JP7203886B2 - detector - Google Patents

Description

TECHNICAL FIELD The present invention relates to a portable detection device for detecting substances to be detected such as smoke particles contained in air sucked from a nozzle member.

High-sensitivity smoke detectors capable of detecting fine smoke are installed in computer rooms where servers and the like are installed and in clean rooms in semiconductor manufacturing facilities and the like. A highly sensitive smoke detector sucks air from a sampling pipe installed in a surveillance area, optically detects particles floating in the sucked air using a laser beam, and detects if the number of particles exceeds a predetermined number. output an alarm.

In addition to such stationary smoke detectors, portable smoke detectors are also known. A portable smoke detector is brought into a surveillance area and used, and has a nozzle section for sucking air and a body section for detecting smoke concentration in the air sucked from the nozzle section. The operator holds the main body of the portable smoke detection device, or fixes it to the body with a shoulder strap or the like, and moves while holding the nozzle in hand. Then, by directing the nozzle portion to various locations, it is possible to specify the locations where smoke is generated. As such a smoke detection device, for example, there is one disclosed in Patent Document 1.

Japanese Patent Application No. 2014-182803

In a portable smoke detection device, the nozzle section is generally shaped like a long and narrow pipe with an opening at the tip. In this case, when detecting smoke in a surveillance area, the tip of the elongated nozzle section is directed to various locations to suck air from the opening.

Locations where smoke may be generated in the monitored area include, for example, computers and manufacturing equipment, pipes installed in rooms, and ceiling spaces in rooms. In a simple pipe-shaped nozzle, the suction point is only the opening at the tip, so it takes time and effort to direct the opening of the nozzle to each point where smoke may be generated. . In addition, in order to point the nozzle toward a high place such as a ceiling, the user must hold the nozzle high by hand for a long time, which imposes a heavy burden on the operator. Furthermore, it was difficult to detect smoke in hard-to-reach places, such as deep inside narrow gaps. Also, a gas detection device or the like in which the substance to be detected is a gas has the same problem when it is made portable.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a detection device capable of improving the work efficiency of detecting a substance to be detected and facilitating the detection work.

In order to solve the above problems, a detection device according to the invention of claim 1 includes a suction port for sucking air in a monitoring area,
a detection unit that detects a substance to be detected contained in the air sucked from the suction port;
a concentration display unit for displaying the concentration of the substance to be detected detected by the detection unit in a predetermined display range;
a control unit that controls the concentration display unit;
The control unit changes the detection sensitivity of the substance to be detected in the detection unit by switching the flow velocity of the air sucked from the suction port according to the concentration of the substance to be detected detected by the detection unit, When the detection sensitivity of the substance to be detected is changed to high sensitivity by switching to increase the flow velocity of the air to be sucked, the display range of the concentration display section is switched to a range of fine numerical values, When the detection sensitivity of the substance to be detected is changed to low sensitivity by switching to reduce the air flow velocity, the display range of the concentration display section is switched to a range of larger numerical values, and the concentration display section displays the detection. It is characterized by displaying the concentration of the substance to be detected detected by the unit.

Further, the detection device according to the invention of claim 2 includes a suction fan for sucking air in the monitoring area from the suction port,
an airflow sensor capable of measuring the flow velocity of the air sucked from the suction port;
The control unit controls the suction fan based on the flow velocity of the sucked air measured by the airflow sensor and the detection state of the substance to be detected by the detection unit, thereby causing suction from the suction port. It is characterized by switching the flow velocity of the air .

According to the detection device of the present invention, it is possible to improve the work efficiency of detection of a substance to be detected and facilitate the detection work.

It is a front view of the smoke detector in this embodiment. It is a top view of a main-body part. It is a bottom view of a main-body part. It is an enlarged view of an alarm display part. It is a top view of a nozzle part. 1 is a block diagram showing the configuration of a smoke detection device; FIG. It is a front view of a nozzle portion and a front view of a nozzle member that can be attached to the nozzle portion. FIG. 4 is a perspective view of the U-shaped nozzle member in use. FIG. 4 is a perspective view of the T-shaped nozzle member in use. It is sectional drawing of a 1st pipe member and a 2nd pipe member. FIG. 4 is a cross-sectional view of the bellows extendable nozzle member in a contracted state toward the tip of the bellows portion. FIG. 4 is a cross-sectional view of the bellows extendable nozzle member in a state of being stretched, from the tip side of the bellows portion; It is a front view near the tip of a U-shaped nozzle member provided with a wheel member. It is a front view near the tip of a T-shaped nozzle member provided with a wheel member. It is a front view of the smoke detection apparatus of a 2nd form. FIG. 4 is a front view when the center of gravity position of the housing is adjusted; FIG. 4 is an exploded view of a nozzle portion attachable to a linear nozzle member;

