JP5489876B2 - Portable gas detector - Google Patents

Description

  The present invention relates to a portable gas detector.

In general, for example, in underground construction sites, tunnels, places where people enter, work areas, etc., there is a risk that dangerous gases such as carbon monoxide gas or hydrogen sulfide gas may be contained in the air of the environment. In many cases, there is a possibility that the air in the environmental atmosphere is in a dangerous state or in a dangerous state, such as when the oxygen gas concentration in the air may be lowered.
And when it becomes dangerous to humans due to the high concentration of dangerous gas contained in the air or low oxygen gas concentration, it is necessary to immediately know that In view of this demand, various types of portable gas detectors have been proposed.

  For example, a portable gas detector having a structure in which a dry battery is used as a driving power source and the dry battery is mounted by sliding the positive electrode with respect to the positive connection terminal while the negative electrode of the dry battery is in contact with the negative connection terminal. In a certain type, as a negative electrode connection terminal and a positive electrode connection terminal, for example, as shown in FIG. 14, a single metal wire is deformed, and the center of the curved battery is in contact with the electrode of the dry cell The thing of the structure which has the contact arm part 91 is used.

Thus, such portable gas detectors are used in an environment where flammable or explosive gas may occur due to the presence of an explosive atmosphere containing flammable gas or vapor. It is necessary that the structure itself does not become an ignition source, that is, a structure that satisfies the so-called explosion-proof specification. For example, a portable gas detector is housed in a wooden box and rotated at a predetermined rotational speed. For example, when vibration is applied to the portable gas detector, it is required that the portable gas detector is configured not to be in a non-conductive state due to, for example, detachment of a dry cell or damage to a connection terminal.
However, in the connection terminal 90 configured as described above, the axial movement of the dry cell due to vibration is absorbed mainly by the elastic deformation of the central contact arm portion 91, so when vibration is repeatedly applied to the portable gas detector, Since the load is repeatedly applied to the center contact arm portion 91, the center contact arm portion 91 may be broken, and there is a problem that the standard of the predetermined explosion-proof specification is not satisfied.
In addition, when an impact is applied to the portable gas detector, for example, by accidentally dropping the portable gas detector, the mounted battery will be displaced beyond the allowable displacement in the axial direction of the dry cell. As a result, the central contact arm portion 91 is deformed, and there is a problem that a contact failure between the dry battery and the connection terminal 90 may occur.

  The present invention has been made based on the above circumstances, and can reliably prevent the connection terminal for a dry cell from being deformed or broken even when an external impact is applied. It is an object of the present invention to provide a portable gas detector that can be configured to satisfy a predetermined explosion-proof specification.

The portable gas detector of the present invention is a portable gas detector in which a dry cell is used as a driving power source,
A positive electrode connection terminal and a negative electrode connection terminal are provided corresponding to the positive electrode and the negative electrode of the cylindrical dry battery to be mounted, and the positive electrode is slid with respect to the positive electrode connection terminal with the negative electrode of the dry battery in contact with the negative electrode connection terminal. A battery compartment in which the dry battery is mounted,
The negative electrode connection terminal comprises a conical coil spring,
In the conical coil spring, the positive electrode connection terminal has a distal end winding portion that contacts an end face of the positive electrode of the dry battery, and a winding axis thereof is relative to a winding axis of a proximal end winding portion excluding the distal end winding portion. It is made of a deformed product so that it can be inclined and stretched,
The positive electrode connection terminal is provided in the battery chamber in a posture in which the tip winding portion is inclined so as to approach the negative electrode connection terminal toward the front in the moving direction of the positive electrode of the dry battery when the dry battery is mounted. It is characterized by.

  In the portable gas detector of the present invention, the end portion of the tip winding portion of the positive electrode connection terminal is bent so as to extend along the moving direction of the positive electrode of the dry cell when the dry cell is mounted. Preferably it is.

  Furthermore, in the portable gas detector of the present invention, the plane on which the tip winding portion of the positive electrode connection terminal is located is inclined with respect to the plane perpendicular to the winding axis of the winding portion excluding the tip winding portion. It is preferable that the angle is in the range of 20 to 40 °.

