JP2003028764A - Gas detector and gas detection device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a gas detector easily usable in various factories, disaster scenes, closed conduits, or manholes, dispensing with a power source or the like, capable of gas detection in a short time, and having a simple mechanism. SOLUTION: This gas detector 10 comprises (A) a cylinder part 20, (B) a piston part 30 slidable in the cylinder part 20, (C) a gas introduction hole 21 formed on the side of the cylinder part 20, (D) a gas sensor storage part 40 disposed on the rear end part of the cylinder part 20, (E) a gas sensor 50 arranged in the gas sensor storage part 40, (F) a stem 31 having one end attached to the piston part 30, penetrating a rear chamber 20B, and having the other end extending up to the gas sensor storage part 40, and (G) a biasing means 33 for biasing the piston part 30 in the tip direction of the cylinder part.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a gas detector and a gas detector incorporating the gas detector.

[0002]

2. Description of the Related Art If gas is leaked at various factories or disaster sites and solvent vapors are generated, if they can be quickly detected and quantified at the site,
It goes without saying that it is extremely meaningful for disaster prevention. There are various chemical or physical detection methods for detecting whether the combustible gas or vapor has reached the concentration within the combustion range or whether the toxic gas exceeds the allowable range.

As conventional chemical or physical detection methods, absorption analysis methods such as the Hempel method, the Olsat method, and the Geckel method, explosion analysis methods, fractional combustion methods, combustion analysis methods such as the copper oxide method, titration methods, gravimetric methods, and absorptiometry. Methods such as chemical analysis, gas chromatography, mass spectrometry, infrared spectroscopy, coulometric titration, density analysis, thermal conductivity analysis, infrared analysis, magnetic analysis, solution conductivity analysis A method using a meter can be mentioned. However, in these conventional chemical or physical detection methods, the detection device is generally large-scale, poor in portability, it is not easy to bring the detection device to the site, and a skilled worker (analyzer) Is required.

As a method for easily detecting gas in the field, a method of using a test paper in which a reagent that reacts with the detected gas and changes color is soaked in a filter paper, etc., a color is developed in a glass tube having an inner diameter of 2 to 4 mm. Use a detection tube filled with a reagent that has adsorbed a reagent, and sealed both ends of the tube.At the time of use, cut both ends of the detection tube and introduce the sample gas into the detection tube with a gas sampler or vacuum pump to color the tube. Detector tube method that measures the concentration of the target component from the length of the layer and the degree of coloring, interferometer method that measures the gas concentration by using the difference in the refractive index of the gas, gas detection with an electrically heated filament The hot wire method and the like are known.

[0005]

However, these methods for easily detecting gas at these sites also require the operator to place a certain distance from the place where the gas should be actually collected. If safety cannot be ensured, it is often difficult to collect gas. It is also possible to use a pipe to draw gas from the place where gas should be collected to the detection equipment, but the dead space of the pipe becomes large, making accurate gas analysis difficult. May be. In addition, there is a problem that it is difficult to detect gas in a short time. Further, although such a method may require a power source or electric power for gas suction, it is often difficult to obtain the power source or electric power especially at a disaster site. Moreover, for example, a disaster site such as a collapsed building or a house is a narrow place where it is difficult for workers to enter, or there are many places where there is a dark part or danger, and it is difficult for workers to enter the underdrain or manhole. Many, simple, and
It is highly desirable to be able to work remotely from where the gas should be collected.

Therefore, an object of the present invention is that it can be easily used in various factories, disaster sites, underdrain and manholes, does not require a power source, etc., and can detect gas in a short time. A gas detector having a simple mechanism, and
An object of the present invention is to provide a gas detection device that incorporates such a gas detector and that enables work at a place away from a place where gas should be collected.

[0007]

A gas detector of the present invention for achieving the above object comprises (A) a cylindrical cylinder part and (B) a cylinder part divided into a front chamber and a rear chamber, A piston part that can slide in the cylinder part, (C) a gas introduction hole provided on the side surface of the cylinder part and communicating with the rear chamber, and (D) a gas sensor housing part arranged at the rear end of the cylinder part. , (E) a gas sensor arranged in the gas sensor housing portion, (F) a stem having one end attached to the piston portion, penetrating the rear chamber, and the other end extending to the gas sensor housing portion, and (G) the piston portion. Urging means for urging the cylinder in the direction of the tip of the cylinder portion.

The gas detector of the present invention may have a structure in which the gas sensor housing portion and the cylinder portion are integrated, but the front end portion of the gas sensor housing portion is a cylinder because of the ease of manufacture and maintenance. It is preferable that the structure is fitted to the rear end of the section.

In the gas detector of the present invention, when not in use, the piston portion is positioned on the tip side of the cylinder portion by the urging means in the cylinder portion, and when in use, the stem is pulled so that the inside of the cylinder portion is pulled. The piston portion is moved toward the rear end portion of the cylinder portion, and with the movement of the piston portion, the gas that has passed through the gas introduction hole and entered the rear chamber is analyzed by the gas sensor.

Further, in the gas detector of the present invention, it is preferable that the gas sensor accommodating portion has a rear end portion provided with mounting means capable of engaging with the tip of the grip bar.

