KR100942759B1 - Air Condition Controller And Driving Method Thereof - Google Patents

Abstract

The present invention relates to an air quality management apparatus and method for driving the air quality management apparatus to improve the ventilation efficiency by setting a reference level according to the air quality and efficiently adjusting the driving frequency of the air quality management apparatus according to generation of pollutants detected by the reference level. will be.

According to an aspect of the present invention, there is provided a method of driving an air quality management apparatus, including a ventilation device for ventilating indoor air, a sensor for detecting pollutants contained in the indoor air, and generating detection data, and reference pollution data and detection created according to the detection data. A method of driving an air quality management apparatus including a controller for controlling driving of the ventilation device by comparing data, the method comprising: repeatedly detecting a pollutant and generating the detection data; Receiving the sensed data and creating the reference contamination data; Comparing the reference contamination data with the sensed data; And controlling the driving of the ventilation device according to the comparison result.

Air Quality Control System, Ventilator, VOC, Formaldehyde

Description

Air Quality Management System and Driving Method {Air Condition Controller And Driving Method Thereof}

The present invention relates to an air quality management apparatus and a driving method thereof, and in particular, sets a reference level according to the air quality condition and efficiently controls the driving frequency of the air quality management apparatus according to the generation of pollutants detected by the reference level to improve ventilation efficiency. The present invention relates to an air quality management apparatus and a driving method thereof.

Modern multi-family homes are not just provided for the purpose of living a large number of people in a small area. Multi-family houses such as apartments are more convenient, comfortable, and have superior facilities than other residential forms, and users select and use multi-family houses in consideration of these characteristics. In particular, recent multi-generational housing facilities are provided in various forms such as multi-purpose buildings, officetels, as well as apartments and villas. In particular, in large urban areas, large multi-family homes, which include at least several tens of generations in one building, are increasing in order to efficiently use limited space and increase efficiency of additional facilities.

Most of these large multi-family homes are located in urban areas and are often located in places with poor natural environment. Moreover, due to the construction materials used in the construction of houses, the hazards to users are increasing, and the hazards contained in the air that users encounter are reaching a level that cannot be ignored. In addition, due to diseases that are increased by environmental factors such as atopic dermatitis and cancer, there is an increasing necessity to clean the surrounding environment of users. In particular, some diseases are affected by toxic substances in the atmosphere, such as volatile organic compounds (VOCs) and formaldehyde (HCHO), which are emitted from building materials used in urban areas, especially in new buildings. Receive. Therefore, ventilation is essential for the removal of such toxic substances.

To this end, recently, in the case of more than 100 households of multi-unit houses, an effort has been made to improve the user's environment by establishing a facility standard that mandates mandatory ventilation of at least 0.7 times per hour. However, this standard has a problem that does not perform efficient ventilation because only the regulation on the number of ventilation is adopted. In addition, the operation of large-scale air conditioners (air-conditioners) used in multi-family housing is causing a lot of noise and vibration, causing the user's convenience. In addition, such an air conditioner is focused on maintaining an appropriate indoor temperature, and the efficiency for ventilation is inferior. Therefore, an air conditioner that is driven only a predetermined number of times regardless of pollutants cannot obtain sufficient air improvement effect. have.

Accordingly, an object of the present invention is to provide a dedicated air quality management device for ventilation, in particular by setting a reference level according to the atmospheric environment and by efficiently adjusting the driving frequency of the air quality management device according to the generation of pollutants detected by the reference level It is to provide an air quality management device and a driving method thereof to improve the ventilation efficiency.

Air quality management apparatus according to the present invention to achieve the above object is a ventilator for ventilation of indoor air;

A sensor for detecting contaminants contained in the indoor air and creating detection data; And

Repeatedly receiving the sensed data from the sensor to create reference contamination data, and repeatedly receiving the detected data and the created reference contamination data to receive the sensed data having a value greater than the value of the reference contamination data. And a controller for driving the ventilation device.

And an external terminal connected to the controller via a public communication network.