An embodiment of the present invention will be described in detail with reference to the drawings. In this embodiment, a smoke detection device in which the substance to be detected is smoke will be described. The smoke detection device of this embodiment is portable, and is used by a worker to hold it by hand or fix it to his/her body, move it within a monitoring area, and identify the location where smoke is generated. FIG. 1 shows a front view of a smoke detector according to this embodiment. As shown in this figure, the smoke detection device is constructed by connecting a body portion 1 and a nozzle portion 2 with a hose member 3 .

The main body 1 has a main body housing 10 formed in a box shape, and a main body handle 11 that can be held by hand is provided on the upper surface thereof. An alarm display section 12 for displaying the level of smoke concentration is arranged on the front of the main body housing 10 . A hose connection portion 15 for connecting the hose member 3 is formed on the side surface of the main body housing 10 .

2 shows a plan view of the main body 1, and FIG. 3 shows a bottom view of the main body 1. As shown in FIG. A power switch 13 and a wind speed changeover switch 32a are arranged on the upper surface of the main body housing 10 in addition to the main body handle 11 described above. The power switch 13 can turn on/off the power supply in the smoke detection device. The air velocity selector switch 32 a can switch the flow velocity of the air sucked by the nozzle portion 2 . Further, an exhaust port 16 for exhausting the air sucked from the nozzle portion 2 is arranged on the bottom surface of the main body housing 10 .

FIG. 4 shows an enlarged view of the alarm display section 12. As shown in FIG. The alarm display unit 12 has a caution light, a warning light, and a warning light corresponding to the detected increase in smoke density. It also has a power supply light indicating power supply, a fault indicator light indicating the occurrence of a fault, and a suction check light indicating clogging of the suction system. Further, the alarm display unit 12 is also provided with a reset switch 14 that is operated when an error occurs in the smoke detection device to restore the normal state.

As shown in FIG. 1, the nozzle section 2 has a box-shaped nozzle section housing 20 . A hose connection portion 21 for connecting the hose member 3 from the main body portion 1 is formed in the nozzle portion housing 20 . A nozzle connection portion 22 is provided on the surface opposite to the surface on which the hose connection portion 21 of the nozzle housing 20 is provided, and a nozzle member can be attached and detached there. Although the nozzle member can be selected from a plurality of types, a straight nozzle member 40 is attached in FIG. The linear nozzle member 40 has a suction port 42 at its tip. Further, inside the linear nozzle member 40, an airflow sensor 25 capable of measuring the flow velocity of the sucked air is provided.

FIG. 5 shows a plan view of the nozzle portion 2. As shown in FIG. A nozzle handle 23 is provided on the upper surface of the nozzle housing 20 so that it can be held by hand. The main body handle portion 11 of the main body housing 10 can be held with one hand, and the nozzle handle portion 23 of the nozzle housing 20 can also be held with one hand. and the nozzle part 2 with the other hand.

A smoke density display section 24 is arranged on the upper surface of the nozzle housing 20 so as to be aligned with the nozzle grip section 23 . The smoke density display section 24 is a bar graph display section, and can display the detected smoke density in real time. The smoke density display unit 24 is not limited to a bar graph type display, and may be in another form such as a numerical display of smoke density, an indicator display, or the like. Further, the smoke density display section 24 may be provided with a switch for switching the range of displayed smoke density or a volume switch for continuously changing the range.

Next, the internal configuration of the smoke detector will be described. FIG. 6 shows a block diagram showing the configuration of the smoke detection device. As shown in this figure, the main body includes a control section 30 for controlling the smoke detection device, a smoke detection unit 31 for detecting smoke concentration, a suction unit 32 for sucking air, and a power source for the smoke detection device. and a power supply unit 34 that supplies the The operation of the smoke detection unit 31 and the suction unit 32 is controlled by the controller 30 . The power supply unit 34 consists of a rechargeable battery.

The power switch 13 , the reset switch 14 , the alarm display section 12 and the transmission section 33 are connected to the control section 30 . When the power switch 13 is turned on from off, power is supplied from the power supply unit 34 to each unit, and the control unit 30, the smoke detection unit 31, the suction unit 32, etc. are put into operation. The transmission section 33 transmits the smoke density information detected by the smoke detection unit 31 to the smoke density display section 24 of the nozzle section 2 .

