JP6619549B2 - Portable gas detector - Google Patents

Description

  The present invention relates to a portable gas detector, and more particularly to a portable gas detector provided with a filter material that suppresses intrusion of disturbing components into a case portion.

  2. Description of the Related Art Conventionally, a portable gas detector provided with a filter material that suppresses intrusion of disturbing components into a case portion is known (see, for example, Patent Document 1).

  Patent Document 1 discloses a portable gas alarm device including a housing member (case portion) and a gas sensor, a dustproof filter, and a gas suction pump provided inside the housing member. The dust-proof filter of the portable gas alarm device described in Patent Document 1 has a function of removing interfering components in the air supplied to the gas sensor inside the housing member. The gas suction pump has a function of supplying external air to the gas sensor via a dustproof filter. In the portable gas alarm device, the display unit provided with the LCD is connected to the upper part of the housing member, and the power supply unit to which the battery is attached is connected to the lower part of the housing member.

JP 2011-257920 A

  However, in the portable gas alarm device described in Patent Document 1, since the dustproof filter is disposed inside the housing member, when replacing the dustproof filter deteriorated due to clogging or the like, the display unit or the power supply unit is replaced. It is considered that many disassembly operations such as removing the gas from the gas detection unit and opening the housing member are required. For this reason, it is thought that there exists a problem that a dustproof filter cannot be replaced easily.

  The present invention has been made to solve the above-described problems, and one object of the present invention is to enable easy replacement of a filter material that suppresses intrusion of disturbing components into the case portion. It is to provide a portable gas detector.

A portable gas detector according to a first aspect of the present invention includes a gas sensor for detecting a predetermined detection target gas, a case portion in which the gas sensor is provided, and an intake hole for taking in the detection target gas. A sensor cap part consisting of a single member that is detachably attached to the case part, and attached to the inside of the sensor cap part. to comprising a filter material, a sensor cap unit seen including a filter accommodating portion for accommodating the filter member, the gas sensor includes a cover member for accommodating the sensing element. The “interfering component” means all components that may affect the detection of a gas sensor such as a gas other than the detection target gas, water, and dust.

In the portable gas detector according to the first aspect of the present invention, as described above, the sensor cap includes the intake hole for taking in the detection target gas and is detachably attached to the case portion. And a filter material attached to the inside of the sensor cap portion. In addition, the sensor cap portion is provided with a filter housing portion that houses the filter material. The gas sensor includes a cover member that houses the detection element. Thus, the filter material can be replaced simply by removing the sensor cap portion that is detachably attached to the case portion from the case portion, disassembling the sensor cap portion to which the filter material is attached, and replacing the filter material. . Thereby, the filter material which suppresses the penetration | invasion of the interference component in a case part can be replaced | exchanged easily, without requiring many decomposition | disassembly operations. Furthermore, when replacing the entire sensor cap portion to which the filter material is attached, it is not necessary to disassemble the sensor cap portion to which the filter material is attached, so that the filter material can be replaced more easily.

The portable gas detector according to the second aspect of the present invention includes a gas sensor for detecting a predetermined detection target gas, a case portion in which the gas sensor is provided, and an intake hole for taking in the detection target gas. A sensor cap portion that is detachably attached to the case portion, and a filter material that is attached to the inside of the sensor cap portion and suppresses the intrusion of the disturbing component into the case portion by at least decomposing or adsorbing the disturbing component. The gas sensor has a detection hole for guiding the detection target gas taken in from the take-in hole to the inside, the case portion includes a first engagement portion, and the sensor cap portion includes the first engagement portion and When the sensor cap part is mounted on the case part, the first engaging part and the second engaging part are engaged at a predetermined engaging position when the sensor cap part is attached to the case part. The insertion hole is paired with the detection hole. And it is configured to be positioned to that circumferential position. With this configuration, the detection target gas taken in from the intake hole positioned at the position corresponding to the detection hole can be reliably guided to the detection hole, so that the detection target gas is reliably guided to the inside of the gas sensor. be able to. As a result, the detection target gas can be detected more accurately.

In this case, preferably, the sensor cap part further includes a contact restricting part that restricts the filter material from being contacted from the outside through the intake hole, and the sensor cap part includes a plurality of intake holes by the contact restricting part. The gas sensor is provided with a plurality of detection holes, and the first engagement portion and the second engagement portion are engaged at a predetermined engagement position, thereby Each region is configured to be positioned at a circumferential position corresponding to a plurality of detection holes. If comprised in this way, since it can suppress that a filter material contacts via the taking-in hole of a sensor cap part by a contact control part, it can suppress that a filter material breaks. Further, even if the contact restricting portion is provided at a position where the intake hole is divided into a plurality of regions, each region of the intake hole is configured to be positioned at a position corresponding to the plurality of detection holes. Thus, it is possible to prevent the detection target gas from being easily taken into the detection hole by the contact restricting portion. Thereby, the detection object gas taken in from each area | region of a taking-in hole can be reliably guide | induced to each of a corresponding some detection hole.

