DE10314803A1 - Defogging process for use in an air-conditioned building room, involves dividing air flow into two parts, in which first part is cooled to remove condensate and second part is bypassed without cooling and merged with first part - Google Patents

Abstract

The method involves cooling an air flow to a temperature below dew point to remove condensate from the air flow. Before cooling the air flow, the air flow is divided into two parts (T1,T2). The first part (T1) is cooled to the temperature below dew point to remove condensate from the air flow. The second part (T2) is bypassed without cooling and is merged with first part to form one air flow. After removing the condensate, the air flow is heated to a required temperature level. An independent claim is included for the defogger.

Description

The The invention relates to a method and a device for dehumidifying and tempering an air flow, such as in the building technology within air conditioners and the like for ventilation of clear Find use. Here it is in addition to the desired temperature control, d. H. Cooling or warming the airflow to a desired one Temperature required, for example, sucked in from the environment Fresh air or recirculated air to a moisture content that is conducive to the indoor climate to adjust, which is accordingly a high humidity Dehumidification of the corresponding air flow is necessary.

The previously known methods and devices with Dehumidification function of the air flow is characterized by that the airflow first z. B. by a cold water register or a register with direct evaporator is directed in which the total amount of air down to the dew point cooled down will, so then the condensation and thus dehumidification effect sets in. This cooling will continue, d. H. the airflow continues to cool until the desired one Moisture content in the air is reached while the remaining moisture turns out to be Condensate precipitates and dissipated becomes. Subsequently it will be like this dehumidified but very cooled Air flow is fed to a reheater and, if necessary, d. H. if necessary to a desired one Temperature according to the level of comfort or the necessary minimum injection temperature in z. B. rooms of buildings heated.

This cooling necessary for dehumidification of the entire air flow to a temperature below the dew point however, lying temperature requires a very high performance the cooling register used to cool down the airflow to the desired one Dehumidification even at high outside temperatures and high humidity. At lower outside temperatures and / or lower moisture content of the air flow if necessary, a lower cooling of the air flow already to the desired dehumidification Sufficient measure, so that in in this case the cooling capacity of the cooling register accordingly must be reduced. Such systems are therefore always subject to extreme conditions designed for most of the year due to less needed Performance oversized, which leads to high plant costs and unfavorable production and operating costs leads.

From the US 6,386,281 B1 a ventilation device without a dehumidification function is known, in which the air flow is only partially cooled, while the remaining part of the air flow is bypassed the cold register and does not cool down.

task the invention is a method and an apparatus for dehumidifying and propose tempering an air flow with those at lower Operating costs the dehumidification and temperature control of the air flow can be effected and the energetic relationship of useful cooling purpose Condensation for upstream cooling of the air from ambient temperature is improved to the dew point.

to solution According to the invention, a method is proposed for this task, in which the airflow before cooling into a first and a second partial air flow is split, of which only below the first partial air flow to a temperature below the dew point lying temperature cooled and the condensate is discharged during the second partial air flow without cooling in Bypass continued and both partial air flows again be combined into a total air flow.

The Invention is the consideration based on the desired Moisture content of the air flow by cooling as much as possible and thus producing maximum moisture removal from the first partial air flow, which then follows with the second untreated and with the original moisture content and the original Temperature promoted second air stream is mixed again, resulting in the result the desired moisture content by mixing both partial air flows in the now reunited total air flow.

Provided the resulting in the total air flow brought together again from the partial air flows setting mixing temperature below the comfort level or another pre-adjustable desired temperature, finds reheating if necessary instead of.

According to one Only the first partial air flow is proposed for this purpose after cooling has already taken place and dehumidifying heated in such a way that subsequent mixing with the second partial air flow, which was conducted in the bypass, the desired mixing temperature established.

In an alternative embodiment of the invention it is provided that the cooled and dehumidified first partial air flow with the in the By pass the guided second partial air flow back into the total air flow and then heat the total air flow thus formed to the desired temperature by heating.

