DE102012202796B4 - Fire extinguishing system with quick emptying - Google Patents

Abstract

A fire extinguishing system (1) comprising a pipe (2) connected at one end (3) to an extinguishing agent source (4) with at least one extinguishing agent outlet (5), at the other end (6) of the pipe (2) via a Control device (11) controllable discharge valve (10) is provided, so that the at least one extinguishing agent outlet (5) between the extinguishing agent source (4) and discharge valve (10) is arranged, wherein the control device (11) is adapted to a first control signal (12) indicating the opening of at least one extinguishing agent outlet (5) to open the drain valve (10) and the drain valve (10) due to a second control signal (13) indicating that a predetermined amount of liquid has passed through the drain valve (10) close, wherein the tube (2) in the standby state of the fire extinguishing system (1) is filled with an antifreeze solution, and wherein for generating the second control signal (13) a collecting basin (31) for the a us the drain valve (10) flowing liquid with a float (32) or a level gauge (33) and / or a pressure vessel (34) with pressure sensor (35) is provided.

Description

The invention relates to a fire extinguishing system comprising a tube connected at its one end to an extinguishing agent source with at least one extinguishing agent outlet. The invention further relates to a retrofit kit for a corresponding fire extinguishing system.

With known fire extinguishing systems, which are also called sprinkler wet systems, fires can be extinguished. As soon as a fire is detected, an extinguishing agent outlet, which is generally designed as a self-triggering sprinkler, opens and pressurized extinguishing liquid passes from the extinguishing agent source via the pipe and the extinguishing agent outlet to the source of the fire. The fire is deleted in this way.

So that the extinguishing liquid can flow out directly after opening an extinguishing agent outlet, it is known, the tube of the fire extinguishing system in the standby state - d. H. before the detection of a fire and the associated opening of an extinguishing agent outlet - already fill with extinguishing liquid and put under pressure. As extinguishing liquid water is usually used.

If a fire extinguishing system is located at least partially in a cold area, such as a freezer house, there is a risk that the extinguishing liquid contained in the pipe of the fire extinguishing system will freeze and damage the pipe. This is especially true in the standby state in which the extinguishing liquid in the tube rests. If the extinguishing liquid flows through the pipe in the cold area, the risk of freezing is low.

In order to avoid the risk of freezing of resting in the pipe extinguishing liquid, it is known to fill the pipe in the standby state at least in the cold area instead of extinguishing liquid with an antifreeze liquid. If an extinguishing agent outlet is opened in the event of a fire, the antifreeze liquid and only then the actual extinguishing liquid pass through it. The antifreeze liquid usually has little fire fighting effect, so that the fire only after it has completely drained and the extinguishing liquid exits the extinguishing agent outlets, is deleted.

Although in the state of the art by filling the pipe in standby with antifreeze liquid the danger of freezing in cold areas banned, but passes in case of fire after opening a Löschmittelauslasses some time in which the fire non-combating antifreeze through the open Löschmittelauslässe from the pipe flows out before there extinguishing liquid escapes to actually extinguish the fire.

The German patent application DE 197 16 585 A1 shows a dry sprinkler system with a pipeline to which an extinguishing agent outlet is arranged. In the ready state, the pipeline is filled with compressed air at a higher pressure than the extinguishing agent. At opposite ends of the tube, a solenoid valve as a controllable drain valve and a dry alarm valve are arranged as a connection to the extinguishing agent source. Furthermore, a control device is provided which receives a signal via an alarm pressure switch that at least one extinguishing agent outlet has been opened.

The German patent application DE 26 11 653 A1 describes a quick-release sprinkler system having a conduit at one end of which an alarm valve is provided for connection to an extinguishant supply. At the other end of the pipeline a quick exhaust valve is connected, between the two valves extinguishing agent outlets are arranged. The quick exhaust valve is controlled by a control diaphragm which receives hydraulic signals through the pipe connections indicating the opening of at least one extinguishing agent outlet. Upon these signals, the control diaphragm opens the quick exhaust valve. The quick exhaust valve closes as soon as extinguishing liquid flows through the valve instead of air or a timer is provided which transmits a hydraulic signal to the control diaphragm after a predetermined time.

The German patent application DE 10 2005 043 213 A1 discloses a sprinkler system for frost-prone areas, in which the feed line is arranged in the frost-free area. Downpipes from the supply line extend into the frost-prone area. In these downpipes, which each have a sprinkler at one end, an antifreeze solution is introduced in the ready state.

The patent US Pat. No. 7,389,824 B2 shows a sprinkler system, the pipe network is filled in the standby state with an antifreeze solution, which exits through the sprinkler heads when triggering the fire extinguishing system, before then extinguishing water escapes. For drainage purposes and in the event of overpressure in the piping network, drainage valves with antifreeze catchment containers are also provided.

The invention has for its object to provide a fire extinguishing system that works reliably in frost-prone areas and in which the extinguishing agent leaks faster. The invention is further based on the object, a To provide a retrofit kit for existing fire extinguishing systems, due to the fire extinguishing system in frost-prone areas works reliably and the extinguishing agent escapes faster.

