JPH0712671A - Autonomous travel type odor-gas source searching system and odor-gas source searching apparatus - Google Patents

Abstract

PURPOSE:To search odor and gas source by moving a body according to a decided result by deciding an odor and gas flowing direction in combination of a gas concentration sensor for measuring odor and gas concentration and a unit for detecting a wind direction. CONSTITUTION:An apparatus for searching odor and gas generation source comprises a body 51, a probe 56 connected to the body 51, a gas concentration display unit 52 with measured data from the probe 56 and an odor.gas flowing direction indicator 53.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an autonomous mobile odor / gas source detection system and an apparatus for detecting the source of odor / gas.

[0002]

2. Description of the Related Art Conventionally, as a technical research on odor / gas source detection, a two-dimensional sensor array, that is, a gas concentration distribution visualization device using 8 × 8 sensors (planar cells) has been used (1) Y ． Hiranaka, H .; Yamasa
ki: "Measurement of Spatia"
l Distribution Change ofG
as Component by Using a S
"ensor Array" Technical Dig
est of the 8th SensorSymp
osium, 1989. pp. 177-180, (2)
Yukio Hiranaka: "Visualization of gas sensor and odor" Fragrance N
o. 162 1989. pp. 75-80, (3) Yukio Hiranaka, Hiroo Yamazaki: "Visualization of gas concentration distribution by semiconductor gas sensor array" Transaction of
Sensor Technology Research
ch, ST-88-4, IEEE of Japan, 1
988. pp. 33-42.

FIG. 11 is a block diagram of such a conventional gas concentration distribution visualization system. In the figure, reference numeral 1 is a two-dimensional gas sensor array, which uses a semiconductor sensor for high-sensitivity detection, takes an image with a video camera 2, and outputs the output from a CRT 3
The digital computer 4 processes the output data from the two-dimensional gas sensor array and sends the output signal to the CRT 3 for spatial measurement and visualization. That is, the size of the array 1 is 8 × 8 and the spacing is 20.
cm, and the image is a little rough with only 64 points of data,
After performing the bilinear interpolation on the computer 4 to interpolate the data points of about 50 points in the vertical and horizontal directions, the density distribution is displayed on the CRT 3 as the density of dots. In addition, by superimposing the current state on the gas distribution image through the video camera 2, it is possible to realize a realistic visualization.

By the way, a sintered body containing a metal oxide such as tin oxide or zinc oxide as a main component generally has a composition deviating from the stoichiometry, and therefore exhibits an n-type semiconductor characteristic, and a hydrocarbon or alcohol. It is known that contact with flammable gas such as carbon monoxide and toxic gas (reducing gas) such as ammonia changes its electrical conductivity depending on the concentration of these gases. A gas sensor is constructed.

[0005]

However, in the above-mentioned conventional odor / gas source detection method, unattended odor /
In the case of detecting a gas source, a so-called multipoint concentration measurement method has been used in which a sensor is arranged in advance at a place where an odor and a gas source are expected to be generated. In the first place, when the odor / gas spreads from the odor / gas source, the molecules are carried by the air flow, so the difference in concentration is small in the direction parallel to the wind. Therefore, with such a fixed multipoint concentration measurement method, it is difficult to detect the odor / gas source even if the concentrations obtained by the multipoint concentration measurement are simply compared. It did not have the ability to search for sources.

In order to solve the above problems, the present invention provides
The combination of a gas concentration sensor that measures odor and gas concentration and a device that detects the wind direction is used to determine the direction of odor and gas flow, and the odor and gas source can be detected by moving the body according to the result of the determination. It is an object of the present invention to provide an autonomous mobile odor / gas source detection system and an odor / gas source detection device capable of performing the above.

[0007]

In order to achieve the above object, the present invention provides [A] an autonomously moving scent / gas source detection system for detecting a source of odor / gas, a movable main body,
A probe arranged on the main body, a first drive means for rotating the probe in a direction parallel or orthogonal to the direction of the odor / gas flow, and a gas concentration detection means connected to the probe, A direction discriminating means for discriminating an odor / gas flowing direction connected to the gas concentration detecting means;
And a driving means of the.

More specifically, (1) the probe is provided on a gas flow partition plate, a first gas suction pipe provided on the front side of the gas flow partition plate, and on the back side of the gas flow partition plate. A second gas suction pipe. (2) The gas concentration detecting means includes a first gas concentration sensor connected to the first gas suction pipe and a second gas concentration sensor connected to the second gas suction pipe. .

