KR20240049150A - Air Cooled DehumidifiDryer - Google Patents

Abstract

The present invention includes a rotor (10), which is divided into a dehumidification area (11), a cooling area (12), and a regeneration area (13), and is connected to the input side of the dehumidification area (11) to produce low-temperature compressed air that requires dehumidification treatment. A cooling unit 15 supplied to the dehumidification area 11 is connected to the input side of the regeneration area 13 and supplies high temperature regeneration air to the regeneration area 13 to desorb moisture adsorbed in the regeneration area 13. A regeneration unit 20 supplied to (13), a dry heater 25 connected to the output side of the dehumidification area 11 and heating the low-temperature dehumidifying compressed air discharged from the dehumidification area 11 to a high temperature, A hopper 30 connected to the drying heater 25 and drying the raw materials contained therein using high-temperature dehumidifying compressed air heated by the drying heater 25. Connected to the hopper 30, the hopper 30 A dry filter (35) filters out foreign substances contained in the high-temperature air that has passed through (30) and is connected to the output side of the regeneration area (13), so that the high-temperature and humid regeneration air that has passed through the regeneration area (13) is discharged. In the hopper 30, the high-temperature dehumidified compressed air heated by the dry heater 25 is converted into high-temperature air by the raw material accommodated inside the hopper 30. It is characterized by being

Description

Air Cooled DehumidifiDryer}

The present invention relates to an air-cooled dehumidifier. More specifically, the present invention relates to an air-cooled dehumidifier, which can stably cool raw materials contained in a hopper using high-temperature dehumidifying compressed air having a preset reference dew point of extremely low temperature, and low-temperature supplied from the outside by a regenerative blower. This relates to an air-cooled dehumidifier that can reduce energy consumption for heating the regenerated air or cooling the high-temperature air by exchanging heat with the high-temperature air discharged from the hopper.

A dehumidifier is a device that dehumidifies low-temperature air and then heats it to high temperature to dry the raw materials contained inside the hopper.

Figure 1 is a configuration diagram of a water-cooled dehumidifier. Referring to Figure 1, a water-cooled dehumidifier includes a cooler, rotor, dry heater, and hopper. First, the cooler cools the high-temperature air discharged from the hopper with water. And, the rotor dehumidifies the low-temperature air cooled by the cooler. Then, the dry heater heats the low-temperature dehumidified air dehumidified by the rotor and supplies it to the hopper. Then, the hopper dries the raw materials using high-temperature dehumidified air heated by a dry heater.

Meanwhile, the regeneration blower supplies low-temperature regeneration air to the regeneration heater. Additionally, the regeneration heater is provided between the regeneration blower and the rotor, heats the low-temperature regeneration air that has passed through the regeneration blower, and supplies it to the rotor. And, in the rotor, the high-temperature regeneration air heated by the regeneration heater desorbs moisture adsorbed from the low-temperature air cooled by the cooler.

However, in the existing water-cooled dehumidifier, there was a problem that when the cooler was in operation, a malfunction, such as water leakage or blockage, could occur in the piping provided inside the cooler.

In addition, the existing water-cooled dehumidifier had a problem in that the energy consumption of the cooler to cool the high-temperature air discharged from the hopper was large when the cooler was in operation.

In addition, in the existing water-cooled dehumidifier, when extracting dried raw materials from a hopper, there is a problem that external air may flow into the hopper or high-temperature dehumidified air may flow out, reducing the dehumidification efficiency of the raw materials.

KR 10-2017-0065791 A KR 10-1946860 B1

The present invention was developed to solve the above problems, and the purpose of the present invention is to stably cool and recycle raw materials contained in a hopper using high-temperature dehumidifying compressed air with a preset cryogenic reference dew point. An air-cooled dehumidifier is provided that heats the low-temperature regenerated air supplied from the outside by a blower with the high-temperature air discharged from the hopper, thereby reducing energy consumption for heating the regenerated air or cooling the high-temperature air. there is.

In addition, the object of the present invention is to provide an air-cooled air dryer that can continuously supply high-temperature dehumidified compressed air with a preset standard dew point of cryogenic temperature to a hopper using a non-heated air dryer, thereby improving the dehumidification efficiency of the raw materials contained in the hopper. We provide dehumidifiers.

In addition, the object of the present invention is to provide an evaporator between the regeneration blower and the regeneration heater to exchange heat with the high-temperature air discharged from the hopper to convert the low-temperature regeneration air supplied from the outside by the regeneration blower into high-temperature regeneration air. The aim is to provide an air-cooled dehumidifier that can reduce the energy consumption of the regenerative heater.

