CH657692A5 - Dehumidifying unit for essentially closed rooms - Google Patents

Abstract

The dehumidifying unit comprises a fan (11) which draws in the room air, there being arranged one after the other in the flow region of the air drawn in an evaporator (8) connected to a compressor (9) and a condenser (10). The evaporator (8) and the condenser (10) are arranged in counterflow, there being arranged on the afflux side of the evaporator (8) and on the afflux side of the condenser (10) a counterflow heat exchanger (12) which is common to these. A dehumidifying unit of this type is characterised in particular by lowering the energy quantities required henceforth by more than half or by way of comparison to at least a doubling of the dehumidifying capacity. <IMAGE>

Description

       

  
 

** WARNING ** beginning of DESC field could overlap end of CLMS **.

 



   PATENT CLAIMS
1. Dehumidification unit for essentially closed rooms, with a fan sucking in the room air, an evaporator and a condenser connected to a compressor being arranged in succession in the flow area of the sucked-in air, characterized in that the evaporator (8) and the condenser (10) are arranged in countercurrent, a common countercurrent heat exchanger (12) being arranged on the upstream side of the evaporator (8) and on the upstream side of the condenser (10).



   2. Dehumidifying unit according to claim 1, characterized in that in the unit housing (1) a counterflow channel is formed with an air-side chamber (4) and an air-side chamber (5), between which chambers there is a chamber partition (13) up to a deflection area (6 ) extends.



   3. Dehumidifying unit according to claim 2, characterized in that the countercurrent heat exchanger (12) penetrates the chamber partition (13) and passes through the chambers (4, 5) with one register side each.



   4. dehumidifying unit according to claim 1, characterized in that the countercurrent heat exchanger (12) comprises two register halves.



   5. Dehumidifying unit according to claim 2, characterized in that the compressor (9) is arranged in the deflection area (6).



   6. Dehumidifying unit according to claim 2, characterized in that in the unit housing (1) a third lower chamber (3) is formed, which is in flow connection via a condensate drain (14) with the supply air-side chamber (4) and which is to accommodate the condensate Collection container (15) is used.



   The present invention relates to a dehumidification unit for essentially closed rooms, with a fan sucking in the room air, an evaporator connected to a compressor and a condenser being arranged in succession in the flow region of the sucked-in air.



   Room air dehumidifiers of the aforementioned type have been known for a long time and are commercially available, whereby such dehumidification units have a wide range of applications and dehumidify the room air in living and working spaces, museums, archives, civil protection rooms, vaults, hospitals and others. serve.



   The known room air dehumidifiers all work on the same principle, in that the moist room air is sucked in by a fan and cooled to below the dew point on the working surfaces of an evaporator. Here, the excess water vapor is excreted as condensed water. The dried air is then passed over the heat exchange surfaces of a condenser, reheated there and returned to the room at a predetermined temperature.



   It is now readily apparent that these units, which are proven per se, are subject to a relatively high level of energy consumption and thus no longer meet today's requirements for energy-saving devices.



   It is therefore an object of the present invention to provide a dehumidifying unit of the aforementioned type which, with unchanged effectiveness, requires a significantly lower energy requirement or provides a significantly higher dehumidifying performance with comparable energy consumption.



   This is achieved according to the invention in that the evaporator and the condenser are arranged in countercurrent, a countercurrent heat exchanger which is common to them being arranged on the upstream side of the evaporator and on the upstream side of the condenser.



   By means of these measures according to the invention, it is now possible to first lower the temperature of the supply air to the evaporator at the upstream countercurrent heat exchanger, with the result that the evaporator itself is substantially relieved. At the same time, however, the counterstorm heat exchanger preheats the dry and cold exhaust air again before it enters the condenser, so that the condenser is also relieved, which overall, with known arrangements, leads to a comparative reduction in the amounts of energy now required by more than half or more leads to at least a doubling of the dehumidification performance.



   It is advantageous for a compact and stable construction of this unit if a counterflow duct with an air-side chamber and an air-side chamber is formed in the unit housing, between which chambers a chamber partition extends to a deflection area.



   This results in a rational and effective structural arrangement in that the counterflow heat exchanger penetrates the chamber wall and passes through the chambers with one register side each, the counterflow heat exchanger comprising two register halves.



