KR102422041B1 - Humidity control device and operation method thereof - Google Patents

Abstract

The present invention provides a first air flow path connected to the room at both ends; a second air passage having both ends connected to the outdoors; a dehumidifying rotor including a first area provided on the first air passage, a second area provided on the second air passage, and an adsorbent that alternately passes through the first area and the second area by rotation; a heating unit for heating air flowing from the second air passage toward the second region; a first sensor unit for sensing temperature and humidity of air flowing from the first air passage toward the first region; a hot water supply unit for supplying hot water to the heating unit; and a controller configured to control the hot water supply unit to adjust the temperature of the hot water according to the set relative humidity. It relates to a humidity control device comprising a and an operating method thereof.

Description

Humidity control device and method of operation thereof

The present invention relates to a humidity control device and an operating method thereof, and more particularly, to a humidity control device capable of precisely controlling a target dehumidification amount by controlling the temperature of supplied hot water, and an operating method thereof.

A humidity control device is a device for maintaining an indoor humidity level by sucking moisture in the indoor air, and has been widely used in recent years. Since the conventional humidity control device operates without considering the ambient temperature of the humidity sensor, precise dehumidification may not be achieved.

That is, when the indoor temperature increases, the relative humidity may be relatively low, and when the indoor temperature increases, the relative humidity may increase. If the amount is lowered, there is a problem that the actual indoor space dehumidification operation may not be possible.

An object of the present invention is to provide a humidity control device capable of precisely adjusting the amount of humidity in consideration of room temperature and an operating method thereof.

A humidity control apparatus according to an embodiment of the present invention includes a first air flow path having both ends connected to a room, a second air flow path having both ends connected to an outdoor area, a first area provided on the first air flow path, and the second air flow path A dehumidifying rotor comprising a second region provided on the upper portion, and an adsorbent that alternately passes through the first region and the second region by rotation, heating air flowing from the second air passage toward the second region a heating unit, a first sensor unit for sensing temperature and humidity of air flowing from the first air passage toward the first region, and a hot water supply unit supplying hot water to the heating unit; and a control unit for controlling the hot water supply unit to adjust the temperature of the hot water according to the temperature, humidity, and set relative humidity of the air measured by the first sensor unit.

In addition, the hot water supply unit may change the temperature of the hot water when the set relative humidity is changed.

In addition, the first air flow path and the second air flow path provided at the intersection point of the flow path switching unit to switch the direction of the flow path of the first air flow path and the second air flow path may be further included.

In addition, the controller may calculate a target hot water temperature according to Equation 1 below, and control the hot water supply unit so that the hot water has the target hot water temperature.

[Equation 1]

Qc = Qp + (Pgain * D) (Qc is the target hot water temperature, Qp is the current hot water temperature, D is the first variable, Pgain is the second variable)

Also, the control unit may calculate the first variable and the second variable according to Equations 2 and 3, respectively.

[Equation 2]

D = Vra - Vtarget (Vra is the current water vapor amount, Vtarget is the target water vapor amount)

[Equation 3]

Pgain = D/Dmax (Dmax is a constant)

In addition, the control unit calculates the current amount of water vapor through the temperature and humidity of the air measured by the first sensor unit, and the target through the temperature and the set relative humidity of the air measured by the first sensor unit The amount of water vapor can be calculated.

In addition, when the calculated target hot water temperature is greater than the maximum temperature of the hot water that the hot water supply unit can supply, the controller sets the maximum temperature of the hot water as the target hot water temperature, and the calculated target hot water temperature is the hot water supply When it is smaller than the minimum temperature of the additionally supplyable hot water, the minimum temperature of the hot water may be set as the target hot water temperature.

The method of operating a humidity control apparatus according to an embodiment of the present invention includes measuring the temperature and humidity of indoor air flowing into a first air flow path, calculating the current amount of water vapor by using the detected temperature and humidity of the indoor air, Calculating a target water vapor amount using the sensed indoor air temperature and set relative humidity, calculating a target hot water temperature using the target water vapor amount, and providing hot water having the target hot water temperature in the second air flow path It may include; supplying to the heating unit.