In the portable gas detector according to the first or second aspect, preferably, the sensor cap portion is disposed inside the sensor cap portion so that the sensor cap portion is in contact with the case portion while being attached to the case portion. A seal member for sealing between the portion and the case portion is further provided. If comprised in this way, it can suppress that a disturbance component penetrate | invades into the inside of a case part from between a sensor cap part and a case part by a sealing member. Thereby, it can suppress that the detection accuracy of the gas sensor provided in the inside of a case part falls.

  According to the present invention, as described above, it is possible to easily replace the filter material that suppresses the intrusion of disturbing components into the case portion.

It is the perspective view which showed the whole structure of the portable gas detector by one Embodiment of this invention. It is the block diagram which showed the control structure of the portable gas detector by one Embodiment of this invention. It is the perspective view which showed the use condition of the portable gas detector by one Embodiment of this invention. It is a disassembled perspective view of the portable gas detector by one Embodiment of this invention. It is the side view which looked at the portable gas detector by one Embodiment of this invention from the X2 side. FIG. 6 is a cross-sectional view taken along line 400-400 in FIG. 5. It is the figure which looked at the sensor cap part of the portable gas detector by one Embodiment of this invention from the X1 side. It is the disassembled perspective view which showed the state before the attachment to the sensor cap part of the sensor press of the portable gas detector by one Embodiment of this invention. It is the top view which showed the state after the attachment to the sensor cap part of the sensor press of the portable gas detector by one Embodiment of this invention. It is the disassembled perspective view which showed the state before mounting | wearing to the case part of the sensor cap member of the portable gas detector by one Embodiment of this invention. It is the perspective view which showed the state after mounting to the case part of the sensor cap member of the portable gas detector by one Embodiment of this invention. It is a disassembled perspective view of the portable gas detector by the modification of one Embodiment of this invention.

  DESCRIPTION OF EXEMPLARY EMBODIMENTS Hereinafter, embodiments of the invention will be described with reference to the drawings.

  First, with reference to FIGS. 1-3, the whole structure of the portable gas detector 100 by one Embodiment of this invention is demonstrated.

  A portable gas detector 100 according to an embodiment of the present invention shown in FIG. 1 detects a predetermined detection target gas (isobutane, methane, hydrogen, etc.) around the portable gas detector 100 and has a predetermined concentration or more. It is a gas detector for notifying the user that the concentration of the detection target gas in the surrounding atmosphere is high due to gas leakage or the like by outputting an alarm when detecting the detection target gas. In addition, the portable gas detector 100 has a dustproof and waterproof function, and water and dust are prevented from entering the portable gas detector 100.

  As shown in FIG. 2, the portable gas detector 100 includes a gas sensor 1, a control unit 2, three input buttons 3 (see FIG. 1), and an output unit 4. The output unit 4 includes a buzzer 4a, two lamps 4b (see FIG. 1), and a display unit 4c.

  The gas sensor 1 detects the concentration of the detection target gas by using the change in the electrical conductivity of the detection piece in accordance with the temperature rise when the detection target gas (combustible gas) burns. Includes gas sensing element. In addition, as a gas detection element of the gas sensor 1, it is not restricted to a catalytic combustion type gas detection element, You may use a different gas detection element according to detection object gas. For example, a semiconductor gas detection element may be used as the gas detection element of the gas sensor 1.

  The control unit 2 includes a CPU, and is configured to control the entire portable gas detector 100 by executing an operation program stored in a storage unit (not shown). Moreover, the control part 2 is comprised so that the warning which alert | reports that the detection target gas exceeded the predetermined density | concentration will be output from the output part 4 at the time of an alarm. Specifically, at the time of alarm, the control unit 2 outputs a predetermined buzzer sound from the buzzer 4a of the output unit 4 and lights a predetermined color lamp in the lamp 4b of the output unit 4 to thereby prompt the user. It is comprised so that a warning may be alert | reported with respect to it. Moreover, the control part 2 is comprised so that predetermined information, such as a density | concentration of detection object gas, can be displayed on the display part 4c of the output part 4 at the time of an alarm. When the portable gas detector 100 is calibrated, the control unit 2 displays the calibration result on the display unit 4c so that the user can check the calibration result.

  The input button 3 is provided for accepting an input operation by the user such as turning on / off the power supply or saving the calibration result.

  As shown in FIG. 3, the portable gas detector 100 is configured so that a clip 5 for attaching to a user's belt 101, a breast pocket, and a helmet (not shown) can be attached. Thereby, it is comprised so that the user can carry the portable gas detector 100 easily.

