KR20240042370A - Air conditioner and the control method thereof - Google Patents

Abstract

The purpose of the present invention is to provide an air conditioner and a control method of the air conditioner that can provide a comfortable indoor environment by maintaining optimal humidity corresponding to the indoor temperature in consideration of the indoor environment and the user's health status. . An air conditioner for implementing this includes a humidity sensor that detects indoor humidity; and a control unit that operates in a humidity control mode so that the indoor humidity falls into the selected humidity section when one of the plurality of humidity sections divided according to the humidity level is selected by the user.

Description

Air conditioner and control method of air conditioner {AIR CONDITIONER AND THE CONTROL METHOD THEREOF}

The present invention relates to an air conditioner and a control method of the air conditioner, and more specifically, to the control of an air conditioner and an air conditioner that are operated to maintain optimal indoor humidity according to the indoor environmental condition and the user's health condition. It's about method.

In general, an air conditioner is a device that maintains a comfortable indoor environment by controlling the indoor temperature and humidity or ventilating the indoor air according to the user's needs.

Recently, technologies have been developed that add various functions such as dehumidification, humidification, cooling, heating, air purification, and ventilation to air conditioners to maintain comfortable indoor air according to seasonal changes according to the user's choice.

Republic of Korea Patent No. 10-1782838 is disclosed as a prior art for the air conditioner.

The air conditioner of the prior art is designed to operate in a dehumidifying mode and a humidifying mode, respectively, so that it is possible to control indoor humidity. However, only the start and end of the dehumidifying mode and the humidifying mode are described, and under what conditions the dehumidifying and humidifying modes can be used. There is no information about whether it is in operation, so it is difficult to create an optimal indoor humidity environment.

Additionally, the optimal indoor humidity range may vary depending on the indoor environment and the user's health condition. For example, if mold is prone to growing indoors, the indoor humidity needs to be maintained at low humidity, and if the user has a cold or the user's skin is dry, the indoor humidity needs to be maintained at a somewhat high humidity.

In this way, the optimal indoor humidity environment varies depending on the indoor environment and the user's health condition, and it is necessary to implement the optimal humidity state by taking these situations into consideration.

The present invention was developed to solve the above-mentioned problems, and is an air conditioner and air conditioner that can provide a comfortable indoor environment by maintaining optimal humidity corresponding to the indoor temperature in consideration of the indoor environment and the user's health status. The purpose is to provide a method of controlling energy.

Another object of the present invention is to provide an air conditioner and a control method for the air conditioner that can improve user convenience by allowing the user to conveniently select the optimal indoor humidity.

Another object of the present invention is to use different optimal control areas for each season. The goal is to provide an air conditioner and a control method for the air conditioner that can create a comfortable indoor environment regardless of the season.

Another object of the present invention is to provide an air conditioner and a control method of the air conditioner that can minimize energy consumption when controlling indoor humidity and minimize the impact of pollutants in indoor air on the human body. there is.

The air conditioner of the present invention for achieving the above object includes a humidity sensor that detects indoor humidity; and a control unit that operates in a humidity control mode so that the indoor humidity falls into the selected humidity section when one of the plurality of humidity sections divided according to the humidity level is selected by the user.

The humidity section is within a humidity area defined by a certain range of temperature and a certain range of humidity, and may be comprised of a plurality of humidity areas so as to correspond to the humidity section.

The plurality of humidity sections may be within an optimal control area defined by a certain range of temperature and a certain range of humidity.

A temperature sensor is provided to detect the indoor temperature; The plurality of humidity sections may be divided by a ratio set by a first optimal humidity section defined as a range between the lowest humidity and the highest humidity within the optimal control area to correspond to the indoor temperature detected by the temperature sensor.

The ratio for dividing the plurality of humidity sections may be stored in advance in the storage unit where the plurality of humidity sections are stored.

The plurality of humidity sections may be divided into the same ratio or may be divided into different ratios.

The optimal control area is set so that the closer the temperature is to the maximum temperature in the certain range, the lower the plurality of humidity sections corresponding to the indoor temperature are, and the closer the temperature is to the minimum temperature in the certain range, the lower the humidity sections corresponding to the indoor temperature are. The plurality of humidity sections may be set to be high.

The optimal control area consists of at least two areas in which at least some areas do not overlap; The control unit can be set to apply the at least two areas to different seasons.

The at least two areas may be set so that some areas overlap.

An input unit is provided so that the user can select one of the plurality of humidity sections, and when the user selects the humidity section through the input unit, the control unit enters a humidity control mode so that the indoor humidity falls within the range of the selected humidity section. It can be operated with

Includes a humidifier for humidifying the indoor air; A second optimal humidity section defined as a range between the lowest humidity and the highest humidity within the selected humidity section is set in the control unit to correspond to the indoor temperature; When the indoor humidity is lower than the second optimal humidity section, the controller may control the humidifier until the humidity is set within the second optimal humidity section.

It includes a dehumidifying unit for dehumidifying the indoor air; A second optimal humidity section defined as a range between the lowest humidity and the highest humidity within the selected humidity section is set in the control unit to correspond to the indoor temperature; When the indoor humidity is higher than the second optimal humidity section, the controller may control the dehumidifier until the humidity reaches a set level within the second optimal humidity section.

The humidity control mode may include a ventilation mode in which indoor air and outdoor air are exchanged.

Information on the level of humidity may be displayed on the input unit to enable the user to identify it, corresponding to the plurality of humidity sections.