In addition, the object of the present invention is to provide an evaporator between the drying filter and the drying blower to exchange heat with the low-temperature regenerated air supplied from the outside by the regenerating blower to convert the high-temperature air discharged from the hopper into low-temperature and humid air. The goal is to provide an air-cooled dehumidifier that does not require a separate cooler.

In order to solve the above technical problems, the air-cooled cooler according to the present invention includes a rotor 10 divided into a dehumidification area 11, a cooling area 12, and a regeneration area 13, and the dehumidification area 11. A cooling unit 15 is connected to the input side of the cooling unit 15 to supply low-temperature compressed air requiring dehumidification treatment to the dehumidification area 11, and is connected to the input side of the regeneration area 13, and is adsorbed in the regeneration area 13. A regeneration unit 20 that supplies high-temperature regeneration air to the regeneration area 13 to desorb treated moisture, is connected to the output side of the dehumidification area 11, and provides low-temperature dehumidification discharged from the dehumidification area 11. A drying heater (25) that heats the compressed air to a high temperature, a hopper connected to the drying heater (25) and drying the raw materials contained therein using the high-temperature dehumidifying compressed air heated by the drying heater (25). (30), connected to the hopper 30 and connected to the drying filter 35 that filters foreign substances contained in the high-temperature air passing through the hopper 30 and the output side of the regeneration area 13, It includes a regeneration discharge line 40 through which high-temperature and humid regeneration air that has passed through the regeneration area 13 is discharged, and in the hopper 30, high-temperature dehumidifying compressed air heated by the drying heater 25 is supplied to the hopper. It is characterized in that it is converted into high temperature air by the raw materials contained within (30).

In addition, in the dehumidification area 11, moisture contained in the low-temperature compressed air supplied from the cooling unit 15 is adsorbed and converted into low-temperature dehumidified compressed air, and in the cooling area 12, the dehumidification area ( Some of the low-temperature dehumidified compressed air that has passed through 11) is recovered and cooled with low-temperature air, and in the regeneration area 13, the dehumidification area ( It is characterized in that the moisture adsorbed in 11) is desorbed.

In addition, the regeneration unit 20 includes a regeneration blower 21 that supplies low-temperature regeneration air to the evaporator 23 from the outside, and is provided on the other side of the regeneration blower 21 to remove foreign substances contained in the low-temperature regeneration air. It is connected to the filtering regeneration filter 22, the regeneration blower 21, and the dry filter 35, and the low-temperature regeneration air supplied from the outside by the regeneration blower 21 is filtered by the dry filter 35. An evaporator 23 that exchanges heat with the filtered high-temperature air and converts it into high-temperature regeneration air is connected to the input side of the evaporator 23 and the regeneration area 13, respectively, and converts the high-temperature air converted by the evaporator 23 into high-temperature regeneration air. It includes a regeneration heater 24 that heats regeneration air and supplies it to the regeneration area 13, and in the evaporator 23, the high temperature air filtered by the dry filter 35 is supplied to the regeneration blower 21. It is characterized in that it exchanges heat with low-temperature regenerative air supplied from outside and is converted into low-temperature air.

In addition, the cooling unit 15 is connected to an unheated air dryer 16 that generates low-temperature compressed air with a preset reference dew point, and to the input side of the non-heated air dryer 16 and the dehumidification area 11, respectively. a drying blower 17 that supplies low-temperature compressed air generated by the non-heating air dryer 16 to the dehumidification area 11, the non-heating air dryer 16, and the drying blower 17, respectively. A first supply line 18 and an evaporator 23 and the first supply line 18 are connected and supply low-temperature compressed air generated by the non-heated air dryer 16 to the drying blower 17. and a second supply line 19 that is respectively connected to the evaporator 23 and supplies the low-temperature air converted by the evaporator 23 to the first supply line 18, and the reference dew point is -50°C or higher -40°C. It is characterized in that it is set to ℃ or lower.

In addition, the first recovery line 45 is connected to the drying filter 35 and the evaporator 23, respectively, and supplies the high temperature air filtered by the drying filter 35 to the evaporator 23, and the cooling. The second recovery line 46 is connected to the output side of the area 12 and the first recovery line 45, respectively, and supplies the low-temperature air discharged from the cooling area 12 to the first recovery line 45. ) is characterized in that it further includes.