In addition, in the step of calculating the target hot water temperature, the target hot water temperature may be calculated by Equation 1 below.

[Equation 1]

Qc = Qp + (Pgain * D) (Qc is the target hot water temperature, Qp is the current hot water temperature, D is the first variable, Pgain is the second variable)

In addition, in the step of calculating the target hot water temperature, the first variable and the second variable may be calculated according to Equations 2 and 3, respectively.

[Equation 2]

D = Vra - Vtarget (Vra is the current water vapor amount, Vtarget is the target water vapor amount)

[Equation 3]

Pgain = D/Dmax (Dmax is a constant)

According to the present invention as described above, since the temperature of hot water is controlled using the amount of water vapor to be removed according to the room temperature, it is possible to precisely control the amount of humidity in consideration of the room temperature.

1 is a view showing a humidity control device according to an embodiment of the present invention.
2 is a flowchart for explaining a method of operating a humidity control device according to an embodiment of the present invention.

The details of other embodiments are included in the detailed description and drawings.

Advantages and features of the present invention and methods of achieving them will become apparent with reference to the embodiments described below in detail in conjunction with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but may be implemented in a variety of different forms, and in the following description, when a part is connected to another part, this is only the case where it is directly connected. It also includes cases in which other elements are electrically connected in the middle. In addition, in the drawings, parts not related to the present invention are omitted to clarify the description of the present invention, and the same reference numerals are assigned to similar parts throughout the specification.

Hereinafter, a humidity control apparatus and an operating method thereof according to an embodiment of the present invention will be described with reference to the drawings related to the embodiments of the present invention.

1 is a view showing a humidity control device according to an embodiment of the present invention.

Referring to FIG. 1 , the humidity control apparatus according to an embodiment of the present invention includes a first air flow path 110 ( 110a , 110b , 110c ), a first sensor unit 120 , a second sensor unit 130 , and a cooling unit ( 140), a first blower 150, a second air flow path 210; 210a, 210b, 210c), a heating unit 220, a second blower 250, a dehumidifying rotor 300, a flow path switching unit 400, It may include a hot water supply unit 500 and a control unit 600 .

The first air flow path 110 is a flow path in which both ends are connected to the room. For example, the first air flow path 110 includes an inlet part 110a through which indoor air is introduced on one side, an intermediate part 110b passing through the first region 310 of the dehumidification rotor 300 , and the inlet. and an outlet portion 110c for discharging the exhausted indoor air back to the other side of the room.

The first air flow path 110 represents a path through which air flows, and may include not only a pipe through which air flows but also a space through which air flows, which may be equally applied to the second air flow path 210 . .

A first sensor unit 120 , a second sensor unit 130 , a cooling unit 140 , and a first blower 150 may be sequentially provided in the first air flow path 110 .

The first sensor unit 120 is provided in the middle part 110b of the first air flow path 110 , and detects the temperature and humidity of air that is sucked in and directed toward the first area 310 of the dehumidifying rotor 300 . can do.

The second sensor unit 130 is provided in the middle portion 110b of the first air flow path 110 , and passes through the first region 310 of the dehumidifying rotor 300 , and the temperature of the air toward the cooling unit 140 . and humidity.

The first sensor unit 120 and the second sensor unit 130 may transmit measured air temperature and humidity information to the control unit 600 .

The cooling unit 140 may cool the dehumidified air in the first air flow path 110 while passing through the dehumidifying rotor 300 . For example, the cooling unit 140 may be an evaporative cooler that sprays water to the air passing through the cooling unit 140 so that the air is cooled in the process of evaporating the sprayed water, but the cooling method may be variously changed. have. Accordingly, the air passing through the cooling unit 140 may be supplied into the room to cool the room.

The first blower 150 is for sucking indoor air or outdoor air into the first air flow path 110 , and is provided on the outlet part 110c side of the first air flow path 110 .

The second air flow path 210 is a flow path in which both ends are connected to the outdoors. For example, the second air passage 210 includes an inlet 210a through which outdoor air is introduced on one side, an intermediate portion 210b passing through the second region 320 of the dehumidification rotor 300 , and the inlet. It consists of an outlet part 210c for discharging the exhausted outdoor air to the other side of the outdoor again.

