DE3502131A1 - Heat exchanger for improving room air - Google Patents

Abstract

A heat exchanger is described for improving the air in rooms, especially in stables, in which the heat exchanger surfaces are designed as exchanger tubes within an enclosed housing, the thin-walled plastic tubes (9) having a meander-like wall structure, and in which, starting from the side walls of the housing, baffles project into the housing space of the heat exchanger, which baffles cause the air flowing round the tubes to pass transversely around the heat exchanger tubes in a meander-like manner. <IMAGE>

Description

Heat exchangers for improving the air in the room

The invention relates to a heat exchanger for improving room air, in particular of stable air, according to the preamble of claim 1.

For improving the air quality in stables for keeping animals, in particular For cattle or pig farming, it is known to use heat exchangers to improve the air in the barn use that have the task of enriched with high humidity To remove stall air from the stall and thereby the heat it contains to the to release fresh air to be supplied. The advantage of using heat exchangers is mainly due to the fact that heating energy is saved in animals that need warmth and no longer extremely cold supply air can get into the barn. By lowering the air humidity, the preheating has a beneficial effect on health the Animals out. On cold days it is no longer necessary, especially the supply air to reduce. There is a more intensive ventilation of the stables, through which the Barn climate and animal performance are improved.

Heat exchangers, the measured values of which appear favorable under laboratory conditions, however, they are not readily available in practical use for purposes in stables suitable. This is particularly due to the fact that the exhaust air from stables is very dirty is and that this dirt is together with the precipitation as a result of the humidity precipitates on the heat exchange surfaces and thus their efficiency is considerable decreased.

In practice, three basic principles have prevailed, namely Heat exchange via plastic foils, plastic pipes and glass pipes. Glass tubes have the best heat transfer, but their costs are the highest. To avoid contamination, all known systems have smooth surfaces that are to be cleaned at certain time intervals. For that is a good one Access to the exchange areas is necessary, as well as an associated increased structural Complexity.

The requirement of regular cleaning to get an adequate To maintain efficiency, and the expensive exchange surfaces has meant that Heat exchangers are only sparingly established in stables.

The invention is based on the object of specifying a heat exchanger, which has a high degree of efficiency, is simple in construction, even with a strong one Pollution has a high efficiency that can be maintained over a long period of time and a allows easy cleaning.

This object is achieved by the invention specified in claim 1. Advantageous further developments of the invention are specified in the subclaims.

The inventive design of the heat exchanger makes it possible in a simple way to achieve a high level of efficiency that is maintained over a long period of time remain.

Due to the special structure of the heat exchange surfaces, it does not Contamination to be avoided only has a small effect on the efficiency. The inventive Heat exchanger has the particular advantage that its structure has a self-cleaning effect which makes it possible to use the heat exchanger for almost an entire season to operate without intermediate cleaning being necessary.

The invention is explained in more detail below with the aid of an exemplary embodiment explained.

Fig. 1 shows a longitudinal section through a heat exchanger according to the invention, Fig. 2 shows a longitudinal section through an exchanger tube.

The heat exchanger shown in Fig. 1 has an elongated, in cross section approximately rectangular housing 1, the side walls preferably made of stainless steel. This material resists aggressive ones to a high degree Steaming the stable air. The heat exchanger has a fresh air Bpreich, the contains an opening 2 through which fresh air can be supplied from the outside. At the the other end of the heat exchanger is a fan 6, which through the heat exchanger discharges fresh air into the house. In the vicinity of the Fresh air outlet 3 is the exhaust air inlet 4, of the from the exhaust air through the heat exchanger tubes 9 to the other side of the heat exchanger is performed and is released there via a fan 7 to the outside.

The air inlet and outlet areas of the heat exchanger are more or less airtight completed against each other.

In the exemplary embodiment, the exhaust air is through the heat exchanger tubes 9 passed through while the fresh air washes around the heat exchanger tubes 9. Even though Such an embodiment has proven itself in practice is also the other way round Arrangement possible. About the heat exchange surfaces of the heat exchanger tubes 9 is the heat contained in the exhaust air is transferred to the supply air. This heats it up and is therefore more suitable for ventilation than the unheated outside air.

According to the invention, the heat exchange tubes 9 consist of thin-walled Plastic pipes which are arranged in the longitudinal direction of the housing 1 and which are in Have a meandering wall structure in the axial direction. This wall structure has proved to be particularly advantageous The meandering structure leads to that dirt is practically only reflected in the depressions, as in Fig. 2 shown. The area originally available for heat exchange the sections 11, 12 and 13 are thus reduced, but still sufficiently large, since the air passed through the tubes is essentially along the inner Strokes along sections 12. On the other hand, through a special leadership, the Pipes sweeping fresh air ensures that the fresh air in particular through the outer depressions 15 passes through and thus continues to be in good contact with the exchange surface 12 remains. The recesses 14 are sufficiently large to to absorb the dirt for a season without leaving the inside of the sections 12 significant pollution occurs. It has been shown that with strong warming the outside air in the spring without any further implementation the exhaust air through the heat exchanger tubes, the contamination within the wells 14 dry out and crust, so that they appear as crumbs of dirt after blowing through with air fall out of the depressions 14 and can be discharged. Through this, so to speak Self-cleaning, the heat exchanger tubes 9 are cleaned again for the next season. Special cleaning during seasonal operation is not required.

