FR2795493A1 - Air-conditioning unit with water evaporation condensing unit - Google Patents

Abstract

Gaseous refrigerant, pressurized by a compressor (10) is converted to liquid form in a condenser (20), sprayed with water (40) through a magnetic valve (402) activated by a control unit (404). A motor-operated fan (602) facilitates the evaporation of the water. A number of condenser coils are coated with absorbers, onto which the water is sprayed. The compressor has a low compression ratio. The fan operates by sucking air between the condenser coils and carrying heat away from the air-conditioner unit.

Description

The present invention relates to an evaporator / condenser device for use in an air conditioner (cooler), and more particularly to such an evaporator / condenser device which significantly improves the operating efficiency of the air conditioner (cooler). SUMMARY OF THE INVENTION

Air conditioners (chillers) are widely used in many countries in the summer to condition the air in buildings, premises, trains, cars, etc. When an air conditioner works, it consumes a lot of energy. In a conventional air conditioner, a coolant in the liquid state is directed to an evaporator to effect heat exchange with air, the cooling air being conducted into the interior space of a building of a local, train or car. After a heat exchange process, the coolant in the liquid state is converted to a gaseous coolant, the gaseous coolant being compressed by means of a coolant. compressor and pumped to a condenser where the cooling agent in the gaseous state returns to the liquid state. On the other hand, the condensing units of conventional air conditioners are divided into three types, namely the air-cooled type, the water-cooled type, and the evaporator type. An air-cooled type air conditioner uses convective air currents to dissipate heat from its condensing unit. Rapid heat removal requires a large air contact area and strong drafts. It follows that an air-cooled type air conditioner is bulky, consumes a lot of energy, and is very noisy in operation. A water cooled type air conditioner uses cooling water to remove heat from its condensing unit. However, a water-cooled type air conditioner is expensive and consumes a lot of cooling water. In addition, the installation of a high water tank for a water-cooled type air conditioner is complicated, and it may be the cause of so-called legionnaire syndrome. An evaporator-type air conditioner dissipates the heat by evaporation of water (1 liter of water absorbs about 539 calories when it evaporates). The heat dissipation effect is significantly better with an evaporator-type air conditioner than with an air-cooled type air conditioner or a water-cooled type air conditioner. However, when an evaporator type air conditioner is used, a water storage means is required to collect residual water that is not evaporated in the evaporator / condenser block of the air conditioner.

The present invention has been made to design an evaporator / condenser device for an air conditioner that does not have the aforementioned drawbacks. An object of the present invention has been to provide an evaporator / condenser device which allows the supplied cooling water to be completely evaporated, so that the heat can be effectively removed during its operation.

Another object of the present invention has been to provide an evaporator / condenser device which is compact, has all of its integrated elements, and can be easily installed in an air conditioner.

According to a feature of the present invention, the evaporator / condenser device comprises an evaporator / condenser block for condensing a cooling agent from the gaseous state to the liquid state, the evaporator / condenser unit comprising a plurality of condensing coils and absorbent means covering the condensing coils, a compressor with a low compression ratio controlled to pump the coolant in the gaseous state into the evaporator / condenser unit, a water supply system comprising a PC control card and an electromagnetic valve controlled by the PC control board for supplying cooling water from the water source to the absorbent material layer of each condensing coil, and a condensing fan controlled to establish flow currents; air through intervals in the condenser coils of the evaporator / condenser block for evacuate the heat from the evaporator / condenser block.

According to another characteristic of the present invention, the condensing coils each comprise a metal coil tube and a layer of absorbent material covering the periphery of the metal coil tube, and the water supply system comprises a plurality of tubing tubes. vaporizing water and absorbent material covering the water outlets of the water spray tubes to allow the supplied cooling water to be evenly and evenly distributed in the absorbent material on the condensing coils.

These features and advantages of the invention will appear more clearly in the following description and the accompanying drawings, in which Fig. 1 is a liquid state / gaseous state curve obtained with the cooling agent R-22; Figure 2 is an exploded view of an air conditioner designed according to the present invention; Figure 3 is an elevational view of the air conditioner shown in Figure 2; Figure 4 is a perspective view of an evaporator / condenser unit according to the present invention; Figure 5 is a perspective view of a variant of the evaporator / condenser unit according to the present invention; Figure 6 is an exploded view of the evaporator / condenser unit shown in Figure 4; Fig. 7 is a perspective view of a condensation coil according to the present invention; Figure 7a is an enlarged view of a portion of Figure 7; Fig. 8 is a diagram showing the arrangement of the water vaporization tubes, the water supply line and the electromagnetic valve of the water supply system according to the present invention; Figure 9 is a Mollier diagram for R-22, obtained with a conventional condenser block; Figure 10 is a Mollier diagram for R-22, obtained with an evaporator / condenser unit according to the present invention; and Fig. 11 is a perspective view of a condenser device combination according to the present invention.