The controller includes a memory for storing the sensed data and the reference contamination data; A communication device for communication with the public communication network; And a central processing unit for controlling the ventilation device by preparing the reference pollution data and comparing the reference contamination data with the sensed data. It is configured to include.

The reference contamination data is characterized in that the average value of the detection data received for a certain period.

The reference contamination data is rewritten when the number of times of driving the ventilation device for a predetermined time is less or more than a preset number.

In addition, the driving method of the air quality management apparatus according to the present invention includes a ventilation device for ventilating the indoor air, a sensor for detecting the pollutants contained in the indoor air to write detection data and the reference pollution data created according to the detection data and A method of driving an air quality management apparatus including a controller for controlling driving of the ventilation device by comparing the sensed data, the method comprising: repeatedly detecting a pollutant and generating the sensed data; Receiving the sensed data and creating the reference contamination data; Comparing the reference contamination data with the sensed data; And controlling the driving of the ventilation device according to the comparison result.

The sensing data creation step, the comparison step and the drive control step are repeatedly performed.

The reference contamination data is calculated by averaging the sensed data received for a predetermined reference time.

The reference contamination data is calculated by averaging the sensed data of a predetermined reference number.

The reference time increases with the reduction of the pollutant.

The sensing data is increased in writing period as the reference time becomes longer.

The reference contamination data is rewritten when the number of driving of the ventilation device is driven more or less than a predetermined number of times.

The air quality management apparatus and driving method thereof according to the present invention continuously change the reference level according to the atmospheric environment, and drive the air quality management apparatus by comparing the changed reference level and measurement data to efficiently control the air quality according to the generation of pollutants. It is possible to adjust the driving frequency of, through which it is possible to improve the ventilation efficiency.

Other features and operations of the present invention in addition to the above objects will become apparent from the detailed description of the embodiments with reference to the accompanying drawings.

The detailed description set forth below in connection with the appended drawings is made with the intention of describing preferred embodiments of the invention, and does not represent the only forms in which the invention may be practiced. It should be noted that the same or equivalent functions included in the spirit or scope of the present invention may be achieved by other embodiments.

Certain features disclosed in the drawings are enlarged for ease of description, and the drawings and their components are not necessarily drawn to scale. However, those skilled in the art will readily understand these details.

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

1 is a configuration example showing the configuration of the air quality management apparatus according to the present invention, Figure 2 is a configuration example showing the configuration of the controller 120 of FIG.

1 and 2, the air quality management apparatus according to the present invention includes a sensor 110, a controller 120, and a ventilation device 150. The air quality management apparatus of the present invention includes a public communication network 170. It may be connected to the external terminal 180 through.

The sensor 110 detects harmful elements including toxic gases in the atmosphere and transmits the detection result to the controller 120. To this end, the sensor 110 is installed in a number of areas where the user lives or lives, and detects the presence and concentration of toxic substances such as volatile organic compounds and formaldehyde contained in the air in the installation space. In addition, the sensor 110 creates the sensing data sda according to the detection result, and transmits the generated sensing data sda to the controller 120. The sensor 110 may be configured as a single type of sensor, but may be configured as two or more different sensors to detect various types of toxic substances. As the sensor 110 can be used for a long time, it is possible to detect a small amount of toxic substances contained in the atmosphere, it is preferable to use a cheap and reliable. For example, the sensor 110 is an electrochemical sensor that detects a displacement potential due to oxidation and reduction reaction with a toxic substance, and a semiconductor that detects a change in conductivity of the semiconductor when a toxic substance contacts the semiconductor surface. It may comprise a type (Semiconductor Type Sensor) and its equivalent sensor. However, this does not limit the present invention.