   If the compressor is arranged in the deflection area, both effective cooling of the compressor and further preheating of the dried and strongly cooled air can be achieved.



   Furthermore, the compact design can be further improved by forming a third lower chamber in the unit housing, which is in flow connection with the supply-side chamber via a condensate drain and which serves to accommodate the condensate collecting container.



   An example embodiment of the subject matter of the invention is explained in more detail below with reference to the drawing.



   The dehumidification unit according to the invention comprises a housing 1 in a compact design, which is preferably supported on swivel castors 2 in a mobile manner. The housing is divided by horizontal partition walls 13 and 13 'into essentially three chambers 3, 4 and 5, the upper chambers 4 and 5 forming a counterflow channel and these chambers being in flow connection via a deflection area 6. Here, the air-side chamber 4 opens out via an inflow opening 16 and the air-side chamber 5 via a fan 11 which sucks in the air.



  The inflow opening 16 is usually covered by a protective screen 17, which is followed by an air filter 7.



   On the outflow side of the air-side chamber 4, an evaporator 8 is arranged, the cold of which is generated by a compressor 9, which is preferably arranged in the deflecting space region 6 in the circulating air flow. Furthermore, a condenser 10 is connected upstream of the fan 11 in the exhaust-side chamber 5.



   According to the invention, a common counterflow heat exchanger 12 is now arranged on the upstream side of the evaporator 8 and on the upstream side of the condenser 10, which passes through the chamber wall 13 and passes through the chamber 4 and the chamber 5 with one register side each.



   This countercurrent heat exchanger 12 can be of any type. However, heat exchangers based on the principle of the heat pipe are preferred. Such countercurrent heat exchangers are laminated registers that are connected to a number of individual heat pipes and with a flow



  work equipment is filled. The heat supplied on the warm side causes this liquid to evaporate, which condenses steam on the cold side and releases its heat to the cold air flow. This cycle is kept in motion solely by the temperature difference between the two air streams in the air-side chamber 4 or at the entrance to the air-side chamber 5, without the need for external energy, which means that generally 40-80% of the power can be economically recovered.



   As can now be seen from the drawing, the moist room air of, for example, 21 ° C. flows against the countercurrent heat exchanger 12 on its one register side in order to give off part of its thermal energy there. This air then flows onto the evaporator 8 at, for example, 14 ° C., where a further drying of the air and a further cooling to approximately 7 ° C. can take place, for example. The dry and cold air then deflected into the counterflow of the chamber 5 is then preheated again in the other register side of the counterflow heat exchange 12, for example to 14 ° C. to be heated to the desired final temperature, for example 22 ° C., before exiting into the space in the condenser 10.

  In addition, with a suitable arrangement of the compressor 9, the deflected air flow can cool the compressor 9 and already absorb thermal energy here.



   Of course, it is possible to fully dehumidify the dehumidification unit, i.e. operate with hygrostat and water level control.



   In this case, a relatively large condensate collecting container 15 is provided for receiving the condensed water in the lower chamber 3, to which the condensed water is supplied via a drip tray 14, which establishes the flow connection to the air-side chamber 4 or to the evaporator 8 arranged there.



   The above results in a dehumidifying unit of robust and compact design, which fully meets the requirements placed on an energy-conscious concept.


    

Claims (6)

