WO2016070990A1 - Fire training installation - Google Patents

Abstract

The invention relates to a fire training installation (2) comprising a fire chamber (4) and a fire unit (6) arranged in the fire chamber (4), said fire unit being connectable to a gas supply unit (8), a first outlet (10) for gaseous gas from the gas supply unit (8), wherein the fire unit (6) has a second outlet (12) for liquid gas from the gas supply unit (8) and the fire chamber (4) has at least one opening (14) in a bottom wall (16) of the fire chamber (4) within a predetermined radius (R1) about the fire unit (6) ·

Description

 Fire training system

description

The invention relates to a fire training system having a fire chamber, a fire unit arranged in the fire unit, which is connectable to a gas supply unit, having a first outlet for gaseous gas from the gas supply unit.

Such fire training systems are known from the prior art. They are used to simulate a fire or a fire. If such a fire is simulated by means of the fire training system, firefighters can practice extinguishing this fire. The firefighters can try different techniques repeatedly and internalize the most appropriate technology for them.

The fire chamber is used to limit a room in which a fire is to be simulated. For this purpose, the fire chamber can be limited by several walls. For example, a container can be used for the fire chamber. Other embodiments with at least substantially refractory walls may alternatively be used.

In order to repeatedly cause similar fires in the fire chamber, which lead to comparable training situations for firefighters, it has proven to be advantageous to arrange a fire unit in the fire chamber. This fire unit is designed as a gas fire unit. It has an outlet for gaseous gas. The first outlet can be formed by a tube with one or more openings. The fire simulation is the Gas escaping from the first outlet ignites, whereupon a fire is created in the fire chamber. A corresponding fire can therefore be caused again even after extinguishing a flame, resulting in comparable fire situations. In order to allow gas to flow out of the outlet for gaseous gas, which is referred to as the first outlet in the context of this invention, the fire unit can be connected to a gas supply unit. Once this has taken place, gaseous gas originating from the gas supply unit can flow out of the first outlet. The gas supply unit may be a stationary gas supply unit or a mobile gas supply unit. A stationary gas supply unit may be, for example, a connection to a gas network, which is arranged stationary. A mobile gas supply unit may be, for example, a gas container in which the gas to be provided is stored.

Although the use of gaseous gas is fundamentally suitable for a fire unit and for simulating a corresponding fire, not all practical fires can be simulated with such a fire unit in the fire chamber. In particular, such a fire training system is not suitable for simulating a so-called "flashover", ie a situation in which the flame of the fire is suddenly increased. Because liquid gas has a higher energy density, it could therefore simulate larger flames with liquid gas, but in practice, it has been found that handling liquid gas with a known fire unit is one of them This can lead to the formation of liquid gas at the bottom of the fire chamber, leading to uncontrolled combustion of the gas that collects, which is an accidental and usually uncontrollable fire situation. The invention is therefore based on the object to provide a fire training system, with the different fires and in particular a "Fläshover" are safely simulated by means of a fire unit in a fire chamber, being banned by the fire unit gas.

 5

 The above object is achieved by the features of claim 1.

Thus, a fire training system with a fire chamber, a fire unit arranged in the fire chamber, which can be connected to a gas supply unit, has a first outlet for gaseous gas from the gas supply unit, wherein the fire unit has a second outlet for liquid gas, and the fire chamber within a predetermined radius around the fire unit has at least one opening in a bottom wall of the fire chamber.

5. , ·

 The invention is based on the idea that liquid gas has a higher density than air and / or gaseous gas. The second outlet therefore differs from the first outlet. The second outlet may have a pipe section with at least one opening, preferably a plurality of <0 openings. Should liquid gas escape from the second outlet and not be burned, but sink into the bottom area of the fire chamber, the fire chamber according to the invention, due to the at least one opening, provides a way through which the liquid gas can independently flow out of the fire chamber. It is provided that the -5 is at least one opening in the bottom wall of the fire chamber.

