JP6266046B2 - Smoke test equipment - Google Patents

Description

  The present invention relates to a smoke test apparatus used for an operation test of a smoke detector.

  Conventionally, when a fire breaks out in a building such as an office or a house, the smoke generated by the fire is detected and alerted by an alarm, etc., and fire extinguishing, evacuation, and fire fighting activities are performed as quickly as possible. Smoke detectors are installed on the ceiling of the building to make it possible. It is required to periodically check whether or not this smoke detector can operate properly after installation in a building. As a smoke tester used for an operation test of the smoke detector, the following Patent Document 1 is required. , 2 using oil smoke or gas cylinders is widely used.

The smoke tester described in Patent Document 1 includes an oil storage unit that stores test oil, an electric heater that heats the test oil in the oil storage unit so as not to burn, and a cover that guides generated smoke to a smoke detector. And a support bar attached to the bottom of the cover.
When performing a smoke detector operation test, hold the support rod, cover the smoke detector installed on the ceiling, heat the electric heater to heat the oil storage section at a low temperature, It is pyrolyzed without burning and sent to the smoke detector as mist-like oily smoke.
In addition, the smoke tester described in Patent Document 2 includes a gas cylinder filled with a raw material material of a particulate gas body in place of the oil smoke storage unit, and a gas body that is atomized and injected from the gas cylinder by the filling pressure. Is detected by the smoke detector as pseudo smoke.

Japanese Unexamined Patent Publication No. 6-309577 JP-A-8-77472

However, for example, according to the smoke tester of the above-mentioned Patent Document 1, the test oil burns and gives off a strange odor, or the oil smoke adheres to the surface and the ceiling surface of the smoke detector to contaminate them, or the attached oil further There is a problem that dust may adhere to the smoke detector and the ceiling surface. Furthermore, there has been a problem that the sensitivity of the smoke detector may be reduced due to adhesion of oily smoke or dust to the smoke detector.
Further, for example, according to the smoke tester of Patent Document 2, there is a problem that the manufacturing cost increases because the gas cylinder is used as the smoke generating body.
In addition, since it is not easy to control the gas injection amount, it takes time to remove the pseudo smoke injected in the test and restore it to a normal detectable state when the pseudo smoke is injected at a high concentration. When simulated smoke is injected at a low concentration, detection by the smoke detector takes time, and in either case, there is a problem that the inspection work efficiency is poor.
In addition, there are smoke testing machines that use industrial incense sticks, but such smoke testing machines have strong odors, so they are not used in buildings where many people gather, and because they use fire types, There is a problem that the object may be burnt, or the smoke detector to be tested may be smudged with a smoke mark.
Therefore, in view of the above problems, the present invention provides a smoke test instrument capable of performing an operation test of a smoke detector accurately, quickly, and at a low manufacturing cost without contaminating the smoke detector and the ceiling surface. This is the issue.