  Next, a specific structure of the portable gas detector 100 will be described with reference to FIGS. 1, 2, and 4 to 11.

  As shown in FIG. 4, the portable gas detector 100 includes a main body 10, a sensor cap member 20 and a battery unit 30 that are detachably attached to the main body 10. The sensor cap member 20 is attached to the side surface 11 a on one side (X2 side) in the longitudinal direction (X direction) of the main body 10. The battery unit 30 is attached to the back surface of the main body 10 on the rear side (Y2 side) in the front-rear direction (Y direction). The sensor cap member 20 and the battery unit 30 are configured to be detachably attached to the main body 10 individually. The battery unit 30 contains a battery (not shown).

  In addition, as shown in FIG. 1, the portable gas detector 100 is formed in a substantially rectangular parallelepiped shape with the battery unit 30 mounted on the main body 10, and each corner of the rectangular parallelepiped is R is chamfered.

  As shown in FIG. 4, the sensor cap member 20 includes a sensor cap portion 21, a water-repellent sheet 22 disposed inside the sensor cap portion 21, a silver filter 23, a packing 24, a filter press 25 and a packing 26. Is included. The water repellent sheet 22 and the silver filter 23 are examples of the “filter material” of the present invention, and the packing 26 is an example of the “seal member” of the present invention.

  The sensor cap part 21 is configured to be detachably attached to an engagement protrusion 12 of the case part 11 described later of the main body part 10. The sensor cap portion 21 is formed of a cylindrical member that is slightly tapered on the other side (X2 side) in the longitudinal direction (X direction) and opened on the X1 side. Further, as shown in FIG. 6, the sensor cap portion 21 includes an intake hole 21 a formed on the X2 side, a filter housing portion 21 b provided inside the sensor cap portion 21 and communicating with the intake hole 21 a, The sensor cap portion 21 includes a protruding portion receiving portion 21c that is provided closer to the X1 side than the filter receiving portion 21b and in which the engaging protruding portion 12 is stored.

  The intake hole 21 a is formed so as to communicate the outside of the portable gas detector 100 and the filter housing portion 21 b, and takes in air containing the detection target gas from the outside of the portable gas detector 100. Is provided.

  In addition, as shown in FIG. 5, the sensor cap part 20 of the sensor cap member 20 is fitted in the case part 11 of the main body part 10 in the intake hole 21 a of the sensor cap part 21 in the front-rear direction (Y direction). 21 d is provided so as to extend. As shown in FIG. 6, the contact restricting portion 21d has a water-repellent sheet 22 and a silver filter 23 attached to the filter housing portion 21b inside the sensor cap portion 21 through the intake hole 21a. It has a function of restricting contact from the outside of the vessel 100. Since the water repellent sheet 22 and the silver filter 23 can be prevented from being contacted from the outside by providing the contact restricting portion 21d, static electricity is generated in the water repellent sheet 22 and the silver filter 23, and the gas sensor 1 It is possible to prevent the malfunction or the water repellent sheet 22 and the silver filter 23 from being damaged.

  As a result, as shown in FIG. 5, the intake hole 21a is divided into a first region 121a and a second region 221a by the contact restricting portion 21d. The first region 121a is positioned on the upper side (Z1 side) of the contact restricting portion 21d in a state where the sensor cap portion 21 of the sensor cap member 20 is attached to the case portion 11 of the main body portion 10. Further, the second region 221a is positioned on the lower side (Z2 side) than the contact restricting portion 21d. The contact restricting portion 21 d is formed integrally with the sensor cap portion 21. The first region 121a and the second region 221a are examples of the “region” in the present invention.

  When the sensor cap portion 21 is attached to the case portion 11, the first region 121a of the intake hole 21a is formed in a semicircular shape having an arc shape on the upper side when viewed from the X2 side. The lower side 221a is formed in a semicircular shape having an arc shape when viewed from the X2 side. Further, the first region 121a and the second region 221a are formed so as to be substantially mirror-image symmetric with respect to the XY plane passing through the center in the vertical direction (Z direction) of the contact restricting portion 21d. Here, by forming the first region 121a and the second region 221a in a semicircular shape, compared to the case where the first region and the second region are formed in a circular shape, from the outside of the portable gas detector 100. A lot of air can be taken inside.

  As shown in FIG. 7, the filter accommodating portion 21b is formed so that the inner diameter is smaller than the protruding portion accommodating portion 21c. A pair of projecting portions 121b projecting inward are formed in the vicinity of the boundary between the filter housing portion 21b and the projecting portion housing portion 21c. The pair of projecting portions 121b project from the inner surface of the filter housing portion 21b at an angular interval of about 180 degrees. The pair of projecting portions 121b are arranged at the front side (Y1 side) and the rear side (Y2 side) at substantially the same height position (vertical direction position) with the sensor cap part 21 attached to the case part 11. Are formed so as to be located respectively.

