JP2013120001A - Device and method of changing set value for co2 concentration control - Google Patents

Abstract

PROBLEM TO BE SOLVED: To save energy by adjusting a set value of COconcentration control to a suitable value corresponding to a deviation width of a measured value of COconcentration.SOLUTION: A minimum value (pvmin) of a measured value of COconcentration in a predetermined period T in each elapsed period T is extracted as a measured value of the COconcentration in a control objective space while a person is not present, every time a predetermined time elapses. A difference between a minimum value (pvmin) and a reference value (predetermined value (400 ppm) fixed as the COconcentration of the atmosphere) is obtained as a drift amount ΔD (ΔD=pvmin-reference value). When the drift amount ΔD is a negative value, SP'=SP-|ΔD| is established and when the drift value ΔD is a positive value, SP'=SP+|ΔD| is established. SP is an initial set value (1,000 ppm) of COconcentration control and SP' is a set value of the COconcentration control after change.

Description

  The present invention relates to a CO2 concentration control setting value changing apparatus and method for changing a CO2 concentration control setting value determined for a control target space.

  The concentration of CO2 is generally used as an indicator of air pollution and is a measure for efficient ventilation. In the building management method, temperature: 17 to 28 ° C., humidity: 40 to 70%, CO: 10 ppm or less, CO2: 1000 ppm or less, dust: 0.15 mg / rice, airflow: 0.5 m / s It is prescribed as follows.

  Among these, CO2 is measured regularly and its concentration is 1000 ppm or less. For this reason, in Patent Document 1, for example, the target value for CO2 concentration control is set to 1000 ppm, and the indoor ventilation is controlled to be 1000 ppm or less.

  In such CO2 concentration control, for example, 800 ppm is set for CO2 concentration control in consideration of drift in the minus direction of the sensor (CO2 sensor) that measures the concentration of CO2 with respect to 1000 ppm defined in the building management method. Value. That is, 800 ppm is determined as a setting value for CO2 concentration control, and the ventilation amount into the room (controlled space) is controlled so that the measured value of CO2 concentration matches this setting value. As a result, even if the CO2 sensor drifts in the minus direction with time, the indoor CO2 concentration is kept at 1000 ppm or less.

JP 2008-304124 A

  However, 800 ppm, which is set as the set value for CO2 concentration control with respect to 1000 ppm set in the Building Management Law, is adopted as a guaranteed value in consideration of variations in the environment and sensor accuracy. In many cases, there is no problem even if it is set higher.

  In other words, the CO2 concentration control setting value is set to a low value in consideration of the maximum value of the deviation of the concentration measurement value from the CO2 sensor, despite the fact that as the value approaches 1000 ppm, the amount of heat from the outside air treatment is reduced to save energy. Therefore, setting the CO2 concentration control to a lower value in consideration of the maximum deviation width of the concentration measurement value hinders energy saving.

  The present invention has been made in order to solve such problems. The object of the present invention is to save energy by setting the set value of CO2 concentration control to an appropriate value corresponding to the deviation width of the measured value of CO2 concentration. An object of the present invention is to provide a setting value changing apparatus and method for CO2 concentration control that can be achieved.

  In order to achieve such an object, a set value changing device for CO2 concentration control according to the present invention includes CO2 concentration measuring means for measuring the CO2 concentration in a control target space, and a predetermined value determined as the CO2 concentration of the outside air. Obtained as a reference value, a drift amount calculating means for obtaining a difference between the measured value of the CO2 concentration in the control target space without a person and the reference value as a drift amount, and a drift amount calculating means. And setting value changing means for changing a setting value of the CO2 concentration control determined for the control target space based on the drift amount.

  According to the present invention, the predetermined value determined as the CO2 concentration in the outside air is used as the reference value, and the difference between the measured value of the CO2 concentration and the reference value in the absence of a person in the control target space is obtained as the drift amount. Based on this drift amount, the set value of the CO2 concentration control determined for the control target space is changed.