These objects are achieved by a device according to the main claim and a retrofit kit according to the independent claim 7. Advantageous embodiments are the subject of the dependent claims.

Accordingly, the invention relates to a fire extinguishing system comprising a pipe connected at one end to an extinguishing agent source with at least one extinguishing agent outlet, wherein at the other end of the pipe, a controllable via a control valve discharge valve is provided so that the at least one extinguishing agent outlet between extinguishing agent source and drain valve arranged wherein the control device is configured to open the drain valve on the basis of a first control signal indicating the opening of at least one extinguishant outlet and to close the drain valve due to a second control signal indicating that a predetermined amount of liquid has flowed through the drain valve, wherein the tube in the standby state of the fire extinguishing system is filled with an antifreeze solution, and wherein for generating the second control signal, a catch basin for the liquid flowing from the drain valve with a float ode r a level gauge and / or a pressure vessel with pressure sensor is provided.

Furthermore, the invention relates to a retrofit kit for a fire extinguishing system for connection to an extinguishing agent outlet comprising the fire extinguishing system tube, comprising a controllable via a control device drain valve for liquid from the pipe, wherein the control device is adapted to a first control signal, which opening at least an extinguishing agent outlet on the pipe of the fire extinguishing system indicates to open the drain valve and due to a second control signal indicating that a certain amount of liquid has flowed through the drain valve from the pipe to close the drain valve, wherein for generating the second control signal a catch basin with a float or a level gauge and / or a pressure vessel with pressure sensor is provided.

For the purposes of this invention, the source of extinguishing agent is understood to be any source of extinguishing agent which can introduce extinguishing agents under pressure into the tube of the fire-extinguishing system. The required pressure in the extinguishing agent can be achieved, for example, by means of a pump or by utilizing gravity. The extinguishing agent source may further comprise a manifold to which a plurality of fire extinguishing systems according to the invention are connected. It is also possible that one or more extinguishing agent outlets are provided on the manifold or in a supply line to the tube of the fire extinguishing system according to the invention. The term extinguishing agent source thus includes in particular a pipe to which the fire extinguishing system according to the invention is connected or which merges into the pipe of the fire extinguishing system according to the invention.

With the invention it is achieved that when opening at least one extinguishing agent outlet, the liquid in the standby state in the tube is removed from the tube more quickly than is the case in the prior art. The liquid in the standby state in the pipe is expelled by the pressurized extinguishing agent flowing from the extinguishing agent source, whereby according to the invention it does not flow exclusively through the opened extinguishing agent outlets but additionally through the drain valve. As soon as a predetermined amount of liquid has drained via the drain valve, this is closed again. Thereafter, liquids - and in particular nachströmendes extinguishing agent - emerge exclusively through opened extinguishing agent outlets.

Thus, the fire extinguishing system can be operated in cold areas, it is in the idle state in the tube liquid preferably an antifreeze solution. However, appropriate antifreeze solutions are not or only partially suitable for firefighting. By the discharge valve according to the invention ensures that the antifreeze solution is removed faster in case of fire from the pipe of the fire extinguishing system, as is possible in the prior art. The originating from the extinguishing agent source, suitable for fire fighting extinguishing agent may emerge earlier from the extinguishing agent outlets, as if the antifreeze solution would have to flow as in the prior art alone through the extinguishing agent outlets. The fire fighting is improved.

In order to prevent extinguishing agent from leaving the discharge valve after complete discharge of the antifreeze solution from the pipe of the fire extinguishing system and thus not used for fire fighting, the drain valve is closed again after a predetermined amount of liquid has flowed through. The predetermined amount of liquid may preferably be selected so that at the time of closing the drain valve virtually no antifreeze solution is more in the pipe of the fire extinguishing system. Alternatively, it is possible that the predetermined amount of liquid is selected so that at least the distance between the extinguishing agent source and the opened extinguishing agent outlet is free from antifreeze solution. In both cases it is achieved that at least after closing the Discharge valve practically only extinguishing agent from the extinguishing agent outlets exits.

To generate the first control signal, a flow detector may preferably be provided on the pipe. If an extinguishing agent outlet is opened on the pipe, the liquid in the pipe exits through this extinguishing agent outlet. The resulting due to the pressure prevailing in the extinguishing agent in the pipe flow is detected by the flow detector and it is a first control signal, which indicates the opening of at least one extinguishing agent outlet, sent to the control device.

It is also possible for a pressure sensor to be provided on the pipe to generate the first control signal. If an extinguishing agent outlet is opened and thereupon a flow in the pipe of the fire extinguishing system occurs, the static pressure in the pipe decreases. By the corresponding pressure change is absorbed by a pressure transducer on the pipe, a flow and thus the opening of at least one extinguishing agent outlet can be detected. A corresponding first control signal is then sent to the control device.

It is also possible that the fire extinguishing system includes a fire alarm panel. When a corresponding fire panel detects a fire, it sends control signals to at least part of the extinguishant outlets to open them. According to the invention it is provided that the fire alarm panel also sends a first control signal to the control device when sending control signals for opening individual or all extinguishing agent outlets, which indicates the opening of at least one extinguishing agent outlet.