In addition, a temperature sensor (T) is provided on the supply side of the hopper 30 and measures the temperature of the air supplied to the hopper 30, and is provided on one side of the temperature sensor (T) to measure the temperature of the air supplied to the hopper 30. A humidity sensor (H), which measures the humidity of the air supplied to the air, is provided on the other side of the first supply line 18, and the flow rate of air supplied from the non-heated air dryer 16 to the first supply line 18 According to the measured values of the solenoid valve (S) and the temperature sensor (T) and humidity sensor (H), which are formed so that the opening degree can be changed, the drying heater 25, the non-heating air dryer ( 16) and a solenoid valve (S), respectively, and the controller (50) controls the temperature sensor (T) when the air temperature measured by the temperature sensor (T) exceeds a preset reference temperature. The dry heater 25 is controlled to be switched to the off state until the temperature of the air falls to the reference temperature, and the controller 50 controls the temperature of the air measured by the temperature sensor T. When the temperature is below the standard temperature, the heating temperature of the dry heater 25 is controlled to change to a preset standard heating temperature until the temperature of the air rises to the standard temperature, and the standard heating temperature is controlled to change to the standard heating temperature set in the dry heater 25. ) is set to the value obtained by adding the temperature deviation and the preset standard ratio to the initial heating temperature, and the temperature deviation is a value obtained by subtracting the air temperature measured by the temperature sensor (T) from the reference temperature. And, the reference ratio is proportional to the outside air temperature and the specific heat of outside air, and is set to be inversely proportional to the efficiency of the dry heater 25, the outside air is outside air, and the reference ratio is set to be 130% or more and 180% or less. It is characterized by

In addition, when the humidity of the air measured by the humidity sensor (H) exceeds the preset reference humidity, the controller 50 operates the non-heated air dryer 16 until the humidity of the air falls to the reference humidity. The standard dew point of the air discharged from is controlled to be changed to a preset setting dew point, and the set dew point is set to a value obtained by adding the standard dew point multiplied by a humidity deviation and a preset standard weight, and the humidity deviation is It is set as a value obtained by subtracting the air humidity measured by the humidity sensor (H) from the reference humidity, and the reference weight is proportional to the outside air humidity and outside air specific heat, respectively, and is determined by the efficiency of the non-heated air dryer 16. It is set to be inversely proportional, the reference weight is set to 1.2 or more and less than 1.6, and the controller 50 determines that when the humidity of the air measured by the humidity sensor (H) is less than the reference humidity, the humidity of the air is set to the reference humidity. The opening of the solenoid valve (S) is controlled to change to a preset standard opening until the humidity rises, and the standard opening is adjusted to the initial opening of the solenoid valve (S) based on the humidity deviation and the It is set by adding a value multiplied by a set setting weight, and the setting weight is set to be proportional to the outside air humidity and outside air specific heat, respectively, and inversely proportional to the square of the inner diameter of the first supply line 18, and the setting weight is 1.4. It is characterized in that it is set to less than 1.8.

In addition, the air-cooled dehumidifier according to the present invention can continuously supply high-temperature dehumidifying compressed air with a preset reference dew point of cryogenic temperature to the hopper using a non-heating air dryer, and thus has a higher dehumidification efficiency of the raw materials contained in the hopper than conventional dehumidifiers. There is an effect that can significantly improve.

In addition, the air-cooled dehumidifier according to the present invention uses a non-heating air dryer to continuously supply high-temperature dehumidifying compressed air with a preset reference dew point of extremely low temperature to the hopper, thereby preventing the inflow of external air and high-temperature dehumidification when the hopper is opened and closed. The outflow of compressed air can be minimized, which has the effect of stably drying the raw materials contained in the hopper and significantly improving the quality of the raw materials.

The air-cooled dehumidifier according to the present invention has an evaporator between the regeneration blower and the regeneration heater, and converts the low-temperature regeneration air supplied from the outside by the regeneration blower into high-temperature regeneration air by exchanging heat with the high-temperature air discharged from the hopper. This has the effect of significantly reducing the energy consumption of the regenerative heater.

In addition, the air-cooled dehumidifier according to the present invention is provided with an evaporator between the drying filter and the drying blower, and exchanges heat with the low-temperature regenerated air supplied from the outside by the regenerative blower to exchange the high-temperature air discharged from the hopper into low-temperature and humid air. This has the effect of significantly reducing the energy consumption of existing coolers.

In addition, the air-cooled dehumidifier according to the present invention controls the drying heater, non-heating air dryer, and solenoid valve respectively according to the temperature and humidity of the air supplied to the hopper, and can supply air matching the standard temperature and standard humidity to the hopper. The efficiency and productivity of air-cooled dehumidifiers are significantly improved.

