KR102380877B1 - Air conditioning systems for pharmaceutical processes - Google Patents

Abstract

The present invention relates to an air conditioning system for pharmaceutical processes provided in pharmaceutical equipment, and specifically, to an air conditioning system for pharmaceutical processes, which is integrally provided with a dehumidifier for supplying dehumidified air into the pharmaceutical equipment and a dust collector for removing dust generated when a coating liquid is applied, and can reduce energy consumption of a main heater by recycling high-temperature air discharged from the pharmaceutical equipment.

Description

Air conditioning systems for pharmaceutical processes

The present invention relates to an air conditioning system for a pharmaceutical process provided in pharmaceutical equipment, in which a dehumidifier for supplying dehumidified air to the inside of pharmaceutical equipment and a dust collector for removing dust generated when coating liquid is applied are integrally provided and discharged from the pharmaceutical equipment It relates to an air conditioning system for pharmaceutical processes that can reduce energy consumption of a main heater by recycling the high-temperature air that is used.

In general, pharmaceutical equipment that coats the surface of pills with a spray is currently mainly using airless spray (AIRLESS SPRAY) coating equipment and HVLP (HIGH VOLUME LOSS PRESSURE) spray coating equipment in the domestic pharmaceutical industry. Occasionally, in the case of imported automatic coating devices, the air spray method and the airless spray method are applied.

Such conventional pharmaceutical equipment is generally equipped with an air conditioning system for a pharmaceutical process including a dehumidifier for dehumidifying sucked outside air, a heater for heating outside air, and a blower for supply and circulation of outside air.

The dehumidifier used at this time injects heated air to perform dehumidification through heat exchange with the outside air.

Therefore, there is a need to develop an air conditioning system for pharmaceutical processes that can realize low carbon emission as well as economic advantages by reusing high-temperature air generated from pharmaceutical equipment to reduce energy consumption.

1. Registered Utility Model Publication No. 20-0293411 'Pill Spray Coating Apparatus' (Registration Date 2002.10.15) 2. Publication date of Published Patent Publication No. 10-2020-0010291 'Apparatus and method for coating bulk material' 2020.01.30)

As devised to solve the above problems of the present invention, an object of the present invention is to provide an air conditioning system for a pharmaceutical process that can reduce energy consumption by reusing high-temperature air generated from pharmaceutical equipment.

The air conditioning system for a pharmaceutical process of the present invention includes a pre-cooler 100 for generating cooling air by lowering the temperature of incoming outside air; a main heater 200 for generating heated air by raising the temperature of the incoming outside air; a honeycomb rotor 300 that absorbs moisture contained in the cooling air while passing through the cooling air, generates dry air, and evaporates the adsorbed water while passing the heating air to discharge wet air containing water; and pharmaceutical equipment 400 for dehumidifying the inner space by receiving dry air from the honeycomb rotor 300; ) The first outdoor air temperature increasing unit 500 for raising the temperature of the outside air flowing into the predetermined temperature; characterized in that it further comprises.

In the present invention, the first outdoor air temperature increasing unit 500 generates dehumidified circulating air through heat exchange between the exhaust air and the outdoor air, and the generated circulating air is transferred to the front end of the honeycomb rotor 300 and recirculated. characterized in that

In addition, between the main heater 200 and the honeycomb rotor 300 of the present invention, the movement path of the heating air passing through the main heater 200 is set in the honeycomb rotor 300 to the pharmaceutical equipment 400 . It characterized in that it further comprises; a first control valve 600 for controlling so as to be introduced to the side of the flow path side.

On the other hand, in the present invention, the heating air that has passed through the pharmaceutical equipment 400 during initial operation is reheated in the main heater 200 and then flows back into the pharmaceutical equipment 400, and the initial temperature increase time of the main heater 200 It is characterized by shortening.

In addition, as another feature of the present invention, it receives the high-temperature wet air discharged from the honeycomb rotor 300 and heats the preheated air branched from the outside air flowing into the precooler 100, and the heated preheating air is heated. a second outdoor air temperature increasing unit 700 for mixing the outdoor air flowing into the main heater 200; may further include.