The gas detector of the present invention for achieving the above object comprises the gas detector of the present invention, a gripping rod, and a wire. That is, the gas detection device of the present invention,
(A) Cylindrical cylinder part, (B) The inside of the cylinder part is divided into a front chamber and a rear chamber, and a piston part that can slide in the cylinder part, and (C) is provided on the side surface of the cylinder part and communicates with the rear chamber. The gas introduction hole, (D) a gas sensor housing portion arranged at the rear end of the cylinder portion, (E) a gas sensor arranged in the gas sensor housing portion, and (F) one end attached to the piston portion. A gas detector comprising a stem that penetrates the rear chamber and has the other end extending to the gas sensor housing portion, and (G) a biasing means that biases the piston portion toward the tip of the cylinder portion; and (H) gas. It is characterized by comprising a grip bar having a tip attached to the rear end of the sensor housing, and (I) a wire having one end attached to the other end of the stem.

The gas detector of the present invention may have a structure in which the gas sensor housing portion and the cylinder portion are integrated, but the front end portion of the gas sensor housing portion is a cylinder because of the ease of manufacture and maintenance. It is preferable that the structure is fitted to the rear end of the section.

In the gas detector of the present invention, the gripping bar is made of a hollow pipe, and the wire extends in the hollow pipe.
The other end of the wire may project from the rear end of the hollow pipe. Alternatively, the grip bar is made of a hollow pipe, a grip having a trigger is attached to the rear end of the hollow pipe, the wire extends in the hollow pipe, and the other end of the wire is attached to the trigger. Further, in this case, the holding portion may be provided with the gas concentration display means. By pulling the trigger, the wire is pulled, which in turn pulls the stem.

Alternatively, in the gas detecting device of the present invention, the gripping rod has a hollow pipe, a rear end attached to the front end of the hollow pipe, and a front end attached to the rear end of the gas sensor housing. A structure comprising a hollow flexible tube capable of swinging movement and longitudinal movement, wherein the wire extends in the hollow flexible tube and the hollow pipe, and the other end of the wire projects from the rear end of the hollow pipe. Can be Alternatively, the gripping rod has a hollow pipe, a rear end attached to the front end of the hollow pipe, and a front end attached to the rear end of the gas sensor accommodating portion, so that the gripping rod is capable of swinging movement and longitudinal movement. A flexible tube, the grip of which has a trigger is attached to the rear end of the hollow pipe, the wire extends in the hollow flexible tube and the hollow pipe, and the other end of the wire is attached to the trigger. In this case, the holding portion may be provided with the gas concentration display means. By pulling the trigger, the wire is pulled,
As a result, the stem is pulled.

In the gas detector of the present invention, when the gripping bar is composed of at least a hollow pipe as described above,
It is preferable that the hollow pipe is composed of a plurality of hollow pipe members and is expandable and contractible.

In the gas detector of the present invention including the above-mentioned various aspects, when not in use, in the cylinder portion,
The piston part is positioned on the tip side of the cylinder part by the urging means, and in use, the stem is pulled by pulling the wire, and as a result, the piston part moves toward the rear end part of the cylinder part in the cylinder part. Along with the movement of the piston portion, the gas that has passed through the gas introduction hole and has entered the rear chamber is analyzed by the gas sensor.

In the gas detector or the gas detector of the present invention (these may be collectively referred to as the present invention), the urging means is disposed between the rear end of the cylinder portion and the piston portion. A push spring installed, or
It may be configured by a tension spring arranged between the tip portion of the cylinder portion and the piston portion, but the biasing means is not necessarily limited to these configurations.

The gas detector or the gas detector of the present invention can be used alone or in combination with other devices. That is, on the outside of the tip of the cylinder,
For example, at least one of a CCD solid-state imaging device, an illumination lamp, a microphone, and a speaker, that is, one of these, any two combinations, any three combinations, and all four combinations are attached. It is also possible to have a configuration in which there is. More specifically, for example, a combination of a CCD solid-state image pickup device and an illumination lamp, a combination of a microphone and a speaker, and a combination of a CCD solid-state image pickup device, an illumination lamp, a microphone, and a speaker can be given.
It should be noted that the CCD solid-state image pickup device, the illumination lamp, the microphone, or the speaker is housed in the housing, and the structure in which the rear end of the housing is fitted to the front end of the cylinder section prevents damage, maintenance, and replacement. Is preferable from the viewpoint of ease of use.

The gases to be detected in the present invention include oxygen gas, carbon dioxide gas, carbon monoxide gas, hydrogen gas,
Various gases such as propane gas and city gas can be exemplified.