(3) The gas concentration detecting means includes a gas concentration sensor for detecting coexisting gas. (4) The gas concentration detecting means includes a gas concentration sensor that detects a specific gas. [B] Further, in the device for detecting the source of odor / gas, the main body, the probe connected to the main body, the gas concentration detecting means connected to the probe, and the gas concentration detecting means are connected. A direction discriminating means for discriminating the direction of odor and gas flow is provided.

More specifically, (1) the probe is provided on a gas flow partition plate, a first gas suction pipe provided on the front side of the gas flow partition plate, and on the back side of the gas flow partition plate. A second gas suction pipe. (2) The gas concentration detecting means includes a first gas concentration sensor connected to the first gas suction pipe and a second gas concentration sensor connected to the second gas suction pipe. .

(3) The gas concentration detecting means includes a gas concentration sensor for detecting coexisting gas. (4) The gas concentration detecting means includes a gas concentration sensor that detects a specific gas.

[0012]

According to the present invention, as described above, the gas concentration sensor for measuring the odor / gas concentration and the device for detecting the wind direction are combined to determine the direction in which the odor / gas flows, and move according to the determination result. By going, we will detect the odor and gas source. As a device for measuring the odor / gas concentration and detecting the wind direction of the air flow, a simple odor / gas source detection device can be obtained by providing a probe having a gas flow partition plate between two gas sensors. .

Further, by incorporating a gas concentration sensor for detecting a specific gas, it is possible to detect the generation source of a specific odor or gas by the presence of the disturbing odor.
In addition, by the autonomous mobile odor and gas source detection system,
It is possible to perform unmanned exploration such as detection of gas leak, detection of drugs (drugs, etc.), detection of dangerous substances, detection of dangerous gas at semiconductor factory, tunnel factory, etc.

[0014]

Embodiments of the present invention will be described in detail below with reference to the drawings. First, an autonomous mobile odor / gas source detection system showing an embodiment of the present invention will be described. FIG. 1 is an overall configuration diagram of an autonomous mobile odor / gas source detection system showing an embodiment of the present invention, and FIG. 2 is a flowchart showing the odor / gas source detection procedure.

As shown in FIG. 1, 11 is a dolly, and a semiconductor gas concentration sensor 12 and an IC control unit 20 are mounted in the dolly 11. Two suction pipes 13 and 14 (not shown) extend upward on the carriage 11 via a rotary stage 17 so that the gas flow partition plate 15 is sandwiched between the two suction pipes 13 and 14 (not shown). With probe 1
6 is provided.

The gas flow partition plate 15 is fixed to the carriage 11, and the rotation of the vehicle body 11 causes the gas flow partition plate 15 to rotate in a direction parallel or orthogonal to the direction of the odor / gas flow. You may do it. Also, 2
A minute pump 18 for sucking gas from the book suction pipes 13 and 14 (not shown) is provided. on the other hand,
The control unit 20 mounted in the carriage 11 has a CPU (central processing unit) 21, a ROM 22 containing a program, a RAM 23 for storing data, a switch 24 that is remotely controlled from the outside, and an input / output of data to / from the outside. An interface 25 for performing is provided.

Next, the operation of the autonomously moving odor / gas source detection device will be described with reference to FIG. (1) First, the switch 24 is turned on by an external remote control device (not shown) (step S
1). (2) Next, the probe 16 is set to the first position, and the semiconductor gas concentration sensor 12 measures the gas concentration (step S2).

(3) Next, the data at the first position of the probe 16 is fetched (step S3). (4) Next, the probe 16 is rotated 90 degrees (step S4). (5) Next, the probe 16 is set to the second position and the gas concentration is measured (step S5).

(6) Next, the data at the second position of the probe 16 is fetched (step S6). (7) Next, based on the above data, the direction of the odor / gas flow is determined (step S7). (8) Next, the carriage 11 is driven in the determined direction (step S8).

(9) Next, it is judged whether or not the odor / gas source is reached (step S9). As a result, if the odor / gas source is not reached, repeat the above steps. If the odor / gas source is reached, switch 2
4 is turned off (step S10), and the process ends. Figure 3
Is a schematic perspective view showing a specific example of the autonomous mobile odor / gas source detection device of the present invention, FIG. 4 is a schematic configuration diagram of the autonomous mobile odor / gas source detection mobile body (robot), and FIG. 5 is its autonomous movement. FIG. 3 is a plan view showing a state in which the gas concentration is measured in accordance with the odor / gas flow by the mold odor / gas source detection moving body.

