DE102012023198A1 - Cooling of mains of a firefighting system - Google Patents

Abstract

Method for cooling main lines of a fire fighting system 2 with, receiving an alarm signal, activating a circulation of extinguishing fluid in the main line 3 in response to the received alarm signal, in such a way that extinguishing fluid flows as a cooling medium through the main lines 3 for a defined waiting time and after the waiting time has expired Opening at least one range valve 10.

Description

The subject matter relates to a method for cooling main lines of a fire-fighting system and a fire-fighting system.

Firefighting systems are usually made of piping, pumps, valves and extinguishing nozzles. The pumps are connected to piping and with the aid of the piping, the pumps can pump extinguishing fluid to the extinguishing nozzles. In large firefighting systems individual firefighting areas are formed by so-called area valves. Divisional valves connect a main extinguishing fluid line (main line) to a subdistribution (area lines), with subdistribution ducts usually connected to extinguishing nozzles. Thus, a plurality of extinguishing nozzles can be assigned to a range valve, wherein the extinguishing nozzles each cover a common area together, so that a fire in this area can be controlled by these extinguishing nozzles. If the corresponding area valve opens, the area lines and extinguishing nozzles of this area are charged with extinguishing fluid and extinguishing fluid is discharged.

The use of area valves prevents fire extinguishing fluid from being discharged through all firefighting nozzles of the firefighting system. It is ensured that extinguishing fluid can be applied only in those areas where a fire is actually present. For this purpose, the range valves or the arranged servomotors or the solenoid valves are controlled by corresponding control signals, wherein the control signals are such that the range valves are opened, in which the fire is located.

The range valves are usually opened by servomotors. The servomotors usually open and close the ball valves of the valves, the opening and closing usually lasting several seconds, sometimes up to one minute. Also solenoid valves can be used.

Particularly in the area of tunnels, firefighting is an enormously important safety feature. If trucks, cars, trains or other vehicles in tunnels are not cleared quickly enough, it can lead to catastrophic consequences. In addition, in tunnels, the heat in the area of a fire is enormous. This tremendous heat build-up in tunnels can cause temperatures of over 800 ° C, even over 1000 ° C, to occur even before a fire-fighting operation has started, which can severely damage the mains, divider valves, or divider ducts.

Also, an evacuation of people in the context of self-rescue or foreign rescue z. B. be required by the fire department from the fire areas before firefighting takes place. In this case, the activation of the fire fighting and the application of cooling extinguishing fluid z. B. fire-extinguishing water deliberately delayed and an enormous heat development in the main line taken into account.

Therefore, in the case of known firefighting systems, the enormous development of heat is problematic, in particular if firefighting is to be enabled due to a very large area to be monitored and thus a detection delay, or evacuation possibility should be possible before discharging extinguishing liquid.

From the DE 10 2010 011 763 A1 It is known to ensure a cooling of the area valves and area lines in that some area valves are opened in a pre-alarm and thus extinguishing fluid is discharged before the actual firefighting, however, which is independent of the position of the fire and only serves to cool the area lines. Often, a discharge of extinguishing fluid over the area lines in this phase, before the actual activation of the fire-fighting system, but not possible because a possibly limited existing supply of extinguishing fluid is not (partially) used up.

For this reason, the object of the object to provide a fire fighting available, which efficiently prevents or reduces the damage of mains by heat development.

This object is achieved in one aspect by a method for cooling mains of a firefighting system comprising the steps of receiving an alarm signal, activating a circulation of extinguishing fluid such that extinguishing fluid flows as cooling medium through the main line for a defined waiting time and after expiry of the waiting period opening at least one area valve.

It has been recognized that, before an effective fire-fighting operation can be started, in some cases a waiting period has to be accepted in order to facilitate evacuation measures. This waiting time can depend on the spatial conditions and the existing escape routes z. B. between 1 minute and 60 minutes. During the waiting period, an enormous heat development can already occur, especially in the case of main ducts installed on the ceilings of tunnels. To counteract this heat development, it is proposed that in the event of an alarm signal or Pre-alarm signal is a circulation of extinguishing liquid in the main line is enabled.