Figure 1 is a configuration diagram of an existing water-cooled dehumidifier.
Figure 2 is a configuration diagram of an air-cooled dehumidifier according to the present invention.
Figure 3 is a configuration diagram of the rotor.
Figure 4 is a configuration diagram of an air-cooled dehumidifier equipped with a temperature sensor, humidity sensor, solenoid valve, and controller.
Figure 5 is a flow chart of the control process of the controller according to the measured value of the temperature sensor.
Figure 6 is a flowchart of the control process of the controller according to the measured value of the humidity sensor.

Hereinafter, in order to explain in detail enough to enable those skilled in the art of the present invention to easily implement the technical idea of the present invention, embodiments of the present invention will be described with reference to the accompanying drawings.

However, the following examples are only examples to aid understanding of the present invention, and the scope of the present invention is not reduced or limited thereby. Additionally, the present invention may be implemented in many different forms and is not limited to the embodiments described herein.

Figure 2 is a configuration diagram of an air-cooled dehumidifier 5 according to the present invention.

Referring to Figure 2, the air-cooled dehumidifier 5 according to the present invention includes a rotor 10, a cooling unit 15, a regeneration unit 20, a dry heater 25, a hopper 30, a dry filter 35, and It is configured to include a regeneration discharge line (40).

Figure 3 is a configuration diagram of the rotor 10.

Referring to FIG. 3, the rotor 10 is divided into a dehumidifying area 11, a cooling area 12, and a regeneration area 13.

At this time, in the dehumidification area 11, moisture contained in the low-temperature compressed air supplied from the cooling unit 15 is adsorbed, and the low-temperature compressed air is converted into low-temperature dehumidified compressed air.

Then, in the cooling area 12, a portion of the low-temperature dehumidified compressed air that has passed through the dehumidifying area 11 is recovered and cooled with low-temperature air.

And, in the regeneration area 13, the moisture adsorbed in the dehumidification area 11 is desorbed through the high temperature regeneration air supplied from the regeneration unit 20.

At this time, the dehumidifying area 11, the cooling area 12, and the regeneration area 13 are each formed in the circumferential direction. Additionally, the area of the dehumidifying area 11 is formed to be larger than the area of the cooling area 12 or the regeneration area 13.

In addition, the rotor 10 is formed in a honeycomb structure filled with a hygroscopic material capable of adsorbing moisture contained in low-temperature compressed air, and rotates at a preset reference speed.

When the rotor 10 rotates at a reference speed, an arbitrary point disposed on the upper surface of the rotor 10 passes through the dehumidifying area 11, the cooling area 12, and the regeneration area 13, respectively.

At this time, a molecular sieve moisture absorbent may be used as the hygroscopic material.

Additionally, the cooling unit 15 is connected to the input side of the dehumidification area 11 of the rotor 10 and supplies low-temperature compressed air requiring dehumidification treatment to the dehumidification area 11 of the rotor 10.

In addition, the regeneration unit 20 is connected to the input side of the regeneration area 13 of the rotor 10 and supplies high-temperature regeneration air to the regeneration area 10 of the rotor 10 to desorb the moisture adsorbed in the regeneration area 13. It is supplied to (13).

Additionally, the dry heater 25 is connected to the output side of the dehumidifying area 11 of the rotor 10 and heats the low-temperature dehumidifying compressed air discharged from the dehumidifying area 11 of the rotor 10 to a high temperature. At this time, the heating temperature of the dry heater 25 may be set to 150 to 160°C.

In addition, the hopper 30 is connected to the drying heater 25 and dries the raw materials contained therein using high-temperature dehumidifying compressed air heated by the drying heater 25.

Meanwhile, in the hopper 30, high-temperature dehumidified compressed air heated by the dry heater 25 is converted into high-temperature air by the raw materials contained within the hopper 30.

Additionally, the dry filter 35 is connected to the hopper 30 and filters foreign substances contained in the high-temperature air passing through the hopper 30.

In addition, the regeneration discharge line 40 is connected to the output side of the regeneration area 13 of the rotor 10, providing a passage through which the high temperature and high humidity regeneration air passing through the regeneration area 13 of the rotor 10 is discharged to the outside. do.

Meanwhile, the regeneration unit 20 includes a regeneration blower 21, a regeneration filter 22, an evaporator 23, and a regeneration heater 24.

And, the regeneration blower 21 supplies low-temperature regeneration air to the evaporator 23 from the outside.

Additionally, the regeneration filter 22 is provided on the other side of the regeneration blower 21 and filters foreign substances contained in the low-temperature regeneration air.

And, the evaporator 23 is connected to the regeneration blower 21 and the drying filter 35, respectively, so that the low-temperature regeneration air supplied from the outside by the regeneration blower 21 is converted into the high-temperature regeneration air filtered by the drying filter 35. It exchanges heat with air and converts it into high-temperature regenerated air.