It is also possible that an alarm pressure switch is provided, upon activation of which a first control signal is sent to the control device, which indicates the opening of the at least one extinguishing agent outlet.

It is sufficient to provide only one of the aforementioned means for generating a first control signal. In order to create redundancies and thus increase the reliability of the fire extinguishing system, however, it may be provided to provide several of the aforementioned devices in parallel. If one of the devices for generating the first control signal fails, then at least one further device is present, which can send a first control signal to the control device, which indicates the opening of at least one extinguishing agent outlet.

To generate the second control signal, which indicates that a predetermined amount of liquid has been drained from the pipe through the drain valve, a sump for the liquid flowing out of the drain valve is provided with a float or level gauge and / or a pressure vessel with pressure sensor. If a catch basin for the liquid leaving the drain valve is provided with a float or a level gauge, the float or level gauge can be used to determine the amount of liquid drained from the pipe. If a predetermined amount of liquid detected in the catch basin, a second control signal is sent to the control device of the drain valve, whereupon it is closed.

If the liquid emerging from the discharge valve is supplied to a pressure vessel, the pressure in the pressure vessel rises due to the supplied liquid, which is detected by a pressure sensor. If a predetermined pressure, which corresponds to a predetermined amount of liquid to be flowed through in the pressure vessel, is detected in the pressure vessel, a second control signal is sent to the control device of the drain valve, whereupon it is closed.

The embodiment according to the invention with sump and / or pressure vessel offer the advantage that the exiting liquid can be collected and subsequently reused. The reusability of the leaked liquid can be ensured basically and independently of the generation of a first control signal through a catch basin.

As with the possible devices for generating the first control signal, it is also possible for the generation of the second control signal to provide redundancies. For example, it is possible to additionally provide a timer for generating a second control signal. If both the flow velocity of the liquid flowing through the discharge valve and the extinguishing agent source flowing out of the extinguishing agent source, as well as the cross section of the pipe or the drain valve known, a predetermined time corresponds to the closing of the drain valve of a certain amount of liquid that has flowed through the drain valve , About the timer, the amount of liquid emerging from the outlet valve can be determined with sufficient accuracy. The timer is started by opening the drain valve and sends after a predetermined period of time, a second control signal to the control device, whereupon this closes the drain valve. The start signal for the timer can be identical to the first control signal.

However, it may also be one of the control device after receiving a first control signal be generated signal. It is possible that the timer is integrated directly in the control device.

It is preferred if the flow resistance through the discharge valve is smaller than the flow resistance through the at least one extinguishing agent outlet. It is further preferred if the discharge valve in the open state releases the entire pipe diameter. This ensures that the drain valve in the open state relative to the tube does not generate additional flow resistance. Both measures mentioned above ensure that, in the case of an opened extinguishing agent outlet and an opened drain valve, the liquid present in the pipe can drain off as quickly as possible.

It is preferred if the predetermined amount of liquid corresponds to 80%, preferably 90%, more preferably 100% of the volume of the tube from which the liquid in the standby state is to be removed. Since a portion of this liquid flows through the opened extinguishing agent outlets (for example 10% or 20%), it is further ensured that, at least after the closure of the drain valve, almost exclusively extinguishing agent escapes from the extinguishing agent outlets. In the state of readiness in the tube located liquid (eg., Antifreeze solution), which completely fills the tube volume, then already practically completely drained via the extinguishing agent outlets and the drain valve.

The antifreeze solution used is preferably a solution whose freezing point is below -10 ° C., more preferably below -20 ° C., more preferably below -30 ° C. The extinguishing agent is preferably water used.

It is possible that a pipe branch is provided on the pipe in the region of the drain valve. A corresponding pipe branch does not affect the operation of the fire extinguishing system according to the invention. But it can serve, for example, as a return for the extinguishing agent to regulate its flow velocity through the pipe. It is also possible to fill the pipe for standby with liquid via the pipe branch.

Between the extinguishing agent source and the associated pipe with at least one extinguishing agent outlet, an alarm valve may preferably be provided, which is closed in the standby state of the fire extinguishing system. By means of a corresponding alarm valve, it is possible to prevent a liquid in the standby state in the tube from being mixed with the extinguishing agent from the extinguishing agent source. If an extinguishing agent outlet is opened, the alarm valve also opens, so that extinguishing agent can flow from the extinguishing agent source to the extinguishing agent outlet. In this case, the alarm valve, for example, open due to a pressure drop on the extinguishing agent source side facing away from the alarm valve.

The alarm valve may be part of the extinguishing agent source. But it is also possible that the alarm valve is located away from the extinguishing source between a supply line connected to the extinguishing agent source and the tube with the extinguishing agent outlet.

It is preferred if the alarm valve comprises a control valve which is designed such that it keeps the alarm valve in the standby state at a small pressure difference between the side of the alarm valve facing the extinguishing agent source and the side of the alarm valve facing away from the extinguishing agent source. In this case, the pressure on the, the extinguishing agent source side facing be higher than the pressure on the side facing away from the extinguishing agent source. The alarm valve is opened via the control valve when said pressure difference rises rapidly or exceeds a preset value.

