KR200320308Y1 - An apparatus for supply of compressed air - Google Patents

Abstract

The present invention relates to a compressed air supply device which is capable of extending the life of a compressor by cooling the compressor oil and removing moisture mixed with the oil to prevent deterioration of the function of the compressor oil by heat and moisture.

According to the present invention, the cylinder 212 and the piston 213 for compressing the suctioned outside air is provided at the top and the oil chamber 211 in which the oil 10 is accommodated at the bottom and the oil 10 of the oil chamber 211. ), The compressor 210 having an oil supply means 215 for supplying the inner wall surface of the cylinder 212, the evaporator 251 connected to the front end or the rear end of the compressor 210 and forming a cooling cycle, the refrigerant In the compressed air supply apparatus including a compressor (252), a condenser (253), an expander (254) and a refrigerant circulation passage (255a, 255b, 255c, 255d) to cool the air supplied. It is connected to the cooler 250 is installed to be immersed in the oil 10 in the oil chamber 211 and to cool the oil 10 by the refrigerant supplied therein and included in the oil 10 on the outer surface Cooling body 240 to allow the condensed moisture and the bottom of the compressor 210 and the The compressed air supply device further comprises a Polyhedrin 240, the outlet means (261, 262) to discharge the condensed water collected in the bottom oil chamber (211) after the condensation to the outside by, is provided.

Description

Compressed air supply unit {An apparatus for supply of compressed air}

The present invention relates to a compressed air supply device, and more particularly to cool the compressor oil and at the same time to remove the moisture contained in the oil to prevent the deterioration of the function of the oil by heat and moisture to extend the life of the compressor To a compressed air supply device.

In general, the compressed air supply device is connected to various mechanical equipment or compressed air injection mechanisms operated by pneumatic pressure to supply compressed air to a predetermined pressure and supply the compressed air to a predetermined pressure. The device is shown.

As shown, the conventional compressed air supply device is provided with a compressor 110 for compressing the air sucked from the outside and a compressed air tank 140 for storing the compressed air by the compressor 110 and the predetermined pressure It is configured to supply the compressed air to the connected mechanical equipment or injection mechanism.

In the compressed air supply device, the inner bottom of the compressor 110 is provided with an oil chamber 111 in which the oil 10 is accommodated, and the crank shaft 114 connected to the piston 113 inside the cylinder 112. It is equipped with a rotary oil supplier 115 for supplying the oil 10 to the inner wall surface of the cylinder. In addition, the oil 10 is to protect the inside of the compressor 110 by cooling the compression heat generated inside the compressor 110 and forming a film on the surface of the driving unit to be rubbed. When the compressor oil 10 is overheated, Since the cooling function and the lubrication function are deteriorated, an air-cooled or water-cooled oil cooler 150 having a radiator 121 and a blower 122 is connected to one side of the oil chamber 111 of the compressor 110.

However, the oil 10 inside the compressor 110 is mixed with water condensed from the compressed air. As described above, the conventional compressed air supply device is simply a temperature of the oil 10 inside the oil chamber 111. The oil cooler 150 is provided to lower the oil, and there is no means for removing the water contained in the oil 10. Therefore, the viscosity of the compressor oil 10 decreases as a whole as the water content increases. At the same time, there was no choice but to be uneven. Accordingly, since the oil 10 whose function is degraded by moisture is continuously supplied to the inner wall surface of the cylinder 112 of the compressor 110, the lubrication inside the compressor 110 becomes very poor, and the compressor 110 is primarily operated. In addition to deepening the wear of each driving unit therein, it promotes the oil 10 temperature rise in the compressor 110 to further lower the viscosity of the oil 10, thereby lubricating the oil 10 There is a problem that causes a further vicious cycle to significantly shorten the life of the compressor (110).

The present invention is to solve the problems as described above, the object of the present invention is to cool the compressor oil at the same time to remove the moisture mixed in the oil to prevent the deterioration of the function of the compressor oil by heat and moisture life of the compressor It is to provide a compressed air supply device that can be extended.

1 is a block diagram showing a conventional compressed air supply device

2 is a configuration diagram of an embodiment of a compressed air supply apparatus according to the present invention