In the present invention, it is preferable to use a semiconductor gas sensor as the gas sensor from the viewpoints of simplifying the structure and reducing the cost. As a semiconductor gas sensor, utilizing the change in electrical resistance due to surface adsorption,
SnO ₂ , ZnO, α-Fe ₂ O ₃ , LaFe _0.9 Co _0.1
O ₃ , γ-Fe ₂ O ₃ , TiO ₂ , CeO ₂ , Nb ₂ O ₅ , A
g _0.04 V ₂ O ₅ , V ₂ O ₅ , gas sensor composed of In ₂ O ₃ ; utilizing electric resistance change due to surface reaction, (L
a, Sr) CoO ₃ , (Ba, Ln) TiO ₃ , Co
O ₃ , Co ₃ O ₄ , SrFeO _2.7 CoO, Co _0.3 Mg _0.7
A gas sensor composed of O; a gas sensor composed of an organic semiconductor (anthracene, metal phthalocyanine, polytetracyanoethylene copper chelate, polypyrrole, heat-treated polyacrylonitrile, etc.) utilizing electric resistance change due to surface adsorption can be mentioned. . In order to improve gas selectivity, SnO ₂ semiconductor gas sensor for LP gas or city gas added with Pt and Pd as sensitizers, and SnO ₂ for CO added with Pt and Sb as sensitizers. Semiconductor gas sensor, ZnO semiconductor gas sensor for H ₂ or CO containing Pd as a sensitizer, Zn for propane gas containing Pt as a sensitizer
An O semiconductor gas sensor can also be used. In addition, Pd / CdS, Pd / TiO ₂ , Pd / Zn are used as non-resistive semiconductor gas sensors utilizing diode rectification.
O, Pt / TiO ₂ , Au / TiO _{2 and the} like can be mentioned. As a non-resistive semiconductor gas sensor using a transistor, a MOS type FET type semiconductor gas sensor using Pd, Pt or SnO ₂ can be mentioned. be able to. A plurality of gas sensors may be arranged in the gas sensor housing to detect different kinds of gas. It is preferable that the gas detection portion of the gas sensor is exposed to the rear chamber that constitutes the cylinder portion.

If the gas sensor is attached to the printed wiring board and the printed wiring board is arranged in the gas sensor housing, the gas sensor can be easily replaced by replacing the printed wiring board. is there. Moreover, if a microprocessor is mounted on the printed wiring board, for example, driving of a gas sensor, signal processing,
Digital signal conversion of analog signal from gas sensor,
Serial data output (RC-232 and IEEE1394
Various serial interfaces, including parallel data output), parallel data output, gas detection level adjustment, gas sensor temperature compensation, self-check function, buzzer and light emitting diode (LED) drive, various gas detection functions. It is also possible to execute on the instrument side.

In the present invention, the cross-sectional shape of the cylindrical cylinder portion taken along a plane perpendicular to the axis thereof may be any cross-sectional shape such as a circle, an ellipse, a rectangle or a polygon. The piston part can be composed of a single plate. Alternatively, the piston portion may be composed of a bottom surface and side surfaces extending from the bottom surface. The side surface may have a structure that extends from the bottom surface toward the tip end side of the cylinder portion, or may have a structure that extends from the bottom surface toward the rear end side of the cylinder portion. The structure may be extended toward the rear end side. By adopting these structures, the piston portion can smoothly slide in the cylinder portion while the side surface forming the piston portion contacts the inner surface of the side surface of the cylinder portion. Further, by adopting these structures, the inside of the cylinder portion is divided into a front chamber and a rear chamber by the bottom surface forming the piston portion. In these structures, the stem may be attached to the bottom surface of the piston portion. The external cross-sectional shape of the piston section or the side surface of the piston section when cut along a plane perpendicular to the axis of the cylinder section is similar to the cross-sectional shape of the inside surface of the side section when the cylinder section is cut along a plane perpendicular to the axis. Shape is desirable.

The material forming the cylinder portion and the gas sensor housing portion, or the material forming the piston portion and the stem has corrosion resistance to gas and has practically sufficient mechanical strength. Any material may be used as long as it is a given material, and examples thereof include various metals and alloys exemplified by aluminum, stainless steel, and titanium, and various plastics. As plastics, fluoro resins such as polytetrafluoroethylene, olefin resins such as polyethylene resins and polypropylene resins; polystyrene resins, AS resins, AB
Styrene resin such as S resin and AES resin; methacrylic resin; polycarbonate resin; polyoxymethylene (polyacetal) resin; polyamide 6, polyamide 66,
Polyamide-based resin such as polyamide MXD6; modified polyphenylene ether (PPE) resin; polyphenylene sulfide resin; polyethylene terephthalate (PET)
Resin, polybutylene ethylene terephthalate (PBT)
Polyester resin such as resin; aromatic polyamide resin,
Materials obtained by adding a reinforcing material such as glass fiber to these resins can be exemplified.

The position, size, and number of gas introduction holes provided on the side surface of the cylinder part are determined by the movement of the piston part.
It suffices that the gas existing in the vicinity of the outside of the cylinder part (referred to as an atmospheric gas for convenience) can be surely introduced into the rear chamber in a position, size and number. A filter made of, for example, a metal plate provided with a large number of holes, glass fiber, natural fiber, synthetic fiber or the like may be attached to the gas introduction hole so that foreign matter does not enter the inside of the cylinder portion.

The hollow pipe member is preferably expandable and contractable, that is, of a telescopic type. The grip bar, the hollow pipe, and the hollow pipe member can be made of metal such as stainless steel or aluminum, or glass fiber reinforced plastics. In addition, the hollow flexible tube is
For example, it can be made of a metal such as stainless steel or aluminum.

The wire may be made of metal or a cord.

It is arranged at the rear end of the gas sensor housing,
As an attachment means that can be engaged with the tip of the grip bar, a protrusion protruding from the rear end of the gas sensor housing and having a thread on the outer peripheral surface can be exemplified. Alternatively, the mounting means can be configured by fixing the nut to the rear end portion of the gas sensor housing portion by bonding, joining, welding or the like. If, for example, a screw thread is provided at the tip of the grip bar,
The tip of the grip bar can be easily attached to the rear end of the gas sensor housing.