  Here, in this embodiment, as shown in FIG. 4 and FIG. 6, the water-repellent sheet is provided in the filter housing portion 21 b from the intake hole 21 a side (X2 side) toward the main body portion 10 side (X1 side). 22, silver filter 23, packing 24, and filter holder 25 are arranged in this order. As shown in FIG. 4, the water repellent sheet 22 and the silver filter 23 are both composed of circular sheets having substantially the same diameter. The packing 24 is composed of an annular rubber member having an outer diameter substantially the same as the diameter of the water repellent sheet 22 and the silver filter 23. Here, both the diameter of the water repellent sheet 22 and the silver filter 23 and the outer diameter of the packing 24 are formed so as to be slightly smaller than the inner diameter of the filter housing portion 21b, and from the distance between the protruding portions 121b. Is also formed to be slightly larger.

  The water repellent sheet 22 adsorbs or blocks interference components such as water and dust other than the detection target gas contained in the air taken in from the intake hole 21 a, so that the X1 side (silver filter 23) of the water repellent sheet 22. Side) has a function to suppress the intrusion of interfering components such as water and dust. Further, the silver filter 23 decomposes or adsorbs an interference component such as a gas other than the detection target gas such as a volatile component of the organic solvent contained in the air that has passed through the water-repellent sheet 22, so that the X1 side of the silver filter 23. It has a function of suppressing interference components such as gases other than the detection target gas from entering the (gas sensor 1 side). The packing 24 has a function of sealing between the silver filter 23 and the filter holder 25.

  As shown in FIG. 4, the filter holder 25 is made of an annular member, and the surface of the X2 side is in surface contact with the X1 side of the silver filter 23, thereby pressing the water repellent sheet 22 and the silver filter 23 toward the X2 side. It is configured as follows.

  As shown in FIG. 8, a pair of engagement grooves 25 a with which the pair of protrusions 121 b are engaged are formed on the outer peripheral surface of the filter retainer 25. The pair of engagement grooves 25a are formed at an angular interval of about 180 degrees so as to correspond to the pair of protrusions 121b. The engagement groove 25a includes a first groove 125a extending in the X direction from the opening on the X2 side, and a second groove 225a extending in the R1 direction along the circumference on the X1 side.

  As a result, the filter retainer 25 is disposed in the filter housing portion 21b so that the pair of protrusions 121b are fitted in the pair of first grooves 125a, respectively, and is opposite to the R1 direction in which the second groove 225a extends. The filter retainer 25 is rotated relative to the sensor cap portion 21 in the R2 direction. As a result, as shown in FIG. 9, the pair of protrusions 121b are arranged in the second groove 225a formed on the X1 side of the filter retainer 25, so that the X1 side surface of the second groove 225a and the protrusions The surface of 121b contacts the X2 side. As a result, the pair of protrusions 121b prevent the filter retainer 25 from being pulled out to the X1 side, so that the water repellent sheet 22 and the silver filter 23 that are retained by the filter retainer 25 on the X2 side are released to the X1 side. Is suppressed. Therefore, the sensor cap part 21 (sensor cap member 20) is attached to and detached from the case part 11 (main body part 10) with the water-repellent sheet 22 and the silver filter 23 attached to the filter housing part 21b inside the sensor cap part 21. It can be installed as possible.

  Further, as shown in FIG. 6, a packing 26 made of an annular rubber member is disposed in the protruding portion accommodating portion 21 c inside the sensor cap portion 21. The packing 26 is disposed so as to abut on the filter retainer 25 and the annular bottom surface 121c of the protruding portion accommodating portion 21c on the X2 side, and abut on the X2 side surface 12d of the case portion 11 described later on the X1 side. Yes. Thereby, the packing 26 has a function of sealing between the sensor cap part 21 and the case part 11 in a state where the sensor cap part 21 is attached to the case part 11. The outer diameter of the packing 26 is formed so as to be slightly smaller than the inner diameter of the protruding portion accommodating portion 21c.

  As shown in FIGS. 7 to 10, a pair of projecting portions 221 c projecting inward is formed in the vicinity of the opening portion on the X1 side of the projecting portion accommodating portion 21 c. The pair of projecting portions 221c project from the inner surface of the projecting portion accommodating portion 21c at an angular interval of about 180 degrees, and are formed at substantially the same angular positions as the pair of projecting portions 121b of the filter accommodating portion 21b.

  As shown in FIG. 10, the main body 10 has a case 11 in which a gas sensor 1, a controller 2, an input button 3, and an output 4 (see FIG. 2) are provided. In addition, on the side surface 11 a on the X2 side of the case portion 11, a cylindrical engagement protrusion portion 12 for attaching the sensor cap member 20 to the case portion 11 is provided integrally with the case portion 11.

