DE19903280A1 - Ventilation device has Peltier element(s) for cooling or heating fresh air flow between fresh air chamber and outgoing air chamber or between incoming air chamber and used air chamber - Google Patents

Abstract

The ventilation device has an incoming air chamber (1) and a fresh air chamber (2) for the fresh air flow, a used air chamber (3) and an outgoing air chamber (4) for the used air flow (8) and a cross-flow heat exchanger (5) for exchanging heat between the used and fresh air. At least one Peltier element for cooling or heating the fresh air flow is arranged between the fresh air chamber and the outgoing sir chamber or the incoming air chamber and the used air chamber

Description

The invention relates to a ventilation device with a supply air chamber and Fresh air chamber for the fresh air flow, an exhaust air chamber and an exhaust air chamber for the exhaust air flow and a cross-flow heat exchanger for heat exchange between the exhaust air and the supply air.

Such a ventilation device is known from DE 44 12 844 A1. With the known device fresh air is supplied to a room and exhaust air is extracted. For Warming of the fresh air flow is behind the cross flow heat exchanger in the Fresh air flow arranged a heat accumulator or an electric radiator. A Unfortunately, the possibility of cooling the fresh air flow is not intended.

DE 195 49 183 A1 is a device for air conditioning a room known, which is a soundproof ventilation system with one or more Peltier elements. The Peltier elements are used for heating or cooling the Outside air used, the known device on an outside, for example a house wall. The air heated or cooled in this way becomes then led into the room to be air-conditioned by means of an air duct. The known device is not designed to cope with an exhaust air flow and thus unsuitable for indoor use.

The object of the invention is thus seen in a ventilation device type mentioned at the same time the heating and cooling of the fresh air stream to enable.

To solve this problem, the invention proposes that the Ventilation device according to the preamble of claim 1 at least one Peltier element for cooling or heating the fresh air flow between the fresh air chamber and the exhaust air chamber or the supply air chamber and the exhaust air chamber is arranged.

A Peltier element consists of two semiconductor legs, one of which is n-conducting, the other is p-type. The two legs are on hers through a copper bridge Front side connected. If a direct current flows through this Peltier element, it cools  removes one side of the element and consequently removes it from the surroundings Thermal energy. The thermal energy absorbed by the cold element side becomes returned to the environment on the opposite warm side. By Current reversal can reverse the direction of heat flow, causing the cold Side to the warm side and the warm side to the cold side. At one in the company Peltier element located is therefore, depending on the polarity, a warm one, for example Given front and an opposite cold back. Through the Arrangement of the Peltier element between the fresh air chamber and the exhaust air chamber or between the supply air chamber and the exhaust air chamber is one side of the Peltier element, for example the back, facing the fresh air flow. Each after whether the fresh air flow should be cooled or heated, the Current polarity selected so that the side facing the fresh air flow is cooled or is heated. If the ventilation unit is operating, the fresh air flow now cuts it off Over the side of the Peltier element, the fresh air is cooled or heated. Through the special arrangement of the at least one Peltier element between the chambers there is the further advantage that the exhaust air flow is also cooled or heated can, and vice versa for cooling or heating the fresh air flow. This creates a ventilation device with which the fresh air flow is cooled or can be heated and also the exhaust air flow cooled or heated can be.

The individual chambers are generally separated by partitions. To one Saving partition, provides a development of the invention that Peltier element essentially a partition between the fresh air chamber and the exhaust air chamber or the supply air chamber and the exhaust air chamber.

In order to obtain the largest possible cooling surface or heating surface, which by the Fresh air flow is swept, provides a further embodiment of the invention that several Peltier elements are arranged within a Peltier block and the Peltier block has a base block and a pressure plate, the Peltier elements are arranged between the base block and the pressure plate. This will vary depending Current polarity of the base block, for example directed towards the fresh air flow, the cold one Side and the pressure plate facing the exhaust air flow with the warm side large surface area.  

For the greatest possible cooling and heating capacity see another Embodiment of the invention that several, in particular six, Peltier blocks are arranged in a Peltier block cascade. The Peltier blocks are in series switched. The cooling capacity can be further increased by using the Peltier block or the Peltier block cascade preferably has at least one heat sink. This increases the cooling surface exposed to the fresh air flow. The Peltier block or the Peltier block cascade can also have two heat sinks, whereby a first heat sink with the block base and a second heat sink with the pressure plate connected is.