The present invention can increase the temperature of the outside air flowing into the main heater to a certain temperature without the use of separate energy by utilizing the high-temperature exhaust air discharged from the pharmaceutical equipment, and additionally when utilizing the thermal energy contained in the high-temperature exhaust air The dehumidification efficiency of the outside air can be improved by recirculating the generated dry air to the re-humidification air conditioner.

1 is a schematic diagram showing an air conditioning system of the present invention.
Figure 2 is a schematic diagram showing an embodiment of the movement of the circulating air of the present invention.
3 is a schematic diagram showing an embodiment in which the heating air of the present invention is circulated.

Hereinafter, an embodiment of the air conditioning system for the pharmaceutical process of the present invention will be described in detail with reference to the drawings.

The present invention relates to an air conditioning system for a pharmaceutical process for supplying dry air dried by removing moisture contained in outdoor air to the inside of pharmaceutical equipment.

Referring to FIG. 1 , the air conditioning system for a pharmaceutical process includes a precooler 100 , a main heater 200 , a honeycomb rotor 300 , and pharmaceutical equipment 400 .

The precooler 100 receives external air supplied through the inlet fan 110 , and cools the delivered external air to a predetermined temperature to generate cooling air. The precooler 100 may be a precooler.

The main heater 200 sucks the outside air from a different direction from the outside air flowing into the precooler 100 , and heats up the sucked outside air to a predetermined temperature to generate heated air. An exhaust fan 210 connected to the main heater 200 is further provided in front of the main heater 200 , and outside air is introduced from the rear of the main heater 200 by the operation of the exhaust fan 210 . That is, the outside air is heated while passing through the main heater 200 , and the heated heated air passes through the exhaust fan 210 and is discharged to the atmosphere.

The honeycomb rotor 300 is a dehumidifier. Cooling air passing through the precooler 100 is delivered to the honeycomb rotor 300 , and as the cooling air passes through the inlet fan 110 , moisture contained in the cooling air is absorbed to generate dry air. In addition, the high-temperature heated air that has passed through the main heater 200 passes through the honeycomb rotor 300 , and the heated air evaporates the moisture adsorbed on the honeycomb rotor 300 , and includes the evaporated moisture at high temperature and high humidity. It is changed to a wet air and discharged.

The honeycomb rotor 300 is a honeycomb rotor type dehumidifier, and is an air-cooled air-cooler type dehumidifier that is widely used because it does not require cooling water supply.

The pharmaceutical equipment 400 is a device for forming a coating layer on the surface of the tablet by spraying a predetermined coating solution on the surface of the tablet. The dry air generated by the honeycomb rotor 300 is supplied to the inside of the pharmaceutical equipment 400 , and dehumidification of the inner space of the pharmaceutical equipment 400 is performed due to the supplied dry air.

Meanwhile, between the pharmaceutical equipment 400 and the honeycomb rotor 300 , an aftercooler 310 for removing residual moisture contained in the dry air discharged from the honeycomb rotor 300 may be further provided. The aftercooler 310 cools the dry air generated by the honeycomb rotor 300 to condense moisture contained in the dry air to remove residual moisture contained in the dry air.

The dry air from which moisture has been removed is transferred to the afterheater 320 disposed on one side of the aftercooler 310 to increase the temperature of the cooled dry air and then transferred to the pharmaceutical equipment 400 .

In addition, the aftercooler 310 and the afterheater 320 have the purpose of adjusting the temperature of the air supplied to the pharmaceutical equipment 400 . In more detail, the required temperature conditions inside the pharmaceutical equipment 400 may be changed according to the pills to be manufactured. However, the dry air discharged from the honeycomb rotor 300 maintains a constant temperature. Therefore, the dry air passes through the aftercooler 310 and the afterheater 320 before being delivered to the pharmaceutical equipment 400 to meet the required temperature conditions of the pharmaceutical equipment 400 .