For this purpose, the main line is preferably installed annularly at least in parts, such that a circulation through this annular part is possible. Preferably, the main line is a closed ring with an extinguishing fluid supply line, which is preferably fed by a pump. It is also possible to apply a first end of the main line with extinguishing fluid and to let emerge at a second end of the extinguishing fluid from the main line. Then there would be no closed, but an open system.

A circulation can z. B. be made possible by at least one circulation pump. Also, for example, a circulation direction may be determined, particularly by using one circulation pump for each direction of the ring of the main pipe. The circulation direction can be selected, for example, depending on the detected fire. In particular, the direction of circulation may be chosen, in which the extinguishing fluid has a shorter path or a longer path through the main line to the source of the fire. Depending on the heat distribution along the main line, the z. B. is detected by appropriate sensors, the feed of the main line with extinguishing fluid for the purpose of circulation of one or the other side may be useful.

During circulation, preferably all range valves are closed.

As already explained above, circulation can take place in a closed ring or an open line. Circulation thus means a volume flow of the extinguishing fluid in the main line. The function of the circulation is the cooling of the main line by the extinguishing fluid.

The main line is formed at rest preferably as a wet system. This means that extinguishing fluid is stored at static pressure in the main line. In case of fire, the extinguishing fluid heats up, z. As water, added water with additives, foam or the like, enormous, which can lead to a necessarily preventing bursting of the main line. Therefore, the main line is cooled by the objective circulation of the extinguishing fluid.

In this case, it is possible that the extinguishing fluid flowing in the main line is cooled by suitable measures. For this purpose, z. B. a heat exchanger connected to the main line. A heat exchanger can be used to cool the extinguishing fluid circulating in a loop.

Once a range valve is opened, quench fluid flows through the main line to the range valve. The area lines are designed as dry systems. This means that no extinguishing fluid is stored in them. As a result, these lines are generally not damaged so quickly by heat, since in them the extinguishing fluid can not expand and can lead to a bursting of the line. Empty lines can withstand heat for longer than with extinguishing fluid, eg. As water, filled lines.

In order to also cool a range valve and the stub line between the main line and the area valve, it is proposed that in the area of a range valve, a nozzle is arranged, which can be opened. This may preferably be a temperature-controlled nozzle. This nozzle can z. B. then open when the area valve or stub is heated strongly. The extinguishing fluid exiting the nozzle may cool the range valve. The volume flow of the extinguishing fluid in the stub line can be used to cool the stub line.

After opening a range valve, the quench fluid may be pumped through the circulation pump or an additional pump (eg, a high pressure pump), into the main and corresponding area line, and to the quench nozzles. It is also possible that the high-pressure pump is used to circulate the extinguishing fluid. Then you can do without an additional pump. Again, a pump may be installed on a supply line of the main line, in particular the ring of the main line. Again, it is possible to choose in which direction the fluid is pumped, depending on the position of the fire and the open area valve. For this purpose, z. B. in the ring for each direction downstream of the supply line, a valve may be provided. In particular, the valve can be opened, the distance is the smallest to the open area valve. Also, both valves can be opened, with the result that in the case of fire fighting extinguishing fluid flows through the entire main line and not, as in the use of only one valve, substantially only upstream of the opened range valve.

The circulation can take place with the existing in the main extinguishing fluid. Then, a heat exchanger is advantageous to cool the quenching fluid during circulation. Also can be included in the circulation volume of the fluid tank. As a result, the heat capacity can be significantly increased. In a circulation through an open at one end line, a fluid reservoir is preferably provided, which provides the necessary for cooling fluid.

In particular in railway tunnels or road tunnels, it may happen that persons have to be evacuated from the endangered area before the actual firefighting by discharging extinguishing fluid. For self-rescue or for alien rescue so-called self-rescue phases or emergency rescue phases are provided, which can last between 1 minute and 60 minutes or more. These phases should be taken into account in the waiting period. A timer can be provided in a control device on which the waiting time is adjustable. Also, a manual termination of the waiting time may be possible. For example, fire fighting can be activated by the fire department, in which the circulation is manually stopped and the area valves associated with the fire are opened. For this purpose, a high pressure pump can be activated manually or automatically. Also, a video surveillance may be provided, by which the fire or rescue teams can see when the circulation or fire fighting is activated. The circulation can also be activated manually.