Figure 1 is a liquid state / gaseous state curve obtained with an R-22 coolant. As indicated, the coolant can easily be condensed at low condensing pressure at low temperatures. For example, at 45 C, the theoretical value of the relative pressure is about 18 <B> kg / </ B> cm 2; if the temperature falls to 30 C, the theoretical value of the relative pressure can be considerably reduced to 12.27 <B> kg / </ B> cm2. Therefore, by reducing the operating pressure of the compressor of the condensing device of an air conditioning or refrigeration system, much of the power (horsepower) of the compressor power can be saved in order to improve the EER of the air conditioning or refrigeration system. The present invention is based on the rule that the condensation temperature is directly proportional to the condensing pressure during the exchange of a coolant between the liquid state and the gaseous state.

Referring to FIGS. 2 and 3, they represent a low compression ratio compressor 10 which operates to pump a gaseous coolant under high pressure and at elevated temperature into an evaporator / condenser unit 20, to condense it at a high temperature. liquid state. A water supply system 40 is controlled by a PC control board 404 for periodically supplying water to the evaporator / condenser unit 20. A condensing fan 60, which includes a motor 604 and a fan block 602, is controlled to create air currents through air passages in the evaporator / condenser unit 20, so that heat and moisture are rapidly removed from the evaporator / condenser unit 20. The PC control board 404 includes a water pressure selector switch to select high, medium, low water pressure levels. The PC control board 404 controls an electromagnetic valve 402 of the water supply system 40, causing the opening and closing of the electromagnetic valve 402 according to the operating cycle of the compressor 10, so that sufficient water can be supplied to the evaporator / condenser unit 20 to cool the coolant and the compressor 10. During the operation of the compressor 10, the supplied water is evaporated with the heat, and the residual water, if any , is collected for reuse. The electromagnetic valve 402 controls the passage of water between the water source, which may for example be a pumping station, and the water supply line, identified at 412, of the water supply system 40 The water supply system 40 further includes a manual switch 406, which is operated to continuously supply water for washing the machine, and a plurality of water vaporization tubes 408 respectively connected to each other. `to the water supply line 412 and installed in the evaporator / condenser block 20.

Referring to FIGS. 4 and 5, it can be seen that the evaporator / condenser unit 20 may have a rectilinear shape as shown in FIG. 4, or a curve as shown in FIG. 5. The evaporator / condenser unit 20 comprises a plurality of support frames 206, a plurality of independent condensing coils 204 secured to the support mounts 206 and arranged in parallel or stacked to circulate a coolant, the condensing coils 204 being respectively coated with absorbent material 202 (Fig. 6), and defining between their sections a plurality of air passages 212, a plurality of clamping bars 208 respectively attached to the support frames 206 by screws for securing together the condensing coils 204 and the support frames 206. water vaporization 408 of the water supply system 40 (see also FIG. 2) are respectively attached to the frames support tube 206 at different levels, and controlled to vaporize water on the condensation coils 204. The water spray tubes 408 are respectively coated with an absorbent material 410, so that the vaporized water can be absorbed. by the absorbent material 410, then evenly and evenly distributed over the condensation coils 204.

Referring to FIGS. 7 and 7A, it can be seen that the condensation coil 204 comprises a metal coil tube 210 and a strip of absorbent material 202 wound helically around the metal coil tube 210. Alternatively, the absorbent material 202 may be packaged under The absorbent material 202 may be made with a nonwoven fabric, fabric, natural fibers, synthetic fibers, recycled fibers, mineral fibers, and the like.

Fig. 8 shows water spray tubes 408 which may be round tubes or flat tubes. The water outlets of the water spray tubes 408 may be designed with a narrow elongated shape or a circular shape. Each spraying tube 408 has a diameter that gradually decreases from the water supply line 412 to its other end, so that the cooling water can be uniformly distributed to the evaporator / condenser unit 20.

As indicated above, the evaporator / condenser unit 20 comprises a plurality of condensing coils 204, each condensing coil 204 comprising a metal coil tube 210 coated with a layer of absorbent material 202. When the cooling water exits water vaporizing tubes 408 of the water supply system 40, it is absorbed by the absorbent material 202 of the condensation coil 20 for heat exchange with the cooling medium passing through the metal coil tubes 210 of the coils 204, thereby allowing the heat to be rapidly removed by air currents flowing through the air passages 212 into the evaporator / condenser unit 20. Since the solenoid valve 402 of the supply system 40 is controlled by the PC control board 404, the amount of cooling water supplied from the water supply system 40 the evaporator / condenser unit 20 can be controlled approximately equal to the amount of water that is evaporated during operation of the machine.