The invention of claim 1 is used for an operation test of a smoke detector installed in a building, and includes a smoke emitting body that emits smoke from a tip portion, and a support rod that supports the smoke emitting body. In the appliance, the smoke generating body includes a cylindrical body having a smoke discharge port at a tip thereof, a heater disposed in the cylindrical body, a water-soluble liquid that is vaporized by heat of the heater, and the water-soluble liquid is A liquid supply unit for supplying to the heater, and sending air to the cylinder, atomizing the water-soluble liquid vaporized by the heater into pseudo smoke, and sending the pseudo smoke from the discharge port An air flow sensor that discharges the smoke sensor toward the smoke detector is connected, and an air flow sensor that detects an air flow from the air blow unit is provided , and a current supplied to the heater is controlled according to the magnitude of the air flow detected by the air flow sensor. The heater can be configured Characterized in that the adjustable amount of heating.
In the present invention, because the support rod is provided, the smoke test apparatus is configured to be portable and generates smoke obtained by atomizing a water-soluble liquid. It is possible to avoid attaching and fouling the ceiling surface and further attaching dust.
Further, the pseudo smoke is emitted from the discharge port toward the smoke detector by the blowing means, so that the pseudo smoke is blown to the smoke detector, and the smoke detector is quickly activated and the operation is confirmed.
Moreover, since a smoke generating body can be manufactured with the water-soluble liquid of an inexpensive component and an inexpensive member, the manufacturing cost of the smoke test apparatus can be suppressed.
Further, it is possible to efficiently replace a portion of the smoke generating body that is easily consumed .
Invention 請 Motomeko 2, in pressurized smoke testing device according to claim 1, as the blowing means to suck rotatably, the pseudo smoke is and released so as to facilitate the release of the pseudo smoke It is comprised so that reverse rotation is possible.
According to a third aspect of the present invention, in the smoke test apparatus according to the first or second aspect , a fan is provided separately from the air blowing means, and the fan is rotatable so as to promote the emission of the pseudo smoke. And it is comprised so that reverse rotation is possible so that the said simulated smoke discharged | emitted may be attracted | sucked.
According to a fourth aspect of the present invention, in the smoke test device according to any one of the first to third aspects, the air blowing means is formed of a rubber manual blower or a bellows. .
According to a fifth aspect of the present invention, in the smoke addition test instrument according to any one of the first to third aspects, the blower means is formed by a manual rotary blower provided with an impeller for blowing air toward the smoke generating body. The impeller is configured to be capable of shifting with a gear.
A sixth aspect of the present invention is the smoke test apparatus according to any one of the first to fifth aspects, wherein the heater is a conductive metal disposed between a proximal end and a distal end of the cylindrical body. It is formed by a line, and the liquid supply unit is arranged along the metal line.
A seventh aspect of the present invention is the smoke test apparatus according to any one of the first to sixth aspects, wherein the heater is formed of a rod-shaped body or a plate-shaped conductive member, and the liquid is formed along the heater. The supply unit is arranged.
The invention according to claim 8 is the smoke testing device according to any one of claims 1 to 7 , wherein the smoke generating body is detachably provided in the smoke adding section.
A ninth aspect of the present invention is the smoke test device according to any one of the first to eighth aspects, wherein the liquid supply unit is detachable from the cylindrical body.
A tenth aspect of the present invention is the smoke test apparatus according to any one of the first to ninth aspects, wherein the water-soluble liquid is stored in a liquid holding container detachably provided on the smoke generating body. The water-soluble liquid is supplied from a liquid holding container to the liquid supply unit.
The invention of claim 11 is the smoke testing device according to any one of claims 1 to 10 , wherein the water-soluble liquid is at least one of propylene glycol, glycerin, dipropylene glycol, tripropylene glycol or glycol. It is characterized by including the component of this.

According to the present invention, the smoke generated from the atomization of the water-soluble liquid is generated, so that viscous oily smoke or the like is adhered to the smoke detector or the ceiling surface, and further dust is adhered. As a result, it is possible to suitably check the operation of the smoke detector installed in the building. Moreover, since the smoke using a water-soluble liquid evaporates, there exists an effect that it can avoid adhering to a smoke sensor and affecting a sensitivity.
Moreover, since a smoke generating body can be manufactured with the water-soluble liquid of an inexpensive component, and an inexpensive member, there exists an effect that the manufacturing cost of a smoke test apparatus can be held down.
Furthermore, since the water-soluble liquid is vaporized and then atomized to generate smoke and discharged by the blowing means, it is easy to control the concentration and amount of smoke, and the smoke detector can be used accurately and efficiently. There is an effect that the operation can be confirmed.
In addition, the water-soluble liquid has an effect that a component with little odor or an odorless component or a component with an odor that is easily liked by humans can be selectively used.

