JP2021137206A - Fire hydrant device - Google Patents

Abstract

To visually check what range discharged water reaches in each of rod-like water discharging and spray water discharging when discharging water from a nozzle of a fire hydrant device.SOLUTION: A fire hydrant device includes a hose (140) and a nozzle (150) connected to the hose (140). The nozzle (150) is configured so as to switch water discharging between rod-like water discharging and spray water discharging, and is provided with a light source (160) for emitting light by switching an illumination range between a narrow illumination range according to the rod-like water discharging and a wide illumination range according to the spread of the spray water discharging.SELECTED DRAWING: Figure 1

Description

The present invention relates to a fire hydrant device, and more particularly to a fire hydrant device capable of confirming a target position or range of water discharged by a nozzle.

Fire hydrant devices for extinguishing fires are installed in various places. A hose equipped with a nozzle is housed in the fire hydrant device. In the event of a fire, the operator opens the fire hydrant door of the fire hydrant device, takes out the nozzle, pulls out the hose, and operates the fire hydrant valve open / close lever to discharge water from the nozzle.

The nozzle is configured to be able to switch between narrow-angle rod-shaped water discharge and wide-angle spray water discharge. Rod-shaped water discharge is to discharge water in a straight line or at a narrow angle, and is mainly used when trying to maximize the fire extinguishing ability while maintaining a sufficient water discharge distance.
On the other hand, the spray water discharge is to discharge water at a wider angle than the rod-shaped water discharge, and is used when the operator approaches the fire source while reducing the radiant heat from the fire. Switching between rod-shaped water discharge and spray water discharge can be performed by rotating the ring-shaped operating unit provided on the nozzle.

In the conventional fire hydrant device, the operator relies on his or her intuition to operate the nozzle and discharge water toward the fire source. For this reason, it was difficult to accurately direct the water discharge to the fire source. As described above, when the water discharged by the nozzle is not accurately discharged to the fire source, there is a problem that not only the initial fire extinguishing is delayed but also the water loss is caused by the inaccurate water discharge.

JP-A-2002-291923

Patent Document 1 discloses a technique in which a laser pointer is attached to a water cannon device to facilitate aiming at a fire source. However, the technique disclosed in Patent Document 1 has a problem that it is not possible to grasp what the water discharge range will be when the nozzle is operated to switch between narrow-angle rod-shaped water discharge and wide-angle spray water discharge. .. Therefore, it is desired to be able to confirm the target position or target range of water discharge according to the state of water discharge from the nozzle.

The present invention has been made to solve the above problems, and an object of the present invention is to provide a fire hydrant device capable of confirming a target position or a target range of water discharge.

(1) The fire hydrant device according to the present invention is a fire hydrant device having a hose and a nozzle connected to the hose, and a light source capable of emitting light in a variable irradiation range is attached to the nozzle. Here, the variable irradiation range includes a narrow irradiation range and a wide irradiation range.

(2) In the fire hydrant device of (1) above, the nozzle is configured to be able to switch between rod-shaped water discharge and spray water discharge, and has a narrow irradiation range according to the rod-shaped water discharge and a wide range according to the spread of the spray water discharge. A light source that irradiates light by switching to the irradiation range is installed.

(3) In the above-mentioned fire hydrant devices (1) and (2), the light source irradiates light by alternately switching between a narrow irradiation range and a wide irradiation range.
(4) In the above (1) to (2) fire hydrant devices, the light source irradiates light between the narrow irradiation range and the wide irradiation range while repeatedly changing the irradiation range in a continuous state.

(5) In the above-mentioned fire hydrant devices (1) and (2), the light source simultaneously executes irradiation in a narrow irradiation range and irradiation in a contour in a wide irradiation range.
(6) In the above-mentioned fire hydrant devices (1) to (5), the light source includes a control unit that controls the narrow irradiation range and the wide irradiation range to irradiate light.

(7) In the fire hydrant device of (6) above, the light source irradiates light into a narrow irradiation range and a wide irradiation range by scanning the light beam output from the light source.
(8) In the fire hydrant device of (6) above, the light source irradiates light into a narrow irradiation range and a wide irradiation range by adjusting the direction of the light source.

(9) In the fire extinguisher device of (6) above, the light source includes a first light source that irradiates light in a narrow irradiation range and a second light source that irradiates light in a wide irradiation range, and the control unit is a first light source. At least one of the light source and the second light source is selected, and at least one of the first light source and the second light source selected by the control unit irradiates the light.

