JP5785868B2 - Sprinkler fire extinguishing equipment - Google Patents

Description

  The present invention relates to a sprinkler fire-extinguishing equipment, and more particularly to a pre-acting sprinkler fire-extinguishing equipment in which a secondary pipe of a pre-acting valve is in a negative pressure state.

  Conventionally, the secondary side pipe to which the sprinkler head is connected is filled with pressurized water, or the secondary side pipe is filled with compressed gas, and a pre-acting valve is provided on the base end side of the secondary side pipe. There is also a pressurized pre-actuated sprinkler fire extinguishing system. And what fills the inside of secondary side piping with water is called wet, and what is not filled with water is called dry.

  Such a pre-acting sprinkler fire extinguishing system opens the pre-actuating valve when the fire detector installed in the same protection zone as the sprinkler head operates, or when the opening of the sprinkler head is detected along with the operation of the fire detector, Water is passed from the side pipe to the secondary side pipe, and if both the fire detector and the sprinkler head do not operate, the fire pump will not start and the fire fighting water will not be discharged continuously. It is hard to cause water damage by.

  However, in the case of a wet type, if the sprinkler head malfunctions even if the fire sensor does not operate and the pre-actuated valve does not open, the fire-extinguishing water filled in the secondary side pipe may flow out and leak. It was. In the case of the dry type, water will remain in the falling pipe part to which the sprinkler head is connected even if the water that has entered the secondary side pipe is drained after completion of water flow tests at the completion of construction or periodic inspections. In some cases, if the sprinkler head malfunctions even if the fire sensor does not operate and the pre-actuating valve does not open, fire extinguishing water in the falling pipe may flow out and leak.

  Therefore, a negative pressure type pre-acting sprinkler fire extinguishing equipment has been proposed in which a vacuum pump is connected to the secondary side pipe and the inside of the pipe has a negative pressure (see, for example, Patent Documents 1 and 2).

  The inside of the secondary side pipe of the negative pressure type pre-actuated sprinkler fire extinguishing equipment is negative pressure water in the wet type and negative pressure air in the dry type, so that the above-described water leakage does not occur.

Japanese Utility Model Publication No. 6-26292 Republished Patent No. 2000/61238

  However, in the conventional negative pressure pre-acting sprinkler fire extinguishing equipment, the negative pressure in the secondary pipe is obtained by a vacuum pump, and there is a risk that the negative pressure cannot be maintained unless the vacuum pump can be operated. It was.

  Even if an emergency power source is used for the vacuum pump so that the vacuum pump can be operated during a power failure, the vacuum pump with high power consumption cannot be operated for a long time during the power failure. Therefore, a huge emergency power supply had to be provided in order to cope with a long power outage. The present invention has been made to solve the above-described problems, and is an emergency power supply for a vacuum pump in preparation for a power failure, and can maintain a negative pressure in the secondary side pipe for a long time. The purpose is to obtain a pressure-type and pre-actuated sprinkler fire extinguishing system.

The sprinkler fire extinguishing equipment according to the present invention includes a pre-acting valve, a secondary side pipe provided on the secondary side of the pre-acting valve and connected to the sprinkler head, a vacuum pipe connected to the secondary side pipe, A vacuum switch that is connected to the vacuum pipe and operates when the inside of the vacuum pipe is at a pressure higher than a predetermined pressure below atmospheric pressure, and is operated by operating the vacuum switch in a monitoring state. A pre-actuated sprinkler fire extinguishing system comprising a vacuum device that sucks the inside of the secondary side pipe to make a negative pressure less than the predetermined pressure, and the vacuum device is driven only by a commercial power source A first vacuum pump and a second vacuum pump driven by a commercial power supply and driven by an emergency power supply in the event of a power failure , wherein the first vacuum pump is operated alone or the first pump Simultaneously with 2 vacuum pumps Rolling to, a suction force of negative pressure from normal pressure is less than the predetermined pressure of the secondary side inside the pipe, the second vacuum pump in advance the lower than the predetermined pressure at normal monitoring state a suction force enough to maintain the pressure of the secondary side in the pipe became, characterized in that in less power consumption during a power outage, it can maintain a normal in the secondary pipe in the monitoring state a predetermined negative pressure And

Moreover, the sprinkler fire extinguishing equipment according to the present invention is characterized in that the first vacuum pump and the second vacuum pump are alternately operated when the power supply from the commercial power source is received .

