DE1946699B2 - PROCESS AND SYSTEM FOR AIR-CONDITIONING ROOMS WITH HIGH HUMIDITY - Google Patents

Description

35

The invention relates to the air conditioning of rooms in which the air has a high moisture content has, taking advantage of the heat contained in the exhaust air for heating the Fresh air with the help of a circulating regenerative heat exchanger, the heat-storing, hygroscopic Contains aluminum swap areas.

Such spaces can be closed swimming pools or industrial spaces, for example Be storage and production rooms for the textile, paper or chemical industry.

In the case of rooms of larger dimensions, the warmth laws play an economically significant one Role that arise from the fact that the consumed Room air in a warm state and the Fresh air from the outside at a relatively low temperature is available, so that it is only on the necessary internal temperature must be heated up. It was therefore obvious, the Wi'.rme content 5b to make the exhaust air usable for heating the fresh air, and it has been known for a long time to use circulating regenerative heat exchangers for this purpose.

These regenerative heat exchangers used for this purpose are designed so that the Saliva circulates while the connections of the ducts are at rest. But that can also come into question known kinematic reversal in such a way that the storage mass rests and the Kanalanschlüssc circulate.

As a rule, finely corrugated asbestos cardboard or other non-metallic material is used as the storage mass used. Such materials can be one by multiple impregnations and a firing process give sufficiently high strength for the present purpose. Furthermore, additives such. B. of lithium chloride, achieve hygroscopic surfaces in addition to the heat exchange as well an exchange of moisture in the desired range between the two air currents cause.

For use under those conditions that exist, for example, in living spaces Air conditioning systems with these heat exchangers τ have proven themselves well. Difficulties arise, however, when it is the air conditioning of rooms in which the air has a higher moisture content has, as is the case, for example, in indoor swimming pools. In rooms of this type, the The moisture content approaches the saturation value. The large amounts of moisture in the air then result in functional difficulties with the hygroscopic storage masses of the heat exchangers, namely the precipitation of the moisture in the storage mass to pollution and with low outside temperatures also give rise to icing.

The dehumidification of rooms using the condensation method is also known. The devices that come with a closed Working refrigerant circuit are arranged in the room, be it that they are driven into the room or are permanently installed in it. The dehumidification is carried out in the course of the air circulation. That The device can also be switched on when the humidity of the fresh air is too high in the supply air duct of the room will. Finally, an arrangement outside the room is also conceivable in such a way that on Lutt is taken from one point on the walls of the room and the dehumidified air from another point on the wall is reintroduced into the room. These devices only take care of dehumidification and compliance a certain room temperature is not possible with them.

The invention is based on the knowledge of these relationships started out and has a new, very useful combination ever known for itself Features of the subject. It thus relates to a method for air conditioning rooms with high levels of humidity, the aim being to achieve the object described in the room exhaust air containing latent and sensible heat with the help of a circulating Rcpcnerativ-Würe exchanger, the heat-storing and hygroscopic Contains exchange surfaces to use for heating the fresh air.

The essential feature of the method according to the invention, by which it is compared to the previous known method is that initially by cooling the room exhaust air up moisture is precipitated at the dew point, whereupon the room exhaust air using the at The heat extracted from this dehumidification is heated up and then fed to the regenerative heat exchanger will.

The implementation of this inventive concept can take place with various constructive means. For example, the cooling can be carried out according to the known condensation method, For this purpose, the air conditioning system to carry out the '' experienced according to the invention

equipped with a refrigerant circuit. In the The room exhaust duct leading to the heat exchanger is followed by the evaporator and the condenser this cycle switched on. It is essential that the amount of heat that the Exhaust air from the room is withdrawn when it cools down, afterwards to re-heat it and via the Finally, regenerative air preheaters for heating the fresh air is made usable. In many cases this means a very substantial one Energy saving. The energy still required to reheat the fresh air can be of the order of magnitude of about 20 ° / ή of the post-heating capacity of known systems.