A particularly preferred embodiment of the invention provides that in the Partition between the fresh air chamber and the exhaust air chamber an opening is provided. On the base block facing the fresh air chamber and also on the heat sink located in the fresh air chamber beats when cooling Fresh air condensation water down. This then flows through the opening of the Fresh air chamber in the exhaust air chamber and is taken up there by the exhaust air and transported outdoors. Since the exhaust air also carries off the waste heat from the Peltier block and thus heated, is the absorbency of the exhaust air for the resulting Sufficient condensation water. This allows the fresh air that enters the room is dehumidified in the ventilation unit.

With the ventilation device according to the invention it is also possible to get out of the room dehumidifying exhaust air and returning it back to the room. For this provides a further particularly preferred embodiment of the invention that in the partition between the exhaust air chamber and the fresh air chamber a first Flap and one in the partition between the supply air chamber and the exhaust air chamber second flap are arranged and a first closure element for closing the inlet side of the cross flow heat exchanger and a second one Closure element for closing the inlet side of the exhaust air chamber Cross-flow heat exchanger are provided. Become the first flap and the second The flap is open and the two input sides of the cross-flow heat exchanger closed, then the air flows change such that the fresh air flow from the Supply air chamber flows into the exhaust air chamber and the exhaust air flow from the exhaust air chamber flows into the fresh air chamber. The exhaust air flow then sweeps in the fresh air chamber past the Peltier block and can be cooled, taking condensation  arises. This is then through the exhaust air chamber as described above the fresh air stream now located in the exhaust air chamber is removed. The first Flap and the second flap are advantageously by a common Damper actuator actuated.

At high air humidity and additionally low temperature, the waste heat can the exhaust air chamber can be returned to the room by the fresh air flow is replaced by a room air flow. This is the entry for the fresh air in the The supply air chamber and the outlet in the exhaust air chamber are closed. The room air flows then into the supply air chamber, further into the exhaust air chamber, here takes the waste heat of the Peltier block and flows out into the room again. By the share thus obtained the efficiency of air dehumidification is significantly increased in heated room air. The condensed water that is in the fresh air chamber Heat sink precipitates, can be collected in a funnel and with a line for example, be discharged to the outside.

One sees for a high throughput of the fresh air flow and the exhaust air flow another embodiment of the invention that a for the fresh air flow Fresh air blower and an exhaust air blower in the flow direction behind for the exhaust air flow the cross-flow heat exchanger are arranged. The air flows are thus in effectively drawn through the heat exchanger.

So that the power supplies required for the blowers and others Power supplies do not heat the fresh air flow in the fresh air chamber a development of the invention that the power supplies for Fresh air blower, the exhaust air blower and the Peltier element in the exhaust air chamber are arranged.

To purify the air in a further embodiment of the invention first filter for the exhaust air flow in the exhaust air chamber and a second filter for the Fresh air flow in the supply air chamber and a third filter and a fourth filter for the Fresh air flow is provided in the fresh air chamber. So that the filters mutually are replaceable, the filters are expediently of an identical size. To the To be able to remove and replace filters in a simple manner, it is advantageous  that the first filter, the third filter and the fourth filter in one housing wall are arranged. This makes the filters easily accessible.

In order to reduce the operating noise of the ventilation unit, especially at high outputs to reduce, a further embodiment of the invention provides that a soundproofing lining is provided. For this purpose, it is convenient The inside of the housing wall is lined with noise-reducing mats.

The invention is explained below with reference to the drawing. The drawing shows an embodiment of the invention. Here represent:

Fig. 1 shows a cross section through the ventilation device,

Fig. 2 shows the ventilation apparatus of FIG. 1 in a Luftentfeuchtungsbetrieb,

Fig. 3 is a plan view of a Peltier block cascade and

Fig. 4 is a partially broken side view of FIG. 3.