  Moreover, the sprinkler fire extinguishing equipment according to the present invention is characterized in that a vacuum tank provided at the inlet of the vacuum device is provided to be interposed in the vacuum pipe.

  According to the sprinkler fire extinguishing equipment according to the present invention, the vacuum pump can be operated with low power consumption. Even if the sprinkler head malfunctions, water damage due to water leakage can be prevented.

1 is a configuration diagram of a sprinkler fire extinguishing facility according to Embodiment 1. FIG. It is a block diagram of the sprinkler fire extinguishing equipment which concerns on Embodiment 2. FIG. FIG. 6 is a configuration diagram of a sprinkler fire extinguishing facility according to Embodiment 3.

[Embodiment 1]
Based on FIG. 1, the sprinkler fire extinguishing equipment according to Embodiment 1 of the present invention will be described.

  First, the configuration of the sprinkler fire extinguishing equipment will be described with reference to FIG.

  The sprinkler fire extinguishing equipment of the present embodiment includes a sprinkler head 2, a pre-actuating valve 22, a primary side pipe 11, a secondary side pipe 12, a vacuum pipe 14, a running water shut-off valve 31, a head operation detecting device 46, and vacuum switches 41 and 52. , Pressurized water supply device 21, repeater 51, fire receiver 4, fire extinguishing system control panel 5, fire extinguishing pump control panel 6, vacuum pump control panel 53, vacuum pump 24 as first vacuum pump, second vacuum pump As a vacuum pump 25.

  The protective section 1 is provided with a plurality of sprinkler heads 2. The protective compartment 1 is provided with a fire detector 3 that detects a fire that has occurred in the protective compartment 1. The fire detector 3 is electrically connected to the fire receiver 4, and the fire receiver 4 that has received the fire alarm from the fire detector 3 sends a fire signal to the fire extinguishing system control panel 5. Further, the fire extinguishing system control panel 5 detects, through the relay 51, a remote start valve 22b that is an electric pilot valve that drives the pre-actuating valve 22 and water flow for extinguishing water due to the opening of the pre-acting valve 22. The water flow signal switch 22a, the on-off valve 47, the vacuum switch 41, and the head operation detection device 46 as detection means are electrically connected, and the fire pump control panel 6 is electrically connected to the pressurized water supply device 21. Has been. The fire extinguishing system control panel 5 is activated by either the vacuum switch 41 that operates at a predetermined pressure or the head operation detection device 46 that operates when the pressure increase per unit time exceeds a predetermined value. It is determined whether the head 2 is activated.

  The plurality of sprinkler heads 2 are each connected to a falling pipe 13. Each of the falling pipes 13 is connected to a secondary side pipe 12 that is not charged in a monitoring state (normal state). One end (base end side) of the secondary pipe 12 is connected to one end (secondary side) of the pre-actuating valve 22 that is closed in the monitoring state and is electrically opened in the event of a fire. Has been. The other end (primary side) of the pre-actuating valve 22 is connected to one end of the primary side pipe 11. Further, the other end (base end side) of the primary side pipe 11 is connected to the discharge port of the pressurized water supply device 21.

  On the other hand, the other end of the secondary side pipe 12 is connected to one end of the terminal test valve 26. A drain pipe 16 is connected to the other end of the terminal test valve 26. Water filled in the secondary side pipe 12 by a water flow test or the like of the sprinkler fire extinguishing equipment is discharged to the outside by opening a drain valve (not shown) provided in the end test valve 26 and the pre-actuating valve 22. In a normal monitoring state, the end test valve 26 is in a closed state.

  In addition, one end of a vacuum pipe 14 is connected to the secondary side pipe 12. A first vacuum pump 24 and a second vacuum pump 25 are connected to the other end of the vacuum pipe 14 via check valves, respectively, and the secondary side pipe 12 is sucked through the vacuum pipe 14 under normal conditions. However, the negative pressure is less than the predetermined pressure below atmospheric pressure.