Further, the control unit 30 is connected to the wind speed changeover switch 32a, the airflow sensor 25, and the sound output unit 26 including a speaker capable of outputting sound. An audio signal is output from the control unit 30 according to the status such as normal, caution, warning, alarm, or failure, and the audio output unit 26 sounds a buzzer or outputs audio based on the audio signal. The wind speed changeover switch 32 a can switch the suction strength of the suction unit 32 via the control section 30 . Thereby, the flow velocity of the air sucked from the suction port 42 can be changed.

The range of smoke density displayed on the smoke density display section 24 may be automatically switched by the control section 30 along with the switching of the wind speed changeover switch 32a. For example, when the wind speed selector switch 32a is operated to increase the flow speed of the air sucked from the suction port 42, smoke can be detected with higher sensitivity. also change to a finer range of numbers. Conversely, when the flow velocity of the air sucked from the suction port 42 is decreased, the smoke density display section 24 is changed to a range of larger numerical values. As a result, the range of the smoke density display section 24 can be automatically set appropriately.

The smoke detection unit 31 draws the air sucked through the nozzle part 2 into the lead-in pipe, and forms a laser light image on the airflow flowing through the lead-in pipe to form a smoke detection point of about 1 micrometer. Scattered light generated when smoke particles pass through this smoke detection point is received by a photodiode arranged parallel to the direction of the electric field component E of the laser light, and a detection pulse is output and counted. Minute smoke density can be detected. Information on smoke concentration detected by the smoke detection unit 31 is sent to the control section 30 . The control unit 30 transmits smoke concentration information to the smoke concentration display unit 24 of the nozzle unit 2 via the transmission unit 33, and causes the smoke concentration display unit 24 to display information corresponding to the smoke concentration detected by the smoke detection unit 31. be able to.

The suction unit 32 has a suction fan inside, so that air can be sucked from the suction port 42 of the nozzle portion 2 . Air sucked from the suction port 42 is taken into the smoke detection unit 31 of the main body 1 through the hose member 3 . The air discharged from the smoke detection unit 31 is discharged outside from the discharge port 16 of the main body 1 .

The airflow sensor 25 provided inside the linear nozzle member 40 measures the flow velocity of the air inside the linear nozzle member 40 while the air is being sucked by the suction unit 32 and transmits the information to the control section 30 . As a result, the controller 30 can grasp the switching state of the wind speed changeover switch 32a and the fact that air is not being sucked. If the flow velocity of the air does not change or if it is detected that the air is not being sucked in spite of the operation of the wind speed changeover switch 32a, the control unit 30 causes the alarm display unit 12 to indicate that a fault has occurred. Along with the display, the sound output unit 26 generates a sound indicating the occurrence of a failure.

Further, based on the flow velocity of the air detected by the airflow sensor 25, the control unit 30 can control the suction fan and adjust the range of the smoke density display unit 24. FIG. Control of the suction fan and adjustment of the range of the smoke density display section 24 are performed as follows. First, the suction fan is controlled so that the flow velocity of the air detected by the airflow sensor 25 increases. At this time, the amount of suction is large, so even if the amount of smoke is small, it is in a high-sensitivity state in which detection is possible. Further, in this state, by setting the smoke density display section 24 to a fine range of numerical values, the smoke density display section 24 can appropriately display detection of a slight amount of smoke.

In the high-sensitivity state, a large amount of air is sucked, disturbing the flow of air around the suction port 42, which may make it difficult to accurately identify the location where smoke is generated. Therefore, when smoke is detected in the high sensitivity state, the control unit 30 controls the suction fan so that the flow velocity of the air detected by the airflow sensor 25 becomes small, thereby setting the low sensitivity state. In this state, by setting the smoke density display section 24 to a range of large numerical values, the place where smoke is generated can be accurately specified by the smoke density display section 24 .

Although the airflow sensor 25 is provided inside the linear nozzle member 40 in this embodiment, it is not limited to this and can be provided in the air flow path inside the main body housing 10 . For example, the airflow sensor 25 can be arranged immediately before the smoke detection unit 31 .

The power supply section 34 is connected to the power supply circuit section 35 . The power supply circuit unit 35 can be connected to an AC plug that can be connected to an AC outlet, and by inputting 100 volts AC, can convert it into a predetermined DC voltage and output it to the power supply unit 34 . As a result, power is input from the power supply circuit unit 35 to the power supply unit 34, and the power supply unit 34 is charged.

