EP2457027A2 - Method for reclaiming an evaporated liquid from an air stream and device for performing the method - Google Patents

Abstract

The invention relates to a method for reclaiming an evaporated liquid from an air stream, such as can be used for extracting drinking water from ambient air, the evaporated liquid is transferred from a first quantity of air into a second quantity of air, wherein the second quantity of air is smaller than the first quantity of air. The evaporated liquid from a first quantity of air is sorbed in a sorption agent, and then desorbed in a second, smaller quantity of air. The specified dew point temperature of the second quantity of air is greater than an exterior temperature under typical operating conditions. A device for carrying out the previously described method for obtaining drinking water from ambient air, wherein the evaporated liquid is sorbed in an sorption agent and then desorbed, comprises a container (9) having a plurality of rotationally supported chambers filled with the sorption agent and permeable by an air flow. The container (9) has circularly disposed, rotationally supported chambers comprising inflow openings and outflow openings disposed at a distance for an air flow.

Description

A process for recovering a vaporized liquid from an air stream and apparatus for carrying out the process

The invention relates to a method for recovering a vaporized liquid from an air stream.

From practice adsorption chillers and

Absorption refrigerating machines are known which produce by cooling a refrigerant, a cooling effect, the

For example, for the air conditioning of closed

Premises can be used. With the sorption, or the desorption of the refrigerant is usually also connected to a change in the state of matter of the refrigerant, or causes.

A commonly used refrigerant is for example water, which in the sorption in a suitable

Sorbent such as silica gel or zeolite is stored. In a subsequent desorption, the refrigerant can be re-evaporated by heating the sorbent. The adsorption or absorption of the refrigerant is favored by low temperature and high pressure. For this reason, sorption refrigerators are either operated at a low working pressure well below normal atmospheric pressure or preferably used in those regions for air conditioning of rooms in which the averaged temperature values are not excessively high, so that the ambient temperature, or outside temperature in the most cases suitable operating conditions for the

Sorption chillers allows and also only a low cooling capacity for a perceived as pleasant

Air conditioning of the premises is required. The required for the operation of the sorption chillers

Energy should, for example, about environmental energy

(Solar energy, geothermal energy) or be provided by waste heat. The air conditioning of closed premises is

however in hot regions with high average

Daytime temperatures of particular interest, especially since due to the high solar energy solar energy in sufficient quantity is available at low cost, which can be used for operation of a sorption refrigeration machine.

In order to ensure a sufficiently efficient adsorption of the refrigerant is usually a cooling of the sorbent required. From an ambient temperature of more than 3O ⁰ C, however, it is often no longer possible for the efficient operation of

Adsorption chiller required cooling the

individual components with a convection flow or artificially generated flow with ambient air

bring about. In these cases, one can

 Evaporative cooling are used, which can be accomplished without much equipment.

For example, by spraying the to be cooled

Surfaces and components with water will

Evaporative cooling generates and operation of the

Adsorption chiller even at high Ambient temperatures allows. Similarly, evaporative cooling or other cooling processes in which water or other liquid refrigerant vaporizes or evaporates may be used for exclusive or auxiliary cooling in any chillers based, for example, on the use of one or more heat exchangers.

The water used for cooling and thereby evaporated increases the moisture content in the environment of the surfaces and components to be cooled and is usually removed with the exhaust air. The evaporative cooling conditions

consequently a continuous water consumption. Especially in hot and therefore often water-poor regions, a continuous water consumption is uneconomical and should be avoided if possible.

The moisture content of the exhaust air is regularly too low to allow a significant condensation and thus a recovery of entrained in the exhaust evaporated liquid without a renewed consuming and energy-intensive cooling of the exhaust air. An active cooling of the

moist exhaust air is, however, as well as intermediate process steps with considerable pressure or vacuum uneconomical and with an increased effort in the production, installation and in the operation of such

Connected devices.

It is therefore considered to be an object of the present invention to provide a process for recovering a

vaporized liquid from a stream of air so

to design that at least part of the vaporized Liquid from a first volume of air even at high

Ambient temperatures of 3O ⁰ C or more can be recovered without having to be generated with a high energy expenditure, an excessive cooling effect or pressure change to a condensation and recovery of

to cause evaporated liquid.

