KR101483628B1 - Absorptive dehumidifier and control method thereof - Google Patents

Abstract

The present invention relates to an absorptive dehumidifier comprising: a dry-type dehumidifying rotor divided into a regeneration zone, a purge zone, and an adsorption zone, and rotating a pre-cooler including a processing fan to pump air containing moisture to the adsorption zone; an after-cooler which cools the air passing through the adsorption zone; a regeneration heater which heats the air passing through the purge zone; a regeneration fan which pumps the heated air to the regeneration zone; a first temperature sensor which measures the temperature of the regeneration heater; and a second sensor which measures the temperature of the regeneration heater. The first and second temperature sensors are capable of preventing the regeneration heater from being over-heated by repeatedly measuring the temperature of the regeneration heater two or more times. Therefore, the present invention has an effect of improving the reliability of the device by reducing the risk of fire due to overheating of the regeneration heater by checking the overheating of the regeneration heater step by step by the first and second temperature sensors.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a desiccant dehumidifier,

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a desiccant type dehumidifier and a control method thereof, and more particularly, to a desiccant type dehumidifier for preventing fire due to overheating of a regenerative heater and a control method thereof.

In general, the adsorption-type dehumidifier is a device for continuously removing moisture contained in the room air by utilizing the moisture absorption and moisture-proof action of the dehumidification rotor.

1 is a schematic view showing a conventional adsorption dehumidifier.

1, the conventional adsorption dehumidifier includes a cabinet 2 having one suction passage 18 and one discharge passage 19 connected to the suction passage 18, A dehumidifying rotor 3 provided on the suction passage 18 in the suction passage 18 and performing a dehumidifying action and a suction passage 18 provided on the suction passage 18 or the discharge passage 19 for sucking indoor air through the suction passage 18, And a rotor drying means for drying the dehumidifying rotor 3 while passing through the dehumidifying rotor 3. The dehumidifying rotor 3 is provided with a processing fan 11 for discharging the dehumidified air through the discharge passage 19,

The rotor drying means includes a circulation flow passage 28 through which the dehumidified rotor 3 is passed and a heat exchanger provided on the circulation flow passage 28 for condensing moisture discharged from the dehumidification rotor 3 A regeneration fan 21 provided on the circulation flow passage 28 for circulating internal air and a regeneration heater 22 provided on the circulation flow passage 28 for heating internal air or the dehumidification rotor, And a water receiving tube (24) provided below the heat exchanger (23) and containing moisture discharged therefrom.

However, the conventional adsorption dehumidifier can cause a fire due to heat accumulated in the regenerative heater 22 and overheating.

Accordingly, there is a demand for development of an improved type adsorption-type dehumidifier and a control method thereof that can prevent a fire caused by overheating of a regenerative heater.

Korean Patent Publication No. 2006-0089075 (Aug. 2006) Korean Patent Publication No. 2011-0096620 (Aug. 31, 2011)

It is an object of the present invention to provide a desiccant-type dehumidifier and a control method thereof, which can prevent a fire due to overheating of a regenerative heater and improve the reliability of the apparatus.

According to an aspect of the present invention, there is provided a desiccant dehumidifier comprising: a dry dehumidification rotor which is divided into a regeneration zone, a purge zone and an adsorption zone and rotates; A precooler including a processing fan for feeding air containing moisture into the adsorption zone; An aftercooler for cooling the air passing through the adsorption zone; A regenerating heater for heating air passing through the purge zone; A regeneration fan for sending the heated air to a regeneration zone; A first temperature sensor for measuring the temperature of the regenerative heater; And a second temperature sensor for measuring the temperature of the regenerative heater, wherein the first and second temperature sensors repeatedly measure the temperature of the regenerative heater more than once to prevent overheating of the regenerative heater.

In addition, it is preferable that an exhaust damper is provided at a discharge side end of the regeneration fan, and an inflow damper is provided in an inflow channel for introducing air into the regenerative heater. When the measured value of the first temperature sensor exceeds a first set value, And the damper is opened.