As shown in these figures, for example, the width l ₁
(80 cm) and a depth of l ₂ (70 cm), a nozzle 32 is provided on one wall of a rectangular wind tunnel 31 having a pyramid-shaped chimney on the opposite side. A discharge port 34 having a suction fan 33 is provided at the tip. In the wind tunnel 31, the autonomous moving odor / gas source detection moving body 40 is set. As described above, the autonomous mobile scent / gas source detection moving body 40 has the carriage 41 and the probe 42 mounted thereon.

As shown in FIG. 4, the odor / gas source detection moving body 40 of the autonomous moving type has a semiconductor gas concentration sensor 47 and a control device 48 mounted in a carriage 41. Further, two gas suction pipes 43, 44 extend above the carriage 41 through a rotary stage 46, and a gas flow partition plate 45, for example, a vertical l is provided between the two gas suction pipes 43, 44.
₃ (7 cm) and lateral l ₃ (3 cm) are arranged.

The two suction pipes 43 and 44 are connected to different gas concentration sensors, that is, the first gas concentration sensor and the second gas concentration sensor, respectively. The gas sucked from the two suction pipes 43 and 44 is sucked by a minute pump (not shown) and detected by the gas concentration sensor. That is, saturated ethanol is sent from the nozzle 32 together with air. Then, the diffusion speed of the odor and gas is very slow, and the odor and gas are mainly carried by the wind.

In this embodiment, the semiconductor gas concentration sensor detects the target odor / gas concentration, and at the same time, detects the wind direction at that location, and by going upwind, the odor / gas source is approached and the odor is detected.・ Can detect gas sources. As shown in FIG. 3, an autonomously moving odor / gas source detection moving body 40 is set in the wind tunnel 31. Therefore, from the nozzle 32 to the exhaust port 34 having the suction fan 33.
Saturated ethanol gas is sent to the air with air.

The output data from the first gas concentration sensor and the second gas concentration sensor are processed by the controller 48 to determine the direction of the odor / gas flow.
That is, the probe 42 detects the odor and the gas concentration,
It is possible to simultaneously detect the wind direction of the air flow that carries odors and gas molecules. The probe 42 can be moved by the carriage 41 working as a remote controller and can be rotated by the rotating stage 46.

With this configuration, the gas concentration gradient in the direction parallel to the wind was small and it was difficult to determine the direction based on the concentration difference. However, by using this probe 42,
It became possible to determine the direction from the density difference between the front and back. The procedure for direction determination was determined as follows. First, FIG.
As shown in (a), the gas flow partition plate 45 is rotated until it becomes vertical to the traveling direction of the odor / gas source detection moving body 40, and the one with a higher gas concentration is determined before and after. next,
As shown in FIG. 5B, the gas flow partition plate 45 is rotated by 90 degrees, and left / right determination is performed. As a result, the directions in which the odor / gas source detection moving body 40 is moved are left front, right front, left rear,
The scent / gas source detection moving body 40 is moved in that direction after being determined to be one of the right rear.

FIG. 6 shows a twelve in the wind tunnel showing an embodiment of the present invention.
FIG. 7 is a diagram showing the results of direction determination at points, and FIG. 7 is a gas concentration (gas / air) in each operation mode of the probe in that case.
7A shows the measured gas concentration (gas / air) at the point a in the center of the plume in FIG. 6, and FIG. 7B shows the point b at the plume end in FIG. The measured gas concentration (gas / air) is shown.

As shown in FIG. 6, ethanol was used as the target gas, and the determination was performed with the odor / gas source detection moving body 40 facing upwind. As a result, the sensor response (R gas / R
The smaller the air), the higher the ethanol concentration. The average width of the plume (spreading of the ejected ethanol) in the figure is where the sensor response was 0.4 when the ethanol concentration distribution was measured.

As shown in FIG. 7, the direction was correctly determined at the center of the plume such as the point a, but it was erroneously determined to be leeward at the plume end such as the point b. FIG. 8 shows the result of actually detecting the odor / gas source. Figure 8
As shown in (a), when starting from the center of the plume, the odor / gas source detection moving body 40 headed straight to the odor / gas source.

