RU2259515C2 - Air-conditioning plant incorporating oxygen-enriching device - Google Patents

Abstract

FIELD: air-conditioning plants including those incorporating oxygen-enriching devices.

SUBSTANCE: proposed air-conditioning plant has outdoor module incorporating external heat-transfer apparatus providing exchange between heat-carrying agent and outdoor air; indoor module incorporating internal heat-transfer apparatus affording heat transfer between indoor air and heat-carrying agent; and device for feeding oxygen-enriched air incorporating air compressor that produces compressed air; oxygen-enriched air separator that functions to separate compressed air into oxygen-enriched air and nitrogen-enriched air; as well as pipe feeding oxygen-enriched air coming from oxygen-enriched air separator to indoor module; oxygen-enriched air separator has main casing, oxygen-enriched air outlet channel for passing oxygen-enriched air through delivery pipe, nitrogen-enriched air outlet channel for discharging nitrogen-enriched air into atmosphere, separating diaphragms for separating compressed air into oxygen- and nitrogen-enriched air; internal part of main case is divided into first space communicating with nitrogen-enriched air outlet channel and second space communicating with internal oxygen-enriched air outlet channel; it also has pressure control unit that functions to maintain desired pressure drop between first and second spaces above preset level. As an alternative, proposed plant can be provided in addition with heating appliance for heating separating diaphragms to desired temperature to improve selective penetrability for oxygen of separating diaphragms.

EFFECT: ability of oxygen-enriched air separator to maintain pressure drop between first and second spaces.

12 cl, 6 dwg

Description

FIELD OF THE INVENTION

The present invention relates to an installation for air conditioning; and more particularly, to an air conditioning installation having an oxygen enriching device capable of providing oxygen enriched air for a room.

State of the art

With the widespread use of air conditioning units, most of their activities are carried out in a closed room. However, when the room is kept closed for a long time, various side effects can be caused, such as difficulty breathing, headache, memory loss, etc.

As an attempt to solve these problems, systems were developed for separating oxygen-enriched air capable of supplying oxygen to the room. In general, separation systems having selective oxygen permeability are used in oxygen enriched air separation systems. Figure 1 shows a known separator of oxygen-enriched air.

As shown in FIG. 1, the oxygen-enriched air separator includes a hollow main body 10 and a plurality of cylindrical separating membranes 20 mounted inside the main body 10. The inner part of the main body 10 is divided into two spaces 11a and 11b by separating membranes 20. The air introduced into the first the space 11a penetrates the separating membranes 20 and is transferred to the second space 11b due to the pressure differential between the first and second spaces 11a and 11b. The air transferred to the second space 11b has a high oxygen concentration ranging from about 30% to 45% (hereinafter referred to as oxygen enriched air), since the separation membranes have a high selective oxygen permeability. Meanwhile, the air remaining in the first space 11a (referred to as nitrogen-enriched air, since the concentration of nitrogen in this air is relatively high) is discharged through the outlet channel 17 of the nitrogen-enriched air available on one side of the main body 10.

However, this conventional oxygen-enriched air separator has the disadvantage that there is a lot of noise when the nitrogen-enriched air is released, that is, the air remaining after oxygen separation. This, apparently, is because the outlet channel of the nitrogen-enriched air is simply an open end.

In addition, since the selective oxygen permeability of the separation membranes is sensitive to temperature fluctuations and rapidly deteriorates during the winter season, when the temperature is low, during the winter, the efficiency of the oxygen-enriched air separator is greatly reduced.

SUMMARY OF THE INVENTION

Therefore, it is an object of the present invention to provide an oxygen enriched air separator capable of maintaining a large pressure drop between the first and second spaces.

Another objective of the present invention is to provide an oxygen-enriched air separator having separation membranes with excellent selective oxygen permeability regardless of external temperature.

