KR20140075599A - Apparatus and method for automatically adjusting co_2 sensor - Google Patents

Abstract

The present invention is to prevent a measured value of CO_2 concentration from being overlapped with an error. An automatic adjusting apparatus of the present invention includes: a unit to acquire a measured value of CO_2 concentration from a CO_2 sensor measuring the concentration of CO_2 of a space to be controlled; a parameter storage unit (122) storing a parameter of instructing an air damper to open or close when the CO_2 sensor is automatically adjusted; a damper control unit (121) controlling the degree of opening of the air damper according to a condition defined by the opening/closing instruction parameter when the automatic adjustment is performed, thereby feeding air to the space to be controlled, and closing the air damper when the measured value of the CO_2 concentration is continuously within a range of a reference value ±α for a desired time; and a CO_2 sensor drift correction unit (124) setting a lowest value of the measured values of the CO_2 concentration from the start of the automatic adjustment to the closing of the air damper as a base line, and substituting the base line by a reference value.

Description

TECHNICAL FIELD [0001] The present invention relates to an apparatus and method for automatically adjusting a CO2 sensor,

The present invention relates to an automatic adjustment apparatus and method for correcting drift of a CO ₂ sensor.

When people do everyday, CO ₂ occurs day and night. For example, by breathing. Therefore, in a state where there is no person causing CO _{2 in} the building, 400 ppm, which is the atmospheric concentration, is set as the minimum value by ventilation by outside air. In a CO ₂ sensor such as a solid electrolytic type in which the concentration of CO ₂ is measured, a deviation due to a drift (change over time) of 150 ppm / year at maximum occurs due to optical factors of the detection element. Conventionally, the correction by CO ₂ gas by ppm gas is performed manually every year, and the drift amount of the CO ₂ sensor is reset.

Calibration by ppm of CO ₂ gas is advantageous in that it can be reliably calibrated and adjusted, but it is troublesome and costly. Therefore, an automatic baseline correction function has been popularized in which the minimum value of the CO ₂ concentration within a predetermined time (period) sampled by the CO ₂ sensor is changed to an atmospheric concentration (400 ppm) (Patent Document 1, Non-Patent Document 1 and Non-Patent Document 2).

Patent Document 1: JP-A-11-14583

Non-Patent Document 1: "Duct insertion type CO2 sensor CDE ", [online], 3K Co., Ltd., [Search on December 4, 2012], Internet <http://www.three-k.biz/pdf/CDE-J .pdf # search> Non-Patent Document 2: "Large CO2 indicator MODEL4018 ", [online], Tsuruga Electric Co., Ltd. [Search on December 4, 2012], Internet <http://www.tsuruga.co.jp/products/4018/index .html>

According to the conventional method, CO ₂ is constantly generated in an environment where the airtightness of a building is high or an environment where a person is resident for 24 hours, and the CO ₂ concentration in the building may not be lowered to the vicinity of the atmospheric concentration . If the minimum value of the CO ₂ concentration is corrected by the automatic adjustment function under such circumstances, there is a possibility that the error is superimposed on the measurement value of the CO ₂ concentration. For example, when the minimum concentration is lowered to 600 ppm, 600 ppm is 400 ppm due to the automatic adjustment function, so an error of -200 ppm occurs in the measured value of the CO ₂ concentration after the adjustment.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and it is an object of the present invention to provide an automatic adjustment device and method of a CO ₂ sensor capable of preventing an error from overlapping with a corrected CO ₂ concentration measurement value.

Automatic adjustment device of the CO ₂ sensor of the present invention, the control CO ₂ concentration measured value obtaining means for obtaining the CO ₂ concentration measured value from the CO ₂ sensor for measuring the CO ₂ concentration in the target area and, when the automatic adjustment of the CO ₂ sensor A parameter storing means for storing an opening / closing instruction parameter of an outside-air damper in advance in accordance with a condition specified by the opening / closing instruction parameter when executing the automatic adjustment according to a predetermined adjustment schedule; Damper control means for introducing outside air into said control subject space and closing said outside air damper when said CO ₂ concentration measurement value is within a range of a reference value ± α (α is a predetermined value) continuously for a predetermined time; the minimum value of CO ₂ concentration measurements in the period from the beginning of the adjustment to which the outside-air damper is closed as a baseline, and the baseline It is characterized by having a CO ₂ sensor drift correction means for performing a drift correction of replacing the reference value.