Advantageous the air volumes in the two partial air flows are inversely proportional adjustable to each other so that the occurring after the two partial air flows have been mixed again Moisture content of the total air flow exclusively via the Air volume is determined, which over led the first partial air flow and thus cooled and is dehumidified.

To For this purpose, the moisture content of the desired temperature is advantageous total air flow measured and dependent from this measured moisture content the amount of air in the first Partial airflow regulated. Should be more dehumidified according to the measurement result air with increasing volume flow over the first partial air flow guided, chilled and dehumidified in the process. Conversely, if less dehumidification is desired also a lower volume flow over the first partial air flow guided, chilled and dehumidifies. The measurement of the moisture content of the already the desired temperature total air flow is required to achieve drying effects if necessary reheated Total air flow.

The In particular, the invention offers the advantage of a possible Energy-optimized dehumidification if the first partial air flow is independent of the one in it Amount of air on a possible cooled down to low temperature will what z. B. about achieved a constant temperature in the cooling register return can be. This will make one possible small amount of air cooled down within the scope of the system performance and maximum possible dehumidified.

The The degree of dehumidification ultimately achieved then does not exceed one Regulation of the cooling register, but about a regulation of the this cooling register out Volume flow set in the first partial air flow.

To For this purpose, the air volume in the first partial air flow is in the area Infinitely adjustable from 0 to 100% of the total air flow, the rest of the total air flow is about led the second partial air flow.

The Device proposed in the context of the invention for dehumidifying and tempering the air flow comprises an inlet duct in a known manner for the Airflow, a cooling register downstream of the inlet duct to cool down of about the inlet duct in a flow direction to a temperature below the dew point temperature and for draining the one from the cooled Air flowing condensate, and a downstream of the cooling register Post-heater, in which the air flow cooled in the cooling register if necessary to a desired one Temperature warmable is, and an outlet channel for discharging the dehumidified and tempered air flow. To the solution The task is a cooling duct and a bypass duct provided which are connected to the inlet channel in such a way that the guided in the entry channel Air flow in one through the cooling duct and the bypass duct out Partial air flow can be divided and the cooling register is arranged in the cooling channel. In the direction of flow seen behind the cooling register ends the cooling channel together with the bypass duct into the outlet duct.

Around if necessary, heating of the guided in the outlet channel Airflow to a desired one To effect temperature is the reheater according to one embodiment the device according to the invention in connection to the cooling register in the cooling channel arranged so that heating the previously cooled and dehumidified partial air flow in the cooling channel before merging with the second partial air flow from the bypass channel is made possible.

alternative can also be provided that the Outlet channel at its upstream end a mixing channel has, in which the cooling channel and the bypass channel alike open out, to those led in these Partial airflows merge again. In this case, the reheater is also in the mixing channel arranged so that if necessary Heating of the already recombined total air flow the desired Temperature allowed in this case is.

In The moisture content is preferably measured in the outlet channel of the reunited total air flow, depending on from this measurement result then the individual flows of the partial air flows can be variably adjusted.

to Regulation of each through the cooling channel and the bypass channel Air volumes of the partial air flows are in the cooling channel and control devices corresponding to the bypass channel are arranged, for example in the form of flaps or the like.

A control device, which communicates with the sensor for measuring the humidity of the air flow guided in the mixing duct, can be a function of the measurement result of the sensor then control the control devices accordingly.

Around always funding of the whole of the The control elements are to ensure the entry channel of the incoming air flow each can be controlled and made inversely proportional to each other an opposite Regulation of the partial air flows in a proportion of 0 to 100% of the total air flow.

