JP2818869B2 - Odor detector - Google Patents

Description

Description: BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an odor detection device that detects odor by sampling air in a monitored area.

(Prior art)

Conventionally, a device for detecting an odor in the air has a zero-value output of the detection element during use, that is, an output in a state where there is no odor changes, and an output based on an accurate odor amount. Can not be obtained. Therefore, the zero-value output of the detection element is calibrated periodically without any odor, for example, by removing the odor with activated carbon or by introducing clean air from a cylinder or the like.

[Problems to be solved by the invention]

In order to create a state for the conventional zero-value output calibration, a place such as a predetermined detection element calibration box is required,
When using activated carbon, it is necessary to replace it when the deodorizing power is reduced, and when using an air cylinder, it takes time for the output of the element to stabilize because the air in the cylinder is dry. There are drawbacks.

[Means for solving the problem]

The present invention focuses on the fact that ozone has a function of decomposing odors, and aims to accurately detect the amount of odors using ozone, and to detect an abnormal odor by sampling air in a monitored area. In the detection device, an element unit for detecting an odor in the air, an ozone supply unit for supplying ozone, a suction unit for sending air to the element unit, and a control unit for each unit. A control unit having abnormality determination means for determining an abnormal odor from the value, wherein the abnormality determination means is based on an output value of the element unit in the ozone-mixed airflow operated by the ozone supply unit. , A predetermined threshold value is set.

Also, in an odor detection device that detects an abnormal odor by sampling air in the monitored area, an element unit that detects an odor in the air, an ozone supply unit that supplies ozone, and a suction unit that sends air to the element unit. A control unit that controls each unit and has an abnormality determination unit that includes a microcomputer and determines an abnormal odor from an output value from the element unit, and the abnormality determination unit includes an ozone supply unit. Ozone is periodically mixed into the air sampled by the periodic operation, and when the difference between the output values of the element units exceeds a predetermined value, it is determined that an abnormality has occurred.

(Operation)

Since a state without smell is created using ozone,
There is no need for a special room as in the case of using activated carbon, and there is no need for replacement. Compared to using a clean air cylinder, when using ozone, ozone is mixed into the measurement airflow, so that zero value calibration can be performed under the same conditions as in the odor monitoring state.

〔Example〕

An embodiment according to the present invention will be described below with reference to the drawings.
FIG. 1 is an embodiment showing a configuration for carrying out the present invention, wherein 1 is a suction device such as a pump, 2 is a ventilation pipe, 3
Is an element unit for detecting an odor, 4 is an ozone supply unit for mixing ozone into the airflow in the ventilation pipe 2, and 5 is a control unit having a microcomputer for controlling the element unit 3, the ozone supply unit 4, and the like. . The element section 3 is an odor detection element such as a hot-wire resistance type using a platinum wire, and the resistance value changes depending on the concentration of the odor. The ozone supply unit 4 is, for example, the same as a silent discharge ozone generator, but may additionally blow ozone from an ozone introducing device using a cylinder or the like, or from the outside. The control unit 5 determines an abnormal smell, sends a signal to an alarm unit (not shown), and also controls a display unit (not shown) that displays the state of the smell.

The operation of the above configuration will be described. Air is sucked into the ventilation pipe 2 by the suction device 1 in each area to be monitored or from each area. On the way, element part 3
Is provided to detect the amount of odor in the flowing air. If the element section 3 is exposed to an odorous air flow,
Odor molecules adhere to the surface of the detection element, and the output value of the zero value, that is, the output value in a state where there is no odor changes, so that an output due to an accurate odor cannot be obtained. Therefore, it is necessary to periodically calibrate the zero output value. When calibrating the output value of the zero value, the ozone supply unit 4 provided on the primary side of the element unit 3 in the ventilation pipe 2 is activated to mix ozone into the airflow passing through the ventilation pipe 2. Then, the airflow coming to the element section 3 is in a state without odor due to the action of ozone, and the ozone mixed in the airflow is further decomposed into odor molecules adhering to the element surface, and purification of the element surface is performed. Accordingly, the output from the element section 3 is free of odor, and an output on a clean surface is obtained, and an output value of zero is accurately set. The above operation can be automatically performed by the control unit 5, and the control unit 5 performs storage of an output value of zero value, calculation of output due to odor, and the like.