The CO ₂ sensor automatically adjusts the opening time of the outside air damper from the start of the automatic adjustment to the closing of the outside air damper and the CO ₂ concentration measurements and, from the start of the automatic adjustment based on the CO ₂ concentration measurements in the period up to which the outside-air damper is closed, to a CO ₂ concentration measurements a certain amount of time successive to that reduced until the range of the threshold value ± α Further comprising parameter setting means for updating the opening / closing instruction parameter so as to satisfy the condition.

Also, automatic adjustment of the CO ₂ sensor according to the present invention method, depending on the adjusted schedule place and the CO ₂ concentration measurement value acquisition step of acquiring the CO ₂ concentration measured value from the CO ₂ sensor for measuring the CO ₂ concentration in the control target area, predetermined when to be executed, the automatic adjusting, according to the conditions specified by a stored switching indication parameter in the parameter storage means controls the opening degree of outside-air damper, and introducing the outdoor air to the controlled space, which the CO ₂ concentration measurements A damper control step of closing the outside air damper when a reference value ± α (α is a predetermined value) is continuously set for a predetermined time, and a CO ₂ concentration measurement value in a period from the start of the automatic adjustment to the closing of the outside air damper a minimum value as a baseline, and the baseline of the capsule performs drift correction for replacing CO ₂ sensor drift compensation stage to the reference value It is characterized in that.

According to the present invention, by controlling the opening degree of outside-air damper, the active introduction of air, and CO ₂ concentration measurements to the control target space constant in accordance with the conditions set by opening and closing directions parameter when to be executed, the automatic adjustment of the CO ₂ sensor Since the time is continuously set within the range of the reference value ± α, it is possible to prevent the error from being superimposed on the CO ₂ concentration measurement value after correction, and the reliability of the automatic adjustment can be enhanced.

In the present invention, the opening time of the outside air damper from the start of the automatic adjustment to the closing of the outside air damper, the CO ₂ concentration measurement value just before the automatic adjustment is started, on the basis of the CO ₂ concentration measurements in the period, by updating the switching indication parameter, it is possible to measure the CO ₂ concentration of a certain period of time continuously to the learning of the opening indication parameter to decrease until the range of the threshold value ± α.

1 is a block diagram showing a configuration of an air conditioning control system according to an embodiment of the present invention.
2 is a block diagram showing a configuration of a controller according to an embodiment of the present invention.
3 is a flowchart showing the operation of the automatic adjustment device during automatic adjustment for correcting the drift of the CO ₂ sensor in the embodiment of the present invention.
4 is a diagram showing an example of recording of data recorded in the parameter setting section in the embodiment of the present invention.

[Principle of the invention]

In the present invention, the outside air damper is completely opened for a predetermined period at a predetermined period to introduce the outside air for a predetermined time, and then the minimum value of the CO ₂ concentration measured by the CO ₂ sensor is corrected to the atmospheric concentration (400 ppm) . Further, in the present invention, the opening time of the outside air damper is learned and the CO ₂ concentration measurement value is lowered to the atmospheric concentration.

[Embodiment Mode]

DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, embodiments of the present invention will be described with reference to the drawings. 1 is a block diagram showing a configuration of an air conditioning control system according to an embodiment of the present invention. The air conditioning control system includes an air conditioner 1, an outside air damper 2 for controlling the amount of introduction of the outside air OA into the air conditioner 1, an air conditioner 1 for returning the air RA from the controlled space 11, A cold water valve 4 for controlling the amount of cold water sent to the cold water coils of the air conditioner 1 and a hot water supply unit 4 for controlling the amount of hot water sent to the hot water coils of the air conditioner 1, A humidification valve 6 for controlling the amount of cold water or hot water sent to the humidifier of the air conditioner 1 and a supply air temperature sensor 6 for measuring the temperature of air (air supply (SA) A sensor 7, an indoor temperature sensor 8 for measuring the temperature of the controlled space 11, a CO ₂ sensor 9 for measuring the CO ₂ concentration in the controlled space 11, A controller 12 for controlling the dampers 2 and 3 and the valves 4 and 5 and 6 and a variable air volume (VAV) unit 13 as humidity sensors 10 It is. The air conditioner 1 includes a filter 14, a cold water coil 15 that cools the air, a hot water coil 16 that heats the air, a humidifier 17, a fan 18 that sends cooled or heated air ).