This object is achieved in that the vaporized liquid is transferred from a first amount of air into a second amount of air, wherein the second

 Air quantity is smaller than the first air quantity. It is preferably provided that the evaporated liquid is sorbed from a first amount of air in a sorbent and then desorbed again in a second amount of air, wherein the second amount of air is smaller than the first

Air quantity is. In place of an adsorption, absorption of the liquid and its subsequent

Desorption. As the sorbent, any material suitable for containing water or water vapor can be used

Sufficient amount to record and save, then to be able to deliver the recorded amount of water again. For example, they may be porous materials with a high surface area to volume ratio. Suitable sorbents may also be suitable

Plastic materials or liquids or gases are used. The invention is based on the finding that a suitable increase of the dew point temperature

Condensation is favored and suitable Conditions already at a cooling on the

Ambient temperature appreciable condensation and thus a recovery of the moisture contained in the air flow can be enforced.

Since the dew point temperature for a given air pressure significantly depends on the total amount of air contained in the air, or contained in the amount of air

Is dependent on the amount of water, the dew point temperature can be increased in a simple manner that for a

Desorption sorbed in the sorbent

Amount of liquid is used a significantly smaller amount of air than in the sorption of the same amount of liquid from the amount of air dried thereby. If the

Moisture content in the second air quantity sufficiently high and the dependent dew point temperature above the

Ambient temperature is, by cooling the second air volume to the ambient temperature, a large proportion of the moisture content of the second air flow to the

Condensation can be brought.

The method according to the invention described above is not for use in connection with a

Air conditioning or cooling limited. Rather, drinking water can be obtained from the ambient air by the method according to the invention, for example, by condensing out the moisture contained in the ambient air. Usually, the production of drinking water is carried out by the extraction of ground or surface water or by the desalination of seawater. In dry-hot regions No appreciable groundwater extraction can take place and, due to lack of rainfall, efficient collection and use of surface water is hardly feasible. A

Seawater desalination necessarily requires access to the seaboard, which is not present in many countries and regions.

In contrast to the previously known methods, moisture can be extracted from the ambient air and condensed water without the use of an energy-intensive

Lowering the temperature or increasing the pressure of the

Ambient air must be made, which make such a process uneconomical.

To extract water vapor from the ambient air and

For example, extracting drinking water can suck in ambient air, dehumidify it in a sorbent and

subsequently be returned. In one

Process air circulation is circulated an air flow, the temperature and absolute humidity in

Depending on the outside temperature is set so that the deposited of a first, large amount of ambient air in the sorbent moisture from a heated second, small amount of air in the

Process air circulation can be recorded. Subsequently, the second amount of air is cooled in the process air cycle again, so that the moisture contained therein condensed to a large extent and can be collected as drinking water. In contrast to the previously known methods in which the ambient air is cooled or compressed to cause the moisture contained therein to condense, the moisture is transferred to a second, preconditioned amount of air, which converts a much more efficient condenser of that air quantity

Humidity allows.

According to an advantageous embodiment of

Erfindungsgedankenens is provided that the first

 Air quantity and the second air quantity have a same air pressure. This air pressure corresponds essentially to the air pressure of the ambient air or locally

prevailing air pressure under normal conditions. An artificial change in air pressure and that

possibly required vacuum generation are not necessary. The effort for the production and operation of a pressure-resistant and under negative pressure or overpressure

Working liquid recovery device is not required and can be saved.

Preferably, it is provided that the second amount of air is less than a limit air amount at a desorption of a predeterminable amount of liquid from the sorbent whose dew point after a recording of the

Desorbed liquid amount of a predefinable

Minimum temperature corresponds. In a first step, it can be specified which amount of liquid should be withdrawn from the first quantity of air, which is initially in the

Sorbent sorbed and then supplied by desorption of the second amount of air. The amount of the second amount of air is then conveniently set so that the quantity of liquid supplied after the desorption can largely be recondensed and recovered again by a suitable increase in the dew point temperature of the second air quantity in a subsequent cooling of this second air quantity to the ambient temperature. The

 Dew point temperature results from the amount of the second amount of air and the moisture absorbed therein.

For efficient operation of the adsorption chiller and extensive recovery of the for cooling

To allow used cooling water, it is appropriate that the predetermined dew point temperature is higher than a

Outdoor temperature under normal operating conditions. The dew point temperature should be higher than the ambient temperature used to cool the second amount of air, which was heated to 75 ^° C. and above for the desorption process.

According to an advantageous embodiment of

The idea of the invention is that after the

 Desorption of stored in the sorbent

Liquid, the second amount of air is supplied to a heat exchanger, which cools the second amount of air. The amount of condensate produced during the cooling of the second quantity of air can be collected and used again, for example for evaporative cooling. The

Evaporative cooling may also be the case

Contain sorbents, as the sorbent is heated in an adsorption of water and excessive heating of the sorbent should be avoided. In order to reduce a loss of water, or consumption of cooling liquid can be provided that the second

Air volume is circulated in a closed circuit. A loss of water can be largely or completely prevented by the fact that the first amount of air is also circulated in a closed circuit and the

Evaporative cooling takes place within this cycle. It is also possible and, under certain conditions, appropriate for one or both quantities of air to be kept open and not in a closed circuit.

