JP6096557B2 - Spraying system - Google Patents

Description

  The present invention combines a function of removing suspended particulates by mist and a temperature lowering function for removing suspended particulates such as smoke floating in the space by emitting low conductivity water such as deionized water from a spray nozzle. Related to the spray system.

  A conventional technique is known in which smoke particles are collected by Coulomb force by spraying charged water particles from a charge spraying head (see, for example, Patent Document 1). According to such charged spraying, an equivalent smoke-extinguishing effect is obtained with about 1/5 the amount of fire extinguishing water at the time of conventional non-charged spraying.

Japanese Patent No. 4989419

However, the prior art has the following problems.
This Patent Document 1 requires a configuration in which a charging spray head that charges and sprays spray particles of a water-based fire extinguisher supplied by a fire extinguishing agent supply facility, and a voltage application unit that applies a charging voltage to the charging spray head. It has become. For this reason, there exists a subject that the apparatus which hits a voltage application part enlarges.

  Moreover, this patent document 1 is specialized in improving a fire extinguishing power, and it was not considered about the mist spray for obtaining the temperature-falling effect when the floating fine particles, such as smoke, are not generated.

  The present invention has been made to solve the above-described problems. In general, spraying that achieves a temperature lowering function is performed, and when airborne particulates such as smoke are generated, the apparatus is simpler than in the past. It aims at obtaining the spray system which can perform the spray which implement | achieves the smoke removal function which electrifies and sprays mist using a structure, and removes suspended particulates, such as the smoke which generate | occur | produced in the object division.

The spray system according to the present invention performs spraying that realizes the function of removing suspended particles when smoke or other suspended particles are generated or flowed into the target compartment, and the temperature is lowered during normal times when the suspended particles are not generated or flown. A spray system that performs spraying to realize a function, and is a spray nozzle that is installed in a target section and sprays water as a mist in the target section, and low-conductivity water corresponding to water having a conductivity of 10 μS / cm or less Low conductivity water supply device for supplying water to the spray nozzle, normal water supply device for supplying normal water equivalent to water having a conductivity higher than 10 μS / cm to the spray nozzle, and low conductivity by manual operation or automatic operation One of the water supply device for rate water and the water supply device for normal water is provided with the switching mechanism part which can be switched to a starting state and the other to a stop state.

  According to the present invention, it is possible to switch between spraying using normal tap water or the like and spraying that achieves the effect of removing suspended particulates such as smoke by charging water particles by spraying low conductivity water from a spray nozzle. Due to the structure, spraying that realizes the temperature lowering function is normally performed, and when suspended particulates such as smoke are generated or inflow, the mist is charged using a simpler device configuration compared to the conventional one. In addition, it is possible to obtain a spray system capable of performing spraying that realizes a function of removing suspended particulates such as smoke generated or flowing into the target section.

It is a general view of the smoke removal apparatus by the anti-electric mist concerning Embodiment 1 of this invention. It is the figure which put together the measurement result of the light extinction rate accompanying elapsed time when the verification experiment 1 in Embodiment 1 of this invention was implemented. The list | wrist of the measurement result of the measurement items 1-3 at the time of implementing the verification experiment 1 in Embodiment 1 of this invention is shown. It is the figure which put together the measurement result of the dimming rate accompanying elapsed time when the verification experiment 2 in Embodiment 1 of this invention was implemented. It is the figure which put together the measurement result of the light extinction rate accompanying elapsed time when the verification experiment 3 in Embodiment 1 of this invention was implemented. It is the figure which put together the measurement result of the light extinction rate accompanying elapsed time when the verification experiment 4 in Embodiment 1 of this invention was implemented. It is a whole block diagram of the spraying system concerning Embodiment 2 of this invention.

Hereinafter, preferred embodiments of the spray system of the present invention will be described with reference to the drawings.
The present invention defines appropriate conditions for obtaining removal of suspended fine particles such as smoke by charging mist particles (hereinafter referred to as charged mist) based on experimental data.

Embodiment 1 FIG.
FIG. 1 is an overall view of a smoke eliminator using charged mist according to Embodiment 1 of the present invention. In the water storage container 1, low conductivity water is stored in advance. Then, the low conductivity water sucked up from the water storage container 1 by the pump 2 is sprayed from the dry mist nozzle 4 (an example of the spray nozzle) provided in the target section by opening the valve 3.