  The outer diameter of the engagement protrusion 12 is formed to be slightly smaller than the inner diameter of the X1 side protrusion accommodating part 21c of the sensor cap part 21, and as a result, the sensor cap part 21 is formed on the engagement protrusion 12. The protruding portion accommodating portion 21c is configured to be fitted. A pair of engagement grooves 12 b extending from the opening 12 a on the X2 side of the engagement protrusion 12 are provided on the outer peripheral surface of the engagement protrusion 12. The pair of engaging grooves 12b are formed at an angular interval of about 180 degrees, and are formed so as to correspond to the protruding portions 221c of the pair of protruding portion accommodating portions 21c. The engaging groove 12b and the protruding portion 221c are examples of the “first engaging portion” and the “second engaging portion” in the present invention, respectively.

  Specifically, as shown in FIG. 10, the pair of engagement grooves 12b both extend toward the X1 side, and in the R3 direction along the circumference in the vicinity of the end portion on the X1 side of the engagement protrusion 12. It is formed to extend toward. The pair of engaging grooves 12b are formed with engaging portions 122b with which the protruding portions 221c of the protruding portion accommodating portions 21c are engaged. The pair of engaging portions 122b are formed on the front side (Y1 side) and the rear side (Y2 side) at substantially the same height.

  Thereby, the sensor cap part 21 (sensor) to which the water-repellent sheet 22 and the silver filter 23 are attached in a state where the pair of projecting parts 221c of the sensor cap part 21 are fitted in the pair of engaging grooves 12b of the case part 11, respectively. By rotating the cap member 20) in the R3 direction with respect to the case portion 11, the pair of protruding portions 221c are moved toward the pair of engaging portions 122b. Then, as shown in FIG. 11, at a predetermined engagement position A1 and A2, the pair of protrusions 221c engage with the pair of engagement portions 122b, so that the sensor cap portion 21 engages with the case portion 11. The protrusion 12 is configured to be attached.

  At this time, the pair of projecting portions 221c of the sensor cap portion 21 is configured to be positioned on the front side (Y1 side) and the rear side (Y2 side) at substantially the same height position. In addition, the first region 121a on the upper side of the intake hole 21a is positioned so as to be located on the upper side (Z1 side) with respect to the contact restricting portion 21d. Further, the second region 221a on the lower side of the intake hole 21a is positioned so as to be located on the lower side (Z2 side) than the contact restricting portion 21d.

  Further, as shown in FIG. 6, an annular surface 112d that slightly protrudes toward the X2 side is formed on the annular surface 12d on the X2 side of the engaging protrusion 12. In addition, a pair of projecting portions 12e projecting inward are formed on the inner surface of the engaging projecting portion 12 in the vicinity of the opening 12a. The pair of projecting portions 12e are formed at an angular interval of about 180 degrees, and are formed on the upper side (Z1 side) and the lower side (Z2 side) of the inner surface of the engaging projecting portion 12, respectively.

  The gas sensor 1 includes a pair of detection members 1a to which a not-shown catalytic combustion type gas detection element is attached, a sensor substrate 1b to which the pair of detection members 1a are attached, and a pair of resin molds 1c that protect the pair of detection members 1a, respectively. Including. In addition, the gas sensor 1 seals the space between the cover member 13 and the sensor substrate 1b, an aluminum cover member 13 that houses the pair of detection members 1a, a sensor press 14 for pressing the cover member 13 to the X1 side. Packing 15 is included.

  The cover member 13 includes a pair of housing portions 13a in which the detection member 1a and the resin mold 1c are respectively housed from the X1 side, and extends from the bottom surface on the X2 side of the pair of housing portions 13a to the surface on the X2 side of the cover member 13. A pair of detection holes 13b (detection holes 113b and 213b) are formed. The cover member 13 is fixed to the sensor substrate 1b with screws 1d. The pair of detection holes 13b includes a detection hole 113b formed at a position spaced a predetermined distance from the approximate center of the cover member 13 to the upper side (Z1 side), and a lower side (Z2) from the approximate center of the cover member 13. And a detection hole 213b formed at a position separated by a predetermined distance.

  In the present embodiment, as shown in FIG. 5, when the sensor cap portion 21 is attached to the case portion 11, the upper detection hole 113b is formed in the upper first region 121a of the intake hole 21a. The lower detection hole 213b is configured to be positioned at a position corresponding to the lower second region 221a of the intake hole 21a. That is, when the sensor cap portion 21 is attached to the case portion 11, when the pair of projecting portions 221c are respectively engaged with the pair of engaging portions 122b at the predetermined engaging positions A1 and A2, the take-in holes 21a. The upper first region 121a is positioned at a position corresponding to the upper detection hole 113b. Similarly, the lower second region 221a of the intake hole 21a is configured to be positioned at a position corresponding to the lower detection hole 213b. Here, when viewed from the X2 side, the entire corresponding detection hole 113b is located in the area of the first area 121a, and the entire corresponding detection hole 213b is located in the opening area of the second area 221a. It is configured as follows.

