet channel after in dry passage, being cooled, gas temperature is constantly to reduce in the dry passage, the minimum dew-point temperature a19 that reaches, gas temperature in wet channel constantly raises, the highest can be to a20, the gas of water and wet channel is realized countercurrent flow, and temperature constantly is increased to a20.Cold water is sent into from colder one section, and hot water is sent from a section of heat.
As shown in Figure 2, one or more strands of room air b1 send into dehumidifier 2b by blower fan 2a, dehumidified by non-condensing, state variation by indirect evaporation cooler 2c, obtains one or more strands of cold dry air b3 and one or more strands of hot humid air b4 again to b2, send into gas b3 indoor during refrigeration, it is outdoor that gas b4 discharges, and when heating gas b4 sent into indoorly, and gas b3 discharges outdoor.Outdoor air then freely infiltrates indoor or is indoor through sending into behind any airhandling equipment, also can partly or entirely carry out the non-condensing dehumidifying by dehumidifier earlier.
As shown in Figure 3, part room air c1 sends into dehumidifier 3b by blower fan 3a, dehumidified by non-condensing, state variation is sent into the dry passage of indirect evaporation cooler 3d again to c2, and another part air c4 sends into the wet channel of indirect evaporation cooler, by humidification and intensification, state variation is to c5, and gas c2 is then but clammy in dry passage etc., and state variation is sent into indoor to c3.
As shown in Figure 4, part room air d1 sends into dehumidifier 4b by blower fan 4a, dehumidified by non-condensing, state variation is sent into the wet channel of indirect evaporation cooler 3d again to d2, by humidification and intensification, state variation is to d3, another part air d4 sends into the dry passage of indirect evaporation cooler, waits but clammyly, and state variation is sent into indoor to d5.
As shown in Figure 5, one or more strands of room air e1 send into dehumidifier 5b by blower fan 5a, dehumidified by non-condensing, state variation by indirect evaporation cooler 5c, obtains one or more strands of cold dry air e3 and one or more strands of hot humid air e4 again to e2, send into gas e3 indoor during refrigeration, it is outdoor that gas e4 discharges, and when heating gas e4 sent into indoorly, and gas e3 discharges outdoor.One or more strands of outdoor air f1 then are blown into dehumidifier 5e by blower fan 5d, dehumidified by non-condensing, state variation is to f2, again by indirect evaporation cooler 5f, obtain one or more strands of cold dry air f3 and one or more strands of hot humid air f4, during refrigeration gas f 3 is sent into indoorly, sent into gas f 4 indoor when heating.
As shown in Figure 6, room air is sent into liquid dehumidifier by blower fan 6a, by solution dehumidification.Liquid dehumidifier comprises filler 6b, is provided with solution tank 6c below, and solution is sent into the solution spraying device 6e of filler upper end by solution pump 6d in the solution tank, sprays on the filler again.Moisture in the solution absorption chamber outer air, its needed cold of regenerating is provided by low-temperature receiver.After air is dehumidified, enter indirect evaporation cooler 6f, be divided into two strands of gases, send into dry and cold gas indoor during refrigeration, outdoor air freely infiltrates or makes it to send into behind the equipment that enthalpy reduces indoor through one, when heating hot humid gas is sent into indoorly, outdoor air freely infiltrates or is indoor through sending into behind any airhandling equipment, also can partly or entirely carry out the non-condensing dehumidifying by dehumidifier earlier.
As shown in Figure 7, room air is sent into multistage liquid dehumidifier by blower fan 7a, multistage liquid dehumidifier is made up of two or more liquid dehumidifying unit, employed solution all has different temperature and concentration in each Dehumidifying element, as represented among the figure be the two-stage liquid dehumidifier, comprise Dehumidifying element 7b and 7c, wherein solution temperature among the 7c and concentration all are higher than 7b.Gas enters indirect evaporation cooler 7d after by multistage liquid dehumidifying again, is divided into two strands of gases, during refrigeration dry and cold gas is sent into indoorly, sends into hot humid gas indoor when heating.
As shown in Figure 8, room air g1 sends into dehumidifier 8b by blower fan 8a, is dehumidified by non-condensing, state variation is to g2, by indirect evaporation cooler 8c, obtain one or more strands of cold dry air g3 and one or more strands of hot humid air g4, during refrigeration again, send into gas g3 indoor, gas g4 sends into heat regenerator 8d, carries out heat exchange with outdoor air h1, and state variation is to g5, after outdoor gas enthalpy reduced, state becomes to be sent into indoor for h2.When heating, gas g4 is sent into indoor, gas g3 sends into heat regenerator, carries out heat exchange with outdoor air.