In the area of the fire, a plurality of extinguishing nozzles can be acted upon with extinguishing fluid via a range valve in order to combat the fire or at least to cool the corresponding area. Extinguishing nozzles can be formed as Lögebebeldüsen. However, sprinkler nozzles and foam nozzles are also possible.

As a rule, it is not necessary for the actual firefighting to open all area valves, since in particular too large an amount of extinguishing fluid escapes from the extinguishing nozzles. Rather, it is necessary for firefighting regularly only to apply the extinguishing nozzles with extinguishing fluid, which are located in the immediate vicinity of the fire zone. For trains, for example, it is usually the case that only one wagon burns, whereas the other wagons are not affected. Thus, it would be a waste of resources, if all extinguishing nozzles would be applied in the firefighting area with extinguishing fluid, since then also extinguishing fluid would be applied in areas where there is no fire. This would be highly problematic, since the amount of extinguishing fluid is often limited and then extinguishing fluid would not be used exclusively for fire fighting, but would be wasted in other areas.

However, to locate the fire, it takes some time. Furthermore, the startup of the pumps, in particular a high-pressure pump requires a certain amount of time. Finally, the evacuation requires a certain waiting time. During this time, the heat is large, so that damage to the main lines could occur. In order to counteract this damage, it is proposed that upon receipt of the fire signal, at least one circulation pump is already activated. The circulation pump may be sized to deliver the amount of quench fluid sufficient to cool the main line down so that no damage occurs and no evaporation of quench fluids in the main line occurs. The circulation pump can also be realized by the already existing pump. Thus, the high pressure pump or a booster pump can also be used to operate the circulation.

As soon as the fire has been localized and a fire zone has been detected and the waiting time for the evacuation has also ended or is ended manually, at least one area valve can be opened. It is proposed that only those area valves are opened, which can be assigned to the fire zone, so that the extinguishing fluid is discharged only in the fire zone. A pressure drop takes place only in the area of the fire zone associated extinguishing nozzles.

According to one embodiment, it is proposed that all the area valves associated with the detected fire zone be completely opened. The complete opening of the zone valves, which are assigned to the fire zone, results in that the extinguishing fluid is spread in the fire zone to the maximum extent and thus the fire can be fought with all available extinguishing fluid. Since the area valves not associated with the fire zone are closed, no extinguishing fluid is wasted and the discharged extinguishing fluid is discharged only in the area of the fire zone.

A fire-fighting system is usually designed as a wet system if it is to cover large areas. This means that the main lines are at rest, at least up to the area valves with extinguishing fluid applied. Thus, in the case of activation, the extinguishing fluid is brought very quickly to the extinguishing nozzles, since immediately after the opening of the range valves, the extinguishing fluid can flow through the range valves via the pipes to the extinguishing nozzles. In order to detect leaks in the main line of the pipeline system at rest, the extinguishing fluid is applied in the idle state at a static pressure. The static pressure is, for example, less than 20 bar, for example, less than 5 bar or 2.5 bar. The static pressure can also correspond to the hydrostatic pressure.

Once the alarm signal (or pre-alarm signal) has been received, a volume flow can be used to circulate the extinguishing fluid. This volume flow can be generated by a preactivation pressure on one of the pumps. at Although circulation pressure does not increase in the circulation, preactivation pressure is necessary to activate the circulation at the pump. The pre-activation pressure is higher than the static pressure. The pre-activation pressure is preferably between 2.5 and 100 bar, more preferably between 1 and 150 bar. The preactivation pressure causes the quench fluid to circulate throughout the main conduit. The volume flow caused by the preactivation pressure is selected so that the amount of quench fluid circulating through the main conduit is just sufficient to sufficiently cool the main conduits and prevent evaporation of the quench fluid.

According to one exemplary embodiment, it is proposed that the after-waiting or manually opened range valves be subjected to extinguishing fluid at an operating pressure which is higher than the static pressure. The moment the area valves associated with the fire zone are (or are) open, the actual firefighting begins. At this moment, a high pressure must be applied to the extinguishing nozzles. Therefore, it is proposed that an operating pressure is then generated, with which the range valves and the extinguishing nozzles are acted upon. The operating pressure is usually higher than the static pressure. The operating pressure may, for example, be above 2.5 bar, preferably above 40 bar, particularly preferably above 80 bar. The operating pressure, for example, be chosen so that the extinguishing nozzles deploy a quenching mist of fine fluid droplets. The extinguishing mist serves to pressurize the fire room with extinguishing mist and sufficiently cool down, so that the fire is effectively combated. It is also possible to apply the extinguishing fluid through special nozzles, generators or rotors as extinguishing foam. Again, an operating pressure is necessary. Also, sprinkler nozzles may be provided, the z. B. can be operated with a lower operating pressure than fog nozzles.

