DE2414663B2 - Recuperative heat exchanger with structure contg. gas filled channels - made of thermoplastics material absorbing more than 40 per cent moisture - Google Patents

Abstract

The recuperative heat exchanger has a honeycomb structure with parallel laminar passages through which gas flows. The passage wall surfaces are of hygroscopic material absorbing >2% moisture under normal conditions at 40% by weight relative air humidity. Gas currents flow through them in alternate and opposite directions, and enthalpy contents. The entire honeycomb structure is of cellulose acetate, polyamide polycarbonatE, polystyrene, polyvinylalcohol, acryl-butyl-styrene or Similar organic polymer plastic. At 40% relative air humidity under normal conditions this absorbs >3% moisture.

Description

The invention relates to a storage heat exchanger with a parallel laminar gas flow A heat exchanger which forms channels and has a honeycomb structure, the channel walls of which are superficially made of hygroscopic Material that is made at 40 percent by weight relative humidity under normal conditions absorbs more than 2% moisture and its channels of at least two opposite one another directed and different enthalpy content exhibiting gas flows alternately permeated will. Normal conditions are understood here to mean a temperature of 18 ° C and a Gas pressure of 760 millimeters of mercury (- 101 325 Pa - 1.1013 bar).

In heat exchangers of this type, the exchanger consumes a gas flow while it is in motion, ζ. Β. to the Exhaust air flow from consumer air in a living space is penetrated, which has a high enthalpy content, Enthalpy in the form of sensible heat and in form

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of latent heat from accumulated moisture and releases it when it is then released by one Air flow with a lower enthalpy content, e.g. the outside air intended for exchange, is penetrated into In the form of sensible and latent heat. In a known storage heat exchanger, the Exchanger a rotor with channels oriented parallel to the axis of rotation, an exhaust air flow and an opposite one Outside air flow each in a limited The angular sector of its flow cross-section is rotatably and driven to penetrate The honeycomb structure of this well-known rotor is made of asbestos cement, which, to the duct walls on which the Exchange takes place, making it hygroscopic, is coated with lithium chloride. The lithium chloride gives the surface of the duct walls a moisture absorption capacity under the specified conditions of 23%.

The object of the invention is to design a storage heat exchanger of the type mentioned at the outset in such a way that that with the simplest possible and low-mass structure of the exchanger, the highest possible energy exchange The invention is characterized in that the entire honeycomb structure is made of cellulose acetate Polyamide, polycarbonate, polystyrene, polyvinyl chloride, polyvinyl alcohol, acrylic butyl styrene or the like. Organic polymer thermoplastic material, which is below 40% relative humidity Normal conditions absorbs more than 3% moisture. The honeycomb structure formed according to the invention can be made thinner-walled and thus lighter than that with the required stability acquaintance. Since it is made of hygroscopic material, a special coating is not necessary and since the hygroscopic properties of the plastic provided according to the invention are more favorable than that of the lithium chloride provided for coating, for this reason alone a higher degree of efficiency achievable. It is noteworthy in these; Context that the plastics in question difficult are flammable, some are even self-extinguishing and, in contrast to asbestos cement, do not contain any inherent components release to the air flowing through. Cellulose acetate is excellent aroma-impermeable, which turns out to be It turns out to be beneficial if the enthalpy can be recovered from strongly aromatic exhaust air currents target. The production of the honeycomb structure is also particularly easy because it is based on common Plastic processing methods can be used. You can use the Let the exchanger stand still and the channels of the penetrating air currents move opposite the exchanger. However, experience has shown that this does not lead to the cheapest It is more advantageous to design the exchanger as a rotor, as in the case of the one described at the beginning known storage heat exchanger. A corresponding embodiment of the invention is thereby characterized in that the honeycomb structure consists of rigid plastic and is dimensionally stable and as a rotor a shaft is inserted axially parallel to the channels and with this alternately penetrating the gas flows is rotatably mounted. This development makes use of the fact that one in the production of The plastics in question can adjust the stiffness of the plastic without great effort, and also so that a sufficiently dimensionally stable rotor can be formed by the honeycomb structure, the

no additional stiffening elements, with the exception of a hub or a den that may be provided Circumferential underlay is required for a drive belt that acts there

According to this development, the honeycomb structure can also easily be designed to be sufficiently torsionally rigid so that there are no spokes and the like required to ensure the required torsional stiffness. It is recommended under these circumstances that the shaft is square in the area of the rotor hub The square design of the shaft is sufficient, to ensure that a large rotor also rotates with the shaft during operation and not on it slips On the shaft provided driving spokes for the same purpose as they are in known storage heat exchangers are provided are then dispensable.