These are the front views of the smoke test apparatus shown as the 1st Embodiment of this invention. These are the schematic diagrams which showed schematic structure of the smoke test apparatus shown as the 1st Embodiment of this invention. These are the front views which showed the inside of the operation part of the smoke test apparatus shown as the 1st Embodiment of this invention. These are the front views which showed the smoke test apparatus shown as the 2nd Embodiment of this invention. These are the front views which showed the other example of the smoke test apparatus shown as the 2nd Embodiment of this invention. These are the schematic block diagrams which showed the other example of the operation part of the smoke test apparatus shown as the 1st-2nd embodiment of this invention. These are the partial cross sections which showed the other example of the smoke generating body of the smoke addition test instrument shown as the 1st-2nd embodiment of this invention. These are the partial cross sections which showed the other example of the smoke generating body of the smoke addition test instrument shown as the 1st-2nd embodiment of this invention. (A), (b) is the partial cross section figure which showed the other example of the smoke generating body of the smoke test apparatus shown as the 1st-2nd embodiment of this invention. These are the partial cross sections which showed the other example of the smoke generating body of the smoke addition test instrument shown as the 1st-2nd embodiment of this invention. These are the partial cross sections which showed the other example of the smoke generating body of the smoke addition test instrument shown as the 1st-2nd embodiment of this invention.

(First embodiment)
The first embodiment of the present invention will be described below with reference to the drawings.
As shown in FIG. 1, a smoke tester (smoke test instrument) 1A according to a first embodiment of the present invention includes a smoke unit 3 that includes a smoke generator 2 and smokes a smoke detector K. The support rod 4 that supports the smoke unit 3 and the operation unit 5 that operates the smoke unit 3 are provided.

As shown in FIG. 1, the smoke adding unit 3 covers a smoke detector K installed on a ceiling material W or the like, and fills the inside with the cover 11 that fills the smoke emitted from the smoke generating body 2. And a smoke generator 2 installed.
The cover 11 is formed of a synthetic resin material or the like, and includes a tapered portion 11a that expands in one direction and a cylindrical portion 11b that is connected to the outer edge of the tapered portion 11a. In addition, an opening 12 is formed at the center of the taper portion 11a on the small diameter portion side, and the cover 11 is attached to the support rod 4 with the distal end portion of the support rod 4 being inserted into the opening 12 as required. It is fixed so that it can be removed. Part of the cylindrical portion 11b has a bellows shape, and thus the cover 11 has a predetermined stretchability in the direction of the axis L. When an exogenous air flow from an air conditioner or the like exists in the vicinity of the smoke detector K to be tested, the cover 11 blocks the air flow and ensures that the pseudo smoke reaches the smoke detector K and is stable. It is intended to ensure that the test can be performed and may be removed if no such airflow exists.
A smoke generating body 2 is attached to the tip of the support bar 4 and in the vicinity of the opening 12 of the tapered portion 11a, and smokes the cover 11 by operating the operating portion 5 as will be described in detail later. Be able to.

  As shown in FIG. 2, the smoke generating body 2 includes a cylindrical body 6, a heater 7 disposed in the cylindrical body 6, and a water-soluble liquid that is provided in the vicinity of the heater 7 and is vaporized by the heat of the heater 7. A liquid supply unit 8 that holds and supplies the water-soluble liquid to the heater 7 (note that FIG. 2 shows the cylindrical body 6 and the liquid supply unit 8 of the smoke generating body 2 on a plane including the axis L). The cut state is viewed from the front (the same applies to FIGS. 8 and 9). The smoke generating body 2 is connected to an air blowing means 10 which blows air from one end side, atomizes the vaporized water-soluble liquid to form pseudo smoke, and discharges the pseudo smoke from the discharge port 9 on the other end side. ing.

  The cylindrical body 6 is formed in a cylindrical shape having a circular cross section with both ends opened, and a smoke discharge port 9 is formed on one end side. The cross-sectional shape, diameter, and longitudinal dimension of the cylindrical body 6 are not particularly limited.

  The heater 7 is formed in a coil shape having a diameter smaller than that of the cylindrical body 6 using a metal wire such as a nichrome wire or a platinum wire, and is arranged in the longitudinal direction with the cylindrical body 6 and the axis L being substantially coincident with each other. One end 7a of the heater 7 is connected to a terminal of a heater connector 15 fixed to the bottom of the cylindrical body 6, and the other end 7b is folded at the end (tip) of the coil and directed toward the heater connector 15. It extends in a straight line, and is connected to the other terminal of the connector 15 in the same manner as the one end 7a, and is electrically connected to the control unit 21 via the connector 15. The control unit 21 allows a predetermined current to flow through the heater 7 in accordance with ON / OFF of the power switch 23 and the drive switch 24, thereby heating / stopping the heater 7.