The vacuum pipe 14 includes a flowing water shut-off valve 31 that closes when the pressure on the secondary side increases from the connection side with the secondary pipe 12 toward the vacuum pumps 24 and 25, and a vacuum that operates at a predetermined pressure or higher. A switch 41, a head operation detecting device 46 that operates when the pressure rise is equal to or higher than a predetermined value, and an orifice 42 are sequentially provided. In order to prevent water remaining in the falling pipe 13 from leaking when the sprinkler head malfunctions or breaks, a negative pressure is applied so that the secondary pipe 12 is sucked strongly, An open / close valve 47 that opens when the time for the negative pressure is shortened after a water test or after a fire fighting activity is connected in parallel with the orifice 42. The vacuum pipe 52 between the orifice 42 and the vacuum pumps 24 and 25 is connected to a vacuum switch 52 that operates at a predetermined pressure not higher than atmospheric pressure, and the internal pressure of the vacuum pipe 14 is less than a predetermined value. Thus, the vacuum pumps 24 and 25 are controlled via the vacuum pump control panel 53.
<Operation of sprinkler fire extinguishing equipment>

  In the sprinkler fire extinguishing equipment according to the present embodiment, in the monitoring state (normal time), the secondary side pipe 12 is not filled with water, the vacuum pumps 24 and 25 are operated, and the secondary side pipe 12 and the vacuum pipe 14 are operated. This is a dry and negative pressure pre-acting sprinkler fire extinguishing facility that has a negative pressure less than a predetermined pressure lower than the atmospheric pressure.

Hereinafter, the operation of the sprinkler fire extinguishing equipment will be described. First, the operation for detecting the operation of the sprinkler head 2 will be described. Next, the fire extinguishing operation of the sprinkler fire extinguishing equipment will be described.
(Sprinkler head operation detection operation)
An operation for detecting the operation of the sprinkler head 2 will be described with reference to FIG.
As described above, in the normal monitoring state, the secondary side pipe 12 and the vacuum pipe 14 have negative pressure. In these secondary side pipes 12 and vacuum pipes 14, air gradually flows in from the connecting part of the falling pipe 13 and the sprinkler head 2, and the negative pressure in the pipe rises (approaches atmospheric pressure). Come). When the vacuum switch 52 detects that the negative pressure in the secondary side pipe 12 and the vacuum pipe 14 are equal to or higher than a predetermined pressure, the control unit 54 in the vacuum pump control panel 53 performs the first vacuum. The vacuum pump 24 is driven through the pump drive unit 55, the vacuum pump 25 is driven through the second vacuum pump drive unit 56, or one or both of them are driven, and the inside of the secondary side pipe 12 and the inside of the vacuum pipe 14 are driven. The negative pressure is kept below a predetermined pressure. In addition, when the pressure in the secondary side pipe | tube 12 which is a negative pressure rises, there exist a case by the action | operation of the sprinkler head 2 and the case by the air inflow from piping. Here, the pressure increase due to the inflow of air from the pipe is detected by the vacuum switch 52, and the pressure increase due to the operation of the sprinkler head 2 is detected by the head operation detection device 46 or the vacuum switch 41.

  When a fire occurs in the protective section 1 and the sprinkler head 2 is activated (when the water outlet of the sprinkler head 2 is opened), the protective section is inserted into the secondary side pipe 12 and the vacuum pipe 14 from the water outlet of the sprinkler head 2. 1 air flows in. Thereby, the pressure in the secondary side piping 12 and the vacuum piping 14 which are negative pressures rises.

  Therefore, in the present embodiment, the pressure in the secondary side pipe 12 and the vacuum pipe 14, which are negative pressures, is detected by the vacuum switch 41 and the vacuum switch 52, and the head operation detector 46 detects the amount of pressure change per predetermined time. Based on the above, the operation of the sprinkler head 2 is detected. More specifically, when air flows in from a pipe connection portion or the like in a monitoring state (normal time), the pressure increase rate in the secondary side pipe 12 and the vacuum pipe 14 which are negative pressures is small. That is, the amount of change per predetermined time in the monitoring state is small. On the other hand, when the sprinkler head 2 is operated, the pressure increase rate in the secondary side pipe 12 and the vacuum pipe 14 which are negative pressures is larger than that in the normal monitoring state. That is, the amount of pressure change per predetermined time when the sprinkler head 2 is operated is larger than that in the monitoring state. The head operation detection device 46 detects the operation of the sprinkler head 2 based on this difference in the pressure change amount per predetermined time. In other words, the head operation detection device 46 determines that the sprinkler head 2 has been operated when the absolute value of the pressure change amount per predetermined time is greater than the predetermined threshold, and controls the fire extinguishing system via the relay 51. The sprinkler head operation signal is sent to the panel 5, and the fire extinguishing system control panel 5 determines that the sprinkler head 2 is activated.