The control method of an air conditioner of the present invention includes the steps of: a) receiving information about indoor humidity to a control unit; b) when one humidity section among a plurality of humidity sections divided according to the humidity level is selected by the user, determining by the control unit whether the indoor humidity is outside the selected humidity section; c) When the indoor humidity is outside the selected humidity range, the control unit includes a step of controlling the indoor humidity in a humidity control mode so that the indoor humidity falls within the selected humidity range.

A plurality of humidity areas are provided to correspond to the humidity areas and are defined by a certain range of temperature and a certain range of humidity, and the humidity area may be within the humidity area.

The optimal control area consists of at least two areas in which at least some areas do not overlap; The controller may determine the season and control the at least two areas to be applied to different seasons.

The plurality of humidity sections may be within an optimal control area defined by a certain range of temperature and a certain range of humidity.

The control unit determines a first optimal humidity section defined as a range between the lowest humidity and the highest humidity to correspond to the indoor temperature within the optimal control area, and divides the first optimal humidity section by a set ratio to determine the plurality of humidity levels. Sections can be defined.

The optimal control area is set so that the closer the temperature is to the minimum temperature in the predetermined range, the higher the first optimal humidity section corresponding to the indoor temperature becomes. When operating the humidifying mode, the closer the indoor temperature is to the minimum temperature, the longer the operating time of the humidifying mode can be controlled.

The optimal control area is set so that the closer the temperature is to the maximum temperature in the predetermined range, the lower the first optimal humidity section corresponding to the indoor temperature becomes. When operating the dehumidifying mode, the closer the indoor temperature is to the maximum temperature, the longer the operation time of the dehumidifying mode can be controlled.

The control unit determines a second optimal humidity section, which is defined as a range between the lowest humidity and the highest humidity corresponding to the indoor temperature within the selected humidity section, and when the indoor humidity is lower than the second optimal humidity section, the second optimal humidity section is determined. It can be controlled to operate in humidifying mode until the humidity is set within the optimal humidity range.

The control unit determines a second optimal humidity section, which is defined as a range between the lowest humidity and the highest humidity corresponding to the indoor temperature within the selected humidity section, and when the indoor humidity is higher than the second optimal humidity section, the second optimal humidity section It can be controlled to operate in dehumidifying mode until the humidity is set within the optimal humidity range.

Selection of one of the plurality of humidity sections may be made by a selection signal input from an input unit.

The humidity control mode may include a ventilation mode in which indoor air and outdoor air are exchanged.

If the control unit determines that the indoor humidity can enter the selected humidity range by operating the ventilation mode, it may operate in the ventilation mode.

The control unit may determine the degree to which the indoor humidity deviates from the selected humidity range, and if the degree of deviation is within a set range, determines that the indoor humidity can enter the selected humidity range by operating the ventilation mode.

According to the present invention, in the humidity control mode, the optimal humidity corresponding to the indoor temperature is maintained in consideration of the indoor environment and the user's health status, thereby providing a comfortable indoor environment.

Additionally, user convenience can be improved as users can conveniently select the optimal indoor humidity.

In addition, by using different optimal control areas for each season, You can create a comfortable indoor environment regardless of the season.

In addition, by controlling humidity using ventilation mode, indoor air quality can be efficiently improved, energy consumption can be minimized, and the concentration of CO2 and VOC contained in indoor air can be maintained at a low level, thereby improving indoor air quality. The impact of pollutants on the human body can be minimized.

1 is a diagram showing the control configuration of the air conditioner of the present invention.
Figure 2 is a diagram showing the state in which dehumidification and humidification are performed in the optimal control area for each temperature of the present invention.
Figure 3 is a diagram showing a state in which the optimal control area for each temperature of the present invention is set differently for each season.
Figure 4 is a diagram showing the state in which seasonal dehumidification and humidification are performed in the optimal control area for each temperature of the present invention.
Figure 5 is a diagram showing a control method in humidity control mode according to the first embodiment of the present invention.
Figure 6 is a diagram showing a control method in humidity control mode according to the second embodiment of the present invention.
Figure 7 is a diagram showing a control method in humidity control mode according to the third embodiment of the present invention.

Hereinafter, the present invention will be described in detail with reference to the attached drawings.

The air conditioner (1) of the present invention includes a humidity sensor (52) that detects indoor humidity, and when one humidity section is selected among a plurality of humidity sections divided according to the level of humidity, the indoor humidity is set to the selected humidity section. It includes a control unit 10 that operates in humidity control mode to enter.

The air conditioner (1) further includes a first blower (21) that operates under the control of the control unit (10). The first blower 21 is for sucking in indoor air or outdoor air and discharging it indoors. In addition, it may further include a second blower 22 that operates under the control of the control unit 10. The second blower 22 is for sucking in indoor air or outdoor air and discharging it outdoors.

The humidity control mode consists of a dehumidifying mode for dehumidifying indoor air and a humidifying mode for humidifying indoor air. For this purpose, the air conditioner 1 includes a dehumidifying unit 23 and a humidifying unit 24.

The dehumidifying unit 23 is used to cool the air discharged into the room by the first blower 21 in the dehumidifying mode, and may be configured as an evaporator of a heat pump, for example. In addition, the dehumidifying unit 23 includes a dehumidifying rotor that absorbs moisture contained in indoor air and releases it to outdoor air, a driving unit that rotates the dehumidifying rotor, and a heating unit that heats outdoor air flowing to the dehumidifying rotor to regenerate the dehumidifying rotor. It may consist of a heating unit that provides heat.