A heating unit 220 and a second blower 250 may be sequentially provided in the second air flow path 210 .

The heating unit 220 may heat the air directed to the second region 320 of the dehumidifying rotor 300 by being sucked from the outside. In this case, the heating unit 220 is configured to have hot water flowing therein, and heat exchange is performed between the hot water and the outdoor air to heat the outdoor air. To this end, the heating unit 220 may include a hot water coil through which hot water flows.

In this case, the hot water supply unit 500 may supply hot water of a specific temperature to the heating unit 220 . For example, the hot water supply unit 500 supplies hot water to the heating unit 220 through the hot water supply pipe 510 , and the hot water heat-exchanged in the heating unit 220 is heated through the hot water return pipe 520 after the temperature drops. It can flow back to the hot water supply unit 500 through.

In addition, the hot water supply unit 500 may adjust the temperature of the hot water according to the control of the controller 600 . The hot water supply unit 500 may be implemented with various types of heat sources, for example, a combined heat and power plant, a heat-only boiler, a micro turbine, a small gas engine, a small gas turbine, and the like.

The second blower 250 is for sucking outdoor air or indoor air into the second air flow path 210 , and is provided on the outlet portion 210c side of the second air flow path 210 .

The dehumidifying rotor 300 may be provided with an adsorbent for adsorbing moisture in the air therein. The dehumidifying rotor 300 may be formed to rotate by a driving unit (not shown) about an axis provided in the center. The dehumidification rotor 300 adsorbs moisture from the air passing through the first region 310 during the dehumidification/cooling operation, and when the adsorbent portion on which the moisture is adsorbed is positioned in the second region 320 by rotation, the second region ( 320) is dried by the outdoor air passing through it and regenerated. Since the outdoor air passing through the second region 320 is air heated by the heating unit 220 , moisture adsorbed to the adsorbent may be dried.

In addition, the dehumidification rotor 300 adsorbs moisture in the air passing through the second region 320 during the humidification operation, and when the adsorbent portion to which the moisture is adsorbed is positioned in the first region 310 by rotation, the first region It is dried by air passing through 310 and regenerated. Since the indoor air passing through the first region 310 is dry air, moisture adsorbed to the adsorbent may be dried.

As described above, the dehumidifying rotor 300 may repeat the process of absorbing and regenerating moisture through rotation.

As the adsorbent, a desiccant such as silica gel or zeolite may be used, and may be configured in a predetermined pattern such as a honeycomb pattern. The surface of the adsorbent may be coated with a polymer desiccant. A desiccant polymer is an electrolyte polymer material that becomes ionized when it comes into contact with moisture. When moisture comes into contact with the adsorbent, bacteria are removed from the adsorbent due to the osmotic pressure caused by the difference in ion concentration, thereby generating an antibacterial effect. In addition, ammonia, hydrogen sulfide, etc., which generate odor, adhere to the ionized polymer desiccant with polar molecules, thereby generating a deodorizing effect. As the polymer desiccant to be coated, silica or zeolite may be used.

The controller 600 may adjust the indoor humidity by varying the rotation speed of the dehumidifying rotor 300 according to the indoor humidity. That is, when dehumidifying a room, if the rotation speed of the dehumidification rotor 300 is increased, the amount of dehumidification by the dehumidification rotor 300 increases, and if the rotation speed of the dehumidification rotor 300 is decreased, the amount of dehumidification is decreased. can be adjusted. In addition, when humidifying the room, if the rotation speed of the dehumidification rotor 300 is increased, the amount of humidification by the dehumidification rotor 300 is increased, and if the rotation speed of the dehumidification rotor 300 is decreased, the amount of humidification is decreased. can be adjusted In this case, the control unit 600 may control the indoor humidity by controlling the amount of air blown by the first blower 150 and the second blower 160 together.