The inventive design of the honeycomb structure made of plastic also allows it to be supple to be carried out by adjusting the plastic appropriately. That makes it possible for the exchanger to give a form with which he can conduct the business even under extremely unfavorable conditions penetrating gas flows can be used. A corresponding embodiment of the invention is characterized in that the storage heat exchanger by in the form of a pliable endless Band formed honeycomb structure is formed and this band rotates and penetrates the gas flows is driven drivable over rollers. You can have an endless belt, especially if you have more than two Rolling leads, deflecting accordingly often and in almost any way also in inaccessible places let go through. The channels can be arranged perpendicular to the plane of the strip and to the roller axes but they can also extend over the belt width and be arranged parallel to the roller axes be.

The invention will now be explained in more detail with reference to the drawing. In the drawing shows

Fig. 1 rnen storage heat exchanger according to the invention with an exchanger designed as a rotor,

F i g. 2 shows a second exemplary embodiment of the storage heat exchanger according to the invention with an exchanger designed as a band, the channels of which are perpendicular extend to the roller axes and

3 shows a third embodiment with a band-shaped exchanger, the channels of which are parallel extend to the roller axles.

In the drawing show *. 1 shows a shaft 1 with a square hub 2 onto which the exchanger 3, which is designed in the form of a disk-shaped core, is plugged. The exchanger 3 consists of a honeycomb structure made of organic polymeric thermoplastic material with the specified hygroscopicity and, as can be seen from FIG. 1, has the outer contour of a circular cylinder. The channels extend parallel to the cylinder axis or the axis 4 of the shaft 1, which extend from the front 5 facing the viewer from FIG. This exchanger 3 is encased on its periphery with a stiff, airtight jacket 7, which serves as a base for a drive belt 9 that can be driven by a motor 8. During operation, the exchanger traverses two oppositely directed air flows as indicated by arrows 11 and 12. The arrow 12 represents an exhaust air flow from used room air whose flow cross-section extends over the angular range of the double arrow Π while the arrow 11 represents an outside air flow whose flow cross-section extends over

the angular range of the double arrow 14 extends. The two air currents are outside the exchanger 3 guided in flow lines whose walls are not shown for the sake of clarity certain channel of the honeycomb structure, e.g. B. the channel

ίο 15, enforced when operating while the exchanger is in Is driven circumferentially in the direction of arrow 16, initially one indicated by double arrow 17 A flow-free angular area, which is provided for sealing purposes. Then it gets into the flow transverse Section of the outside air or fresh air flow according to arrow 11 and is flowed through by this in a laminar manner. the Outside air absorbs enthalpy in the form of sensible and latent heat with moisture from the hygroscopic channel walls. Subsequently

Λΐ reaches the channel 15 in the angular range ·:.: I accordingly the arrow! 3 and is penetrated in the opposite direction by the exhaust air according to arrow 12 and takes from this enthalpy in the form of sensible and latent heat.

2> The honeycomb structure 3 is by corresponding Adjustment of the plastic used to be stiff enough to give the exchanger the necessary dimensional stiffness, so that it can serve directly as a rotor. Any additional stiffening elements, like

«Ι spokes and the like are not provided.

In the second embodiment, the honeycomb structure is designed in the form of an endless belt 30, the channels 31, 32, 33 extending perpendicular to the plane of the belt. The belt is over two rollers

r. 34, 35 out of which one in the direction of the arrow is driven to rotate so that the belt rotates in the direction of arrow 36 during operation. By arrows 37 to 40 two opposing currents are indicated, the upper run 41 and the

w lower run 42 of belt 30 in the opposite direction. The two gas flows represented by the arrows 37 and 39 on the one hand and by the arrows 38 and 40 on the other hand are guided in lines not shown. In the case of gas flow,

■ Γ) according to the arrows 37 and 39 it can refer to the used exhaust air flowing from a room and in the case of the arrows 38 and 40 represented the flow around the outside air fed into this room.