<Description of the symbols for the main parts of the drawings>

210: compressor 211: oil chamber

212 cylinder 213 piston

215: oil supply 240: cooling body

250: cooler 251: evaporator

252: refrigerant compressor 253: condenser

254: expanders 255a, 255b, 255c, 255d: refrigerant circulation pipe

259: cooling chamber 260: compressed air tank

261: discharge pipe 262: discharge valve

271, 272: heat exchanger

According to the present invention, the cylinder 212 and the piston 213 for compressing the suctioned outside air is provided at the top and the oil chamber 211 in which the oil 10 is accommodated at the bottom and the oil 10 of the oil chamber 211. ), The compressor 210 having an oil supply means 215 for supplying the inner wall surface of the cylinder 212, the evaporator 251 connected to the front end or the rear end of the compressor 210 and forming a cooling cycle, the refrigerant In the compressed air supply apparatus including a compressor (252), a condenser (253), an expander (254) and a refrigerant circulation passage (255a, 255b, 255c, 255d) to cool the air supplied. It is connected to the cooler 250 is installed to be immersed in the oil 10 in the oil chamber 211 and to cool the oil 10 by the refrigerant supplied therein and included in the oil 10 on the outer surface Cooling body 240 to allow the condensed moisture and the bottom of the compressor 210 and the The compressed air supply device further comprises a Polyhedrin 240, the outlet means (261, 262) to discharge the condensed water collected in the bottom oil chamber (211) after the condensation to the outside by, is provided.

According to another feature of the present invention, the cooler 250 is connected to the air suction pipe passage 201 of the front end of the compressor 210 is installed compressed air supply device characterized in that to cool the air sucked into the compressor 210 Is provided.

The above objects, features and advantages will become more apparent from the following detailed description taken in conjunction with the accompanying drawings. Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Figure 2 is a block diagram showing an embodiment configuration of a compressed air supply apparatus according to the present invention.

As shown, the compressed air supply apparatus of the present invention is connected to the air suction pipe passage 201 on one side and the compressor 210 for compressing the air sucked through the air suction pipe passage 201 to a predetermined pressure, and the compressor A compressed air tank 260 connected to the air transport pipe 202 and storing the compressed air by the compressor 210 therein, and one side thereof is connected to the air suction pipe path 201 and the other. The side is connected to the air transfer pipe 202, the cooler 250 for cooling the air sucked into the compressor 210 and the air compressed by the compressor 210, and for removing the moisture contained in the compressor oil (10) It consists of water removal means.

Here, the compressor 210 is provided with a plurality of cylinders 212 and the piston 213 on the upper inner side, the crank shaft 214 connected to the piston 213 via the connecting rod 216 is provided at the lower side thereof. It consists of a normal reciprocating compressor installed, the inner bottom is formed with an oil chamber (211) for accommodating the oil (10), the crankshaft (214) to the oil (10) of the oil chamber (211) The oil supplier 215 is mounted to partially lock and is configured to supply the oil 10 of the oil chamber 211 to the inner wall surface of the cylinder 212 according to the rotation of the crankshaft 214.

In addition, the compressor 210 is provided with a connecting pipe 219 connecting the inlet 217 and the exhaust port 218 of the cylinder 212 to each other, which is closed when the compressor 210 is operated. And a solenoid valve 205 which is opened when the compressor 210 is inoperative is installed. As a result, the inlet 217 and the exhaust port 218 are communicated with each other when the compressor 210 is inoperative. Then, the inlet 217 and the exhaust port 218 of each cylinder 212 are restarted when the compressor 210 is restarted. The piston starts to operate at no load with no pressure difference between the engines and starts smoothly.

The cooler 250 is a conventional refrigerant circulation type cooler, and is evaporator 251, refrigerant compressor 252, condenser 253, and expander 254 sequentially connected through refrigerant circulation conduits 255a, 255b, 255c, and 255d. ) Is provided, the inflator 254 may be made of a conventional expansion valve, capillary tube and the like. In addition, first and second heat exchangers 271 and 272 connected to the cooler 250 are installed in the air suction pipe path 201 and the air transfer pipe path 202, respectively. The first and second heat exchangers 271 and 272 may be air-cooled or water-cooled, and are provided in the cooling chamber 259 in which the evaporator 251 of the cooler 250 is installed through a cooling fluid circulation pipe 281. Is connected and configured to cool the air transported through the air suction pipe passage 201 and the air transfer pipe passage 202 by the cooling air or cooling water supplied from the cooler 250, respectively. In addition, in some cases, the evaporator 251 of the cooler 250 may be directly installed in the first and second heat exchangers 271 and 272.

The water removing means is installed to be immersed in the oil 10 accommodated in the oil chamber 211 of the compressor 210 and one side of the refrigerant circulation between the expander 254 and the evaporator 251 of the cooler 250. The cooler 250 connected to the conduit 255a and the other side thereof is connected to the coolant circulation conduit 255b between the evaporator 251 of the cooler 250 and the coolant compressor 252 and passes through the expander 254. A cooling body 240 in which some of the refrigerant is introduced into the inside, a discharge pipe path 261 connected to the bottom of the compressor 210 so that the bottom of the oil chamber 211 communicates with the outside, and the discharge pipe path 261. It consists of a discharge valve 262 installed in.

On the other hand, in the present embodiment, the air suction pipe passage 201 is provided with an air filter 271 for filtering foreign matter contained in the air sucked, the air transfer pipe passage 202 is oil mixed with compressed air ( An oil separator 278 for removing 10 is installed.