In accordance with one aspect of the present invention, there is provided an air conditioning installation comprising an outdoor unit having an external heat exchanger for exchanging heat between a heat transfer medium and external air; an indoor unit having an internal heat exchanger for exchanging heat between the air in the room and the coolant; and an oxygen enriched air supply device including an air compressor for providing compressed air, an oxygen enriched air separator for separating compressed air into oxygen enriched air and nitrogen enriched air; and a lead tube for supplying oxygen-enriched air received from the oxygen-enriched air separator to the indoor unit, the oxygen-enriched air separator including a main body; an outlet channel for oxygen-enriched air, discharging oxygen-enriched air through a lead pipe; an outlet channel of nitrogen-enriched air for discharging nitrogen-enriched air into the atmosphere; separating membranes for separating compressed air into oxygen-enriched air and nitrogen-enriched air, wherein the inner part of the main body is divided into a first space communicating with an exhaust channel of nitrogen-enriched air, and a second space communicating with an exhaust channel of oxygen-enriched air; and a pressure maintenance unit for maintaining a pressure differential between the first and second space exceeding a predetermined level.

In accordance with another aspect of the present invention, there is provided an air conditioning installation comprising an outdoor unit having an external heat exchanger for exchanging heat between a heat transfer medium and external air; an indoor unit having an internal heat exchanger for exchanging heat between the air in the room and the coolant; and an oxygen enriched air supply device including an air compressor for providing compressed air; an oxygen enriched air separator for separating compressed air into oxygen enriched air and nitrogen enriched air; and a lead tube for supplying oxygen-enriched air received from the oxygen-enriched air separator to the indoor unit, the oxygen-enriched air separator including a main body; an outlet channel of oxygen-enriched air connected to the indoor unit through a supply pipe; a nitrogen-enriched air exhaust duct for discharging nitrogen-enriched air to the outside; and separating membranes for separating compressed air into oxygen-enriched air and nitrogen-enriched air, wherein the inner part of the main body is divided into a first space communicating with an exhaust channel of nitrogen-enriched air and a second space communicating with an exhaust channel of oxygen-enriched air; and heating means for heating the separation membranes to a predetermined temperature to improve the selective oxygen permeability of the separation membranes.

Brief Description of the Drawings

The above and other objects and features of the present invention will become apparent from the following description of preferred embodiments thereof with reference to the accompanying drawings, in which:

figure 1 shows a view in cross section of a known installation for air conditioning;

FIG. 2 is an isometric view of an air conditioning apparatus according to the invention; FIG.

3 is a schematic view of an apparatus for supplying oxygen-enriched air according to a first embodiment of the invention;

4 is a side cross-sectional view of an apparatus for supplying oxygen-enriched air according to a first embodiment of the invention;

5 is a side cross-sectional view of an apparatus for supplying oxygen-enriched air according to a second embodiment of the invention; and

6 is a separator of oxygen-enriched air according to a third embodiment of the invention.

The best embodiment of the invention

Turning to FIG. 2, an air conditioning apparatus according to the invention is shown. An air conditioning installation includes an indoor unit 100, an outdoor unit 200, and an oxygen enriched air supply unit.

Figure 3 is a schematic view of an apparatus for supplying oxygen-enriched air of Figure 2.

With regard to figure 2 and 3, the installation for supplying oxygen-enriched air includes an air compressor 310, a separator 320 of oxygen-enriched air, the first and second filter nodes 330 and 340, a sound-absorbing device 350, an oxygen sensor 360 and a control unit (not shown )

An air compressor 310 is mounted on one side of the outdoor unit 200 to compress outside air.

The oxygen-enriched air separator 320 has one inlet channel, two outlet channels and separation membranes installed therein. The inlet channel of the oxygen-enriched air separator 320 is in communication with the air compressor 310. One of the two outlet channels of the oxygen-enriched air separator 320 is an exhaust channel 326 of nitrogen-enriched air, and the other is an outlet channel of oxygen-enriched air, and the outlet channel of nitrogen-enriched air communicates with the space outside the room, while the outlet of the oxygen-enriched air communicates with the room through the oxygen-enriched air inlet tube 304 ha. Further, the separation membranes have a high selective permeability to oxygen and are preferably made, for example, of polyimide. However, it should be noted that the material of the elements of the separating membranes is not limited to the polyimide, but can be any material having selective oxygen permeability, for example, it can be triacetate, polyculfone, polyolefin and similar materials.