 In addition, the at least one aperture is located proximate to the second outlet because a predetermined radius about the firing unit indicates how far the at least one aperture may be from the second outlet. This radius may be adapted to the practical application of the fire unit or the fire equipment and / or the gas used.

However, the predetermined radius should not be too large to minimize the amount of unburned liquid gas. Preferably, the radius is less than 5 meters, 3 meters, 2 meters or 1 meter. Pass the unburned liquid gas through the at least one Opening out of the fire chamber, even with a subsequent ignition of the liquid gas for firefighters who simulate the extinguishing a fire with the fire practice, only a minimal risk that the ignited gas on the interior of the fire chamber, at least in thermal terms , affects. Because the gas passes through the opening in the bottom wall, the gas is carried away mostly by natural wind. The practicing firefighters are effectively protected from the aforementioned fire. The openings in the bottom wall of the fire chamber can be made by drilling. As a particularly cost-effective embodiment of the openings in the bottom wall, grids, in particular step grille have proven. In the area of the grids, the bottom wall of the fire chamber is characterized at least essentially by struts arranged at an angle to one another, between which transit areas are formed, which then represent the at least one opening of the bottom wall. Thus, it can also be said that a certain area of the bottom wall, in particular in the region of the specific radius around the fire unit, is characterized by spaced apart webs which form a multiplicity of openings. The cross-sectional area of the openings can therefore be many times greater than the material parts of the bottom wall forming between the openings, in particular the webs of a grid.

A preferred embodiment of the fire training system is characterized in that the at least one opening in the bottom wall of the fire chamber leads into an environment outside the fire chamber. This is preferably the case when the bottom wall of the fire chamber, at least in the region of the openings is spaced from a bottom on which the fire chamber is. Alternatively or additionally, the openings in the bottom wall may be channel-shaped, and then lead to an area which belongs to the environment of the fire chamber.

A further preferred embodiment of the fire training system is characterized in that on the outside via a bottom of the fire chamber excellent leg features are provided: The leg members ensure that the underside of the fire chamber is spaced from a floor on which the belt chamber is standing with the leg members. The leg members therefore serve to transmit the force of gravity of the fire chamber to the aforementioned ground. With the leg elements is particularly easy to ensure that liquid gas that flows through the opening in a bottom wall of the fire chamber, enters an area surrounding the fire chamber. By keeping the fire chamber at a distance from the bottom of the fire chamber, the leaking liquid gas is particularly easy and quick to disperse. In addition, the liquid gas that has entered the environment can be detected particularly easily by natural wind and / or by an artificially generated wind current in order to be transported away from the fire chamber. The leg elements are preferably attached to the underside of the fire chamber frictionally and / or cohesively. Thus, a high level of stability can be guaranteed. In addition, such leg elements are particularly simple and inexpensive to manufacture. If the fire chamber is made of metal, the leg elements can be fastened to the underside of the fire chamber by means of a welded joint.

 .