  On the inner side and the outer side of the coil-shaped heater 7, for example, a fiber-based incombustible filter such as glass fiber or a non-combustible filter made of foamed resin is disposed as the liquid supply unit 8. The filter of the liquid supply unit 8 has a large number of air holes formed therein so as to be able to vent in all directions on the surface thereof, and a water-soluble liquid serving as a smoke generating agent can be held in the air holes. It has become. The liquid supply unit 8 can be atomized by the heat of the heater 7 by supplying the smoke generating agent to the heater 7 along the heater 7 in a state of being impregnated with the water-soluble liquid, that is, in contact with or adjacent to the heater 7. It is installed as follows.

  As a component of the water-soluble liquid, a water-soluble liquid that is hydrophilic and has a high water retention property, such as a water-insoluble liquid that is harmless to the human body including at least one component such as glycerin and propylene glycol. The water-soluble liquid is preferably a component that has high moisture retention and is less likely to volatilize, and is preferably a component that does not alter the smoke detector K and the ceiling material W of the building (see FIG. 1).

  A container 20 having a heater connector 15 and an airflow sensor 19 therein is connected to the base end side (support bar 4 side) of the cylindrical body 6. The air blowing means 10 is connected to the container 20 through a hollow rod-like body so as to be able to vent. The air flow from the air blowing means 10 is blown into the cylindrical body 6 through the internal space of the container 20, and the heater 7 The vaporized water-soluble liquid is atomized to form pseudo smoke (aerosol) S and the generated pseudo smoke S is discharged from the discharge port 9. For example, a blower pump or a fan is used as the blower unit 10.

  The airflow sensor 19 is a device that detects the airflow in the container 20. When air is blown in by the blower 10, the airflow sensor 19 detects the airflow, sends a signal to the control unit 21, and sends a predetermined current to the heater 7. When the airflow is not detected, the current to the heater 7 is limited or cut off so as not to be heated. The air flow sensor 19 prevents the heater 7 from being heated even when there is no air flow, thereby causing the temperature to rise abnormally, and the heater 7 is heated with a predetermined current only when an air flow is detected. Yes. When the heater 7 is heated and reaches a predetermined temperature, the water-soluble liquid is vaporized. An appropriate sensor may be provided in addition to the airflow sensor 19, and the control unit 21 may further perform control such as temperature control of the heater 7 and prevention of overheating based on these signals. Further, the supply current value to the heater 7 may be changed continuously or stepwise according to the change or strength of the airflow, the change in temperature or the height of the heater 7, and the like.

  As shown in FIG. 1, the support bar 4 has a predetermined length dimension so that the user can press the upper end of the cover 11 of the smoke adding unit 3 against the ceiling material W from below. Thus, the heating unit 3 is provided on the distal end side, and the operation unit 5 for operating the smoke generating body 2 and the air blowing means 10 is provided on the proximal end side. The support bar 4 has a hollow shape, and wiring (not shown) for supplying electric power to the heater 7 and the air blowing means 10 is disposed inside the support bar 4. Further, the support bar 4 has a structure in which short hollow bar-like members are slidably connected, and is configured so that the entire length of the support bar 4 can be expanded and contracted as necessary while maintaining internal ventilation. Has been. During the test, the rod-shaped member is slid to adjust the overall length of the support rod 4, and the connecting portion between the rod-shaped members is fixed and the length is used.

Further, the operation unit 5 is provided on the base end side of the support bar 4, and the smoke generator 2 and the air blowing unit 10 are hand-held by the user while the cover 11 of the smoke unit 3 is covered with the smoke detector K. Can be activated.
As shown in FIGS. 2 and 3, the operation unit 5 includes a control unit 21 that controls heating / stopping heating of the heater 7 in accordance with detection of the airflow by the airflow sensor 19, a power supply unit 22, and a control unit 21. And a power switch 23 that connects the power supply unit 22 and a drive switch 24 that supplies power to the blowing unit 10 via the control unit 21 and drives the blowing unit 10 while the power switch 23 is ON. It has been.
The power supply unit 22 may be any device that can supply operating power. For example, a dry battery, a rechargeable battery, or an AC power supply can be used.