The humidifier 24 is used to heat the air discharged into the room by the first blower 21 in the humidifying mode, and may be configured as a condenser of a heat pump, for example.

The humidity control mode may further include a ventilation mode in which indoor air and outdoor air are exchanged in addition to the dehumidifying mode and humidifying mode. In other words, when there is a difference in humidity between indoor air and outdoor air, when operating in ventilation mode, the indoor air can be humidified or dehumidified using the humidity contained in the outdoor air.

The humidity section consists of a plurality of sections to implement the user's desired humidity condition according to the user's health condition or indoor environment condition.

In this case, the air conditioner 1 may further include a temperature sensor 51 that detects the indoor temperature. Humidity conditions that a user feels comfortable with may vary depending on the indoor temperature, and may also vary depending on the user's health condition or the condition of the indoor environment. Therefore, the control unit 10 can be configured to find the optimal humidity section in which the user can feel comfortable in response to the current indoor temperature detected by the temperature sensor 51.

In addition, the air conditioner 1 may further include a storage unit 60 in which the plurality of humidity sections are set and stored. An optimal control area defined by a certain range of temperature and a certain range of humidity can be set and stored in the storage unit 60.

The air conditioner 1 may be provided with an input unit 31 so that a user can select one of the plurality of humidity sections. That is, the user can select high or low indoor humidity through the input unit 31. If the user has a cold or has dry skin, they may want a high humidity section, and if mold is prone to growing indoors, they may want a low humidity section.

For such user selection, the input unit 31 may include an input button. For example, the input button may display text such as “cold mode,” “dry skin mode,” and “mold removal mode” to convey information to the user about humidity control that takes into account health status and indoor environmental conditions. . Additionally, the input button may display characters such as “high humidity mode,” “medium humidity mode,” and “low humidity mode” to convey information about high and low humidity.

Using this input unit 31, the user selects the desired humidity range, and when the indoor humidity is outside the humidity range selected by the user, the control unit 10 switches to the humidity control mode so that the indoor humidity falls within the selected humidity range. It goes into operation.

The air conditioner 1 may further include at least one filter (not shown) for filtering air discharged into the room.

The factors that determine the quality of indoor air include CO2, VOC, fine dust, temperature, and humidity, and among these, the concentration of pollutants such as dust, CO2, and VOC can be used as a standard for determining the degree of pollution of indoor air. .

The efficiency of air conditioning may vary depending on which of the plurality of operation modes is operated. In other words, the degree to which the concentration of CO2, VOC, and fine dust is lowered may vary, and the degree to which the temperature/humidity of indoor air may vary.

Since the CO2 is not filtered by the filter, the concentration of CO2 contained in indoor air can be most efficiently reduced by operating in ventilation mode.

The VOC has some effect even when operated in air purifying mode, but operating in ventilation mode can reduce the VOC concentration in indoor air more effectively than in air purifying mode.

Some of the dust can be removed by operating in ventilation mode and discharging outdoors, but the concentration can be most effectively reduced by operating in air purification mode and filtering through a filter.

In the case of the above humidity, the indoor humidity can be most effectively brought to a comfortable state by operating the dehumidifying mode. Of course, instead of operating in dehumidifying mode, it can be configured to operate in ventilation mode to control indoor humidity within a limited range using outdoor air.

Ultimately, the most effective driving mode for changing the factors that determine indoor air quality may vary depending on each factor. In this case, for elements that are not filtered by the filter, such as CO2 and VOC, it is most effective to operate in ventilation mode, and for elements that are filtered by the filter, such as dust, it is effective to operate in air purification mode. In this case, CO2 and VOC have a significant impact on the human body, so they become very important criteria in determining the comfort of the indoor environment.

Referring to FIG. 2, a plurality of humidity areas, humidity sections, optimal humidity sections, and optimal control areas will be described.

In Figure 2, a graph in which the horizontal axis is the indoor temperature (T) and the vertical axis is the indoor humidity (RH; relative humidity) shows a plurality of humidity areas (H1, H2, H3) whose humidity sections vary depending on the indoor temperature.

In this case, the entire area where the plurality of humidity areas (H1, H2, H3) are combined can be defined as the optimal control area.

In addition, within the plurality of humidity areas (H1, H2, H3), which are the optimal control areas, an optimal humidity section (first optimal humidity section), which is the range of optimal humidity corresponding to the current indoor temperature, can be defined. For example, in FIG. 2, when the current indoor temperature is T1, the first optimal humidity section corresponding to the current indoor temperature ranges from RH3, the lowest humidity, to RH9, the highest humidity.

In addition, a plurality of humidity sections corresponding to the optimal humidity areas (H1, H2, H3) can be defined. For example, in FIG. 2, the plurality of humidity sections may be comprised of a first humidity section (RH3 - RH5), a second humidity section (RH5 - RH7), and a third humidity section (RH7 - RH9).

In this case, the humidity section selected by the user among the first to third humidity sections can be defined as the second optimal humidity section. For example, if the user selects the second humidity section, the second optimal humidity section is between RH5, the lowest humidity, and RH7, the highest humidity.

The optimal control area defines a humidity area in which the user can feel comfortable depending on the indoor temperature, and can be stored in the storage unit 60 as a table value to obtain the optimal indoor humidity for the current indoor temperature. In this case, the plurality of humidity sections can be configured to be within the range of the optimal control area.

