DE102010046521A1 - Ventilation device for inner rooms of buildings or vehicles to exchange of exhausted internal air with fresh external air, has units, which enable to completely or partially remove condensation water from heat exchanger - Google Patents

Abstract

The ventilation device has units, which enable to completely or partially remove condensation water from the heat exchanger (7) continuously before the starting of the supply air operation. The condensation water is accumulated during the exhaust operation if required in heat exchanger.

Description

The invention describes a ventilation device for interiors of z. B. buildings or vehicles for the exchange of used indoor air with fresh outdoor air through a regenerative heat storage with extensive preservation of indoor heat and with freely selectable influencing the indoor humidity. The heat storage of the ventilation device is to flow through with a period of preferably about 2 minutes alternately from the supply air and the exhaust air.

Ventilation devices for interiors with a regenerative heat storage and alternating air flow direction are well known. Normally these devices are used in pairs in opposite directions in opposite directions. H. if the first device operates in the supply air mode, the other works in the exhaust air mode, and vice versa. The period for the flow reversal is designed so that the previously cooled by the outside air heat storage is then flowed through only so long by the warm indoor air that he ideally is not noticeably warmer at its outer opening. Thereafter, the device sucks outside air at the outer opening and directs them into the interior, this supply air has been previously heated in the heat storage to the interior temperature.

During the cooling of the outflowing internal air in the heat storage is often, especially in winter, the dew point of the indoor air below and it condenses in the heat storage moisture, which is reflected as Tauschicht on the surfaces of the heat storage material. The thickness of this exchange layer is usually in the micrometer range, i. H. A drop formation and thus drainage of this condensate by gravity are very unlikely. After the flow reversal, the dry outside air now sweeps past these layers of turf and, especially as it is warmed up, lets the rope evaporate again. Has the intake outside air before entering the heat storage a relative humidity of 100%, then changes in otherwise ideal operating conditions, the indoor humidity not at all, because the removed from the interior humidity has not left the heat storage to the outside and is completely in the Interior returned. This ventilation principle is thus not suitable in its previous versions for room dehumidification. However, if you still find smaller dehumidifying effects in practice under special climatic conditions, this is partly due to the fact that the heat exchange values are not 100% (which is what you are aiming for) and partly because the outside air does not always have a relative humidity of 100% (in winter, when dehumidification is particularly important, but often).

While ventilation units with plate heat exchangers lead to low humidity in the interior in winter, the ventilation units with regenerative heat accumulators leave the humidity in the interior largely constant. This is initially an advantage for the indoor climate. However, as the inhabitants of the room produce direct and indirect air humidity, the relative humidity increases. There are values of 60% r. F. and more achieved, which leads in winter to condensation on walls and windows. Adherent condensation on walls favors mold growth. For a healthy room climate, therefore, a ventilation device is necessary, which does not lower these values even further at low indoor air humidity values and which at high indoor air humidity values dissipates this excess moisture from the room. Without active elements such as air humidifiers or dehumidifiers, there is no such a ventilation device until today. The invention presented here now offers for the first time a technically easy to implement solution for it.

The principle of this solution is to use a ventilation device with regenerative heat storage and in too high indoor air humidity values, and only then to remove the condensation in the heat storage immediately in its formation or at the latest before the beginning of the supply air phase from the heat storage. When outside air then flows back into the interior, it retains its low (absolute) air humidity value despite warming up in the heat storage tank and reduces the air humidity value of the indoor air via the mixture with the indoor air. If the indoor air humidity is low enough, the condensation water is no longer removed from the heat accumulator and the indoor air humidity value remains largely constant depending on the relative outside air humidity.

Specifically, this means that with this new ventilation device you can reduce the dehumidification performance (= the amount of water removed from the room in grams per kilogram of fresh air) down to the difference between the absolute humidity of the outside air to the saturation humidity of the outside air (which is common in regenerative heat storage) or maximize to the difference between the absolute humidity of the indoor air to the absolute humidity of the outside air (which is the main feature of this invention) or set to any intermediate value (which is described in the dependent claims).