 PATENT CLAIMS 1. Dehumidification unit for essentially closed rooms, with a fan sucking in the room air, an evaporator and a condenser connected to a compressor being arranged in succession in the flow area of the sucked-in air, characterized in that the evaporator (8) and the condenser (10) are arranged in countercurrent, a common countercurrent heat exchanger (12) being arranged on the upstream side of the evaporator (8) and on the upstream side of the condenser (10).  2. Dehumidifying unit according to claim 1, characterized in that in the unit housing (1) a counterflow channel is formed with an air-side chamber (4) and an air-side chamber (5), between which chambers there is a chamber partition (13) up to a deflection area (6 ) extends.  3. Dehumidifying unit according to claim 2, characterized in that the countercurrent heat exchanger (12) penetrates the chamber partition (13) and passes through the chambers (4, 5) with one register side each.  4. dehumidifying unit according to claim 1, characterized in that the countercurrent heat exchanger (12) comprises two register halves.  5. Dehumidifying unit according to claim 2, characterized in that the compressor (9) is arranged in the deflection area (6).  6. Dehumidifying unit according to claim 2, characterized in that in the unit housing (1) a third lower chamber (3) is formed, which is in flow connection via a condensate drain (14) with the supply air-side chamber (4) and which is to accommodate the condensate Collection container (15) is used.  The present invention relates to a dehumidification unit for essentially closed rooms, with a fan sucking in the room air, an evaporator connected to a compressor and a condenser being arranged in succession in the flow region of the sucked-in air.  Room air dehumidifiers of the aforementioned type have been known for a long time and are commercially available, whereby such dehumidification units have a wide range of applications and dehumidify the room air in living and working spaces, museums, archives, civil protection rooms, vaults, hospitals and others. serve.  The known room air dehumidifiers all work on the same principle, in that the moist room air is sucked in by a fan and cooled to below the dew point on the working surfaces of an evaporator. Here, the excess water vapor is excreted as condensed water. The dried air is then passed over the heat exchange surfaces of a condenser, reheated there and returned to the room at a predetermined temperature.  It is now readily apparent that these units, which are proven per se, are subject to a relatively high level of energy consumption and thus no longer meet today's requirements for energy-saving devices.  It is therefore an object of the present invention to provide a dehumidifying unit of the aforementioned type which, with unchanged effectiveness, requires a significantly lower energy requirement or provides a significantly higher dehumidifying performance with comparable energy consumption.  This is achieved according to the invention in that the evaporator and the condenser are arranged in countercurrent, a countercurrent heat exchanger which is common to them being arranged on the upstream side of the evaporator and on the upstream side of the condenser.  By means of these measures according to the invention, it is now possible to first lower the temperature of the supply air to the evaporator at the upstream countercurrent heat exchanger, with the result that the evaporator itself is substantially relieved. At the same time, however, the counterstorm heat exchanger preheats the dry and cold exhaust air again before it enters the condenser, so that the condenser is also relieved, which overall, with known arrangements, leads to a comparative reduction in the amounts of energy now required by more than half or more leads to at least a doubling of the dehumidification performance.  It is advantageous for a compact and stable construction of this unit if a counterflow duct with an air-side chamber and an air-side chamber is formed in the unit housing, between which chambers a chamber partition extends to a deflection area.  This results in a rational and effective structural arrangement in that the counterflow heat exchanger penetrates the chamber wall and passes through the chambers with one register side each, the counterflow heat exchanger comprising two register halves.  If the compressor is arranged in the deflection area, both effective cooling of the compressor and further preheating of the dried and strongly cooled air can be achieved.  Furthermore, the compact design can be further improved by forming a third lower chamber in the unit housing, which is in flow connection with the supply-side chamber via a condensate drain and which serves to accommodate the condensate collecting container.  An example embodiment of the subject matter of the invention is explained in more detail below with reference to the drawing.  The dehumidification unit according to the invention comprises a housing 1 in a compact design, which is preferably supported on swivel castors 2 in a mobile manner. The housing is divided by horizontal partition walls 13 and 13 'into essentially three chambers 3, 4 and 5, the upper chambers 4 and 5 forming a counterflow channel and these chambers being in flow connection via a deflection area 6. Here, the air-side chamber 4 opens out via an inflow opening 16 and the air-side chamber 5 via a fan 11 which sucks in the air. The inflow opening 16 is usually covered by a protective screen 17, which is followed by an air filter 7.  On the outflow side of the air-side chamber 4, an evaporator 8 is arranged, the cold of which is generated by a compressor 9, which is preferably arranged in the deflecting space region 6 in the circulating air flow. Furthermore, a condenser 10 is connected upstream of the fan 11 in the exhaust-side chamber 5.    According to the invention, a common counterflow heat exchanger 12 is now arranged on the upstream side of the evaporator 8 and on the upstream side of the condenser 10, which passes through the chamber wall 13 and passes through the chamber 4 and the chamber 5 with one register side each.  This countercurrent heat exchanger 12 can be of any type. However, heat exchangers based on the principle of the heat pipe are preferred. Such countercurrent heat exchangers are laminated registers that are connected to a number of individual heat pipes and with a flow ** WARNING ** End of CLMS field could overlap beginning of DESC **.