As shown in Figure 9, room air j1 sends into dehumidifier 9b by blower fan 9a, is dehumidified by non-condensing, and state variation by indirect evaporation cooler 9c, obtains one or more strands of cold dry air j3 and one or more strands of hot humid air j4 again to j2, sends into gas j3 indoor.Outdoor air k1 sends into dehumidifier 9e dehumidifying by blower fan 9d, state variation is to k2, by the dry passage of indirect evaporation cooler 9f, carry out the indirect evaporation cooling again, wait wet reduction temperature with gas j4, state variation is to k3, send into the room, gas j4 sends into the wet channel of indirect evaporation cooler 9f, and humidification heats up, state variation is discharged indirect evaporation cooler 9f to j5.
As shown in figure 10, room air m1 sends into liquid dehumidifier 10b dehumidifying by blower fan 10a, and state variation is to m2, again by indirect evaporation cooler 10c, obtain one or more strands of cold dry air m4 and one or more strands of hot humid air m3, gas m3 is sent into indoor, it is outdoor that m4 discharges.Outdoor air n1 is also by a liquid dehumidifier 10d, because the temperature of solution and steam partial pressure force rate air n1 want high among the liquid dehumidifier 10b, therefore the solution among the dehumidifier 10b is introduced among the dehumidifier 10d, utilize gas n1 to reclaim, after n1 is heated humidification by dehumidifier 10d, state variation is sent into indoor to n2.
As shown in figure 11, room air is sent into dehumidifier 11b by blower fan 11a, dehumidified by non-condensing, by indirect evaporation cooler 11c, produce certain cold water again, at the indoor air processor 11d such as coil pipe or cooling ceiling, radiation floor, air-conditioning box that are provided with the gas of its discharge, water is sent into from the front end of indirect evaporation cooler, the rear end is sent, and the cold water of producing is sent into 11d, equally also can be used to produce hot water.
As shown in figure 12, the indoor air processor 12d such as coil pipe or cooling ceiling, radiation floor, air-conditioning box that are provided with, room air is sent into liquid dehumidifier 12b dehumidifying by blower fan 12a, again by indirect evaporation cooler 12c, the cold water that method is as described in Figure 11 produced is through behind the 12d, send into plate type heat exchanger 12e again, come the dehumidifying liquid among the cooling liquid dehumidifier 12b.When adopting multistage liquid dehumidifying, can utilize the cold water that makes to cool off the dehumidifying liquid of afterbody Dehumidifying element.
As shown in figure 13, one or more strands of room air p1 send into full heat or sensible heat recover 13b by blower fan 13a, one or more strands of outdoor air q1 also send into 13b by blower fan 13d, p1 and q1 carry out full heat or sensible heat exchange, and state became q2 after q1 reduced temperature and water capacity, sent into the dry passage of indirect evaporation cooler 13c then, becoming q3 after being cooled sends into indoor, after p1 temperature and water capacity raise, state became p2, sends into and is separated into dry and cold gas p3 and hot humid gas p4 among the 13c.
As shown in figure 14, one or more strands of room air r1 send into full heat or sensible heat recover 14b by blower fan 14a, one or more strands of outdoor air s1 also send into 14b by blower fan 14e, r1 and s1 carry out full heat or sensible heat exchange, state became s2 after s1 reduced temperature and water capacity, send into indoor, after r1 temperature and water capacity raise, state becomes r2, send into indirect evaporation cooler 14c, in addition one or more strands of room air r4 send into dehumidifier 14f by blower fan 14d, are dehumidified by constant enthalpy or the dehumidifying of non-constant enthalpy heats up, and state variation is to f5, send into the dry passage of indirect evaporation cooler 14c again, r2 is separated into dry and cold gas r3 and hot humid gas r7, and the wet state r6 that is cooled to such as r5 sends into indoor.
As shown in figure 15, one or more strands of room air t1 send into full heat or sensible heat recover 15b by blower fan 15a, one or more strands of outdoor air u1 also send into 15b by blower fan 15d, t1 and u1 carry out full heat or sensible heat exchange, state became u2 after u1 reduced temperature and water capacity, send into the dry passage of indirect evaporation cooler 15c then, after being cooled to u3, send into indoor, after t1 temperature and water capacity raise, state becomes t2, send into dehumidifier 15e, dehumidified by constant enthalpy or the dehumidifying of non-constant enthalpy heats up, state variation is to t3, send into indirect evaporation cooler 15c again, be separated into dry and cold gas t4 and hot humid gas t5.