Here, the reason why the head operation detection device 46 detects the operation of the sprinkler head 2 based on the pressure change amount per predetermined time will be described.
The conventional sprinkler fire extinguishing equipment has a sprinkler when the pressure in the secondary pipe 12 and the vacuum pipe 14 which are negative pressures is larger than a certain threshold value (when the pressure is closer to the atmospheric pressure than a certain threshold value). It was determined that the head 2 was activated. Also in the present embodiment, it is determined that the sprinkler head 2 is activated even when the vacuum switch 41 has a pressure equal to or higher than a predetermined threshold. However, since the water outlet of the sprinkler head 2 is smaller than the volume in the secondary side pipe 12 and the vacuum pipe 14, and the pressure difference between the pressure in the secondary side pipe 12 and the protection section 1 is small, the sprinkler head Since the amount of air flowing into the secondary side pipe 12 from 2 is small, it takes time to increase the pressure in the secondary side pipe 12 and the vacuum pipe 14 which are negative pressure. For this reason, when the sprinkler head 2 is operated, for example, the vacuum pumps 24 and 25 are just started to operate, the negative pressure in the secondary pipe 12 and the vacuum pipe 14 is low, and the pressure between the current pressure and a certain threshold value. When the difference is large, it takes time for the pressure to rise to the threshold value, and the detection of the operation of the sprinkler head 2 by the vacuum switch 41 is delayed.

On the other hand, in the present embodiment, the absolute value of the amount of change per predetermined time of the pressure in the secondary side pipe 12 and the vacuum pipe 14 that are negative pressure in the head operation detection device 46 is larger than a predetermined threshold value. It is also determined that the sprinkler head 2 has operated. Therefore, the operation of the sprinkler head 2 can be detected at an early stage regardless of the pressure in the secondary side pipe 12 and the vacuum pipe 14 when the sprinkler head 2 is operated. In this embodiment, when the sprinkler head 2 is operated during operation of the vacuum pumps 24 and 25, the pressure of the secondary side pipe 12 does not change and the head operation detection device 46 is prevented from being operated. The orifice 42 is provided in the vacuum pipe 14 between the head operation detection device 46 and the vacuum pumps 24 and 25.
(Fire fighting operation)

Next, the fire extinguishing operation of the sprinkler fire extinguishing equipment will be described with reference to FIG.
In the monitoring state (normal time), the pre-actuating valve 22 of the primary side pipe 11 is filled with water, and the secondary side pipe 12 and the vacuum pipe 14 are not filled with water.

  When a fire occurs in the protective zone 1, the fire detector 3 that detects the fire sends a fire signal to the fire receiver 4, and the fire receiver 4 that receives this fire signal sends a fire signal to the fire extinguishing system control panel 5. To do. After that, when the sprinkler head 2 is operated and the pressure of the secondary side pipe 12 is increased, the fire extinguishing system control panel 5 operates the vacuum switch 41 or the head operation detection device via the relay 51. The operation of the sprinkler head 2 is detected based on the pressure change amount per predetermined time 46. When both the fire signal and the operation of the sprinkler head 2 are detected, the fire extinguishing system control panel 5 performs control for discharging water.

  The fire-extinguishing system control panel 5 opens the pre-actuation valve 22 by opening the remote start valve 22b when water is discharged, and supplies (fills) fire-extinguishing water to the secondary side pipe 12.

  After the pre-actuating valve 22 is opened, the pressure in the primary side pipe 11 is reduced accordingly. The fire detection pump control panel 6 which has detected the pressure drop by a pressure detection means (not shown) and has received a pressure drop signal from the pressure detection means starts the pressurized water supply device 21 and supplies the water for fire fighting toward the secondary side pipe 12. Pump. When the pre-actuating valve 22 is opened, the running water signal switch 22 a provided in the pre-acting valve 22 transmits a running water signal to the fire extinguishing system control panel 5 via the relay 51.

  Then, the secondary side pipe 12 is filled with fire-extinguishing water, and the fire-extinguishing water in the secondary side pipe 12 that has reached the specified pressure is regulated from the activated sprinkler head 2 to the protective section 1 via the falling pipe 13. Discharge the water at the discharge pressure and extinguish the fire that occurred in the protected area 1.