The first and second filter assemblies 330 and 340 are installed in the connecting pipe 302 between the air compressor 310 and the oxygen enriched air separator 320 to remove contaminants contained in the air compressed by the air compressor 310. In addition, the first filter assembly 330 eliminates the pulsating pressure of the compressed air produced air compressor 310, and the second filter assembly 340 removes water condensate from the compressed air and discharges water condensate through an exhaust valve 342 installed therein.

The sound absorber 350 has a plurality of noise suppression materials stacked therein and is installed near the suction unit of the air compressor 310 to reduce noise when external air enters the air compressor 310. The sound absorber 350 preferably also functions to remove contaminants in the air.

An oxygen sensor 360, mounted on one side of the indoor unit, detects the oxygen concentration in the room air and transmits the estimated oxygen concentration to the control unit.

The control unit controls the installation for supplying oxygen-enriched air by turning on / off the air compressor 310 depending on the concentration of oxygen coming from the oxygen sensor 360, thereby allowing the room environment to be kept in optimal condition. At the same time, the control unit also controls the entire operation of the indoor unit and the outdoor unit of the air conditioning installation.

Meanwhile, instead of or along with the 360 oxygen sensor, a carbon dioxide sensor can be used. In addition, the CO sensor, NO _X sensor or SO _X sensor can be used independently of the oxygen sensor, depending on the environment of the room. Moreover, in addition to these sensors, a timer can be used, and the control unit controls the air compressor to operate for a period of time set by the user.

The operation of the unit for supplying oxygen-enriched air starts when the function for supplying oxygen-enriched air is selected in the manual control mode. On the other hand, in the automatic control mode, the control unit initiates the operation of the installation for supplying oxygen-enriched air when the oxygen concentration in the room air, determined by the oxygen sensor 360, falls below a predetermined level.

The supply of oxygen-enriched air is triggered by the action of the air compressor 310. The air outside the room is introduced into the air compressor 310 and is compressed there after passing through the sound-absorbing device 350. The noise produced by the introduction of air into the air compressor 310 is greatly reduced during the passage of the introduced air through the noise suppression materials present in the sound absorption device 350. In addition, the contaminants contained in the introduced air are also removed during the passage of air through the sound absorption separating apparatus 350. The air with contaminants removed by air is compressed by the compressor 310 at a high temperature with high pressure. Then, compressed air is introduced through the connecting tube 302 into the separator 320 of oxygen-enriched air. While the compressed air passes through the connecting tube 302, the first and second filter assemblies 330 and 340 mounted between the air compressor 310 and the oxygen enriched air separator 320, respectively, remove contaminants and water condensate from the compressed air.

An oxygen-enriched air separator 320 separates the introduced air into oxygen-enriched air having a higher oxygen concentration than ordinary air and a nitrogen-enriched air having a relatively lower oxygen concentration than ordinary air, using separating membranes with selective oxygen permeability installed therein. The oxygen concentration of oxygen-enriched air varies approximately in the range from approximately 30% to 45%. However, the oxygen concentration of oxygen-enriched air can be further increased to 50% by varying the pressure or pressure of compressed air supplied to the oxygen-enriched air separator 320, or by installing two or more oxygen-enriched air separators in series.

Separated oxygen-enriched air is introduced into the indoor unit 100 of the air conditioning unit through an oxygen-enriched air introduction tube 304 connected to an oxygen-enriched air outlet duct, and discharged into the room through an oxygen-enriched air outlet 305 provided at the end of the oxygen-enriched air introducing tube 304 . On the other hand, the separated nitrogen enriched air is discharged out of the room through the outlet channel 326 of the nitrogen enriched air.

If oxygen-enriched air is continuously supplied to the room to such an extent that the oxygen concentration in the room, detected by the 360 sensor, reaches or exceeds a predetermined level, for example, approximately 22% -23%, (or when the CO ₂ concentration is detected in the air by a CO ₂ sensor, component, for example, 18% or less), or if the operation stop signal is entered in the manual control mode, the control unit stops supplying oxygen-enriched air, stopping the operation of the air compressor 310.

Refer to FIG. 4, which illustrates an oxygen enriched air separator according to a first embodiment of the invention.