In the gas detector of the present invention, a wiring (cable) for taking out an electric signal or the like from the gas sensor and, if necessary, a wiring (cable) for supplying electric power for driving the gas sensor. Can be configured to pass through the inside of the grip bar and be pulled out from the rear end of the grip bar. From the viewpoint of simplification of the structure, it is preferable to lead the wiring into the grip bar through a through hole provided at the rear end of the gas sensor housing. By connecting these wires to a well-known electric circuit contained in the grip or the control box, the concentration of the detected gas is obtained by the operation of the electric circuit, and information to the operator (for example, the deflection of the needle of the meter) , Or deciphered or indexed numbers). In this case, the meter or digital display device corresponds to the gas concentration display means. Alternatively, when a gas concentration higher than the allowable value is detected, a gas concentration display means such as a buzzer, a lamp, or a light emitting diode (LED) notifies the operator of the gas concentration, and the gas concentration higher than the allowable value is detected. It is also possible to transmit the information to a personal computer, a mobile phone, a portable information device, or to notify a remote place by wireless or the like that a gas concentration or a gas concentration higher than an allowable value is detected.
It is also possible to adopt a transmission / reception system that uses Bluetooth, which is one of the wireless LAN protocols, as a protocol, and to send it to a personal computer, a mobile phone, or a portable information device located in the vicinity of the gas detection device. it can. A dry battery for supplying electric power for driving the gas sensor may be arranged in the gas sensor storage portion or may be arranged in the grip portion. If the microprocessor is mounted on the printed wiring board and the buzzer and LEDs are driven, the control box may be unnecessary in some cases, or the electric circuit may not be provided in the grip. Become.

In the gas detector or the gas detector of the present invention, air or an inert gas such as nitrogen gas is introduced from the outside of the system into the cylinder through a tube of polytetrafluoroethylene or the like. You can also With such a structure, gas purging in the cylinder portion can be completed promptly. Specifically, for example, a cylinder filled with compressed air or an inert gas and a cylinder part or a gas sensor storage part may be connected using a tube, and a valve may be arranged in the middle of the tube or in the cylinder. The tube may be passed through the grip bar.

In the present invention, by pulling the stem, the atmospheric gas can be immediately sucked from the gas introduction hole into the rear chamber of the cylinder portion, and the gas can be analyzed by the gas sensor. Therefore, suction of atmospheric gas into the cylinder portion does not require any power source or electric power, and the structure of the gas detector or the gas detector can be simplified. Moreover, in the gas detection device of the present invention, since the gas detector is attached to the tip of the grip bar, not only can the safety of the operator be reliably ensured, but the atmospheric gas can be directly sucked, Since there is almost no dead volume, the gas can be detected reliably and in a short time.

[0031]

BEST MODE FOR CARRYING OUT THE INVENTION The present invention will be described below with reference to the drawings on the basis of an embodiment of the invention (hereinafter, simply referred to as an embodiment).

(Embodiment 1) A schematic sectional view of a gas detector according to Embodiment 1 is shown in FIGS. 1 and 3, and a schematic view of a gas detector is shown in FIG. 1 shows the state of the gas detector during use, and FIG. 3 shows the state of the gas detector during use.

The gas detector 10 according to the first embodiment has a cylindrical cylinder portion 20, a piston portion 30 which can slide in the cylinder portion 20, and a gas sensor housing arranged at the rear end portion of the cylinder portion 20. Part 40 and gas sensor storage part 4
A gas sensor 50 disposed within the 0, a stem 31, and
It is composed of a push spring 33 which is a biasing means. The cross-sectional shape of the cylindrical cylinder portion 20 taken along a plane perpendicular to its axis is circular. The piston portion 30 made of polyoxymethylene (polyacetal) resin has a bottom surface 3
0A and an annular side surface 30B extending from the bottom surface 30A. The side surface 30B extends from the bottom surface 30A toward the tip side of the cylinder portion 20. Piston part 3
The piston portion 30 can smoothly slide in the cylinder portion 20 while the side surface 30B forming 0 contacts the inner surface of the side surface of the cylinder portion 20. In addition, due to the bottom surface 30A forming the piston portion 30, the inside of the cylinder portion 20 is the front chamber 20A.
And is divided into the rear chamber 20B. The external cross-sectional shape of the side surface 30B of the piston portion 30 when cut along a plane perpendicular to the axis of the cylinder portion 20 is similar to the cross-sectional shape of the inside surface of the side surface when the cylinder portion 20 is cut along a plane perpendicular to the axis. is there.

A plurality of gas introducing holes 21 communicating with the rear chamber 20B are provided on the side surface of the aluminum cylinder portion 20.
It is provided. The cylinder portion 20 has a structure in which the tip portion 23 is closed. The gas sensor housing 40 made of aluminum has a structure in which the rear part is closed, and the front end part is fitted to the rear end part of the cylinder part 20. In particular,
A threaded portion 22 is provided at the rear end edge of the cylinder portion 20, and the threaded portion 22 is screwed into a threaded portion 41 provided at the tip edge portion of the gas sensor housing portion 40, thereby Gas sensor housing 4 at the rear end
The front end of 0 can be fitted. Cylinder part 2
A plate 42 made of aluminum having a through hole 43 is arranged between the rear end of the gas sensor housing 40 and the rear end of the gas sensor housing 40 to partition the cylinder 20 and the gas sensor housing 40. The stem 31 is passed through the through hole 43.