  As a result, as shown in FIG. 6, in the portable gas detector 100, the air taken in from the first region 121a of the take-in hole 21a passes through the water repellent sheet 22 and the silver filter 23. At this time, the disturbing components contained in the air are removed by being decomposed or adsorbed. Then, the air from which the disturbing components have been removed passes directly through the inner holes of the packing 24, the filter retainer 25 and the packing 26 formed in an annular shape, and directly reaches the detection hole 113b of the cover member 13. , Guided into the gas sensor 1. Similarly, after the air taken in from the second region 221a of the intake hole 21a passes through the water-repellent sheet 22 and the silver filter 23 to remove disturbing components, the inside of the packing 24, the filter retainer 25 and the packing 26 And then directly reaches the detection hole 213 b of the cover member 13 and is guided into the gas sensor 1. As a result, the air introduced from the detection holes 113b and 213b reaches the pair of detection members 1a of the gas sensor 1, whereby the detection target gas in the air from which the disturbing components have been removed is detected.

  Further, as shown in FIG. 4, the sensor presser 14 has the same structure as the filter presser 25 and has a function of suppressing the cover member 13 of the gas sensor 1 from coming off to the X2 side. Specifically, a pair of engagement grooves 14 a are formed on the outer peripheral surface of the sensor press 14 to engage with the pair of protrusions 12 e of the engagement protrusion 12. Then, by rotating the sensor presser 14 with respect to the case portion 11 in the R4 direction (see FIG. 10) opposite to the R3 direction, the pair of engaging grooves 14a are engaged with the pair of projecting portions 12e. It is configured. When the engaging groove 14a and the protruding portion 12e are engaged, the X2 side surface of the engaging groove 14a and the X1 side surface of the protruding portion 12e come into contact with each other, so that the sensor presser 14 comes out to the X2 side. Therefore, the cover member 13 of the gas sensor 1 is suppressed from coming off to the X2 side.

  The direction of rotation when the sensor cap portion 21 is attached to the case portion 11 (R3 direction) and the direction of rotation when the pair of engagement grooves 14a engage with the pair of protrusions 12e. (R4 direction) is configured to be in the opposite direction. Thereby, when the sensor cap part 21 is removed from the case part 11, the sensor cap part 21 is rotated in the R4 direction. As a result, even if the rotational force of the sensor cap portion 21 is transmitted to the sensor retainer 14 and the sensor retainer 14 rotates in the R4 direction, the sensor retainer 14 has a pair of engaging grooves 14a formed on the pair of projecting portions 12e. Since it rotates so that it may engage, it is possible to suppress unintentionally removing the sensor presser 14 from the case part 11 with the removal of the sensor cap part 21 from the case part 11.

  The casing of the case part 11, the sensor cap part 21, and the battery unit 30 are all made of a resin to which a conductive material that is an antistatic agent is added. Thereby, the danger of ignition by electrostatic charging can be avoided.

  In the present embodiment, the following effects can be obtained.

  In the present embodiment, as described above, the sensor cap portion 21 that includes the intake hole 21 a for taking in the detection target gas and is detachably attached to the case portion 11, and the repellent attached to the inside of the sensor cap portion 21. A water sheet 22 and a silver filter 23 are provided. Thereby, the sensor cap part 21 detachably attached to the case part 11 is removed from the case part 11, and the sensor cap part 21 to which the water repellent sheet 22 and the silver filter 23 are attached is disassembled to disassemble the water repellent sheet 22 and The water-repellent sheet 22 and the silver filter 23 can be replaced simply by replacing the silver filter 23. Thereby, the water-repellent sheet 22 and the silver filter 23 which suppress the penetration | invasion of the obstructive component in the case part 11 can be easily replaced, without requiring many decomposition | disassembly operations. Furthermore, when replacing the entire sensor cap portion 21 to which the water repellent sheet 22 and the silver filter 23 are attached, it is not necessary to disassemble the sensor cap portion 21 to which the water repellent sheet 22 and the silver filter 23 are attached. The water repellent sheet 22 and the silver filter 23 can be replaced more easily.