The oxygen-enriched air separator includes a main body 110, separating membranes 120, and a pressure maintaining unit. The main body 110 is a hollow cylinder-shaped element, and a plurality of separation membranes 120 are disposed within the main body 110 by a pair of volumetric nozzles 112, where the separation membranes are cylindrical tubes with two open end portions. The separating membranes 120 are made of materials with a high selective permeability to oxygen compared to any other elements in the air, for example, polyimide. The inner part of the main body 110 is divided by volumetric nozzles 112 and separating membranes 120 into a first space 111a communicating with the inner part of the separating membranes 120, and a second space 111b communicating with the outer part of the separating membranes 120.

The inlet 114 of the main body 110 and the outlet 117 of the nitrogen-enriched air are in communication with the first space 111a, while the outlet of the oxygen-enriched air 116 is in communication with the second space 111b. The pressure maintaining unit used here is a narrow tube 130 mounted in an exhaust duct 117 of nitrogen enriched air, and is preferably mounted in a twisted spiral.

After oxygen-enriched air is introduced into the separator through the inlet 114, a portion of the compressed air enters through the separation membranes 120 and moves from the first space 111a to the second space 111b, while the rest of the air is discharged through a narrow tube 130 located in the exhaust channel 117 of the enriched nitrogen air. The discharge rate and pressure at the outlet of the nitrogen-enriched air can always be maintained at a predetermined level, since the narrow tube 130 through which the nitrogen-enriched air is discharged has a high flow resistance.

Accordingly, the air introduced into the first space 111a cannot be exhausted out through the outlet channel 117 of the nitrogen-enriched air at the same speed as in normal cases, therefore, the pressure drop between the first and second space 111a and 111b can be maintained above a predetermined level, and the efficiency of the separation process of oxygen-enriched air can be significantly improved. In addition, the pressure drop between the nitrogen-enriched air discharged out through the narrow tube 130 and the outside atmosphere can be minimized by adjusting the length of the narrow tube 130. As a result, the noise produced by the discharge of the nitrogen-enriched air can also be minimized.

Refer to figure 5, which shows a separator of oxygen-enriched air in accordance with the second embodiment of the present invention.

The oxygen-enriched air separator according to the second embodiment has the same construction as in the first embodiment shown in FIG. 2, except that the pressure-maintaining device of the oxygen-enriched air separator in the second embodiment is a valve 130 'instead of a narrow tube 130, as in the first embodiment.

Valve 130 'controls the rate of release of air discharged through the nitrogen enriched air outlet 117 so that it is small while properly maintaining the cross-sectional area of the air flow in the nitrogen enriched air outlet 117. Accordingly, the same results can be obtained as in the first embodiment of the invention. In addition, the discharge rate and the outlet pressure of the nitrogen-enriched air can also be controlled by controlling the opening of the valve 130 '.

Referring to FIG. 6, there is provided an oxygen enriched air separator in accordance with a third embodiment of the present invention.

The oxygen-enriched air separator includes a main body 110, separating membranes 120 and a heating element 130 having a heating wire 132, a power supply switch (not shown), a temperature sensor 134 and a casing 136. The heating element 130 is mounted on the outside of the main body 110 in such a way to surround the main body 110. The heating wire 132 is located around the main body 110 and is connected to a power source through a power source switch. The heating wire 132 is preferably spirally wound around the outer surface of the main body 110. The temperature sensor 134 is mounted either in the first space 111a or in the second space 111b of the main body 110. The power supply switch supplies power to the heating wire 134 or turns it off depending on the temperature determined temperature sensor 134. The casing 136 accommodates both the main body 110 and the heating wire 132 located around the main body 110 so as not to expose the heating wire 132 from the outside.

If the temperature inside the main body 110, detected by the temperature sensor 134, exceeds a predetermined value, for example, 10 ° C, the power supply switch is maintained in the “off” state. However, if it is determined that the temperature of the main body is below a predetermined value, the power supply switch is turned on and allows power to be supplied to the heating wire 132. Then, the heating wire 132 heats the main body 110 and the separation membranes 120 installed inside the main body 110. If the separation membranes 120 are completely sufficiently heated to demonstrate selective oxygen permeability, i.e., if the temperature of the main body reaches, for example, approximately itelno 60 ° C, the power source switch is turned off again. Accordingly, an oxygen enriched air separator according to the present invention can efficiently provide oxygen for a room regardless of the outside temperature.

