CH635517A5 - REFRIGERATION DRYER FOR COMPRESSED AIR. - Google Patents

Description

The invention relates to a refrigeration dryer device for compressed air or another gas, consisting of at least one air-air heat exchanger and one air-freon heat exchanger, the heat exchangers having bent, interlocking tubes.

Refrigeration dryer devices are increasingly being used in connection with compressed air networks to remove the moisture from the air and thus complicated compressed air systems, e.g. in connection with control and regulation systems to be able to operate trouble-free. In known refrigeration dryer devices, the air compressed by a compressor is first pre-cooled and then fed to an air-air heat exchanger at a temperature of approximately 30 ° C., in which the air is cooled to approximately 12 ° C. The further cooling of the air takes place in an air-freon heat exchanger, in which a final temperature of the air of about 2 ° C is reached. The moisture that has precipitated is then separated in a separator connected to it. The moisture-free air enters the air-air heat exchanger and is used to cool the compressed air. The air entering this heat exchanger at 2 ° C warms up to about 22 ° C and is then fed to the consumers. It has now proven to be expedient to use standard units for the two heat exchangers and to combine a number of these units which corresponds to the size of the compressed air system.

A known heat exchanger unit consists of an outer tube with an inner tube arranged coaxially therein, which is bent into a number of turns. By a small height, e.g. of two pipe diameters, it is necessary to arrange the heat exchanger pipes in spirals. However, the production of heat exchanger units with spirally laid turns is difficult in terms of production technology and is therefore more complex than units with helically arranged pipe turns. For a given heat exchange unit output for the heat exchanger

However, in the case of a helical arrangement of the pipe windings, the unit cannot maintain the desired small overall height for a given winding diameter. Although it is known to improve the heat exchange performance of two coaxial tubes by means of internals, this makes the heat exchanger unit complicated and expensive to manufacture.

The invention is therefore based on the object of designing a refrigeration dryer device of the type described at the outset such that, with the simplest construction of the heat exchanger unit, a helical arrangement of the pipe windings is possible while observing the heat exchange performance, the pressure loss, the height and the winding diameter is.

This object is achieved according to the invention in that the gas-gas heat exchanger has an outer tube and at least three inner tubes and the gas-freon heat exchanger has an outer tube and a coaxial inner tube with at least three inner tubes arranged in the coaxial inner tube with mutual line contact.

According to the invention, air can also be used as the gas to be dried.

An embodiment is shown in the drawing and described below. Show it:

1 is a side view of two superimposed heat exchangers,

2 is a plan view of the heat exchanger according to FIG. 1,

3 shows a cross section of an air-air heat exchanger,

4 shows a cross section of an air freon heat exchanger,

Fig. 5 is a plan view in an enlarged view of the tube ends of an air-air heat exchanger and

Fig. 6 is a plan view in an enlarged view of the tube ends of an air freon heat exchanger.

The heat exchangers shown in FIGS. 1 and 2 are composed of an air-air heat exchanger 1 and an air-freon heat exchanger 2. Both heat exchangers 1, 2 have a turn length of one and a half turns. It is thereby achieved that when heat exchangers are stacked on top of each other, an intermediate space Z is created through which the interior space formed by the tube windings is accessible, which is advantageous in the production of a refrigeration dryer device.

The air-air heat exchanger 1, see FIG. 3, is composed of an outer tube 3 and four inner tubes 4, but a different number of inner tubes 4 can also be used. The cooling air flows through the inner tubes 4, for example, and the air to be cooled flows in the interior between the outer tube 3 and the inner tubes 4.

The air freon heat exchanger has, see FIG. 4, an outer tube 3 with a coaxial inner tube 5. Four inner tubes 4 are arranged in the interior of the coaxial inner tube 5. It is essential here that the inner tubes 4 are in mutual line contact 13 with each other and with the inner wall of the coaxial inner tube. The air to be cooled flows through the coaxial inner tube 5 and the inner tubes 4, for example, while the freon flows in the annular space between the outer tube 3 and the coaxial inner tube 5.

The two heat exchangers 1, 2 have straight connections 6 at their ends of the turns, see FIG. 2. These are used to connect the heat exchangers 1, 2 to collectors. In Fig. 2 manifolds 8,9 are schematically shown for the cooling air and the air to be cooled.

5 and 6, the connections of the heat exchangers 1, 2 are shown enlarged. The nozzle 6 of the outside 5

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Pipes 3 opens into the manifold 8 shown in dashed lines, while the inner tubes 4 are combined in a connecting piece 10 which opens into the manifold 9 shown in dashed lines.

FIG. 6 shows the connection of the air-freon heat exchanger. 5 A conical connecting piece with a connecting pipe 12 connects to the connecting piece 6, while the coaxial inner pipe 5 is connected directly to the collecting pipe 9. Since the one medium flows both in the inner tubes 4 and in the coaxial inner tube 5, only the 10 coaxial inner tube 5 needs to be connected to the header tube 9; this avoids an undesirable risky and later inaccessible solder joint in the freon area.

With the heat exchanger units 1, 2 described, which are designed with only one and a half turns, significant material savings are achieved despite the use of the inner tubes 4. Also, in order to maintain the desired heat exchange unit output, no greater pressure drop is required than in comparable known ones Units.

Air is primarily used as the operating medium, but another gas can also be used in the same way as air in the refrigeration dryer device described.

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1 sheet of drawings

Claims (4)

635517 1. refrigeration dryer device for compressed air or another gas, consisting of at least one air-air heat exchanger and one air-freon heat exchanger, the heat exchangers having curved, interlocking tubes, characterized in that the air-air -Heat exchanger (1) an outer tube (3) and at least three inner tubes (4) and the air-freon heat exchanger (2) an outer tube (3) and a coaxial inner tube (5) with at least three in the coaxial inner tube with mutual line contact (13 ) arranged inner tubes (4). 2. Device according to claim 1, characterized in that the air-air heat exchanger (1) and the air-freon heat exchanger (2) have the same winding length. 2nd PATENT CLAIMS 3. Device according to claim 2, characterized in that the winding length of the heat exchanger (1, 2) is one and a half turns. 4. The device according to claim 1, characterized in that the heat exchangers (1, 2) lie one above the other, with all air-air heat exchangers adjacent in the upper region and all air-freon heat exchangers in the lower region adjacent.