One end of the stem 31 made of polyoxymethylene resin is attached to the bottom surface 30A of the piston portion 30, penetrates the rear chamber 20B, and the other end extends to the gas sensor housing portion 40. The one end of the stem 31 can be attached to the bottom surface 30A of the piston portion 30 by inserting one end of the stem 31 into a through hole provided in the bottom surface 30A and caulking the tip portion of the stem 31. In the figure, reference numeral 34 is an auxiliary ring made of polyoxymethylene resin for fixing one end of the stem 31 to the bottom surface 30A of the piston portion 30.

A pushing spring 33, which is a biasing means for biasing the piston portion 30 toward the tip of the cylinder portion 20, is arranged between the rear end portion of the cylinder portion 20 and the piston portion 30 so as to surround the stem 31. It is set up.

At the rear end portion of the gas sensor housing portion 40, there is provided an attaching means capable of engaging with the tip end of the grip bar. Specifically, the mounting means projects from the rear end portion of the gas sensor housing portion 40 and has a protrusion 45 formed with a thread on the outer peripheral surface.
It consists of A through hole 44 is formed in the protrusion 45. A ring (not shown) made of polytetrafluoroethylene, for example, may be provided on the inner surface of the through hole 44 so that the wire 32 is not rubbed and damaged.

A gas sensor 50 composed of a SnO ₂ semiconductor gas sensor is attached to a printed wiring board 51. The gas detecting portion of the gas sensor 50 is exposed to the rear chamber 20B forming the cylinder portion 20 through the through hole 46 provided in the plate 42. Printed wiring board 51
Are arranged in the gas sensor storage portion 40. Specifically, the printed wiring board 51 is attached to the board 42. The outer shape of the printed wiring board 51 is a substantially “C” shape. The stem 31 passes through the central portion 52 of the “C” shape. The gas detection result of the gas sensor 50 is converted into an electric signal by the printed wiring board 51, and is displayed on the LED 63 which is a gas concentration display means described later via the wiring (cable) 53. By configuring the gas sensor 50 to be attached to the printed wiring board 51, the gas sensor 50 can be replaced by replacing the printed wiring board 51.
Can be easily replaced.

As shown in FIG. 2, in the gas detector of the first embodiment, the tip is attached to the gas detector 10 shown in FIG. 1 and the protrusion 45 at the rear end of the gas sensor housing 40. It is composed of a grip bar and a wire 32 having one end attached to the other end of the stem 31. The grip bar consists of a single hollow pipe 60 made of glass fiber reinforced plastics, with a trigger 62 at the rear end of the hollow pipe 60.
A grip portion (grip portion) 61 having is attached. The wire 32 extends in the hollow pipe 60, and the other end of the wire 32 is attached to the trigger 62. Further, the grip 61 has an LED as a gas concentration display means.
For example, three 63 are arranged, and further, a well-known electric circuit, the gas sensor 50, and the printed wiring board 5 are provided.
1 has a built-in dry battery. Furthermore,
The grip 61 is provided with a switch (not shown) for turning on / off the gas sensor 50 and the LED 63.
For example, when the gas concentration above the allowable value is not detected, one LED is made to emit light, and when the gas concentration above the allowable value is detected, two LEDs are made to emit light, and a gas of higher concentration is detected. In that case, the operator can be informed of the presence of the gas by causing the three LEDs to emit light. A screw thread (not shown) is provided on the inner surface of the tip of the hollow pipe 60, and the thread can be screwed into the protrusion 45 at the rear end of the gas sensor storage portion 40. The tip can be easily attached to the gas sensor storage portion 40. Also, the gas sensor 5
Wiring (cable) for taking out electrical signals from 0
53, gas sensor 50, and printed wiring board 51
A wiring (cable) 53 for supplying electric power for driving the upper circuit (not shown) is passed through the hollow pipe 60.

The gas detection information may be directly transmitted to a personal computer, a mobile phone, or a portable information device, or a transmission / reception system using Bluetooth as a protocol may be adopted to locate the gas detection device near the gas detection device. It can also be configured to be sent to a personal computer, a mobile phone, or a mobile information device. Furthermore, if a personal computer, a mobile phone, or a mobile information device is used, the gas detection information can be easily sent to another place, for example, via the Internet, and centralized management of the information and a support system for rescue at a disaster site, etc. Can be easily established.

When not in use, as shown in FIG. 1, in the cylinder portion 20, the piston portion 30 is positioned on the tip end side of the cylinder portion 20 by a pushing spring 33.