In the present embodiment, the running water shut-off valve 31 is controlled to be closed by the pressure increase in the secondary side pipe 12. For this reason, even if the pre-actuating valve 22 is opened and water is supplied to the secondary side pipe 12, it is possible to prevent water from flowing into the vacuum pipe 14 downstream from the flowing water shutoff valve 31. That is, water can be prevented from flowing into the vacuum pumps 24 and 25. Therefore, it is possible to prevent the vacuum pumps 24 and 25 from sucking water and stopping due to overload or causing a failure.
(Operation of vacuum pump)

  In the present embodiment, the base end of the vacuum pipe 14 includes a vacuum pump 24 serving as a first vacuum pump via a check valve and a vacuum pump serving as a second vacuum pump via another check valve. 25. The vacuum pump 24 is electrically connected to the first vacuum pump drive unit 55 in the vacuum pump control panel 53, and the vacuum pump 25 is electrically connected to the second vacuum pump drive unit 56 in the vacuum pump control panel 53, respectively. It is connected to the. The first vacuum pump drive unit 55 is connected to a commercial power source 8 as a power source, and the second vacuum pump drive unit 56 is connected to a commercial power source 8 and an emergency power source 7 as power sources. The vacuum pumps 24 and 25 are both drivable when they are alive, and the vacuum pump 25 is drivable when power supply from the commercial power supply 8 is interrupted (power failure).

  The vacuum pump drive units 55 and 56 are similarly controlled by the control unit 54 in the vacuum pump control panel 53. When the vacuum switch 52 connected to the vacuum pipe 14 is operated at a pressure equal to or higher than a predetermined negative pressure equal to or lower than the atmospheric pressure, the control unit 54 that receives this signal performs a vacuum via the vacuum pump driving units 55 and 56. One or both of the pumps 24 and 25 are controlled and driven.

The operation method of the vacuum pumps 24 and 25 differs depending on whether power is supplied from the commercial power supply 8 or when power supply is interrupted.
First, a case where the power supply from the commercial power supply 8 is interrupted (power failure) will be described. In this case, suction is performed so as to maintain the negative pressure of the secondary side pipe 12 only with the vacuum pump 25. However, the vacuum pump 25 has only a suction capability to maintain the negative pressure of the secondary side pipe 12 that has become less than a predetermined pressure in advance in order to suppress power consumption as much as possible. That is, it is possible to operate the emergency power supply 7 for a long time by suppressing power consumption. In this state, at the time of completion, after the fire extinguishing activity, and after the water flow test, when the inside of the secondary side pipe 12 is at a normal pressure, the suction force until it becomes a negative pressure less than a predetermined pressure There is no. It is only possible to maintain the negative pressure in the normal monitoring state, and to reduce power consumption. As a result, the negative pressure in the secondary side pipe 12 can be maintained even if a power failure occurs, so that even if the sprinkler head 2 malfunctions or is damaged, it does not leak and cause water loss.

  Next, a case where power supply from the commercial power source 8 is active will be described. The suction capacity of the vacuum pump 24 is set to be equal to or higher than the suction capacity of the vacuum pump 25. However, since power consumption is large correspondingly, power is not supplied from the emergency power source 7 at the time of a power failure, and operation is not performed.

  When the vacuum switch 52 connected to the vacuum pipe 14 is operated at a pressure equal to or higher than a predetermined negative pressure equal to or lower than the atmospheric pressure, the control unit 54 that has received this signal sends a vacuum via the vacuum pump driving unit 55 or 56. Either of the pumps 24 and 25 is automatically controlled and driven. At this time, in order to extend the lifetime of the vacuum pumps 24 and 25, they may be operated alternately. As in the case of a power failure, such a control method may be used as long as the operation only maintains the negative pressure in the secondary pipe 12.

In addition, when the inside of the secondary pipe 12 is at normal pressure, such as after completion of fire, fire extinguishing activity, and water flow test, operate a quick suction switch (not shown) provided in the vacuum pump control panel 53, The secondary side pipe 12 that has become a normal pressure is strongly sucked so as to have a negative pressure that is less than a predetermined pressure that is equal to or lower than the atmospheric pressure . For example, operating the vacuum pump 24 and vacuum pump 25 at the same time. Alternatively, the vacuum pump 24 may have a suction force stronger than that of the vacuum pump 25 and may be operated alone.
[ Embodiment 2]

A sprinkler fire extinguishing facility according to Embodiment 2 of the present invention will be described with reference to FIG. In FIG. 2, the same parts as those of the first embodiment are denoted by the same reference numerals, and the description thereof is omitted.

  The sprinkler fire extinguishing equipment according to the second embodiment is greatly different from the first embodiment in that the sprinkler fire extinguishing equipment is wet rather than dry, and the sprinkler head 2, the pre-actuating valve 65, the primary side Piping 11, Secondary piping 61, Vacuum piping 14, Vacuum switch 52, Pressurized water supply device 21, Relay device 66, Fire receiver 4, Fire extinguishing system control panel 9, Fire pump control panel 6, Vacuum pump control panel 53, A vacuum pump 24 as a first vacuum pump, a vacuum pump 25 as a second vacuum pump, and the like are included.