There are several solution variants for the technical implementation of the new principle:
If the heat accumulator consists of parallel plates, through which the air flows, then the layers of powder on these plates may be similar to those of a windscreen wiper Rubber lips are deducted. Preferably, a wiper is used per plate gap, which then subtracts the two adjacent surfaces together. If, on the other hand, the heat accumulator, as already used today, consists of a ceramic honeycomb with many channels, then a large number of pistons must pierce these channels and push them free. The condensed water collected in this way is discharged to the outside.

There is also the possibility of imparting a vibration to ultrasound to the heat accumulator of any type coated with layers of tar, which causes the water in aerosol form to leave the surface and be blown outwards.

A very strong compressed air pulse through the heat accumulator in the direction of the outer opening is already suitable alone for blowing off and draining off the layers.

Flushing the heat accumulator with water, with decompressed water or even with a liquid that largely bubbles off the surface are also techniques that can be used to remove the condensation water.

The beading can be further improved by appropriate coating of the surfaces of the heat accumulator. Of course, this surface treatment would also be helpful with other condensation removal methods.

As mentioned above, gravity alone is rarely able to move the dewarting articles to drain. Far greater forces on the individual water particles can be generated via a rotation similar to a centrifuge. The heat storage must be constructed so that the air can flow through it parallel to the axis of rotation and that at the same time radially thrown condensed water can leave the heat accumulator further unhindered in the radial direction. On the inner surface of the outer wall of the ventilation device, the condensate can then collect and drain through suitable openings or be sucked through wicks and capillary action.

Heat storage, which can be flowed through in two mutually perpendicular directions, z. As rod structures similar to a cylindrical wire brush, beds of small solid particles, which also receives defined air paths especially with identically sized particles, with distance spirally wound perforated plates to wire mesh or knitted fabric or balls of wires or other fibers, eg. B. also (precious) steel wool.

While with a humidity control in the room in the former proposals for a defrost water removal only has the ability to completely remove the condensation or not, the last possibility shows the advantage of increasing the defrost water steadily over the speed or lower. This can z. B. the heat storage constantly rotate independently of Zuluft- or exhaust air phase, its speed then determines the permanently adjusting indoor air humidity. Such a ventilation device is particularly easy to set up and requires little control effort. Because the centrifugal force generated at a fixed rotational speed is only able to move this drop from a certain drop size. However, if the indoor air humidity is already so low that the drops of condensation water no longer reach this droplet size during an exhaust air phase, it is no longer dehumidified automatically. As the indoor humidity increases, the dew drops also grow larger until they are large enough to be caught by the centrifugal force and to flow off radially.

Dry air has a significantly lower enthalpy content than moist air due to the heat of evaporation of the water in the humid air. If the heat is removed from the moist interior air in the heat accumulator, a significantly greater amount of fresh air can be heated to the interior temperature value with this amount of heat. In the long run, however, you can not blow in fresh air into the room as you draw off exhaust air. This heat surplus must therefore be used elsewhere, for. B. over an internal air circulation in the room, which cooled air is reheated from cold room areas. If you have three heat storage in use, then so comes to Zuluft- and the exhaust phase nor the recirculation phase.