In addition, the regeneration heater 24 is connected to the evaporator 23 and the input side of the regeneration area 13 of the rotor 10, respectively, and heats the high-temperature regeneration air converted by the evaporator 23 to produce the rotor 10. is supplied to the regeneration area (13). At this time, the regeneration temperature of the regeneration heater 24 may be set to 150 to 180 degrees.

Meanwhile, in the evaporator 23, the high-temperature air filtered by the dry filter 35 exchanges heat with low-temperature regenerative air supplied from the outside by the regenerative blower 21, and is converted into low-temperature air.

Meanwhile, the cooling unit 15 includes a non-heated air dryer 16, a drying blower 17, and a first supply line 18 and a second supply line 19.

First, the non-heated air dryer 16 (Heatless Air Dryer) generates low-temperature compressed air having a preset cryogenic reference dew point. At this time, the standard dew point can be set to -50℃ or higher and -40℃ or lower.

In addition, the drying blower 17 is connected to the input side of the dehumidifying area 11 of the non-heating air dryer 16 and the rotor 10, respectively, and blows the low-temperature compressed air generated by the non-heating air dryer 16 to the rotor. It is supplied to the dehumidifying area (11) of (10).

And, the first supply line 18 is connected to the non-heating air dryer 16 and the drying blower 17, respectively, so that the low-temperature compressed air generated by the non-heating air dryer 16 is supplied to the drying blower 17. It becomes a supply channel.

And, the second supply line 19 is connected to the evaporator 23 and the first supply line 18, respectively, and is a passage through which the low-temperature air converted by the evaporator 23 is supplied to the first supply line 18. It becomes.

For this reason, in the first supply line 18, the low-temperature compressed air generated by the non-heating air dryer 16 and the low-temperature air converted by the evaporator 23 are mixed and supplied to the drying blower 17. .

However, since the flow rate of low-temperature compressed air generated by the non-heated air dryer 16 is overwhelmingly greater than the flow rate of low-temperature air converted by the evaporator 23, the drying blower is supplied through the first supply line 18. The air supplied to (17) is mainly in the form of low-temperature compressed air.

Meanwhile, the air-cooled dehumidifier 5 according to the present invention may be configured to further include a first recovery line 45 and a second recovery line 46.

First, the first recovery line 45 is connected to the dry filter 35 and the evaporator 23, respectively, and becomes a passage through which the high temperature air filtered by the dry filter 35 is supplied to the evaporator 23.

In addition, the second recovery line 46 is connected to the output side of the cooling area 12 of the rotor 10 and the first recovery line 45, respectively, to collect low temperature discharged from the cooling area 12 of the rotor 10. It becomes a passage through which air is supplied to the first recovery line (45).

At this time, the flow rate of low-temperature air discharged from the cooling area 12 of the rotor 10 is about 30 wt% of the flow rate of low-temperature dehumidifying compressed air discharged from the dehumidifying area 11 of the rotor 10.

Figure 4 is a configuration diagram of an air-cooled dehumidifier 5 including a temperature sensor (T), a humidity sensor (H), a solenoid valve (S), and a controller 50.

Referring to FIG. 4, the air-cooled dehumidifier 5 according to the present invention may further include a temperature sensor (T), a humidity sensor (H), a solenoid valve (S), and a controller 50.

First, the temperature sensor T is provided on the supply side of the hopper 30 and measures the temperature of the air supplied to the hopper 30.

Additionally, the humidity sensor H is provided on one side of the temperature sensor T and measures the humidity of the air supplied to the hopper 30.

In addition, the solenoid valve (S) is provided on the other side of the first supply line (18) and has an opening degree so that the flow rate of air supplied from the non-heated air dryer (16) to the first supply line (18) can be changed. It is formed so that change is possible.

At this time, the degree of opening refers to the degree to which the solenoid valve (S) is opened. For example, when the opening degree of the solenoid valve (S) is 100%, the solenoid valve (S) is fully open, and when the opening degree of the solenoid valve (S) is 0%, the solenoid valve (S) is fully open. It is completely closed.

For example, when the opening degree of the solenoid valve (S) is 100%, 100% of air is supplied. When the opening degree of the solenoid valve (S) is 70%, air equal to 70% of the initial flow rate is supplied.

And, the controller 50 controls the drying heater 25, the non-heated air dryer 16, and the solenoid valve (S), respectively, according to the measured values of the temperature sensor (T) and the humidity sensor (H).

Figure 5 is a flowchart of the control process of the controller 50 according to the measured value of the temperature sensor T.