  As the smoke detector K, a smoke detector adopting a scattered light method as a detection principle is used.

Next, a method of using the smoke tester 1A will be described.
As shown in FIGS. 1 and 2, in order to perform an operation test of the smoke detector K with the smoke tester 1A, the power switch 23 of the operation unit 5 is turned on, and the smoke detector K is connected to the smoke detector K. For example, the cover 11 is placed on the smoke detector K toward the installed ceiling material W, and the peripheral edge of the cover 11 is brought into close contact with the ceiling material W.
Then, when the drive switch 24 is turned on and the air blowing means 10 shown in FIG. 2 is driven, the airflow flows through the container 20. Then, the airflow sensor 19 detects the airflow and sends a signal to the control unit 21, and the control unit 21 supplies power to the heater 7 to heat the heater 7. The water-soluble liquid which is a smoke generating agent impregnated in the filter of the liquid supply unit 8 is vaporized by the heating of the heater 7 and further atomized by the air blown by the blowing means 10 and flows toward the tip of the cylindrical body 6. The pseudo smoke (aerosol) S in which the water-soluble liquid is atomized is discharged from the discharge port 9 of the cylindrical body 6. If the smoke detector K is able to operate normally when the pseudo smoke fills the cover 11, the smoke detector K reacts to the pseudo smoke S, emits a warning sound and / or turns on the warning lamp. It can be confirmed that the smoke detector K operates normally. On the other hand, if the smoke sensor K is defective, the smoke sensor K does not react to the pseudo smoke S, does not emit an alarm sound, and / or does not turn on the warning lamp. I can confirm that.

As described above, according to the smoke tester 1A, the smoke detector K and the ceiling material are generated in order to generate the pseudo smoke S in which the water-soluble liquid is atomized as the smoke for operating the smoke detector K on a trial basis. It is possible to check the operation of the smoke detector K suitably by avoiding the sticking of viscous oily smoke or the like to the W to contaminate the sensor K or the like, or further attaching dust. In particular, water-soluble liquids contain components such as propylene glycol and glycerin that are hydrophilic and have high water retention properties. Therefore, these components evaporate with water using a heater, and these components become the core at the jet nozzle. And atomize. Since these components have high water retention, unlike the case where only water evaporates, they can float well in the air for a while and play a role as simulated smoke. This has been confirmed by experiments conducted by the inventors. In general, it is believed that propylene glycol or glycerin evaporates with water and then atomizes and discharges, then cools to become nuclei, and water vapor aggregates to form white smoke. And since propylene glycol and glycerin have high hydrophilicity and take in the evaporated water and prevent the evaporation of the taken-in water, the white smoke will float in the air for a relatively long time.

On the other hand, since the smoke using the water-soluble liquid evaporates in the environment soon after the test, it can be avoided that the smoke remains attached to the smoke sensor K and affects its sensitivity.
Moreover, since the smoke generating body 2 can be manufactured with a simple structure using an inexpensive component water-soluble liquid and an inexpensive resin member, the manufacturing cost of the smoke tester 1A can be reduced. In addition, since environmentally harmful gases such as chlorofluorocarbon are not discharged, the environmental load is small.

Furthermore, since the water-soluble liquid is vaporized and then atomized to generate pseudo smoke and discharged by the air blowing means 10, the smoke concentration and emission amount can be easily controlled, and smoke detection is performed accurately and efficiently. The operation of the device K can be confirmed.
In addition, it is possible to selectively use odorless components, low odor components, or odor-friendly components as water-soluble liquids, and use the smoke tester 1A in hospitals and other places where many people gather. The effect is easy. Alternatively, when an odor that does not cause discomfort to humans is added to the water-soluble liquid, the smoke remaining state can be recognized after the operation test of the smoke detector K by the smoke tester 1A.

In addition, a coil-shaped heater 7 is disposed along the axis L of the cylindrical body 6, and a liquid supply unit 8 impregnated with a water-soluble liquid is disposed inside and outside the coil of the heater 7. The effect that the water-soluble liquid of the part 8 can be efficiently vaporized in a wide range by the coil heater 7 is obtained. In addition, the heater 7 can adjust the generation | occurrence | production density | concentration of the pseudo smoke S suitably by narrowing or expanding the winding pitch of a coil, and adjusting the internal diameter of a coil.