The flow path conversion unit 400 includes a first inlet 410 through which indoor air is introduced, a second inlet 420 through which outdoor air is introduced, and a first outlet connected to the first region 310 of the dehumidifying rotor 300 . 430, the second outlet 440 connected to the second region 320 of the dehumidifying rotor 300, and the first inlet 410 are connected to the first outlet 430 or the second outlet 440, The second inlet 420 is formed of a direction change gate 450 in which the connection direction is changed so as to be connected to the first outlet 430 or the second outlet 440 .

The direction change gate 450 is positioned at a central portion where the first inlet 410 , the second inlet 420 , the first outlet 430 , and the second outlet 440 intersect. When the direction change gate 450 is positioned at the first position, the first inlet 410 and the first outlet 430 are connected, and the second inlet 420 and the second outlet 440 are connected. When the direction change gate 450 is rotated 90 degrees by the driving unit (not shown) in the first position to the second position, the first inlet 410 is connected to the second outlet 440, and the second inlet ( 420 is connected to the first outlet 430 .

The controller 600 may control the overall operation of the humidity control device. For example, the control unit 600 may control the rotation speed of the dehumidification rotor 300 or perform a temperature and humidity sensing operation through the first sensor unit 120 and the second sensor unit 130 .

In addition, the controller 600 may control the hot water supply unit 500 to adjust the temperature of the hot water supplied by the hot water supply unit 500 in response to a preset relative humidity.

On the other hand, the humidity control apparatus according to the embodiment of the present invention can adjust the amount of humidity regardless of changes in the indoor temperature through control using the amount of water vapor, and target dehumidification by controlling the temperature of hot water supplied to the heating unit 220 . The amount can be precisely controlled.

To this end, the controller 600 may control the hot water supply unit 500 to change the temperature of the hot water supplied from the hot water supply unit 500 according to the set relative humidity. The hot water supply unit 500 may change the temperature of the hot water according to the control of the controller 600 .

In this case, the controller 600 may calculate the target hot water temperature Qc according to Equation 1 below, and control the hot water supply unit 500 so that the hot water has the target hot water temperature Qc.

[Equation 1]

Qc = Qp + (Pgain * D) (Qc is the target hot water temperature, Qp is the current hot water temperature, D is the first variable, Pgain is the second variable)

Also, the controller 600 may calculate the first variable D and the second variable Pgain according to Equations 2 and 3, respectively.

[Equation 2]

D = Vra - Vtarget (Vra is the current water vapor amount, Vtarget is the target water vapor amount)

[Equation 3]

Pgain = D/Dmax (Dmax is a constant)

In this case, the constant Dmax is a constant for preventing the target hot water temperature Qc from being changed too rapidly, and may be set as the maximum value of the first variable D. As shown in FIG.

The control unit 600 calculates the current water vapor amount Vra through the temperature and humidity of the air measured by the first sensor unit 120 , and the temperature and setting relative of the air measured by the first sensor unit 120 . The target water vapor amount Vtarget may be calculated from the humidity. For example, the controller 600 may calculate the target water vapor amount Vtarget by using information about the measured air temperature and humidity, and the set relative humidity using the pre-stored information on the saturated water vapor amount.

In addition, when the calculated target hot water temperature Qc is greater than the maximum temperature of the hot water that can be supplied from the hot water supply unit 500 , the controller 600 may set the maximum temperature of the hot water as the target hot water temperature Qc. Also, when the calculated target hot water temperature Qc is smaller than the minimum temperature of the hot water that can be supplied from the hot water supply unit 500 , the controller 600 may set the minimum temperature of the hot water as the target hot water temperature Qc.

For example, a method of calculating the target hot water temperature Qc by the control unit 600 will be described. For example, it is assumed that the temperature and the current relative humidity of the indoor air measured by the first sensor unit 120 are 30° C. and 70%, respectively, and the set relative humidity is 30% (here, the set relative humidity is the user's It may be a value set by manipulation). In addition, it is assumed that the constant Dmax has the same value as the current amount of water vapor, and the current hot water temperature Qp is 10°C. And, it is assumed that the maximum temperature of the hot water supply unit 500 is 80 ℃, and the minimum temperature is 10 ℃.

