KR102425343B1 - Explosion Proof type Air Conditioner - Google Patents

Abstract

The present invention relates to an explosion proof type air conditioner. More particularly, the present invention relates to an explosion proof type air conditioner that can completely seal the inside of a chamber by driving a fan of an evaporator installed indoors and a fan of a condenser installed outdoors inside the sealed chamber, and at the same time maintains a positive pressure inside the chamber with inert gas to prevent external combustible gas from entering, increasing safety. The explosion proof type air conditioner of the present invention can be safely used in various industrial sites handling flammable materials by improving the explosion-proof properties. Accordingly, the explosion proof type air conditioner of the present invention can be usefully utilized by being installed in a vehicle or transportation equipment that transports flammable dangerous goods.

Description

Explosion Proof type Air Conditioner

The present invention relates to an explosion-proof air conditioner, and more particularly, it is possible to completely seal the inside of the chamber by driving a fan of an evaporator installed indoors and a fan of a condenser installed outdoors in the sealed chamber. At the same time, it relates to an explosion-proof air conditioner capable of increasing safety by maintaining a positive pressure in the chamber with an inert gas to prevent external combustible gas from flowing in.

In general, in industrial sites such as oil refineries and chemical plants that handle combustible substances such as petroleum products, petrochemical products, explosives, combustible gas, and explosive gas, explosion-proof structures are installed in various equipment to prevent explosions caused by electric sparks in advance. It is being applied.

This explosion-proof structure is divided into explosion-proof type, narrow-pore explosion-proof type, and safety explosion-proof type according to the structure. First of all, the explosion-proof type puts electrical equipment in a sturdy sealed container and withstands the pressure even if an explosion occurs in the container so that flames do not leak to the outside. In addition, the narrow explosion-proof type connects the inside and outside of the container through a narrow gap so that flames or storms do not go out at high temperatures even if an explosion occurs inside. Electrical circuits are devised to prevent sparks or sparks that may cause an explosion.

However, since the conventional air conditioner does not have an explosion-proof structure applied to it, it is not possible to install the air conditioner in various industrial sites handling combustible materials because of the risk of ignition, so that cooling and heating cannot be performed smoothly. In addition, there are devices with explosion-proof structure applied only to some parts, but not only cannot completely block combustible materials, but also when a short circuit occurs in the general cable connecting these devices, the insulation coating peels off and causes an explosion, so there is always a risk of explosion. There was a technical problem that contained the.

Republic of Korea Patent No. 10-1964337 discloses an air conditioner to which an explosion-proof structure is applied.

The air conditioner has a problem in that it is difficult to completely seal the housing because a condenser, an evaporator, a compressor, etc. are all installed inside the sealed housing.

Republic of Korea Patent Registration No. 10-1964337: Explosion-proof air conditioner

The present invention was created to improve the above problems, in which a compressor and various electric devices are installed inside a sealed chamber, and the evaporator and condenser are installed outside the chamber, and then the steam and the condenser fan are driven inside the chamber. An object of the present invention is to provide an explosion-proof air conditioner that can completely seal the inside of the chamber and at the same time maintain a positive pressure inside the chamber with an inert gas to prevent the inflow of flammable gas from the outside, thereby increasing safety.

Explosion-proof air conditioner of the present invention for achieving the above object and the sealed chamber; a positive pressure maintaining means for maintaining the inside of the hermetic chamber at a positive pressure so that combustible gas does not flow into the inside of the hermetic chamber; An evaporator positioned indoors and installed outside the sealed chamber to evaporate refrigerant to exchange heat with indoor air, a compressor installed inside the sealed chamber to compress the refrigerant evaporated in the evaporator, and an outdoor location to seal the seal A condenser installed outside the chamber and condensing the gaseous refrigerant compressed by the compressor to exchange heat with outdoor air, and an expansion valve installed between the condenser and the evaporator to expand the refrigerant condensed in the condenser. a refrigeration cycle; and a fan driving unit installed inside the sealed chamber to rotate an indoor fan installed in the evaporator and an outdoor fan installed in the condenser.

The positive pressure maintaining means includes an inert gas supply part for supplying an inert gas into the sealed chamber, a purge part for discharging the inert gas inside the sealed chamber to the outside, and is installed inside the sealed chamber to provide the sealed chamber. and a pressure sensor for sensing the pressure of the airtight chamber, and a controller installed inside the sealed chamber to control the operation of the inert gas supply unit and the purge unit according to the pressure value sensed through the pressure sensor.