The process takes place in such a way that the heat exchanger is supplied with warm air whose absolute humidity is significantly lower and whose temperature is significantly higher than that of the room exhaust air initially withdrawn from the room held, which is also otherwise customary and even desired, wel! namely, this moisture is supplied to the fresh air flow to be heated by the heat exchanger via the storage mass. For swimming pools it is of particular importance that the partial pressure gradient between the water vapor contained in the room air and the boundary layer above the water level is smaller than with conventional ventilation systems, which reduces water evaporation. Due to the device according to the invention, the re-humidification results in only slight fluctuations in humidity in the room air supplied to the room, almost independently of the outside air condition. If the absolute humidity of the outside air is high and the absolute humidity of the exhaust air is also high, the exhaust air is enabled by its cooling, dehumidification and reheating by means of a cooling circuit to absorb moisture from the fresh air side via the heat exchanger, so that the moisture of the supply air flowing into the room is decreased. With regard to the extended heating period (heating and humidification of the fresh air) compared to the cooling period in the entire year-round operation of the system, the dehumidification output that the cooling circuit has to contribute is correspondingly lower, while the heat recovery is greater, and considerable amounts of energy are recovered from the exhaust air, contrasted with lower performance for dehumidification by means of a relatively small refrigeration circuit - _{) 0.}

Another important possibility for implementing the method according to the invention consists in the use of a closed air circuit instead of the refrigerant circuit explained above. The refrigerant compressor is then replaced by an air compressor of the throttle valve an expansion turbine, the compressor and turbine on a common Motor shaft are arranged. The air cooler corresponds to the evaporator and the air heater to the Capacitor.

The first mentioned constructive solution, namely equipping an air conditioning system with a refrigerant circuit, however, is likely to be economical be the most favorable obscuration of the inventive idea. Therefore, a system of this type is shown in the drawing as an exemplary embodiment,

A b b. 1 thus shows, in a schematically simplified form, one for carrying out the method according to FIG the invention serving air conditioning system with refrigerant circuit.

Fig. 2 illustrates this in an extended ix diagram according to Mollier, barometer reading 735.5 mm QS _1, the changes in state for the exhaust air and the supply air. The code numbers of those points in the diagram for which the air condition is explained are shown in A b b. 1 at those points in the system where these conditions prevail.

V / ie A b b. 1 shows, that part of the air that is to be discharged from the room to be imagined on the right flows through the room air line RL in the direction to the left to the heat exchanger W, in order to leave it in the cooled state through the exhaust air line AL to the left in the direction of the outside air. The device for separating part of the moisture from the exhausted room air, in this case a refrigerant circulation system, is connected upstream of the heat exchanger. This refrigerant circuit contains the evaporator V connected in series in the direction of flow, through which the temperature of the air flowing through is pressed down to the dew point, and the condenser K, which heats the Luit again, which takes place to one temperature as a result of the heat of condensation released by the water excretion that is considerably higher than room temperature. The compressor Kr for compressing the refrigerant while increasing the temperature and a throttle D for reducing the temperature are also switched on in the circuit. The device F serves to remove the precipitated moisture. It should be mentioned, however, that the water can also be drained away in the evaporator by appropriately designing the exchange surfaces. An additional droplet separator can then be dispensed with.

From the outside, the fresh air is supplied to the heat exchanger W from the left via the fresh air line FL. The heated fresh air emerging from the heat exchanger W is passed through an air heater B, in which it can be brought to a somewhat higher temperature depending on the prevailing conditions. In the exemplary embodiment it is assumed that it may be an electrically heated block storage system, the storage mass of which is heated at times of lower heat demand, so that this stored heat is also available during times of higher heat demand. After leaving this Bloc'r'.speicher B , the heated fresh air then passes through the supply air line ZL ^; n a room, for example the hall of an indoor swimming pool.

As already indicated, in A b b. 2 shows the changes in state for the extract air and for the supply air. It is assumed here that the room air has a temperature of 28 ° C. and a relative humidity of 70 ⁰ Zo, as indicated by the state point RL or 1 in the diagram. The water temperature in the corner should be 26 ° C.