In this case, based on the saturated steam amount table, the controller 600 may calculate the current water vapor amount Vra and the target water vapor amount Vtarget, respectively, as follows.

Current water vapor (Vra): 21.2506 [g/m ³ ]

Target water vapor content (Vtarget): 9.1074 [g/m ³ ]

Accordingly, the target hot water temperature Qc may be calculated according to the following equation.

Qc = 10 + {(12.14 / 21.2506) * 12.14} = 16.94

As a result, the controller 600 may set 16.94° C. as the target hot water temperature Qc, and adjust the temperature of the hot water supplied through the hot water supply unit 500 as the target hot water temperature Qc.

As another example, it is assumed that the temperature and the current relative humidity of the indoor air measured by the first sensor unit 120 are 30° C. and 70%, respectively, and the set relative humidity is 40% (that is, the set relative humidity is It is assumed that it is changed from 30% to 40% by the operation of ). In addition, it is assumed that the constant Dmax has the same value as the current amount of water vapor, and the current hot water temperature Qp is 10°C. And, it is assumed that the maximum temperature of the hot water supply unit 500 is 80 ℃, and the minimum temperature is 10 ℃.

In this case, based on the saturated steam amount table, the controller 600 may calculate the current water vapor amount Vra and the target water vapor amount Vtarget, respectively, as follows.

Current water vapor (Vra): 21.2506 [g/m ³ ]

Target water vapor content (Vtarget): 12.1432 [g/m ³ ]

Accordingly, the target hot water temperature Qc may be calculated according to the following equation.

Qc = 10 + {(9.1074 / 21.2506) * 9.1074} = 13.90

As a result, the controller 600 may set 13.9° C. as the target hot water temperature Qc, and adjust the temperature of the hot water supplied through the hot water supply unit 500 as the target hot water temperature Qc.

In the above examples, when the minimum temperature of the hot water supply unit 500 is 20°C, the controller 600 may set the target hot water temperature Qc to 20°C.

Similarly, when the calculated target hot water temperature Qc is greater than the maximum temperature of the hot water supply unit 500 , the maximum temperature of the hot water supply unit 500 may be set as the target hot water temperature Qc.

2 is a flowchart for explaining a method of operating a humidity control device according to an embodiment of the present invention. Hereinafter, an operating method of the humidity control apparatus according to an embodiment of the present invention will be described with reference to FIGS. 1 and 2 , and descriptions of parts overlapping with the above description will be omitted.

The method of operating the humidity control apparatus according to an embodiment of the present invention includes the steps of measuring the temperature and humidity of indoor air (S10), calculating the current amount of water vapor and the target amount of water vapor (S20), and calculating the target hot water temperature (S30). ), and supplying hot water according to the target hot water temperature (S40).

First, in the step of measuring the temperature and humidity of the indoor air ( S10 ), the temperature and humidity of the indoor air may be measured through the first sensor unit 120 provided in the first air flow path 110 .

In the step (S20) of calculating the current amount of water vapor and the target amount of water vapor, the current amount of water vapor (Vra) is calculated through the temperature and humidity of the indoor air measured in the previous step (S10), and the temperature of the indoor air measured in the previous step (S10) And it is possible to calculate the target water vapor amount (Vtarget) through the set relative humidity.

In the step of calculating the target hot water temperature (S30), the target hot water temperature Qc may be calculated using Equations 1, 2, and 3 described above.

In the step of supplying hot water according to the target hot water temperature ( S40 ), hot water may be supplied to the heating unit 220 provided in the second air flow path in accordance with the target hot water temperature Qc calculated in the previous step ( S30 ).

As described above, the humidity control device according to the present invention increases the temperature of hot water supplied to the humidity control device to increase the dehumidification amount when the target water vapor amount is less than the current water vapor amount, and controls the humidity so that the dehumidification amount decreases when the target water vapor amount is greater than the current water vapor amount. It is possible to reduce the temperature of the hot water supplied to the device. By this operation, the target amount of water vapor in the room may be precisely maintained in real time.