Although the present invention has been described with reference to preferred embodiments thereof, those skilled in the art will appreciate that various modifications and modifications can be made without departing from the spirit and scope of the claims as defined in the appended claims.

Claims (12)

1. Installation for air conditioning, comprising an outdoor unit having an external heat exchanger for heat exchange between the coolant and the external air, an indoor unit having an internal heat exchanger for heat exchange between the air in the room and the coolant, and an oxygen-enriched air supply device including an air compressor for providing compressed air, an oxygen-enriched air separator for separating compressed air into oxygen-enriched air and nitrogen-enriched air, and a supply pipe a box for supplying oxygen-enriched air received from the oxygen-enriched air separator to an indoor unit, in which the oxygen-enriched air separator includes a main body, an outlet for oxygen-enriched air, discharging oxygen-enriched air through a supply pipe, an outlet for nitrogen-enriched air to discharge enriched air nitrogen into the atmosphere, separating membranes for separating compressed air into oxygen-enriched air and nitrogen-enriched air, at than the inner part of the main body is divided into a first space communicating with the outlet channel of nitrogen-enriched air, and a second space communicating with the outlet channel of oxygen-enriched air, and a pressure maintaining unit for maintaining the pressure differential between the first and second space above a predetermined level. 2. The installation according to claim 1, in which the pressure maintaining unit is a narrow tube with open end sections passing from the outlet channel of nitrogen-enriched air. 3. The installation according to claim 2, in which the narrow tube is twisted in the form of a spiral. 4. The installation according to claim 1, in which the pressure maintaining unit is a valve installed in the outlet channel of nitrogen-enriched air. 5. The installation according to claim 1, in which the device for supplying oxygen-enriched air further includes a first filter assembly mounted in a connecting tube between the air compressor and the oxygen-enriched air separator to remove contaminants in the compressed air and reduce the pulsating pressure of the compressed air, the second node a filter installed in the connecting tube between the air compressor and the oxygen-enriched air separator to remove contaminants and water condensate from the compressed air. 6. The apparatus of claim 5, wherein the second filter assembly has an exhaust valve for discharging the separated water condensate. 7. The installation according to claim 1, in which the device for supplying oxygen-enriched air further includes a sensor for determining the environment of the room and a control unit for controlling the operation of the indoor unit, the outdoor unit and the air compressor depending on the detected room environment. 8. The apparatus of claim 7, wherein the sensor is an oxygen sensor for determining an oxygen concentration in a room air. 9. The apparatus of claim 7, wherein the sensor is a carbon dioxide sensor for determining a concentration of carbon dioxide in a room air. 10. The installation according to claim 1, in which the device for supplying oxygen-enriched air further includes a sound-absorbing device mounted near the suction unit of the air compressor. 11. Installation for air conditioning, comprising an outdoor unit having an external heat exchanger for heat exchange between the heat transfer medium and external air, an indoor unit having an internal heat exchanger for heat transfer between the air in the room and the heat transfer medium, and an oxygen-enriched air supply device including an air compressor for providing compressed air, an oxygen-enriched air separator for separating compressed air into oxygen-enriched air and nitrogen-enriched air, and supply air a box for supplying oxygen-enriched air received from the oxygen-enriched air separator to the indoor unit, the oxygen-enriched air separator comprising a main body, an outlet for oxygen-enriched air connected to the indoor unit through a supply tube, an outlet for nitrogen-enriched air to discharge nitrogen-enriched air air to the outside, and separating membranes for separating compressed air into oxygen-enriched air and nitrogen-enriched air, while the inside a portion of the main body is divided into a first space communicating with an exhaust channel of nitrogen-enriched air, and a second space communicating with an exhaust channel of oxygen-enriched air, and heating means for heating the separation membranes to a predetermined temperature to improve the selective oxygen permeability of the separation membranes. 12. The installation according to claim 11, in which the heating means includes a heating wire located around the main body, a temperature sensor for determining the temperature inside the main body or outside the main body, a switch for controlling the power supplied to the heating wire, the switch being configured to turn on when the temperature detected by the temperature sensor is lower than the first preset value, and with the possibility of switching off when the temperature detected by the temperature sensor The temperature is higher than the second setpoint in excess of the first setpoint.

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