A further preferred embodiment of the fire practice system is characterized in that an opening in a side wall of the fire chamber, a door associated with the fire chamber for opening or closing the opening, and a sensor for monitoring the door or opening are provided. In practice, it has been found that unburned, liquid gas exiting the second outlet of the fire unit, flows through the opening in the bottom wall of the fire chamber particularly quickly when the fire chamber has at least one further, not closed, opening. In this case, the flow resistance for the liquid gas is particularly low. In order to ensure that the unburned, liquid gas with the aforementioned reduced flow resistance from the fire chamber can flow through the opening in the bottom wall, the sensor can be used to monitor whether the opening in the side wall of the fire chamber is open. In this case, the opening itself and / or a door to open or Close the. Opening to be monitored. With both alternatives, the information necessary to determine whether the opening is open or closed can be generated. A further advantageous embodiment of the fire training system is characterized in that the fire unit has a sensor for fire monitoring at the first outlet. The first outlet of the fire unit is used for the discharge of gaseous gas. During operation, this gaseous gas is ignited to initially simulate a fire situation. With the gaseous gas flowing out of the first outlet, a pilot flame can be ignited. This pilot flame remains independent of a spill of liquid gas from the second outlet of the fire unit, because with the pilot flame, the effluent, liquid gas is ignited. In other words, the pilot flame also serves as a pilot flame for the liquid gas flowing out of the second outlet. This provides a particularly high level of safety for the ignition of the liquid gas. In order to ensure that the liquid gas does not flow unburned into the interior of the fire chamber, the pilot flame can be monitored by means of the sensor for monitoring the fire at the first outlet. Preferably, the sensor is disposed near the first outlet. The sensor may for example comprise or be a temperature sensor. Other sensors suitable for fire monitoring may also be provided. If the pilot flame is monitored with the fire monitoring sensor, it can be ensured that escaping, liquid gas is ignited. For monitoring the pilot flame, for example, the temperature can be monitored. In this case, the temperature of the pilot flame can be compared with an associated minimum limit temperature. If the first outlet for the gaseous gas is not punctiform, but is formed, for example, by a plurality of openings in a pipe section, other sensor configurations for fire monitoring can also be provided. The sensor for fire monitoring can be formed in this sense by a plurality of sensor elements, which is spaced apart on the aforementioned tube with the plurality of openings arranged. In particular, the Sensor elements have a certain distance from the aforementioned tube so as not to be exposed to high temperature.

A further preferred embodiment of the firing system is characterized in that the sensor for monitoring a fire at the first and the second outlet is configured. The first outlet for gaseous gas and the second outlet for liquid gas are associated with the fire unit. It has proven in practice, when the two outlets are arranged so close to each other, that a flame which arises when igniting the gaseous gas from the first outlet, at least to the second outlet ranges. Other configurations are also conceivable in which the flames which have an overlap region when gas is combusted from the first outlet and / or the second outlet. Therefore, it has proven to be advantageous in practice to use the same sensor, in particular with the same sensor elements, in order to generate a flame caused by the gaseous gas from the first outlet as well as a flame caused by the liquid gas from the second outlet monitor. Thus, the number of sensors for monitoring a fire at the first outlet and the second outlet can be kept very low. In particular, a sensor for fire monitoring with two sensor elements has proven to be advantageous in practice. The two sensor elements can be attached to opposite ends of the fire unit and / or the two outlets, so that it can be assumed that the flames of the fire unit to be generated can be monitored.