Furthermore, in the portable gas detector according to the present invention, the battery chamber includes a plurality of cylindrical dry batteries arranged in series in a state in which the positive and negative electrodes of adjacent dry batteries are arranged in parallel so that they face each other in opposite directions. It is configured to be connected and attached,
The positive electrode connection terminal to which the positive electrode of one dry battery is electrically connected has a negative electrode connection terminal made of a conical coil spring to which the negative electrode of another dry battery adjacent to the one dry battery is electrically connected. It can be set as the structure integrally formed in the base end of the positive electrode connection terminal continuously.

According to the portable gas detector of the present invention, the cylindrical dry battery slides the positive electrode with respect to the positive electrode connection terminal in a state where the negative electrode is in contact with the negative electrode connection terminal made of a conical coil spring. In the mounted configuration, in the conical coil spring, the tip winding portion that contacts the end face of the positive electrode of the dry battery has a winding axis with respect to the winding axis of the winding portion excluding the tip winding portion. In a posture in which the positive electrode connection terminal that is deformed so as to extend in an inclined manner is inclined so as to approach the negative electrode connection terminal toward the front in the moving direction of the positive electrode of the dry battery when the tip winding part is attached to the dry battery. Because of the configuration provided in the room, basically, when mounting the dry battery, the peripheral edge of the end face of the positive electrode of the dry battery is the end in the winding axis direction of the tip winding portion of the positive electrode connection terminal. Therefore, for example, it is possible to reliably avoid the occurrence of contact failure due to the tip winding portion of the positive electrode connection terminal being bent under the peripheral surface portion of the positive electrode of the dry cell and being submerged. Can be reliably mounted in a state where proper electrical connection is achieved.
Moreover, even if vibration is applied to the portable gas detector, for example, the movement of the dry cell in the axial direction due to the vibration is absorbed by the displacement of the positive electrode connection terminal and the negative electrode connection terminal in the winding axis direction. Therefore, a sufficient amount of allowable displacement with respect to the axial direction of the dry battery can be secured, so that it is possible to reliably prevent problems such as breakage of the positive electrode connection terminal, and a predetermined explosion-proof specification. Satisfies the standard.

  In addition, the end portion of the tip winding portion of the positive electrode connection terminal is bent so as to extend in the radial direction along the moving direction of the positive electrode of the dry battery when the dry battery is mounted. Functions as a guide member, and the positive electrode of the dry battery is slid along the terminal portion, so that the winding end portion constituting the contact portion with the positive electrode of the dry battery bends and contacts with the slide movement of the positive electrode of the dry battery. It is possible to avoid the occurrence of a defect, and it is possible to more reliably attach the dry battery in a state where an appropriate electrical connection is achieved.

It is a top view which shows the structure in an example in the portable gas detector of this invention. It is a rear view which shows the structure of the portable gas detector shown in FIG. 1 in the state which removed the sensor chamber cover cover. It is a right view of the portable gas detector shown in FIG. It is the sectional view on the AA line in FIG. It is the elements on larger scale which expand and show a part of FIG. It is a top view which shows the structure of a gas detection unit. It is a block diagram which shows roughly the piping structure in the portable gas detector shown in FIG. It is a bottom view which shows the dry cell power supply unit in the portable gas detector shown in FIG. 1 in the state by which the battery chamber cover cover was made into the open state. It is sectional drawing which cut | disconnects and shows the structure of a dry cell power supply unit in the direction perpendicular | vertical to the longitudinal direction of a dry cell. FIG. 9 is an explanatory view showing, in an enlarged manner, an engaging portion between the battery chamber cover lid and the housing member in a state where the battery chamber cover lid is in an open state, and (A) an enlarged cross-sectional view taken along line BB in FIG. (B) It is an expanded sectional view in the CC line in FIG. It is a figure for demonstrating the mounting method of a dry cell, Comprising: (A) The explanatory view which shows the state with which the negative electrode of the dry cell was contact | connected to the negative electrode connection terminal, (B) It is explanatory drawing which shows the state with which the dry cell was mounted | worn. . It is the (A) front view and the (B) right side which show the structure of a positive electrode connection terminal. It is (A) front view and (B) bottom view which show the structure of the positive electrode connection terminal in which the negative electrode connection terminal was integrally formed. It is a perspective view which shows the outline of the structure in an example of the conventional connection terminal for dry cells.