In the embodiment according to FIG. 3 is the The honeycomb structure is designed as an endless belt 50, which extends over two rollers 5i and 52 in the direction of arrow 53 is stored all around. The channels 66, 67 extend parallel to the Dei this embodiment

Y> axes 54 and 55 of rollers 51 and 52. In the case between the dash-dotted lines 60 and 61, the two runs 62 and 63 are opposed by a first gas flow and in the area between the dash-dotted lines 61 and 65 by a second one.

M) sets directional flow penetrated. Also in this Fall, the two flows outside of the band 62 acting as an enthalpy exchanger are not through lines shown and it can be the exhaust air and outside air for air renewal

h> act in an enclosed space.

In the embodiment according to FIG. I rise from a configuration of the honeycomb structure Cellulose acetate foleende operating conditions The

Has the exhaust air before it passes through the honeycomb structure, a temperature of 22 ° C and a relative humidity of 40% and after it has passed through the honeycomb structure, a temperature of minus 3.5 ⁰ C and a relative humidity of 95%. The outside air has before it passes through the honeycomb structure, a temperature of minus 15 ° C and a relative humidity of 90% and after it has passed through the honeycomb structure, a temperature of 11.5 ⁰ C and a relative humidity of 60%. This corresponds to an efficiency of 70% based on the recovered enthalpy. With a diameter of the rotor formed by the honeycomb structure 3 of one meter and a thickness of the honeycomb structure, measured in the longitudinal extent of the channel, i.e. parallel to the axis 4, of 40 cm and a rotational speed of 10 revolutions per minute, the specified values are achieved with an air throughput of 100 Liters per minute of air throughput in both directions, i.e. in the direction of arrow 11 and arrow 12.

The storage heat exchanger - i.e. the exchanger 3 from FIG. 1 and the band 30 from FIG. 2 and the tape 50 from FIG. 3 - are made of cellulose acetate. Acryl-butyl-styrene or the like. Organic polymer thermoplastic plastic. While the plastic

'"is set stiff for exchanger 3, is the Plastic door hinges 30 and 50 are set resiliently and flexibly. This setting is achieved with the Production of the plastic by adding more or less large amounts of plasticizers.

ι "> For the sake of simplicity, only for some channels, 15, ^ 1,32,33,66 and 67, the mouths shown.

1 sheet of drawings

Claims (6)

Patent claims: 1. Storage heat exchanger with a parallel laminar gas-permeable channel forming A heat exchanger with a honeycomb structure, the surface of the duct walls of which are made of hygroscopic Material that is made at 40 percent by weight relative humidity under normal conditions absorbs more than 2% moisture and its channels of at least two opposite one another directed and different enthalpy content exhibiting gas flows alternately be enforced, characterized in that that the entire honeycomb structure made of cellulose acetate, polyamide, polycarbonate, polystyrene, polyvenyl chloride, Polyvinyl alcohol, acrylic butyl styrene or the like organic polymeric thermoplastic Plastic, which at 40% relative humidity under normal conditions is more than 3% Absorbs moisture 2. Storage heat exchanger according to claim i, characterized characterized in that the honeycomb structure consists of rigid plastic and is dimensionally stable and as Rotor (3) is plugged on a shaft (1) axially parallel to the channels (15) and with this the Gas flows alternately penetrating rotatably 3. Storage heat exchanger according to claim 2, characterized in that the shaft (1) in the area the rotor hub (2) is square. 4. Storage heat exchanger according to claim 1, characterized in that »that cW exchanger (F i g. 2) formed by the honeycomb structure in the form of a flexible, endless belt (30, 50) and this belt permeating the gas flows can be rotated and driven via rollers (34, 51) is led. 5. Storage heat exchanger according to claim 4, characterized in that the channels (31, 32) are arranged perpendicular to the strip plane and perpendicular to the roller axes. 6. Storage heat exchanger according to claim 4, characterized in that the channels (66, 67) are üher extend the band width and are arranged parallel to the roller axes (55).