  For example, if the reference value is 400 ppm, the measured value of CO2 concentration in the absence of a person is 350 ppm, and the target value (initial setting value) for CO2 concentration control is 1000 ppm, the drift amount (measured value−reference value) is − The absolute value of drift amount 50 ppm is subtracted from the initial setting value 1000 ppm of CO2 concentration control, and the changed setting value of CO2 concentration control is set to 950 ppm. As a result, the set value of the CO2 concentration control is changed from 1000 ppm to 950 ppm. In this case, if the control value is set so that the measured value of the CO2 concentration coincides with the changed setting value 950 ppm of the CO2 concentration control by changing the setting value of the CO2 concentration control to 950 ppm, Since the drift amount of the measured value is −50 ppm, the actual CO 2 concentration in the controlled space is adjusted to 1000 ppm.

  In the present invention, the measured value of the CO2 concentration in a state where there is no person in the control target space is obtained, but the minimum value of the measured value of the CO2 concentration in a predetermined period (for example, one month) It may be obtained as a measurement value, or the control target space may be in a state where no person is present, and an average value or a weighted average of the measurement value of CO2 concentration in that state may be obtained as a measurement value of CO2 concentration in the state where no person is present. It is good to do.

  According to the present invention, a predetermined value determined as the CO2 concentration of the outside air is used as a reference value, and a difference between the measured value of the CO2 concentration in a state where there is no person in the control target space and the reference value is obtained as a drift amount. Since the set value of the CO2 concentration control determined for the control target space is changed based on the obtained drift amount, the set value of the CO2 concentration control is appropriately set according to the deviation width of the measured value of the CO2 concentration. As a low value, it becomes possible to save energy.

It is a figure which shows the outline of the system using one Embodiment of the setting value change apparatus of the CO2 density | concentration control which concerns on this invention. It is a functional block diagram of a set value changing device for CO2 concentration control used in this system. It is a flowchart of the processing operation which CPU in this setting value change apparatus performs. It is a figure which illustrates a mode that the setting value of CO2 concentration control is changed for every predetermined period T. FIG.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. FIG. 1 is a diagram showing an outline of a system using an embodiment of a set value changing device for CO2 concentration control according to the present invention.

  In FIG. 1, reference numeral 100 denotes a CO2 concentration control target space, 200 denotes a CO2 concentration control setting value changing device according to the present invention, 300 denotes a CO2 concentration control device, and 400 denotes a ventilation device provided for the control target space 100. In addition, a CO2 sensor S1 is installed in the control target space 100 as means for measuring the CO2 concentration in the space. The control target space 100 may be any space where people are active, and is not limited to a space in a building.

  FIG. 2 shows a functional block diagram of a setting value changing device (hereinafter simply referred to as a setting value changing device) 200 for CO2 concentration control. The setting value changing device 200 is realized by hardware including a processor and a storage device, and a program that realizes various functions in cooperation with the hardware, and the measurement value is a function block unique to the present embodiment. A capture unit 1, a measured value storage unit 2, a reference value storage unit 3, an initial set value storage unit 4, a minimum value extraction unit 5, a drift amount calculation unit 6, and a set value change unit 7 are provided. ing. In this embodiment, the CO2 sensor S1 is provided as one of the components of the set value changing device 200.

  In the set value changing device 200, the measured value capturing unit 1 captures the measured value pvi of the CO2 concentration from the CO2 sensor S1 at a constant cycle. The measured value storage unit 2 stores the measured value pvi of the CO2 concentration from the CO2 sensor S1 taken in at regular intervals in time series. The reference value storage unit 3 stores a predetermined value determined as the CO2 concentration of outside air as a reference value. In this embodiment, a predetermined value determined as the CO2 concentration of the outside air is set to 400 ppm, and this 400 ppm is stored in the reference value storage unit 3 as a reference value. In the initial set value storage unit 4, 1000 ppm defined by the building management method is set as the initial set value SP of the CO2 concentration control.

  The minimum value extraction unit 5 calculates the minimum value pvmin of the measured value of the CO2 concentration in the predetermined period T from the measurement values stored in the measurement value storage unit 2 every time the predetermined period T elapses. Extracted as a measured value of the CO2 concentration in a state where there is no person in the space 100. In the present embodiment, the predetermined period T is, for example, one month.

  The drift amount calculation unit 6 receives the minimum value pvmin of the measured value of the CO2 concentration in the predetermined period T from the minimum value extraction unit 5 as input, and the reference value (400 ppm) stored in the minimum value pvmin and the reference value storage unit 3. ) As a drift amount ΔD (ΔD = pvmin−reference value).