Next, the operation of the air conditioning control system of Fig. 1 will be briefly described. The cold water coil 15 of the air conditioner 1 cools the outside air OA and the ventilation RA by the cold water supplied from the heat exchanger not shown through the cold water valve 4. [ The hot water coil 16 of the air conditioner 1 heats the outside air OA and the ventilation RA by the hot water supplied from the heat exchanger through the hot water valve 5. [ The cold water or warm water sent out from the heat exchanger is supplied to the humidifier 17 through the humidification valve 6. The humidifier 17 controls the humidity of the supply air SA cooled or heated by the coils 15 and 16 by creating a water spray state. The air supply (SA) that has been cooled or heated by the coils 15 and 16 and humidified by the humidifier 17 is sent to the control target space 11 by the fan 18. A part of the air in the controlled space 11 is returned to the air conditioner 1 as the ventilation RA.

The supply air temperature sensor 7 measures the temperature of the supply air SA delivered from the air conditioner 1. The room temperature sensor 8 measures the temperature of the controlled space 11 and the CO ₂ sensor 9 measures the CO ₂ concentration in the controlled space 11 and the humidity sensor 10 measures And the humidity of the object space 11 is measured. The controller 12 controls the opening degree of the valves 4 and 5 so that the temperature of the supply air SA coincides with the predetermined supply air temperature set value. Further, the controller 12 controls the opening degree of the outside-air damper 2 so that the CO ₂ concentration in the controlled space 11 coincides with the predetermined CO ₂ concentration set value. The controller 12 also controls the opening degree of the humidification valve 6 so that the humidity of the control subject space 11 coincides with a predetermined humidity setting value.

The VAV unit 13 calculates the required air volume of the controlled space 11 so that the temperature of the controlled space 11 coincides with the predetermined room temperature set value and controls the damper (Not shown). The controller 12 calculates the total demand air volume value of the entire system from the required air volume value sent from the plurality of VAV units 13 and obtains the fan rotation number according to the total required air volume value, (1).

In the above-described building management method for the air-conditioning control system, the CO ₂ concentration is determined to be 1000 ppm or less, measured six times a year. Hereinafter, an automatic adjustment device for correcting the drift of the CO ₂ sensor 9 will be described.

Fig. 2 is a block diagram showing the configuration of the controller 12. Fig. And a controller 12, CO ₂ sensor, and (9) CO ₂ concentration measurement value acquisition unit 120 for acquiring the CO ₂ concentration measurements from the damper damper control unit 121, which (2, 3) controlling, CO ₂ sensor A parameter setting unit 123 for updating the opening / closing instruction parameter, a parameter setting unit 123 for updating the opening / closing instruction parameter, and a parameter storage unit 122 for storing the opening / closing instruction parameter of the outside air damper 2 at the time of automatic adjustment of the CO ₂ sensor 9 A CO ₂ sensor drift correction unit 124 for performing drift correction, a measurement value acquisition unit 125 for acquiring measurement values from the air supply temperature sensor 7 and the humidity sensor 10, and valves 4, 5, And a valve control unit 126 for controlling the valve mechanism. The CO ₂ concentration measurement value acquisition section 120, the damper control section 121, the parameter storage section 122, the parameter setting section 123 and the CO ₂ sensor drift correction section 124 constitute an automatic adjustment device.

Since the control of the outside air damper 2 at the normal time by the damper control unit 121 and the control of the valves 4, 5 and 6 at the normal time by the valve control unit 126 are the same as described above, It is omitted.

Fig. 3 is a flowchart showing the operation of the automatic adjustment device in the automatic adjustment for correcting the drift of the CO ₂ sensor 9. Fig.

When it is time to perform automatic adjustment according to a predetermined adjustment schedule (for example, a schedule to be executed once a year, a schedule to be executed on January 1) (YES in step S3 of Fig. 3), the damper control unit 121 The opening degree of the outside-air damper 2 is controlled in accordance with the opening / closing instruction parameter (the opening time and the opening degree of the outside-air damper 2) of the outside-air damper 2 stored in the parameter storage section 122, (Step S2 of FIG. 3). At the time of automatic adjustment, the opening degree of the outside-air damper 2 is normally set to 100% (full opening). In this way, outside air is introduced from the outside air damper 2 to the control target space 11 through the air conditioner 1, and the CO ₂ concentration in the control target space 11 is lowered.