Figure 9 shows a Mollier diagram for R-22, obtained with a conventional condenser block. Figure 10 shows a Mollier diagram for R-22, obtained with an evaporator / condenser device according to the present invention. In FIG. 9, the temperature of the cooling agent in the gaseous state at the inlet orifice of the condenser block is approximately 80 ° C., the temperature of the coolant in the liquid state at the temperature of The outlet orifice of the condenser block is approximately 37 ° C., and the condensation pressure is approximately 20 kg / cm 2-a. In FIG. 10, the temperature of the coolant in the gaseous state at the inlet orifice of the evaporator / condenser device is about 60 ° C., the temperature of the coolant in the liquid state at the outlet of the evaporator / condenser device is about 30 C, and the condensing pressure is about 14 <B> kg / </ B> cmz-a (theoretically, the condensing pressure if R- 22 to 30 C is about 12.27 <B> kg / </ B> cmz-a, see Figure 1). Because the compression ratio is greatly reduced, the temperature of the condensed coolant can be decreased by about 7 ° C, thus improving the efficiency by about 20%. Because the compression ratio is greatly reduced, the energy consumption of the compressor 10 can be reduced by about $ 25, compared to an equivalent conventional block. Therefore, the evaporator / condenser device of the present invention can significantly reduce the energy consumption of an air conditioner or refrigerator, and significantly improve its EER (or COP) value by about 50%. Based on tests conducted with the Shuan-Shih Electric Engineers Taiwan model RC870489 at Taiwan's Air-conditioning Department of Hsu-Lin Laboratory, the EER value is 4.027 kcal / hour. , 68). Compared with equivalent conventional devices, the energy saving is about 40%.

Referring to FIG. 11, it will be seen that the evaporator / condenser unit 20 can be attached to a conventional air cooling condenser 80 to form a combination of condenser device. The block 80 is advantageously a condenser block radiating air cooling fins.

 It should be noted that the drawings are for illustrative purposes only and should not be construed as limiting the scope of the invention.

Claims (7)

1) Evaporator / condenser device characterized in that it comprises an evaporator / condenser unit (20) for condensing a cooling agent from a gaseous state to a liquid state, said evaporator / condenser unit (20) comprising a plurality of condensing coils (204) covered with absorbent means (202); a low compression ratio compressor (10) controlled for pumping a gaseous coolant into said evaporator / condenser block (20); a water supply system (40) having a PC control board (404) and an electromagnetic valve (402) controlled by said PC control board (404) for supplying cooling water from a a source of water to the absorbent material layer (202) of each of said condensing coils (204) of said evaporator / condenser unit (20); and a condensing fan (60) having a motor (604) and a fan blade unit (602) driven by said motor (604) to create air currents in intervals in the condensing coils (204) said evaporator / condenser block (20), which exhaust heat from said evaporator / condenser block (20). Evaporator / condenser apparatus according to claim 1, characterized in that said PC control board (404) of said water supply system (40) includes a selector switch for high level water pressure selections. , medium and low, and controls the operation of said electromagnetic valve (402) according to the operating cycle of said low compression ratio compressor (10), to allow the cooling water to be supplied periodically to said evaporator block / condenser (20) in such a manner that the evaporation rate of water in said evaporator / condenser unit (20) is approximately equal to the supplied volume of cooling water from said water supply system ( 40). Evaporator / condenser apparatus according to claim 1 or 2, characterized in that said water supply system (40) comprises a water supply line (412) having a connected water inlet end to said electromagnetic valve (402) and water outlet ends, and a plurality of water vaporization tubes (408) respectively connected to the water outlet ends of said water supply pipe (412) for supplying cooling water to said condensing coils (204), said water vaporization tubes (408) each having a gradually decreasing diameter from said water supply line (412), a plurality of water outlets respectively facing said condensing tubes (204), and absorbent material (410) provided on said water outlets. 4) Evaporator / condenser device according to one of claims 1 to 3, characterized in that said water supply system (40) further comprises a manual switch (406) operated for a continuous supply of said evaporator / condenser block (20). 5) Evaporator / condenser device according to one of claims 1 to 4; characterized in that said evaporator / condenser block (20) comprises at least one support mount (206) for supporting said condensing coils (204), and at least one clamp bar (208) attached to said support mount ( 206) for holding said condensation coils (204) in place. 6) Evaporator / condenser device according to one of claims 1 to 5, characterized in that it further comprises a condenser type radiating fins air cooling unit (80) attached to said evaporator / condenser block (20). 7) evaporator / condenser device according to one of claims 1 to 6, characterized in that said condensing coils (204) each comprise a metal coil tube (210) and a layer of absorbent material (202) covering the periphery of said metal coil tube (210).