The controller 120 creates and updates the reference contamination data bcod according to the detection data sda from the sensor 110, and determines whether to drive the ventilation device 150 based on the created reference pollution data bcod. do. Then, the controller 120 controls and drives the ventilation device 150 according to the determination result to proceed with the ventilation process. In particular, the controller 120 determines the degree of contamination based on the sensed data sda, and rewrites the reference contamination data bcod according to the determination result. The controller 120 creates reference contamination data bcod using the sensed data sda provided from the sensor 110 for a predetermined time. Here, the reference contamination data bcod is a value for determining the driving of the ventilator 150 and may be calculated as an average value of the sensing data sda provided for a predetermined period of time, or as a value corresponding to the average value. In addition, the controller 120 controls the generation period of the detection data sda by adjusting the detection period of the sensor 110 according to a preset condition for the preparation of the reference pollution data bcod and the operation of the ventilation device 150. do. For example, when the controller 120 is an initial driving condition, the controller 120 may receive the sensing data sda from the sensor 110 in units of seconds to several tens of seconds. On the other hand, when a considerable period has elapsed, the controller 120 may be provided with the sensing data sda in units of tens of minutes to several hours. In addition, the operation period of the sensor 110 can be changed by reference pollution data (bcod) and the degree of contamination. That is, when the value of the reference pollution data bcod indicates a pollution degree more than a predetermined value, the controller 120 may increase the frequency of writing the detection data sda. On the other hand, when the value of the reference pollution data (bcod) represents the pollution degree less than the preset value, the controller 120 can reduce the frequency of writing the detection data (sda). However, this does not limit the present invention, and it is also possible to use it without changing the period of the sensing data bocd. On the other hand, the controller 120 creates the reference pollution data (bcod) using the sense data (sda) of a certain time. The prepared reference pollution data bcod is prepared based on the average level of the pollution recorded in the detection data sda. When the reference pollution data bcod is created, the controller 120 periodically compares the values of the detection data sda provided from the sensor 110 with the reference pollution data bcod, and the value of the detection data sda is Ventilation is performed by driving the ventilator 150 during a section showing a value higher than the reference pollution data bocd. Then, the controller 120 creates a new reference pollution data (bcod) when the pollution degree is reduced through the comparison of the detection data (sda) and the reference pollution data (bcod), accordingly to control the operation of the ventilator 150 do. That is, when the air quality management device is driven and the generation of pollutants is reduced after a considerable period of time, proper operation of the ventilation device 150 becomes difficult when using the previously generated reference pollution data bocd. This is because, since the intervals in which the pollution degree is lower than the value of the reference pollution data bcod increase, the driving of the ventilation device 150 is significantly reduced. Therefore, when the driving frequency of the ventilation device 150 is less than the predetermined number of times, the controller 120 creates new reference contamination data bcod. In addition, it is also possible to rewrite and use the reference pollution data (bcod) having a higher standard than the previous reference pollution data (bcod) to control when the degree of pollution is increased and the ventilator 150 is excessively driven. Through this method, the controller 120 may drive the ventilator 150 only at the time when the toxic substance is spread in the air and the pollution degree is increased, and also increase the driving efficiency of the ventilator 150. Will be. On the other hand, the controller 120 may be connected to the external terminal 180 through the Internet, wired telephone network, FAX network and the equivalent public communication network 170, in this case is controlled by the external terminal 180, or the sensing data (sda ), Reference pollution data (bcod) may be provided to the external terminal (180). To this end, the controller 120 controls the ventilator 150, prepares the reference pollution data bcod, the central processing unit 122 for comparing the reference pollution data bcod and the detection data sda, and a public communication network. Communication device 126 for connection with 170 and reference pollution data (bcod), the detection data (sda) and the memory 124 that stores the operating conditions of the air quality management device may be configured to include.

The ventilation device 150 operates under the control of the controller 120 to ventilate the air in the apartment house. To this end, the ventilation device 150 is connected to the controller 120, and a control panel 153 may be provided. In addition, the ventilator 150 includes one or more fans 151 for forced circulation of air, and includes a filter / dust collector 155 and a temperature / humidity controller for removing contaminants and dust in the air. 157 may be further included. However, the device other than the fan 151 can be omitted and can be configured, and any equivalent device is also possible, for example, it is also configured as a window driving device to open the window for ventilation, thereby limiting the present invention. It is not.