The fan driving unit includes a motor installed in the sealed chamber, and a non-contact power transmission means for transmitting the rotational force of the motor to at least one of the indoor fan and the outdoor fan in a non-contact manner.

The non-contact power transmission means is coupled to the driving shaft of the motor and is positioned outside the sealed chamber so as to face an internal magnetic positioned inside the sealed chamber and the internal magnetic with the wall of the sealed chamber interposed therebetween. and an external magnetic coupled to the rotation shaft of at least one of the indoor fan and the outdoor fan.

The drive shaft is installed to protrude in both directions of the motor, and the internal magnetics are respectively installed at both ends of the drive shaft to rotate both the indoor fan and the outdoor fan at the same time.

The fan driving unit includes a plurality of motors to independently rotate the indoor fan and the outdoor fan.

As described above, in the present invention, the compressor and various electric devices are installed inside the hermetic chamber, the evaporator and the condenser are installed outside the hermetic chamber, and then the steam and the condenser fans are driven inside the hermetic chamber. can be completely sealed inside.

In addition, according to the present invention, the inside of the sealed chamber is maintained at a positive pressure with an inert gas to prevent an external combustible gas from flowing in, thereby improving safety.

As described above, the present invention can be safely used in various industrial sites handling inflammable materials by improving the explosion-proof properties.

In addition, the present invention can be effectively utilized by being installed in a vehicle or a transportation device that transports inflammable dangerous substances.

1 is a block diagram showing an explosion-proof air conditioner according to an example of the present invention;
Figure 2 is a block diagram showing the configuration of the positive pressure maintaining means applied to Figure 1,
3 is a block diagram showing an explosion-proof air conditioner according to another example of the present invention;
4 is a block diagram showing an explosion-proof air conditioner according to another example of the present invention.

Hereinafter, an explosion-proof air conditioner according to a preferred embodiment of the present invention will be described in detail.

1 and 2, the explosion-proof air conditioner according to an embodiment of the present invention includes a sealed chamber 10, a positive pressure maintaining means for maintaining the inside of the sealed chamber 10 at positive pressure, and cooling the indoor air. The refrigeration cycle and the fan driving unit for rotating the indoor fan 27 installed in the evaporator 20 and the outdoor fan 39 installed in the condenser 30 are provided.

The sealed chamber 10 is provided with a space of a certain size therein. A compressor 15 and various electric devices are installed inside the sealed chamber 10 . The sealed chamber 10 may be installed indoors or outdoors. In addition, the sealed chamber 10 may be installed at the boundary between the indoor and the outdoor. In the illustrated example, the airtight chamber 10 is installed at the boundary between the indoor and the outdoor.

The inside of the sealing chamber 10 has a structure that can be completely sealed with the outside. The sealed chamber 10 may be formed of a synthetic resin material having high heat resistance, chemical resistance, pressure resistance, and the like. Although not shown, an openable and openable cover may be installed in the airtight chamber 10 . In this case, the gap between the sealing chamber 10 and the cover is treated with a sealing member to enable sealing.

The positive pressure maintaining means serves to maintain the inside of the hermetic chamber 10 at a positive pressure higher than atmospheric pressure so that the combustible gas does not flow into the inside from the outside of the hermetic chamber 10 .

The positive pressure maintaining means includes, for example, an inert gas supply unit 40 for supplying an inert gas into the sealed chamber 10 and a purge unit 50 for discharging the inert gas inside the sealed chamber 10 to the outside; , a pressure sensor 60 installed inside the hermetic chamber 10 to sense the pressure of the hermetic chamber 10, and a pressure value installed inside the hermetic chamber 10 and sensed through the pressure sensor 60 and a controller 65 for controlling the operations of the inert gas supply unit 40 and the purge unit 50 by the

The inert gas supply unit 40 is installed in a gas storage tank (not shown) in which the inert gas is stored, a gas supply pipe 41 connecting the gas storage tank and the sealed chamber 10, and the gas supply pipe 41 to open and close the flow path. It is provided with a valve (45).

Inert gas is stored in the gas storage tank. Nitrogen, argon, etc. are mentioned as an inert gas. Of course, a portable or movable gas storage container may be used instead of the gas storage tank.