In addition, when the measured value of the first temperature sensor exceeds the first set value, the regenerative heater is stopped with an alarm.

The bypass passage may further include a solenoid valve and a cooling fan. The bypass passage may include a solenoid valve and a cooling fan. The bypass passage may include a solenoid valve and a cooling fan.

Further, when the measured value of the first temperature sensor exceeds the first set value, the solenoid valve is opened and the cooling fan is driven.

In addition, a receiver tank for supplying a nonflammable gas to the regenerative heater is further provided. When the measured value of the second temperature sensor exceeds a second set value, the exhaust damper is shut off. After the inflow damper is opened, the receiver tank is opened .

An alarm is generated when the measured value of the second temperature sensor exceeds the second set value, and the regenerative fan is driven to remove the residual heat of the regenerative heater.

In addition, if the measured values of the first and second temperature sensors are less than the first and second set values, the inverter may control the rotation speed of the regenerative fan The proportional control is performed.

Further, a controller for controlling the adsorption-type dehumidifier and an emergency power supply for applying power to the adsorption-type dehumidifier are further provided.

In the control method of the adsorption dehumidifier of the present invention,

I) driving the adsorption dehumidifier described above by applying power;

II) measuring the temperature of the regenerative heater

III) determining whether the temperature of the regenerating heater exceeds a first set value; And

IV) determining whether the temperature of the regenerative heater exceeds a second predetermined value.

When the temperature of the regenerative heater exceeds the first set value as a result of the determination in the step (III), the alarm generating and regenerating heater is stopped and the inflow damper is opened.

When the temperature of the regenerative heater exceeds the first set value as a result of the determination in the step (III), the cooling fan is driven after opening the bypass flow path to supply the air cooled by the precooler to the regenerative heater .

If the temperature of the regenerative heater does not exceed the first set value as a result of the determination in the step (III), the operation state is maintained and the temperature of the regenerative heater is measured by returning to the step (II).

If the temperature of the regenerative heater exceeds the second set value as a result of the determination in the step (IV), an alarm is generated, the exhaust damper is shut off, and the receiver tank is opened after opening the inflow damper.

When the temperature of the regenerative heater exceeds the second set value as a result of the determination in the step (IV), the regenerative fan is driven to remove the residual heat of the regenerative heater.

When the temperature of the regenerative heater does not exceed the second set value as a result of the determination in the step (IV), the driving of the adsorption type dehumidifier is terminated.

The steps (III) and (IV) are repeated two or more times.

According to the adsorption-type dehumidifier and the control method thereof, it is possible to check the overheating of the regenerative heater step by step by means of the first temperature sensor and the second temperature sensor, thereby preventing fire due to overheating of the regenerative heater, .

In addition, the number of revolutions of the regenerative heater is controlled by the temperature of the regenerative heater by the regenerative fan to which the inverter is attached, thereby suppressing the overheat of the regenerative heater.

In addition, when the regenerative heater is overheated by the receiver tank, the non-combustible gas is supplied to the regenerative heater to prevent the entire building from being burned due to overheating of the regenerative heater.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a schematic view showing a conventional adsorption dehumidifier. FIG.
FIG. 2 is a schematic view showing the adsorption-type dehumidifier according to the present invention.
3 is a flowchart showing a control method of the adsorption-type dehumidifier according to the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 2 is a view showing a structure of a desiccant type dehumidifier according to the present invention, and FIG. 3 is a flowchart showing a control method of a desiccant type dehumidifier according to the present invention.

2, the adsorption-type dehumidifier A according to the present invention includes a dry dehumidification rotor 100 divided into a regeneration zone 110, a purge zone 120, and an adsorption zone 130, A precooler 200 including a process fan 210 that pressurizes air containing moisture into the adsorption zone 130, an aftercooler 300 that cools the air that has passed through the adsorption zone 130, A regeneration heater 400 for heating the air that has passed through the purge zone 120, a regeneration fan 500 for feeding the heated air to the regeneration zone 110, And a second temperature sensor 600b for measuring the temperatures of the regenerative heater 400 and the first temperature sensor 600a.