On the other hand, as shown in FIG. 8B, when starting from the plume end, the odor / gas source detection moving body 40
Begins to move leeward, but when entering the plume, the correct direction is determined, and the odor / gas source detection moving body 40
I was able to reach the source of smell and gas. FIG. 9 is a perspective view of an odor / gas source detection apparatus showing another embodiment of the present invention, and FIG. 10 is an overall configuration diagram of the odor / gas source detection system.

As shown in FIG. 9, the main body 51 of the odor / gas source detection device 50 is provided with a gas concentration display section 52 and a gas flow direction display section 53. A lead wire 54 is led out from the main body 51 and connected to a handle 55. This handle 5
Two gas suction pipes 57 and 58 extend to the valve 5, and a probe 56 composed of a gas flow partition plate 59 is provided at the tip end thereof. That is, the probes 56 having the gas suction pipes 57 and 58 attached to the front and back of the gas flow partition plate 59 are provided. Here, semiconductor gas concentration sensor (not shown)
Is incorporated in the handle 55, and the measurement data by the odor and the gas flow is taken into the main body 51 via the lead wire 54, and the data processing device (not shown) inside the main body 51.
Displays the gas concentration and the direction of the gas flow.

The operation will be described below with reference to FIG. In FIG. 10, when the probe 56 is at the position A with respect to the gas flow, the measurement data from the gas suction pipes P ₁₁ and P ₂₁ are stored in the memories 61 and 62 of the data processing device 60. Next, when the probe 56 rotates to the B position,
The measurement data from the gas suction pipes P ₁₂ and P ₂₂ are stored in the memories 63 and 64 of the data processing device 60.

Therefore, these measurement data are input to the gas flow direction discriminating device 65 to discriminate the gas flow direction as described above. Therefore, the gas concentration data from the memory 61 is displayed on the gas concentration display unit 52, and the output from the gas flow direction determination device 65 is displayed on the gas flow direction display unit 53.
This odor / gas source detection device allows a person to hold a probe in his hand and walk along the gas flow direction displayed on a small portable body connected to this probe.
The gas source can be detected.

Further, by moving the probe by a person, the odor and gas source can be detected regardless of the condition of the road surface, and the three-dimensional odor and gas source can be detected within a range of several meters above the ground. Can be a reality. It can also be applied as a system for detecting the source of a specific odor or a specific gas.

That is, in order to detect the odor / gas concentration, a plurality of types of gas (coexisting gas) having different characteristics are used by using a plurality of types of gas sensors, and the output thereof is pattern-recognized to determine the odor / gas type. You can By this method, the source of a specific odor or gas can be detected by the presence of the disturbing odor.

For example, as a disturbing odor, in a semiconductor factory, an organic solvent gas such as toluene or acetone is used for a gas sensor such as silane or phosphine. Further, in the case of searching for a gas leak location in a home, gas such as alcohol may be used as opposed to city gas. In general,
The change in sensor electrical resistance with respect to gas concentration is expressed by the following equation.

R = kC ^-n where R is the electrical resistance of the sensor, C is the gas concentration, and n, k
Is a constant. Therefore, in the semiconductor gas sensor, the sensitivity of the target component can be increased by controlling the catalyst component added to the sintered body, the operating temperature of the element, etc., and the sensitivity of the coexisting gas can be suppressed to provide selectivity. .

The present invention is not limited to the above embodiments, and various modifications can be made based on the spirit of the present invention, and these modifications are not excluded from the scope of the present invention.

[0039]

As described in detail below, according to the present invention, the following effects can be obtained. (1) The odor / gas source can be detected by detecting the wind direction of the airflow at the same time as measuring the odor / gas concentration.

(2) Further, as a device for measuring the odor / gas concentration and detecting the wind direction of the air flow, by providing a probe having a gas flow partition plate between two gas sensors, it is possible to easily detect the odor / gas source. The device can be obtained. (3) Furthermore, the presence of the disturbing odor enables detection of the source of a specific odor or gas.

(4) In addition, an autonomous mobile odor / gas source detection system is used to detect gas leaks, drugs (narcotics, etc.),
It is possible to perform unmanned exploration such as detection of dangerous substances and detection of dangerous gas at semiconductor factory or tunnel factory sites.

[Brief description of drawings]

FIG. 1 is an overall configuration diagram of an autonomous mobile odor / gas source detection system showing an embodiment of the present invention.