Hereinafter, embodiments of the present invention will be described in detail.
FIG. 1 is a top view showing the configuration of an example of the portable gas detector of the present invention, and FIG. 2 is a rear view showing the configuration of the portable gas detector shown in FIG. 1 with the sensor chamber cover lid removed. 3 is a right side view of the portable gas detector shown in FIG. 1, FIG. 4 is a cross-sectional view taken along line AA in FIG. 1, and FIG. 5 is a partially enlarged view showing a part of FIG. is there.
The portable gas detector 10 has a box (heavy box) shape as a whole, and is detachably attached to the main unit 15 including the display unit 20 and the gas detection unit 40. For example, it is configured as a shoulder type that is used by being hung on an operator's shoulder by an appropriate mounting member. 1 and 3, reference numeral 11 denotes an operation button, 12 denotes, for example, a belt-like mounting member mounting portion, 13A denotes a gas introduction portion, 13B denotes a gas discharge portion, and 14 denotes a display portion.

The display unit 20 is provided with an upper surface side housing member 21 made of, for example, resin and having an opening at the lower side. A panel-like display mechanism (LCD) 35 is arranged at the center of the upper surface of the control circuit board 30.
In one side region (the left side region in FIG. 4) inside the upper surface side housing member 21, an acoustic chamber 25 that forms a square columnar acoustic space is formed, and the inner space of the acoustic chamber 25 is The upper surface side alarm sound formed on the upper surface of the upper surface side housing member 21 while communicating with the buzzer arrangement portion 43 in the gas detection unit 40 through the opening K formed in the lower wall 25B constituting a part of the acoustic chamber 25. The sound emission opening 23A and a slit-like back side alarm sound emission opening 23B formed on the back surface of the upper housing member 21 communicate with the outside.

On the upper surface of the lower wall 25B of the acoustic chamber 25, a waterproof sheet 26 having sound permeability is provided.
The waterproof sheet 26 is made of a porous film made of, for example, polypropylene, and is fixed to the upper surface of the lower wall 25B of the acoustic chamber 25 by, for example, bonding the outer peripheral edge portion thereof.

  In addition, a plurality of minute sound emission holes 28A each having an opening diameter smaller than the opening diameter of the sound emission opening 62 in the piezoelectric buzzer 60 described later are formed in the upper surface side alarm sound emission opening 23A. For example, a plate member 28 made of polycarbonate is provided so as to close the upper side alarm sound emitting opening 23A.

  The gas detection unit 40 includes a cylindrical lower surface side housing member 41 made of, for example, resin that is connected to the lower end of the upper surface side housing member 21 of the display unit 20 via a frame-shaped packing 16 and is detachably fixed. A buzzer arrangement portion 43 in which the piezoelectric buzzer 60 is arranged is formed at an upper portion inside the lower surface side housing member 41 at a position below the acoustic chamber 25 in the display unit 20.