Next, the nozzle member will be explained. 7 shows a front view of the nozzle portion 2 and a front view of a nozzle member that can be attached to the nozzle portion 2. FIG. As described above, the nozzle member can be attached and detached to and from the nozzle connecting portion 22 of the nozzle portion 2 . A plurality of types of nozzle members with different shapes are prepared. Threads are formed on the outer peripheral surface of the nozzle connection portion 22, and the threads formed on the inner peripheral surface of each nozzle member on the proximal end side can be screwed into the nozzle connection portion 22, so that the nozzle The member is detachable. However, the attachment/detachment structure of the nozzle member is not limited to this, and another structure such as a fitting structure may be used.

The nozzle members include a linear nozzle member 40 shown in FIG. 1 and the like, a U-shaped nozzle member 45 having a U-shaped tip, and a T-shaped nozzle member 50 having a T-shaped tip. Also, a multi-stage telescopic nozzle member 60 whose length can be expanded and contracted, and a bellows telescopic nozzle member 70 whose length can be expanded and contracted are prepared. However, it is sufficient that two or more types of nozzle members are prepared as options, and nozzle members having shapes other than these may be prepared.

The linear nozzle member 40 is composed of a hollow pipe portion 41 as a whole and has an open tip, which serves as a suction port 42 for sucking air. The linear nozzle member 40 is a nozzle member normally attached to the nozzle part 2, and can suck air regardless of the location by directing the suction port 42 at the tip.

The U-shaped nozzle member 45 has a pipe-shaped root portion 46 , and a U-shaped portion 47 communicating with the root portion 46 is formed at the tip of the root portion 46 . Both end surfaces of the U-shaped portion 47 are closed, and a plurality of suction ports 48 are formed in the U-shaped portion 47 along its length direction. The suction ports 48 are arranged so as to face the side of the area surrounded by the U-shaped portion 47, that is, the inner peripheral side.

FIG. 8 shows a perspective view of the U-shaped nozzle member 45 in use. As shown in this figure, the U-shaped nozzle member 45 is suitable for detecting the presence or absence of smoke generation in the piping 80 within the monitoring area. When the U-shaped part 47 of the U-shaped nozzle member 45 is arranged so as to straddle the pipe 80 from below, the suction ports 48 formed in the U-shaped part 47 are all arranged so as to face the inside. Therefore, it is in a state of facing the surface of the pipe 80 . By moving the U-shaped portion 47 in the longitudinal direction of the pipe 80 in this state, when smoke is generated from the pipe 80, the position can be easily specified. Note that the U-shaped nozzle member 45 can be used not only for the pipe 80 but also for smoke detection at other locations.

The T-shaped nozzle member 50 has a root portion 51 formed in a pipe shape, and a laterally extending portion 52 extending laterally at the tip of the root portion 51 . Since the laterally extending portion 52 extends from the tip of the root portion 51 to both sides, the tip portion of the root portion 51 and the laterally extending portion 52 form a T-shape at the tip of the T-shaped nozzle member 50. do. The end surface of the laterally extending portion 52 is closed, and the laterally extending portion 52 is formed with a plurality of suction ports 53 along its length direction. All of the suction ports 53 are arranged so as to face the tip side of the T-shaped nozzle member 50 .

FIG. 9 shows a perspective view of the T-shaped nozzle member 50 in use. The T-shaped nozzle member 50 is suitable for detecting the presence or absence of smoke on the ceiling surface in the monitored area. When the laterally extending portion 52 of the T-shaped nozzle member 50 is brought close to the ceiling surface from below, the suction ports 53 of the laterally extending portion 52 are all provided on the distal end side, so that they face the ceiling surface. becomes. In this state, by moving the side extending portion 52 in the plane direction of the ceiling surface, if smoke is generated from the ceiling surface or smoke is generated or stays in the upper space of the ignition place. can be easily identified. Note that the T-shaped nozzle member 50 can be used not only for the ceiling surface but also for smoke detection at other locations.

In the T-shaped nozzle member 50 described here, the side extending portion 52 extends from the tip of the base portion 51 toward both sides, but the side extending portion 52 extends only to one side, and the tip portion The shape may be substantially L-shaped.