In use, in the state shown in FIG. 1, for example, an operator operates the hollow pipe 60 and the gripper 61 in the vicinity of a factory, a disaster site, a culvert or a manhole to collect gas. Guide the gas detector 10 to the desired location where it should be. Then, at the time of use, the trigger 62 provided on the grip 61 is pulled. The trigger 62 may be pulled once or more, but preferably plural times. Then, the wire 32 attached to the trigger 62 is pulled, and the stem 31 is pulled. As a result, in the cylinder portion 20, the piston portion 30 is moved toward the rear end portion of the cylinder portion 20, and along with the movement of the piston portion 30, the gas that has passed through the gas introduction hole 21 into the rear chamber 20B. Are analyzed by the gas sensor 50. This state is shown in the schematic sectional view of FIG. After a predetermined time has passed,
The LED 63 is turned on. After the gas detection operation is completed, the operator operates the hollow pipe 60 and the grip portion 61 to return the gas detector 10 to the operator's hand, and pulls the trigger 62 a plurality of times to remove the gas in the cylinder portion 20. Just purge.

As shown in FIG. 4, the biasing means may be constituted by a tension spring 33A arranged between the tip of the cylinder portion 20 and the piston portion 30.

(Embodiment 2) Embodiment 2 is a modification of the gas detection device described in Embodiment 1, and the structure of the gripping rod is changed as shown in FIGS. 5 and 6. The gripping rod shown in FIG. 5 is composed of a hollow pipe 60A, more specifically, a plurality of hollow pipe members 160A. The hollow pipe 60A has a stretchable structure, that is, a nested structure. The wire 32 extends in the hollow pipe 60A,
The other end of the wire 32 projects from the rear end of the hollow pipe 60A. The stem 31 is pulled by the operator pulling the other end of the wire 32. As a result, in the cylinder portion 20, the piston portion 30 becomes
The gas sensor 50 analyzes the gas that has been moved toward the rear end portion of 0 and has entered the rear chamber 20B through the gas introduction hole 21 as the piston portion 30 moves.

The gripping rod shown in FIG. 6 is a hollow pipe 6
0A and a hollow flexible tube 60B having a hollow pipe 60A having a rear end attached to the front end thereof and a gas sensor housing 40 having a rear end attached to the rear end thereof and capable of swinging movement and longitudinal movement. . The hollow pipe 60A is composed of a plurality of hollow pipe members 160A, and has a retractable structure, that is, a nested structure. Wire 3
2 is inside the hollow flexible tube 60B and the hollow pipe 60A
The other end of the wire 32 extends inside and projects from the rear end of the hollow pipe 60A. A gripping part having a trigger may be attached to the rear end of the gripping rod having such a structure, specifically, the rear end of the hollow pipe 60A, as in the case shown in FIG. The other end of the wire 32 may be attached to the trigger. By providing the hollow flexible tube 60B, the bending motion of the hollow flexible tube 60B, in particular,
By bending the hollow flexible tube 60B due to the multiple cushion effect, the gas detector 10 can be positioned at a desired angle at a desired location.
Can be easily guided.

If the hook 60C is attached to a part of the side wall of the hollow pipe 60A, the wire 32 and the wiring 53 can be easily stored when not in use.

(Third Embodiment) The third embodiment is also a modification of the gas detector described in the first embodiment, and as shown in FIG. 7 or FIG.
A microphone 70 such as a condenser microphone and a speaker 71 for calling are attached to the outside of the unit 3. As shown in FIG. 7, the microphone 70 and the speaker 71 may be directly attached to the outside of the tip portion 23 of the cylinder portion 20, or, as shown in FIG. 8, to the outside of the tip portion 23 of the cylinder portion 20. The housing 72 may be screwed (fitted) to house the microphone 70 and the speaker 71 in the housing 72. This can surely prevent the microphone 70 and the speaker 71 from being damaged. In the latter case, it is preferable to provide a plurality of holes 73 on the front surface of the housing 72. A through hole 23A is formed in the tip 23 of the cylinder portion 20.
And a wiring (not shown) extending from the microphone 70 and the speaker 71 is made to pass through the through hole 23A. The stem 31 is provided with a through hole 31A, the wiring is passed through the through hole 31A, and the hollow pipe 60
Through the inside, it is connected to the electric circuit built in the grip 61. It is preferable that a headset (not shown) having an earphone for listening to a voice and a microphone for interrogating is attached to the grip portion 61, and a speaker and a microphone volume control knob are provided.

(Embodiment 4) Embodiment 4 is also a modification of the gas detector described in Embodiment 1. In the fourth embodiment, a schematic front view is shown in FIG. 9A, and a partial cross-sectional view taken along line BB of FIG. 9A is shown in FIG. 9B. In addition, for example, a compact CCD television camera 8 including a CCD solid-state image pickup device
4, the housing 81 accommodating the illumination lamp 83, the microphone 85, the speaker (not shown), and the reflector 82 is screwed (fitted) to the tip portion 23 of the cylinder portion 20.
It has a configuration. In addition, the illumination lamp 83 is the reflection plate 8
It is located in the center of 2. Further, in order to prevent halation, a V-shaped heat-resistant shield reflection plate 86 is arranged between the illumination lamp 83 and the CCD television camera 84, which are attached to the CCD television camera 84. A protective plate 87 made of transparent glass or plastics is arranged at the tip of the housing 81.