(10) In the fire hydrant devices (1) to (9) above, the nozzle is provided with an operation unit for switching between rod-shaped water discharge and spray water discharge, and the light source has a narrow irradiation range and a wide irradiation range according to the operation of the operation unit. To irradiate light by switching between.

(11) In the fire hydrant devices (1) to (10) above, the nozzle is provided with an operation unit for switching between rod-shaped water discharge and spray water discharge, and the light source is when the nozzle discharges rod-shaped water based on the operation of the operation unit. Irradiates a narrow irradiation range with light, and when the nozzle sprays water, it irradiates a wide irradiation range with light.

(12) In the fire hydrant devices (1) to (10) above, the nozzle is provided with an operation unit for switching between rod-shaped water discharge and spray water discharge, and the light source is when the nozzle discharges rod-shaped water based on the operation of the operation unit. Irradiates a wide irradiation range with light, and when the nozzle sprays water, it irradiates a narrow irradiation range with light.

(13) In the above (1) to (12) fire hydrant devices, the hose is housed in a fire hydrant box, and at least a fire hydrant valve that supplies water to the hose by being operated in the closed state and the open state at all times is provided. Be prepared.

According to the fire hydrant device of the present invention, it is possible to confirm the target position of the rod-shaped water discharge or the target range of the spray water discharge by the light emitted from the light source.

It is a block diagram which shows the structural example of the fire hydrant apparatus in Embodiment 1 of this invention. It is a block diagram which shows the structural example of the nozzle of the fire hydrant device in Embodiment 1 of this invention. It is a block diagram which shows the circuit structure of the light source of the fire hydrant device in Embodiment 1 of this invention. It is explanatory drawing which shows the water discharge state of the nozzle of the fire hydrant device and the light emission state of a light source in Embodiment 1 of this invention. It is explanatory drawing which shows the other example of the water discharge state of the nozzle of the fire hydrant device and the light emission state of a light source in Embodiment 1 of this invention.

Hereinafter, embodiments of the fire hydrant device of the present invention will be described with reference to the drawings. In each figure, the same parts are designated by the same reference numerals.

Embodiment 1.
First, the basic configuration of the fire hydrant device 100 according to the first embodiment of the present invention will be described with reference to FIG. FIG. 1 is a configuration diagram showing a configuration example of the fire hydrant device 100 according to the first embodiment of the present invention.

[Configuration of fire hydrant device 100]
In FIG. 1, the fire hydrant device 100 includes a fire hydrant box 101, a pipe 110, an operation lever 120, a fire hydrant valve 130, a hose 140, a nozzle 150, and a light source 160.

A hose 140 to which a nozzle 150 is attached is wound and stored in the fire hydrant device 100. FIG. 1 shows a state in which the nozzle 150 and the hose 140 are pulled out. A nozzle 150 is attached to one end of the hose 140, and the other end is connected to one end of the fire hydrant valve 130. The other end of the fire hydrant valve 130 is connected to the pipe 110. The pipe 110 is supplied with fire-fighting water from a pump facility (not shown). The fire hydrant valve 130 is always in the closed state, and is operated in the open state by the operating lever 120 to supply water to the hose. The fire hydrant valve 130 may be either a mechanical type or an electric type. The nozzle 150 is equipped with a light source 160 capable of emitting light in a variable irradiation range and irradiating light in the water discharge direction.

The detailed configuration of the nozzle 150 will be described with reference to FIGS. 2 and 3. FIG. 2 is a configuration diagram showing a configuration example of the nozzle 150 of the fire hydrant device 100 according to the first embodiment of the present invention. FIG. 2A shows a straight type nozzle 150 to which a light source 160 is attached, and FIG. 2B shows a nozzle 150 with a grip to which a light source 160 is attached.

The nozzle 150 shown in FIG. 2A is for discharging the cylindrical tubular portion 151, the connecting portion 153 to which the hose 140 is connected, and the water supplied via the hose 140 in a predetermined water discharge shape. It is equipped with a water outlet 155. A switching operation ring 157 is provided around the water discharge port 155. By turning this switching operation ring 157, the water discharge switching mechanism built in the water discharge port 155 operates to switch between rod-shaped water discharge and wide-angle spray water discharge.

A light source 160 capable of irradiating light in the water discharge direction and capable of emitting light in a variable irradiation range is attached to the vicinity of the water discharge port 155 of the nozzle 150. In the case of (a) of FIG. 2, the light source 160 is attached to the tubular portion 151, but the attachment location is not limited.