  Further, in the present embodiment, when the sensor cap part 21 of the sensor cap member 20 is mounted on the case part 11 of the main body part 10, the pair of engagement grooves 12 b of the case part 11 and the pair of protrusions of the sensor cap part 21. When the part 221c is engaged with each other at predetermined engagement positions A1 and A2, the intake hole 21a is positioned at a position corresponding to the detection hole 13b. Thereby, since the detection target gas taken in from the intake hole 21a positioned at the position corresponding to the detection hole 13b can be reliably guided to the detection hole 13b, the detection target gas is reliably guided to the inside of the gas sensor 1. Can do. Thereby, even if it does not provide the suction device for forcibly taking in the air containing detection target gas from the intake hole 21a, detection target gas can be detected more correctly.

  In the present embodiment, the intake hole 21a of the sensor cap portion 21 is divided into the first region 121a and the second region 221a by the contact restricting portion 21d, and the pair of engaging grooves 12b of the case portion 11 and the sensor cap are divided. When the pair of protrusions 221c of the portion 21 are engaged with each other at predetermined engagement positions A1 and A2, the first region 121a and the second region 221a of the intake hole 21a respectively correspond to the detection holes 113b. It is configured to be positioned at a position corresponding to the position and the detection hole 213b. Thereby, since it can suppress that the water repellent sheet 22 and the silver filter 23 are contacted via the taking-in hole 21a of the sensor cap part 21 by the contact control part 21d, the water repellent sheet 22 and the silver filter 23 can be suppressed. Can be prevented from being damaged. Even if the contact restricting portion 21d is provided at a position where the intake hole 21a is divided into the first area 121a and the second area 221a, the first area 121a and the second area 221a of the intake hole 21a are respectively By being configured to be positioned at a position corresponding to the detection hole 113b and a position corresponding to the detection hole 213b, the detection target gas is less likely to be taken into the detection hole 13b (detection holes 113b and 213b) by the contact restricting portion 21d. Can be suppressed. Thereby, the detection target gas taken in from the first region 121a and the second region 221a of the take-in hole 21a can be reliably guided to the corresponding detection holes 113b and 213b.

  Further, in the present embodiment, the sensor cap portion 21 is disposed inside the sensor cap portion 21 so as to contact the case portion 11 in a state where the sensor cap portion 21 is attached to the case portion 11. A packing 26 for sealing the gap is provided. If comprised in this way, it can suppress that a disturbance component penetrate | invades into the inside of the case part 11 from between the sensor cap part 21 and the case part 11 with the packing 26. FIG. Thereby, it can suppress that the detection accuracy of the gas sensor 1 provided in the case part 11 falls.

  The embodiment disclosed this time should be considered as illustrative in all points and not restrictive. The scope of the present invention is shown not by the above description of the embodiment but by the scope of claims for patent, and further includes all modifications (modifications) within the meaning and scope equivalent to the scope of claims for patent.

  For example, in the said embodiment, although the example which attached the water-repellent sheet 22 and the silver filter 23 to the filter accommodating part 21b inside the sensor cap part 21 was shown, this invention is not limited to this. In the present invention, for example, activated carbon 327 may be attached to the inside of the sensor cap portion 21 in addition to the water repellent sheet 22 and the silver filter 323 as in a modification of the present embodiment shown in FIG. The activated carbon 327 has a function of suppressing the intrusion of a disturbing component into the gas sensor by adsorbing a disturbing component such as a gas other than the detection target gas. Further, the activated carbon 327 is disposed together with the silver filter 323 in a locking recess 25 b formed inside the annular filter holder 25. At that time, the activated carbon 327 is disposed in the locking recess 25b so that the activated carbon 327 is positioned on the X2 side and the silver filter 323 is positioned on the X1 side. In order to arrange the silver filter 323 in the locking recess 25b, the silver filter 323 is formed to have a smaller diameter than the silver filter 23 of the present embodiment. As a result, by providing the activated carbon 327, it is possible to more reliably remove interference components that are difficult to be decomposed or adsorbed by the silver filter 323 or the water repellent sheet 22. Further, even when the activated carbon 327 is newly provided, the members other than the silver filter can be made the same as the members when the activated carbon 327 is not provided (this embodiment), so that the sensor cap member 320 can be easily provided. It is possible to add activated carbon 327 to the surface. The silver filter 323 and the activated carbon 327 are examples of the “filter material” of the present invention.

  Further, as the filter material of the present invention attached to the inside of the sensor cap portion 21, in the above embodiment, an example using the water repellent sheet 22 and the silver filter 23 is shown. In the modified example of the above embodiment, activated carbon 327 is further added. Although the example used was shown, this invention is not limited to this. In the present invention, only one of a water repellent sheet, a silver filter, and activated carbon may be used as the filter material of the present invention attached to the inside of the sensor cap portion, or a water repellent sheet may be used without using a silver filter. Alternatively, only activated carbon may be used. Furthermore, you may use filter materials other than a water repellent sheet, a silver filter, and activated carbon as a filter material of this invention. At this time, the filter material needs to be a filter material capable of at least decomposing or adsorbing interference components other than the detection target gas. Moreover, the number of filter materials may be one or plural. A plurality of the same filter material may be used.