The illumination lamp 83, the CCD television camera 84, the microphone 85 composed of a condenser microphone for collecting sound, and the connecting cables each having one end connected to a speaker (not shown) for interrogating are the cylinder portion 20. A through hole 23A provided at the tip portion 23 of the
An image display device such as a television receiver, a liquid crystal display device, or a personal computer, which is passed through a through hole 31A provided in the stem 31 and a holding rod (hollow pipe 60A, or hollow flexible tube 60B and hollow pipe 60A). (Not shown) and a power supply unit. A control box (not shown) includes a headset (both not shown) having an earphone for listening to a voice and a microphone for interrogating, a DC input connection cord,
An AV input connection cord, a headset connection terminal, a camera power switch, a lighting lamp power switch, an image display device power switch, a speaker volume control knob, a microphone volume control knob, etc. (both not shown) are stored.
In addition, it is possible to directly send various information including image information, voice information, and gas detection information to a personal computer, a mobile phone, or a mobile information device, or to adopt a transmission / reception system using Bluetooth as a protocol, It can also be configured to send to a personal computer, a mobile phone, or a mobile information device located near the gas detection device. If a personal computer is equipped with a headset or a mobile phone is used, it is possible to exchange voice information with a simple configuration. Furthermore, by using a personal computer, a mobile phone, or a mobile information device, image information, audio information, and gas detection information can be easily sent to another place via the Internet,
It becomes possible to easily manage information centrally and establish a support system for rescue at disaster sites.

Although the present invention has been described based on the embodiments, the present invention is not limited to these. The structure of the gas detector or the gas detector described in the embodiments, the members and materials used, the gas sensor, and the like are examples, and can be appropriately changed. The gas detection device having the configuration described in the modified example of the first embodiment or the second embodiment can be applied to the third embodiment and the fourth embodiment. The cylinder portion and the gas sensor housing portion may be integrated into a structure that is difficult to distinguish, and such a structure is also included in the present invention. In such a structure, a kind of stopper may be provided between the cylinder part and the gas sensor housing part in order to control the movement of the piston part.

[0051]

According to the present invention, suction of atmospheric gas into the cylinder portion does not require any power source or electric power,
It is possible to simplify the structure of the gas detector or the gas detection device and reduce the manufacturing cost. Further, maintenance is easy, and gas suction and gas discharge can be easily performed. Moreover, in the gas detection device of the present invention, not only can the safety of the operator be reliably ensured, but in the present invention, since the gas existing in the vicinity of the gas detector can be directly sucked, the dead space (dead space)・ There is almost no volume) and gas can be detected reliably and in a short time.
If the tip of the grip bar is formed of a hollow flexible tube that can be swung and moved in the longitudinal direction, the gas detector can be easily and reliably guided to the atmosphere to be detected. If a CCD solid-state imaging device and an illumination lamp are provided, the state near the gas detector can be visually observed, and if a microphone and a speaker are provided, it is possible to call or talk to a person near the gas detector. Is possible.

[Brief description of drawings]

FIG. 1 is a schematic sectional view of a gas detector according to a first embodiment of the invention when not in use.

FIG. 2 is a schematic diagram of a gas detection device according to a first embodiment of the invention.

FIG. 3 is a schematic cross-sectional view of the gas detector according to the first embodiment of the invention when in use.

FIG. 4 is a schematic cross-sectional view of a modified example of the gas detector according to the first embodiment of the invention when not in use.

FIG. 5 is a schematic diagram showing a grip bar in a gas detection device according to a second embodiment of the invention.

FIG. 6 is a schematic view showing a modified example of the grip bar in the gas detection device according to the second embodiment of the invention.

FIG. 7 is a schematic sectional view of a gas detector according to a third embodiment of the invention when not in use.

FIG. 8 is a schematic cross-sectional view of a modified example of the gas detector according to the third embodiment of the invention when not in use.

FIG. 9 is a schematic partial cross-sectional view of a gas detector according to a fourth embodiment of the invention when not in use.

[Explanation of symbols]

10 ... Gas detector, 20 ... Cylinder part, 20
A ... front chamber, 20B ... rear chamber, 21 ... gas introduction hole, 22 ... screw part, 23 ... tip part, 30 ...
Piston part, 30A ... Bottom of piston part, 30B
..Piston side surfaces, 31 ... Stem, 31A ...
・ Through hole, 32 ... Wire, 33 ... Push spring, 3
3A ... tension spring, 34 ... auxiliary ring, 40
... Gas sensor housing, 41 ... Screw, 42 ...
..Plates, 43, 44, 46 ... Through holes, 45 ... Projections, 50 ... Gas sensor, 51 ... Printed wiring board, 52 ... Wiring, 53 ... Wiring (cable ),
60 ... Hollow pipe, 61 ... Gripping part (grip part), 62 ... Trigger, 63 ... LED, 70 ...
・ Microphone, 71 ... Speaker, 72 ... Housing, 73 ... Hole, 81 ... Housing, 8
2 ... Reflector, 83 ... Illumination lamp, 84 ... C
CD television camera, 85 ... Microphone, 86 ... Shielding reflector, 87 ... Protective plate

   ─────────────────────────────────────────────────── ─── Continued front page    F-term (reference) 2G046 AA02 AA09 AA28 BA01 BA06                       BA09 BG01 BH02 EA14 EB01                       FA01 FA02 FE02 FE04 FE09                       FE12 FE15 FE18 FE20 FE24                       FE29 FE31 FE39 FE40 FE44                       FE45 FE48                 2G052 AA01 AB00 AB22 AC12 AD02                       AD42 BA14 CA02 CA04 CA13                       GA23 JA02