Referring to the effect of the compressed air supply device of the present invention configured as described above are as follows.

When the compressor 210 is operated, the outside air is sucked through the air suction pipe passage 201 and compressed to a predetermined pressure, and the compressed air is transferred to the compressed air tank 260 through the air transfer pipe passage 202. It is then stored and supplied to an external pneumatic or compressed air jet. At this time, in the present embodiment, since the cooler 250 is connected to the front end of the compressor 210 to cool the suction air first and then compress the air, the compression efficiency of the air is not only high, but also the heat generation of the compressor 210 is considerably increased. It is alleviated.

While the compressor 210 is operated, the oil 10 contained in the oil chamber 211 is sprinkled and supplied to the cylinder 212 side by a predetermined amount by the oil feeder 215 which is rotated. It moves downward along the inner wall surface of the compressor 210 and is recovered to the oil chamber 211 again. At this time, the oil 10 is condensed around the cooling body 240 in the oil chamber 211 and at the same time moisture mixed in the oil 10 is condensed on the surface of the cooling body 240, and the condensed water Due to the density difference with the silver oil 10, the oil chamber 211 sinks to the bottom. Water collected at the bottom of the oil chamber 211 through this process can be easily removed by opening the discharge valve 262 and discharging it to the outside when the compressor 210 is stopped.

Therefore, not only cooling of the oil 10 accommodated in the oil chamber 211 by the cooling body 240, but also collection and removal of water mixed in the oil 10 may be performed at the same time. Lubrication and cooling function of the compressor oil 10 has been prevented, which has the advantage that the life of the compressor 210 can be significantly extended. Particularly, in the case of the oil cooler installed in the conventional compressor 210, the oil chamber 211 cannot be cooled to a temperature below room temperature, whereas in the present invention, the refrigerant is supplied from an external cooler 250. Since the surface temperature of the cooling body 240 is maintained at a very low temperature (approximately 5 ° C. or less), as in this embodiment, even if the oil 10 is configured to pre-cool the air sucked into the compressor 210. The difference between the temperature and the temperature of the cooling body 240 is increased to effectively condense moisture.

On the other hand, in the present invention, the cooling body 240 may be directly connected to the refrigerant purifying passages 255a and 255b of the cooler 250 to cool the oil 10 by the refrigerant gas as in the above-described embodiment, In some cases, the evaporator 251 of the cooler 250 may be connected to the cooler 250 by a separate refrigerant circulating path through which a heat exchanger is accommodated to cool the oil 10. Accordingly, the refrigerant may be formed of not only the refrigerant gas of the cooler but also a conventional fluid used for cooling such as cooling air or cooling water. In addition, the cooling body 240 collectively refers to an internal space in which the coolant supplied from the cooler 250 flows out regardless of its appearance, and the external shape is not only a pipe shape shown in FIG. 2. , Plate, cylinder, mesh, radiator and the like can be made in various forms.

The present invention described above is not limited to the above-described embodiment and the accompanying drawings, and various substitutions, modifications, and changes are possible in the art without departing from the technical spirit of the present invention. It will be clear to those of ordinary knowledge.

As described above, according to the present invention, cooling and oil of the oil 10 accommodated in the oil chamber 211 by supplying a coolant supplied from the cooler 250 to the cooling body 240 installed in the oil chamber 211. It is configured to simultaneously collect and remove the water mixed in the (10), thereby providing a compressed air supply device that can prevent the lubrication and cooling function of the compressor oil (10) due to water to extend the life of the compressor. can do.

Claims (2)

A cylinder 212 and a piston 213 for compressing the suctioned outside air are provided at an upper portion thereof, and an oil chamber 211 containing an oil 10 at a lower portion thereof, and an oil 10 of the oil chamber 211 is transferred to the cylinder ( Compressor 210 is provided with an oil supply means 215 for supplying to the inner wall surface of the 212, the evaporator 251, refrigerant compressor 252, which is connected to the front or rear end of the compressor 210 and forms a cooling cycle, In the compressed air supply apparatus including a condenser 253, an expander 254 and a refrigerant circulation conduit 255a, 255b, 255c, 255d to cool the air supplied, the cooler 250 Connected to the oil chamber 211 so as to be immersed in the oil 10 inside the oil chamber 211 so as to cool the oil 10 by the refrigerant supplied therein and to condense moisture contained in the oil 10 on its outer surface. Cooling body 240 and the bottom of the compressor 210 is provided by the cooling body 240 Compressed air supply apparatus further comprises a connected after oil chamber 211, a discharge means to discharge condensed water collected in the bottom portion to the outside (261, 262). The compressed air supply device according to claim 1, wherein the cooler (250) is connected to an air suction pipe (201) in front of the compressor (210) to cool the air sucked into the compressor (210).