As shown in FIG. 6, the piezoelectric buzzer 60 is a low-profile columnar member in which a piezoelectric vibrator (not shown) is disposed in a case 61 having a sound emitting port 62 that opens upward. The outer peripheral surface of the lower part of the case 61 is located at a diagonal position centered on the sound outlet 62 and is larger than the outer diameter of the positioning pin member 43B provided so as to extend in a direction perpendicular to the horizontal buzzer arrangement surface. A tongue-like support portion 63 having a support hole having an inner diameter is formed.
The piezoelectric buzzer 60 is placed on the buzzer arrangement surface 43 </ b> A in a state where the positioning pin member 43 </ b> B is inserted into the support hole of the tongue-like support portion 63 and the sound emission port 62 is positioned with respect to the acoustic chamber 25. The outer edge portion on the upper surface of the piezoelectric buzzer 60 is provided on the peripheral portion on the lower surface side of the opening portion 30A formed at a position facing the sound emission port 62 of the piezoelectric buzzer 60 in the control circuit board 30. It is pressed from above via a buffer member (cushion member) 31, and is thus supported on the buzzer arrangement surface 43 </ b> A so as to be able to be finely displaced in the horizontal surface direction and the vertical direction. With such a buzzer support structure, the vibration of the piezoelectric buzzer 60 itself is not suppressed, the sound pressure level of the alarm sound can be increased, and the piezoelectric buzzer 60 can be used even when an impact is applied. The impact is relieved by the minute displacement of the piezoelectric element, so that the energy generated in the piezoelectric buzzer 60 can be reduced and the standard of a predetermined explosion-proof specification can be satisfied.

  Further, a sensor board 58 is disposed inside the lower surface side housing member 41 so as to extend in a direction perpendicular to the control circuit board 30. For example, five gas sensors 50 </ b> A and 50 </ b> B are provided on the back side of the sensor board 58. , 50C, 50D, 50E are detachably held, sensor holders 46A, 46B, 46C, 46D, 46E, and a sensor holder 45 having a gas inlet 48A and a gas outlet 48B are formed. A gas suction pump 66 that sucks air in the ambient atmosphere from the outside and supplies it to each of the gas sensors 50A to 50E is disposed in the other side region (the right region in FIG. 6) on the front side of the gas, and gas suction is performed in the central region. A part of the gas flow path of air in the ambient atmosphere sucked by the pump 66 and supplied to each of the gas sensors 50A to 50E. Air reservoir portion for forming (space buffer) 44 is formed.

  An example of a combination of the gas sensors 50A to 50E is as follows. As the gas sensor 50A, a hydrogen sulfide gas detection gas sensor composed of a constant potential electrolytic gas sensor, and as the gas sensor 50B, a combustible gas such as a hydrocarbon gas composed of a catalytic combustion type gas sensor. The first combustible gas sensor for detection in the measurement range of% LEL (explosive lower limit concentration), the gas sensor 50C, a carbon monoxide gas detection gas sensor comprising a constant potential electrolytic gas sensor, and the gas sensor 50D as a heat conduction gas sensor As the second combustible gas sensor for detecting a combustible gas such as hydrocarbon gas in a volume% measurement range, the gas sensor 50E, an oxygen gas detection gas sensor composed of a galvanic cell type gas sensor can be exemplified. .

  As the gas suction pump 66, for example, a diaphragm pump driven by a motor is used. For example, the gas suction pump 66 has a performance capable of supplying air in an environmental atmosphere at a flow rate of 0.75 liter / min or more.

As shown in FIG. 7, the air reservoir 44 is sucked by the gas suction pump 66 from the gas inlet 13A through the dust filter 65 and supplied to each of the gas sensors 50A to 50E. The throttle part 68 is provided at a position downstream of the gas suction pump 66 at a position downstream of the air reservoir 44.
A pressure sensor 67 is connected to the air reservoir 44, and the exhaust pressure from the air reservoir 44 measured by the pressure sensor 67 is monitored. A decrease in the gas flow rate due to the occurrence of clogging or the deterioration of the gas suction pump 66 over time is detected.

  The dry battery power supply unit 80 is connected to the lower surface of the lower surface side housing member 41 constituting the gas detection unit 40 via the packing 18 and is detachably fixed, and is disposed in the upper surface side region of the housing member 81. A power supply circuit board 85 on which a power supply circuit (not shown) for supplying power to the main unit 15 via the limiting resistance element is formed, and a power supply provided on the upper surface side of the power supply circuit board 85. And a protection member 84 that protects the circuit board 85.