  The spray control unit 5 controls the pump 2 and the valve 3 when receiving an external signal notifying the generation or inflow of smoke from a smoke detector not shown in FIG. Then, low conductivity water is supplied to the dry mist nozzle 4. Even if the external signal from the smoke detector and the spray control unit 5 are not used, the low-conductivity water can be dry-misted by opening the valve 3 and driving the pump 2 by manual operation based on the operator's judgment. It is possible to supply to the nozzle 4.

  In addition, it is said that when water is made fine particles rapidly, it is negatively charged due to the Leonard effect. At this time, in the case of high conductivity water (for example, tap water), the negative charge is neutralized by impurities contained in the water, but in the case of low conductivity water (for example, deionized water), the negative charge is neutralized. Is maintained. Accordingly, when low conductivity water is radiated using a nozzle that radiates with a small particle diameter, such as the dry mist nozzle 4, the water particles are charged. Therefore, the present invention has a technical feature in that the effect of removing smoke particles floating in the target compartment is obtained by utilizing the chargeability of the water particles.

  In order to verify such a removal effect, four verification experiments were performed, and the verification results will be described in detail below.

<Verification experiment 1>
(1) Sample water The following two were used as sample water as low conductivity water and high conductivity water which is difficult to be charged.
Low conductivity water: deionized water with conductivity = 0.9 μS / cm High conductivity water: tap water with conductivity = 270 μS / cm

(2) Mist discharge conditions As the mist nozzle and mist pump, those having the following performance were used.
Mist nozzle: 6MPa-20mL / min x 1 Mist pump: High pressure plunger pump (Output 0.4kW)
Mist release time: 1 minute

(3) Size of experimental section The following capacity was used as the experimental section corresponding to the protective section.
Glove box (capacity: 100L)

(4) Smoke generation source Smoke to be removed was generated under the following conditions.
Fuel (fireplate): Automotive gasoline (φ25 × 20mm)
Combustion amount: Approximately 3mL
(5) Measurement item The following three data were measured and the smoke removal effect in low conductivity water and high conductivity water was compared.
Measurement item 1 (dimming rate): The smoke density before and after mist emission (after sedimentation saturation) is measured as an optical smoke densitometer (hereinafter referred to as Cs meter) extinction rate. Measurement item 2 (sedation saturation time) : Mist is released for a certain period of time, and after the mist emission is stopped, the time until the recovery of light attenuation (decrease in light attenuation) is saturated due to the settling of smoke and water particles is measured Item 3 (electrostatic voltage): Measures the voltage at a distance of about 5 cm from the mist pattern near the nozzle during mist discharge as mist static electricity.

(6) Verification Experiment Procedure Verification data was measured by the following procedure.
Step 1: Ignition of fuel in the glove box Step 2: After combustion is completed, the smoke particles adhering to the window of the Cs meter light path are wiped off, and the light attenuation rate (smoke concentration) in the glove box is measured. Step 3: As a predetermined time Discharge mist for 1 minute, and continuously measure the recovery status of dim rate during mist emission and after mist emission stop. Step 4: After saturation of dim rate recovery, water particles attached to the window of Cs meter light path Wipe off and measure the light attenuation rate (smoke density) in the glove box

  The experimental results of the verification experiment 1 as described above will be described. FIG. 2 is a table summarizing the measurement results of the dimming rate with the elapsed time when the verification experiment 1 according to Embodiment 1 of the present invention was performed. FIG. 3 shows a list of measurement results of the measurement items 1 to 3 when the verification experiment 1 according to Embodiment 1 of the present invention is performed.

  FIG. 3 shows that the deionized water mist is charged with static electricity of −4 to −5 kV.

Moreover, the following can be understood from the experimental results shown in FIGS.
(Effect 1) Improvement of dimming rate As a result of spraying deionized water mist on gasoline combustion smoke for about 1 minute, the dimming rate, which was about 95% before release, recovered to about 25% after release ( is decreasing. On the other hand, when the tap water mist is sprayed under the same conditions, the recovery of the spray rate after release is only about 59%. Therefore, the use of low-conductivity water resulted in a significant improvement in the attenuation rate.