Those of ordinary skill in the art to which the present invention pertains will understand that the present invention may be embodied in other specific forms without changing the technical spirit or essential features thereof. Therefore, it should be understood that the embodiments described above are illustrative in all respects and not restrictive. The scope of the present invention is indicated by the claims to be described later rather than the above detailed description, and all changes or modifications derived from the meaning and scope of the claims and their equivalent concepts are included in the scope of the present invention. should be interpreted

110: first air flow path 120: first sensor unit
130: second sensor unit 140: cooling unit
150: first blower 210: second air flow path
220: heating unit 250: second blower
300: dehumidification rotor 400: flow path conversion unit
500: hot water supply 600: control unit

Claims (10)

a first air passage having both ends connected to the room;
a second air passage having both ends connected to the outdoors;
a dehumidifying rotor including a first area provided on the first air flow path, a second area provided on the second air flow path, and an adsorbent that alternately passes through the first area and the second area by rotation;
a heating unit for heating air flowing from the second air passage toward the second region;
a first sensor unit configured to sense temperature and humidity of air flowing from the first air passage toward the first region;
a hot water supply unit for supplying hot water to the heating unit; and
a control unit for controlling the hot water supply unit to adjust the temperature of the hot water through a target hot water temperature set according to the temperature, humidity and set relative humidity of the air measured by the first sensor unit and the current hot water temperature of the hot water;
Humidity control device comprising a.

According to claim 1,
The hot water supply unit,
Humidity control device, characterized in that for changing the temperature of the hot water when the set relative humidity changes.
According to claim 1,
a flow path switching unit provided at a point where the first air flow path and the second air flow path intersect to change flow directions of the first air flow path and the second air flow path;
Humidity control device further comprising.
According to claim 1,
The control unit is
The humidity control apparatus according to the following Equation 1, calculating the target hot water temperature, and controlling the hot water supply unit so that the hot water has the target hot water temperature.
[Equation 1]
Qc = Qp + (Pgain * D) (Qc is the target hot water temperature, Qp is the current hot water temperature, D is the first variable, Pgain is the second variable)
5. The method of claim 4,
The control unit is
Humidity control device, characterized in that for calculating the first variable and the second variable according to the following Equations 2 and 3, respectively.
[Equation 2]
D = Vra - Vtarget (Vra is current water vapor, Vtarget is target water vapor)
[Equation 3]
Pgain = D/Dmax (Dmax is a constant)
6. The method of claim 5,
The control unit is
calculating the current amount of water vapor through the temperature and humidity of the air measured by the first sensor unit, and calculating the target amount of water vapor through the temperature and the set relative humidity of the air measured by the first sensor unit humidity control device.
5. The method of claim 4,
When the calculated target hot water temperature is greater than the maximum temperature of the hot water that the hot water supply unit can supply, the controller sets the maximum temperature of the hot water as the target hot water temperature, and the calculated target hot water temperature is supplied by the hot water supply unit Humidity control device, characterized in that the minimum temperature of the hot water is set as the target hot water temperature when it is smaller than the minimum temperature of the possible hot water.
measuring the temperature and humidity of indoor air introduced into the first air passage;
calculating a current amount of water vapor by using the detected temperature and humidity of the indoor air, and calculating a target amount of water vapor by using the detected temperature and a set relative humidity of the indoor air;
calculating a target hot water temperature by using the target amount of water vapor; and
supplying hot water having a target hot water temperature to a heating unit provided in a second air flow path; A method of operating a humidity control device comprising a.
9. The method of claim 8,
In the calculating of the target hot water temperature, the operating method of the humidity control device, characterized in that calculating the target hot water temperature according to Equation (1).
[Equation 1]
Qc = Qp + (Pgain * D) (Qc is the target hot water temperature, Qp is the current hot water temperature, D is the first variable, Pgain is the second variable)
10. The method of claim 9,
In the calculating of the target hot water temperature, the first variable and the second variable are calculated according to Equations 2 and 3, respectively.
[Equation 2]
D = Vra - Vtarget (Vra is current water vapor, Vtarget is target water vapor)
[Equation 3]
Pgain = D/Dmax (Dmax is a constant)

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