Meanwhile, the humidity section most suitable for the user may vary depending on the indoor environmental condition and the user's health condition. For example, if the indoor environment is prone to mold, it is necessary to keep the room dry, and if the user has a cold or has dry skin, the room needs to be kept somewhat humid. In addition, for various reasons, there is a need to maintain indoor humidity lower or higher than the median value of the optimal humidity range.

Since the optimal control area is set considering the average situation of the general public without considering the indoor environmental condition and the user's health condition, the first optimal humidity section set by the optimal control area has a wide humidity range.

Therefore, if the first optimal humidity section is divided into a plurality of humidity sections and the user is able to select the second optimal humidity section among the plurality of humidity sections, the user can select the most suitable humidity section for the user in consideration of the indoor environmental condition and the user's health condition. Appropriate humidity can be maintained.

In the above, only the case where the optimal control area is stored in the storage unit 60 has been described. However, if the optimal control area is not stored in the storage unit 60, the plurality of humidity sections are arbitrary humidity levels at which the user can feel comfortable. It can also be composed of sections. In other words, when the optimal control area is not set, the humidity section does not vary depending on temperature, and multiple constant humidity sections can be set.

The plurality of humidity areas (H1, H2, H3) represent the optimal indoor humidity areas for the current indoor temperature, and the optimal indoor humidity for each indoor temperature is stored as a table value for humidity in a certain range ( 60).

The plurality of humidity areas (H1, H2, H3) include a low humidity area (H1) indicating a low humidity area, a high humidity area (H3) indicating a high humidity area, and a space between the low humidity area (H1) and the high humidity area (H3). It may be composed of an intermediate region (H2) representing the intermediate humidity region of.

Figure 2 illustrates an embodiment in which three regions appear, but it may consist of only two regions, a low humidity region (H1) and a high humidity region (H3), or may be further subdivided into three or more regions.

In addition, in Figure 2, the boundaries of the low humidity area (H1), the high humidity area (H3), and the middle area (H2) are connected to form a plurality of neighboring humidity sections. However, at least two of the three areas are It may be configured so that adjacent humidity sections are spaced apart in the vertical direction and are spaced apart rather than continuous with each other.

When the indoor temperature detected by the temperature sensor 51 is T1 and the indoor humidity sensed by the humidity sensor 52 is RH1, the current indoor environmental condition in the graph of FIG. 2 is the location of P1.

In this case, the first optimal humidity section (RH3 - RH9) is an optimal humidity section corresponding to the current indoor temperature to create a comfortable indoor environment, and consists of a relatively wide range of humidity sections. Therefore, in a general environment, the humidity control mode can be operated so that the indoor humidity falls within the first optimal humidity range (RH3 - RH9).

However, since a humidity section more suitable for the user's health condition or indoor environment is needed, it is necessary to control the indoor humidity so that it can be maintained in a humidity section smaller than the first optimal humidity section (RH3 - RH9).

In this way, in order for the user to select the humidity section most suitable for the user, there are three humidity sections corresponding to the optimal humidity areas (H1, H2, H3), and the first humidity section (RH3 - RH5) is the first humidity section (RH3 - RH5). It is located at the bottom within the first optimal humidity section (RH3 - RH9) and corresponds to the low humidity area (H1), and the third humidity section (RH7 - RH9) is located at the top within the first optimal humidity section (RH3 - RH9). is located in the high humidity area (H3), and the second humidity section (RH5 - RH7) is located in the middle within the first optimal humidity section (RH3 - RH9) and corresponds to the middle area (H2). .

The first humidity section (RH3 - RH5) is a low humidity section within the first optimal humidity section (RH3 - RH9) and can be set as a humidity section corresponding to the low humidity mode of the input button. If the indoor environment is prone to mold growth, it is desirable to maintain it in the first humidity range (RH3 - RH5).

The third humidity section (RH7 - RH9) is a high humidity section within the first optimal humidity section (RH3 - RH9) and can be set as a humidity section corresponding to the high humidity mode of the input button. If the user has a cold or has dry skin, it is desirable to maintain the humidity in the third humidity range (RH7 - RH9).

The second humidity section (RH5 - RH7) is a humidity section located in the middle of the first optimal humidity section (RH3 - RH9) and can be set as a humidity section corresponding to the middle mode of the input button. If the user wants average humidity conditions, it can be configured to maintain the second humidity range (RH5 - RH7).

In this case, when the first humidity section (RH3 - RH5) is selected, the second optimal humidity section is defined as between the lowest humidity (RH3) and the highest humidity (RH5). Similarly, when the second humidity section (RH5 - RH7) or the third humidity section (RH7 - RH9) is selected, the second optimal humidity section is between the lowest humidity (RH5) and the highest humidity (RH7) or the lowest humidity (RH7). It is defined as between and maximum humidity (RH9). When information about the indoor temperature is received from the temperature sensor 51 to the control unit 10 and a selection signal for a humidity section is received from the user to the control unit 10, the second optimal humidity section is set to the control unit 10. It is set.

The first to third humidity sections may be formed by dividing the first optimal humidity section (RH3 - RH9) at a certain ratio. For example, the ratio of the first to third humidity sections is stored in the storage unit 60 as 1:1:1, and the first optimal humidity section (RH3 - RH9) corresponding to the current indoor temperature is stored in the storage unit 60. The first to third humidity sections are obtained by dividing into three equal proportions. In this state, when the user selects a desired humidity section among the first to third humidity sections, the humidity control mode is operated to maintain the selected humidity section. The ratio for dividing the first to third humidity sections may be divided into the same ratio or may be divided into different ratios for each section.