As shown in FIGS. 8 and 9, for example, three cylindrical batteries (for example, AA batteries (AA size)) 86A, 86B, 86C are connected to the housing member 81, and the positive and negative electrodes of adjacent ones are connected to each other. A battery chamber 81 </ b> A that opens in a downward direction and is connected in series while being arranged in parallel so as to face in the opposite direction is formed.
The battery chamber 81A has a receiving support portion 81B that supports each of the dry cells 86A, 86B, 86C in contact with an upper portion of the peripheral surface thereof, and electrodes of the respective dry cells on both end surfaces of each receiving support portion 81B. A positive electrode connection terminal and a negative electrode connection terminal are arranged at positions corresponding to.

  In the opening of the battery chamber 81A, the battery chamber cover lid 83 is in a closed position in which the battery chamber cover lid 83 is fixed in the closed state by the lid lock member 83B and, for example, the lower surface of the housing member 81 faces upward. A part of the outer surface of the lid 83 is provided so as to be openable and closable between an open state where it is in contact with a stopper portion 81D formed at the opening edge of the battery chamber 81A and maintained in a self-supporting state.

A method for mounting the battery chamber cover lid 83 on the housing member 81 will be described in detail. The battery chamber cover lid 83 is arranged at one end (left end in FIG. 4) in the direction in which the dry cells are arranged (direction perpendicular to the paper surface in FIG. 4). The pivot shaft 83A extends in the direction of the axis, and the pivot shaft 83A is engaged with a pair of engaging claws 81C formed on the housing member 81. As shown in FIG. When the external force F is applied in a direction in which the battery chamber cover lid 83 is further opened in a state in which 83 is in an open state (indicated by a thin line represented by a diameter thinner than the shape line in FIG. 10), By the “lever principle” using the stopper portion 81D as a fulcrum, the engagement between the pivot shaft 83A of the battery chamber cover lid 83 and the engaging claw portion 81C is released, and the battery chamber cover lid 83 is moved to the housing member 81. It has a configuration to leave Ri. Here, when the battery chamber cover lid 83 is in an open state, the opening angle θ of the battery chamber cover lid 83 with respect to the lower surface of the housing member 81 is, for example, 125 °.
With such a configuration, external force acts on the battery chamber cover lid 83 unexpectedly in a state where the battery chamber cover lid 83 is in an open state, for example, when a dry battery is replaced. Thus, it is possible to reliably avoid the occurrence of a situation such as damage to the dry battery power supply unit 80.

In the portable gas detector 10, each of the display unit 20, the gas detection unit 40, and the dry battery power supply unit 80 is provided with a protective cover 22, 42, 82 made of, for example, a conductive thermoplastic elastomer composition. In the state in which the protect covers 22, 42, 82 are mounted, the size of the continuous resin surface portion of the housing member exposed to the outside is regulated to a predetermined size, for example, 400 mm ² or less. It has sufficient and reliable explosion-proof properties.

  Thus, the battery chamber 81A in the dry battery power supply unit 80 is connected to each negative battery 86A (86B, 86C) with the negative electrode connected to the negative electrode connection terminal 89 as shown in FIG. The positive electrode 861 is slid (slid) with respect to the positive electrode connection terminal 88 provided so as to face the terminal 89.

The negative electrode connection terminal 89 in the dry battery power supply unit 80 is configured by, for example, a conical coil spring in which one metal wire is deformed.
As shown in FIG. 12, the positive electrode connection terminal 88 is a conical coil spring in which one metal wire is deformed, and a tip winding portion 88 </ b> A that contacts the end surface 862 of the end surface 862 of the positive electrode 861 of the dry battery. However, the winding axis C2 is formed by deformation so that the winding axis C2 extends obliquely with respect to the winding axis C1 of the proximal end winding part 88C excluding the distal end winding part 88A. The end of 88A is formed with a bent portion 88B which is bent and extends linearly so as to extend inclined at a different angle in the same direction as the inclined direction of tip winding portion 88A.