The gas supply pipe 41 connects the gas storage tank and the hermetic chamber 10 so that the inert gas stored in the gas storage tank can be introduced into the hermetic chamber 10 . The flow path of the gas supply pipe 41 is opened and closed by the valve 45 installed in the gas supply pipe 41 . The operation of the valve 45 installed in the gas supply pipe 41 is controlled by the controller 65 .

The purge unit 50 serves to discharge the air or inert gas inside the sealed chamber 10 to the outside. The purge unit 50 includes a purge pipe 51 connected to the sealed chamber 10 , and a valve 55 installed in the purge pipe 51 .

The flow path of the purge pipe 51 is opened and closed by the valve 55 provided in the purge pipe 51 . The operation of the valve 55 installed in the purge pipe 51 is controlled by the controller 65 .

The pressure sensor 60 is installed inside the sealed chamber 10 . The pressure inside the sealed chamber 10 is measured in real time by the pressure sensor 60 and sent to the controller 65 .

The controller 65 is installed inside the sealed chamber 10 . The controller 65 has a conventional structure and includes a microprocessor and various driving circuits. The controller 65 controls the operation of the valve 45 of the inert gas supply unit 40 and the valve 55 of the purge unit 50 by the pressure value sensed through the pressure sensor 60 to control the operation of the closed chamber 10 . ) is always maintained at a constant pressure.

The refrigeration cycle includes an evaporator 20 that evaporates refrigerant and exchanges heat with indoor air, a compressor 15 that compresses the refrigerant evaporated in the evaporator 20, and a vapor phase refrigerant compressed by the compressor 15 to condense the refrigerant in the outdoor environment. It includes a condenser 30 exchanging heat with air, and an expansion valve 17 installed between the condenser 30 and the evaporator 20 to expand the refrigerant condensed in the condenser 30 .

Among the elements constituting the above-described refrigeration cycle, the compressor 15 is installed inside the sealed chamber 10 , and the evaporator 20 and the condenser 30 are installed outside the sealed chamber 10 . different from technology.

The evaporator 20 is located indoors and is installed outside the sealed chamber 10 . And the condenser 30 is located outdoors and is installed outside the sealed chamber 10 . As described above, in the present invention, the sealing chamber 10 can be completely sealed by installing the evaporator 20 for heat exchange with indoor air and the condenser 30 for heat exchange with outdoor air outside the hermetic chamber 10 .

The evaporator 20 includes an indoor housing 21 installed indoors, a first heat exchanger 23 installed inside the indoor housing 21 , and a first heat exchanger 23 for passing indoor air. It consists of a fan (27).

The indoor housing 21 is installed in a form coupled to the outside of the sealed chamber 10 . An inlet through which indoor air can be introduced and an outlet through which the cooled air is discharged through the heat exchanger 23 are formed in the indoor housing 21 . The first heat exchanger 23 is connected to the liquid separator 18 and the receiver 19 installed inside the sealed chamber 10 through a pipe. The indoor fan 27 is coupled to the rotation shaft 29 . The indoor fan 27 is rotated by the fan driving unit.

The condenser 30 includes an outdoor housing 31 installed outdoors, a second heat exchanger 33 installed inside the outdoor housing 31, and a second heat exchanger 33 for passing outdoor air. It consists of a fan (37).

The outdoor housing 31 is installed in a form coupled to the outside of the sealed chamber (10). An inlet through which outdoor air can be introduced and an outlet through which the cooled air is discharged through the second heat exchanger are formed in the outdoor housing 31 . The second heat exchanger 33 is connected to the receiver 19 and the compressor 15 installed in the sealed chamber 10 through a pipe. The outdoor fan 37 is coupled to the rotating shaft. The outdoor fan 37 is rotated by the fan driving unit.

The present invention has a structure in which the indoor fan 27 installed in the evaporator 20 and the outdoor fan 37 installed in the condenser 30 are rotated inside the sealed chamber 10 . When the motor 70 for rotating the indoor fan 27 and the outdoor fan 37 is installed in each of the evaporator 20 and the condenser 30 located outside the sealed chamber 10, there is a risk of explosion. Therefore, in the present invention, the indoor fan 27 and the outdoor fan 37 are installed outside the sealed chamber 10, and the motor 70 for rotating the indoor fan 27 and the outdoor fan 37 is installed in the sealed chamber ( 10) By installing it inside, the explosion-proof effect can be increased.