The nozzle 150 shown in FIG. 2B has a cylindrical tubular portion 151, a grip 152 as a grip portion attached to the tubular portion 151, a connecting portion 153 to which the hose 140 is connected, and a hose. It is provided with a water discharge port 155 for discharging the water supplied via the 140 in a predetermined water discharge shape, and a switching operation ring 157 for switching the water discharge.

A light source 160 capable of irradiating light in the water discharge direction and capable of emitting light in a variable irradiation range is attached to the vicinity of the water discharge port 155 of the nozzle 150. In the case of (b) of FIG. 2, the light source 160 is attached to the tubular portion 151, but the light source 160 may be attached to the grip 152.

FIG. 3 shows the electrical configuration of the light source 160 capable of emitting light in a variable irradiation range. FIG. 3 is a configuration diagram showing a circuit configuration of a light source 160 of the fire hydrant device 100 according to the first embodiment of the present invention.

The light source 160 includes a control unit 161, a power supply unit 162, and a laser diode 163. The detection result of the sensor 157s provided on the switching operation ring 157 is transmitted to the control unit 161. When either the rod-shaped water discharge or the spray water discharge is selected by the rotation of the ring of the switching operation ring 157, the sensor 157s transmits the detection result of the operation state of the switching operation ring 157 to the control unit 161.

The control unit 161 receives power from the power supply unit 162, and based on the operation state of the switching operation ring 157 by the sensor 157s, the control unit 161 has a narrow irradiation range corresponding to the rod-shaped water discharge and a wide irradiation range corresponding to the spread of the spray water discharge. By switching, the laser diode 163 is controlled to irradiate light.

In the light source 160, the laser diode 163 receives power from the power supply unit 162 and switches between a narrow irradiation range corresponding to the rod-shaped water discharge and a wide irradiation range according to the spread of the spray water discharge based on the control of the control unit 161. Lights up. In this way, the light source 160 capable of emitting light in a variable irradiation range can switch between a narrow irradiation range corresponding to the rod-shaped water discharge and a wide irradiation range corresponding to the spread of the spray water discharge to emit light.

When the light source 160 emits light in a narrow irradiation range, it may be adjusted to the discharge range of the rod-shaped discharge, but the center point of the discharge range of the rod-shaped discharge may be pinpointed by parallel light from the laser diode 163. .. That is, the emission of the laser diode 163 in the narrow irradiation range includes the irradiation of parallel light. In the following description, parallel light irradiation will be used as the light emission in the narrow irradiation range of the laser diode 163.
Further, when the light source 160 emits light in a narrow irradiation range, the parallel light from the laser diode 163 can be scanned for the parallel light so as to draw a circle along the contour of the narrow range due to the rod-shaped water discharge.

On the other hand, when the light source 160 emits light in a wide irradiation range, the laser diode 163 may directly generate a light beam having a spread, but the parallel light is scanned so as to draw a circle along the contour of the wide irradiation range. Can be done. That is, the light emission in the wide irradiation range of the laser diode 163 includes the irradiation of parallel light that causes the optical axis to move.

When the light source 160 emits light in a wide irradiation range, a small electromagnetically driven mirror that applies MEMS (Micro-Electro-Mechanical Systems) technology is used as a method for scanning in a circular motion with parallel light. Various methods such as a method to be used and a method of mechanically moving the laser diode 163 can be used.

Further, when the light source 160 emits light in a wide irradiation range, a method of emitting light of a plurality of laser diodes 163 prepared in advance so as to irradiate parallel light at any position on the contour of the wide irradiation range may be used. good.

Further, as a control of light emission of the laser diode 163 at the time of water discharge, the control unit 161 controls to irradiate light by alternately switching between a narrow irradiation range and a wide irradiation range regardless of the operating state of the switching operation ring 157. You may.

Further, as a control of the light emission of the laser diode 163 at the time of water discharge, the control unit 161 may control to simultaneously irradiate the light in the narrow irradiation range and the wide irradiation range regardless of the operating state of the switching operation ring 157. good.

Further, as a control of the light emission of the laser diode 163 at the time of water discharge, the control unit 161 eliminates the irradiated laser light between the narrow irradiation range and the wide irradiation range regardless of the operating state of the switching operation ring 157. The irradiation range may be changed smoothly so as to be in a continuous state.

The state of water discharge from the nozzle 150 and light emission from the light source 160 will be described with reference to FIG. FIG. 4 is an explanatory diagram showing a water discharge state of the nozzle 150 of the fire hydrant device 100 and a light emission state of the light source 160 according to the first embodiment of the present invention.

FIG. 4A shows a state in which the nozzle 150 discharges rod-shaped water, and W1 shows a flow of water due to rod-shaped water discharge.