The ventilation device has a supply air chamber 1 , a fresh air chamber 2 , an exhaust air chamber 3 , an exhaust air chamber 4 , a cross-flow heat exchanger 5 and a Peltier block 6 . The Peltier block 6 is arranged between the fresh air chamber 2 and the exhaust air chamber 4 . In normal operation or air exchange operation, as shown in FIG. 1, a fresh air flow 7 runs from the supply air chamber 1 through the cross-flow heat exchanger 5 into the fresh air chamber 2 . The fresh air flow 7 runs diagonally through the ventilation device. In a direction perpendicular to the diagonal direction of the fresh air flow 7 and likewise diagonal through the ventilation device, an exhaust air flow 8 runs from the exhaust air chamber 3 through the cross-flow heat exchanger 5 into the exhaust air chamber 4 . The individual chambers 1 , 2 , 3 , 4 are delimited on the outside by a housing 9 . The inlet air chamber 1 is delimited on the inside by an inlet side 10 of the cross-flow heat exchanger 5 . The exhaust air chamber 3 is limited on the inside by an inlet side 11 of the cross-flow heat exchanger 5 . Furthermore, the fresh air chamber 2 is delimited by an outlet side 12 of the cross-flow heat exchanger 5 and the exhaust air chamber 4 by an outlet side 13 of the cross-flow heat exchanger 5 . The individual chambers are separated from one another by partition walls, the supply air chamber 1 from the exhaust air chamber 3 by a partition wall 14 , the exhaust air chamber 3 by the fresh air chamber 2 by a partition wall 15 with a first flap 16 , and the fresh air chamber 2 by the exhaust air chamber 4 by a partition wall 17 and the exhaust air chamber 4 are separated from the supply air chamber 1 by a partition 18 with a second flap 19 . The partition 17 is essentially formed by the Peltier block 6 . The partition 17 has an opening 20 towards the housing 9 , which serves as a drain for condensed water.

An inlet opening 21 for the fresh air is provided in the supply air chamber 1 . Further inlet openings 22 for the room air are arranged in a side wall of the housing 9 and an underside of the housing 9 . An inlet opening 23 for the exhaust air is provided in the side wall of the housing 9 in the area of the exhaust air chamber 3 . An outlet opening 24 for the fresh air is provided in the housing 9 on the top and on the side wall. In the area of the exhaust air chamber 4 there is an outlet opening 25 for continuing the exhaust air to the outside and further outlet openings 26 for continuing the exhaust air flow 8 into the room. The outlet openings 26 are located on the side wall and the underside of the housing 9 .

The inlet opening 23 is covered with a first filter 27 for the exhaust air flow 8 . A second filter 28 for the fresh air flow 7 is arranged in the supply air chamber 1 . A third filter 29 and a fourth filter 30, also for the fresh air flow, are provided in the outlet openings 24 . All filters 27 , 28 and 29 are of identical size.

A fresh air blower 31 is provided in the fresh air chamber 2 and an exhaust air blower 32 is provided in the exhaust air chamber 4 . Further, in the exhaust air chamber 4, the power supply for the fresh air blower 31, the power supply to the exhaust fan 32 and the power supply for the Peltier block 6 is arranged.

The Peltier block 6 has a base block 36 , Peltier elements 37 and a pressure plate 38 . The Peltier elements 37 are arranged between the base block 36 and the pressure plate 38 . The Peltier elements 37 are electrically connected in series. However, thermally, the Peltier elements 37 are parallel, so that all cold sides are on one block side. The surface of the base block 36 faces the fresh air chamber 2 and the surface of the pressure plate 38 faces the exhaust air chamber 4 . A cooling body 39 is attached to the Peltier block 6 , facing the fresh air chamber 2 , and a cooling body 40 facing the exhaust air chamber 4 .

A total of six Peltier blocks 6 can be arranged to form a Peltier block cascade 41 . The Peltier blocks 6 are electrically connected in series. They are thermally parallel, so that all cold sides are on one side. Each Peltier block 6 has about 100 watts of thermal power and 65 watts of cooling power. In the ventilation device shown in FIGS . 1 and 2, the Peltier block cascade 41 has six Peltier blocks 6 .