To control the alarm valve depending on the size of the pressure difference, the control valve may have a pressure boost. In this case, for example, the pressures on both sides of the alarm valve are translated into forces via differently sized pressure transducer surfaces in such a way that at a first pressure ratio (eg a lower pressure difference) a sufficiently large force for closing or keeping closed the alarm valve results while at a second pressure ratio (FIG. eg a higher pressure difference) the resulting force opens the alarm valve.

It is alternatively possible to provide an alarm valve, which is kept mechanically closed in the standby state. The alarm valve can be opened via a hydraulic signal. The hydraulic signal may, for example, be a pressure drop on the side of the alarm valve facing away from the extinguishing agent source.

With both said alternatives for an alarm valve, it is possible that the pressure on the side of the alarm valve facing the extinguishing agent source in the standby state of the fire extinguishing system is greater than on the side facing away from the extinguishing agent source. This offers the advantage that the pressure in the tube with the at least one extinguishing agent outlet, ie, on the side of the alarm valve facing away from the extinguishing agent source, is increased by the inflowing extinguishing agent only when the fire extinguishing system is triggered. The thus increased pressure in the tube causes the inflowing extinguishing agent from the extinguishing agent source on a direct route to the at least one open Extinguishing agent outlet is transported. The liquid which is in the standby state in the pipe and thus also in a section of the pipe in which no extinguishing agent outlet is open and which is not in the direct path between the alarm valve and the at least one opened extinguishing agent outlet, is pushed back and remains in this pipe section or pipe corresponding pipe sections. The removal of the liquid in the standby state in the pipe from the section between the alarm valve and the at least one opened extinguishing agent outlet can thereby be further accelerated. This is especially true in the case where the tube is branched.

To explain the retrofit kit according to the invention, reference is made to the above statements. The use of a corresponding retrofit kit with a fire extinguishing system is also included in this invention.

• 1 ein Ausführungsbeispiel einer nicht-erfindungsgemäßen Feuerlöschanlage;
• 2 ein erstes Ausführungsbeispiel einer erfindungsgemäßen Feuerlöschanlage;
• 3 ein zweites Ausführungsbeispiel einer erfindungsgemäßen Feuerlöschanlage;
• 4 ein drittes Ausführungsbeispiel einer erfindungsgemäßen Feuerlöschanlage;
• 5 eine Prinzipskizze zur Festlegung der vorgegebenen Flüssigkeitsmenge;
• 6 ein erstes Ausführungsbeispiel eines erfindungsgemäßen Nachrüstsatzes; und
• 7a,b weitere Ausführungsbeispiele einer erfindungsgemäßen Feuerlöschanlage.

The invention will now be described by way of example with reference to preferred embodiments with reference to the accompanying drawings. Show it:

• 1 an embodiment of a non-inventive fire extinguishing system;
• 2 a first embodiment of a fire extinguishing system according to the invention;
• 3 A second embodiment of a fire extinguishing system according to the invention;
• 4 A third embodiment of a fire extinguishing system according to the invention;
• 5 a schematic diagram for determining the predetermined amount of liquid;
• 6 a first embodiment of a retrofit kit according to the invention; and
• 7a , B further embodiments of a fire extinguishing system according to the invention.

In 1 is an embodiment of a non-inventive fire extinguishing system 1 shown.

The fire extinguishing system 1 includes a tube 2 which is at one end 3 with an extinguishing agent source 4 connected is. The source of extinguishing agent 4 is designed to introduce extinguishing agent under pressure in the pipe. The source of extinguishing agent 4 may have a pump to do so. But it is also possible that the extinguishing agent source geodetically above the tube 2 is arranged so that the extinguishing agent solely by gravity into the pipe 2 suppressed. The source of extinguishing agent 4 may also include a manifold, to which several fire extinguishing systems according to the invention 1 are connected. It is also possible that the source of extinguishing agent 4 a supply line to the pipe 2 includes, are provided at the extinguishing agent outlets. Between extinguishing agent source 4 and pipe 2 Furthermore, a return protection can be provided, with which a liquid flow from the pipe 2 in the direction of the extinguishing agent source 4 is prevented.

At the pipe 2 are still extinguishing agent outlets 5 intended. The extinguishing agent outlets 5 can be designed as sprinklers that open automatically in case of fire or due to an external signal. Corresponding sprinklers are known in the art. In the illustrated first embodiment is in the event of fire automatically opening extinguishing agent outlets 5 ,

Will at least one extinguishing agent outlet 5 opened, extinguishing agent flows from the extinguishing agent source 4 through the pipe 2 to the opened extinguishing agent outlets 5 ,

A part of the pipe 2 and the extinguishing agent outlets 5 are in a cold area 90 , For example, in a freezer, arranged. To prevent it in standby mode - ie, when all extinguishant outlets 5 are closed - to freezing in the fire extinguishing system 1 and subsequent damage to the pipe 2 come, is the pipe 2 Fully charged with antifreeze solution in standby mode. The antifreeze solution is chosen so that it is in the cold area 90 temperatures do not freeze.