  The fire detector 3 that detects a fire that has occurred in the protective compartment 1 is electrically connected to the fire receiver 4, and the fire receiver 4 that has received the fire alarm from the fire detector 3 extinguishes the fire signal. Send to the system control panel 9. Further, the fire extinguishing system control panel 9 detects the flow of fire-extinguishing water by opening the remote start valve 65b, which is an electric pilot valve that drives the pre-actuating valve 65, and the pre-acting valve 65, via the relay 66. The water flow signal switch 65a as a detection means is electrically connected, and the fire pump control panel 6 is electrically connected to the pressurized water supply device 21.

  Each of the plurality of sprinkler heads 2 is connected to the falling pipe 13, and these are connected to the filled secondary side pipe 61 and filled with water in the monitoring state (normal time). One end (base end side) of the secondary side pipe 61 is connected to one end (secondary side) of the pre-actuating valve 65 that is closed in the monitoring state and is electrically opened in the event of a fire. Has been. The other end (primary side) of the pre-actuating valve 65 is connected to one end of the primary side pipe 11. Further, the other end (base end side) of the primary side pipe 11 is connected to the discharge port of the pressurized water supply device 21.

  On the other hand, the other end of the secondary pipe 61 is connected to one end of the terminal test valve 26. A drain pipe 16 is connected to the other end of the terminal test valve 26. The water filled in the secondary side pipe 61 by a water flow test or the like of the sprinkler fire extinguishing equipment is discharged to the outside by opening the end test valve 26. In a normal monitoring state, the end test valve 26 is in a closed state.

  In addition, one end of the vacuum pipe 14 is connected to the secondary side pipe 61 via a branch pipe 62, a water level detector 63, and an on-off valve 64. A vacuum pump 24 and a vacuum pump 25 are connected to the other end of the vacuum pipe 14 via check valves, respectively, and the secondary side pipe 12 is sucked through the vacuum pipe 14 in a normal state and is at a predetermined pressure below atmospheric pressure. The negative pressure should be less than

One end of the water level detector 63 is connected to the secondary pipe 61 via the branch pipe 62, and the other end is connected to the vacuum pipe 14 via the on-off valve 64. When the water level detector 63 has reached a predetermined water level, that is, when the water has stopped at the maximum water level, the water level detector 63 sends a signal to the fire extinguishing system control panel 9 via the repeater 66. The fire extinguishing system control panel 9 that has received the signal sends a signal to the vacuum pump control panel 53 to control the vacuum pumps 24 and 25 to stop operating. This prevents fire-fighting water in the secondary side pipe 61 from flowing out to the vacuum pipe 14 unnecessarily.
<Operation of sprinkler fire extinguishing equipment>

In the sprinkler fire extinguishing equipment according to the present embodiment, in the monitoring state (normal time), the secondary side pipe 61 is filled with water, and the vacuum pumps 24 and 25 are operated to enter the secondary side pipe 61 and the vacuum pipe 14. This is a wet, negative pressure pre-acting sprinkler fire extinguishing facility in which the negative pressure is less than a predetermined pressure lower than the atmospheric pressure.
Hereinafter, the fire extinguishing operation of the sprinkler fire extinguishing equipment will be described.
(Fire fighting operation)

The fire extinguishing operation of the sprinkler fire extinguishing equipment will be described with reference to FIG.
In the monitoring state (normal time), the pre-acting valve 65 of the primary side pipe 11 is filled with water, the secondary side pipe 61 is also filled with fire-extinguishing water, and the secondary pressure by the negative pressure air in the vacuum pipe 14 is secondary. The water for fire extinguishing is kept at a negative pressure in the side pipe 61.