As such, the most appropriate humidity section may vary within the first optimal humidity section (RH3 - RH9) depending on the user's health condition or indoor environment, so the first optimal humidity section (RH3 - RH9) is divided according to the level of humidity. It is divided into a plurality of humidity sections, and the control unit 10 is configured to operate in a humidity control mode so that the current indoor humidity falls into the humidity section selected by the user, thereby forming optimal humidity conditions considering the indoor environment and various situations of the user. there is.

When the user selects one of the low humidity mode, medium mode, and high humidity mode at the input unit 31, one of the first to third humidity sections is selected as the optimal humidity section for the current indoor temperature (T1). In this case, when the current indoor environmental condition is at the position of P1, the current indoor humidity is lower than the humidity range selected by the user and humidification is required, so the control unit 10 operates the humidifier 24 to change the indoor humidity to the humidity selected by the user. It operates in humidifying mode to enter the section.

In the above, it was explained that the indoor humidity is maintained within each humidity range desired by the user. As an example of this control method, the control unit 10 operates the humidifier 24 to adjust the indoor humidity to the highest humidity of each humidity section (RH5 for the first humidity section, RH7 for the second humidity section, and RH7 for the third humidity section). In the case of the humidity section, it can be operated in humidifying mode until it reaches RH9), and the lowest humidity of each humidity section (RH3 for the first humidity section, RH5 for the second humidity section, and RH7 for the third humidity section) It can also be configured to operate until the set humidity is between and maximum humidity (RH5, RH7, RH59).

Meanwhile, when the indoor temperature is T2 and the indoor humidity is RH10, the current indoor environmental condition is the location of P2 in the graph of FIG. 2.

In this case, the optimal humidity section (first optimal humidity section), which is the range of optimal humidity corresponding to the current indoor temperature (T2) within the plurality of humidity areas (H1, H2, H3), ranges from RH2, the lowest humidity, to RH8, the highest humidity. It becomes a range between.

In this case, for the user's selection of the optimal humidity section, the three humidity sections corresponding to the optimal humidity areas (H1, H2, H3) are located at the bottom within the first optimal humidity section (RH2 - RH8). A first humidity section (RH2 - RH4) located at the top and corresponding to the low humidity area (H1), and a third humidity section ( RH6 - RH8), and a second humidity section (RH4 - RH6) located in the middle within the first optimal humidity section (RH2 - RH8) and corresponding to the middle area (H2).

If the user selects any one of the first to third humidity sections and the current indoor humidity is RH10, dehumidification is necessary because it is higher than the maximum humidity of the humidity section selected by the user among the first to third humidity sections.

The control unit 10 may operate the dehumidifying unit 23 in a dehumidifying mode so that the indoor humidity is maintained within the humidity range selected by the user. In this case, it can also be operated in dehumidifying mode until the lowest humidity of the humidity section selected by the user is reached, or it may not be operated until the lowest humidity of each humidity section is reached and the lowest humidity of each humidity section (RH2, RH4, RH6) can be set. It can also be configured to operate until the set humidity is between the highest humidity (RH4, RH6, and RH8).

The optimal control area will be described with reference to FIG. 3.

The optimal control area (A, B) can be expressed as a certain area defined by a certain range of temperature and a certain range of humidity.

The optimal control area (A, B) may be composed of at least two areas (A, B) in which at least some areas do not overlap.

In this case, the at least two areas (A, B) can be configured to apply different areas depending on the season. In Figure 3, the optimal control area (A), which is an area with a low temperature, can be applied in the winter, and the optimal control area (B), which is an area with a high temperature, can be applied in the summer. Additionally, it can be configured to apply area C, which overlaps area A and area B, in between seasons. The C area may be set as a separate area distinct from areas A and B, or the optimal control area may be composed of two areas, A area including C area and B area including C area.

Referring to FIG. 4, a case in which the seasonal optimal control area is applied will be described.

When the optimal control area is set to area A, when the current indoor environmental condition is at the location of P3, the first optimal humidity section is between the lowest humidity (a1) and the highest humidity (a2). Additionally, if the user selects the third humidity section, which is the high humidity mode, within the first optimal humidity section, a second optimal humidity section is defined between the lowest humidity (a4) and the highest humidity (a2). In this way, the first optimal humidity section and the second optimal humidity section have a small range and become high humidity sections.

This situation can occur in dry indoor situations, such as during the winter. In this case, it is operated in humidifying mode, and in P3, the operation time of humidifying mode is controlled to be long in order to ensure that the indoor humidity falls into the second optimal humidity range (a4 - a2) selected by the user.

In this case, the humidification mode operation can be configured to end when the indoor humidity reaches a set humidity between the lowest humidity (a4) and the highest humidity (a2). However, if the humidification ends when the indoor humidity is lower than the highest humidity (a2), As the indoor humidity quickly deviates from the second optimal humidity zone, frequent start and stop of the humidification mode may be repeated. Therefore, it is desirable to operate the humidifying mode until the indoor humidity reaches the highest humidity (a2).

Additionally, when the optimal control area is set to area B, when the current indoor environmental condition is at the position of P4, the first optimal humidity section is between the lowest humidity (b1) and the highest humidity (b2). Additionally, within the first optimal humidity section, when the user selects the first humidity section in the low humidity mode, a second optimal humidity section is defined between the lowest humidity (b1) and the highest humidity (b3). In this way, the first optimal humidity section and the second optimal humidity section have a small range and become low humidity sections.