  The set value changing unit 7 receives the drift amount ΔD from the drift amount calculating unit 6 and, when the drift amount ΔD is a negative value, the drift amount from the initial set value SP stored in the initial set value storage unit 4. If the absolute value of ΔD is subtracted to obtain the changed CO2 concentration control setting value SP ′ (SP ′ = SP− | ΔD |) and the drift amount ΔD is a positive value, it is stored in the initial setting value storage unit 4. The absolute value of the drift amount ΔD is added to the initial setting value SP thus set to obtain the changed CO2 concentration control setting value SP ′ (SP ′ = SP + | ΔD |).

  In the functional block diagram shown in FIG. 2, the CO2 sensor S1 and the measured value capturing unit 1 constitute a CO2 concentration measuring unit in the present invention. The minimum value extracting unit 5 and the drift amount calculating unit 6 Drift amount calculation means is configured. Further, the set value changing unit 7 corresponds to the set value changing means in the present invention, and the reference value storage unit 3 corresponds to the reference value storage means. Further, the functions of the measured value fetching unit 1, the minimum value extracting unit 5, the drift amount calculating unit 6 and the set value changing unit 7 are realized as processing functions of the CPU 8 according to a program.

  In FIG. 1, the CO2 concentration control device 300 receives the set value SP ′ of CO2 concentration control from the set value changing device 200 as input, and makes the measured value pvi of the CO2 concentration from the CO2 sensor S1 coincide with the set value SP ′. In addition, the amount of ventilation from the ventilation device 400 to the control target space 100 is controlled.

  FIG. 3 shows a flowchart of processing operations executed by the CPU 8 in the setting value changing device 200. The CPU 8 captures the measured value pvi of the CO2 concentration from the CO2 sensor S1 (step S101), and stores the captured measured value pvi of the CO2 concentration in the measured value storage unit 2 (step S102).

  The CPU 8 repeats the processing operations of steps S101 and S102, and when a predetermined period T (one month in this example) has elapsed (YES in step S103), the minimum value pvmin of the measured value of the CO2 concentration in the predetermined period T Is extracted from the measured value storage unit 2 as a measured value of the CO2 concentration in a state where there is no person in the control target space 100 (step S104).

  Then, the reference value (400 ppm) is read from the reference value storage unit 3 (step S105), and the difference between the minimum value pvmin of the measured value of the CO2 concentration in the predetermined period T extracted in step S104 and the reference value is determined as a drift amount ΔD (ΔD = Pvmin-reference value) (step S106).

  Next, the CPU 8 checks whether the drift amount ΔD obtained in step S106 is a positive value or a negative value (step S107).

  Here, if the drift amount ΔD is a negative value (“minus” in step S107), the absolute value of the drift amount ΔD is subtracted from the initial setting value SP stored in the initial setting value storage unit 4 to obtain the changed value. The set value SP ′ (SP ′ = SP− | ΔD |) for CO2 concentration control is set (step S108), and is output to the CO2 concentration control device 300 (step S110).

  If the drift amount ΔD is a positive value (“plus” in step S107), the absolute value of the drift amount ΔD is added to the initial setting value SP stored in the initial setting value storage unit 4, and the changed CO2 concentration The control set value SP ′ (SP ′ = SP + | ΔD |) is set (step S109), and is output to the CO2 concentration control apparatus 300 (step S110).

  FIG. 4 illustrates a state in which the set value of the CO2 concentration control is changed every predetermined period T. In this example, the period T1 is set to “2012/1/1 to 2012/1/31” for one month, the period T2 is set to “2012/2/1 to 2012/2/28”, and the period T3 is set to “ 2012/3/1 to 2012/3/31 ". In addition, the measurement period of the CO2 concentration during the period T1 to T3 is 1 minute, and the reference value of the CO2 concentration is 400 ppm.

  In this example, in the period T1, the minimum value pvmin of the measured value of the CO2 concentration is extracted as 350 ppm, and the drift amount ΔD is obtained as −50 ppm. For this reason, the set value SP ′ of the changed CO2 concentration control is set to SP ′ = SP− | ΔD | = 1000 ppm−50 ppm = 950 ppm.

  In the period T2, the minimum value pvmin of the measured value of the CO2 concentration is extracted as 410 ppm, and the drift amount ΔD is obtained as +10 ppm. For this reason, the set value SP ′ of the changed CO2 concentration control is set to SP ′ = SP + | ΔD | = 1000 ppm + 10 ppm = 1010 ppm.