  The inclination angle of the winding axis C2 of the tip winding portion 88A in the positive electrode connection terminal 88 with respect to the winding axis C1 of the coil portion excluding the tip winding portion 88A, that is, the tip winding portion 88A in the positive electrode connection terminal 88 is located. The inclination angle α of the flat surface with respect to the plane perpendicular to the winding axis C1 of the base end winding portion 88C excluding the front end winding portion 88A (the plane on which the base end winding portion 88C is located) is, for example, 20 to 40 °. It is preferable that the size is within the range. If the inclination angle α is too small, the positive electrode of the dry battery 86A (86B, 86C) is likely to be caught on the positive electrode connection terminal 88, making it difficult to attach the dry battery 86A (86B, 86C). When the magnitude of the inclination angle α is excessive, the dry battery 86A (86B, 86C) is repelled by the spring elasticity of the positive electrode connection terminal 88, making it difficult to attach the dry battery 86A (86B, 86C).

  This positive electrode connection terminal 88 is connected to the negative electrode of the dry battery as the inclination direction of the tip winding portion 88A moves forward of the positive electrode of the dry battery when the dry battery is mounted (for example, the direction toward the back side of the page in FIG. 8). While being inclined so as to approach the negative electrode connection terminal side to be contacted, the bent portion 88B extends along the moving direction of the positive electrode of the dry battery when the dry battery is mounted, and the winding axis C1 of the base end winding portion 88C is the negative electrode The battery terminal 81 </ b> A is disposed in a posture positioned coaxially with the winding axis of the connection terminal.

In this example, for example, the positive electrode connection terminal 88 that is in electrical contact with the positive electrode of the dry battery 86A mounted in the center of the battery chamber 81A is one dry battery 86B adjacent to the dry battery 86A as shown in FIG. A negative electrode connection terminal 89 made of a conical coil spring that is in electrical contact with the negative electrode is continuously formed integrally with the terminal end of the proximal winding portion 88C.
In addition, a positive electrode connection terminal that is in electrical contact with the positive electrode of the other dry battery 86C adjacent to the dry battery 86A mounted in the center of the battery chamber 81A has a similar configuration. Three dry batteries 86A, 86B, 86C are connected in series.

  The positive electrode connection terminal 88 and the negative electrode connection terminal 89 have a magnitude of the amount of displacement in the axial direction of the dry cell by the positive electrode connection terminal that is in contact with the positive electrode of one dry cell and the negative electrode connection terminal that is in contact with the negative electrode of the dry cell. For example, the wire diameter of the metal wire is φ0.6 mm, the number of coil turns of the positive electrode connection terminal 88 is 2.5, and the tip winding portion 88A is, for example, The outer diameter is φ4 mm, the maximum length in the winding axis C1 direction is 3.5 mm, the number of coil turns of the negative electrode connection terminal 89 is 4.5, and the length in the winding axis direction is 8.6 mm. With such a configuration, individual differences in the lengthwise dimension of the dry battery itself can be reliably absorbed, and the dry battery can be properly attached.

  The method for mounting the dry cell 86A (86B, 86C) in the portable gas detector 10 will be specifically described. The negative electrode of the dry cell 86A (86B, 86C) is compressed and the negative electrode connection terminal 89 is compressed in the winding axis direction. In the state of being in contact with each other, the peripheral edge portion of the end face 862 of the positive electrode 861 of the dry battery 86A (86B, 86C) is brought into contact with the edge in the winding axis direction of the distal end winding portion 88A of the positive electrode connection terminal 88. When the positive electrode 861 of (86B, 86C) is slid to guide the positive electrode 861 of the dry battery 86A (86B, 86C) along the bent portion 88B, the tip winding portion 88A of the positive electrode connection terminal 88 is changed. While being rotated, it is compressed in the winding axis direction, so that the end surface in the winding axis direction of the tip winding portion 88A of the positive electrode connection terminal 88 is dry battery 8. A (86B, 86C) are Taise' the end face 862 in the positive electrode 861, the battery 86A (86B, 86C) are electrically connected.