Parameter setting unit 123, when the automatic adjustment is started, the outdoor air damper (2) is the open time that is open, the CO ₂ concentration measured value acquisition unit 120 records the CO ₂ concentration measurements to obtain (step 3 S3).

When the CO ₂ concentration measurement value continuously falls within the range of the atmospheric concentration (400 ppm) ± α (α is a predetermined allowable value) (YES in step S 3 of FIG. 3), the damper control section 121 controls the outside air damper 2 (Step S5 of FIG. 3). On the other hand, when the CO ₂ concentration measurement value does not fall within the range of the atmospheric concentration (400 ppm) ± α continuously for a predetermined time even though the opening time of the outside air damper 2 specified by the opening / closing instruction parameter has elapsed, the CO ₂ concentration The opening time of the outside-air damper 2 is extended until the measured value continuously falls within the range of the atmospheric concentration (400 ppm) ± α for a predetermined time.

The CO ₂ sensor drift correction unit 124 sets the minimum value of the CO ₂ concentration measurement value as the base line in the period from the start of the automatic adjustment to the closing of the outside air damper 2 when the outside air damper 2 is closed, The drift correction is performed to replace the baseline with the reference atmospheric concentration value (400 ppm) (step S6 in Fig. 3). Thereafter, the CO ₂ concentration measurement value sampled by the CO ₂ sensor 9 is treated on the premise that the base line determined at the time of the drift correction is 400 ppm.

Finally, the parameter setting unit 123 sets the opening time of the outside-air damper 2 from the start of the automatic adjustment to the closing of the outside-air damper 2, the CO ₂ concentration measurement value immediately before the automatic adjustment starts, The opening / closing instruction parameter of the parameter storage unit 122 is updated, as necessary, based on the minimum value of the CO ₂ concentration measurement value during the period from the start of the adjustment to the closing of the outside-air damper 2 (Fig. 3, step S7).

4 is a diagram showing an example of recording of data recorded in the parameter setting unit 123. In FIG. 4, the opening time of the outside air damper 2 from the start of the automatic adjustment to the closing of the outside air damper 2, the CO ₂ concentration measurement value just before the automatic adjustment is started, is the outside-air damper (2) the period of the minimum value and the difference between the minimum value and the immediately preceding measured CO ₂ concentration and CO ₂ concentration measurements of CO ₂ concentration measurement is recorded in up to close.

For example, in the example of October 25, 2011 or October 7, 2012, when the outside air damper 2 is opened for two hours, the CO ₂ concentration measurement value falls to a range of 400 ppm ± α (for example, 10 ppm). Therefore, when the open time of the outside-air damper 2 defined by the opening / closing instruction parameters is two hours, it is not necessary to update the opening / closing instruction parameters. On the other hand, in the example of April 20, 2012, it is found that the measurement of the CO ₂ concentration took 2 hours and 20 minutes to decrease to the range of 400 ppm ± α. Therefore, when the opening time of the outside-air damper 2 defined by the opening / closing instruction parameter is 2 hours, it can be seen that this opening time is not sufficient. Therefore, the parameter setting unit 123 updates the opening time and the opening degree of the outside-air damper 2 defined by the opening / closing instruction parameters. In this example, the open time is set to 2 hours and 20 minutes.

In this way, the parameter setting unit 123 sets the parameter storage unit 122 to the open / close state of the parameter storage unit 122 so as to satisfy the condition that the CO ₂ concentration measurement value is lowered until the ambient concentration (400 ppm) The instruction parameter is updated. In the next automatic adjustment, the updated opening / closing instruction parameter is used. The recording example of Fig. 4 is an example, and the average value of the staff room may be recorded.

As described above, in this embodiment, when the automatic adjustment of the CO ₂ sensor 9 is to be executed, the opening degree of the outside-air damper 2 is controlled in accordance with the conditions specified by the opening / closing instruction parameters, It is possible to prevent the error from being superimposed on the CO ₂ concentration measurement value after the correction because the outside air is positively introduced and the measurement value of the CO ₂ concentration is made to fall within the range of the atmospheric concentration ± α for a predetermined time continuously. . Further, in the present embodiment, it is possible to learn the opening / closing instruction parameters so that the CO ₂ concentration measurement value decreases continuously until it reaches the atmospheric concentration ± α for a predetermined time.