The external terminal 180 may be a portable terminal such as a computer terminal or a server or a PDA of a responsible person or person in charge of the post-management of a construction company or a multi-family house. The external terminal 180 is connected by the controller 120 of the air quality management device and the public communication network 170 to check whether the air quality management device operates normally, set operating conditions, or receive data generated during the operation. can do.

3 is a flow chart for explaining the operation of the air quality management apparatus according to the present invention, Figure 4 is a flow chart showing another embodiment of FIG.

3 and 4, the air quality management device is installed to start the operation (S100). In the operation start step, the controller 120 of the air quality management device is preset and stored, or an operation condition input through the external terminal 180 is input (S100).

When the operation starts, the controller 120 requests the sensor 110 to sense data sda (S110). The sensor 110 starts an operation according to the request and detects the contaminants at the installed position, thereby creating the detection data sda. Here, although the operation of the sensor 110 may be set to proceed without a request by the controller 120, it is assumed in the description of the present invention to operate according to the request of the controller 120. However, this does not limit the present invention (S120). In addition, the generated sensing data sda is transferred to the controller 120 (S130). In addition, the generation of the sensing data (S120) and the transmission of the sensing day (sda) (S130) is continuously repeated until the operation of the air quality management device is stopped. In addition, the sensing period of the sensor 110 may be changed by the controller 120 as necessary. For example, in the initial installation and operation phase, the detection data (sda) can be generated in 10 seconds or 20 seconds. On the other hand, after several days have elapsed, the detection data (sda) can be prepared in units of 30 minutes or an hour. In this case, the longer the detection period is, the longer the period for integrating the detection data sda for the preparation of the reference contamination data bcod may be adjusted. That is, the reference contamination data bcod may be created by integrating the sensing data sda provided in units of 30 minutes or 1 hour over 168 to 336 times a week. Alternatively, the controller S120 may selectively use the sensing data sda transmitted every 30 minutes without changing the period, thereby not limiting the present invention.

Upon receiving the sensing data sda, the controller 120 creates the reference contamination data bcod using the sensing data sda for a predetermined time (S140).

When the reference pollution data bcod is created, the controller 120 compares the newly received detection data sda with the reference contamination data bcod, and operates / stops / maintains the ventilation device S150 according to the comparison result. In this case, the ventilation device 150 is controlled accordingly (S150 and S160). That is, when the detection data sda having a pollution level higher than the reference pollution data bcod is received, the controller 120 receives the detection data sda having a pollution degree value lower than the reference pollution data bcod for a predetermined time. Until the ventilator 150 is driven. On the other hand, when the detection data sda having a pollution level lower than the reference pollution degree data bcod is received, the controller 120 stops the operation of the ventilation apparatus 150 or maintains the importance state. Control (S150, S160). In addition, the step (S160) of controlling the driving of the ventilation device 150 from the step (S120) of the detection data (sda) is continuously performed repeatedly.

On the other hand, the controller 120 continuously determines whether or not reconstruction of reference pollution data (bcod) is necessary. If it is not necessary to rewrite the reference contamination data bcod, a step (S150) of comparing the reference contamination data bcod and the detection data sda is performed. However, when rewriting is required, the controller 120 proceeds to the reference contamination data creation step (S140). Here, the rewrite time of the reference pollution data (bcod) can be determined by applying various criteria. For example, the ventilation device may be operated and repeatedly performed after a predetermined time or every designated time. Alternatively, the timing may be determined by various methods, such as when the value of the sensed data sda is different from the value of the reference contamination data bcod by more than a predetermined value. In addition, the value of the reconstructed reference pollution data bcod may have a larger value than the value of the previous reference pollution data bcod when the degree of contamination increases.

By such a method, the air quality management apparatus of the present invention can concentrate or disperse the driving of the ventilation apparatus 150 according to the concentration of contaminants, and can be operated at a number of times or more as necessary. Through this, the air conditioner of the present invention can quickly improve the air environment in the area in which the apartment or the air quality management device is installed.