This situation can occur in humid indoor situations, such as during the rainy season. In this case, the dehumidifying mode is operated, and the operation time of the dehumidifying mode is controlled to be long in order for the indoor humidity to reach the lowest humidity (b1) of the second optimal humidity section at P4.

In this case, the dehumidification mode operation can be configured to end when the indoor humidity reaches a set humidity between the lowest humidity (b1) and the highest humidity (b3). However, if the indoor humidity is higher than the lowest humidity (b1), dehumidification ends. When humidity is high, such as during the rainy season, the indoor humidity quickly leaves the second optimal humidity zone, and the dehumidification mode may be started and stopped frequently. Therefore, it is desirable to operate the dehumidification mode until the indoor humidity reaches the minimum humidity (b1).

In addition, when the optimal control area is set to area A or B, when the current indoor environmental condition is at the location of P5, the first optimal humidity section is within area C and is between the lowest humidity (c1) and the highest humidity (c2). Additionally, if the user selects the second humidity section, which is an intermediate mode, within the first optimal humidity section, the second optimal humidity section is defined between the lowest humidity (c3) and the highest humidity (c4). In this way, the range of the first optimal humidity section and the second optimal humidity section is larger compared to the case where the current indoor environmental condition is P3 or P4.

In this case, the operation of the humidifying mode can be configured to operate until the highest humidity (c4) is reached, but it can also be configured to humidify until the set humidity between the lowest humidity (c3) and the highest humidity (c4) is reached. It may be possible. In this way, even if the end point of the humidification mode is between the lowest humidity (c3) and the highest humidity (c4), the range of the second optimal humidity section is large, and the change in indoor humidity is not large between seasons, so the humidity is maintained until it exceeds the second optimal humidity section. This can prevent frequent starting and stopping of the humidifying mode, which takes a long time. Meanwhile, when the indoor environmental condition is at the location of P6, it has the same effect as when it is at P5, except that it is operated in dehumidifying mode.

From this point, the closer it is to the highest temperature (TH1 or TH2), the smaller the range of the optimal humidity section corresponding to the indoor temperature is, and the lower the humidity is set, and the closer it is to the lowest temperature (TL1 or TL2), the optimal humidity section corresponding to the indoor temperature is set. The range can be set to be small and the humidity high, and the range of the optimal humidity section can be set large in the middle between the highest temperature (TH1 or TH2) and the lowest temperature (TL1 or TL2). Therefore, the first optimal humidity section and the second optimal humidity section can be configured to have different ranges depending on temperature.

Referring to FIG. 5, a control method in the humidity control mode according to the first embodiment of the present invention will be described.

In step S101, one of a plurality of humidity modes is selected. When the user selects one of the high humidity mode, medium mode, and low humidity mode through the input unit 31, the selection signal is received by the control unit 10. The control unit 10 selects a humidity area corresponding to the selection signal among a plurality of humidity areas H1, H2, and H3.

In step S102, the indoor temperature information detected by the temperature sensor 51 and the indoor humidity information sensed by the humidity sensor 52 are received by the control unit 10.

In step S103, the control unit 10 calculates the second optimal humidity section. The second optimal humidity section consists of a range between the lowest humidity and the highest humidity corresponding to the indoor temperature detected by the temperature sensor 51 in the selected humidity area.

In step S104, the control unit 10 determines whether the received indoor humidity is within the second optimal humidity range. As a result of the judgment, if it is within the second optimal humidity zone, the current state is maintained, otherwise, the process proceeds to step S105.

In step S105, the control unit 10 operates in the humidity control mode to ensure that the indoor humidity is within the second optimal humidity range.

In step S106, the control unit 10 determines whether the conditions for ending the humidity control mode are met. In this case, the condition for ending the humidity control mode can be set to the indoor humidity reaching the highest humidity of the second optimal humidity section, or it can be set to reaching the humidity set between the lowest humidity and the highest humidity of the second optimal humidity section. As a result of the judgment, if the humidity control mode termination conditions are met, the operation of the humidity control mode is terminated. Otherwise, the operation of the humidity control mode is maintained.

Referring to FIG. 6, a control method in the humidity control mode according to the second embodiment of the present invention will be described. The second embodiment is for a case where the order of steps S103 and S104 is reversed in the first embodiment.

Steps S201 and S202 are the same as steps S101 and S102 described in FIG. 5.

In step S203, the control unit 10 determines whether the current indoor environmental condition is within the selected humidity area. As a result of the determination, if the current indoor environmental condition is within the selected humidity area, the current state is maintained. Otherwise, the process proceeds to step S204.

In step S204, the control unit 10 calculates the second optimal humidity section, and operates in humidity control mode in step S205 to ensure that the indoor humidity is within the second optimal humidity section.

In step S206, the control unit 10 determines whether the conditions for ending the humidity control mode are met. As a result of the judgment, if the humidity control mode termination conditions are met, the operation of the humidity control mode is terminated. Otherwise, the operation of the humidity control mode is maintained.

Referring to FIG. 7, a control method in the humidity control mode according to the third embodiment of the present invention will be described.

Step S301 is the same as step S101 described in FIG. 5.

In step S302, the control unit 10 selects which of the plurality of optimal control areas (A and B) stored in the storage unit 60 to apply. In this case, the season can be determined and the optimal control area corresponding to the season can be selected.