In order to be able to extract drinking water from the ambient air, it is provided that the first quantity of air is drawn in from the ambient air. The first amount of air is not circulated in a closed circuit to allow cooling of an air-conditioned air drawn in from the environment

allow, but continuously removed from the ambient air to at least partially condense their moisture and thus be able to win drinking water efficiently with the method described above.

To the highest possible moisture content from the

Ambient air to be transferred to the sorbent is provided that the first amount of air is cooled before the moisture contained therein in a

Sorbent sorbed and then desorbed in a second amount of air again. The cooling can take place via a heat exchanger or, for example, in a natural manner by flowing through an earth tunnel or the like. The moisture transferred to the sorbent is removed by means of a second, suitably

preconditioned air quantity desorbed from the sorbent, wherein preferably the dew point temperature of the second air quantity after the absorption of moisture from the sorbent is significantly above the ambient air. By a subsequent cooling of the second amount of air, the moisture contained therein is condensed to a large extent and can be collected to possibly treated and as drinking water or

To be made available to utility water.

The invention also relates to a device for

Carrying out the method described above for recovering a vaporized liquid from a

Air flow, the evaporated liquid in one

Sorbent adsorbed and then again

is desorbed. According to the invention it is provided that the device comprises a container with a plurality of rotatably mounted chambers which are filled with the sorbent and can be flowed through by an air flow. By using a container with rotatably mounted, can be traversed by an air flow sorption chambers, an adsorption of a first amount of air in a chamber on one side of the container and at the same time

Desorption be performed in a second amount of air in a chamber on another, preferably opposite side of the container. In this way, a continuous operation of the device and thus a continuous recovery of the adsorbed from the first amount of air moisture is possible. It is advantageously provided that the device has a device for air flow guidance, which forms a closed circuit and guides an air flow through at least one chamber of the container and subsequently through a heat exchanger. The

 Air flow guide may be a flow channel whose course is adapted to the spatial conditions.

To facilitate collection, caching and provision of the recovered liquid

provided that the device comprises a collecting device for auskondensierende from the second amount of air liquid. According to an advantageous embodiment of the inventive idea, it is provided that the container has annularly arranged, rotatably mounted chambers, which are filled with a sorbent and

Inflow openings and spaced apart

Have outflow openings for an air flow. The annularly arranged chambers may have inflow and outflow openings arranged in the radial direction

have in the inflow areas, or in

Outflow areas of the associated air flow guide open. In addition to an air flow guide for the second air quantity, an air flow guide for the first air quantity can also form a closed circuit and at the same time space a throughflow

allow arranged chambers of the container. Embodiments of the invention will be explained in more detail, which are illustrated in the drawing. 1 shows a schematic representation of a device and a method sequence of a refrigerating machine for

Air conditioning of premises where one

Evaporative cooling is used and the sprayed cooling water is recovered in a second cycle,

Fig. 2 is a schematic representation of a container with rotatably mounted sorption chambers, Fig. 3 the container shown in Fig. 2 in a reduced and exploded view and

Fig. 4 is a schematic representation of a device and a process sequence for drinking water extraction

Ambient air.

The only shown schematically in Fig. 1

Chiller 1 cools via a first heat exchanger 2 a sucked from the environment and flowing

Supply air flow 3 from. With an upstream second

Heat exchanger 4 is a preconditioning of

Supply air flow 3 causes, whereby usually both a cooling and a drying of the supply air flow 3 come into consideration for the preconditioning. By a cooling process performed in the first heat exchanger 2, the supply air of the supply air stream 3 to the desired

Supply air temperature cooled. The supply air is subsequently fed to the air-conditioned premises 5 and discharged as exhaust air stream 6 again.