Referring to FIG. 5, when the temperature of the air measured by the temperature sensor T exceeds the preset reference temperature, the controller 50 turns off the drying heater 25 until the temperature of the air falls to the reference temperature. Control so that it can be converted to a state.

And, when the temperature of the air measured by the temperature sensor T is below the reference temperature, the controller 50 adjusts the heating temperature of the dry heater 25 to a preset reference temperature until the air temperature rises to the reference temperature. Controlled to change by temperature.

At this time, the standard heating temperature is set as a value obtained by adding the initial heating temperature of the dry heater 25 multiplied by the temperature deviation and a preset standard ratio. And, the temperature deviation means the value obtained by subtracting the air temperature measured by the temperature sensor (T) from the reference temperature.

For example, if the air temperature measured by the temperature sensor T is 152°C and the reference temperature is 157°C, the temperature deviation is 5°C. In addition, when the initial heating temperature of the dry heater 25 is 150°C, the standard heating temperature of the dry heater 25 is a preset standard ratio of 150 with a temperature deviation of 5°C to the initial heating temperature of the dry heater 25 of 150°C. It becomes 157.5℃ by adding 7.5℃ multiplied by %.

And, the reference ratio can be changed depending on the outside air temperature, outside air specific heat, and the efficiency of the dry heater 25. Specifically, the reference ratio may be set to be proportional to the outside air temperature and outside air specific heat, respectively, and inversely proportional to the efficiency of the dry heater 25. Here, outside air means outside air. At this time, the standard ratio may be set to 130% or more and 180% or less.

Figure 6 is a flowchart of the control process of the controller 50 according to the measured value of the humidity sensor (H).

Referring to FIG. 6, when the air humidity measured by the humidity sensor H exceeds the preset standard humidity, the controller 50 operates the non-heated air dryer 16 until the air humidity falls to the standard humidity. The standard dew point of the air discharged from is controlled to change to the preset setting dew point.

At this time, the setting dew point is set as a value obtained by adding the standard dew point multiplied by the humidity deviation and a preset standard weight. Here, the humidity deviation is set as the standard humidity minus the air humidity measured by the humidity sensor (H).

For example, if the air humidity measured by the humidity sensor (H) is 50% and the standard humidity is 40%, the humidity deviation is -10%, which is the standard humidity of 40% minus the air humidity of 50%. . In addition, when the standard dew point of the non-heated air dryer 16 is -50 degrees, the setting dew point is -63°C by adding 10.3°C, which is the standard dew point of -50°C multiplied by the humidity deviation -10% and a preset standard weight of 1.3. do.

Additionally, the reference weight may be changed depending on the outside air humidity, outside air specific heat, and the efficiency of the non-heated air dryer 16. Specifically, the reference weight may be set to be proportional to the outside air humidity and outside air specific heat, respectively, and inversely proportional to the efficiency of the non-heated air dryer 16. Here, outside air means outside air. And, the reference weight may be set to 1.2 or more and less than 1.6.

And, when the air humidity measured by the humidity sensor (H) is less than the standard humidity, the controller 50 adjusts the opening degree of the solenoid valve (S) to a preset standard opening until the air humidity rises to the standard humidity. Control the road to change.

At this time, the standard opening degree is set to be proportional to the value obtained by subtracting the air humidity measured by the humidity sensor (H) from the standard humidity.

At this time, the standard opening degree is set by adding the initial opening degree of the solenoid valve (S) multiplied by the humidity deviation and a preset setting weight. And, the humidity deviation is set as a value obtained by subtracting the air humidity measured by the humidity sensor (H) from the reference humidity.

For example, if the air humidity measured by the humidity sensor H is 30% and the standard humidity is 40%, the humidity deviation is 10% obtained by subtracting the air humidity of 30% from the standard humidity of 40%. And, if the initial opening of the solenoid valve (S) is 50%, the standard opening is 67%, which is the initial opening of 50% plus 17% multiplied by the humidity deviation of 10% and the preset setting weight of 1.7. do.

And, the setting weight may be changed depending on the outside air humidity, outside air specific heat, and the inner diameter of the first supply line 18. Specifically, the setting weight may be set to be proportional to the outside air humidity and outside air specific heat, respectively, and inversely proportional to the square of the inner diameter of the first supply line 18. Here, outside air means outside air. And, the setting weight can be set to 1.4 or more and less than 1.8.

The air-cooled dehumidifier (5) according to the present invention can continuously supply high-temperature dehumidifying compressed air with a preset reference dew point of cryogenic temperature to the hopper (30) using the non-heating air dryer (16), which is better than existing dehumidifiers. There is an effect of significantly improving the dehumidification efficiency of the raw materials contained in the hopper 30.