Here, the control unit 161 receives the detection result of the sensor 157s for the switching operation ring 157 operated to discharge the rod-shaped water, and the light source 160 so as to emit light L1 in a narrow irradiation range in accordance with the rod-shaped water discharge of the nozzle 150. To control. That is, the light source 160 capable of emitting light in a variable irradiation range emits light L1 in a narrow irradiation range in accordance with the rod-shaped water discharge of the nozzle 150.

As a result, the operator can confirm the target position of the rod-shaped water discharge by referring to the position irradiated by the light emitting L1 in the narrow irradiation range from the light source 160.

Therefore, the operator does not operate the nozzle 150 by relying on his or her intuition, but refers to the target position irradiated by the light emitting L1 in the narrow irradiation range from the light source 160, and uses the rod-shaped water discharged by the nozzle 150 as the fire source. You will be able to do it accurately toward. Therefore, it is possible to suppress the delay of initial fire extinguishing and the occurrence of water loss due to inaccurate water discharge.

FIG. 4B shows how the nozzle 150 sprays and discharges water, and W2 shows the flow of water by spraying and discharging water.

Here, the control unit 161 receives the detection result of the sensor 157s for the switching operation ring 157 operated to perform the spray water discharge, and the light source 160 so as to perform the light emission L2 in a wide irradiation range in accordance with the spray water discharge of the nozzle 150. To control. That is, the light source 160 capable of emitting light in a variable irradiation range emits light L2 in a wide irradiation range in accordance with the spray water discharge of the nozzle 150.

As a result, the operator can confirm the target range of the sprayed water by referring to the range irradiated by the light emitting L2 in the wide irradiation range from the light source 160.

Therefore, the operator does not operate the nozzle 150 by relying on his or her intuition, but refers to the range irradiated by the light emitting L2 in the wide irradiation range from the light source 160, and uses the spray water discharged by the nozzle 150 as the fire source. You will be able to do it accurately. Therefore, it is possible to suppress the delay of initial fire extinguishing and the occurrence of water loss due to inaccurate water discharge.

Another example of discharging water from the nozzle 150 and emitting light from the light source 160 will be described with reference to FIG. FIG. 5 is an explanatory diagram showing another example of the water discharge state of the nozzle 150 of the fire hydrant device 100 and the light emission state of the light source 160 according to the first embodiment of the present invention.

FIG. 5A shows a state in which the nozzle 150 discharges rod-shaped water, and W1 shows a flow of water due to rod-shaped water discharge.

Here, the control unit 161 receives the detection result of the sensor 157s for the switching operation ring 157 operated to perform the rod-shaped water discharge, and has a wide irradiation range matched to the spray water discharge, which does not match the rod-shaped water discharge of the nozzle 150. The light source 160 is controlled so as to emit light L2. That is, the light source 160 capable of emitting light in a variable irradiation range intentionally emits light L2 in a wide irradiation range in accordance with the spray water discharge when the nozzle 150 discharges rod-shaped water.

As a result, the operator can confirm the target position of the rod-shaped water discharge by predicting the vicinity of the center while referring to the range irradiated by the light emitting L2 in the wide irradiation range from the light source 160.

Therefore, the operator does not operate the nozzle 150 by relying on his or her intuition, but refers to the range irradiated by the light emitting L2 in the wide irradiation range from the light source 160 and aims toward the vicinity of the center of the range. The rod-shaped water discharged by the nozzle 150 can be accurately directed toward the fire source. Therefore, it is possible to suppress the delay of initial fire extinguishing and the occurrence of water loss due to inaccurate water discharge.

FIG. 5B shows a state in which the nozzle 150 is spraying water, and W2 shows the flow of water by spraying water.

Here, the control unit 161 receives the detection result of the sensor 157s for the switching operation ring 157 operated to perform the spray water discharge, and has a narrow irradiation range matched to the rod-shaped water discharge, which does not match the spray water discharge of the nozzle 150. The light source 160 is controlled so as to emit light L1. That is, the light source 160 capable of emitting light in a variable irradiation range intentionally emits light L1 in a narrow irradiation range in accordance with the rod-shaped water discharge when the nozzle 150 sprays water.

As a result, the operator can confirm the target range of the sprayed water by predicting the surroundings while referring to the target position irradiated by the light emitting L1 in the narrow irradiation range from the light source 160.

Therefore, the operator does not operate the nozzle 150 by relying on his or her intuition, but refers to the target position irradiated by the light emitting L1 in the narrow irradiation range from the light source 160 and covers the surrounding area. The spray water discharged by the nozzle 150 can be accurately directed toward the fire source. Therefore, it is possible to suppress the delay of initial fire extinguishing and the occurrence of water loss due to inaccurate water discharge.