(Effect 2) Improvement of sedimentation saturation time As a result of observing the inside of the glove box during 1 minute during the mist spraying, the smoke particles adsorb to the charged water particles, so that the smoke particles are aggregated (that is, a large number of smoke particles are formed). The phenomenon of forming aggregates) was observed. As a result, as shown in FIG. 2, a measurement result is obtained in which the light attenuation rate recovers even while the deionized water mist is sprayed for about 1 minute.

  Further, it is considered that the same agglomeration occurred even after the mist emission was stopped, and the sedimentation speed of the smoke particles was increased. As a result, when deionized water mist is employed, the sedimentation saturation time corresponding to the time until recovery of the light attenuation rate is saturated is about 1 minute. On the other hand, when the tap water mist is adopted under the same conditions, the sedimentation saturation time takes 3 minutes or more. Therefore, the effect of shortening the sedimentation saturation time to about 1/3 was obtained by employing deionized water mist.

  As described above, according to the verification experiment 1, the deionized water, which is low conductivity water, is sprayed from the dry mist nozzle 4, thereby reducing the amount of light compared to the case where tap water having high conductivity is sprayed. Significant improvements were obtained with respect to rate recovery and sedimentation saturation time.

  And as such low electrical conductivity water, deionized water can be employ | adopted, for example, and can be stored in a water storage container beforehand. As a result, it is possible to obtain an apparatus for removing suspended particulates such as smoke caused by mist and a method for removing suspended particulates such as smoke caused by mist, which can eliminate the need for a voltage application unit for applying a charging voltage to the charging and spreading head.

<Verification experiment 2>
Next, a verification experiment 2 in which the scale of the experimental section is enlarged and the effect of the smoke removal method using the charged mist of the present invention is verified will be described.

(1) Sample water The following two were used as sample water as low conductivity water and high conductivity water which is difficult to be charged.
Low conductivity water: deionized water with conductivity = 1.2 μS / cm High conductivity water: tap water with conductivity = 280 μS / cm

(2) Mist discharge conditions As the mist nozzle and mist pump, those having the following performance were used.
Mist nozzle: 6MPa-47mL / min x 20 mist pump: High pressure plunger pump (output 0.4kW)
Mist release time: 2 minutes

(3) Size of experimental section The following capacity was used as the experimental section corresponding to the target section.
1.86m x 1.86m x 1.86m high (capacity: 6.43m ³ )

(4) Smoke generation source Smoke to be removed was generated under the following conditions.
Fuel (fireplate): Automotive gasoline (10cm square, depth 10cm)
Combustion amount: Approximately 50mL
(5) Measurement item The following two data were measured and the smoke removal effect in low conductivity water and high conductivity water was compared.
Measurement item 1 (dimming rate): A Cs meter is grounded at two locations of 1.6 m and 0.8 m in the experimental section, and the change over time of the dimming rate is measured. Measurement item 2 (sedimentation saturation time): constant Measures the time from when the mist is released and after the mist emission is stopped, the recovery of the light extinction rate is saturated due to sedimentation of smoke and water particles

(6) Verification Experiment Procedure Verification data was measured by the following procedure.
Step 1: Ignition of fuel in the experimental compartment Step 2: After combustion is completed, mist is released for 2 minutes, and the recovery status of the dimming rate during mist emission and after mist emission stops until the recovery of the dimming rate is saturated Continuous measurement

  The experimental results of the verification experiment 2 as described above will be described. FIG. 4 is a table summarizing the measurement results of the dimming rate with the elapsed time when the verification experiment 2 according to Embodiment 1 of the present invention was performed.

From the experimental results shown in FIG.
(Effect 1) Improvement of dimming rate As a result of spraying deionized water mist on gasoline combustion smoke for about 2 minutes, the dimming rate, which was about 90% before release, recovered to about 10% after release. ing. On the other hand, when tap water mist is sprayed under the same conditions, the recovery of the fading rate after the discharge is only about 50%. Therefore, the use of low-conductivity water resulted in a significant improvement in the recovery of dimming rate.