As shown in figure 16, one or more strands of room air v1 send into full heat or sensible heat recover 16b by blower fan 16a, one or more strands of outdoor air w1 also send into 16b by blower fan 16e, v1 and w1 carry out full heat or sensible heat exchange, state became w2 after w1 reduced temperature and water capacity, send into indoor, after v1 temperature and water capacity raise, state became v2, sends into dehumidifier 16f, dehumidified by constant enthalpy or the dehumidifying of non-constant enthalpy heats up, state variation is sent into indirect evaporation cooler 16c again to v3, and one or more strands of room air v5 send into dehumidifier 16g by blower fan 16d in addition, dehumidified by constant enthalpy or the dehumidifying of non-constant enthalpy heats up, state variation is sent into the dry passage of indirect evaporation cooler 16c again to v6, and v3 is separated into dry and cold gas v4 and hot humid gas v8, the wet state v7 that is cooled to such as v6 sends into indoor.
Claims (10)
1. a method for adjusting indoor air environment is characterized in that: regulate indoor air environment by the enthalpy of regulating indoor exhaust wind.The status adjustment that is about to indoor exhaust wind arrives, its enthalpy should be as far as possible near the limit enthalpy of indoor exhaust wind.Cooling condition, the state of indoor exhaust wind limit enthalpy is, the highest dry-bulb temperature that its wet-bulb temperature equals in adjustment process to be occurred, heating condition, the state of indoor exhaust wind limit enthalpy is, the minimum dew-point temperature that its wet-bulb temperature equals in adjustment process to be occurred.
2. method for adjusting indoor air environment according to claim 1, it is characterized in that: room air is by non-condensing dehumidifying or indirect evaporation cooling processing, obtain one or more strands of dry and cold gases and one or more strands of hot humid gas, during refrigeration, the hot humid gas of high enthalpy drains into outdoor; When heating, the dry and cold gas of low enthalpy drains into outdoor.Said room air can mix with outdoor air earlier or with replenish indoor outdoor air and carry out heat exchange, handle again.
3. method for adjusting indoor air environment according to claim 2 is characterized in that: during refrigeration, the hot humid gas of high enthalpy or the dry and cold gas of low enthalpy with replenish indoor outdoor air and carry out draining into after the heat exchange outdoor; When heating, the dry and cold gas of low enthalpy or the hot humid gas of high enthalpy with replenish indoor outdoor air and carry out draining into after the heat exchange outdoor.
4. method for adjusting indoor air environment according to claim 1, it is characterized in that: can be earlier with room air with replenish indoor outdoor air and carry out heat exchange, utilize then after the heat exchange room air as the cooling air to replenish indoor outdoor air dehumidify again drain into after cooling or the indirect evaporation cooling outdoor.
5. method for adjusting indoor air environment according to claim 4 is characterized in that: the said outdoor air that is cooled can comprise the outdoor air that does not carry out heat exchange for the first time.
6. according to claim 2 or 4 described method for adjusting indoor air environment, it is characterized in that: when refrigeration, one or more strands of dry and cold gas and one or more strands of hot humid gas by indirect evaporation cooling can be used for producing cold water earlier, become drain into behind the hot humid gas outdoor; When heating, one or more strands of dry and cold gas and one or more strands of hot humid gas by indirect evaporation cooler can be used for producing hot water earlier, become discharge behind the dry and cold gas outdoor.
7. method for adjusting indoor air environment according to claim 2 is characterized in that: replenish indoor outdoor air and can carry out non-condensing dehumidifying or indirect evaporation cooling earlier.
8. according to claim 2 or 4 described method for adjusting indoor air environment, it is characterized in that: said dehumidifying is a liquid dehumidifying.
9. method for adjusting indoor air environment according to claim 8 is characterized in that: said dehumanization method is, one air contacts with water, and humidification is saturated, heat absorption, enthalpy raises, and the air of another strand contacts with solution, removal moisture drying, heat release, enthalpy reduces.Two strands of air have heat exchange, and the heat release of one air is absorbed by another strand air.