A further advantageous embodiment of the fire training system is characterized in that the fire training system has a control unit for controlling and / or monitoring the fire unit. For this purpose, the fire unit may for example be associated with valves with which a gas flow or gas flow to the first outlet and / or second outlet is adjustable. In this case, at least one check valve and / or at least one throttle valve can be provided for each outlet. At least one of the valves associated with the respective outlet may be controlled by the control unit become. Alternatively or additionally, the control unit can be designed to monitor the fire unit. For this purpose, a communication connection can be provided between the at least one sensor for fire monitoring and the control unit. Thus, the information of the sensor with respect to the respective flame to be monitored can be transmitted to the control unit. This can evaluate the information. Depending on the result of the evaluation, the control unit can control, for example, the valves of the fire unit. For example, the control unit firstly opens the valve to the first outlet to produce a pilot flame. If the pilot flame is detected by the fire monitoring sensor, a valve may then be opened to the second outlet to allow the liquid gas to flow out through the second outlet to produce a so-called "flashover." This is a flame with In addition, the control unit can be connected to a control unit, which controls the conditions of the fire unit, and in particular the control of the valves, in which case the control unit can be configured to carry out the desired commands Person can be generated by means of the control unit, only implement if certain conditions are met.So example, the opening of a valve for discharging liquid gas from the second outlet is only possible if detected by the sensor for fire monitoring a pilot flame at the first outlet Another preferred embodiment The firing system is characterized in that the second outlet is arranged above the first outlet. If a flame is ignited by the outflowing, gaseous gas from the first outlet, this extends upwards. The flame hits the second outlet. Preferably, the second outlet is arranged above the first outlet, such that a flame which arises when gaseous gas is combusted from the first outlet reaches at least to the second outlet and / or extends beyond. Thus, a pilot flame is generated which ignites liquid gas immediately for combustion as it exits the second outlet. The Thus, liquid gas is safely set on fire as it exits the second outlet. Therefore, a fire training system with the above-explained arrangement of the two outlets is particularly safe. A further advantageous embodiment of the fire training system is characterized in that a gas sensor is provided on and / or under the bottom wall of the fire chamber. In this case, the gas sensor may be arranged in the immediate vicinity of the opening in the bottom wall. If the gas sensor is arranged below the bottom wall, however, the gas sensor can be fastened to the fire chamber, in particular to the associated bottom wall. The gas sensor can be used to monitor a fire that occurs when a liquid gas burns when it exits the second outlet. It has previously been explained that at least one sensor for fire monitoring is assigned to the fire unit in order to monitor reliable combustion of the escaping gas at the first outlet and / or second outlet. Should this monitoring, for example due to a defect, fail and at the same time unburned, liquid gas flow through the opening in the bottom wall of the fire chamber, this liquid gas is detected by the gas sensor and / or under the bottom wall. The gas sensor is thus preferably designed for the detection of liquid gas and / or the corresponding gas type. If now by means of said sensor, a minimum concentration of the liquid gas is detected, which has optionally passed into the gaseous phase, this information can be used for monitoring. If no gas is measured, although liquid gas flows out of the second outlet, the liquid gas is burned. Otherwise there is a malfunction. We recognized the malfunction, precautions can be taken. For example, a valve can be closed to stop the gas flow from liquid gas to the second outlet.

A further advantageous embodiment of the fire training system is characterized in that between the control unit and the gas sensor, a communication connection is formed. The information of the gas sensor are thus transmitted to the control unit. This can then be recorded Compare gas value with gas threshold size. If the measured gas value exceeds the gas threshold value, follow-up actions can be initiated. This may, for example, be the determination of the malfunction as explained in the previous section. Alternatively or additionally, valves can be closed, in particular the valve which is designed to open and / or close a gas flow to the second outlet. The control unit can thus use the available information of the gas sensor and / or the Feuerüberwachuiig the fire unit to generate control signals that stop another gas flow from the first outlet and / or from the second outlet. This is the case, in particular, if escaping gas from the first outlet and / or out of the second outlet does not produce any corresponding flame which can be detected directly or indirectly with at least one of the aforementioned sensors.