(Effect 2) Improvement of sedimentation saturation time Regarding sedimentation saturation time, when deionized water mist was sprayed, the fading rate recovered rapidly in 2 to 3 minutes, while water supply was maintained under the same conditions. When water mist is used, it takes more than 20 minutes. Therefore, the effect of significantly shortening the sedimentation saturation time was obtained by employing deionized water mist.

  As described above, according to the verification experiment 2, even when the scale of the experimental section is enlarged as compared with the previous verification experiment 1, the low conductivity water is sprayed from the dry mist nozzle 4 so that the high conductivity can be achieved. Compared to when spraying tap water, significant improvements were obtained in terms of recovery of the light decay rate and sedimentation saturation time.

<Demonstration experiment 3>
Next, a verification experiment 3 in which the conductivity of the water sprayed from the dry mist nozzle 4 is changed to verify the effect of the smoke removal method using the charged mist of the present invention will be described.

(1) Sample water The following five were used as sample water as low conductivity water and high conductivity water which is hard to be charged.
Low conductivity water (4 types): Deionized water with conductivity = 1, 3, 6, 10 μS / cm High conductivity water: Tap water with conductivity = 280 μS / cm

(2) Mist discharge conditions As the mist nozzle and mist pump, those having the following performance were used.
Mist nozzle: 6MPa-20mL / min x 1 Mist pump: High pressure plunger pump (Output 0.4kW)
Mist release time: 2 minutes

(3) Size of experimental section The following capacity was used as the experimental section corresponding to the protective section.
Glove box (capacity: 100L)

(4) Smoke generation source Smoke to be removed was generated under the following conditions.
Fuel (fireplate): Automotive gasoline (φ25 × 20mm)
Combustion amount: Approximately 3mL
(5) Measurement item The following two data were measured and the smoke removal effect in low conductivity water and high conductivity water was compared.
Measurement item 1 (dimming rate): Measures smoke concentration before and after mist emission (after sedimentation saturation) as Cs meter extinction rate Measurement item 2 (sedation saturation time): Releases mist for a certain period of time and releases mist Measures the time after which the recovery of the light attenuation rate is saturated due to the settling of smoke and water particles

(6) Verification Experiment Procedure Verification data was measured by the following procedure.
Step 1: Ignition of the fuel in the glove box Step 2: After the completion of combustion, mist is released for 2 minutes, and the recovery status of the dimming rate during mist emission and after the mist emission stop until the dimming rate recovery is saturated Continuous measurement

  The experimental results of the verification experiment 3 as described above will be described. FIG. 5 is a table summarizing the measurement results of the dimming rate with the elapsed time when the verification experiment 3 according to Embodiment 1 of the present invention was performed.

Moreover, the following can be understood from the experimental results shown in FIG.
(Effect 1) Improvement of dimming rate Deionized water mist was sprayed on gasoline combustion smoke for about 2 minutes. As a result, the dimming rate, which was about 90% before discharge, was 1 μS / cm after discharge. About 20% for mist, about 25% for deionized water mist at 3 μS / cm, about 35% for deionized water mist at 6 μS / cm, about about 25% for deionized water mist at 10 μS / cm It has recovered to 50%. On the other hand, when the tap water mist is sprayed under the same conditions, the recovery of the light extinction rate is not saturated at 3 minutes 30 seconds after the release, and the recovery is about 60%. It was confirmed that the lower the water conductivity, the higher the smoke removal effect.

(Effect 2) Improvement of sedimentation saturation time As a result of observing the inside of the glove box for 2 minutes during mist spraying, smoke particles adsorb to charged water particles in deionized water mist of 1, 3, 6 μS / cm. Thus, aggregation of smoke particles (that is, a phenomenon in which a large number of smoke particles form an aggregate) was observed. In addition, the same aggregation occurs even after the mist release is stopped. Regarding the sedimentation saturation time, in the case of 1 μS / cm deionized water mist, about 1 minute after the mist release, 3, 6 μS / cm deionized water. In the case of mist, about 1 minute and 30 seconds after mist release, even in the case of 10 μS / cm deionized water mist, the dimming rate recovered rapidly and became saturated in about 2 minutes after mist release. On the other hand, the tap water mist did not rapidly recover the dimming rate, and did not reach saturation even after 3 minutes and 30 seconds had elapsed after release.