2 and 3, a flowchart and a block circuit diagram showing the configuration and operation of the control unit 5 will be described. The MPU is a microprocessor, the ROM 1 is a program storage area relating to the operation of the control unit 5, and the ROM 2 is described later. A storage area for various constants, RAM1 is a work area, RAM2 is a storage area for each numerical value to be described later, IF1, IF2, IF3 and IF4 are interfaces, GS is an element unit 3, OP is an ozone supply unit 4. , CL are clocks, and DP is a display such as a CRT. The control unit 5 usually includes
The sensor output SLV from the element section 3 is compared with, for example, a threshold B to display an abnormality or to display odor intensity SLV−SLV ₀ (steps 202, 204, 205, 206). If the read time is the calibration time (Y in steps 201 and 203), and if a predetermined amount of output value A has not been detected at that time (N in step 207), the zero-value output value SLV ₀ is calibrated. To start. In that case, the control unit 5 first starts the ozone supply unit 4 to create an odorless environment (steps 208 and 209). The sensor output is read after the output of the zero value has sufficiently settled, and the output value of the zero value SLV ₀ is set there.
The ozone supply unit 4 is stopped by adding L and K, setting a predetermined amount of the output value A and the threshold value B (steps 201, 211, and 212). The predetermined amount of output value A is a case where an amount of odor in which it is difficult to set the zero-value output value SLV ₀ of ozone is generated. Therefore, a sensor output SLV equal to or more than the predetermined amount of output value A is obtained. If yes, the monitoring state is continued without performing the calibration of the zero output value SLV ₀ (Y in step 207). Here, by making the output value A of the predetermined amount smaller than the threshold value B, when the output value A exceeds the threshold value, the monitoring state can be continued without performing the calibration of the _zero output value SLV ₀ .

The above operation is a case where it is determined that an abnormality occurs when the output value of the element section 3 exceeds a threshold value. The operation in the case of using other abnormality determination means will be described below with reference to a flowchart shown in FIG. Control unit 5, generally after reading the sensor output SLV ₁ in air (step 403), thereby starting the ozone supply portion 4 for a while by generating ozone mixed stream (step 404, 405), an ozone mixed gas stream read the sensor output SLV ₂ (step 406). The two outputs are compared, and if the difference is larger than the predetermined threshold X, it is determined that there is an abnormality (Y, 409 in step 408). An ozone supply portion 4 after a while stopped (Step 407 and 410), reads the sensor output SLV ₁ returns to the beginning. Normally, the monitoring state is continued by repeating this, but when the read time T becomes the calibration time (Y in steps 401 and 402), the element section 3 enters the purification state (steps 412, 413, 414 and 415), and the operation of the ozone supply section 4 causes the element section 3 to operate. Clean the surface. That is, in the operation of the ozone supply unit 4 in the monitoring state, the element surface is not always completely purified, so that the cleaning is periodically performed. Waiting time T ₂ of the time ozone supply in purification state therefore, keep sufficiently longer than the waiting time T ₁ of the at ozone supply in monitoring state. Also,
The waiting time for supplying ozone in this operation is (Step 410,
415) is the same as the waiting time T ₁ of the at ozone supply in monitoring state, may be different time such as increase towards the ozone supply time. If the difference between the two sensor output does not exceed the threshold value X (N in step 408), when the sensor output SLV ₂ exceeds compared to a predetermined value Y displays an abnormality (Y in step 416, 4
17) If not exceeded, cancel the error display (step
416 N, 418). That is, if an abnormality is displayed, a problem such as contamination of the element section 3 has occurred.
They need to be cleaned or replaced.

When the configuration of the present embodiment is provided, it is preferable to provide a catalyst or the like for decomposing ozone at an exhaust port (not shown) of the ventilation pipe 2 and exhaust the gas after completely decomposing ozone.

〔The invention's effect〕

In the odor detection device according to the present invention, since the ozone is mixed into the measurement airflow, the element portion can be easily made to have no odor, and an accurate zero value output value can be set, so that the abnormality can be reliably determined. .

Also, periodically mix ozone into the air in the monitored area,
By determining the odor abnormality from the output difference between when ozone is generated and when there is no ozone, it is possible to continuously monitor without having to wait until the output of the element section is stabilized.

[Brief description of the drawings]

FIG. 1 is a schematic diagram showing a configuration of an embodiment according to the present invention;
FIG. 2 is a flowchart showing the operation of FIG. 1, FIG. 3 is a block circuit diagram showing the control unit, and FIG. 4 is a flowchart showing another operation of FIG. 3 ... Element part, 4 ... Ozone supply part, 5 ... Control part.

Claims (2)

(57) [Claims] An odor detection device for detecting an abnormal odor by sampling air in a monitoring area, comprising: an element for detecting an odor in the air; an ozone supply unit for supplying ozone; A suction unit that controls the respective units, and a control unit that includes a microcomputer and includes an abnormality determination unit that determines an abnormal odor from an output value from the element unit. The means is based on an output value of the element unit in the ozone-mixed airflow operated by the ozone supply unit,
An odor detection device, wherein a predetermined threshold is set. 2. An odor detection device for detecting an abnormal odor by sampling air in a monitoring area, comprising: an element for detecting an odor in the air; an ozone supply unit for supplying ozone; A suction unit that controls the respective units, and a control unit that includes a microcomputer and includes an abnormality determination unit that determines an abnormal odor from an output value from the element unit. The means is characterized in that ozone is periodically mixed into the sampled air by the periodic operation of the ozone supply unit, and when the difference between the output values of the element units exceeds a predetermined value, it is determined that an abnormality has occurred. Odor detector.