In step S303, the indoor temperature information detected by the temperature sensor 51 and the indoor humidity information sensed by the humidity sensor 52 are received by the control unit 10.

In step S304, the control unit 10 calculates a first optimal humidity section from the received indoor temperature information and the selected optimal control area.

In step S305, the control unit 10 calculates the second optimal humidity section, which is the humidity section selected by the user. The first optimal humidity section is divided into a number of humidity sections corresponding to a plurality of modes provided in the input unit 31, and each humidity section can be divided at a preset constant ratio. Among the plurality of humidity sections divided in this way, the humidity section selected by the user becomes the second optimal humidity section.

In step S306, the control unit 10 determines whether the received indoor humidity is within the second optimal humidity range. As a result of the judgment, if it is within the second optimal humidity zone, the current state is maintained. Otherwise, the process proceeds to step S307.

In step S307, the control unit 10 operates in the humidity control mode to ensure that the indoor humidity is within the second optimal humidity range.

In step S308, the control unit 10 determines whether the conditions for ending the humidity control mode are met. As a result of the judgment, if the humidity control mode termination conditions are met, the operation of the humidity control mode is terminated. Otherwise, the operation of the humidity control mode is maintained.

In the above-described embodiment, it is exemplified that temperature and humidity information is received in steps S102, S202, and S303, but the indoor temperature and indoor humidity are detected by the temperature sensor 51 and the humidity sensor 52 through the air conditioner (1). Since this is continuously performed when the power is turned on, it may be configured to be performed before steps S102, S202, and S303.

Meanwhile, the case where the user selects one of a plurality of humidity sections has been described above, but if the user does not select a humidity section, it is also possible to control in humidity control mode to maintain the humidity within the optimal control area. do.

In addition, even when the indoor humidity exceeds the humidity area selected by the user and satisfies the humidifying mode or dehumidifying mode operation conditions, it can be configured to control the ventilation mode instead of the humidifying mode or dehumidifying mode. In other words, if the humidity of the outdoor air is higher than the humidity of the indoor air, the indoor air can be humidified using the outdoor air, and if the humidity of the outdoor air is lower than the humidity of the indoor air, the indoor air can be dehumidified using the outdoor air. can do.

For example, in FIG. 2, when the current indoor environmental condition is at the location P1, when operating in ventilation mode, outdoor air can be introduced indoors to humidify the indoor air. In this case, when the humidity of the indoor air falls within the range of the second optimal humidity section, the operation of the ventilation mode can be stopped. In addition, since it may be difficult to humidify to the desired level using ventilation mode alone, the system is configured to operate in ventilation mode until the humidity of the indoor air reaches the lowest humidity, which is the bottom of the second optimal humidity range, and to operate in humidification mode from the lowest humidity to the highest humidity. You may.

In addition, even when the indoor environmental conditions are at the location of P2, it can be configured to dehumidify only in the ventilation mode in the same way.

In addition, the degree to which the location of P1 or P2, which is the current indoor environmental condition, deviates from the second optimal humidity zone is determined, and if the degree of deviation is within the setting range, the device is not operated in the humidifying mode or dehumidifying mode first, but is operated in the ventilation mode first. You can.

In this case, it is possible to determine in advance whether the target humidity control is possible when operating in ventilation mode based on information about indoor humidity and outdoor humidity, and then decide whether to operate in ventilation mode. Whether or not the target humidity control is possible can be determined from the indoor humidity that changes by operating the ventilation mode for a certain period of time.

In this way, if the ventilation mode is given priority instead of operating in the humidifying or dehumidifying mode first, the concentration of CO2/VOC in the indoor air is reduced and there is no need to operate the dehumidifying unit 23 and the humidifying unit 24, thereby saving energy. Consumption can be reduced.

As described above, the present invention has been described in detail with preferred embodiments, but the present invention is not limited to the above-described embodiments, and may be modified in various ways within the scope of the claims, the detailed description of the invention, and the accompanying drawings. It is possible to implement this, and this also belongs to the present invention.

1: air conditioner 10: control unit
21: first blower 22: second blower
23: dehumidification unit 24: humidification unit
31: Timer 51: Temperature sensor
52: humidity sensor 60: storage unit

Claims (21)