The heat exchanger tubes 9 are preferably made of polyethylene, it However, another plastic material can also be used that is sufficient has high heat transfer coefficients. As heat exchanger tubes have proven so-called unperforated drainage pipes have proven to be particularly suitable, which are used in the Drainage technology can be used for completely different purposes. Such tubes have however, a meandering structure which is suitable for the purposes of the invention is.

In the housing 1 of the heat exchanger, the tubes are against each other arranged offset in several layers at a distance from one another. From the side walls of the housing 1, according to the invention, partition walls 10 protrude over at least the Half the width of the housing space 8 into this. These partitions 10, the also preferably made of stainless steel or aluminum, cover about 4/5 of the Cross-sectional area of the housing 1 from. Over the length of the housing 1 are several this partition walls 10 arranged, each alternating from one side and the other side of the housing 1 protrude into the interior space 8. This results in a Forced guidance of the outside air supplied through the opening 2. This must therefore cross to the heat exchanger tubes 9 flow through them, then around the partition walls 10 around multiple times deflected and flows again in the transverse direction between the heat exchanger tubes 9 through. Due to the mutual arrangement of the partition walls 10 the supplied air is therefore forced to meander between the heat exchanger tubes to strike through. This results in a particularly strong heat exchange effect. The special structure of the heat exchanger tubes 9 supports this heat exchanger effect, in that the tubes have circumferential depressions 15 through which the flow around them Air is guided. Thus, in addition to the sections 12, there are also the side sections 13 and the outer sections 11 involved in the heat exchange.

In the event of severe contamination within the depressions 14 However, the sections 12 still remain as heat exchange surfaces. The multiple The redirection of the fresh air flowing around the pipes also causes a prolonged Exchange path, which also increases the efficiency.

The fans provided for the supply air and the exhaust air are preferred The air flow rate can be regulated in order to adapt the air requirement to different climatic conditions Adapt conditions and house characteristics. The ones intended for the supply and removal Inlet and outlet openings can meet the respective requirements in a particular Stable to be adjusted.

In one example carried out, the effective total length was Heat exchanger 3 m with a width of 75 cm.

The condensate accumulating in the exchanger tubes during operation of the heat exchanger 9 can automatically with a slight inclination of the tubes 9 to the horizontal drain off, with a remainder of condensate remaining within the depressions 14. When the exchanger tubes 9 are in a horizontal position, however, the condensate is caused by the air flow driven out of the tubes and can through a condensate drain at the end of the Exchanger tubes are collected.

The principle of the heat exchanger design according to the invention can be also for use in heat pumps and other similar applications insert.

LIST OF REFERENCE NUMERALS: 1 housing 2 supply air inlet 3 supply air outlet 4 exhaust air inlet 5 Exhaust air outlet 6 Fan 7 Fan 8 Interior 9 Pipes 10 Partition wall 11 Outer section 12 inner section 13 side section 14 recess 15 recess

Claims (9)

Claims: Heat exchangers for improving the air in the room, in particular of stable air, in which the air to be extracted from the room along one side of the Heat exchanger surfaces is performed, on the other side of the room to be supplied Air is at least partially passed in countercurrent, the heat exchange surfaces located inside a closed housing (1) for the supply of outside air and an inlet opening (2, 4) and an outlet opening for the discharge of the room air (3, 5) and in the case of fans (6, 7) for supplying and removing the air are provided, characterized in that the heat exchangers have thin-walled plastic pipes (9), which are arranged in the longitudinal direction of the housing (1) and in the axial direction have a meandering wall structure, and that of the side walls of the housing (1) starting from partition walls (10) over at least half the width of the housing space (8) protrude into this, through which at least a part of the transverse to it Pipes (9) is passed through, wherein the partition walls (10) in the longitudinal direction of the housing alternately from one and the other side of the housing (1) into the housing space protrude. 2. Heat exchanger according to claim 1, characterized in that the Wall structure of the pipe (s) in longitudinal section successively in radial and in has straight sections (11, 12, 13) in the axial direction. 3. Heat exchanger according to claim 2, characterized in that the Sections are formed about the same length. 4. Heat exchanger according to one of the preceding claims, characterized characterized in that the exhaust air is passed through the pipes (9). 5. Heat exchanger according to one of the preceding claims, characterized characterized in that the tubes (9) are arranged horizontally. 6. Heat exchanger according to one of the preceding claims, characterized characterized in that the tubes (9) are made of polyethylene. 7. Heat exchanger according to claim 1, characterized in that the Housing (1) is made of stainless steel. 8. Heat exchanger according to claim 1, characterized in that a Condensate drain is provided on the housing (1). 9. Heat exchanger according to claim 1, characterized in that the The air throughput of the fans (6, 7) can be regulated.