DE102008048238B4 - Method of operating an air conditioner - Google Patents

Abstract

Method for operating an air conditioning system using at least one enthalpy exchanger (1), in which the heat exchange surface on one side is provided with a fluid for cooling or heating air (3) and on the other side with air to be dehumidified or humidified (3 ) and with a hygroscopic sorption solution, such that the fluid and the sorption solution are passed in cocurrent and the fluid and the air (3) are passed in countercurrent through the enthalpy exchanger (1),
characterized,
that the air conditioning system is used as a function of the temperature and / or the humidity of the air (3) both in the dehumidifying operation and in the humidifying operation, and
in that the sorption solution is circulated from a store (11) into the enthalpy exchanger (1) and returned from the enthalpy exchanger (1) to the store (11),
whereby the increase in the water content of the sorption solution in the dehumidifying operation, which is carried out in the dehumidifying operation, is reversed in the humidifying mode, and on the basis of ...

Description

The The invention relates to a method for operating an air conditioning system using at least one enthalpy exchanger.

From the US 6745826 B2 is a heat exchanger of parallel plates, which form a plurality of tube-like parallel passages known. Water flows through these passages. Air flows through the gap between the plates transversely to the water flow direction. In addition, a liquid desiccant flows down the gap forming surfaces of the plates from top to bottom to dehumidify the air. After leaving the nip, the liquid desiccant (sorbent solution) is collected and regenerated for a new use. During this regeneration, the water taken up from the air must be expelled again. This can be done by means of an additional, heat-requiring heat exchanger. The heat can be supplied for example by a boiler or solar absorber. This requires either heating energy or high investment costs, a lot of space and considerable maintenance costs.

• a) Trocknung eines zu konditionierenden Luftstromes durch Sorption von darin enthaltenem Wasser und
• b) Regeneration der durch die Sorption von Wasser niedrigkonzentrierten Sorptionslösung durch Desorption von Wasser unter Verwendung von Niedrigtemperaturwärme und Umgebungsluft.

From the DE 199 52 639 A1 discloses a process for air conditioning by sorption and desorption of water by means of a recirculated hygroscopic sorbent solution comprising the steps of:

• a) drying of an air stream to be conditioned by sorption of water contained therein and
• b) regeneration of the sorbent solution which is low in sorption of water by desorption of water using low temperature heat and ambient air.

It is therefore the object of the present invention, a method for operating an air conditioner using at least one Enthalpy or heat exchanger, where the heat exchange surface on one side with one for cooling or for heating air-serving fluid and dehumidifying fluid on the other side or to be humidified air and with a hygroscopic sorption solution in contact such that the fluid and the sorbent solution are co-current and the fluid and the air countercurrently through the enthalpy exchanger guided be specified, in which the regeneration of the sorbent solution no additional Energy needed and that works largely maintenance-free.

These The object is achieved by a Method solved with the features of claim 1. Advantageous developments This method will become apparent from the dependent claims.

Thereby, that the air conditioning is dependent from the temperature and / or humidity of the air in both Dehumidification as well as used in humidification and that the sorption solution circulated from a memory in the Enthalpietauscher out and is returned from the enthalpy exchanger in the memory, wherein the dehumidifying operation the increase in the water content of the sorption solution in the humidifying operation occurred reversed and, due to a concentration gradient in the memory, the sorption in the dehumidifying operation sorption solution from a higher concentration having led the storage area in the enthalpy exchanger and from this to a lower concentration area the memory returned as well in the humidifying operation sorption solution from a lower one Concentrating area of the store in the enthalpy exchanger guided and from this into a higher one Concentrating area of the memory is attributed to achieved that both the dehumidification operation as well as the humidifying operation in the desired manner carried out with a significant overall energy saving. This advantage results from the fact that the usual in dehumidifying Way with a cooling of Air through the fluid and humidifying operation usually with a warming the air are coupled by the fluid.

By a natural one Concentration gradient decreases the concentration of the sorption solution in memory from top to bottom, and in dehumidifying mode becomes sorption solution led from the lower part of the memory in the Enthalpietauscher and from this returned to the upper part of the memory, and in the humidifying operation becomes sorption solution out of the upper part of the store into the enthalpy store and from this returned to the lower part of the memory.

It is sought that the concentration reduction of the sorption solution in Dehumidification during a run through the enthalpy exchanger preferably is high. This ensures that the cycle of water absorption and the water delivery through the sorbent solution over a full year can, without an excessively large memory needed becomes.

Advantageous should the concentration reduction of sorption in the cooling between the removal from the store and the return to the store at least 15%.