Referring to FIG. 1 , the air conditioning system for a pharmaceutical process further includes a first outdoor air temperature increasing unit 500 receiving the exhaust air discharged from the pharmaceutical equipment 400 .

The exhaust air discharged from the pharmaceutical equipment 400 is hot and humid air, and the exhaust air passes through the first outdoor air temperature increasing unit 500 to heat the first outdoor air temperature increasing unit 500 . And the outdoor air flowing into the main heater 200 through the first outdoor air temperature raising unit 500 passes, and the outdoor air that is transferred to the main heater 200 while exchanging heat with the outdoor air passing through the first outdoor air temperature increasing unit 500 is made. is heated Therefore, the temperature of the outside air delivered to the main heater 200 is supplied in an elevated state, thereby shortening the operation time of the main heater 200 and reducing the amount of thermal energy used, thereby improving the operation efficiency.

On the other hand, the exhaust air delivered to the first outdoor air temperature increasing unit 500 is cooled through heat exchange, and moisture contained in the exhaust air is condensed. The condensed condensate is discharged to the outside. That is, the exhaust air is converted into dehumidified circulating air through heat exchange while passing through the inside of the first outdoor air temperature increasing unit 500 and delivered to the honeycomb rotor 300 .

At this time, the supply of the outdoor air flowing into the inlet fan 110 is blocked, and the circulating air delivered to the honeycomb rotor 300 replaces the role of the outdoor air flowing into the inlet fan 110 . Accordingly, it is possible to continuously supply dry air to the pharmaceutical equipment 400 without introducing outside air. (See FIG. 2) This has the advantage of improving the operating efficiency by minimizing the loss rate of thermal energy.

1 and 3 , a first control valve 600 is further provided between the main heater 200 and the honeycomb rotor 300 . The first control valve 600 has a purpose for controlling the movement path of the heating air to flow from the honeycomb rotor 300 to the pharmaceutical equipment 400 side. That is, the movement path of the heating air passing through the main heater 200 through the first control valve 600 may be changed to any one of the honeycomb rotor 300 and the pharmaceutical equipment 400 .

The first control valve 600 changes the path so that the heating air is directed toward the pharmaceutical equipment 400 during the initial operation of the main heater 200 . Thereafter, the heated air passes through the pharmaceutical equipment 400 and is delivered to the main heater 200 again. At this time, the operating state of the pharmaceutical equipment 400 is an OFF state.

In this case, a second control valve 610 for changing the movement path of the fluid may be further provided between the pharmaceutical equipment 400 and the first outside air temperature increasing unit 500 . The second control valve 610 changes the movement path of the air from the pharmaceutical equipment 400 to any one of the main heater 200 and the first outside air temperature increasing unit 500 .

That is, when the first control valve 600 changes the path of heating air to the pharmaceutical equipment 400 , the second control valve 610 changes the air movement path to the main heater 200 so that air can be circulated. . (See FIG. 3 ) At this time, a separate blower is provided on the moving path moving from the first control valve 600 to the pharmaceutical equipment 400 to induce smooth circulation of the heated air.

At this time, the outside air flowing into the precooler 100 and the main heater 200 is blocked, and a preheating process in which the heated air that has passed through the pharmaceutical equipment 400 circulates is performed, so that the main heater 200 and the after heater 320 are performed. It is possible to shorten the initial heating time of

Due to this, when the main heater 200 is initially operated, the temperature of the outside air passing through the main heater 200 is not transferred to the honeycomb rotor 300 at a sufficient temperature, so that the dry air from which moisture cannot be removed is transferred to the pharmaceutical equipment 400 . It is possible to solve the problem of lowering the coating quality of the pill by supplying it.

Referring to FIG. 1 , a suction fan 310 for sucking high-temperature wet air from the honeycomb rotor 300 is further provided. Between the suction fan 310 and the honeycomb rotor 300 , a second outdoor air temperature increasing unit 700 receiving the high-temperature wet air discharged from the honeycomb rotor 300 may be further provided.