Under inversely proportional or reverse regulation of the partial air flows in one According to the invention, a proportion of 0 to 100% of the total air flow becomes a regulation understood, in which in the first extreme case the bypass channel is fully opened and the cooling channel Completely is closed, so that the Total air flow exclusively over the Bypass channel led and in the second extreme case the reverse air flow takes place, d. H. the bypass channel completely is closed and the cooling duct is fully open and leads 100% of the total air flow. Under the scheme of the method according to the invention and the device are then all between these extreme values Intermediate values, such as 70% to 30% or 60% to 40% etc. for the cooling and Bypass channel adjustable.

Further Details of the method according to the invention and the device are explained below with reference to the drawing.

It demonstrate:

1 an embodiment of the device according to the invention,

2 a further embodiment of the device according to the invention.

The 1 shows a schematic representation of a device for dehumidifying and tempering an air stream that enters the device in the direction of arrow E.

The device comprises a channel system which, viewed in the direction of flow according to arrow E, from an inlet channel 10 goes out, which is subsequently in a cooling channel 11 and a bypass channel 12 branches further downstream into a mixing channel 13 merge and ultimately in a discharge channel 14 for the exiting air flow according to arrow A ends.

In the cooling channel 11 is a cooling register 4 arranged in the area between the mixing channel 13 and the discharge channel 14 is a reheater 5 arranged.

The How that works shown device and the underlying method is the following.

First, an air flow according to arrow E enters the inlet duct 10 z. B. by funding with one in the entry channel 10 arranged fan 2 on. The entering air flow according to arrow E can be, for example, a pure fresh air flow, a returning air flow from a building or a mixture of fresh air and returning air flow.

At the downstream end of the entry channel 10 this branches into the cooling channel 11 and the bypass channel 12 , the incoming air flow E is divided into two partial air flows T1, T2, the partial air flow T1 via the cooling duct 11 and the partial air flow T2 via the bypass duct 12 to be led.

The respective air volumes in the partial air flows T1, T2 are in the entrance area of the cooling duct 11 and the bypass channel 12 arranged control elements 3a . 3b determined for example in the form of pivotable flaps.

The one over the cooling channel 11 Partial air flow T1 flows into the inside of the cooling channel 11 arranged cooling register 4 , for example a cold water register or a register with a direct evaporator and is subjected to the greatest possible cooling to a temperature below the dew point, so that condensate fails, which flows through a condensate drain 40 is dissipated. As a result, the partial air flow T1 experiences when it passes through the cooling register 4 a strong cooling and at the same time dehumidification, which is in the liquid condensate discharged at the condensate drain 40 reflected.

After this cooling and dehumidification in the cooling register 4 The partial air flow T1 then flows into the mixing duct 13 on.

In contrast to that, it experiences via the bypass channel 12 guided partial air flow T2 has no influence on its temperature or its moisture content and also enters the mixing duct with the temperature and moisture content, which is essentially unchanged from the incoming air flow E. 13 where the second partial air flow T2 mixes with the greatly cooled and dried partial air flow T1 and in turn forms a total air flow T3 and combines. However, this new total air flow T3 formed from the partial air flows T1 and T2 has a lower temperature and a lower moisture content than the incoming air flow E due to the strong cooling and dehumidification of the partial air flow T1.

This total air flow T3, cooled and dehumidified in this way, now flows through the mixing duct 13 in the reheater 5 , in which the total air flow T3 is heated to the desired temperature according to the level of comfort. Then the airflow through the outlet duct 14 dissipated as a temperature-controlled and dehumidified air stream A and, for example, passed into a room.

A sensor is used to regulate the moisture content of the total air flow T3 and thus also the ultimately emerging air flow A 32 the moisture content of the total air flow T3 after passing through the reheater 5 measured when the desired mixing of the partial air flows T1, T2 and the necessary heating has taken place.

This measurement in the area of the outlet channel 14 drying effects due to the need to heat the total air flow T3 in the reheater are also taken into account.

A control device 31 compares that from the humidity sensor 32 measured value with a target value and can with deviations via an actuator 30 the position of the control elements 3a . 3b change.