First, the dry dehumidification rotor 100 is constituted by continuously arranging an adsorbent layer using an adsorbent such as silica gel, zeolite or activated carbon as a component of a dry dehumidification rotor along the rotating direction of the rotor.

Further, the dry dehumidification rotor 100 is rotated by the rotation driving means 140.

The outer surface of the pre-cooler 200 receives the outside air OA and the ventilation RA according to a method of absorbing moisture of the air, and a processing fan 210 is installed inside.

Here, the processing fan 210 moves the air introduced from the outside air OA (or the outside air OA and the ventilation RA) to the aftercooler 300 via the dry dehumidifying rotor 100 do.

The aftercooler 300 is cooled before supplying the dehydrated air to the object space (a clean room such as an electronic part, a medicine, a film, an LCD or a semiconductor) in which dehumidification is required, Etc.).

According to the adsorption dehumidifier of the present invention, moisture containing moisture supplied from the precooler 100 is adsorbed and removed from the adsorption zone 130 of the dry dehumidification rotor 100, and then supplied to the target space. Some of the air that has passed through is passed through the purge zone 120 to the regeneration heater 400 by the regeneration fan 500 to be heated.

Next, the heated air passes through the regeneration zone 110, and the moisture adsorbed by the heated air is removed from the dry dehumidification rotor 100, and the regeneration fan 500 discharges the regeneration air through the regeneration air discharge passage.

As for the other structures, various configurations of known adsorption dehumidifiers may be employed, so that a detailed description thereof will be omitted.

The temperature of the regenerative heater 400 is repeatedly measured twice or more by the first and second temperature sensors 600a and 600b to prevent a fire due to overheating of the regenerative heater 400, Thereby preventing overheating and fire.

Specifically, an exhaust damper 700a is provided at a discharge side end of the regeneration fan 500, an inflow damper 700b is provided in an inflow channel 700 for introducing air into the regenerative heater 400, When the measured value of the first temperature sensor 600a exceeds the first set value, the inflow damper 700b is opened.

Accordingly, the inflow damper 700b is opened to allow the outside air to flow into the regenerative heater 400, which is overheated.

Here, the first set value is set to a dangerous fire temperature due to overheating of the regenerative heater 400. Outside air flows into the inflow channel 700.

In addition, when the measured value of the first temperature sensor 600a exceeds the first set value, the regenerative heater 400 is stopped with an alarm and the user recognizes the overheat of the regenerative heater 400, (400) is stopped to prevent additional overheating.

The bypass passage 102 connects the cooling passage 101 before the purge zone 120 and the regenerative heater 400. The bypass passage 102 is provided with a solenoid valve 810 And a cooling fan 820 are further provided to supply the regenerated heater 400 with the air cooled by the precooler 200 to prevent the regenerative heater 400 from overheating.

Although the bypass flow path 102 is shown through the dry dehumidification rotor 100 in the drawing, the bypass flow path 102 is configured to bypass the dry dehumidification rotor 100. Thus, the air cooled by the precooler 200 is directly supplied to the regenerative heater 400.

The bypass flow path 102 can cool the regenerative heater 400 even when the bypass flow path 102 is configured to connect the regeneration heater 400 to the supply flow path 103 before being discharged to the target space through the aftercooler 300.

That is, when the measured value of the first temperature sensor 700a exceeds the first set value, the solenoid valve 810 is opened and the cooling fan 820 is driven.

Further, when the measured value of the second temperature sensor 700b exceeds the second set value, the exhaust damper 700a is shut off (disconnected) from the regenerative heater 400, After the inlet damper 700b is opened, the receiver tank 900 is opened to cool the regenerative heater 400 or to extinguish the fire.

Accordingly, when the regenerative heater 400 is overheated by the receiver tank 900, the non-combustible gas is supplied to the regenerative heater 400 to prevent the entire building from being overheated due to the overheat of the regenerative heater 400.