The multi-stage telescopic nozzle member 60 has a first pipe member 61 and a second pipe member 62, a third pipe member 63 and a fourth pipe member 64, which are pipe-shaped members, respectively, on the root side, that is, the nozzle of the nozzle housing 20. They are connected in order from the connecting portion 22 side so as to be continuous in the length direction, and are configured as one pipe. Each pipe member has a different diameter, the second pipe member 62 is in the hollow interior of the first pipe member 61, the third pipe member 63 is in the hollow interior of the second pipe member 62, and the fourth pipe member 64 is in the third pipe member. 63 can be entered respectively, whereby the length of the multi-stage telescopic nozzle member 60 can be changed. The tip of the fourth pipe member 64 arranged on the tip side serves as the suction port 65 .

FIG. 10 shows cross-sectional views of the first pipe member 61 and the second pipe member 62 . One end surface of the first pipe member 61 has a small-diameter opening 61a. Also, the other end surface of the first pipe member 61 has an opening 61b that approximately matches the outer diameter of the second pipe member 62 . One end of the second pipe member 62 is arranged in the hollow interior of the first pipe member 61, and an opening 62a is formed in the end face. A portion of the second pipe member 62 disposed inside the hollow interior of the first pipe member 61 is formed with a projecting portion 62b that protrudes in the radial direction and substantially fits the inner diameter of the first pipe member 61. are doing. The outer diameter of the protrusion 62b is larger than the opening 62a of the first pipe member 61, so that when the second pipe member 62 is extended, the protrusion 62b extends from the opening 62a of the first pipe member 61. You can't get out, you can stop in that position. Also, the second pipe member 62 can be slid with respect to the first pipe member 61 and stored in the hollow interior, as indicated by the dashed line in the figure. The end of the second pipe member 62 on the projecting portion 62b side contacts the end surface of the first pipe member 61 on the opening 61a side, and can be prevented from moving any further.

The second pipe member 62 and the third pipe member 63 and the third pipe member 63 and the fourth pipe member 64 are also connected with the same structure. As a result, each pipe member can be accommodated in an adjacent pipe member having a larger diameter, so that the length of the multistage telescopic nozzle member 60 can be arbitrarily expanded or contracted. Moreover, since the hollow interior of each pipe member communicates with each other in the longitudinal direction by the opening, air can be reliably sucked.

The structure of the multistage telescopic nozzle member 60 is not limited to that shown in FIG. For example, a structure in which a plug whose diameter changes as it rotates may be provided at the end of the second pipe member 62 that is to be housed in the hollow interior of the first pipe member 61 . In this case, the second pipe member 62 can be expanded or contracted to an arbitrary position with respect to the first pipe member 61 , and the second pipe member 62 can be rotated in this state to change the diameter of the plug within the hollow interior of the first pipe member 61 . Then, the second pipe member 62 is fixed to the first pipe member 61 . By rotating the second pipe member 62 in the opposite direction, the diameter of the plug is reduced, and the second pipe member 62 can be moved in the longitudinal direction again. A similar structure can be provided for the third pipe member 63 and the fourth pipe member 64 as well. Also, the structure of the multi-stage telescopic nozzle member 60 may be any other structure as long as each pipe member can be arbitrarily expanded and contracted and fixed. The number of pipe members in the multistage telescopic nozzle member is not limited to four, as long as it is two or more.

In the structure of FIG. 10 , a suction port 65 is formed at the tip of the multistage telescopic nozzle member 60 . In this case, since there is only one suction port 65, the amount of air sucked increases, so smoke can be detected more precisely. On the other hand, the opening formed in the end face of each pipe member on the tip side may be formed with a notch with a larger diameter in the circumferential direction, and the suction port may be formed in the end face of each pipe member. In this case, since suction ports are formed at a plurality of locations in the length direction of the multistage telescopic nozzle member 60, it is possible to detect smoke generation over a wider range at once.

The bellows extendable nozzle member 70 has a pipe-shaped root portion 71 and a bellows portion 72 formed on the tip side. A pipe-shaped tip portion 73 is provided on the tip side of the bellows portion 72 , and the tip thereof serves as a suction port 74 .

FIG. 11 shows a cross-sectional view of the distal end side of the bellows portion 72 of the bellows extendable nozzle member 70 in a contracted state. The bellows portion 72 is formed by bending the peripheral surface at a plurality of locations in the length direction. The bellows portion 72 and the tip portion 73 are made of a metal material, but may be made of a resin material. FIG. 12 shows a cross-sectional view of the distal end side of the bellows extendable nozzle member 70 with respect to the bellows portion 72 in an extended state. In this way, the bellows portion 72 can be extended in the longitudinal direction, thereby allowing the length of the bellows extendable nozzle member 70 to be changed arbitrarily. In addition, the bellows portion 72 can be bent in any direction as well as extended and contracted in the length direction.