  As described above, according to the verification experiment 3, by spraying low-conductivity water having a conductivity of 6 μS / cm or less from the dry mist nozzle 4, a high smoke removal effect is exhibited and a low conductivity having a conductivity of 10 μS / cm. Even when the rate water was sprayed from the dry mist nozzle 4, a result showing a certain smoke removing effect was obtained as compared with the case where tap water was sprayed from the dry mist nozzle 4.

  And as such low electrical conductivity water, deionized water can be employ | adopted, for example, and can be stored in a water storage container beforehand. As a result, it is possible to obtain an apparatus for removing suspended particulates such as smoke caused by mist and a method for removing suspended particulates such as smoke caused by mist, which can eliminate the need for a voltage application unit for applying a charging voltage to the charging and spreading head.

<Verification experiment 4>
Next, a verification experiment 4 in which the effect of the smoke removal method using the charged mist of the present invention is verified by changing the radiation pressure sprayed from the dry mist nozzle 4 will be described.

(1) Sample water The following was used as sample water as low conductivity water.
Low conductivity water: Deionized water with conductivity = 1 μS / cm

(2) Mist discharge conditions The mist nozzles and mist pumps having the following performance were used, and the experiment was conducted by changing the discharge pressure. The number of mist nozzles was adjusted so that the total amount of water was the same.
Mist nozzle: 6MPa-47mL / min
Mist pump: High pressure plunger pump (Output 0.4kW)
Mist discharge time: 2 minutes Mist discharge pressure (3 types): 1.5, 3, 6 MPa
Mist nozzle quantity (3 types): 20 (discharge pressure: 1.5 MPa), 14 (discharge pressure: 3 MPa), 10 (discharge pressure: 6 MPa)

(3) Size of experimental section The following capacity was used as the experimental section corresponding to the target section.
1.86m x 1.86m x 1.86m high (capacity: 6.43m ³ )

(4) Smoke generation source Smoke to be removed was generated under the following conditions.
Fuel (fireplate): Automotive gasoline (10cm square, depth 10cm)
Combustion amount: Approximately 50mL
(5) Measurement item The following two data were measured and the smoke removal effect in low conductivity water and high conductivity water was compared.
Measurement item 1 (dimming rate): A Cs meter is grounded at two locations of 1.6 m and 0.8 m in the experimental section, and the change over time of the dimming rate is measured. Measurement item 2 (sedimentation saturation time): constant Measures the time from when the mist is released and after the mist emission is stopped, the recovery of the light extinction rate is saturated due to sedimentation of smoke and water particles

(6) Verification Experiment Procedure Verification data was measured by the following procedure.
Step 1: Ignition of fuel in the experimental compartment Step 2: After combustion is completed, mist is released for 2 minutes, and the recovery status of the dimming rate during mist emission and after mist emission stops until the recovery of the dimming rate is saturated Continuous measurement

  The experimental results of the verification experiment 4 as described above will be described. FIG. 6 is a table summarizing the measurement results of the dimming rate with the elapsed time when the verification experiment 4 according to Embodiment 1 of the present invention is performed.

  From the experimental results shown in FIG. In the verification experiment 4, the smoke removal effect is compared by changing the size of the mist particle size by changing the discharge pressure while keeping the total water amount substantially constant. In the case of the mist nozzle used in this experiment, the average particle size when released at 1.5 MPa is about 45 μm, the average particle size when released at 3 MPa is about 35 μm, and the average particle size when released at 6 MPa is about 30 μm. It is.

(Effect 1) Improvement of light attenuation rate When deionized water mist is sprayed on gasoline combustion smoke for about 2 minutes, the light attenuation rate of about 85% before release is released at 1.5 MPa after release. Is about 45% when released at about 65% and 3 MPa, and recovered to about 25% when released at 6 MPa. Therefore, if the amount of discharged water is the same, the smaller the mist particle size, the higher the smoke removal effect.

(Effect 2) Improvement of sedimentation saturation time In any case, the recovery of the fading rate was observed during the mist release, and the fading rate decreased rapidly in 2 to 3 minutes after the release. From this result, in this experiment, the dimming rate when released at 1.5 MPa recovered only to about 65%, but even when mist was released at 1.5 MPa, it decreased by increasing the emission amount. Recovery of light rate can be expected.

