NL8401494A - Compressed air drier cooling unit - has inlet air cooled by evaporator and cooled air reheated by condenser after passing through moisture separator - Google Patents

Abstract

The compressed air drier comprises a cooling unit (1) consisting of a refrigerant compressor (2), condenser (3), throttle valve (4) and evaporator (5). The compressed air line (8,7) contains a heat exchanger (10) in heat transfer contact with the evaporator, a separator (11) for moisture and oil and a heat exchanger (14) to re-heat the cooled dry air. This heat exchanger is in heat transfer contact with the condenser (3), heat exchange pref. being in counterflow.

Description

84.5068 / Rey / sme

Short designation: Refrigeration dryer for compressed air.

The present invention relates to a compressed air refrigeration dryer, comprising a refrigeration unit consisting essentially of a compressor for a refrigeration medium, a condenser, a control valve or restriction, and an evaporator, further comprising a compressed air line, which is provided with a heat exchanger in heat transfer connection with the evaporator of the cooling unit, of a moisture separator and of a heat exchanger for reheating the cooled compressed air from the moisture separator.

Such a refrigeration dryer is placed behind the compressed air compressor and serves to condition the compressed air, ie, to remove moisture, oil and other contaminants, in order to avoid malfunction of the compressed air operated equipment.

In the known refrigeration dryers, the compressed air is pre-cooled by heat exchange with the cold, conditioned air leaving the dryer, which air is then reheated leaving the refrigeration dryer. This construction has the drawback that the compressed air leaving the dryer has a temperature which is generally lower than that of the ambient air, so that there is a risk of condensation settling on the outside of the compressed air pipes, which has an adverse effect can have. Moreover, the known cooling dryers are provided with a cooling fan, in order to cool the condenser of the cooling unit with the ambient air. Such a fan consumes about 30-40% of the power absorbed by the refrigeration dryer. In addition, the condenser is exposed to contamination, which can negatively affect its proper functioning.

The present invention aims to provide a refrigeration dryer, avoiding the aforementioned drawbacks.

This object is achieved according to the invention in that the heat exchanger for reheating the compressed air is in heat-transferring connection with the condenser of the cooling unit.

In this way the condenser is cooled with the cold S 4 ~ 4 5 4 1, β ^ «.

- 2 - compressed air instead of the ambient air. This construction has the advantage that the condenser can thus be made smaller due to the lower temperature of the compressed air and the fan, which also takes up a lot of space and consumes a lot of energy, can be omitted. In addition, the refrigeration dryer can be housed in a closed cabinet, so that contamination is excluded.

According to a preferred embodiment of the invention, the condenser of the cooling unit consists of a spiral wound tube for the cooling medium, around which tube the conduit for the compressed air is arranged almost concentrically, which tubes are flowed in opposite directions.

The invention is further elucidated with reference to the drawing, in which: Fig. 1 shows a diagram of a refrigeration dryer according to the prior art; and Fig. 2 shows a diagram of a refrigeration dryer according to the present invention.

In the two figures the same parts are indicated with the same reference numbers as much as possible. The refrigeration dryer shown in fig. 1 consists of a refrigeration unit 1, which mainly consists of a compressor 2 for cooling medium, a condenser 3, a collecting vessel 15 for cooling medium, a control valve 4 and an evaporator 5. The condenser 3 is provided with a cooling fan 6 to cool the condenser with ambient air.

A compressed air line 7 communicates with the cooling unit 1, which line is provided with an inlet opening 8, which can be connected to an air compressor (not shown). From the inlet 8, the pipe 7 is provided with a heat exchanger 9 in which the compressed air is pre-cooled by the cold air leaving the refrigeration dryer. The compressed air is then cooled in a heat exchanger 10, which is in heat-transferring connection with the evaporator 5 of the cooling unit. The cooled compressed air is then fed to a moisture separator 11, which is provided with an automatic discharge 12. The air thus cooled and dried 8401494-3 - then leaves the refrigeration dryer via the heat exchanger 9.

The operation of this known refrigeration dryer follows directly from the drawing. The compressed air fed into the refrigeration dryer is cooled in the heat exchanger 9 and then cooled in the heat exchanger 10 to about 1 ° C, so that the water present in the compressed air condenses and can be separated in the moisture separator 11. The air from the moisture separator has a temperature of 1 to 2 ° C and is reheated via the heat exchanger 9 and then leaves the refrigeration dryer 10 via the air outlet 13.