According to the multistage telescopic nozzle member 60 and the bellows telescopic nozzle member 70, the length of the nozzle member can be arbitrarily changed. It can be aimed at the object to be detected. In addition, the bellows extendable nozzle member 70 can be bent in any direction, and the degree of freedom in the orientation of the suction port can be increased.

The nozzle member can also be provided with a wheel member. FIG. 13 shows a front view near the tip of the U-shaped nozzle member 45 provided with the wheel member 49 . As shown in this figure, wheel members 49 can be provided at both ends of the U-shaped portion 47, respectively. As a result, the wheel member 49 is brought into contact with the ceiling surface, and the wheel member 49 is caused to run on the ceiling surface. The nozzle member 45 can be moved, and working efficiency can be improved.

14 shows a front view of the vicinity of the tip of the T-shaped nozzle member 50 provided with the wheel member 54. As shown in FIG. As shown in this figure, a wheel member 54 can be provided on each of the side extensions 52 on both sides. Also in this case, by bringing the wheel member 54 into contact with the ceiling surface and running the wheel member 54 on the ceiling surface, the space between the laterally extending portion 52 and the ceiling surface is properly maintained, and smooth movement can be achieved. The T-shaped nozzle member 50 can be moved, and working efficiency can be improved. Further, wheel members may be provided for other nozzle members.

Next, a method of using the smoke detection device of this embodiment will be described. A fixed smoke detection device is installed in the monitoring area, and when the smoke detection device detects a smoke concentration higher than a predetermined value, a worker holds the smoke detection device of this embodiment and moves to the monitoring area. work to identify where smoke is generated. When using the smoke detection device, first, one of the plurality of types of nozzle members described above is selected according to the necessity such as the situation of the area to be monitored, and attached to the main body 1 .

An operator who has entered the surveillance area turns the power switch 13 from off to on to turn on the power of the smoke detector. The worker then moves to an area where smoke is likely to occur, for example, near the server if the monitored area is a computer room. When reaching a place where smoke is likely to occur, air is sucked by directing the suction port of the nozzle part 2 to various places, and the smoke detection unit 31 detects smoke concentration. Since the smoke density is displayed on the smoke density display unit 24 at hand, the operator can grasp the smoke density in real time. In addition, according to the level of smoke concentration, the display state of the alarm display part 12 of the main body part 1 changes, and when smoke is generated from the place where the suction port is directed, it can be grasped immediately. can be done.

As described above, in the smoke detection device of this embodiment, one of a plurality of types of nozzle members having different tip shapes can be selectively attached to the main body 1. Depending on the shape and situation, smoke can be detected using a nozzle member having a shape that facilitates suction of air, thereby improving work efficiency and facilitating smoke detection work.

The smoke detection device to which the present invention is applied is not limited to those described above. FIG. 15 shows a front view of the smoke detector of the second embodiment. The smoke detection device of this embodiment has a housing 90 that can be held by hand. The housing 90 is formed in a substantially rectangular parallelepiped box shape. Any one of a plurality of types of nozzle members 91 can be selectively attached to one surface of the housing 90 . The shape of the nozzle member 91 is the same as that of the smoke detector of the first embodiment.

The smoke detection device of this embodiment does not have a hose member, and a nozzle member 91 is directly attached to a housing 90 containing a smoke detection unit, a suction unit, a power supply section, and the like. The housing 90 has a grip portion 92, and can be held with one hand to direct the suction port of the nozzle member 91 toward the inspection site. In the smoke detection device of this embodiment, since the nozzle member 91 is directly connected to the housing 90, there is no need to hold the housing 90 and the nozzle member 91 separately. It can be easily handled.

By adjusting the center-of-gravity position of the nozzle member 91 or the housing 90, handling can be made easier. Since the nozzle member 91 is elongated, it is difficult to handle if the weight of the tip side is large. Therefore, by configuring the nozzle member 91 so that the center of gravity is biased toward the base side, for example, by reducing the wall thickness toward the tip side of the nozzle member 91, it is possible to improve the ease of handling the nozzle member 91 to various places. .