Another aspect is a fire fighting system with a preferably annularly formed main supply line for supplying a plurality of area valves with extinguishing fluid, wherein the plurality of area valves are arranged in a fire fighting area, wherein the area valves each at least one extinguishing nozzle head is assigned via the main supply line, the area valve and a conduit connected thereto is exposed to extinguishing fluid in case of fire, detection means for receiving an alarm signal, control means for activating a circulation of the extinguishing fluid in the main conduit in response to the received alarm signal, such that extinguishing fluid flows as cooling medium through the main conduit.

It is understood that when it comes to extinguishing, extinguishing nozzles or extinguishing fluid is always meant their fire fighting property. Whether a fire is actually extinguished, depends regularly on the source of the fire, so that only a fight is possible, which either leads to a containment of the fire or even to extinguishing. Thus, the firefighting, firefighting nozzles or firefighting fluid could be discussed.

The article will be explained in more detail with reference to drawings showing an exemplary embodiments. In the drawing show:

1 a schematic view of a fire-fighting system in a tunnel with a rail vehicle in which a circulation is activated;

2 the firefighting system according to 1 in which the rail vehicle is deleted in the area of the fire zone.

1 shows a firefighting system 2 preferably in a tunnel 4 is arranged. In the tunnel 4 can a train 5 drive. In the tunnel 4 are firefighting areas at intervals 20 arranged. The firefighting areas 20 can be arranged, for example, at intervals of a few kilometers to each other. The length of firefighting areas can be approximately the length of the turn 5 correspond, for example, several 100 meters, for example, 900 meters. In the case of road tunnels, as a rule no separate firefighting area is provided, but the tunnel is equipped over its entire length for firefighting.

Associated with a firefighting area are a receiver 6 for receiving arm signals. There is also a control device 8th provided, which with the receiver 6 is in operative connection and also to control a pump 9 as well as at area valves 10 arranged actuators is set up. The control device 8th is also equipped to circulating pumps 9a . 9b head for. In addition, the control device 8th directional valves 11a . 11b drive. The circulation pumps 9a . 9b can also be arranged, unlike the illustrated, in a bypass of the main line, so that they do not represent a flow resistance in the case of fire fighting. Also, the main pump 9 to be used for the circulation in the main 3 to effect. But then preferably one end of the main supply line 3 open and only one of the directional valves 11a . 11b open.

The main pump 9 is via a supply line 3a with a main supply line 3 and the area valves 10 connected.

The main supply line 3 is closed annularly in the example shown, so that a circulation of extinguishing liquid in the main supply line 3 is possible. Not shown is a heat exchanger, which is used for cooling the circulating in the main supply line fluid. A heat exchanger is preferably arranged in the region of the directional valves.

Also not shown is that an extinguishing agent supply is integrated into the circulation circuit. In this case, via a suitable valve control in the case of circulation, the main supply line may be connected to an inlet and an outlet of the supply, so that the extinguishing agent supply is also circulated. As a result, the heat capacity can be increased.

In the main supply line 3 are the circulation pumps 9a . 9b arranged. Depending on which of the circulation pumps 9a . 9b is activated, the circulation is in the main supply line 3 right or left. However, it can only be a circulation pump 9a . 9b be used.

In the fire fighting case, the circulation pumps 9a . 9b either bypassed via a piping / valves, not shown, or the circulation pumps 9a . 9b provide only a low flow resistance for through the pump 9 over the supply line 3a fed extinguishing agent.

Every single area valve 10 has a sub-distribution with at least one pipe, at the end of a plurality of extinguishing nozzles 12 is provided. The extinguishing nozzles 12 are preferably Lögebebeldüsen for spreading a finely dispersed Löschebel. Also, the extinguishing nozzles 12 be formed as Sprinklerdüsen, Sprühflut- or foam generators.