  Further, in the above embodiment, when the pair of projecting portions 221c are respectively engaged with the pair of engaging portions 122b at the predetermined engaging positions A1 and A2, the first region on the upper side of the intake hole 21a. 121a is positioned at a position corresponding to the upper detection hole 113b, and the lower second region 221a of the intake hole 21a is positioned at a position corresponding to the lower detection hole 213b. However, the present invention is not limited to this. In the present invention, when the sensor cap member is attached to the main body portion (case portion), the intake holes (first region and second region) may not be positioned at positions corresponding to the detection holes. That is, the contact restricting portion may be located at a position corresponding to the detection hole. At this time, the flow of the air containing the detection target gas to the detection hole is not hindered by providing a gap between the contact restriction portion and the detection hole so that the detection hole is not blocked by the contact restriction portion. It is necessary to.

  Moreover, in the said embodiment, although the example in which the intake hole 21a is divided | segmented into the 1st area | region 121a and the 2nd area | region 221a by the contact control part 21d was shown, this invention is not limited to this. In the present invention, the intake hole may be divided into three or more regions by the contact restricting portion. Further, by not providing the contact restricting portion, the intake hole may not be divided into a plurality of regions.

  Moreover, in the said embodiment, the example which provided the area | region (1st area | region 121a and 2nd area | region 221a) of two (same number) of the intake holes 21a corresponding to the two detection holes 13b (detection holes 113b and 213b), respectively. However, the present invention is not limited to this. In the present invention, the number of detection holes and the number of regions formed by dividing the intake holes may be different. At this time, it is preferable that the number of regions is larger than the number of detection holes, and regions corresponding to all the detection holes are provided.

  In the above embodiment, an example is shown in which the portable gas detector 100 is not provided with a suction device for forcibly taking in air containing the gas to be detected from the intake hole 21a. However, the present invention is not limited to this. I can't. In the present invention, the portable gas detector may be provided with a suction device.

DESCRIPTION OF SYMBOLS 1 Gas sensor 11 Case part 12b Engagement groove | channel (1st engagement part)
13b, 113b, 213b Detection hole 21 Sensor cap part 21a Intake hole 21d Contact restricting part 22 Water repellent sheet (filter material)
23, 323 Silver filter (filter material)
26 Packing (seal member)
100, 300 Portable gas detector 121a First region (region)
221a Second region (region)
221c Protruding part (second engaging part)
327 Activated carbon (filter material)
A1, A2 Predetermined engagement position

Claims (4)

A gas sensor for detecting a predetermined detection target gas;
A case portion in which the gas sensor is provided;
A sensor cap part comprising a single member that is detachably attached to the case part, including an intake hole for taking in the detection target gas;
A filter material that is attached to the inside of the sensor cap portion and suppresses the intrusion of the disturbing component into the case portion by at least decomposing or adsorbing the disturbing component, and
The sensor cap unit, viewed contains a filter accommodating portion for accommodating the filter member,
The gas sensor is a portable gas detector including a cover member that houses a detection element . A gas sensor for detecting a predetermined detection target gas;
A case portion in which the gas sensor is provided;
A sensor cap part that includes an intake hole for taking in the detection target gas and is detachably attached to the case part;
A filter material that is attached to the inside of the sensor cap portion and suppresses the intrusion of the disturbing component into the case portion by at least decomposing or adsorbing the disturbing component, and
The gas sensor has a detection hole for guiding the detection target gas taken in from the intake hole to the inside,
The case portion includes a first engagement portion,
The sensor cap portion includes a second engagement portion that engages with the first engagement portion,
When the sensor cap portion is attached to the case portion, the first engagement portion and the second engagement portion engage at a predetermined engagement position, so that the intake hole becomes the detection hole. and has, portable gas detector that is configured to be positioned to that circumferential position corresponding to. The sensor cap part further includes a contact restricting part that restricts the filter material from being contacted from outside through the intake hole,
The intake hole of the sensor cap part is divided into a plurality of regions by the contact restricting part,
Said detection hole of the gas sensor, with multiply provided, by which the first engaging portion and the second engaging portion is engaged at the predetermined engaging position, the areas of the intake hole These are each configured to be positioned at the circumferential positions corresponding to the plurality of detection holes. The portable gas detector according to claim 2.   A seal member disposed inside the sensor cap portion and sealing between the sensor cap portion and the case portion so that the sensor cap portion is in contact with the case portion in a state where the sensor cap portion is mounted on the case portion; The portable gas detector according to any one of claims 1 to 3, further comprising:

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