When a fire occurs in the protective zone 1, the fire detector 3 that detects the fire sends a fire signal to the fire receiver 4, and the fire receiver 4 that receives this fire signal sends a fire signal to the fire extinguishing system control panel 9. To do. At this time, the fire extinguishing system control panel 9 opens the pre-actuating valve 65 by opening the remote start valve 65b via the relay 66, and makes the secondary side pipe 61 and the primary side pipe 11 communicate. At this time, the release valve 64 interposed in the vacuum pipe 14 is closed so that the fire-extinguishing water in the secondary side pipe 61 is not sucked. And when the sprinkler head 2 is opened by a fire, the pressure of the primary side piping 11 falls in connection with this. The fire detection pump control panel 6 which has detected the pressure drop by a pressure detection means (not shown) and has received a pressure drop signal from the pressure detection means starts the pressurized water supply device 21 and supplies the water for fire fighting toward the secondary side pipe 12. Pump. When the pre-actuating valve 65 is opened, the water flow signal switch 65 a provided in the pre-acting valve 65 transmits a water flow signal to the fire extinguishing system control panel 9 via the relay 66.
Then, the fire-extinguishing water that has reached the specified pressure in the secondary side pipe 12 is discharged from the activated sprinkler head 2 to the protection section 1 through the falling pipe 13 at the specified discharge pressure, and a fire that has occurred in the protection section 1 Extinguish the fire.
(Operation of vacuum pump)

  In the present embodiment, the base end of the vacuum pipe 14 includes a vacuum pump 24 serving as a first vacuum pump via a check valve and a vacuum pump serving as a second vacuum pump via another check valve. 25. The vacuum pump 24 is electrically connected to the first vacuum pump drive unit 55 in the vacuum pump control panel 53, and the vacuum pump 25 is electrically connected to the second vacuum pump drive unit 56 in the vacuum pump control panel 53, respectively. It is connected to the. The first vacuum pump drive unit 55 is connected to a commercial power source 8 as a power source, and the second vacuum pump drive unit 56 is connected to a commercial power source 8 and an emergency power source 7 as power sources. The vacuum pumps 24 and 25 are both drivable when they are alive, and the vacuum pump 25 is drivable when power supply from the commercial power supply 8 is interrupted (power failure).

  The vacuum pump drive units 55 and 56 are similarly controlled by the control unit 54 in the vacuum pump control panel 53. When the vacuum switch 52 connected to the vacuum pipe 14 is operated at a pressure equal to or higher than a predetermined negative pressure equal to or lower than the atmospheric pressure, the control unit 54 that receives this signal performs a vacuum via the vacuum pump driving units 55 and 56. One or both of the pumps 24 and 25 are controlled and driven.

The operation method of the vacuum pumps 24 and 25 differs depending on whether power is supplied from the commercial power supply 8 or when power supply is interrupted.
First, a case where the power supply from the commercial power supply 8 is interrupted (power failure) will be described. In this case, suction is performed only by the vacuum pump 25 so as to maintain the negative pressure of the secondary side pipe 61. However, the vacuum pump 25 has only a suction capability for maintaining the negative pressure of the secondary side pipe 61 that has previously become less than a predetermined pressure in order to suppress power consumption as much as possible. That is, it is possible to operate the emergency power supply 7 for a long time by suppressing power consumption. It is only possible to maintain the negative pressure in the normal monitoring state, and to reduce power consumption. As a result, even if a power failure occurs, the negative pressure in the secondary side pipe 61 can be maintained. Therefore, even if the sprinkler head 2 malfunctions or is damaged, water leakage does not occur and water damage does not occur.

  Next, a case where power supply from the commercial power source 8 is active will be described. The suction capacity of the vacuum pump 24 is set to be equal to or higher than the suction capacity of the vacuum pump 25. However, since power consumption is large correspondingly, power is not supplied from the emergency power source 7 at the time of a power failure, and operation is not performed.

  When the vacuum switch 52 connected to the vacuum pipe 14 is operated at a pressure equal to or higher than a predetermined negative pressure equal to or lower than the atmospheric pressure, the control unit 54 that has received this signal sends a vacuum via the vacuum pump driving unit 55 or 56. Either of the pumps 24 and 25 is automatically controlled and driven. At this time, in order to extend the lifetime of the vacuum pumps 24 and 25, they may be operated alternately. As in the case of a power failure, such a control method may be used as long as the operation only maintains the negative pressure in the secondary pipe 12.

In addition, when the inside of the secondary pipe 12 is at normal pressure, such as after completion of fire, fire extinguishing activity, and water flow test, operate a quick suction switch (not shown) provided in the vacuum pump control panel 53, The secondary side pipe 12 that has become a normal pressure is strongly sucked so as to have a negative pressure that is less than a predetermined pressure that is equal to or lower than the atmospheric pressure . For example, operating the vacuum pump 24 and vacuum pump 25 at the same time. Alternatively, the vacuum pump 24 may have a suction force stronger than that of the vacuum pump 25 and may be operated alone.
[ Embodiment 3]

A sprinkler fire extinguishing facility according to Embodiment 3 of the present invention will be described with reference to FIG. In FIG. 3, the same parts as those of the first embodiment are denoted by the same reference numerals, and the description thereof is omitted.