For example, the fan driving unit is non-contact for transmitting the rotational force of the motor 70 to at least one of the motor 70 installed in the sealed chamber 10 and the indoor fan 27 and the outdoor fan 37 in a non-contact manner. A power transmission means is provided.

The motor 70 is installed inside the sealed chamber 10 . In the illustrated example, one motor 70 is installed inside the sealed chamber 10 .

The non-contact power transmitting means serves to transmit the rotational force of the motor 70 to at least one of the indoor fan 27 and the outdoor fan 37 in a non-contact manner.

The non-contact power transmission means includes an internal magnetic 73 coupled to the driving shaft 71 of the motor 70 and positioned inside the sealed chamber 10, and an internal magnetic 73 with the wall of the sealed chamber 10 interposed therebetween. It is located outside the sealed chamber 10 so as to face the external magnetic 75 coupled to the rotation shaft 29, 39 of at least one of the indoor fan 27 and the outdoor fan 37.

The internal magnetic 73 has a structure in which a permanent magnet is installed on a disk-shaped driving disk. And the external magnetic 75 has a structure in which a permanent magnet is installed on a disk-shaped driven disk.

The inner magnetic 73 and the outer magnetic 75 face each other with the wall of the sealed chamber 10 interposed therebetween. The inner magnetic 73 is positioned to be spaced apart from the inner surface of the wall of the hermetic chamber 10 . And the external magnetic 75 is positioned to be spaced apart from the outer surface of the wall of the sealing chamber (10).

The inner magnetic 73 and the outer magnetic 75 have different polarities on the surfaces facing each other. Accordingly, the inner magnetic 73 and the outer magnetic 75 are attracted to each other to act. Accordingly, when the motor 70 rotates, either one of the indoor fan 27 and the outdoor fan 37 may be rotated, or both the indoor fan 27 and the outdoor fan 37 may be rotated.

In the present invention, in order to prevent the attractive force of the inner magnetic 73 and the outer magnetic 75 from weakening, the inner magnetic 73 and the outer magnetic 75 are separated within the limit of not contacting the wall of the hermetic chamber 10. It is desirable to minimize the distance. Although not shown, for this purpose, a circular inner groove larger than the diameter of the inner magnetic 73 is provided on the inner side surface of the wall corresponding to the inner magnetic 73, and the outer side of the wall corresponding to the outer magnetic 75 is provided with an external A circular outer groove larger than the diameter of the magnetic 75 may be provided. In this case, the inner magnetic 73 is positioned to be inserted into the inner groove, and the outer magnetic 75 is positioned to be inserted into the outer groove. Therefore, even if the wall of the sealed chamber 10 is thick, the distance between the inner magnetic 73 and the outer magnetic 75 can be greatly reduced.

The example shown in FIG. 1 shows that both the indoor fan 27 and the outdoor fan 37 are rotated simultaneously with one motor 70 . To this end, the drive shaft 71 of the motor 70 is installed to protrude in both directions of the motor 70 . And internal magnetics 73 are installed at both ends of the drive shaft 71, respectively. In addition, external magnetics 75 are installed at the end of the rotating shaft 29 of the indoor fan 27 and the end of the rotating shaft 39 of the outdoor fan 37 , respectively. Accordingly, by driving one motor 70, both the indoor fan 27 and the outdoor fan 37 can be rotated at the same time.

Also, as shown in FIG. 3 , the fan driving unit may include a plurality of motors 70a and 70b to independently rotate the indoor fan 27 and the outdoor fan 37 .

Referring to FIG. 3 , two motors 70a and 70b are installed in the sealed chamber 10 . In one motor 70a, the drive shaft 72a faces the evaporator 20, and in the other motor 70b, the drive shaft 72b faces the condenser 30 direction.

And internal magnets 73 are installed at the ends of the drive shafts of the respective motors 70a and 70b, respectively. In addition, external magnetics 75 are installed at the end of the rotating shaft 29 of the indoor fan 27 and the end of the rotating shaft 39 of the outdoor fan 37 , respectively. Accordingly, the indoor fan and the outdoor fan can be independently rotated by the motors that can be independently driven.

The explosion-proof air conditioner structure shown in FIGS. 1 and 3 is applied when explosion-proof both indoors and outdoors is required.