In addition, the air-cooled dehumidifier 5 according to the present invention uses a non-heating air dryer 16 to continuously supply high-temperature dehumidifying compressed air having a preset reference dew point of cryogenic temperature to the hopper 30. ) When opening and closing, the inflow of external air and the outflow of high-temperature dehumidifying compressed air can be minimized, thereby stably drying the raw materials contained in the hopper 30, which has the effect of significantly improving the quality of the raw materials.

The air-cooled dehumidifier (5) according to the present invention is provided with an evaporator (23) between the regeneration blower (21) and the regeneration heater (24), and transfers low-temperature regeneration air supplied from the outside by the regeneration blower (21) to a hopper ( It can be converted into high-temperature regenerative air by exchanging heat with the high-temperature air discharged from 30), which has the effect of significantly reducing the energy consumption of the regenerative heater 24.

In addition, the air-cooled dehumidifier 5 according to the present invention is provided with an evaporator 23 between the drying filter 35 and the drying blower 17, and transfers the high temperature air discharged from the hopper 30 to the regenerative blower 21. By exchanging heat with the low-temperature regenerative air supplied from outside, it can be converted into low-temperature and high-humidity air, which has the effect of significantly reducing the energy consumption of existing coolers.

In addition, the air-cooled dehumidifier 5 according to the present invention controls the drying heater 25, the non-heating air dryer 16, and the solenoid valve (S) according to the temperature and humidity of the air supplied to the hopper 30, Air matching the standard temperature and standard humidity can be supplied to the hopper 30, which has the effect of significantly improving the efficiency and productivity of the air-cooled dehumidifier 5.

As described above, the main technical idea of the present invention is to provide an air-cooled dehumidifier (5), and the embodiment described above with reference to the drawings is only one embodiment, and the true scope of the present invention is the patent claims. Although it is based on a range, it can also be said to extend to equivalent embodiments that may exist in various ways.

5: Air-cooled dehumidifier
10: rotor
11: Dehumidification area
12: Cooling area
13: Play area
15: Cooling unit
16: Non-heated air dryer
17: Drying blower
18: first supply line
19: Second supply line
20: Playback unit
21: Regenerative blower
22: Playback filter
23: Evaporator
24: Regenerative heater
25: dry heater
30: Hopper
35: dry filter
40: Regeneration discharge line
45: first recovery line
46: second recovery line
T: temperature sensor
H: Humidity sensor
S: Solenoid valve
50: controller

Claims (7)