The Invention will be described below with reference to one shown in the figures embodiment explained in more detail. It demonstrate:

1 an air conditioner in the dehumidifying or cooling mode and

2 the air conditioning after 1 in humidification or heating mode.

The reproduced in the figures air conditioning contains two constructed in the same way Enthalpietauscher 1 and 2 , wherein the enthalpy exchanger 1 for cooling and dehumidification or enthalpy exchanger 2 for heating supply air 3 and the enthalpy exchanger 2 for heating or cooling in an enthalpy exchanger 1 for cooling or heating of the supply air used fluids through the exhaust air 4 of the enthalpy exchanger 1 serve cooled or heated room. As a suitable fluid, water is preferably used.

The enthalpy exchanger 1 and 2 For example, each contain an unillustrated capillary tube from one or more capillary tube mats, which consist of preferably parallel to each other and vertically arranged capillary tubes. These are flexible plastic tubes with an outer diameter between 0.5 and 5 mm. The capillary tube each have a common flow line 5 respectively. 6 for the supply of the fluid to the respective enthalpy exchanger 1 and 2 and a common return line 7 respectively. 8th for the removal of the fluid from the respective enthalpy exchanger 1 and 2 , The supply line 5 of the enthalpy exchanger 1 and the return line 8th of the enthalpy exchanger 2 on the one hand and the supply line 6 of the enthalpy exchanger 2 and the return line 7 of the enthalpy exchanger 1 on the other hand are connected to each other, so that the fluid in the circuit successively through the capillary tube of the two Enthalpietauscher 1 and 2 flows. A pump 9 ensures the constant circulation of the fluid. The supply and return lines are arranged so that the fluid in the enthalpy exchangers 1 and 2 flows from top to bottom, while the supply or exhaust air flows in countercurrent thereto from bottom to top.

When cooling the supply air preferably also their dehumidification is desired, while conversely, when the supply air is heated, this is to be additionally moistened. For this purpose, the heat exchanger 1 over an inlet 10 fed to a hygroscopic sorption solution, which is in a container or storage 11 located. The capillary tubes are wetted at their upper end with this sorption solution, and this flows down the capillary tubes to an outlet 12 about which they are in the container 11 is returned. A dosing pump 13 keeps the sorption solution in constant circulation.

Around to achieve a high dehumidifying effect, it is necessary that the capillary tubes over her entire length evenly with the sorption solution be wetted. This can, even if to increase the efficiency of the Enthalpietauschers the supplied Amount of sorption solution preferably is low, can be achieved in that the capillary tubes a hydrophilic or water-spreading surface with a contact angle less than 20 °. For this purpose, the capillary tubes are preferably with a Nonwoven fabric coated.

The hygroscopic sorbent solution is suitably an aqueous LiCl solution having a concentration in the range of about 15% to 40%. Another suitable sorption solution is a CaCl ₂ solution or a mixture of these two solutions. Due to the specific weight and also the control of the inflow direction arises in the container 11 a concentration gradient such that a lower region 14 with a higher concentrated (rich) sorption solution and an upper area 15 be formed with a weaker concentrated (poor) sorption solution. Within these ranges, of course, there is also the concentration gradient from top to bottom.

Im in 1 illustrated cooling operation, in which the supply air 3 in the enthalpy exchanger 1 is dehumidified at the same time, is the inlet 10 with a passage 16 near the bottom of the container 11 connected, so that the capillary tubes, the rich sorbent solution is supplied. As it flows down the capillary tubes, the sorbent solution absorbs moisture from the supply air, increasing its water content and thus reducing its concentration. The poor sorption solution thus obtained is then passed over the outlet 12 and one on the surface of the sorbent solution in the container 11 located float 17 in the container 11 recycled. In this way, in the cooling mode, the volume of the sorbent solution in the container 11 increased.

at The illustrated air conditioning system finds an extremely high heat recovery instead of an extra warming or cooling the supply air is superfluous, in each case by an enthalpy exchanger for the supply air and the exhaust air is used.

In cooling or summer operation, the supply air 3 in the first enthalpy exchanger 1 cooled and dehumidified. The fluid (cooling water) flows in the circuit through both Enthalpietauscher 1 and 2 , It will be in the register of the first enthalpy exchanger 1 during cooling and dehumidification of the supply air 3 heated. In the register of the second enthalpy exchanger 2 the fluid gets through the exhaust air 4 cooled again after it was cooled in an upstream humidifier adiabatically to dew point. The exhaust air 4 is thereby heated and moistened and then led out of the building.