Will now be an extinguishing agent outlet 5 open, first the antifreeze solution must be removed from the pipe 2 - at least in the area between source of extinguishing agent 4 and the opened extinguishant outlets - are removed before from the extinguishant source 4 originating extinguishing agent from the opened extinguishing agent outlets 5 can escape. Since the antifreeze solution has only a low fire-fighting effect, a fire is not extinguished until extinguishing agents are actually removed from the opened extinguishing agent outlets 5 exit. If the extinguishing agent in the cold area 90 through the pipe 2 flows, there is no danger of freezing.

To get the antifreeze solution out of the tube as fast as possible 2 To remove as quickly as possible extinguishing agent from the extinguishing agent outlets 5 to flow, according to the invention is a drain valve 10 provided, which via a control device 11 is controlled. The drain valve 10 is at one end 6 of the pipe 2 arranged so that the extinguishing agent outlets 5 between extinguishing agent source 4 and drain valve 10 are arranged.

The control device 11 is formed to be responsive to a first control signal 12 the drain valve opens and due to a second control signal 13 closes.

For generating the first control signal 12 is a flow detector 20 on the pipe 2 intended. This flow detector 20 sends a control signal 12 out as soon as he has a flow in the pipe 2 detected. In standby mode is in the pipe 2 no flow available. But becomes an extinguishant outlet 5 opened, creates a flow from the extinguishing agent source 4 in the direction of the extinguishing agent outlets 5 , With the detection of a flow in the pipe 2 So is the opening of an extinguishing agent outlet 5 detected. Due to the control signal then generated 12 opens the control device 11 the drain valve 10 and liquid from the pipe 2 can emanate through this.

With opening the drain valve 10 is initially for in standby mode in the pipe 2 an additional drain has been created. The antifreeze solution can then be next to the opened extinguishing agent outlets 5 also through the drain valve 10 stream. The time it takes for enough antifreeze solution to drain off the source of extinguishing agent 4 originating extinguishing agent from the extinguishing agent outlets 5 can escape, is opposite a fire extinguishing system 1 without the outlet valve according to the invention 10 significantly shortened. This will improve firefighting.

To prevent, if necessary, also extinguishing agent from the drain valve 10 flows and then can no longer contribute to fire fighting, is provided, the drain valve 10 to close again after some time. The drain valve 10 is closed according to the invention, namely, when a predetermined amount of liquid has flowed through this. The predetermined amount of liquid is chosen so that at least after closing the drain valve 10 almost exclusively extinguishing agent from the extinguishing agent outlets 5 exit, at least the distance between source of extinguishing agent 4 and the opened extinguishing agent outlet 5 So is free from antifreeze solution.

For generating the second control signal 13 to close the drain valve 10 is in the embodiment according to 1 a timer 30 intended. The timer 30 starts with opening the drain valve 10 to run and sends a second control signal after a predetermined period of time 13 to the control unit 11 , whereupon the drain valve 10 is closed. With known flow cross-section of the drain valve 10 and known flow rate of the liquid through the drain valve 10 corresponds to the predetermined period of time while the predetermined amount of liquid.

To the timer 30 can, as shown, directly the first control signal 12 be sent. On the first control signal 12 The timer starts 30 to run. Alternatively, it is possible that the timer 30 from the controller 11 is activated, after the latter a first control signal 12 had received. It is also possible to use the timer 30 in the control device 11 to integrate.

In 2 is a first embodiment of a fire extinguishing system according to the invention 1 shown. The embodiment corresponds in many parts to the embodiment 1 , which is why reference is made to the statements there. The following is based only on the differences of the embodiment 2 from the embodiment 1 received.

For generating the first control signal 12 is a pressure sensor 21 on the pipe 2 intended. Starts in standby mode in the pipe 2 dormant liquid after opening an extinguishing agent outlet 5 to flow, the static pressure in the pipe decreases 2 , This pressure change, which is the opening of an extinguishing agent outlet 5 is indicated by the pressure sensor 21 recorded and in the form of a first control signal 12 to the controller 11 reported. The control device 11 then opens the drain valve 10 ,

The through the drain valve 10 flowing liquid flows into a catch basin 31 , In this catch basin 31 is a swimmer 32 arranged with those in the catch basin 31 amount of liquid - and thus the through the drain valve 10 flowed amount of liquid - is determined. Once with the help of the swimmer 32 the predetermined amount of liquid in the catch basin 31 is detected, a second control signal 13 to the controller 11 sent, whereupon the drain valve 10 is closed.

In 3 is a second embodiment of a fire extinguishing system according to the invention 1 shown. The embodiment corresponds in many parts to the embodiments 1 and 2 , which is why reference is made to the statements there. The following is based only on the differences of the embodiment 3 compared to the embodiments 1 and 2 received.

The extinguishing agent outlets 5 in the embodiment according to 3 do not open automatically in case of fire, but are controlled by a fire alarm panel 22 with the help of control signals 23 driven. Once the fire alarm panel 22 a fire is reported, it opens the extinguishing agent outlets 5 by control signals 23 , At the same time it sends a first control signal 12 to the controller 11 to open the drain valve 10 ,

The from the drain valve 10 outflowing liquid passes as in the embodiment according to 2 in a catch basin 31 , To determine the catch basin 31 amount of liquid - and thus the through the drain valve 10 amount of fluid flowed - is a level gauge 33 intended. Is the predetermined amount of liquid on the level gauge 33 is detected, a second control signal 13 generated and sent to the control unit 11 Posted.