The controller 12 of the present embodiment can be realized by a CPU (Central Processing Unit), a storage device, a computer having an interface with the outside, and a program for controlling these hardware resources. In such a computer, a program for realizing the automatic adjustment method of the present invention is provided in a state recorded on a recording medium such as a flexible disk, a CD-ROM, a DVD-ROM, or a memory card. The CPU records the program read from the recording medium in the storage device and executes the process of this embodiment in accordance with the program stored in the storage device.

Industrial availability

The present invention can be applied to a technique for correcting the drift of the CO ₂ sensor.

1: air conditioner 2: outside damper
3: Ventilation damper 4: Cold water valve
5: Hot water valve 6: Humidification valve
7: Supply air temperature sensor 8: Room temperature sensor
9: CO ₂ sensor 10: Humidity sensor
11: Controlled space 12: Controller
13: VAV unit 14: filter
15: cold water coil 16: hot water coil
17: Humidifier 18: Fan
120: CO ₂ concentration measurement value acquisition unit 121: Damper control unit
122: Parameter storage unit 123: Parameter setting unit
124: CO ₂ sensor drift correcting unit 125:
126:

Claims (4)

Control CO ₂ concentration measured value obtaining means for obtaining the CO ₂ concentration measured value from the CO ₂ sensor for measuring the CO ₂ concentration in the target area and,
Parameter storage means for previously storing an opening / closing instruction parameter of the outside-air damper at the time of automatic adjustment of the CO ₂ sensor,
Therefore, the adjustment schedule a predetermined amount of time to carry out the automatic adjustment according to the conditions specified by the on-off indication parameter to control the opening degree of the outside-air damper, and introducing the outdoor air to the controlled space, the CO ₂ concentration A damper control means for closing the outside air damper when the measured value continuously falls within a range of a reference value ± α (α is a predetermined value)
A CO ₂ sensor drift correcting means for performing a drift correction for replacing the baseline with the reference value with the minimum value of the CO ₂ concentration measurement value as a base line in a period from the start of the automatic adjustment to the closing of the outside air damper
And an automatic adjustment device for the CO ₂ sensor. The air conditioner according to claim 1, further comprising: an opening time of the outside air damper from the start of the automatic adjustment to the closing of the outside air damper; a CO ₂ concentration measurement value immediately before the automatic adjustment is started; to satisfy the condition in that lowered until into the basis of the CO ₂ concentration measurements in the period between the outdoor air damper is closed, the CO ₂ concentration to measure the predetermined time continuous range from the reference value ± α, to update the on-off indication parameter Further comprising a parameter setting means for setting a parameter of the CO ₂ sensor. And the CO ₂ concentration measurement value acquisition step of acquiring the CO ₂ concentration measurements from a CO ₂ sensor for measuring the CO ₂ concentration in the control object space,
When the automatic adjustment of the CO ₂ sensor is to be executed according to the predetermined adjustment schedule, the opening degree of the outside-air damper is controlled in accordance with the conditions specified by the opening / closing instruction parameters stored in advance in the parameter storage means, The damper control step of closing the outside air damper when the CO ₂ concentration measurement value continuously falls within the range of the reference value ± α (α is a predetermined value)
A CO ₂ sensor drift correction step of performing drift correction for replacing the baseline with the reference value with the minimum value of the CO ₂ concentration measurement value as a base line in a period from the start of the automatic adjustment to the closing of the outside air damper
And a _second sensor for detecting the temperature of the CO ₂ sensor. The air conditioner according to claim 3, further comprising: an opening time of the outside air damper from the start of the automatic adjustment to the closing of the outside air damper; a CO ₂ concentration measurement value immediately before the automatic adjustment starts; to satisfy the condition in that lowered until into the basis of the CO ₂ concentration measurements in the period between the outdoor air damper is closed, the CO ₂ concentration to measure the predetermined time continuous range from the reference value ± α, to update the on-off indication parameter Further comprising a parameter setting step of setting a parameter of the CO ₂ sensor.

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