A further advantageous embodiment of the fire training system is characterized in that the fire training system has at least one gas monitoring unit outside of the fire chamber in an environment with a maximum radius of 15 meters, in particular between 1 meter and 25 meters, to the at least one opening of the bottom wall Fire chamber is arranged or are. The above-discussed gas sensor on and / or under the bottom wall of the fire chamber and the sensor for fire monitoring at the first and the second outlet are arranged in close proximity to the fire, which may be caused by the outflowing gaseous or liquid gas. Although the fire monitoring sensor and / or gas sensor may have heat resistance, proximity to the aforementioned fire poses a residual risk which increases the risk of failure of the aforementioned sensors. With a gas monitoring unit at a greater distance to the fire chamber, of a maximum of 5 meters, 10 meters, 15 meters or 25 meters, it is achieved that the gas monitoring unit is exposed to a significantly lower heat or heat load and that through the opening in the bottom wall the fire chamber leaking, liquid gas is detected promptly and with a good measurable concentration. Especially Preferably, the gas monitoring unit is arranged in a radius of the fire chamber between 1, 5 meters and 15 meters, more preferably between 2 meters and 10 meters. Thus, the gas monitoring unit also has a minimum distance to the fire chamber in order to minimize the heat or heat impact on the gas monitoring unit. The gas monitoring unit may comprise at least one gas meter. More preferably, a plurality of gas measuring devices are provided for the gas monitoring unit. These gas meters may be spaced from one another about the fire chamber. In particular, the plurality of gas measuring devices of the gas measuring unit are arranged in a star shape relative to the fire chamber. With such a configuration, a flowing through the opening in the bottom wall of the fire chamber, liquid gas can be detected particularly quickly and safely. Because regardless of the wind direction, through which the escaping, liquid gas is transported away from the fire chamber, the gas strikes one of the gas meters. The evaluation of the information about the measured gas generated by the gas measuring instruments can be carried out analogously to the previous embodiment with the gas sensor on and / or under the bottom wall of the fire chamber. Reference is therefore made to the corresponding explanations by analogy. If a plurality of gas measuring devices are provided for the gas monitoring unit, these can form a communications network in order to exchange information with one another and / or with the control unit. In particular, the information network for data forwarding and / or alarm message forwarding to the control unit can be configured.

A further advantageous embodiment of the fire training system is characterized in that a communication connection is formed between the control unit and the gas monitoring unit. Thus, information of the gas monitoring unit, in particular of at least one gas measuring device of the gas monitoring unit, can be transmitted to the control unit. The control unit can evaluate the corresponding information and initiate follow-up actions. The follow-up actions may be, for example, closing at least one valve to stop the gas flow to the first outlet and / or the second outlet. A further advantageous embodiment of the fire training system is characterized in that the fire unit is fastened on the inside to a side wall of the fire chamber. A flame that arises when igniting the gaseous and / or liquid gas at the outlet from the respectively associated outlet, can then spread very large volume. This can be used to simulate different fire situations. In addition, the arrangement of the fire unit on the inner side wall of the fire chamber offers the advantage that liquid gas flowing out of the second outlet still ignites before it reaches the opening in the bottom wall of the fire chamber. This increases the passive safety of the firing system.

characters

 In the following the invention without limiting the general inventive concept will be described by means of embodiments with reference to the drawings. In the drawings: FIG. 1 is a schematic perspective view of the

 Fire training system, a schematic sectional view of a fire chamber with a view from above into the associated interior,

Fig. 3 is a schematic representation of the fire chamber in one

 Partial section, and

Fig. 4 is a schematic view of the fire unit.