It is also in a firefighting area 20 a plurality of fire detectors 16 intended. The fire detectors 16 are with a fire alarm panel 14 connected. By means of the fire alarm panel 14 can send a fire signal to the receiver 6 be transmitted. Also, only a single fire alarm line (eg a fire alarm cable) can be provided over the entire length to be monitored.

In the 1 it can be seen that to a range valve 10a a plurality of extinguishing nozzles 12a are connected via pipelines. A range valve 10 can also be located away from the firefighting area, in which case the pipeline to the extinguishing nozzles is longer. Also, a range valve 10 be protected in a housing. In addition, a fire detector 16a the corresponding area of the area valve 10a assigned. So form a range valve 10a , the piping connected to it, the extinguishing nozzles 12a as well as the fire detector 16a a first zone and the respective area valves 10b . 10c . 10d and 10e with the appropriate piping and extinguishing nozzles 12b . 12c . 12d . 12e and the fire detectors 16b . 16c . 16d . 16e one more zone each.

Using the at the area valves 10 arranged actuators can be the range valves 10 drive up and drive. Also it is possible that the range valves 10 only partially open. The opening of the area valves 10 is via the control device 8th controlled. Furthermore, the control device controls 8th the pump 9 on, leaving the pump 9 the area valves 10 via the main supply line 3 with extinguishing fluid at a static pressure, a pre-activation pressure and an operating pressure can apply. The static pressure is preferably below 5 bar, but may also be higher, the pre-activation pressure is for example between 1 and 10 bar, and the operating pressure is preferably between 2.5 and 100 bar. The operating pressure is high enough that the extinguishing fluid from the extinguishing nozzles 12 z. B. emerges as a finely divided mist.

In the train 5 can a fire 18 be detected. Once the train stops, people have to be evacuated. In this case, no water from the extinguishing nozzles 12 escape. Therefore, the fire fighting by opening the range valves 10 suppressed for a certain wait. The fire 18 can increase in the waiting time. That causes the firefighting area 20 is heated enormously. In the area of the fire 18 Temperatures of more than 1000 ° C may arise, in particular at the tunnel ceiling, which can lead to the main line 3 and the extinguishing fluid contained therein are strongly heated. This may cause a bursting of the main line 3 that firefighting becomes impossible and people are endangered.

To prevent this, once the alarm signal is in the receiver 6 was received, this alarm signal to activate the controller 8th used. The control device 8th receives the alarm signal and activates one of the pumps for the duration of the waiting time 9a . 9b such that the the main supply line 3 is applied with extinguishing fluid at a pre-activation pressure. Furthermore, the control device controls 8th the servomotors to the valves 11a . 11b such that these two valves 11 be opened.

Depending on the position of the fire, either the pump will 9a or the pump 9b activated, and thus determines the direction of circulation. A valve 11c to the pump 9 will be closed. The valve 11c can also be a check valve. This means that while waiting already in the main line anyway 3 existing extinguishing fluid is circulated through the pre-activation pressure in this. The main line 3 is in this case a closed ring. That through the main line 3 flowing through the extinguishing fluid leads to a cooling of this, so that damage is avoided. If the extinguishing fluid flows past the heat exchanger, not shown, it is also cooled.

During the entire waiting time is tried, by means of the fire detectors 16 the fire 18 to locate so that a fire zone can be determined. The fire detectors 16 For example, it is possible to measure a temperature profile as well as a flue gas development and, depending on the temperature profile as well as the flue gas evolution, determine whether the fire zone lies in their area. The corresponding status data are from the fire detectors 16 taken and to the fire panel 14 transmitted. The fire alarm panel 14 evaluates the results and determines a fire zone.

Im in 2 the case shown is the fire zone in the area of the area valve 10b , the extinguishing nozzles 12b and the fire detector 16b , A fire zone can also extend over several areas, but in the present case is limited to only one area for the sake of simplicity. The fire alarm panel 14 reports the detected fire zone to the receiver 6 ,

In the meantime, the waiting time, the z. B. by the controller 8th can be monitored and z. B. 5 minutes, has expired.

The control device 8th deactivates the previously activated circulation pump after expiry of the waiting time 9a . 9b , In addition, the valve 3a open.