Since the second set value is higher than the first set value and the first set value is set to the fire danger temperature due to overheating of the regenerative heater 400, Is set to a temperature at which it is determined that a fire has occurred. That is, it is set to the fire occurrence temperature.

In addition, the second set value may be set to a fire hazard temperature of a relatively high probability as a temperature higher than the first set value.

As a result, the first and second set values can be set to various values.

In addition, when the measured value of the second temperature sensor 700b exceeds the second set value, an alarm is generated to notify the user of a specific situation, and the regenerative fan 500 is driven to change the residual heat of the regenerative heater 400 .

If the measured values of the first and second temperature sensors 700a and 700b are less than the first and second set values, the inverter 510 may be connected to the first and second temperature sensors 700a and 700b, 2, the rotation speed of the regeneration fan 500 is controlled in proportion to the measured value of the temperature sensors 700a and 700b.

That is, if the measured values of the first and second temperature sensors 700a and 700b are high, the number of revolutions of the regenerative fan 500 is increased, and if the measured value is low, the number of revolutions of the regenerative fan 500 is decreased.

Accordingly, the regeneration fan 500 with the inverter 510 controls the rotational speed of the regenerative heater 400 according to the temperature of the regenerative heater 400, thereby suppressing the overheat of the regenerative heater 400.

Finally, a controller 910 for controlling the above-described configuration and an emergency power supply 920 (UPS) for applying the emergency power to the above-described configuration are further provided.

According to the present invention, the first temperature sensor 700a and the second temperature sensor 700b check the overheat of the regenerative heater 400 step by step, thereby improving the reliability of the apparatus.

A control method of the adsorption type dehumidifier according to the present invention will be described with reference to FIG.

First, the power is applied to drive the adsorption dehumidifier (S110).

That is, the exhaust damper 700a is opened, the inlet damper 700b is shut off (S120), and the dry dehumidification rotor 100, the regeneration fan 500, and the process fan 210 are driven (S130, S140).

Further, the regenerative heater 400 is driven (S150).

Next, the temperature of the regenerative heater 400 is measured by the first temperature sensor 600a (S160).

Then, it is determined whether the temperature of the regenerative heater 400 exceeds the first set value (S170).

If the temperature of the regenerative heater 400 exceeds the first set value in step S170, the alarm generating and regenerating heater 400 is stopped in step S180 and the inflow damper 700b is opened in step S190.

If it is determined in step S170 that the temperature of the regenerative heater 400 exceeds the first set value, the cooling fan 820 is driven after the bypass flow path 102 is opened to cool the air cooled in the precooler 200 And supplied to the regenerative heater 400 to cool the regenerative heater 400 (S200).

If it is determined in step S170 that the temperature of the regenerative heater 400 does not exceed the first set value, the operation state is maintained (S210) and the process returns to step S160.

Next, the temperature of the regenerative heater 400 is measured by the second temperature sensor 600b (S220).

Then, it is determined whether the temperature of the regenerative heater 400 exceeds a second set value (S230).

If the temperature of the regenerative heater 400 exceeds the second set value in step S230, an alarm is generated in step S240, the exhaust damper 700a is shut off, and the inflow damper 700b is opened in step S250. .

After the step S250, the regeneration fan 500 is driven to remove residual heat of the regenerative heater 400 (S260).

After step S260, the receiver tank 900 is opened.

If it is determined in step S230 that the temperature of the regenerative heater 400 does not exceed the second set value, the driving of the adsorption dehumidifier is terminated (S270).

Finally, steps S170 and S230 are repeated one or more times to not only identify the malfunction, but also accurately determine the overheat or fire of the regenerative heater 400.

Although the preferred embodiments of the present invention have been described in detail, the technical scope of the present invention is not limited to the above-described embodiments, but should be construed according to the claims. It will be understood by those skilled in the art that many modifications and variations are possible without departing from the scope of the present invention.