To ensure effective operation of the chiller too

must enable the flowing into the heat exchanger 2 refrigerant, a substantially at ambient air pressure flowing cooling air flow 7, by means of a

Evaporative cooling 8 are cooled. About the

Evaporative cooling 8 demineralized cooling water is discharged to the cooling air flow 7, so that it is a

Adiabatic evaporation of the cooling water in the cooling air flow 7 comes, why the humidity of the cooling air flow 7 increases and the temperature drops. The cooling air flow 7 is guided in a closed circuit by a in connection with FIGS. 2 and 3 explained in more detail container 9, with a

Sorbent 10 filled chambers 11, which are rotatably mounted. The chambers 11 are arranged in a ring and connected to each other, so that the chambers 11 form a rotatably mounted chamber ring 12, which is substantially completely filled with the sorbent 10. Both within the chamber ring 12 and outside of the chamber ring 12 are circular segment-shaped supply and discharge chambers 13 are arranged concentrically, which are connected to the circuit of the cooling air flow 7. Both the individual chambers 11 and the supply and

Discharge chambers 13 have inflow and

Outlet openings 14, which allow the cooling air flow 7 to flow from a feed chamber 13 through the filled with sorbent 10 chambers 11 into the associated discharge chamber 13. The Flow direction of the cooling air flow 7 can be arbitrarily specified, so that the cooling air flow 7 flows either from the inside to the outside or from outside to inside through the chambers 11. The chamber ring 12th

surrounding chambers 13 are depending on the flow direction of the flowing air flow either feed chambers 13 or discharge chambers 13th

The annular chamber 12 is rotatable between the spatially

stored supply and discharge chambers 13 and can be driven by a motor and placed in a continuous or interval-like rotational movement. To the annular chamber 12, two feed chambers 13 and two associated discharge chambers 13 are arranged, so that a first air flow, for example, the cooling air flow 7, and a second air flow through at the same time

different chambers 11 can flow. While in some chambers 11 a sorption of moisture from the

Cooling air flow 7 takes place, can already be in opposite chambers 11 a desorption in the

 Sorbent 10 stored moisture done.

2 and 3 show an exemplary sectional view of the container 9. The container 9 may have a cylindrical shape and have an almost any length, so that the amount of flow through

Sorbent 10 also almost arbitrarily specified and can be adapted to the particular requirements. The arrangement and design of the inflow and outflow openings 14 can ensure that during the rotational movement of the chamber ring 12 between the supply and discharge chambers 13 at any time a substantially consistent freer

 Flow cross-section can be ensured so that it must not come to noticeable pressure fluctuations during operation.

In addition to the cooling air flow 7 is a

Desorption air flow 15 passed through the container 9. In Fig. 2 is for illustration by way of example a

simultaneous flow through the container 9 with the

Cooling air flow 7 and indicated by the Desorptionsluftstrom 15.

The heated desorption air stream 15 decreases in the

Flow through the filled with sorbent 10 chambers 11, the moisture stored therein. Of the

 Volume flow of Desorptionsluftstroms 15 is less than the volume flow of the cooling air flow 7. Studies have shown that, for example, a factor 10 between the two volume flows is suitable, it being assumed that regardless of the respective volume flow per unit time sorption of moisture or subsequent desorption of moisture in, or from the sorbent 10 is approximately constant. Due to the lower volume flow of the

Desorptionsluftstroms 15 takes a correspondingly lower second air quantity of the Desoptionsluftstroms 15, the same amount of liquid, or amount of water vapor, which was previously introduced by a larger first amount of air of the cooling air flow 7 in the sorbent 10. The absolute moisture content of the second air quantity is therefore

considerably larger, so that the dew point temperature is higher than the dew point temperature of the cooling air flow 7. at a suitable embodiment of the volume flows and the container 9 can be achieved that the

Dew point temperature of Desorptionsluftstroms 15 is above ambient temperature.

In a subsequent process step, only the desorption air stream 15 enriched with moisture from the sorbent 10 has to be passed through a heat exchanger 16 and cooled below the dew point temperature in order to condense the moisture contained in the desorption air stream 15 and thus recover the liquid entrained in the desorption air stream 15 enable. The separated liquid can be collected and fed back to the evaporative cooling 8.

For the necessary heat supply and

 Flow generation facilities required energy can be generated by a solar system 17 and the respective

Energy consumers are supplied. The chiller 1 can therefore exclusively with water consumption

Solar energy operated and allow a cost-effective and economically sensible air conditioning of premises 5 in hot regions. It is also conceivable to use the previously described

Recovery of moisture from an air flow to obtain drinking water from salt water or seawater. The contained in an air flow, generated by evaporation, or evaporation of salt water

Water vapor can be transferred to a second air flow, whose dew point is much higher and an economically sensible separation of the water, or Auskondensierung allowed.