Im in 2 shown heating or winter operation is the supply air 3 in the first enthalpy exchanger 1 heated and moistened. The fluid is now in Enthalpietauscher 1 cooled and via the return line 7 as well as the supply line 6 in the second enthalpy exchanger 2 in which it passes through the exhaust air 4 is heated before passing it over the return line 8th and the supply line 5 back to the enthalpy exchanger 1 to be led.

In heating mode the floats are by appropriate valve control 17 and the inlet 10 on the one hand, as well as the passage 16 and the outlet 12 on the other hand interconnected. It is thus the poor sorption solution from the container 11 used for wetting the capillary tubes, and this is when passing through the Enthalpietauscher 1 due to the humidification of the supply air 3 Deprived of water, leaving it as a rich sorption solution over the outlet 12 and the passage 16 the area 14 in the container 11 is supplied. Here is a reduction in the volume of the sorbent solution according to the amount of the supply air 3 discharged moisture instead.

In heating mode, the silt solution diluted by the cooling operation can thus be regenerated. By controlling the amount of the enthalpy exchanger 1 supplied sorption via the metering pump 13 can be determined how strong the supply air 3 moistened and thus the sorbent solution is concentrated. The tolerance for the adjustment of the room humidity in the winter is relatively high, so that a large margin exists. In this way, a concentration increase that compensates for a previous concentration reduction in cooling operation can be set very accurately.

The container 11 the initial sorption solution and, in addition, until regeneration, the total amount of water released from the sorption solution during cooling operation must be from the supply air 3 was recorded, save. In an air conditioning system with, for example, 10,000 m ³ / h of supply air, which can be used to air-condition an office space of around 2,000 m ² , in mid-European climate, around 14,500 liters of absorbed water accumulate each summer.

With a high concentration of the rich sorption solution and the lowest possible concentration of the poor sorption solution, the storage volume of the container 11 be minimized. Thus, for the example above, with a sorbent solution of LiCl at a rich solution of 40% and a poor solution of 20, 30 or 35%, respectively a storage volume of 29, 58 or 116 m ^{3 is} needed. It is therefore expedient to reduce the storage capacity to make the concentration difference between rich and poor sorbent solution as large as possible, advantageously greater than 15%.

The difference in concentration can be determined by the flow rate of the sorption solution in the enthalpy exchanger 1 to be controlled. The lower the flow rate, the higher the concentration difference. However, for a uniform wetting of the capillary tubes a minimum flow rate is required, so that the desired concentration difference often not in a single pass through the Enthalpietauscher 1 is reached. However, there is the possibility of passing through the outlet 12 escaping sorption solution directly over the inlet 10 in the enthalpy exchanger 1 attributed, so that the sorbent more than once the enthalpy 1 goes through until it has reached the desired concentration difference and into the container 11 is directed.

In the heating case, the adiabatic cooling of the exhaust air in an air washer before entering the Enthalpietauscher 2 switched off. A sprinkling of the capillary tube register of the enthalpy exchanger 2 with water, on the other hand, it can be continued because the efficiency is thereby increased. In addition, a large part of the enthalpy exchanger is moistened anyway at lower outside temperatures by the condensate water emerging from it when the exhaust air cools down.

The overall efficiency of the air conditioner can be significantly increased if, in heating or winter operation, the capillary tube of the enthalpy exchanger 2 is also sprinkled with sorption. For this purpose are correspondingly an inlet 18 and an outlet 19 intended. The sorbent solution may also be used for this purpose 11 be removed and returned to this. By wetting the surface of the capillary tubes with the sorbent solution, the dew point of the air is raised so that the heat of condensation resulting from the contact between the moist exhaust air and the surface of the capillary tubes becomes effective at higher temperatures. Thus, in a capillary tube coil sprinkled with a LiCl sorption solution, condensation heat can already be released at an air temperature of 20 ° C. In the case of a non-irrigated register, on the other hand, assuming an exhaust air temperature of 22 ° C and 50% relative humidity, this only takes place when the dew point temperature falls below approx. 11 ° C.

Also, measures can be taken against the formation of ice on the capillary tubes in the enthalpy exchanger 2 Become unnecessary, since the irrigation of the capillary tube with sorption solution can greatly reduce the temperature for ice formation.

Finally, the sorption solution can also as antifreeze for the through the capillary tubes of the two Enthalpietauscher 1 and 2 flowing fluid can be used. In heating mode, the temperature of the fluid in the return line 7 lowered almost to the outside air temperature. The fluid must therefore be mixed with antifreeze, which usually consists of a glycerol solution. However, this significantly increases the viscosity of the fluid, leaving that of the pump 10 permanently increased performance to four times the value. In addition, such antifreeze deteriorates the heat transfer, and the specific heat capacity of the fluid is reduced, so that the flow rate of the fluid must be increased.