In 4 is a third embodiment of a fire extinguishing system according to the invention 1 shown. The embodiment corresponds in many parts to the embodiments 1 to 3 , which is why reference is made to the statements there. The following is based only on the differences of the embodiment 4 compared to the embodiments 1 to 3 received.

In the third embodiment, for generating the first control signal 12 an alarm pressure switch 24 intended. The source of extinguishing agent 4 In this embodiment, it is designed such that it opens an extinguishing agent outlet 5 detected and in the form of a signal 25 to the alarm pressure switch 24 reports and thus activated. The alarm pressure switch 24 then generates a first control signal 12 and sends it to the controller 11 , The drain valve 10 will be opened in the sequence.

Is it the source of extinguishing agent 4 For example, to a Sprinklerzentrale, there is usually provided a so-called. Tripping valve, which opens an extinguishing agent outlet 5 in the form of a signal 25 displays. This signal 25 - Which is often used in the prior art for triggering alarm bells or - horns - can then according to the third embodiment of the invention via the alarm pressure switch 24 the first control signal 12 trigger.

The through the exhaust valve 10 flowing liquid is in the third embodiment, a pressure vessel 34 fed. As the amount of liquid in the pressure vessel increases due to the inflowing liquid, the pressure in the hermetically sealed pressure vessel also increases 34 , This pressure increase is via the pressure transducer 35 registered. Reached the pressure in the pressure vessel 34 a predetermined value, which corresponds to a predetermined amount of liquid that has passed, becomes a second control signal 13 generated and to the controller 11 Posted. The drain valve 10 will be closed again.

The individual devices for generating the first and the second control signal from the embodiments according to 1 to 4 can be combined with each other. It is also possible to provide a plurality of devices for generating the first and / or the second control signal to provide redundancy and the reliability of the fire extinguishing system 1 to increase.

In all embodiments according to 1 to 4 is the drain valve 10 configured such that it has a lower flow resistance than the extinguishing agent outlets 5 having. It is preferred if the drain valve 10 in its open state the entire cross-section of the tube 2 releases, and thus against the pipe 2 generates no additional flow resistance.

In 5 shows how a value for the given amount of liquid can be determined in principle.

So as fast as possible extinguishing agent from the extinguishing agent source 4 from the extinguishing agent outlets 5 can emerge in the standby state in the pipe 2 Liquid present - eg antifreeze solution - as quickly as possible from the pipe 2 be drained. For this purpose, after opening at least one extinguishing agent outlet 5 at times also the drain valve 10 open. The standby in the pipe 2 located liquid can drain faster. As a result, premature extinguishing agent exits the extinguishing agent source 4 from the opened extinguishing agent outlets 5 off to extinguish a fire as if in standby mode in the pipe 2 Liquid located exclusively over the opened extinguishing agent outlets 5 itself would have to be drained.

The drain valve 10 should then be closed again according to the invention, if a predetermined amount of liquid from the pipe 2 was drained that ensures that almost exclusively extinguishing agents from the extinguishing agent outlets 5 exit.

The predetermined amount of liquid may be above the volume of the tube 2 be determined. This can be the tube volume 40 as the volume of the pipe 2 from the extinguishing agent source 4 to the extinguishing agent outlet farthest from the extinguishing agent source 5 be defined. Will in the standby state in the pipe 2 located liquid in the corresponding volume 40 from the extinguishing agent from the extinguishing agent source 4 displaced, it is ensured that then only extinguishing agent from the extinguishing agent outlets 5 exit.

The volume 41 does not necessarily have to pipe volume 40 be counted, as it is at a closed drain valve 10 is a dead area. There are there Liquid flows when the drain valve is closed 10 and opened extinguishing agent outlets 5 not off, as long as sufficient extinguishing agent from the extinguishing agent source 4 nachströmt. Even if this volume 41 So continue to stay filled with, for example, antifreeze, exits the extinguishing agent outlets 5 nevertheless only extinguishing agents.

From the tube volume 40 and optionally in addition to the volume 41 can the predetermined amount of liquid determined. Since the standby in the pipe 2 but not exclusively via the opened drain valve 10 flows, but also through the then also opened extinguishing agent outlets 5 , may be sufficient in determining the predetermined amount of liquid, only a portion of the tube volume 40 - For example, 80% or 90% - to take into account.

In 6 an inventive retrofit kit 1 'is shown. The retrofit kit 1 'includes a via a control device 11 controllable drain valve 10 which has a connection 7 can be connected to the pipe of a fire extinguishing system. The control device 11 also has an entrance 12 ' for a first control signal. If a first control signal, which indicates that an extinguishing agent outlet of the fire extinguishing system to which the retrofit kit 1 'is connected, has been opened by the control device 11 over the entrance 12 ' receive, the drain valve 10 open.