Meanwhile, a branch valve 900 for branching the outside air transferred to the precooler 100 is further provided between the inlet fan 110 and the precooler 100 , and the preheating air branched from the branch valve 900 is connected to the second It is transmitted to the outdoor air temperature rising unit (700).

The high-temperature wet air passing through the second outdoor air temperature raising unit 700 heats the second outdoor air temperature raising unit 700 and heats the preheating air while exchanging heat with the preheating air delivered to the second outdoor air temperature increasing unit 700 . The preheated air heated in the second outdoor air temperature increasing unit 700 is mixed with the outdoor air flowing into the main heater 200 to increase the temperature of the outdoor air flowing into the main heater 200 to improve the operation efficiency of the main heater 200 . can do it

In an embodiment of the present invention, the honeycomb rotor 300 may be a low dewpoint purge. The auxiliary preheating air is branched from the preheating air (see FIG. 1 ), and the auxiliary preheating air passes through a partial space of the honeycomb rotor 300 . At this time, the auxiliary preheating air is heated while passing through a partial space of the honeycomb rotor 300, which is heated and heated. The heated auxiliary preheating air is mixed with the outside air flowing into the main heater 200 to raise the temperature of the outside air. Accordingly, the energy consumption and operating time of the main heater 200 can be shortened.

Referring to FIG. 1 , between the pharmaceutical equipment 400 and the first outdoor air temperature increasing unit 500, a dust collection filter 800 for collecting dust, dust, etc. contained in the exhaust air discharged from the pharmaceutical equipment 400 is further provided. can be

The present invention according to such a configuration has an advantage in that the energy consumption efficiency of the present invention can be improved by recycling the high-temperature exhaust air discharged from pharmaceutical equipment.

100: precooler 200: main heater
300: honeycomb rotor 400: pharmaceutical equipment
500: first outdoor air temperature rising unit

Claims (5)

a precooler 100 for generating cooling air by lowering the temperature of the incoming outside air;
a main heater 200 for generating heated air by raising the temperature of the incoming outside air;
a honeycomb rotor 300 that absorbs moisture contained in the cooling air as the cooling air passes through, generates dry air, and evaporates the adsorbed moisture while passing the heating air to discharge wet air containing moisture; and
Pharmaceutical equipment 400 for dehumidifying the inner space by receiving the dry air from the honeycomb rotor 300;
A first outdoor air temperature raising unit 500 for receiving the high-temperature exhaust air discharged from the pharmaceutical equipment 400 and raising the temperature of the outside air flowing into the main heater 200 to a predetermined temperature;
Between the main heater 200 and the honeycomb rotor 300, the moving path of the heating air passing through the main heater 200 is directed toward the path flowing from the honeycomb rotor 300 to the pharmaceutical equipment 400 side. a first control valve 600 for controlling the inflow;
A second control valve 610 provided between the pharmaceutical equipment 400 and the first outdoor air temperature increasing unit 500 to convert the movement path of the fluid; is further provided,
The second control valve 610 blocks the outside air flowing into the main heater 200 so that the heated air that has passed through the pharmaceutical equipment 400 is reheated in the main heater 200 and then again the pharmaceutical equipment 400 . ) and circulates, and shortens the initial temperature increase time of the main heater 200 during initial operation. The method of claim 1,
The first outdoor air temperature increasing unit 500 generates dehumidified circulating air through heat exchange between the exhaust air and the outside air, and the generated circulating air is transferred to the front end of the honeycomb rotor 300 and recirculated. Air conditioning systems for pharmaceutical processes. delete delete The method of claim 1,
It receives high-temperature wet air discharged from the honeycomb rotor 300 and heats the preheated air branched from the outside air flowing into the precooler 100 , and the heated preheating air is introduced into the main heater 200 . a second outdoor air temperature increasing unit 700 for mixing with outdoor air; Air conditioning system for pharmaceutical processes, characterized in that it further comprises.

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