Also, the position of the center of gravity of the housing 90 can be adjusted by arranging heavy objects inside the housing 90 . FIG. 16 shows a front view when the center-of-gravity position of the housing 90 is adjusted. Since a heavy object such as a battery is installed in the housing 90, by adjusting the arrangement position, the center of gravity 93 of the housing 90 can be moved to the plane where the nozzle member 91 is provided, rather than the central position of the handle portion 92. and the opposite side. Further, the center of gravity 93 of the housing 90 is desirably closer to the lower surface of the housing 90 on the side opposite to the upper surface on which the handle portion 92 is provided. By holding a grip portion 92 provided on the housing 90, the housing 90 tilts so that the nozzle member 91 side faces upward. Since smoke rises upward, there are many places where the nozzle member 91 is directed. Therefore, in the smoke detection device, by inclining the housing 90 so that the nozzle member 91 faces upward, the handleability can be improved.

The position of the center of gravity of the housing 90 does not necessarily have to be behind the central position of the handle portion 92, and the arrangement of heavy objects may be adjusted so that it is as far back as possible. This also makes it possible to improve the ease of handling of the nozzle member 91 when the housing 90 is held. Further, a weight member may be arranged inside the housing 90 in order to adjust the position of the center of gravity of the housing 90 .

The adjustment of the center-of-gravity position of the nozzle member and the center-of-gravity position of the housing can also be applied to the smoke detection device of the first embodiment. In this case, the center-of-gravity position of the nozzle housing 20 is adjusted, but since the nozzle housing 20 of the first embodiment has a small amount of heavy objects such as batteries, the center-of-gravity position cannot be sufficiently adjusted as it is. Sometimes. In this case, the position of the handle portion 23 of the nozzle housing 20 may be adjusted. Specifically, by moving the position of the handle 23 toward the side of the surface on which the nozzle member is provided, the relative center of gravity of the nozzle housing 20 with respect to the position of the handle 23 becomes closer to the side opposite to the nozzle member. Therefore, the nozzle housing 20 can be easily turned upward, and the handling performance can be improved.

Although the embodiment of the present invention has been described above, the application of the present invention is not limited to this embodiment, and can be applied in various ways within the scope of its technical ideas. The shape of each nozzle member is not limited to that of the above-described embodiment, and the number of selectable nozzle members is not limited to that of the above-described embodiment as long as it is two or more.

Furthermore, in the above-described embodiments, the substance to be detected is smoke, but the present invention can also be applied to a detection device that detects substances other than smoke, such as gas. Examples of the gas include carbon monoxide in gas. In the case of a detection device that detects gas, the smoke detection unit in the above embodiments is replaced with a gas detection unit that can detect gas.

In the detection device for detecting gas, when the gas to be detected is heavier than air, the nozzle member is directed downward in adjusting the position of the center of gravity of the nozzle housing 20 or housing 90. is desirable. Therefore, it is desirable that the center of gravity of the nozzle housing 20 or housing 90 is set closer to the surface on which the nozzle member is provided than the center position of the handle. As a result, the nozzle housing 20 or the housing 90 faces downward when the handle is held by hand, so that the nozzle member can be easily handled downward.

In the T-shaped nozzle member 50 shown in FIG. 9 , a plurality of suction ports 53 are arranged along the length direction of the side extending portion 52, and each suction port 53 has the same shape and diameter. , the suction port 53 on the side closer to the root portion 51 may have a larger suction amount, and the suction port 53 on the tip side may have a smaller suction amount. , the diameter of the suction port 53 on the distal end side may be made smaller so that the suction amount is uniform at each suction port 53 . Also, the shape of the suction port 53 is not limited to a circular shape, and may be another shape such as a rectangular shape. Furthermore, in the U-shaped nozzle member 45 shown in FIG. 8 as well, the diameter and shape of the suction port 48 can be similarly changed.

Instead of the wheel members 49 and 54 shown in FIGS. 13 and 14, a low-friction material can be arranged at the position of contact with the ceiling surface of the nozzle member. The low-friction material is made of a resin material or the like having a smooth surface, is arranged on the surface of the nozzle member facing the ceiling surface, and protrudes toward the ceiling surface. The corners of the low-friction material are chamfered to prevent them from getting caught on the ceiling. By bringing the low-friction material into contact with the ceiling surface, the nozzle member can be smoothly moved in the planar direction of the ceiling surface while maintaining a constant distance between the nozzle member and the ceiling surface.

Further, an operating switch such as a microswitch may be provided near the suction port at the tip of the nozzle member. The actuation switch is connected to the control unit 30 and is switched from off to on by pressing. When the tip of the nozzle member is brought close to the object to be detected and the operation switch near the suction port comes into contact with the object to be detected and is turned on, the suction unit 32 is operated to suck air into the smoke detection unit 31 . As a result, the suction unit 32 can be operated only when the suction port approaches the object to be detected, so battery consumption can be suppressed.