In operation of the ventilation unit according to the invention in normal operation or air exchange operation according to Fig. 1, the fresh air flow 7 enters via the inlet opening 21 into the air supply chamber 1 and is drawn through the cross-flow heat exchanger 5 by means of the fresh air blower 31 and then enters into the fresh air chamber 2. Here the fresh air flow 7 sweeps over the surface of the base block 36 of the Peltier block 6 and exits via the outlet openings 24 into the space to be ventilated. If the fresh air stream 7 is to be cooled, the power supply for the Peltier elements 37 in the Peltier block 6 is polarized such that the base block 36 is the cool side of the Peltier block 6 . This enables cooling of the fresh air flow 7 . If the fresh air stream 7 is to be heated, the power supply for the Peltier block 6 is reversed and the base block 36 is the warm side of the Peltier block 6 . As a result, the fresh air flow 7 is heated. The fresh air stream 7 can thus be cooled or heated as required. At the same time, the exhaust air flow 8 enters the exhaust air chamber 3 via the inlet opening 23 and is drawn through the cross-flow heat exchanger 5 by the exhaust air blower 32 and enters the exhaust air chamber 4 . In the exhaust air chamber 4, the exhaust air stream 8 sweeps over the pressure plate 38 of the Peltier block 6 , is heated if the pressure plate 38 forms the warm side of the Peltier block 6 , and is continued via the outlet opening 25 .

In the operation shown in FIG. 2 for dehumidifying the exhaust air, the fresh air flow 7 and the exhaust air flow 8 are deflected. For this purpose, the first flap 16 is opened and a closure element 42 on the inlet side 11 of the cross-flow heat exchanger 5 is closed. As a result, the exhaust air flow 8 is not passed through the cross-flow heat exchanger 5 , but instead passes directly from the exhaust air chamber 3 into the fresh air chamber 2 . Furthermore, the second flap 19 is open and a closure element 43 on the inlet side 10 of the cross-flow heat exchanger 5 is closed. As a result, the fresh air flow 7 is not passed through the cross-flow heat exchanger 5 , but instead passes directly from the supply air chamber 1 into the exhaust air chamber 4 . The fresh air flow 7 is then led away via the outlet opening 25 . Likewise, the exhaust air flow 8 is returned via the outlet openings 24 into the room to be ventilated. The exhaust air flow 8 sweeps in the fresh air chamber 2 over the surface of the base block 36 of the Peltier block 6 . If the base block 36 is the cool side of the Peltier block 6 , then the moisture condenses in the exhaust air stream 8 as condensed water and passes through the opening 20 into the exhaust air chamber 4 , from where it is led away to the outside by means of the fresh air stream 7 . The fresh airflow 7 has a high absorption capacity for the condensate as it sweeps in the exhaust air chamber 4 through the hot side of the Peltier block 6 is heated and thus become a high absorption capacity. The desired air humidity can be set on the ventilation unit. For this purpose, the actual moisture value of the fresh air is detected in the supply air chamber 1 with a moisture sensor 44 . In the exhaust air chamber 3 , the actual moisture value of the exhaust air is detected with a moisture sensor 45 . The two measured values are fed together with a target value to a comparator which regulates the voltage supply for the Peltier block 6 . If the humidity setpoint is exceeded, the switchover takes place for dehumidifying the room air or fresh air. If the humidity falls below the setpoint, the system switches back to the normal operating state.

If the air humidity is high and the temperature is low, the waste heat from the exhaust air chamber can be returned to the room by replacing the fresh air flow with a room air flow. For this purpose, the inlet opening 21 for the fresh air flow 7 in the supply air chamber 1 and the outlet opening 25 in the exhaust air chamber 4 are closed. The room air or exhaust air then flows through the inlet opening 22 into the supply air chamber 1 , further into the exhaust air chamber 4 , takes over the waste heat of the Peltier block 6 and flows out into the room again via the outlet openings 26 . The proportion of heated room air thus obtained considerably increases the efficiency of the dehumidification and also increases the room temperature. The condensed water, which is deposited on the cooling body 39 located in the fresh air chamber 2 , is collected in a funnel (not shown in the drawing) and discharged with a line.

Thus, due to the special arrangement of the Peltier block 6 between the fresh air chamber 2 and the exhaust air chamber 4, on the one hand the fresh air stream 7 can be cooled and heated in normal operation or air exchange operation and on the other hand the room air can be dehumidified in the dehumidification operation. The room air can also be heated in dehumidification mode. Instead of a single Peltier block 6 , a Peltier block cascade 41 consisting of six Peltier blocks can also be provided. This does not change the mode of operation of the ventilation device according to the invention.

