ITPD20070002A1 - COMPRESSED AIR DRYER - Google Patents

Description

DESCRIPTION

The present invention relates to a compressed air dryer of the type including the characteristics mentioned in the preamble of the main claim.

In the technical field of compressed air treatment plants, refrigeration dryers are known in which the compressed air is placed in contact with cooled heat exchangers so as to separate the dry air from the water vapor by condensation. Such dryers usually include a device for draining condensed water.

Usually, dryers with simple direct expansion or with a thermal mass heat accumulator are used.

In a direct expansion air dryer, the refrigerant circuit is regulated by a valve located between the compressor delivery and suction. By varying the opening of this valve, it is possible to recirculate, by-passing the condenser and evaporator, part of the compressed refrigerant fluid flow from the compressor, adjusting it according to the flow rate and / or temperature of the air to be dried.

The main drawback of this solution is represented by the low efficiency of this regulation method which involves a high energy consumption even when the required air flow rate from the dryer is low. In fact, in all operating conditions, the refrigeration circuit remains on anyway, operating at a constant rate independent of the actual operating thermal load requirements.

In thermal mass air dryers this drawback is partially obviated by a mass capable of accumulating heat in which the frigories in excess of the instantaneous consumption are temporarily accumulated for future use.

In this way there is a clear improvement in the efficiency of the system and an equal decrease in energy consumption.

The main drawback of this solution is represented by the fact that, typically, the thermal mass is confined inside a chamber, in thermal contact with the air to be dried, which causes a considerable increase in the overall dimensions of the dryer.

The main object of the present invention is to provide a dryer for compressed air which is structurally and functionally conceived to obviate all the drawbacks complained of with reference to the cited prior art.

This object and others that will appear in the following are addressed and achieved by the invention by means of a dryer made in accordance with the following claims.

The characteristics and advantages of the invention will become clearer from the detailed description of a preferred embodiment thereof illustrated, by way of non-limiting example, with reference to the accompanying drawings in which:

Figure 1 is a schematic view of a dryer made in accordance with the invention;

Figure 2 is a perspective view of a component of the dryer of Figure 1;

- figures 3 and 4 are two perspective views in partial section, from opposite directions, of the component of figure 2;

Figures 5 and 6 are two views of two respective enlarged details of figure 3;

Figure 7 is a perspective view of a cut-away section of a constructive variant of the component of Figure 2;

- figure 8 is a view of an enlarged detail of figure 7.

A compressed air dryer 1 is schematically represented in Figure 1. With reference to Figures 2 to 6, the dryer 1 comprises a pressure vessel 2, provided with a cylindrical shell 2a, of axis X, whose axially opposite ends they are closed by respective funds 3a, b. The vessel 2 is supported by support feet 4a, b, c.

The shell 2a, in correspondence with the bottom 3a, is provided with two openings 5,6 longitudinally spaced along the X axis, respectively, for the inlet of the humid air and the outlet of the dry air. In the non-limiting example of Figures 1 and 2, the opening 5 is located on the top of the shell 2a, while the opening 6 is located laterally, at an angular distance of about 90 ° with respect to the opening 5. The dryer 1, in correspondence with the openings 5,6, is provided with two respective portions of flanged piping 7,8.

A separator baffle 11 divides the pressure vessel 2 into two chambers 12a, b communicating with the outside through a respective opening 5,6. The humid air to be dried is introduced into the chamber 12a through the opening 5 while the dried air is extracted from the chamber 12b through the opening 6.

A window 13 is provided on the septum 11 onto which the inlet section of a thermal pre-exchange circuit 9 faces, extending along the X axis from the septum 11 to a terminal section 32.

A finned pack exchanger 10 is adjacent to the heat pre-exchange circuit 9. The finned pack exchanger 10 extends along the X axis from section 32 to a terminal section 14, close to the bottom 3b.

The pre-change circuit 9 comprises a shell and tube exchanger 15, the tubes of which are interconnected and supported by a fin 16 comprising a plurality of equally spaced fins 16a extending along the X axis from the opening 13 to the section 32.

The dry air coming from the exchanger 10 passes through the tube bundle 15 receiving heat from the humid compressed air coming from the chamber 12a, which passes through the pre-exchange circuit 9, touching the external surface of the tube bundle 15 and the fins 16.

At the outlet of the tube bundle 15, the dry air is sent to the users through the opening 6 of the pressure vessel 2.

The finned pack exchanger 10 comprises a first tube bundle 20, in which a cooling fluid is circulated, and a second tube bundle 21, in which a thermal mass in the fluid state is circulated.

The tube bundles 20, 21 are orthogonal to the X axis and arranged on respective alternate rows, so that each row of each tube bundle is interposed between two successive rows of the other tube bundle. The mutual arrangement of the tubes of the tube bundles 20, 21 is highlighted, in the detail of Figure 5, by means of the graphic application of a surface screening on the drawing of the tubes of the tube bundle 21.