In this portable gas detector 10, when air in the environmental atmosphere is sucked and introduced by the gas suction pump 66 through the dust filter 65 from the gas inlet 13 </ b> A, the air is stored via the air reservoir 44 and the throttle 68. The gas to be detected is sequentially supplied to each of the gas sensors 50A to 50E, and the type and concentration of the detected gas are displayed on the display unit 14, and the concentration of one of the detection target gases is a reference value. Is detected, an alarm operation signal is issued, whereby the piezoelectric buzzer 60 is activated.
For example, in the case of oxygen gas (O ₂ gas), the reference value is, for example, 18.0% by volume (vol%), and an alarm operation signal is issued when the reference value is lower than that. The reference value is, for example, 10% LEL (gas concentration with respect to the lower explosion limit concentration) when the detection target gas is hydrocarbon gas (HC gas), and when the detection target gas is carbon monoxide gas (CO gas). For example, it is 25 ppm, and in the case of hydrogen sulfide gas (H ₂ S gas), for example, it is 10 ppm. When the reference value is exceeded, an alarm operation signal is issued.

Thus, according to the portable gas detector 10 described above, the cylindrical dry battery 86A (86B, 86C) has the negative electrode in contact with the negative electrode connection terminal 89 made of a conical coil spring, and the positive electrode 861. In the configuration in which the battery is slid with respect to the positive electrode connection terminal 88, the conical coil spring contacts the positive electrode 861 within the surface area of the end surface 862 of the positive electrode 861 of the dry battery 86A (86B, 86C). The distal end winding portion 88A is deformed so that the winding axis C2 extends with an inclination with respect to the winding axis C1 of the proximal end winding portion 88C excluding the distal end winding portion 88A. 88 approaches the negative electrode connection terminal 89 toward the front in the moving direction of the positive electrode 861 when the tip winding portion 88A is mounted with the dry battery 86A (86B, 86C). By being configured to be inclined and provided in the battery chamber 81A, basically, when the dry battery 86A (86B, 86C) is mounted, the positive electrode 861 of the dry battery 86A (86B, 86C) is used. Since the peripheral edge portion of the end surface can be brought into contact with the end edge in the winding axis direction of the tip winding portion 88A of the positive electrode connection terminal 88, for example, the tip winding portion 88A of the positive electrode connection terminal 88 is made of a dry battery 86A (86B, 86C), it is possible to reliably avoid the occurrence of poor contact due to bending under the peripheral surface portion of the positive electrode 861 and entering the battery 86A (86B, 86C) in a state where proper electrical connection is achieved. It can be installed securely.
Moreover, even when vibration is applied to the portable gas detector 10, the axial movement of the dry battery 86 </ b> A (86 </ b> B, 86 </ b> C) due to the vibration is the winding axis of the positive electrode connection terminal 88 and the negative electrode connection terminal 89. This is absorbed by the displacement in the direction, and a sufficient amount of allowable displacement with respect to the axial direction of the dry battery 86A (86B, 86C) can be secured, so that a problem such as breakage of the positive electrode connection terminal 88 occurs. This can be surely prevented and satisfies the standard of a predetermined explosion-proof specification.

  Further, the end of the tip winding portion 88A of the positive electrode connection terminal 88 is bent so as to extend in the radial direction along the moving direction of the positive electrode of the dry cell 86A (86B, 86C) when the dry cell 86A (86B, 86C) is mounted. Thus, the bent portion 88B extending linearly is formed, so that the bent portion 88B functions as a guide member, and the positive electrode 861 of the dry battery 86A (86B, 86C) slides along the bent portion 88B. Therefore, the tip winding portion 88A constituting the contact portion of the dry battery 86A (86B, 86C) with the positive electrode 861 is bent so as to be displaced with the slide movement of the positive electrode of the dry battery 86A (86B, 86C), resulting in poor contact. The battery 86A (86B, 86C) is more reliably installed in a state where proper electrical connection is achieved. It can be.

As mentioned above, although embodiment of this invention was described, this invention is not limited to said embodiment, A various change can be added.
For example, the number and size of the dry batteries constituting the dry battery power supply unit are not particularly limited, and the positive electrode connection terminal and the negative electrode connection terminal do not need to be integrally formed.
The positive electrode connection terminal in the above example is configured such that the entire leading edge winding portion is inclined, but a part of the tip winding portion may be deformed in a predetermined inclination state.
In addition, the portable gas detector of the present invention may be used by being mounted on the body with an appropriate mounting tool, or may be used in a state of being placed on a horizontal plane in the detection target space, for example.