Claims (20)

[Claims] 1. (A) a cylindrical cylinder portion; (B) a piston portion that divides the inside of the cylinder portion into a front chamber and a rear chamber and is slidable in the cylinder portion; and (C) is provided on a side surface of the cylinder portion. A gas introduction hole communicating with the rear chamber, (D) a gas sensor housing portion arranged at the rear end of the cylinder portion, (E) a gas sensor arranged in the gas sensor housing portion, and (F) one end Is attached to the piston portion, penetrates the rear chamber, and has the other end extending to the gas sensor housing portion, and (G) a biasing means for biasing the piston portion toward the tip of the cylinder portion. Gas detector. 2. The front end of the gas sensor storage portion is fitted to the rear end of the cylinder portion.
Gas detector according to. 3. When not in use, the piston portion is positioned on the tip side of the cylinder portion by the urging means in the cylinder portion, and when not in use, the stem is pulled so that the piston portion moves in the cylinder portion. The gas which is moved toward the rear end portion and which has entered the rear chamber through the gas introduction hole along with the movement of the piston portion is analyzed by the gas sensor. Gas detector. 4. The urging means comprises a push spring arranged between the rear end of the cylinder portion and the piston portion, as claimed in any one of claims 1 to 3. Gas detector. 5. The urging means comprises a tension spring arranged between the tip of the cylinder portion and the piston portion, as claimed in any one of claims 1 to 3. Gas detector. 6. A mounting means which is engageable with a tip of a gripping bar is provided at a rear end portion of the gas sensor accommodating portion, according to any one of claims 1 to 5. Gas detector according to. 7. The CCD solid-state image pickup device, an illumination lamp, a microphone and a speaker are attached to the outside of the front end of the cylinder portion, and at least one of them is attached. The gas detector according to item 1. 8. A cylindrical cylinder part (A), (B) a piston part that divides the inside of the cylinder part into a front chamber and a rear chamber, and is slidable inside the cylinder part, and (C) is provided on a side surface of the cylinder part. A gas introduction hole communicating with the rear chamber, (D) a gas sensor housing portion arranged at the rear end of the cylinder portion, (E) a gas sensor arranged in the gas sensor housing portion, and (F) one end Is attached to the piston portion, penetrates the rear chamber, and has the other end extending to the gas sensor housing portion, and (G) a gas detector comprising a biasing means for biasing the piston portion toward the tip of the cylinder portion. (H) A gas detection device comprising: a grip bar having a tip attached to the rear end of the gas sensor housing; and (I) a wire having one end attached to the other end of the stem. 9. The front end of the gas sensor housing is fitted to the rear end of the cylinder.
The gas detection device described in 1. 10. The gripping rod comprises a hollow pipe, the wire extends in the hollow pipe, and the other end of the wire projects from the rear end of the hollow pipe. Gas detector. 11. The gripping bar comprises a hollow pipe, a gripping part having a trigger is attached to a rear end of the hollow pipe, the wire extends in the hollow pipe, and the other end of the wire is attached to the trigger. The gas detection device according to claim 8 or 9, wherein 12. The gas detection device according to claim 11, wherein the grip portion is provided with a gas concentration display means. 13. The gripping rod has a hollow pipe, a rear end attached to the front end of the hollow pipe, and a front end attached to the rear end of the gas sensor accommodating portion, which is capable of swinging movement and longitudinal movement. 10. A flexible tube, wherein the wire extends in the hollow flexible tube and in the hollow pipe, and the other end of the wire projects from the rear end of the hollow pipe. The gas detector described. 14. A gripping rod having a hollow pipe, a rear end attached to the front end of the hollow pipe, and a front end attached to the rear end of the gas sensor housing portion, which is capable of swinging movement and longitudinal movement. It consists of a flexible tube, and a gripping part with a trigger is attached to the rear end of the hollow pipe, the wire extends in the hollow flexible tube and the hollow pipe, and the other end of the wire is attached to the trigger. The gas detection device according to claim 8 or 9, wherein the gas detection device is provided. 15. The gas detection device according to claim 14, wherein the grip portion is provided with a gas concentration display means. 16. The gas detection device according to claim 10, wherein the hollow pipe is composed of a plurality of hollow pipe members and is expandable and contractible. 17. When not in use, the piston part is positioned on the tip side of the cylinder part by the biasing means in the cylinder part, and when not in use, the stem is pulled by pulling the wire, and as a result, in the cylinder part, 9. The piston is moved toward the rear end of the cylinder, and the gas sensor analyzes the gas that has passed through the gas introduction hole and entered the rear chamber as the piston moves. The gas detection device according to claim 16. 18. The urging means comprises a push spring arranged between the rear end portion of the cylinder portion and the piston portion, as claimed in any one of claims 8 to 17. Gas detector. 19. The urging means comprises a tension spring arranged between the tip of the cylinder portion and the piston portion, as claimed in any one of claims 8 to 17. Gas detector. 20. A CCD is provided outside the tip of the cylinder.
20. The gas detection device according to claim 8, wherein at least one of a solid-state imaging device, an illumination lamp, a microphone, and a speaker is attached.