From Figure 1, the fire training system 2 is shown schematically. The fire training system includes a fire chamber 4. The fire chamber 4 has a metallic container. On the front doors are attached to open the container. In addition, on a side wall 22 a Opening 20 is provided, which is closable by means of two superimposed doors 24 and can be opened. A further opening of the fire chamber 4 is provided in a roof wall, wherein a chimney 40 connects to the opening. In the longitudinal direction, however, the fire chamber 4 is not configured continuously. Rather, a transverse wall 42 is provided, as can also be seen from Figure 2, wherein the transverse wall 42 divides the interior of the container into two spaces. One of the two rooms, preferably the smaller, forms the technical room 44, in which the control unit 30 of the fire training system 2 is arranged. From the other room then the fire chamber 4 is at least partially formed. In the fire chamber 4 fires are simulated to give firefighters the opportunity to practice appropriate countermeasures and extinguish the respective fire. In order to simulate a fire, a fire unit 6 is arranged in the interior of the fire chamber 4. Preferably, the fire unit 6 is attached to the transverse wall 42. To supply the fire unit 6 with combustible gas, the fire chamber 4 or the fire unit 6 with a gas supply unit 8 is connectable. For this purpose, appropriate pipe connection can be provided, which are suitable for transporting gas from the gas supply unit 8 to the fire unit 6. If the fire unit 6 is now connected to the gas supply unit 8, for example a gas storage, then gas can flow out of a first outlet 10, as can be seen for example from FIG. The first outlet 10 is configured to discharge gaseous gas. The gas originates from the gas supply unit 8. The first outlet 10 may be formed by a tubular element 46 having a plurality of openings 48. Other configurations of the first outlet 10 are also possible, which are suitable for allowing gaseous gas to flow out. In order to achieve a fire by means of the outflowing, gaseous gas, the gaseous gas is ignited. For this purpose, a corresponding ignition device (not shown) may be provided. The ignited gas causes a corresponding flame, with which, in particular depending on the pressure with which the gaseous gas flows out of the first outlet 10 and / or the number of openings 48, which are associated with the first outlet 10, different fires can be simulated. Gaseous gas has one Energy density suitable for simulating a specific number of fire situations. However, gaseous gas is for the most part not suitable for simulating a so-called "flashover." Therefore, the fire unit 6 according to the invention has a second outlet 12 for liquid gas of the firing system 2. Analogously to the design of the first outlet 10, the second outlet 12 can be provided by a Pipe element 50 may be configured with a plurality of openings 52. In order to discharge liquid gas by means of the second outlet 12, the fire unit 6 is connected to the gas supply unit 8, which is preferably designed to also provide liquid gas Instead of a common gas supply unit for liquid gas and for gaseous gas, different gas supply units may be provided for each of the two types of gas and it is also preferred that the second outlet is designed specifically for the outflow of liquid gas, in particular for the associated openings 52.

In order to simulate a "flashover" by means of the firing system 2, first of all gaseous gas flowing out of the first outlet 10 is ignited, and a corresponding flame is also called a pilot flame, since this is suitable for igniting liquid gas which is emitted from the gas If the liquid gas, which has a significantly higher energy density than the gaseous gas, ignites, a significantly larger flame is formed, which forms the previously discussed "flashover". With the pressure and / or volume flow of liquid gas exiting the second outlet 12, the size of the resulting flame and / or range of the "flashover" can be determined.

As can be seen from FIG. 4, a controllable valve 56 is provided in the gaseous gas supply line 54 in order to control a volume flow of gaseous gas to the first outlet 10. The valve 56 can be controlled by the control unit 30. In this case, the valve 56 can pass a volume flow of gaseous gas, stop and / or throttle. Analogous to the supply line 54 and the valve 56 is for the second outlet 12, a supply line 58 for liquid gas to the second outlet 12 and a controllable valve 60 for the supply line 58 is provided. With the valve 60, a volume flow of liquid gas to the second outlet 12 can be blocked, released and / or throttled. For this purpose, the controllable valve 60 can be controlled by means of the control unit 30. Due to the controllability of the volume flows for gaseous gas and liquid gas, different fire situations can be simulated.