  The sprinkler fire extinguishing equipment according to the third embodiment is different from the first embodiment in that the sprinkler fire extinguishing equipment is provided with a vacuum tank 50 which is an inlet portion of vacuum pumps 24 and 25 which are vacuum devices and is interposed in the vacuum pipe 14. .

  By providing the vacuum tank 50, the pressure fluctuation applied to the vacuum switch 52 is reduced, and hence the frequency of intermittent operation of the vacuum switch 52 is reduced, so that the intermittent operation of the vacuum pumps 24, 25 is reduced. For this reason, the number of times of startup when the vacuum pumps 24 and 25 consume the most power is reduced, so that the power consumption can be reduced. The volume of the vacuum tank 50 is appropriately determined so that the pressure fluctuation is suppressed within a desired range according to the volumes of the secondary side pipe 12 and the vacuum pipe 14.

  The vacuum tank 50 is most effective when the power supply from the commercial power supply 8 is interrupted (when a power failure occurs). That is, the volume of the vacuum tank 50 is appropriately determined so as to maintain the vacuum pressure for a predetermined time according to the volumes of the secondary side pipe 12 and the vacuum pipe 14, thereby reducing the power consumption of the vacuum pump 25, thereby It is possible to suppress the consumption of the power source 7 and extend the operable time. Further, the negative pressure in the secondary pipe 12 can be maintained by the negative pressure air in the vacuum tank 50 to some extent.

  In this embodiment, a vacuum tank is provided in the dry negative pressure type pre-acting sprinkler fire extinguishing equipment of the first embodiment, but the wet negative pressure type pre-acting sprinkler fire extinguishing equipment shown in the second embodiment. The power consumption of the vacuum pump 25 can be reduced, thereby suppressing the consumption of the emergency power supply 7 and extending the operable time.

1 Protective area, 2 Sprinkler head, 3 Fire detector,
4 Fire receiver, 5, 9 Fire extinguishing system control panel, 6 Fire extinguishing pump control panel,
7 Emergency power supply, 8 Commercial power supply, 10 Fire fighting water tank, 11 Primary side piping,
12, 61 Secondary piping, 13 Falling piping, 14 Vacuum piping,
16 drainage pipe, 21 pressurized water supply device, 22, 65 pre-actuated valve,
22a, 65a Flow water signal switch, 22b, 65b Remote start valve,
24 first vacuum pump, 25 second vacuum pump,
26 Terminal test valve, 31 Run-off valve, 41 Vacuum switch,
42 orifice, 46 head operation detection device, 47, 64 on-off valve,
51, 66 repeater, 52 vacuum switch, 53 vacuum pump control panel,
54 control unit, 55 first pump drive unit, 56 second pump drive unit,
62 branch pipe, 63 water level detector

Claims (3)

A pre-actuating valve;
A secondary pipe provided on the secondary side of the pre-acting valve and connected to the sprinkler head;
A vacuum pipe connected to the secondary pipe;
A vacuum switch connected to the vacuum pipe and operating when the inside of the vacuum pipe is at a pressure not lower than a predetermined pressure below atmospheric pressure;
A vacuum device that operates by operating the vacuum switch in a monitoring state, and sucks the inside of the secondary side pipe through the vacuum pipe to make the negative pressure less than the predetermined pressure; and
In a pre-actuated sprinkler fire extinguishing system comprising:
The vacuum device includes a first vacuum pump driven only by a commercial power source, and a second vacuum pump driven by a commercial power source and driven by an emergency power source during a power failure .
The first vacuum pump is operated alone or simultaneously with the second vacuum pump, and the pressure in the secondary side pipe is changed from normal pressure to a negative pressure less than the predetermined pressure. With suction,
The second vacuum pump has a suction force sufficient to maintain the pressure in the secondary side pipe that has become less than the predetermined pressure in a normal monitoring state in advance ,
A sprinkler fire extinguishing system characterized in that the secondary pipe can be maintained at a predetermined negative pressure in a normal monitoring state with low power consumption during a power failure . The sprinkler fire extinguishing equipment according to claim 1, wherein when the power supply from the commercial power source can be received, the first vacuum pump and the second vacuum pump are operated alternately . The sprinkler fire extinguishing equipment according to claim 1 or 2 , further comprising a vacuum tank provided at an inlet portion of the vacuum device so as to be interposed in the vacuum pipe.