10. according to the method for adjusting indoor air environment of claim described 2 or 4 or 7, it is characterized in that: said indirect evaporation cooler is when one gas is sent into wherein, send into wet being cooled to such as a part of gas near its dew-point temperature, another part humidification is saturated, and its wet-bulb temperature is near the dry-bulb temperature of sending into gas; When gas was sent into indirect evaporation cooler more than two strands or two strands, the gas temperature in the dry passage can be near the minimum dew-point temperature that enters gas in the wet channel.
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| Application Number | Priority Date | Filing Date | Title |
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| CNB2004100674246A CN1328552C (en) | 2004-10-20 | 2004-10-20 | Method for adjusting indoor air environment |
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| CNB2004100674246A CN1328552C (en) | 2004-10-20 | 2004-10-20 | Method for adjusting indoor air environment |
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| CN1328552C CN1328552C (en) | 2007-07-25 |
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| CNB2004100674246A Expired - Fee Related CN1328552C (en) | 2004-10-20 | 2004-10-20 | Method for adjusting indoor air environment |
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Cited By (8)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN100419348C (en) * | 2005-11-14 | 2008-09-17 | 绍兴吉利尔科技发展有限公司 | Air processing method and apparatus |
| CN102997343A (en) * | 2012-12-13 | 2013-03-27 | 澳蓝(福建)实业有限公司 | Solution type constant-temperature dehumidifier and control method thereof |
| CN103403459A (en) * | 2010-12-24 | 2013-11-20 | 奥普提麦尔控股有限公司 | System for drying and/or cooling an airflow |
| CN105413213A (en) * | 2015-12-22 | 2016-03-23 | 袁一军 | Solution component separation method and system |
| CN106196365A (en) * | 2016-07-13 | 2016-12-07 | 福建工程学院 | A kind of new wind low cost cool-down method |
| CN107771264A (en) * | 2015-06-22 | 2018-03-06 | 荷兰空气处理创新公司 | Building provided with air treatment system |
| CN109598034A (en) * | 2018-11-15 | 2019-04-09 | 上海朗诗规划建筑设计有限公司 | A kind of determination method of indoor design state dew point limit offset |
| CN111964207A (en) * | 2020-07-16 | 2020-11-20 | 东南大学 | Operation control method for air conditioning unit with integrated processing of cooling, heating and fresh air |
Family Cites Families (2)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| JP3351307B2 (en) * | 1997-08-08 | 2002-11-25 | 日立プラント建設株式会社 | Refrigerant natural circulation heat exchange system |
| JP2001147037A (en) * | 1999-11-19 | 2001-05-29 | Fujitsu General Ltd | Air conditioner |
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2004
- 2004-10-20 CN CNB2004100674246A patent/CN1328552C/en not_active Expired - Fee Related
Cited By (11)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN100419348C (en) * | 2005-11-14 | 2008-09-17 | 绍兴吉利尔科技发展有限公司 | Air processing method and apparatus |
| CN103403459A (en) * | 2010-12-24 | 2013-11-20 | 奥普提麦尔控股有限公司 | System for drying and/or cooling an airflow |
| CN102997343A (en) * | 2012-12-13 | 2013-03-27 | 澳蓝(福建)实业有限公司 | Solution type constant-temperature dehumidifier and control method thereof |
| CN102997343B (en) * | 2012-12-13 | 2015-07-15 | 澳蓝(福建)实业有限公司 | Solution type constant-temperature dehumidifier and control method thereof |
| CN107771264A (en) * | 2015-06-22 | 2018-03-06 | 荷兰空气处理创新公司 | Building provided with air treatment system |
| CN105413213A (en) * | 2015-12-22 | 2016-03-23 | 袁一军 | Solution component separation method and system |
| CN106196365A (en) * | 2016-07-13 | 2016-12-07 | 福建工程学院 | A kind of new wind low cost cool-down method |
| CN109598034A (en) * | 2018-11-15 | 2019-04-09 | 上海朗诗规划建筑设计有限公司 | A kind of determination method of indoor design state dew point limit offset |
| CN109598034B (en) * | 2018-11-15 | 2023-01-31 | 上海朗绿建筑科技股份有限公司 | Method for determining maximum dew point temperature limit in indoor state |
| CN111964207A (en) * | 2020-07-16 | 2020-11-20 | 东南大学 | Operation control method for air conditioning unit with integrated processing of cooling, heating and fresh air |
| CN111964207B (en) * | 2020-07-16 | 2022-05-10 | 东南大学 | Operation control method for air conditioning unit with integrated processing of cooling, heating and fresh air |
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| Publication number | Publication date |
|---|---|
| CN1328552C (en) | 2007-07-25 |
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