DESCRIPTION OF SYMBOLS 10 Portable gas detector 11 Operation button 12 Mounting member attachment part 13A Gas introduction part 13B Gas discharge part 14 Display part 15 Main unit 16 Packing 18 Packing 20 Display unit 21 Upper surface side housing member 22 Protect cover 23A Upper surface side alarm sound Sound emission opening 23B Rear side alarm sound emission opening 25 Acoustic chamber 25B Lower wall K Opening 26 Waterproof sheet 28 Plate member 28A Micro sound emission hole 30 Control circuit board 30A Opening 31 Buffer member (cushion member)
35 Panel display (LCD)
40 Gas detection unit 41 Lower surface side housing member 42 Protect cover 43 Buzzer arrangement portion 43A Buzzer arrangement surface 43B Positioning pin member 44 Air reservoir (buffer space portion)
45 Sensor holder 46A to 46E Sensor holding part 48A Gas introduction part 48B Gas discharge part 50A to 50E Gas sensor 58 Sensor substrate 60 Piezoelectric buzzer 61 Case 62 Sound outlet 63 Tongue piece support part 65 Dustproof filter 66 Gas suction pump 67 Pressure sensor 68 Aperture part 80 Dry battery power supply unit 81 Housing member 81A Battery chamber 81B Receiving support part 81C Engaging claw part 81D Stopper part 82 Protect cover 83 Battery chamber cover cover 83A Pivot shaft 83B Cover lock member 84 Protection member 85 Power supply circuit board 86A, 86B , 86C Dry cell 861 Positive electrode 862 End face 88 Positive electrode connection terminal 88A Tip winding part 88B Bending part 88C Base end winding part 89 Negative electrode connection terminal 90 Connection terminal 91 Central contact arm part

Claims (4)

A portable gas detector using a dry cell as a power source for driving,
A positive electrode connection terminal and a negative electrode connection terminal are provided corresponding to the positive electrode and the negative electrode of the cylindrical dry battery to be mounted, and the positive electrode is slid with respect to the positive electrode connection terminal with the negative electrode of the dry battery in contact with the negative electrode connection terminal. A battery compartment in which the dry battery is mounted,
The negative electrode connection terminal comprises a conical coil spring,
In the conical coil spring, the positive electrode connection terminal has a distal end winding portion that contacts an end face of the positive electrode of the dry battery, and a winding axis thereof is relative to a winding axis of a proximal end winding portion excluding the distal end winding portion. It is made of a deformed product so that it can be inclined and stretched,
The positive electrode connection terminal is provided in the battery chamber in a posture in which the tip winding portion is inclined so as to approach the negative electrode connection terminal toward the front in the moving direction of the positive electrode of the dry battery when the dry battery is mounted. A portable gas detector.   2. The portable gas according to claim 1, wherein an end portion of the tip winding portion of the positive electrode connection terminal is bent so as to extend along a moving direction of the positive electrode of the dry battery when the dry battery is mounted. Detector.   The inclination angle of the plane where the tip winding portion of the positive electrode connection terminal is located with respect to the plane perpendicular to the winding axis of the winding portion excluding the tip winding portion is in the range of 20 to 40 °. The portable gas detector according to claim 1 or 2.   The battery chamber is configured in such a manner that a plurality of cylindrical dry batteries are connected in series with a positive electrode and a negative electrode of adjacent dry batteries arranged in parallel so that they face each other in opposite directions. The positive electrode connection terminal to which the positive electrode of the dry battery is electrically connected is connected to the negative electrode connection terminal made of a conical coil spring to which the negative electrode of another dry battery adjacent to the one dry battery is electrically connected. The portable gas detector according to any one of claims 1 to 3, wherein the portable gas detector is integrally formed continuously with a base end of the connection terminal.

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