The retrofit kit 1 'further comprises a device for determining the from the drain valve 10 streamed liquid. In the illustrated embodiment, this is a catch basin 31 with swimmers 32 as it related to the fire extinguishing system 2 has been described. Will over the float 32 found that a predetermined amount of liquid through the drain valve 10 has passed, becomes a second control signal 13 generated and to the controller 11 sent, whereupon the drain valve 10 is closed.

Instead of the catch basin 31 with swimmers 32 may also include means for detecting the amount of liquid that has flowed through the drain valve, as shown in FIGS 3 and 4 is shown used. It is also possible, instead of a corresponding device to the switching device 11 merely to provide an input for a second control signal. The second control signal 13 can then be generated by a device outside the retrofit kit 1 '.

To further explain the retrofit kit 1 'and the operation of a retrofit kit 1' equipped fire extinguishing system is to the comments to 1 to 5 directed.

In 7 a, b show two further embodiments of a fire extinguishing system according to the invention. Although the two embodiments differ in some structural features, both are based on the same operation, so they will be discussed together below.

The fire extinguishing system 1 according to 7 a, b each comprise a tube 2 , which at its one end with an extinguishing agent source 4 connected is. The pipe 2 has several extinguishant outlets 5 , For example, sprinkler, and is in the standby state with one of the extinguishing agent from the extinguishing agent source 4 various liquid, for example. An antifreeze solution, filled. In case of fire, the actual extinguishing agent from the extinguishing agent source 4 from the extinguishing agent outlets 5 to let it flow is over 6 the pipeline 2 a drain valve 10 intended. This drain valve 10 is in accordance with one of the embodiments of 2 to 4 executed, which is why the comments there on the design and operation of the drain valve 10 is referenced.

Between the pipe 2 and the source of extinguishing agent 4 is an alarm valve 8th provided, which is closed in the standby state. This prevents the extinguishing agent from the extinguishing agent source 4 in standby mode with the tube 2 located liquid, for example. The antifreeze mixed. The alarm valve 8th can be considered from the source of extinguishing agent 4 be executed separate element ( 7a ). But it is also possible that the alarm valve 8th into the extinguishing agent source 4 is integrated ( 7b ).

The alarm valve 8th should in the event that fire should be deleted and for at least one extinguishing agent outlet 5 is opened, also opened, so that extinguishing agent from the extinguishing agent source 4 to the at least one opened extinguishing agent outlet 5 can get. To the alarm valve 8th to open in this case is an activation element 9 intended. Once the activation element 9 determines that at least one extinguishing agent outlet 5 is opened, the alarm valve 8th controlled so that it also opens.

At the activation element 9 it can be a control valve (see 7a ). About this control valve can be determined by the pressure difference across the alarm valve 8th a pressure drop in the pipe 2 which is usually due to an opened extinguishing agent outlet 5 arises, be established. At a corresponding pressure drop then the alarm valve 8th open.

The control valve as activation element 9 is designed to cause a pressure difference a pressure drop in the pipe 2 from one via the alarm valve 8th applied pressure difference between the extinguishing agent from the extinguishing agent source 4 and the liquid in the pipe 2 to distinguish. In particular, the pressure in the tube 2 in the standby state also be lower than the pressure of the extinguishing agent from the extinguishing agent source. In this case, the pressure difference increases at the opening of an extinguishing agent outlet 5 , whereupon the activation element 9 the alarm valve 5 opens.

Alternatively to the control valve as activation element 9 according to 7a can act as an activation element 9 also be provided a hydraulic signal generator. The hydraulic signaler opens the alarm valve 8th as soon as a pressure drop in the pipe 2 is detected.

Unless at the fire extinguishing system 1 another element is provided to allow a pressure drop in the pipe 2 to detect, if necessary, the control signal generated by this element also to the opening of the alarm valve 8th be used. In this case, the other element would be as an activation element 9 to understand.

Regardless of the final execution of the activation element 9 offers the alarm valve 8th the advantage that in the standby state, the pressure in the pipe 2 may be lower than the pressure of the extinguishing agent from the extinguishing agent source 4 , About the alarm valve 8th is in the standby state of the fire extinguishing system 1 So a pressure difference, where the extinguishing agent source 4 facing side of the alarm valve 8th has a higher pressure than that of the extinguishing agent source 4 opposite side or on the pipe 2 facing side. This can reduce the time after opening an extinguishing agent outlet 5 passes until this extinguishing agent from the extinguishing agent source 4 to be further reduced. This effect occurs especially in cases where only one of several extinguishing agent outlets 5 on the pipe 2 is opened. The following is based on the 7 a, b exemplified.

In 7a is the fire extinguishing system 1 shown in standby mode. The extinguishing agent outlets 5 , the drain valve 10 and the alarm valve 8th are closed. The pipe 2 is filled with an antifreeze solution, which is under pressure P2 stands. On the other side of the alarm valve 8th provides the source of extinguishing agent 4 that the extinguishing agent located there under a pressure P4 stands, whereby the pressure P4 is greater than the pressure P2 , The activation element 9 in 7a is designed so that the pressure difference between P2 and P4 does not open the alarm valve 8th leads.