(Second Embodiment)
Next, as a second embodiment of the present invention, a smoke tester 1B will be described with reference to FIGS. In the following embodiments, portions having the same configuration as those of the first embodiment are denoted by the same reference numerals, and detailed description thereof is omitted.

As shown in FIG. 4, the smoke tester 1 </ b> B has a small size in which the power switch 23, the air flow sensor 19, the control unit 21, and the power supply unit 22, that is, a battery, are built in the smoke tester 1 </ b> A of the first embodiment. The case 25 is attached on the outer peripheral surface of the tip of the support bar 4.
The smoke emitting body 2 is connected to the control unit 21 via a connector (not shown in FIG. 4). A manual blower 10 is provided on the base end side of the hollow support rod 4. The air blowing means 10 is formed by, for example, a rubber manual blower. The blowing means 10 may be a bellows or the like instead of the rubber manual blower.

  Alternatively, as shown in FIG. 5, the blowing means 10 rotates the impeller 27 by rotating the rotary handle 26 to cause the air to flow, and passes through the hollow support rod 4 toward the smoke generating body 2. It may be a manual rotary blower that blows air. This manual rotary blower may be provided with a gear (not shown) in the impeller 27 so that the rotation of the impeller 27 can be changed.

  As mentioned above, although the embodiment of the present invention has been described using the smoke tester 1A, 1B, the present invention is not limited to the aspect shown in the above first to second embodiments, Each part can be appropriately changed and used in a more preferable aspect without departing from the gist of the present invention.

Specifically, the cylinder 6 including the heater 7 and the liquid supply unit 8 impregnated with the water-soluble liquid is configured to be detachable from the cover 11 and the container 20 by, for example, a screwing structure or a fitting structure. can do.
By adopting such a configuration, even when the water-soluble liquid or the heater 7 is consumed, the liquid supply unit 8 and the heater 7 can be easily replaced together with the cylindrical body 6, and the smoke tester 1A can be economically operated. The effect that it can be used is obtained.

  Further, the liquid supply unit 8 impregnated with the water-soluble liquid may be configured to be detachable from the cylindrical body 6. Moreover, the heater 7 of the smoke generating body 2 shown by the said 1st-2nd embodiment may be made exchangeable. By making the liquid supply unit 8 and / or the heater 7 impregnated with a water-soluble liquid detachable, an effect that the most consumable portion of the smoke tester 1A can be efficiently exchanged can be obtained. .

  In addition to the air blowing means 10 for blowing air into the cylinder 6 of the smoke generating body 2, the fan 35, the fan 35 switch 36 and the fan are provided in the vicinity of the smoke generating body 2 or in the operation unit 5 as illustrated in FIG. By providing 35 transmissions (not shown), it is possible to adopt a configuration that can accelerate the emission of the pseudo smoke S as necessary. By providing such a fan 35, the pseudo smoke S emitted from the discharge port 9 of the smoke generating body 2 is quickly filled in the entire cover 11 or the entire housing 31 without staying in the vicinity of the discharge port 9. The effect that it becomes possible is acquired.

Furthermore, in addition to the above-described configuration, a changeover switch that switches energization or interruption (ON / OFF) of current to the heater 7 may be provided.
By making the air blowing means 10 or the fan 35 usable so that the heater 7 can be turned on and off, the heater 7 is energized (turned on) when performing an operation test of the smoke detector K. While generating the pseudo smoke S, as described above, the pseudo smoke S can be quickly filled by the blowing means 10 or the fan 35. When the operation test is completed, the energization of the heater 7 is cut off (turned off) to stop the generation of the pseudo smoke S, and the blowing means 10 or the fan 35 is driven in this state to detect smoke. The air can be sent toward the device K, and the released smoke S can be quickly removed from the smoke detector K and its surroundings. As a result, after the operation test of the smoke detector K is completed, the normal smoke detection state can be promptly restored.
Note that a cylinder filled with compressed air may be used instead of the blower 10 or the fan 35.
Further, the blower 10 or the fan 35 may be provided with a changeover switch (not shown) that reversely rotates the fan. By providing such a change-over switch and rotating the fan in the reverse direction, the smoke emitted after the operation test is completed can be sucked and the smoke around the smoke sensor K can be quickly removed.