These disadvantages are significantly reduced when the sorption solution is used as antifreeze. This can be done by means of a simple valve circuit and suitable connection lines from the container 11 be fed to the capillary tube registers, wherein the concentration of each prevailing outside temperature can be adjusted in such a way that it is as high as necessary, but as low as possible.

Claims (13)

Method for operating an air conditioning system using at least one enthalpy exchanger ( 1 ), in which the heat exchange surface on one side with a for cooling or for heating air ( 3 ) and on the other side with air to be dehumidified or humidified ( 3 ) and a hygroscopic sorption solution such that the fluid and the sorbent solution are cocurrently and the fluid and the air ( 3 ) in countercurrent through the enthalpy exchanger ( 1 ), characterized in that the air conditioning system is dependent on the temperature and / or the humidity of the air ( 3 ) is used both in the dehumidifying operation and in the humidifying operation and that the sorption solution in recirculation mode from a memory ( 11 ) in the enthalpy exchanger ( 1 ) and from the enthalpy exchanger ( 1 ) in the memory ( 11 ), wherein the increase in the water content of the sorption solution in the dehumidifying operation is reversed in the humidifying operation, and due to a in the memory ( 11 ) adjusting concentration gradient of the sorption solution in the dehumidifying operation sorption solution from a higher concentration region of the memory ( 11 ) in the enthalpy exchanger ( 1 ) and out of this into a lower concentration region of the memory ( 11 ) and, in the humidifying mode, sorption solution from a region of the memory which has a lower concentration ( 11 ) in the enthalpy exchanger ( 1 ) and out of this into a higher concentration area of the memory ( 11 ) is returned. A method according to claim 1, characterized in that the concentration of the sorption solution in the memory ( 11 ) increases from top to bottom and in the dehumidifying operation sorption solution from a lower part ( 14 ) of the memory ( 11 ) in the enthalpy exchanger ( 1 ) and from this into an upper part ( 15 ) of the memory ( 11 ) and in the humidifying operation sorption solution from the upper part ( 15 ) of the memory ( 11 ) in the enthalpy exchanger ( 1 ) and from this to the lower part ( 14 ) of the memory ( 11 ) is returned. A method according to claim 1 or 2, characterized in that the concentration reduction of the sorption solution in the dehumidifying operation in a passage through the Enthalpietauscher ( 1 ) is as high as possible. A method according to claim 1 or 2, characterized in that the sorption solution before returning to the memory ( 11 ) repeatedly the enthalpy exchanger ( 1 ) goes through. Method according to one of claims 1 to 4, characterized in that the concentration reduction of the sorption solution on the amount of per unit time to the Enthalpietauscher ( 1 ) guided sorption solution is controlled. Method according to one of claims 3 to 5, characterized in that the concentration reduction of the sorption solution in the cooling operation between the removal from the memory ( 11 ) and the return to the memory ( 11 ) is at least 15%. Method according to one of claims 1 to 6, characterized that as a sorption solution a aqueous LiCl is used. A method according to claim 7, characterized in that the concentration of LiCl solution in the memory ( 11 ) ranges between 15% and 40%. Method according to one of claims 1 to 8, characterized that the sorption solution the Fluid is added as antifreeze. Method according to one of claims 1 to 9, characterized in that at least two Enthalpietauscher ( 1 . 2 ) are used, which are flowed through by the fluid in a closed circuit in succession, wherein in the dehumidifying operation, the first Enthalpietauscher ( 1 ) for cooling and dehumidifying incoming air ( 3 ) and the second Enthalpy exchanger ( 2 ) for cooling the fluid by exhaust air ( 4 ) and in humidification mode the first enthalpy exchanger ( 1 ) for heating and humidifying incoming air ( 3 ) and the second enthalpy exchanger ( 2 ) for heating the fluid by exhaust air ( 4 ) be used. A method according to claim 10, characterized in that the heat exchange surface of the second enthalpy exchanger ( 2 ) is also wetted with sorption solution. Process according to claim 10 or 11, characterized in that the concentration gradient of the sorption solution in the second enthalpy exchanger ( 2 ) inversely to that in the first enthalpy exchanger ( 1 ). Method according to one of claims 1 to 12, characterized in that the exhaust air ( 4 ) before entering the second enthalpy exchanger ( 2 ) is cooled adiabatically.