A rotor (10) each divided into a dehumidifying area (11), a cooling area (12) and a regeneration area (13);
a cooling unit (15) connected to the input side of the dehumidification area (11) and supplying low-temperature compressed air requiring dehumidification treatment to the dehumidification area (11);
A regeneration unit 20 connected to the input side of the regeneration area 13 and supplying high temperature regeneration air to the regeneration area 13 to desorb moisture adsorbed in the regeneration area 13;
A dry heater (25) connected to the output side of the dehumidification area (11) and heating the low-temperature dehumidifying compressed air discharged from the dehumidification area (11) to a high temperature;
A hopper (30) connected to the drying heater (25) and drying the raw materials contained therein using high-temperature dehumidifying compressed air heated by the drying heater (25);
A dry filter 35 connected to the hopper 30 and filtering foreign substances contained in the high-temperature air passing through the hopper 30; and
It includes a regeneration discharge line (40) connected to the output side of the regeneration area (13), through which high temperature and high humidity regeneration air that has passed through the regeneration area (13) is discharged,
In the hopper 30
An air-cooled cooler, characterized in that the high-temperature dehumidified compressed air heated by the dry heater (25) is converted into high-temperature air by the raw materials accommodated inside the hopper (30). According to clause 1,
In the dehumidifying area 11
Moisture contained in the low-temperature compressed air supplied from the cooling unit 15 is adsorbed and converted into low-temperature dehumidifying compressed air,
In the cooling area 12
A portion of the low-temperature dehumidified compressed air that has passed through the dehumidifying area 11 is recovered and cooled with low-temperature air,
In the play area 13,
An air-cooled cooler, characterized in that the moisture adsorbed in the dehumidification area (11) is desorbed through the high temperature regeneration air supplied from the regeneration unit (20). According to clause 2,
The reproduction unit 20 is
A regeneration blower (21) that supplies low-temperature regeneration air to the evaporator (23) from the outside;
A regeneration filter (22) provided on the other side of the regeneration blower (21) to filter out foreign substances contained in the low-temperature regeneration air;
They are each connected to the regeneration blower 21 and the dry filter 35, and heat exchange the low-temperature regeneration air supplied from the outside by the regeneration blower 21 with the high-temperature air filtered by the dry filter 35. , an evaporator (23) that converts it into high-temperature regenerated air; and
A regeneration heater (24) connected to the input side of the evaporator (23) and the regeneration area (13), respectively, to heat the high-temperature regeneration air converted by the evaporator (23) and supply it to the regeneration area (13); Including,
In the evaporator (23)
An air-cooled cooler, characterized in that the high-temperature air filtered by the dry filter (35) exchanges heat with low-temperature regenerative air supplied from the outside by the regenerative blower (21) and is converted into low-temperature air. According to clause 2,
The cooling unit 15 is
A non-heated air dryer (16) that generates low-temperature compressed air with a preset reference dew point;
A drying blower ( 17);
A first supply line that is connected to the non-heated air dryer 16 and the drying blower 17, respectively, and supplies low-temperature compressed air generated by the non-heated air dryer 16 to the drying blower 17 ( 18); and
a second supply line (19) connected to the evaporator (23) and the first supply line (18), and supplying the low-temperature air converted by the evaporator (23) to the first supply line (18); Including,
The above standard dew point is
An air-cooled dehumidifier characterized in that it is set to -50℃ or more and -40℃ or less. According to clause 1,
a first recovery line (45) connected to the drying filter (35) and the evaporator (23), respectively, through which the high-temperature air filtered by the drying filter (35) is supplied to the evaporator (23); and
The second recovery line is connected to the output side of the cooling area 12 and the first recovery line 45, respectively, and supplies low-temperature air discharged from the cooling area 12 to the first recovery line 45. (46); An air-cooled dehumidifier further comprising: According to clause 1,
A temperature sensor (T) provided on the supply side of the hopper 30 to measure the temperature of the air supplied to the hopper 30;
a humidity sensor (H) provided on one side of the temperature sensor (T) to measure the humidity of the air supplied to the hopper (30);
A solenoid is provided on the other side of the first supply line 18 and is formed to change the degree of opening so that the flow rate of air supplied from the non-heated air dryer 16 to the first supply line 18 can be changed. valve (S); and
It further includes a controller 50 that controls the drying heater 25, the non-heated air dryer 16, and the solenoid valve S, respectively, according to the measured values of the temperature sensor T and the humidity sensor H. do,
The controller 50 is
When the temperature of the air measured by the temperature sensor T exceeds the preset reference temperature, the dry heater 25 is controlled to be switched to the off state until the temperature of the air falls to the reference temperature. do,
The controller 50 is
When the temperature of the air measured by the temperature sensor T is below the reference temperature, the heating temperature of the dry heater 25 is adjusted to the preset reference heating temperature until the temperature of the air rises to the reference temperature. Control it to change,
The standard heating temperature is
It is set as a value obtained by adding the initial heating temperature of the dry heater 25 multiplied by the temperature deviation and a preset standard ratio,
The temperature difference is
It is a value obtained by subtracting the air temperature measured by the temperature sensor (T) from the reference temperature,
The above standard ratio is
It is set to be proportional to the outside air temperature and the specific heat of the outside air, respectively, and inversely proportional to the efficiency of the dry heater 25,
The above external air
is the outside air,
The above standard ratio is
An air-cooled dehumidifier characterized in that it is set to 130% or more and 180% or less. According to clause 6,
The controller 50 is
When the humidity of the air measured by the humidity sensor (H) exceeds the preset reference humidity, the reference dew point of the air discharged from the non-heated air dryer 16 until the humidity of the air falls to the reference humidity. Controls the change to the preset setting dew point,
The setting point is
It is set as a value obtained by multiplying the reference dew point by the humidity deviation and a preset reference weight,
The humidity deviation is
It is set to a value obtained by subtracting the air humidity measured by the humidity sensor (H) from the reference humidity,
The standard weight is
It is set to be proportional to the outside air humidity and outside air specific heat, respectively, and inversely proportional to the efficiency of the non-heated air dryer (16),
The standard weight is
is set to 1.2 or more but less than 1.6,
The controller 50 is
When the air humidity measured by the humidity sensor (H) is less than the standard humidity, the opening degree of the solenoid valve (S) is changed to the preset standard opening degree until the air humidity rises to the standard humidity. Control as much as possible,
The standard opening degree is
It is set by adding the initial opening degree of the solenoid valve (S) multiplied by the humidity deviation and a preset setting weight,
The setting weight is
It is set to be proportional to the outside air humidity and outside air specific heat, respectively, and inversely proportional to the square of the inner diameter of the first supply line 18,
The setting weight is
An air-cooled dehumidifier, characterized in that it is set to 1.4 or more and less than 1.8.