  Further, the liquid supply unit 8 impregnated with the water-soluble liquid is disposed only on the inner peripheral side of the coil shape of the heater 7, and a sponge filter that forms an air flow path without impregnating the water-soluble liquid on the outer side thereof. May be arranged. Further, the outer sponge filter does not necessarily have to be arranged as long as the heater 7 and the liquid supply unit 8 can be positioned and fixed in the cylinder 6 and an appropriate amount of air can flow. Further, the liquid supply unit 8 impregnated with the water-soluble liquid may be disposed only outside the coiled heater 7.

Further, in the above embodiment, the heater 7 is formed in a coil shape. However, as shown in FIG. 7, the metal wire arranged on a straight line is moved from the proximal end 6 a side to the distal end 6 b side of the cylindrical body 6. Even if both ends of the metal wire are connected to the respective terminals of the heater connector 15 so as to extend linearly toward the end, bend in the vicinity of the distal end 6b and extend linearly toward the base end 6a. Good.
Further, as shown in FIG. 8, the heater 7 is formed by bending a metal wire into a comb shape on one plane, and the heater 7 formed on a flat plate is formed by two flat plate filters (liquid supply portions) 8 (FIG. 8). In FIG. 8, the heater 7 may be placed in contact with or close to the liquid supply unit 8 by being sandwiched by only one flat plate filter (shown on the back side of the drawing).

  9 to 11 are cross-sectional views of the smoke generating body 2 on a plane including the axis L and the heater 7. As shown in these drawings, the heater 7 does not necessarily need to be a metal wire, and may be a rod-like body or a plate-like body made of ceramic or metal. In this case, the rod-like or plate-like heater 7 made of ceramic or metal has one rod-like or plate-like heater 7 arranged in the cylinder 6 as shown in FIG. In addition, a liquid supply unit 8 impregnated with a water-soluble liquid may be disposed so as to cover the surfaces 7a, 7b, etc. of the rod-like or plate-like heater 7, or as shown in FIG. A plurality of rod-shaped other-body or plate-like heaters 7, 7... Are arranged at intervals, and ventilation is possible between these heaters 7, 7 .. and between the heater 7 and the cylindrical body 6. A liquid supply unit 8 impregnated with a water-soluble liquid may be provided. Also in this case, substantially the same effect as the above embodiment can be obtained.

  The surfaces 7a, 7b, etc. of the metal or ceramic rod-like or plate-like heater 7 shown in FIGS. 9A and 9B are the same as the heater 7 shown in FIG. May be formed in a wave shape. With such a configuration, the contact area between the heater 7 and the sponge fill 8 impregnated with the water-soluble liquid can be further increased, and smoke can be generated efficiently.

Further, as shown in FIG. 11, the smoke generating body 2 may be externally attached with a liquid holding container 40 for storing a water-soluble liquid and supplying the liquid supply unit 8 with a small amount of the smoke generating agent.
In this case, since the liquid holding container 40 supplies the water-soluble liquid stored with respect to the liquid supply part 8, it has the fine hole 41 which only allows air to flow in from the outside, and water-soluble liquid is supplied to the opening. What connected the pipe | tube 43 made to flow is used. The tube 43 is connected to the liquid supply unit 8. The shape of the container body 44 may be a rectangular parallelepiped shape, a cylindrical shape, or any other shape. And the pipe | tube 43 is connected to the opening part provided in the cylinder 6 of the smoke generating body 2. As shown in FIG.
The smoke testers 1A and 1B can be used without changing the liquid supply unit 8 over a long period of time by adopting the above configuration.

Further, in the first and second smoke testers 1A and 1B, for example, a smoke density sensor such as a dimming density meter or a scattered light density meter, and a heater based on the result detected by the smoke density sensor 7 may be provided with a control device that adjusts the applied power to 7.
By setting it as such a structure, it can control automatically so that smoke generation amount may be maintained at a fixed density.