Humidity sensor that detects indoor humidity;
When one humidity section among a plurality of humidity sections divided according to the humidity level is selected by the user, a control unit that operates in a humidity control mode so that the indoor humidity falls into the selected humidity section;
Including,
The humidity section is within a humidity area defined by a certain range of temperature and a certain range of humidity, and is comprised of a plurality of humidity areas so as to correspond to the humidity section,
Divided into the plurality of humidity sections based on the current indoor temperature,
An input unit is provided so that the user can select one of the plurality of divided humidity sections, and when the user selects the humidity section through the input unit, the control unit controls the indoor humidity to fall within the range of the selected humidity section. Operate in control mode,
An optimal control area consisting of the entire area of the plurality of humidity areas is set in the control unit;
the plurality of humidity sections are within the range of the optimal control area;
The optimal control area consists of at least two areas in which at least some areas do not overlap;
An air conditioner in which the control unit is set to apply the at least two areas to different seasons. According to paragraph 1,
A temperature sensor is provided to detect the indoor temperature;
The plurality of humidity sections are characterized in that a first optimal humidity section defined as a range between the lowest humidity and the highest humidity within the optimal control area is divided at a set ratio to correspond to the indoor temperature detected by the temperature sensor. air conditioner. According to paragraph 2,
An air conditioner, characterized in that the ratio for dividing the plurality of humidity sections is previously stored in the storage unit where the plurality of humidity sections are stored. According to paragraph 2,
An air conditioner, characterized in that the plurality of humidity sections are divided into the same ratio or divided into different ratios. According to paragraph 1,
The optimal control area is set so that the closer the temperature is to the maximum temperature in the certain range, the lower the plurality of humidity sections corresponding to the indoor temperature are, and the closer the temperature is to the minimum temperature in the certain range, the lower the humidity sections corresponding to the indoor temperature are. An air conditioner, characterized in that the plurality of humidity sections are set to be high. According to paragraph 1,
An air conditioner, characterized in that the at least two areas are set so that some areas overlap. According to paragraph 1,
It includes a humidifying unit for humidifying the indoor air;
A second optimal humidity section defined as a range between the lowest humidity and the highest humidity within the selected humidity section is set in the control unit to correspond to the indoor temperature;
The control unit is an air conditioner characterized in that when the indoor humidity is lower than the second optimal humidity section, the control unit controls the humidification unit until the humidity is set within the second optimal humidity section. In clause 7,
An air conditioner, characterized in that the set humidity within the second optimal humidity section is the highest maximum humidity in the second optimal humidity section. According to paragraph 1,
It includes a dehumidifying unit for dehumidifying the indoor air;
A second optimal humidity section defined as a range between the lowest humidity and the highest humidity within the selected humidity section is set in the control unit to correspond to the indoor temperature;
The control unit is an air conditioner characterized in that when the indoor humidity is higher than the second optimal humidity section, the control unit controls the dehumidification unit until the humidity is set within the second optimal humidity section. According to clause 9,
An air conditioner, characterized in that the set humidity within the second optimal humidity section is the lowest minimum humidity in the second optimal humidity section. According to paragraph 1,
An air conditioner wherein the humidity control mode includes a ventilation mode in which indoor air and outdoor air are exchanged. According to paragraph 1,
An air conditioner, wherein information on the level of humidity corresponding to the plurality of humidity sections is displayed on the input unit so that the user can identify it. a) receiving information about indoor humidity from the control unit;
b) when one humidity section among a plurality of humidity sections divided according to the humidity level is selected by the user, determining by the control unit whether the indoor humidity is outside the selected humidity section;
c) when the indoor humidity is outside the selected humidity range, the control unit controls the indoor humidity in a humidity control mode so that the indoor humidity falls within the selected humidity range;
Including,
A plurality of humidity areas are provided to correspond to the humidity areas and are defined by a certain range of temperature and a certain range of humidity, and the humidity range is within the humidity range;
Divided into the plurality of humidity sections based on the current indoor temperature,
When the user selects one of the plurality of divided humidity sections through an input unit, the control unit operates in a humidity control mode so that the indoor humidity falls within the range of the selected humidity section,
An optimal control area consisting of the entire area of the plurality of humidity areas is set in the control unit;
The plurality of humidity sections are within the range of the optimal control area;
The optimal control area consists of at least two areas in which at least some areas do not overlap;
The control method of an air conditioner wherein the control unit determines the season and controls the at least two areas to be applied to different seasons. According to clause 13,
The control unit,
Obtain a first optimal humidity section defined as the range between the lowest humidity and the highest humidity to correspond to the indoor temperature within the optimal control area,
A control method for an air conditioner, characterized in that the plurality of humidity sections are defined by dividing the first optimal humidity section by a set ratio. According to clause 14,
The optimal control area is set so that the closer the temperature is to the minimum temperature in the predetermined range, the higher the first optimal humidity section corresponding to the indoor temperature becomes.
A control method of an air conditioner, characterized in that when the humidifying mode is activated, the closer the indoor temperature is to the minimum temperature, the longer the humidifying mode operation time is. According to clause 14,
The optimal control area is set so that the closer the temperature is to the maximum temperature in the predetermined range, the lower the first optimal humidity section corresponding to the indoor temperature becomes.
A control method of an air conditioner, characterized in that when the dehumidifying mode is activated, the closer the indoor temperature is to the maximum temperature, the longer the dehumidifying mode operation time is. According to clause 13,
The control unit,
Obtain a second optimal humidity section defined as the range between the lowest humidity and the highest humidity corresponding to the indoor temperature within the selected humidity section,
A control method of an air conditioner, characterized in that when the indoor humidity is lower than the second optimal humidity section, the air conditioner is controlled to operate in a humidifying mode until the set humidity within the second optimal humidity section is reached. According to clause 13,
The control unit,
Obtain a second optimal humidity section defined as the range between the lowest humidity and the highest humidity corresponding to the indoor temperature within the selected humidity section,
A control method for an air conditioner, characterized in that when the indoor humidity is higher than the second optimal humidity section, the air conditioner is controlled to operate in a dehumidifying mode until the set humidity within the second optimal humidity section is reached. According to clause 13,
A control method of an air conditioner, wherein the humidity control mode includes a ventilation mode in which indoor air and outdoor air are exchanged. According to clause 13,
The control method of an air conditioner, wherein the control unit operates in the ventilation mode when it is determined that the indoor humidity can enter the selected humidity range by operating the ventilation mode. According to clause 20,
The control unit determines the degree to which the indoor humidity deviates from the selected humidity range, and, if the degree of deviation is within a set range, determines that the indoor humidity can enter the selected humidity range by operating the ventilation mode. Control method of an air conditioner.

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