At the embodiment of claim 8 is with 1 describes the mode of action of the ventilation device:
The interior ( 1 ) is through a wall ( 3 ) from the outside atmosphere ( 2 ) separated. For replacing used indoor air with fresh outside air is in the wall ( 3 ) a breakthrough ( 4 ) cut out with circular cross-section. In the breakthrough is a fan behind the other ( 5 ) and a heat storage ( 7 ) arranged. The direction of rotation of the blower motor ( 6 ) changes periodically, so that in one direction of rotation fresh outside air flows into the interior ( 15 ) and in the other direction of rotation consumed indoor air flows to the outside ( 16 ). Both air streams pass each heat storage ( 7 ), which consists of a rotatably mounted central cylinder ( 8th ) with many attached rods ( 9 ) consists. The central cylinder ( 8th ) with the bars ( 9 ) is controlled by the engine ( 10 ) is set in rotary motion. Flows in the exhaust air phase ( 16 ) the warm, moist indoor air at the previously cooled by the fresh outside air rods ( 9 ) of the heat accumulator ( 7 ) passes, the outflowing indoor air cools and it condenses water on the rods ( 9 ) out. The condensation drops on the rods ( 9 ) continue to grow until they have reached a size that they are due to the centrifugal force on the rods ( 9 ) along the inner surface of the outer boundary wall ( 11 ) of the ventilation unit. At the boundary wall ( 11 ) the water flows in the direction of rotation of the heat accumulator ( 7 ) to a series of openings ( 12 ) and through this into the collection channel ( 13 ) to the outflow ( 14 ). If the direction of rotation of the blower motor changes ( 6 ) flows fresh cold outside air on the warm, largely dry rods ( 9 ) to the inside ( 15 ). The outside air is at the rods ( 9 ) is heated. Due to the continuous rotation of the heat accumulator ( 7 ) is a good heat transfer from the rods ( 9 ) to the flowing air, a slip on the rods ( 9 ) is over. This good heat transfer applies to both directions of flow, so that a very good heat exchange efficiency is evident.

Claims (10)

Ventilation device for interiors of z. B. buildings or vehicles for the exchange of spent indoor air with fresh outdoor air while largely maintaining the indoor heat with at least one heat storage, which is alternately flowed through with a period of preferably about 2 minutes of the supply air and the exhaust air, characterized in that means are present that make it possible to completely or even partially remove the condensate occurring during the exhaust air operation in the heat accumulator continuously or at the latest before the beginning of Zuluftbetriebs from the heat storage. Ventilation device according to claim 1, characterized in that at least two identical heat storage in the ventilation device are present, whereby the device can also be used for central ventilation systems, of which at least one heat storage of the supply air and at least one heat storage is traversed by the exhaust air, and which with a Periods of preferably about 2 minutes alternately from a supply air duct in an exhaust duct and vice versa are moved, and that means are available which allow the optionally accumulating in the heat storage of an exhaust duct condensate continuously or at the latest before the beginning of the transition into a supply air duct or completely even partially removed from the heat storage. Ventilation device according to claim 1 or 2, characterized in that the optionally present in the form of layers of water condensate is mechanically removed, for. B. in a heat storage in plate structure with rubber lips or a heat storage in tube construction of running in the tubes piston. Ventilation device according to claim 1 or 2, characterized in that the condensate present optionally in the form of layers of layers is stimulated by sonication of the heat accumulator or by other vibrations to leave the heat storage surface to be transferred in aerosol form and blown, or by a strong compressed air pulse is blown out alone. Ventilation device according to claim 1 or 2, characterized in that the optionally present in the form of layers of water condensation is washed off by a rinsing liquid. Ventilation device according to claim 1 or 2, characterized in that the heat storage rotates about an axis parallel to the direction of air flow, so that any accumulating condensation is thrown off, the dehumidification of the ventilation device can be adjusted or controlled by the speed of the rotating heat storage. Ventilation device according to claims 1 or one of claims 2 to 6, characterized in that the coming into contact with the air streams surfaces of the heat accumulator are coated water or liquid repellent or consist of a material having such properties. Ventilation device according to claim 6, characterized in that the rotating heat storage is constructed similar to a cylindrical wire brush with the cylinder axis parallel to the air flow direction. Ventilation device according to claim 6, characterized in that the rotating heat storage consists of a bed of small solid or of a wire or fiberballs and that these materials are housed in a cylindrical cage or solidified to intrinsically stable cylindrical bodies, each with the cylinder axis parallel to the air flow direction , Ventilation device according to claim 1 or 2, characterized in that after termination of the supply air phase, ie after the heating of the normally relatively dry outside air, remaining in the heat storage enthalpy is withdrawn before the beginning of the following exhaust air Zuluftperiode the heat storage and recovered.

Images