Further, not limited to the specific examples shown in FIGS. 4 and 5, when the rod-shaped water is discharged by the nozzle 150, the light emitting L1 in the narrow irradiation range from the light source 160 shown in FIG. 4A and The light emission L2 in a wide irradiation range from the light source 160 shown in FIG. 5A may be alternately repeated. Alternatively, while the rod-shaped water is discharged by the nozzle 150, the light emitting L1 in the narrow irradiation range and the light emitting L2 in the wide irradiation range may be executed at the same time.

In this case as well, the operator did not operate the nozzle 150 by relying on his or her intuition, but was irradiated by the light emission L1 in the target range and the narrow irradiation range irradiated by the light emission L2 in the wide irradiation range from the light source 160. With reference to the target position, the rod-shaped water discharge by the nozzle 150 can be accurately performed toward the fire source toward the vicinity of the center of the range. Therefore, it is possible to suppress the delay of initial fire extinguishing and the occurrence of water loss due to inaccurate water discharge.

Further, the present invention is not limited to the specific examples shown in FIGS. 4 and 5, and when spray water is discharged by the nozzle 150, the light emission L2 in a wide irradiation range from the light source 160 shown in FIG. The light emission L1 in the narrow irradiation range from the light source 160 shown in FIG. 5B may be alternately repeated. Alternatively, when spraying water is discharged by the nozzle 150, the light emitting L2 in the wide irradiation range and the light emitting L1 in the narrow irradiation range may be executed at the same time.

In this case as well, the operator does not operate the nozzle 150 by relying on his or her own intuition, but instead of operating the nozzle 150, the target position and wide irradiation irradiated by the light emission L1 in the narrow irradiation range from the light source 160 capable of emitting light in the variable irradiation range. With reference to the light emitting L2 in the range and the more irradiated target range, the spray water discharged by the nozzle 150 can be accurately directed toward the fire source so as to cover the surrounding area. Therefore, it is possible to suppress the delay of initial fire extinguishing and the occurrence of water loss due to inaccurate water discharge.

Other embodiments.
Not limited to the above specific description, various modifications can be made as the fire hydrant device 100.

The light source 160 is attached to the tubular portion 151 so as to be located at the lower part of the water discharge port 155 in FIGS. 1, 2, 4 to 5, but the light source 160 is not limited to this state and emits light in the water discharge direction. The mounting position is not limited as long as it can be irradiated. For example, the appearance of the nozzle 150 can be made the same as the conventional one by incorporating it in the water discharge port 155 or the grip 152. The nozzle 150 is shown in FIGS. 1, 2, and 4 to 5 as being handheld, but the nozzle 150 is not limited to this, and may be of the type of a water cannon attached to a support base.

When switching between a plurality of water discharge angles a1, a2, ... As spray water discharge, the light emission L2 in the wide irradiation range described above is matched with the plurality of water discharge angles a1, a2, ... , L2_a2, ... may be set.

The control unit 161 considers that the discharged water is shifted downward according to the distance from the nozzle 150 to the fire source and arrives at the irradiation position by the light emitting L1 in the narrow irradiation range and the irradiation range by the light emitting L2 in the wide irradiation range. Can be set by shifting it downward.

The light emission L1 in the narrow irradiation range and the light emission L2 in the wide irradiation range are not limited to the light irradiation in which a circle is drawn. That is, it is possible to irradiate various types of light so that the target position or target range of water discharge can be confirmed. For example, the target position or the target range may be confirmed by irradiating the target position or the target range with light on the left and right, the top and bottom, or the top, bottom, left and right outside the target range. The mark to be displayed is not limited to the mark in parentheses, and various modifications such as the mark of an arrow pointing to the target position or the target range can be performed.

100 fire hydrant device, 101 fire hydrant box, 110 piping, 120 operation lever, 130 fire hydrant valve, 140 hose, 150 nozzle, 151 cylinder, 152 grip, 153 connection, 155 water outlet, 157 switching operation ring, 157s sensor, 160 light source , 161 control unit, 162 power supply unit, 163 laser diode, water flow by W1 rod-shaped water discharge, water flow by W2 spray water discharge, L1 narrow irradiation range light emission, L2 wide irradiation range light emission.

Claims (1)

A fire hydrant device having a hose and a nozzle connected to the hose.
A fire hydrant device characterized in that a light source capable of emitting light in a variable irradiation range is attached to the nozzle.

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