It is known that even outside of the actual bathing times all year round, as long as the pool is filled with water at all to use a considerable amount of energy for the removal of moisture is. This means that, regardless of the hygienic-physiological requirements, it is a year-round experience Fresh air operation necessary. The egg

need to be carried out for the continuous heating of the proportion of outside air required for the moisture removal, which is also necessary with the aid of the refrigerant circuit alone. For this purpose, in indoor swimming pools, a short circuit generally exceeds the consumption figures for covering the transmission between the room air duct RL and the supply air emission heat requirement on the side next to the heat exchanger II '. 5 channel ZL, namely between points 13 and 14,

The room air is cooled when it is passed through, as indicated in Fig. 1. at

due to the evaporator V with simultaneous humidity this operating mode has a high energy content

In the diagram, the compressor power is also decisive for coverage

Change of state from point 1 to point 2 showing the transmission heat losses available,

represents. This results in a temperature io in point 2 The performance-related costs for the large

of 14.5 ° C and a relative humidity of 95 ° / o. block storage B and for the refrigerant circuit

The amounts caused by the refrigerant in the evaporator V are approximately the same. The savings on state change of the air from point 1 to point 2 Investment costs are therefore especially to those recorded as well as the electric compressors application possibilities of the revolving Regenerativsorarbeit equivalent amount of heat will then be attributed 15 heat exchanger, which returns only through the capacitor K to return to this air flow - Interposition of the refrigerant circuit - or additionally released. As a result, this is opened with or a similar device - in the room air constant absolute humidity (about 10 g per current.

Kilograms of dry air) from 14.5 to 55 ° C - In the refrigerant circuit, both the what through the change of state of 20 bare as well as the bound heat through the cold point 2 to point 3 is shown. agent in the evaporator for dehumidifying the room air

This room air is now at a high temperature, and both quantities of heat and the percentage of low moisture content then enters the circulating regenerative heat as condensation heat in the condenser K, again on this air exchanger W coming from the room, where it transfers its heat to the storage tank. 25 current transferred back, so that this air current gives off the mass and at the same time also part of the air humidity remaining for the heat exchange in the circulating regenerative. It is this the state heat exchanger advantageous amount of temperature change from point 3 to point AL. receives.

The sucked in through the fresh air duct FL should also be mentioned that instead of the block storage

Fresh air is also taken from the storage mass of the heater B by any other source as an after-heating source

exchangers W heat and moisture, whereby their heat source can be used, for example

Temperature in the selected example from -15 to an electrode boiler in connection with a

-f 36 ^C C rises, represented by the connecting hot water storage tank.

line from point FL to point 4 of the diagram. In some cases the moisture accumulation is very constant absolute moisture content (7.5 g 35 different. This applies in particular to halls per kilogram of dry air) then the post-swimming pools take place. During the hours of use, the heating in the block storage tank B is followed by evaporation not only from the surface temperature that is required for the supply air to be introduced into the swimming pool. but as an effective use to maintain the desired room temperature in the room to a considerable extent, namely in this case on the humid walkways and the cleaning showers at 54.5 ° C. These are both the state and the Body surfaces in appearance, change from point 4 to point 6 of the diagram. Outside of the operating hours, i.e. when the

The line connecting point 6 to point 1 of the shower and the walkways are not used

The diagram finally shows those states - have dried out, then only the over-

tion. the area of the swimming pool via the air supply line ZL into room 45 as an evaporation area,

introduced supply air by mixing it with the room It is advisable to use the air conditioning

Mt experiences, namely by cooling down and being able to adapt to these changed conditions.

simultaneous adjustment to the moisture content sen. This means that during times of low humidity

the room air. "keitsanfalles the refrigerant circuit is sufficient

The dehumidification can be outside of the bathing times 50 in order to dehumidify the extracted room air

For this 1 sheet of drawings

Claims (3)

Patent claims: 1. Process for the air conditioning of rooms with high humidity using the in the Exhaust air contained heat for heating the fresh air with the help of a circulating Regenerative heat exchanger, which contains heat-storing, hygroscopic exchange surfaces, characterized in that moisture is initially precipitated by cooling the room exhaust air to the dew point whereupon the room air using the heat extracted during this dehumidification is heated and then fed to the regenerative heat exchanger. 2. Air conditioning system for carrying out the method n £ vh claim 1, characterized in that in the room air duct leading to the heat exchanger (RL) one behind the other the Verüo damper (V) of a refrigerant circuit and the air re-heating condenser (K ) of this refrigerant circuit are switched on. 3. Air conditioning system for carrying out the method according to claim 1, characterized in that a closed air circuit is switched on in the room air duct (RL) leading to the heat exchanger, namely one behind the other the air cooler and the air that re-heats the air that heats the air Circuit, whose air compressor and expansion turbine sit on a common mot (... shaft.