  As described above, according to the verification experiment 4, it is possible to obtain a high smoke removal effect even with a small amount of water by making the mist particle size smaller, and smoke is emitted if the mist is discharged with an average particle size of 45 μm or less. It was confirmed that a removal effect was obtained.

  Furthermore, from this verification experiment 4, it can be confirmed that the smoke removal effect can be obtained by setting the pressure for releasing the mist to 1.5 MPa or more, preferably 3 MPa or more. It was confirmed that a sufficient smoke removal effect was obtained in both the sedimentation saturation time and the sedimentation saturation time.

  Regarding the verification experiment 4, when generating mists having the same average particle diameter using different nozzles, it has been confirmed that the charge mist generated at a higher discharge pressure has a higher smoke removal effect.

And as such low electrical conductivity water, deionized water can be employ | adopted, for example, and can be stored in a water storage container beforehand. As a result, it is possible to obtain an apparatus for removing suspended particulates such as smoke caused by mist and a method for removing suspended particulates such as smoke caused by mist, which can eliminate the need for a voltage application unit for applying a charging voltage to the charging and spreading head.

  As described above, according to Embodiment 1, low-conductivity water such as deionized water is stored in the water storage container 1 in advance, so that charged water particles are obtained without applying a voltage during spraying. Compared with the case of using high conductivity water such as ordinary tap water, an excellent smoke removal effect can be obtained. As a specific smoke removal effect, significant improvement results in the recovery of the light attenuation rate and the sedimentation saturation time were confirmed through the verification experiment.

  Moreover, in the structure of FIG. 1, although the case where the low electrical conductivity water is previously stored in the water storage container is assumed, this invention is not limited to such a structure. The same effect can be obtained by providing a water conditioner that generates low conductivity water from tap water.

Embodiment 2. FIG.
In the second embodiment, a spray system that combines the temperature lowering function and the smoke removal function using the charging mist described in the first embodiment will be described.

  FIG. 7 is an overall configuration diagram of a spray system according to Embodiment 2 of the present invention. The spray system in FIG. 7 includes a water storage container 1a provided for temperature drop spraying, a pump 2a (an example of a normal water supply device), a valve 3a (an example of a switching mechanism), and a water storage container provided for smoke removal. 1b, a pump 2b (an example of a low-conductivity water supply device), a valve 3b (an example of a switching mechanism), a dry mist nozzle 4, a spray control unit 5, and a smoke detector 6 ( An example of a suspended particle detector).

  Here, the water storage container 1b, the pump 2b, the valve 3b, the dry mist nozzle 4, and the spray control unit 5 provided for smoke removal in FIG. 7 are the same as those shown in FIG. 1 is different from the configuration shown in FIG. 1 in that a water storage container 1a, a pump 2a, a valve 3a, and a smoke detector 6 provided for temperature-fall spraying are further provided.

  The spray control unit 5 according to the second embodiment has a spray water supply mechanism including a water storage container 1a, a pump 2a, and a valve 3a provided for the temperature lowering spray at a normal time when no smoke is generated or inflowing. On the other hand, normal tap water (that is, high conductivity water) is supplied. On the other hand, when the spray control unit 5 detects that smoke is generated or flows in by an external signal from the smoke detector 6, the spray control unit 5 uses the water storage container 1b, the pump 2b, and the valve 3b provided for smoke removal. Low conductivity water is supplied to the dry mist nozzle 4 by the spray water supply mechanism.

  In this way, the spray control unit 5 realizes a spray system having both a smoke removal function by charging mist and a temperature lowering function by switching and controlling the spray water supply mechanism according to the presence or absence of smoke generation or inflow. Yes.

  Further, since both the temperature lowering spray and the smoke removing spray require only a small amount of spray water, the pumps 2a and 2b may be small pumps. Further, as the smoke removal spraying pump 2b, a high pressure type pump can be used in order to obtain a sufficient smoke removal effect.

  As described above, according to the second embodiment, spraying that can achieve a temperature lowering effect using high-conductivity water during normal times, and can achieve a smoke removal effect using low-conductivity water when smoke occurs or flows in. The system can be realized with an inexpensive and simple configuration.