An exemplary process for obtaining

Drinking water from the ambient air is shown in FIG. 4

shown. From the environment 18 ambient air is sucked by means of a fan 19. The ambient air has, for example, a temperature of 45 ^° C. and a relative humidity of 15%, so that approximately 9 g / kg of evaporated water are contained in the ambient air. The ambient air is first cooled in a cooling device 20, for example to 28 ⁰ C and then passed through the container 9, which contains the sorbent 10 in several chambers 11. A portion of the moisture contained in the ambient air is taken up in the sorbent 10 and stored. When using suitable sorbent of the previously cooled to 28 ⁰ C ambient air about 7.6 g / kg of water can be withdrawn. The dehumidified and thereby

simultaneously heated ambient air is again the

Environment supplied.

In a closed circuit 21 is a

 Process air flow 22 circulated. The process air stream 22 is heated via a solar collector assembly 23 to

then at a temperature of for example 75 ⁰ C and a relative humidity of 33% to flow through the container 9 and the moisture stored therein

take. The relative humidity of the process air stream 22 increases, for example, to 74%, so that the

Process air stream 22 has absorbed about 153 g / kg of water. Each kilogram of process air can thus absorb the amount of water that is about 20 kilograms

Ambient air transferred to the sorbent and stored there. This means that the first one

Air volume about twenty times the volume of the second

Air volume is.

In a subsequent process step, the

Process air stream 22 passed through a heat exchanger 16 and cooled by the also sucked by means of a fan 19 ambient air 18 at a temperature of 45 ⁰ C, for example, 51 ⁰ C. Initially, the relative humidity increases to 100% and then a proportion of the contained in the process air stream 22 condenses

Moisture. In the previously described

exemplary temperature and humidity values are condensed at 51 ⁰ C when cooled, the process air stream 22 about 153 g / kg of water. This amount of water can be removed via an outlet 24 from the process air stream 22 and collected to drinking water or utility water for

 To provide available, which was obtained from the ambient air. The energy required for the operation of the fans 19 and the heating of the process air stream 22 can be obtained via photovoltaic systems, or solar collector systems 23, so that in dry-hot regions in particular efficient drinking water production from the

Ambient air is possible.

Claims

Process for the recovery of a vaporized liquid from an air stream and apparatus for carrying out the process P atentanspr che

1. A process for recovering a vaporized

Liquid from an air stream, characterized in that the evaporated liquid is transferred from a first amount of air into a second amount of air, wherein the second amount of air is less than the first amount of air.

2. The method according to claim 1, characterized in that the evaporated liquid is sorbed from a first amount of air in a sorbent and then desorbed in a second amount of air, wherein the second amount of air is less than the first amount of air.

3. The method according to claim 1 or claim 2, characterized in that the first amount of air and the second amount of air have a same air pressure.

4. The method according to claim 3, characterized in that the air pressure substantially the air pressure of

Ambient air corresponds.

5. The method according to any one of the preceding claims, characterized in that the second air quantity is smaller than a limit air quantity at a desorption of a predeterminable amount of liquid from the sorbent, whose Dew point temperature corresponds after absorption of the desorbed liquid amount of a predetermined minimum temperature.

6. The method according to any one of the preceding claims, characterized in that the predefinable

Dew point temperature of the second air quantity is greater than an outdoor temperature under normal operating conditions.

7. The method according to any one of the preceding claims, characterized in that the second amount of air is circulated in a closed circuit.

8. The method according to any one of the preceding claims, characterized in that the first amount of air is circulated in a closed circuit and the

Evaporative cooling takes place within this cycle.

9. The method according to any one of claims 1 to 7, characterized in that the first amount of air from the

 Ambient air is sucked in.

10. The method according to claim 9, characterized in that the first amount of air is cooled before the therein

contained moisture sorbed in a sorbent and then in a second amount of air again

is desorbed.

11. The method according to claim 9 or 10, characterized

characterized in that the second air quantity

condensed liquid is collected and removed.

12. Apparatus for carrying out the foregoing

described method for recovering a

evaporated liquid from an air stream, wherein the evaporated liquid is adsorbed in a sorbent and then desorbed again, characterized

characterized in that the device comprises a container with a plurality of rotatably mounted chambers which are filled with the sorbent and can be flowed through by an air flow.

13. The apparatus according to claim 12, characterized in that the device is a device for

Air flow guide which forms a closed circuit and an air flow through at least one chamber of the container and then passes through a heat exchanger therethrough.

14. The apparatus of claim 12 or claim 13, characterized in that the device is a collecting device for auskondensierende from the second amount of air

Has liquid.

15. Device according to one of claims 12 to 14, characterized in that the container has annularly arranged, rotatably mounted chambers, which with a

 Sorbent are filled and have inflow openings and spaced apart outflow openings for an air flow.