The control elements 3a . 3b are each infinitely adjustable between fully open and fully closed, but inversely proportional to one another, so that a correspondingly opposite distribution of the air quantities in the partial air flows T1, T2 is achieved.

Now on the moisture sensor 32 If the air humidity is too high compared to the set target value, the control device initiates it 31 a larger opening of the control valve 3a inside the cooling channel 11 and a corresponding reverse reversal of that from the control valve 3b approved cross-section of the bypass channel 12 , so that the partial air flow T1, which via the cooling channel 11 flows, increases in volume, and to the same extent the partial air flow T2 via the bypass duct 12 decreases in quantity.

Because the cooling register 4 a cooling of the partial air flow T1 in the cooling channel 11 to a temperature as low as possible for the purpose of the greatest possible dehumidification, a larger amount of air, which is now conveyed in the partial air flow T1, is cooled to this temperature and dehumidified, so that after the subsequent mixing in the mixing duct 13 the resulting total moisture content in the total air flow T3 is reduced accordingly. A correspondingly at the cooling register 4 The control valve provided (not shown) constantly controls the return temperature of the cooling medium in order to always achieve the maximum possible cooling and dehumidification within the scope of the available cooling capacity.

The control device moves in a correspondingly reverse manner 31 if the moisture content from the sensor is too low 32 within the mixing channel 13 is measured. In this case, the control device reduces 31 that of the control device 3a approved cross section of the cooling channel 11 and increases that of the control device 3b approved cross-section of the bypass channel 12 by the same amount, so that the amount of air in the partial air flow T1 decreases and increases accordingly in the partial air flow T2. In this way, a smaller amount of air is now on the cooling channel 11 the cooling register 4 supplied and cooled there and dehumidified, so that the moisture content in the reunited total air flow T3 increases.

In this way, the cooling register can always be operated in the economically optimal range, with only a partial amount of air always having to be cooled and, accordingly, only a small amount of reheating in the reheater 5 is necessary, which saves further energy.

The reheater 5 can in a known manner, for. B. by means of pump hot water heating cause the heating of the total air flow T3.

In addition, the bypass arrangement to the cooling register 4 by means of the bypass channel 12 in operating times without dehumidification and cooling, e.g. B. in winter, also electrical drive energy for the fan 2 can be saved because then by completely closing the cooling channel 11 by means of the control device 3a the total air flow through the bypass duct 12 can be performed and the resistance of the cooling register does not have to be overcome, which results in a reduced drive power required for air transport by the fan 2 Precipitation takes place.

In the other extreme case the very high temperature and humidity of the incoming air flow E becomes the bypass duct 12 by means of the control device 3b completely closed and the entire air flow via the cooling duct 11 managed and in the cooling register 4 subjected to cooling and dehumidification.

The 2 shows an alternative embodiment of the invention, the same parts with the same reference numerals as in 1 are provided and are not explained again.

In contrast to the exemplary embodiment according to 1 open the cooling channel 11 and the By right channel 12 directly into the outlet channel 14 a, in which the total air flow T3 is formed from the recombined partial air flows T1 and T2 and the device via the outlet duct 14 leaves as a tempered and dehumidified air stream A.

The reheater 5 for heating the total air flow T3 as required is in this case connected to the cooling register 4 inside the cooling channel 11 arranged so that the previously in the cooling register 4 cooled and dehumidified partial air flow T1 can be heated if necessary before being combined with the partial air flow T2. A desired mixture temperature in the total air flow T3 can thus ultimately be regulated.

The remaining function of the device according to 2 corresponds to that already based on 1 described device. The control of the reheater 5 takes place in both embodiments by means of temperature sensors, not shown, which z. B. adjacent to the sensor 32 are arranged. The control of the reheater 5 can then also in the control device 31 be integrated.