  In addition, as low electrical conductivity water, the thing whose electrical conductivity is 10 microsiemens / cm or less is suitable. By using such low-conductivity water, as described in detail in the first embodiment, a significant improvement result can be obtained in the recovery of the light attenuation rate and the sedimentation saturation time.

  High conductivity water corresponds to water having a conductivity higher than 10 μS / cm. By using such high-conductivity water, it is not necessary to perform a water conditioning treatment to obtain low-conductivity water, and the temperature lowering effect in the target compartment can be obtained using normal tap water or the like.

  In the first and second embodiments, the experiment is performed using smoke as suspended particulates. However, suspended particulates that can be removed by the mist of the present application are not limited to smoke and are harmful to people suspended in the air. For example, pollen, dust, dust, sand dust, PM2.5, and the like.

  In the second embodiment, spraying is normally performed for lowering the temperature. However, the present invention is not limited to this, and when spraying is not necessary, the valves 3a and 3b and the pumps 2a and 2b are provided. You may stop.

  Moreover, in this Embodiment 2, although it is set as temperature-falling as a normal usage method, it is not limited to this, For example, you may use for humidification.

  Moreover, in the structure of FIG. 7, although the case where the low electrical conductivity water is previously stored in the water storage container 1b is assumed, this invention is not limited to such a structure. The same effect can be obtained by providing an ion exchange water conditioner that generates low conductivity water from tap water.

  Moreover, in Embodiment 2 using FIG. 7, although the automatic control which the spray control part 5 switches spray operation according to the detection result of the smoke detector 6 was demonstrated, this invention is limited to such a structure. It is not something. Even if the external signal from the smoke detector 6 and the spray control unit 5 are not used, the same effect can be obtained by switching and driving the valves 3a and 3b and the pumps 2a and 2b by manual operation based on the operator's judgment. .

  In addition, in FIG. 7 of the present embodiment, the dry mist nozzle 4 provided in the target section shows only one system connected in series, but via a system selection mechanism unit such as an electric valve, It is also possible to adopt a configuration that branches into a plurality of systems. And when such a plurality of systems are provided, one of the systems is selected during normal operation, and the operation is switched according to the situation so that all systems are selected when smoke is generated. Is also possible.

  Furthermore, the system selected in the normal time can be rotated every predetermined period.

  DESCRIPTION OF SYMBOLS 1 Water storage container, 1a Water storage container for temperature fall spray, 1b Water storage container for smoke removal spray, 2 pump, 2a Pump for temperature drop spray, 2b Pump for smoke removal spray, 3 valve, 3a Valve for temperature drop spray, 3b Valve for smoke removal spray 4 Dry mist nozzle, 5 spray control unit, smoke detector.

Claims (4)

When suspended particulates such as smoke are generated or flowed into the target compartment, spraying that realizes the suspended particulate removal function is performed, and during normal times when the suspended particulates are not generated or flown, spray that realizes the temperature lowering function is performed. A spraying system,
A spray nozzle that is installed in the target section and sprays water as a mist in the target section;
A low-conductivity water supply device for supplying low-conductivity water corresponding to water having a conductivity of 10 μS / cm or less to the spray nozzle;
A normal water supply device for supplying normal water corresponding to water having a conductivity higher than 10 μS / cm to the spray nozzle;
A spraying system comprising: a switching mechanism that can switch one of the low-conductivity water- feeding device and the normal water-feeding device to an activated state and the other to a stopped state by manual operation or automatic operation. The spray system according to claim 1,
The spray system which made the spray particle diameter of the said mist sprayed from the said spray nozzle 45 micrometers or less. The spray system according to claim 2,
The spray system which made the pressure which discharge | releases the said mist from the said spray nozzle 1.5 MPa or more. The spray system according to any one of claims 1 to 3,
A particle detector that is installed in the target section and sends out an output signal indicating either an abnormal state in which the suspended particles are generated or flown into the target section or a normal state in which the suspended particles are not generated or flown in When,
When the output signal from the particle detector is received and the output signal indicates the normal state, the normal water supply device is activated and the low conductivity water supply device is stopped. When the switching mechanism is controlled and the output signal indicates the abnormal state, the switching mechanism is configured so that the low-conductivity water supply device is activated and the normal water supply device is deactivated. A spray system further comprising: a spray control unit for controlling.

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