Claims (16)

1.Ventilation unit with a supply air chamber ( 1 ) and a fresh air chamber ( 2 ) for the fresh air flow ( 7 ), an exhaust air chamber ( 3 ) and an exhaust air chamber ( 4 ) for the exhaust air flow ( 8 ) and a cross-flow heat exchanger ( 5 ) for heat exchange between the exhaust air and the fresh air, characterized in that at least one Peltier element ( 37 ) for cooling or heating the fresh air flow ( 7 ) is arranged between the fresh air chamber ( 2 ) and the exhaust air chamber ( 4 ) or the supply air chamber ( 1 ) and the exhaust air chamber ( 3 ). 2. Ventilation device according to claim 1, characterized in that the Peltier element ( 37 ) essentially forms a partition ( 17 ) between the fresh air chamber ( 2 ) and the exhaust air chamber ( 4 ) or the supply air chamber ( 1 ) and the exhaust air chamber ( 3 ). 3. Ventilation device according to one of the two preceding claims, characterized in that a plurality of Peltier elements ( 37 ) are arranged within a Peltier block ( 6 ) and the Peltier block ( 6 ) has a base block ( 36 ) and a pressure plate ( 38 ), the Peltier elements ( 37 ) are arranged between the base block ( 36 ) and the pressure plate ( 38 ). 4. Ventilation device according to one of the preceding claims, characterized in that several Peltier blocks ( 6 ) are arranged to form a Peltier block cascade ( 41 ). 5. Ventilation device according to one of the preceding claims, characterized in that the Peltier block ( 6 ) has at least one heat sink ( 39 , 40 ). 6. Ventilation device according to claim 5, characterized in that the Peltier block ( 6 ) has two heat sinks ( 39 , 40 ), a first heat sink ( 39 ) with the base block ( 36 ) and a second heat sink ( 40 ) with the pressure plate ( 38 ) connected is. 7. Ventilation device according to one of the preceding claims 2 to 6, characterized in that an opening ( 20 ) is provided in the partition ( 17 ) between the fresh air chamber ( 2 ) and the exhaust air chamber ( 4 ). 8. Ventilation device according to one of the preceding claims, characterized in that in a partition ( 15 ) between the exhaust air chamber ( 3 ) and the fresh air chamber ( 2 ) a first flap ( 16 ) and in a partition ( 18 ) between the supply air chamber ( 1 ) and a second flap ( 19 ) is arranged in the exhaust air chamber ( 4 ) and a first closure element ( 43 ) for closing the inlet side ( 10 ) of the cross-flow heat exchanger ( 5 ) and a second closure element ( 42 ) for closing the inlet side ( 11 ) of the exhaust air chamber Cross-flow heat exchanger ( 5 ) are provided. 9. Ventilation device according to claim 8, characterized in that the first flap ( 16 ) and the second flap ( 19 ) can be actuated with a common flap actuator. 10. Ventilation device according to one of the preceding claims, characterized in that a fresh air blower ( 31 ) for the fresh air flow ( 7 ) and an exhaust air blower ( 32 ) for the exhaust air flow ( 8 ) are arranged in the flow direction behind the cross-flow heat exchanger ( 5 ). 11. Ventilation device according to claim 10, characterized in that power supplies for the fresh air blower ( 31 ), the exhaust air blower ( 32 ) and the Peltier element ( 37 ) are arranged in the exhaust air chamber ( 4 ). 12. Ventilation device according to one of the preceding claims, characterized in that a first filter ( 27 ) for the exhaust air flow ( 8 ) in the exhaust air chamber ( 3 ) and a second filter ( 28 ) for the fresh air flow ( 7 ) in the supply air chamber ( 1 ) and a third filter ( 29 ) and a fourth filter ( 30 ) for the fresh air flow ( 7 ) are provided in the fresh air chamber ( 2 ). 13. Ventilation device according to claim 12, characterized in that the filters ( 27 , 28 , 29 , 30 ) have an identical size. 14. Ventilation device according to one of the two preceding claims, characterized in that the first filter ( 27 ), the third filter ( 29 ) and the fourth filter ( 30 ) are arranged in a housing ( 9 ). 15. Ventilation device according to one of the preceding claims, characterized, that a sound-absorbing covering is provided. 16. Ventilation device according to claim 15, characterized in that the inside of the housing ( 9 ) is lined with noise-reducing mats.