The device according to the invention is shown in fig. 2 and also comprises a cooling unit 1, which conventionally consists of the compressor 2 for cooling medium, the condenser 3, the collection vessel 15, the control valve 4 and the evaporator 5.

The device according to the invention differs from the known device in that the discharge pipe 7 'runs from the air inlet 8 directly to the heat exchanger 10, which is in contact with the evaporator 5 of the cooling unit, where the compressed air is cooled. to about 1 ° C. Subsequently, the compressed air line runs to the moisture separator 11 with the automatic discharge 12. From there, the line 7 'runs to a heat exchanger 14, which is in a heat-transferring connection with the condenser 3 of the cooling unit. The compressed air then leaves the refrigeration dryer via the air outlet 13.

The difference with the conventional refrigeration dryer according to Fig. 1 thus lies in the fact that the compressed air leaving the moisture separator, which has a temperature of about 1 - 2 ° C, is used for cooling the condenser 3 of the refrigeration unit. During operation, the condenser has a temperature well above that of the ambient air and the compressed air leaving the refrigeration dryer thus obtains a temperature higher than that of the ambient air, thus avoiding any risk of condensation on the compressed air lines. Since the condenser 3 is cooled by the compressed air, the fan 6 of fig. 1 can be omitted from the device according to the invention, thereby obtaining a considerable energy saving. In general, the fan consumes about 30 to 40% of the consumed power of the refrigeration dryer. This also has the consequence that the condenser can be arranged in a closed box 5 and is thus not exposed to contamination, which previously could negatively affect the operation of the condenser. Because the condenser 3 is cooled with compressed air of + 1 - 2 ° C, a more efficient cooling is obtained and the condenser 3 can therefore be made smaller, which, together with the removal of the fan, allows for a totally compact construction of the refrigeration dryer makes.

Optionally, a combination of the known refrigeration dryer from Fig. 1 with the refrigeration dryer according to the invention from Fig. 2 is possible. In this case, the cold air leaving the moisture separator 11 is first slightly heated by heat exchange with the incoming compressed air before being used to cool the condenser 3. The incoming compressed air is therefore somewhat pre-cooled.

Such a construction has the advantage that excessive cooling of the condenser is avoided. Namely, such too strong a cooling has the drawback that the refrigerant condensed in the condenser and which collects in the vessel 15 is supercooled, so that the evaporator 5 has to be made unnecessarily large. Thus, with this combined embodiment, an energetically optimal efficiency can be obtained.

The condenser 3 of the cooling unit is preferably formed by a spiral-wound tube, around which the conduit for compressed air is arranged almost concentrically, which concentric tubes are flowed in opposite directions.

It will be clear that the device according to the invention can still be provided with other means for cleaning the compressed air, such as filters and the like.

Essential to the invention, however, is that the condenser of the refrigeration unit is cooled with the cold air treated in the refrigeration dryer before this air leaves the device, 840-494-5 - this cold treated air being heated to operating temperature. The device according to the invention can of course also be used for drying gases other than compressed air.

8401494

Claims (3)

Compressed air refrigeration dryer, comprising a refrigeration unit, consisting essentially of a refrigerant fluid compressor, a condenser, a control valve or restrictor, and an evaporator, further comprising a compressed air line provided with a heat transfer evaporator of the refrigeration unit connection of a heat exchanger, of a moisture separator, and of a heat exchanger for reheating the cooled compressed air from the moisture separator, characterized in that the heat exchanger for reheating the compressed air is in heat-transferring connection with the condenser of the cooling unit. 2. Compressed air refrigeration dryer, comprising a refrigeration unit, consisting of a compressor for refrigeration medium, a condenser, a control valve or restriction, and an evaporator, further comprising a compressed air line which is heat-transferable with the evaporator of the refrigeration unit connecting heat exchanger, of a moisture separator, and of a heat exchanger for reheating the cooled compressed air originating from the moisture separator, characterized in that the heat exchanger for reheating the compressed air has a first part, which is in heat-transferring connection with the incoming compressed air and a second part that is in heat-transferring connection with the condenser of the cooling unit. 25 3. Refrigerant dryer according to claim 1 or 2, characterized in that the condenser of the cooling unit consists of a spiral wound tube for the cooling medium, around which tube the conduit for the compressed air is arranged substantially concentrically, said concentric tubes in opposite directions. flow through. 84 0 1 4 9 4