The recipient 6 controls the controller 8th such that it controls the servomotor at the range valve 10b controls, such that the range valve 10b in which area the fire was located, is completely opened. In parallel, controls the controller 8th the pump 9 on, the main supply line 3 To apply with extinguishing fluid at an operating pressure, preferably at over 50 bar.

Depending on the position of the fire area becomes one of the valves 11a . 11b closed and another valve 11a . 11b open. Also both valves can 11 remain open, then extinguishing fluid flows from both sides of the range valve 10b , The flow area in this case is from the pump to the area valve 10b doubled.

Through the open area valve 10b the extinguishing fluid flows through the extinguishing nozzles 12b applied. During firefighting, the fire can spread to other areas. Therefore, it is proposed to continuously monitor the fire and, if necessary, to change the area of admission by opening other area valves.

Like in the 2 can be seen, extinguishing fluid flows exclusively from the extinguishing nozzles 12b and the extinguishing nozzles 12a . 12c . 12d , and 12e do not emit extinguishing fluid. Like in the 2 can also be seen, it suffices the spreading of the extinguishing fluid through the extinguishing nozzles 12b to the fire 18 to fight sufficiently in the fire zone. The extinguishing fluid is used exclusively for fire fighting and no extinguishing fluid is wasted for areas where no fire was detected.

It goes without saying that with a detected fire, the fire zone not only on the immediate fire 18 but may be extended to neighboring areas. The fire zone could also be present on the area valves 10a and 10c be extended, which also led to the extinguishing nozzles 12a and 12c that are immediately adjacent to the fire 18 are arranged, ausschächten extinguishing fluid.

By means of the subject firefighting system it is possible, during a waiting period which can be used for evacuation, to protect the main line from excessive heat and thus to prevent damage. It is also achieved that once a fire zone has been detected, the fire is effectively combated with extinguishing fluid and no extinguishing fluid is wasted.

QUOTES INCLUDE IN THE DESCRIPTION

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Cited patent literature

• DE 102010011763 A1 [0008]

Claims (9)

Method for cooling main lines of a firefighting system ( 2 ) with, - receiving an alarm signal, - activating a circulation of extinguishing fluid in the main line ( 3 ) in response to the received alarm signal, such that quenching fluid as the cooling medium through the main lines ( 3 ) circulates for a defined waiting time and after expiry of the waiting time - opening at least one area valve ( 10 ). A method according to claim 1, characterized in that the waiting time can be between 1 minute and 30 minutes, depending on the spatial conditions and the existing escape routes. A method according to claim 1 or 2, characterized in that a fire zone is detected and that after the waiting time all of the detected fire zone associated area valves ( 10 ) are opened completely. Method according to one of claims 1 to 3, characterized in that a circulation direction is determined, in particular by using in each case a circulation pump 9a ) 9b ) for each direction of the ring of the main line ( 3 ). Method according to one of claims 1 to 4, characterized in that when receiving the alarm signal at least one circulation pump ( 9a . 9b ) is activated. Method according to one of claims 1 to 5, characterized in that in the circulation all area valves ( 10 ) are closed. Method according to one of claims 1 to 6, characterized in that in response to the received alarm signal, the main line ( 3 ) is applied in the circulation with extinguishing fluid with a pre-activation pressure which is higher than a static pressure. Method according to one of claims 1 to 7, characterized in that after the waiting time, the opened range valves ( 10 ) are applied with extinguishing fluid at an operating pressure which is higher than the pre-activation pressure and / or the static pressure. Fire-fighting system with, - a main supply line ( 3 ) for supplying a plurality of area valves ( 10 ) with extinguishing fluid, - wherein the plurality of area valves ( 10 ) is disposed in a firefighting area, - wherein the area valves ( 10 ) in each case at least one extinguishing nozzle head ( 12 ) assigned via the main supply line ( 3 ), the range valve ( 10 ) and a pipe connected to it in the event of fire is treated with extinguishing fluid, - detection means ( 6 ) for receiving an alarm signal, - control means ( 8th ) for activating a circulation of the extinguishing fluid in the main supply line ( 3 ) in response to the received alarm signal, such that quenching fluid as the cooling medium through the main supply line ( 3 ) flows.

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