Now opens an extinguishing agent outlet 5 the pressure drops P2 to a lower level P2 ' from. This pressure drop is from the activation element 9 it is due to the change in the pressure difference across the alarm valve 8th (see. 7a ), the pressure change in the pipe 2 (see. 7b ) or otherwise. The alarm valve will then turn on 8th opened and extinguishing agent flows into the pipe 2 , It is about the extinguishing agent source 4 Ensures that the extinguishing agent continues to be under pressure P4 stands.

The extinguishing agent displaces the antifreeze from the pipe 2 through the drain valve 10 and the opened extinguishing agent outlet 5 , As the pressure of antifreeze in the pipe 2 in the standby state, however, is less than the pressure of the extinguishing agent from the extinguishing agent source 4 Only the antifreeze is displaced, which is on the route between the alarm valve 8th and opened extinguishing agent outlet 5 or the opened drain valve 10 located. The pipe sections 43 , through which no extinguishing agent must flow for fire fighting, remain filled with antifreeze. Due to the initially lower pressure of the antifreeze in these areas 43 No antifreeze flows from these areas 43 out, towards the opened extinguishing agent outlets 5 ,

As a result, due to the pressure conditions in the in 7 a, b illustrated embodiments, only the volume of antifreeze displaced, which actually has to be replaced by extinguishing agent, so that extinguishing agent can flow from the opened Löschmittelauslässen. Because areas 43 of the pipe 2 , which must not be flown through by fire fighting extinguishing agent, even when opening the alarm valve 8th must be filled with extinguishing agent, the extinguishing agent passes faster to the opened extinguishing agent outlets 5 , Firefighting with extinguishing agent from the extinguishing agent source 4 So it can be accelerated.

LIST OF REFERENCE NUMBERS

1

Fire extinguishing system

1`

Retrofit kit [not shown]

2

Pipe, pipeline

3.6

Ends of the pipe

4

Extinguishing media source

5

Löschmittelauslass

7

connection

8th

alarm valve

9

energizer

10

drain valve

11

Control device, control device, switching device, control unit

12

First control signal

12 '

entrance

13

Second control signal

20

Water flow detectors

21

pressure sensor

22

Fire Panel

23

control signals

24

Alarm Pressure Switch

25

signal

30

timer

31

catch basin

32

swimmer

33

level meter

34

pressure vessel

35

Pressure transducer, pressure sensor

40

Pipe volume, volume

41

volume

43

Pipe section, area of the pipe

90

cold area

P2, P4

print

P2 '

Pressure level [not shown]

Claims (7)

A fire extinguishing system (1) comprising a pipe (2) connected at one end (3) to an extinguishing agent source (4) with at least one extinguishing agent outlet (5), at the other end (6) of the pipe (2) via a Control device (11) controllable discharge valve (10) is provided, so that the at least one extinguishing agent outlet (5) between the extinguishing agent source (4) and discharge valve (10) is arranged, wherein the control device (11) is adapted to a first control signal (12) indicating the opening of at least one extinguishing agent outlet (5) to open the drain valve (10) and the drain valve (10) due to a second control signal (13) indicating that a predetermined amount of liquid has passed through the drain valve (10) close, wherein the tube (2) in the standby state of the fire extinguishing system (1) is filled with an antifreeze solution, and wherein for generating the second control signal (13) a collecting basin (31) for the a us the drain valve (10) flowing liquid with a float (32) or a level gauge (33) and / or a pressure vessel (34) with pressure sensor (35) is provided. Fire extinguishing system (1) after Claim 1 , characterized in that for generating the first control signal (12), a flow detector (20), a pressure sensor (21), a fire alarm panel (22) and / or an alarm pressure switch (24) is provided. Fire extinguishing system (1) according to one of Claims 1 or 2 , characterized in that the flow resistance through the discharge valve (10) is smaller than the flow resistance through the at least one extinguishing agent outlet (5). Fire extinguishing system (1) according to one of Claims 1 to 3 , characterized in that the discharge valve (10) releases the entire pipe cross-section in the open state. Fire extinguishing system (1) according to one of Claims 1 to 4 , characterized in that between the pipe (2) and extinguishing agent source (4) an alarm valve (8) is provided. Fire extinguishing system (1) after Claim 5 , characterized in that in the standby state, the pressure of a liquid in the tube (2) is lower than the pressure of the extinguishing agent from the extinguishing agent source (4). Retrofit kit (1 ') for a fire extinguishing system (1) for connection to a fire extinguishing system (1) pipe (2) comprising an extinguishing agent outlet (5), comprising a drain valve (10), controllable by a control device (11), for liquid from the pipe (2), wherein the control device (11) is adapted to open the drain valve (10) on the basis of a first control signal (12) indicating the opening of at least one extinguishing agent outlet (5) on the pipe (2) of the fire extinguishing system (1) and due to a second control signal (13), which indicates that a certain amount of liquid has flowed out of the pipe (2) through the bleed valve (10), to close the bleed valve (10), wherein a catch basin is provided for generating the second control signal (13) (31) with a float (32) or a level gauge (33) and / or a pressure vessel (34) with pressure sensor (35) is provided.

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