FIG. 2 is a flowchart showing an autonomous odor / gas source detection procedure according to an embodiment of the present invention.

FIG. 3 is a schematic perspective view showing a specific example of an autonomous mobile scent / gas source detection apparatus showing an embodiment of the present invention.

FIG. 4 is a schematic configuration diagram of an autonomous mobile odor / gas source detection mobile body (robot) showing an embodiment of the present invention.

FIG. 5 is a plan view showing a state in which a gas concentration is measured in accordance with an odor / gas flow by an autonomous mobile odor / gas source detection moving body according to an embodiment of the present invention.

FIG. 6 is a diagram showing a result of direction determination at 12 points in the wind tunnel showing the embodiment of the present invention.

FIG. 7: Smell with each probe showing an embodiment of the present invention
It is a figure which shows the detection data of gas.

FIG. 8 is a diagram showing a result of detection of an odor and a gas source showing an example of the present invention.

FIG. 9 is a perspective view of an odor and gas source detection device according to another embodiment of the present invention.

FIG. 10 is an overall configuration diagram of an odor / gas source detection system showing another embodiment of the present invention.

FIG. 11 is a configuration diagram of a conventional gas concentration distribution visualization system.

[Explanation of symbols]

 11,41 Truck 12,47 Semiconductor gas concentration sensor 13,14,43,44,57,58 Gas suction pipe 15,45,59 Gas flow partition plate 16,42,56 Probe 17,46 Rotation stage 18 Micro pump 20 Control Part 21 CPU (Central Processing Unit) 22 ROM 23 RAM 24 Switch 25 Interface 31 Wind Tunnel 32 Nozzle 33 Suction Fan 34 Discharge Port 40 Autonomous Mobile Smell / Gas Source Detecting Mobile 48 Controller 50 Smell / Gas Source Detecting Device 51 Main Body 52 gas concentration display 53 gas flow direction display 54 lead wire 55 grip 60 data processing device 61, 62, 63, 64 memory 65 gas flow direction determination device

Claims (10)

[Claims] 1. An autonomous mobile odor / gas source detection system for detecting a source of odor / gas, wherein (a) a movable body, (b) a probe arranged on the body, and (c). First drive means for rotating the probe in a direction parallel or orthogonal to the direction of odor / gas flow; (d) gas concentration detection means connected to the probe; and (e) gas concentration detection Autonomous characterized by comprising a direction discriminating means connected to the means for discriminating a flow direction of odor and gas, and (f) second drive means for moving the main body in the discriminating direction by the direction discriminating means. Mobile odor / gas source detection system. 2. The probe comprises: (a) a gas flow partition plate, (b) a first gas suction pipe provided on the front side of the gas flow partition plate, and (c) a back side of the gas flow partition plate. The autonomous scent / gas source detection system according to claim 1, further comprising a second gas suction pipe provided. 3. The gas concentration detecting means includes: (a) a first gas concentration sensor connected to the first gas suction pipe;
The autonomous mobile odor / gas source detection system according to claim 1, further comprising (b) a second gas concentration sensor connected to the second gas suction pipe. 4. The autonomous scent / gas source detection system according to claim 1, wherein the gas concentration detecting means comprises a gas concentration sensor for detecting coexisting gas. 5. The autonomous scent / gas source detection system according to claim 1 or 3, wherein said gas concentration detecting means comprises a gas concentration sensor for detecting a specific gas. 6. An apparatus for detecting a source of odor and gas, (a) a main body, (b) a probe connected to the main body, (c) a gas concentration detecting means connected to the probe, (D) Smell connected to the gas concentration detecting means
An odor / gas source detection device, comprising: a direction determination unit that determines the direction of gas flow. 7. The probe comprises: (a) a gas flow partition plate, (b) a first gas suction pipe provided on the front side of the gas flow partition plate, and (c) a back side of the gas flow partition plate. The odor / gas source detection device according to claim 6, further comprising a second gas suction pipe provided. 8. The gas concentration detecting means comprises: (a) a first gas concentration sensor connected to the first gas suction pipe;
The odor / gas source detection device according to claim 6, further comprising: (b) a second gas concentration sensor connected to the second gas suction pipe. 9. The odor / gas source detection device according to claim 6, wherein the gas concentration detection means comprises a gas concentration sensor for detecting coexisting gas. 10. The odor / gas source detection device according to claim 6, wherein the gas concentration detection means includes a gas concentration sensor that detects a specific gas.