A - Dehumidifier for adsorption 100 - Dry dehumidification rotor
200 - Pre-cooler 210 - Processing fan
300 - Aftercooler 400 - Regenerative heater
500 - regeneration fan 600a - first temperature sensor
600b - second temperature sensor 700 - inflow channel
700a - exhaust damper 700b - inflow damper
810 - Solenoid valve 820 - Cooling fan
900 - Receiver Tank 910 - Controller
920 - Emergency Power Supply

Claims (17)

A dry dehumidifying rotor which is divided and rotated by a regeneration zone, a purge zone, and an adsorption zone;
A precooler including a processing fan for feeding air containing moisture into the adsorption zone;
An aftercooler for cooling the air passing through the adsorption zone;
A regenerating heater for heating air passing through the purge zone;
A regeneration fan for sending the heated air to a regeneration zone;
A first temperature sensor for measuring the temperature of the regenerative heater; And
And a second temperature sensor for measuring the temperature of the regenerative heater,
Wherein the first and second temperature sensors repeatedly measure the temperature of the regenerative heater at least twice to prevent overheating of the regenerative heater.
The method according to claim 1,
An exhaust damper is provided at a discharge side end of the regeneration fan, and an inflow damper is provided in an inflow passage for introducing air into the regeneration heater,
Wherein the inlet damper is opened when the measured value of the first temperature sensor exceeds a first set value.
3. The method of claim 2,
Wherein when the measured value of the first temperature sensor exceeds a first set value, an alarm is generated and the regenerative heater is stopped.
The method of claim 3,
Further comprising a bypass flow path connecting the cooling flow path and the regenerating heater before passing through the purge zone, wherein the bypass flow path further comprises a solenoid valve and a cooling fan.
5. The method of claim 4,
Wherein the solenoid valve is opened and the cooling fan is driven when the measured value of the first temperature sensor exceeds a first set value.
The method of claim 3,
Further comprising a receiver tank for supplying a non-combustible gas to the regenerative heater,
Wherein the exhaust damper is shut off when the measured value of the second temperature sensor exceeds a second set value, and the receiver tank is opened after the inflow damper is opened.
The method according to claim 6,
Wherein an alarm is generated when the measured value of the second temperature sensor exceeds a second set value, and the regenerative fan is driven to remove residual heat of the regenerative heater.
The method according to claim 1,
The regeneration fan further includes an inverter,
Wherein when the measured values of the first and second temperature sensors are less than the first and second set values, the inverter controls the rotational speed of the regenerative fan in proportion to the measured value of the first and second temperature sensors.
The method according to claim 1,
A controller for controlling the adsorption type dehumidifier, and an emergency power supply for applying power to the adsorption type dehumidifier.
I) driving the adsorption dehumidifier of claim 1 by applying power;
II) measuring the temperature of the regenerative heater
III) determining whether the temperature of the regenerating heater exceeds a first set value; And
IV) determining whether the temperature of the regenerating heater exceeds a second predetermined value.
11. The method of claim 10,
Wherein when the temperature of the regenerative heater exceeds the first set value as a result of the determination in the step (III), the alarm generating and regenerating heater is stopped and the inflow damper is opened.
12. The method of claim 11,
Wherein when the temperature of the regenerative heater exceeds the first set value as a result of the determination in the step (III), the cooling fan is driven after opening the bypass flow path to supply the air cooled by the precooler to the regenerative heater / RTI >
11. The method of claim 10,
If the temperature of the regenerative heater does not exceed the first set value as a result of the determination in the step (III), the control unit returns to the step (II) to measure the temperature of the regenerative heater.
11. The method of claim 10,
And when the temperature of the regenerative heater exceeds the second set value as a result of the determination in the step (IV), an alarm is generated, and the exhaust damper is shut off and the receiver tank is opened after opening the inflow damper .
15. The method of claim 14,
Wherein when the temperature of the regenerative heater exceeds the second set value as a result of the determination in the step (IV), the regenerative fan is driven to remove residual heat of the regenerative heater.
11. The method of claim 10,
And if the temperature of the regenerative heater does not exceed the second set value as a result of the determination in the step (IV), the driving of the adsorption type dehumidifier is terminated.
11. The method of claim 10,
Wherein the steps (III) and (IV) are repeated two or more times.

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