Further, another nozzle portion may be attached to the tip portion of the nozzle member. FIG. 17 shows an exploded view of a nozzle portion that can be attached to the linear nozzle member 40. As shown in FIG. FIG. 17(a) shows a case where a tip U-shaped nozzle portion 95 can be attached to the tip portion of the linear nozzle member 40. FIG. The tip U-shaped nozzle portion 95 has a portion corresponding to the U-shaped portion 47 of the U-shaped nozzle member 45 and a portion attached to the tip portion of the straight nozzle member 40 . By attaching the tip U-shaped nozzle portion 95 to the straight nozzle member 40 , the straight nozzle member 40 can have the same function as the U-shaped nozzle member 45 .

FIG. 17(b) shows a case where a tip T-shaped nozzle portion 96 can be attached to the tip portion of the straight nozzle member 40. FIG. The tip T-shaped nozzle portion 96 has a portion corresponding to the side extending portion 52 of the T-shaped nozzle member 50 and a portion attached to the tip portion of the straight nozzle member 40 . By attaching the tip T-shaped nozzle portion 96 to the straight nozzle member 40 , the straight nozzle member 40 can have the same function as the T-shaped nozzle member 50 .

Further, the control section 30 can control the suction fan of the suction unit 32 as follows. Each nozzle member has a discriminating section that allows the control section 30 to discriminate the type of the nozzle member when it is attached to the nozzle housing 20 . The determination unit can be configured by a memory that stores different information for each type of nozzle member, for example. The controller 30 changes the flow velocity of the sucked air according to the type of nozzle member attached to the nozzle housing 20 . For example, when the nozzle member is the U-shaped nozzle member 45, the U-shaped nozzle member 45 has a plurality of suction ports 48, so that the flow velocity of the sucked air is made higher than in the case of the linear nozzle member 40. Control the suction fan. As a result, a sufficient flow rate of the air sucked from each suction port 48 can be ensured. Also when the nozzle member is the T-shaped nozzle member 50, the flow velocity of the sucked air is increased because the T-shaped nozzle member 50 has a plurality of suction ports 53. FIG.

1 Main Body Part 2 Nozzle Part 3 Hose Member 10 Main Body Case 11 Main Body Handle 12 Alarm Display Part 13 Power Switch 14 Reset Switch 15 Hose Connector 16 Discharge Port 20 Nozzle Case 21 Hose Connector 22 Nozzle Connector 23 Nozzle Handle Part 24 Smoke Density Display Part 30 Control Part 31 Smoke Detection Unit 32 Suction Unit 33 Transmission Part 34 Power Supply Part 35 Power Supply Circuit Part 40 Linear Nozzle Member 41 Pipe Part 42 Suction Port 45 U-shaped Nozzle Member 46 Root Part 47 U-shaped Part 48 suction port 49 wheel member 50 T-shaped nozzle member 51 root portion 52 side extension portion 53 suction port 54 wheel member 60 multistage telescopic nozzle member 61 first pipe member 62 second pipe member 63 third pipe member 64 fourth pipe Member 65 Suction port 70 Accordion extendable nozzle member 71 Root portion 72 Accordion portion 73 Tip portion 74 Suction port 80 Piping

Claims (2)

a suction port for sucking air in the surveillance area;
a detection unit that detects a substance to be detected contained in the air sucked from the suction port;
a concentration display unit for displaying the concentration of the substance to be detected detected by the detection unit in a predetermined display range;
a control unit that controls the concentration display unit;
The control unit changes the detection sensitivity of the substance to be detected in the detection unit by switching the flow velocity of the air sucked from the suction port according to the concentration of the substance to be detected detected by the detection unit, When the detection sensitivity of the substance to be detected is changed to high sensitivity by switching to increase the flow velocity of the air to be sucked, the display range of the concentration display section is switched to a range of fine numerical values, When the detection sensitivity of the substance to be detected is changed to low sensitivity by switching to reduce the air flow velocity, the display range of the concentration display section is switched to a range of larger numerical values, and the concentration display section displays the detection. A detection device characterized by displaying the concentration of a substance to be detected detected by a part. a suction fan for sucking air in the monitoring area from the suction port;
an airflow sensor capable of measuring the flow velocity of the air sucked from the suction port;
The control unit controls the suction fan based on the flow velocity of the sucked air measured by the airflow sensor and the detection state of the substance to be detected by the detection unit, thereby causing suction from the suction port. 2. The detection device according to claim 1, wherein the air flow velocity is switched.

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