The tube bundles 20, 21 are interconnected by a plurality of fins 22, which act as a heat exchange member between the tube bundles 20, 21.

The moist pre-cooled air coming from the pre-exchange circuit 9 passes through the exchanger 10, touching the external walls of the tube bundles 20, 21 and the fins 22, giving them heat until the dew point is reached.

Near the bottom 3b the dryer 1 comprises a condensate recovery device 33, known per se.

The tube bundles 20,21 are fed by means of respective inlet tubes 23,24 and output tubes 25,26. The pipes 23,24,25,26 pass through respective holes made on the bottom 3b of the dryer.

The inlet tubes 23,24 are provided, at one respective end, with two respective collector tubes 27,28, perpendicular to the X axis and to the tube bundles 20,21. From the collector tubes 27,28, respectively, the tubes of the tube bundles 20,21 branch off.

The outlet tubes 25,26 are provided, at one respective end, with two respective collector tubes 29,30, perpendicular to the X axis and to the tube bundles 20,21. In the collector tubes 29,30, respectively, the tubes of the tube bundles 20,21 converge.

The tube bundle 20 is included in a refrigeration circuit which allows to cool both the air to be dried and, through the fins 22, the thermal mass inside the tube bundle 21.

The exchanger 10 comprises means (not shown) for circulating the thermal mass in the second tube bundle 21. According to a non-exclusive embodiment of the invention, said circulation means include a heat accumulator.

Any fluid characterized by a high thermal capacity, for example a mixture of water and glycol, can conveniently be used inside the tube bundle 21. In a possible variant embodiment of the invention, this mixture is recirculated within a closed circuit exclusively dedicated to feeding the tube bundle 21.

In a further implementation of the invention, the tube bundle 21 is fed by means of a circuit comprising one or more users external to the compressed air dryer 1.

According to a constructive variant of the invention, shown in Figures 7 and 8, a portion 21a of the second tube bundle 21 extends at least partially into the pre-exchange circuit 9 in conditions of heat exchange. The portion 21a of the tube bundle is interposed with the tubes 15 of the pre-change circuit 9 and allows to further reduce the temperature of the humid air entering the exchanger 10.

In cases where a relatively low flow rate of dry air is required from the users, the cold accumulated in the thermal mass is sufficient to guarantee the operation of the dryer 1. In these cases, the refrigeration circuit can therefore be switched off.

The mutual arrangement of the tube bundles 20, 21 in the exchanger 10 allows the efficiency of the dryer to be increased, in particular in low-speed operation, without considerably changing its dimensions. The present invention therefore solves the problems complained of with reference to the cited prior art, being able to dry compressed air with lower operating costs and with higher yields than, without modifying at the same time the basic structure and the maximum dimensions of the dryer. .

Claims (1)

CLAIMS 1.Compressed air dryer with thermal mass comprising a finned pack and thermal mass exchanger for cooling and drying a compressed air flow, characterized in that said exchanger comprises a first tube bundle in which a fluid is circulated refrigerant, a second tube bundle in which a thermal mass in the fluid state is circulated, said tube bundles being interconnected by the same finning acting as a heat exchange bridge between said tube bundles and as an exchange organ with the circulating air flow to be dried in said finning on the outside of said tube bundles. 2. A compressed air dryer according to claim 1 wherein said exchanger comprises means for circulating the thermal mass in said second tube bundle. 3. A compressed air dryer according to claim 2 wherein said circulation means comprises a heat accumulator. 4. Compressed air dryer according to one of the preceding claims, wherein said dryer comprises a heat pre-exchange circuit, placed upstream of said finned pack exchanger, acting as a heat exchange member between the air flow in inlet to said dryer and the flow of air leaving said finned pack exchanger. 5. A compressed air dryer according to claim 4 wherein said pre-change circuit comprises a plurality of tubes traversed by said air flow leaving said finned pack exchanger and externally lapped by said air flow entering said dryer. 6. A compressed air dryer according to claim 5 wherein said plurality of tubes are interconnected by means of a fin. 7. Compressed air dryer according to one of claims 4 to 6 wherein said second tube bundle extends at least partially into the pre-exchange circuit under heat exchange conditions. 8. Dryer according to one or more of the preceding claims, wherein said dryer comprises a cylindrical vessel with a longitudinal axis, the tubes of said first tube bundle, second tube bundle and tube bundle of the pre-exchange circuit being arranged inside said container, orthogonally to said longitudinal axis. 9. A compressed air dryer according to claim 1 wherein said thermal mass is a fluid mixture comprising water. 10 Compressed air dryer according to claim 1 or 9 wherein said thermal mass is a fluid mixture comprising glycol.