On the other hand, when explosion-proof is required only in one of indoor and outdoor areas, the explosion-proof air conditioner structure shown in FIG. 4 may be applied. The case where explosion-proof is not required indoors and explosion-proof is required outdoors is shown in FIG. 4 as an example.

Referring to FIG. 4 , two motors 70b and 70c are installed in the sealed chamber 10 . In one motor 70c, the drive shaft 72c faces the evaporator 20, and in the other motor 70b, the drive shaft 72b faces the condenser 30 direction. Among them, the driving shaft 72c of the motor 70c facing the evaporator 20 is directly coupled to the indoor fan 27 through the wall of the sealed chamber 10 . In this case, a conventional mechanical seal is applied as a mechanical sealing means to the wall of the hermetic chamber 10 through which the driving shaft 72c of the motor 70c passes, so that the inside of the hermetic chamber 10 is kept sealed. make it possible

An internal magnetic 73 is installed at the end of the drive shaft 72b of the motor 70b facing the condenser 30 . And an external magnetic 75 is installed at the end of the rotation shaft 39 of the outdoor fan (37).

As such, the indoor fan of the evaporator located indoors that does not require explosion-proof is directly connected to the motor's drive shaft to transmit the rotational force of the motor. to transmit

And, although not shown, in the opposite case, that is, when explosion-proof is required indoors and explosion-proof is not required outdoors, the indoor fan of the evaporator located in the room that requires explosion-proof is connected to the motor's drive shaft in a non-contact manner to transmit the rotational force of the motor, The outdoor fan of the condenser located outdoors that does not require explosion protection is directly connected to the motor's drive shaft to transmit the motor's rotational force.

As mentioned above, although the present invention has been described with reference to an embodiment, it will be understood that this is only an example, and that various modifications and equivalent embodiments are possible therefrom by those of ordinary skill in the art. Therefore, the true scope of protection of the present invention should be determined only by the appended claims.

10: sealed chamber 15: compressor
17: expansion valve 20: evaporator
27: indoor fan 30: condenser
37: outdoor fan 70: motor
73: internal magnetic 75: external magnetic

Claims (6)

an airtight chamber;
a positive pressure maintaining means for maintaining the inside of the hermetic chamber at a positive pressure so that combustible gas does not flow into the inside of the hermetic chamber;
An evaporator positioned indoors and installed outside the sealed chamber to evaporate refrigerant to exchange heat with indoor air, a compressor installed inside the sealed chamber to compress the refrigerant evaporated in the evaporator, and an outdoor location to seal the seal A condenser installed outside the chamber and condensing the gaseous refrigerant compressed by the compressor to exchange heat with outdoor air, and an expansion valve installed between the condenser and the evaporator to expand the refrigerant condensed in the condenser. a refrigeration cycle;
and a fan driving unit installed inside the sealed chamber to rotate an indoor fan installed in the evaporator and an outdoor fan installed in the condenser. According to claim 1, wherein the positive pressure maintaining means includes an inert gas supply unit for supplying an inert gas to the inside of the sealed chamber, a purge unit for discharging the inert gas inside the sealed chamber to the outside; a pressure sensor installed in the airtight chamber to sense the pressure of the closed chamber, and a controller installed inside the closed chamber to control the operation of the inert gas supply unit and the purge unit by the pressure value sensed through the pressure sensor Explosion-proof air conditioner, characterized in that it is provided. The method of claim 1, wherein the fan driving unit includes a motor installed inside the sealed chamber, and a non-contact power transmission means for transmitting the rotational force of the motor to at least one of the indoor fan and the outdoor fan in a non-contact manner. Explosion-proof air conditioner, characterized in that. 4. The sealing according to claim 3, wherein the non-contact power transmission means is coupled to the drive shaft of the motor to face an internal magnetic positioned inside the sealed chamber and the internal magnetic with a wall of the sealed chamber interposed therebetween. An explosion-proof air conditioner, which is located outside the chamber and includes an external magnetic coupled to a rotation shaft of at least one of the indoor fan and the outdoor fan. The explosion-proof air conditioner according to claim 4, wherein the drive shaft is installed to protrude in both directions of the motor, and the internal magnets are respectively installed at both ends of the drive shaft to rotate both the indoor fan and the outdoor fan at the same time. . The explosion-proof air conditioner according to claim 3, wherein the fan driving unit includes a plurality of motors to independently rotate the indoor fan and the outdoor fan.

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