Claims (14)

A method for dehumidifying and controlling the temperature of an air stream, wherein in a first step the air flow to a below the dew point lying temperature cooled and the condensate from the air stream is discharged and, if necessary, the air stream is heated to a desired temperature in a second step, characterized characterized in that the air flow before cooling is divided into a first and a second partial air flow (T1, T2), of which only the first partial air flow (T1) is subsequently cooled to a temperature below the dew point temperature and the condensate is discharged during the second partial air flow (T2) is continued without cooling in the bypass and subsequently both partial air flows (T1, T2) are brought together again to form a total air flow (T3). A method according to claim 1, characterized in that for warming as needed the airflow to the desired one Temperature of the partial air flow (T1) heated after cooling and then with the Partial airflow (T2) is combined to form the total airflow (T3). A method according to claim 1, characterized in that for warming as needed the airflow to the desired one Temperature of the merged partial air flows (T1, Total air flow (T3) formed is heated. Method according to one of claims 1 to 3, characterized in that that the Air volumes in the partial air flows (T1, T2) can be regulated in inverse proportion to each other. Method according to one of claims 1 to 4, characterized in that that the Moisture content of the desired Total air flow temperature (T3) measured and the Air volume in the first partial air flow (T1) depending on the measured Moisture content is regulated. Method according to one of claims 1 to 5, characterized in that that the Air volume in the first partial air flow (T1) in the range from 0 to 100 % of the total air flow is regulated. Device for dehumidifying and tempering an air stream, comprising an inlet duct ( 10 ) for the air flow, an the inlet duct ( 10 ) downstream cooling register ( 4 ) for cooling the via the inlet channel ( 10 ) air flow brought up in a flow direction to a temperature below the dew point temperature and to discharge the condensate precipitating from the cooled air flow, one to the cooling register ( 4 ) downstream reheater ( 5 ), in which the in the cooling register ( 4 ) cooled air flow can be heated to a desired temperature if necessary, and an outlet duct ( 14 ) for removing the dehumidified and tempered air flow, characterized in that a cooling duct ( 11 ) and a bypass channel ( 12 ) are provided, which are connected to the inlet channel ( 10 ) are connected in such a way that the in the inlet channel ( 10 ) led air flow (E) in one through the cooling channel ( 11 ) and the bypass channel ( 12 ) guided partial air flow (T1, T2) can be split and the cooling register ( 4 ) in the cooling channel ( 11 ) is arranged and the cooling duct ( 11 ) seen in the flow direction behind the cooling register ( 4 ) together with the bypass channel ( 12 ) in the outlet channel ( 14 ) flow into. Apparatus according to claim 7, characterized in that the reheater ( 5 ) seen in the flow direction behind the cooling register ( 4 ) in the cooling channel ( 11 ) is arranged. Apparatus according to claim 7, characterized in that the outlet channel ( 14 ) at its upstream end a mixing channel ( 13 ) in which the cooling channel ( 11 ) and the bypass channel ( 12 ) and the reheater ( 5 ) in the mixing channel ( 13 ) is arranged. Device according to one of claims 7 to 9, characterized in that in the cooling duct ( 11 ) and the bypass channel ( 12 ) Control devices ( 3a . 3b ) to regulate each through the cooling channel ( 11 ) and the bypass channel ( 12 ) guided air quantities of the partial air flows (T1, T2) are arranged. Device according to one of claims 7 to 10, characterized in that a sensor ( 32 ) to measure the humidity of the in the outlet channel ( 14 ) guided air flow is provided. Device according to claim 11, characterized in that a control device ( 31 ) is provided, which is dependent on the measurement result of the sensor ( 32 ) the control devices ( 3a . 3b ) controls. Device according to one of claims 10 to 12, characterized in that the control elements ( 3a . 3b ) can be controlled inversely proportional to each other and an opposing regulation of the partial air flows in a proportion of 0 to 100% of that in the inlet duct ( 10 ) guided air flow (E) can be effected. Device according to one of claims 7 to 13, characterized in that the cooling register ( 4 ) a condensate drain ( 40 ) to remove the condensate.