5A and 5B are exemplary diagrams illustrating a relationship between reference pollution data and sensed data.

Referring to FIG. 5A, the controller 120 determines driving of the ventilator 150 using the sensing data sda and the reference pollution data 1 bcod1. In FIG. 5A, the ventilation device is provided only in a period A in which the detection data sda having a higher value than the reference contamination data 1 bcod1 is received based on the reference contamination data 1 bcod1 created using the previous detection data sda. 150 is driven. At this time, when the number of driving of the ventilation device 150 is less than the predetermined number of times, the number of driving is increased, and thus the reference pollution data 2 (bcod2) having a lower value than the reference pollution data 1 (bcod1) is created. In other words, since the detection data sda having a pollution level lower than the reference pollution data 1 (bcod1) is continuously received, when averaged, the reference pollution data having a lower value such as the reference pollution data 2 (bcod2) can be obtained. do.

On the other hand, as shown in FIG. 5B, even when the number of driving of the ventilation device 150 is too large, the reference pollution data 3 (bcod3) is rewritten to create a new host pollution data 4 (bcod4). By using the method as described above, the driving frequency of the ventilation device 150 may be efficiently adjusted.

6 is an exemplary view illustrating an example of an interface screen provided to a user or an administrator by an air quality management apparatus.

Referring to FIG. 6, the interface may be configured as an area representing a driving and standby state of the air quality management device. 6 illustrates an interface in the form of a driving condition display 210, a status display 220, a driving display 230, and a pollution degree display 240.

The driving condition display 210 indicates that the air quality management apparatus is driven by a preset condition such as manual / automatic / night / outing.

The status display 220 displays a current air state and other information, and displays information such as temperature, humidity, and time of the air.

The driving display 230 displays the operation of the ventilation device 150 and the sensor 110. Sensitivity and operation of the sensor 110, whether or not the operation of the ventilator 150, the operating intensity, etc. are easily provided by the user.

The pollution degree display 240 displays the specific gravity of the pollutants using the colored palette 250 so that the user can easily check the degree of pollutants in the air. The pollution degree display 240 displays the type of pollutant detected and the current amount of pollutant. That is, when the amount of pollutants is large, all the palettes 250 are colored and displayed as shown in (a), and when the amount of pollutants is small, only some palettes 250 are colored and displayed as shown in (b). .

The display area is provided as an example, and various modifications are possible, and the present invention is not limited thereto.

1 is a configuration example showing a configuration of an air quality management apparatus according to the present invention.

2 is a configuration example showing the configuration of the controller 120 of FIG.

Figure 3 is a flow chart for explaining the operation of the air quality management apparatus according to the present invention.

4 is a flow diagram of FIG. 3 in another form;

5A and 5B are exemplary diagrams showing a relationship between reference pollution data and sensed data in a graph.

6 is an exemplary view showing an example of an interface screen provided to a user or an administrator by the air quality management device.

<Description of the symbols for the main parts of the drawings>

110: sensor

120: controller 150: ventilator

170: public communication network 180: external terminal

Claims (12)

Ventilation device for ventilating indoor air, a sensor for detecting contaminants contained in the indoor air and creating detection data, and controlling the operation of the ventilation device by comparing the reference pollution data prepared according to the detection data with the detection data. In the driving method of the air quality management device comprising a controller, Repeatedly detecting contaminants and generating the detection data; Receiving the sensed data and creating the reference contamination data; Comparing the reference contamination data with the sensed data; And And controlling driving of the ventilation device according to a result of comparing the reference contamination data with the sensed data. The reference pollution data, And calculating the average of the detected data received for a predetermined reference time so as to increase as the pollutant decreases. The method of claim 1, Creating the sensed data; Comparing the reference contamination data with the sensed data; and And controlling the driving of the ventilation device is repeatedly performed. The method of claim 1, The sensing data writing period is increased as the reference time becomes longer. The method of claim 1, And the reference contamination data is rewritten when the number of driving of the ventilation device is driven more or less than a predetermined number of times. delete delete delete delete delete delete delete delete

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