The control unit 21 of the smoke tester 1A, 1B detects a signal when the smoke detector K is covered with the cover 11 of the smoke tester 1A, 1B, and starts heating the heater 7 by this detection signal. After the time, the air blowing is started by the air blowing means, and when the smoke testers 1A and 1B are separated from the smoke detector K, the heating and the air blowing may be stopped.
Moreover, the control part 21 may be set so that the ventilation means 10 operate | moves only when mounting | wearing of the smoke body 2 is detected.
By setting it as such, it is possible to prevent forgetting to install the smoke generating body 2.

  Moreover, you may provide the smoke body 2 in the operation part 5 or its vicinity. With such a configuration, the replacement work of the smoke generating body 2 can be facilitated.

  Further, a small smoke densitometer is installed in the cover 11 of the smoke tester 1A, 1B shown in the first embodiment or the second embodiment, and the cover 11 is operated when the smoke tester 1A, 1B is in operation. It may be configured such that the concentration of the pseudo smoke inside is measured and displayed.

1A, 1B Smoke tester (Smoke test equipment)
2 Smoke body 3 Smoke unit 6 Cylinder 7 Heater 8 Liquid supply unit 9 Discharge port 10 Blowing means 24 Changeover switch (drive switch)
35 Fan 40 Liquid holding container S Simulated smoke

Claims (11)

In a smoke test apparatus comprising a smoke body that emits smoke from a tip portion, and a support rod that supports the smoke body, which is used for an operation test of a smoke detector installed in a building,
The smoke generating body has a cylinder having a smoke discharge port at a tip thereof, a heater disposed in the cylinder, a water-soluble liquid that is vaporized by heat of the heater, and supplies the water-soluble liquid to the heater And a liquid supply unit
Air blowing means that sends air into the cylinder, atomizes the water-soluble liquid vaporized by the heater into pseudo smoke, and emits the pseudo smoke from the discharge port toward the smoke detector. Are concatenated,
An airflow sensor for detecting an airflow from the blowing means is provided ;
A smoke addition test instrument characterized in that the current supplied to the heater can be controlled by the magnitude of the airflow detected by the airflow sensor, and the heating amount of the heater can be adjusted . The smoke test apparatus according to claim 1 ,
The smoke test apparatus, wherein the blowing means is configured to be rotatable so as to promote the emission of the pseudo smoke, and to be rotated reversely so as to suck the emitted pseudo smoke. The smoke test device according to claim 1 or 2 ,
Apart from the blowing means, a fan is provided,
The smoke test apparatus, wherein the fan is configured to be rotatable so as to promote the emission of the pseudo smoke, and to be rotated reversely so as to suck the emitted pseudo smoke. The smoke test device according to any one of claims 1 to 3 ,
The air blowing means is formed of a rubber manual blower or a bellows. The smoke test device according to any one of claims 1 to 3 ,
The air blowing means is formed by a manual rotary blower provided with an impeller for blowing air toward the smoke generating body,
The impeller is configured to be variable by a gear. The smoke test apparatus according to any one of claims 1 to 5 ,
The heater is formed of a conductive metal wire disposed between a proximal end and a distal end of the cylindrical body,
A smoke test apparatus, wherein the liquid supply unit is disposed along the metal wire. The smoke test apparatus according to any one of claims 1 to 6 ,
The heater is formed of a rod-like body or a plate-like conductive member,
A smoke test apparatus, wherein the liquid supply unit is disposed along the heater. The smoke test apparatus according to any one of claims 1 to 7 ,
The smoke generator is detachably provided in a smoke unit. The smoke test apparatus according to any one of claims 1 to 8 ,
The smoke test instrument, wherein the liquid supply unit is detachable from the cylindrical body. The smoke test apparatus according to any one of claims 1 to 9 ,
The water-soluble liquid is stored in a liquid holding container detachably provided on the smoke generating body, and the water-soluble liquid is supplied from the liquid holding container to the liquid supply unit. . The smoke test apparatus according to any one of claims 1 to 10 ,
The water-soluble liquid contains at least one component of propylene glycol, glycerin, dipropylene glycol, tripropylene glycol, or glycol.

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