  In the period T3, the minimum value pvmin of the measured value of the CO2 concentration is extracted as 370 ppm, and the drift amount ΔD is obtained as −30 ppm. For this reason, the set value SP ′ of the changed CO2 concentration control is set to SP ′ = SP− | ΔD | = 1000 ppm−30 ppm = 970 ppm.

  In this case, based on the result obtained from the period T1, the initial setting value of CO2 concentration control, 1000 ppm, is changed to 950 ppm, and the measured value pvi of CO2 concentration matches the changed setting value of 950 ppm of CO2 concentration control. The amount of ventilation that will be controlled will be controlled. Thus, the actual CO2 concentration in the control target space 100 is adjusted to 1000 ppm because the drift amount ΔD of the measured value pvi of CO2 concentration is −50 ppm.

  Further, based on the result obtained from the period T2, the initial setting value for CO2 concentration control, 1000 ppm, is changed to 1010 ppm, and the measured value pvi of CO2 concentration is made to coincide with the changed setting value for CO2 concentration control, 1010 ppm. Such ventilation control is performed. As a result, the actual CO2 concentration in the control target space 100 is adjusted to 1000 ppm because the drift amount ΔD of the measured value pvi of CO2 concentration is +10 ppm.

  Further, based on the result obtained from the period T3, the initial setting value of 1000 ppm for CO2 concentration control is changed to 970 ppm, and the measured value pvi of CO2 concentration is made to coincide with the changed setting value 970 ppm for CO2 concentration control. Such ventilation control is performed. As a result, the actual CO2 concentration in the control target space 100 is adjusted to 1000 ppm because the drift amount ΔD of the measured value pvi of CO2 concentration is −30 ppm.

  Thus, in the present embodiment, the difference between the measured value pvmin of the CO2 concentration in a state where there is no person in the control target space 100 and the reference value (400 ppm) is obtained as the drift amount ΔD, and the obtained drift amount ΔD. By changing the setting value of the CO2 concentration control determined for the control target space 100 based on the above, the setting value of the CO2 concentration control is set to an appropriate value according to the deviation width of the measured value of the CO2 concentration, thereby saving energy. Can be planned.

  In the above-described embodiment, the minimum value pvmin of the measured value of the CO2 concentration in the predetermined period T is obtained as the measured value of the CO2 concentration in the state where there is no person, but the control target space 100 is in the state where there is no person. The average value or weighted average of the CO2 concentration in that state may be obtained as the measured value of the CO2 concentration in the absence of a person.

[Extension of the embodiment]
The present invention has been described above with reference to the embodiment, but the present invention is not limited to the above embodiment. Various changes that can be understood by those skilled in the art can be made to the configuration and details of the present invention within the scope of the technical idea of the present invention.

  S1 ... CO2 sensor, 1 ... measured value take-in unit, 2 ... measured value storage unit, 3 ... reference value storage unit, 4 ... initial set value storage unit, 5 ... minimum value extraction unit, 6 ... drift amount calculation unit, 7 ... setting value changing unit, 8 ... CPU, 100 ... control target space, 200 ... setting value changing device for CO2 concentration control, 300 ... CO2 concentration control device, 400 ... ventilation device.

Claims (2)

CO2 concentration measuring means for measuring the CO2 concentration in the control target space;
Reference value storage means for storing a predetermined value determined as the CO2 concentration of outside air as a reference value;
Drift amount calculating means for obtaining a difference between the measured value of the CO2 concentration in a state where there is no person in the space to be controlled and the reference value as a drift amount;
Setting value changing means for changing a setting value of CO2 concentration control determined for the control target space based on the drift amount obtained by the drift amount calculating means. Setting value change device. A CO2 concentration measuring step for measuring the CO2 concentration in the control target space;
A reference value storing step for storing a predetermined value determined as the CO2 concentration of outside air as a reference value;
A drift amount calculating step for obtaining a difference between a measured value of the CO2 concentration in a state where there is no person in the control target space and the reference value as a drift amount;
A setting value changing step of changing a setting value of the CO2 concentration control determined for the space to be controlled based on the drift amount obtained in the drift amount calculating step. Setting value change method.

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