Due to the high energy density of the liquid gas is from the fire unit 6 a higher risk. Therefore, it is provided according to the invention and can be seen from FIG. 2 that the fire chamber 4 has at least one opening 14 in a bottom wall 16 of the fire chamber 4 within a predetermined radius R1 of at most 1.5 meters around the fire unit 6. In other words, an opening 14 is provided in the bottom wall 16 of the fire chamber 4 in the immediate vicinity of the fire unit 6. The bottom wall 16 of the fire chamber 4 is therefore not closed. Rather, the bottom wall 16 of the fire chamber 4 is open in the vicinity of the fire unit 6. Should it now happen that flows out of the second outlet 12 liquid gas, which does not fire immediately thereafter, but due to the higher density than the ambient air sinks to the ground, the liquid gas, the fire chamber 4 through the openings 14 in the bottom wall 16 left. As can be seen from Figure 3, the bottom wall 16 of the fire chamber 4 from a floor, in particular the earth on which the fire chamber 4 is spaced. It thus forms at the bottom of the fire chamber 4 in the region of the opening 14 in the bottom wall 16, a transverse channel, which is externally connected to the environment. Thus, wind or an artificially generated air flow can flow under the fire chamber 4 through the channel and thereby carry the exiting through the openings 14, liquid gas. The liquid gas is removed from the danger point near the fire chamber 4, so that the risk of uncontrolled ignition drops quickly. With the openings 14 in the bottom wall 16 of the fire chamber 4 so the passive safety of the fire training system 2 with a fire unit 6, which has an outlet for liquid gas, significantly increased. In addition, an active monitoring of the fire unit 6 is provided to increase safety. For this purpose, a fire sensor 28 may be provided, as can be seen from FIG. This fire sensor 28 is preferably designed as a temperature sensor and / or as an optical flame sensor. The fire sensor 28 is connected to the control unit 30 through a communication link. The control unit 30 may be designed to evaluate the sensor signals of the fire sensor 28 in order to detect whether a fire is produced when a gaseous gas flows out of the first outlet 10. If this is not the case, the gas flow can be interrupted by means of the valve 56. In addition, the fire sensor 28 can also be designed to detect a "flashover", since in this case a significantly larger flame with a correspondingly higher temperature is produced, ie should liquid gas flow out of the second outlet 12 without the aid of the fire sensor 28 and the Control unit 30 a large increase in temperature and / or a correspondingly larger flame are detected, this may indicate that the liquid gas exits from the second outlet 12, without there then comes to a combustion.In this case, by means of the control unit 30, the valve 60 closed to prevent further outflow of liquid gas and / or uncontrolled ignition of the liquid gas.

It has previously been explained that the firing system 2 has both improved passive safety through the openings 14 in the bottom wall 16 and improved active safety by the fire sensor 28 on the fire unit 6. The fire sensor 28 is exposed to high thermal stress due to its close proximity to the fire unit 6 fire. Therefore, in order to further improve the active safety of the fire training system 2, a gas sensor 32 is arranged under the bottom wall 16 or on an outer side of the bottom wall 16 of the fire chamber 4. Should it therefore come to an outflow of liquid gas through the second outlet 12, wherein the outflowing gas flows unburned through the opening 14, the gas can be detected by means of the gas sensor 32. The gas sensor 32 is connected to the control unit 30 through a communication link. With the detection of the liquid gas on the underside of the bottom wall 16 can therefore be concluded that liquid gas flows unburned into the fire chamber 4. The control unit 30 is therefore configured in such a way that then at least the valve 60 and preferably also the valve 56 are closed in order to stop a further gas flow to the first outlet 10 and second outlet 12, respectively. This then increases the active safety of the fire exercise 2.

To ignite gas to a fire, oxygen is necessary. If there is no oxygen in the fire chamber 4, the gas flowing out of the first outlet 10 and / or out of the second outlet 12 can not be ignited. To improve the passive safety of the fire training system 2, is therefore at least one. Sensor 26 is provided, which is configured to monitor a door 24 and / or an opening 20 in a side wall 22 of the fire chamber 4. With the door 24, the opening 20 can be opened or closed. Thus, the sensor 26 serves to monitor the door 24 and / or the opening or to determine whether oxygen can flow from the environment into the fire chamber 4 through the opening 20. If this is the case, the gas flowing out of the outlets 10, 12 can be ignited. This improves the safety of the fire training system 2.

An expanded safety concept for the fire training system 2 also provides for the monitoring of the environment around the fire chamber 4. The fire training system 2 is therefore associated with a gas monitoring unit 36. With the gas monitoring unit 36, the environment can be monitored for gas, in particular for gaseous gas and / or liquid gas. The gas monitoring unit 36 has for this purpose a plurality of gas measuring devices 38. These gas measuring devices 38 can be arranged in a radius R2 between 2 meters and 25 meters around the fire unit 6. The radius R2 is significantly greater than the previously explained radius R1, within which the openings 14 are arranged in the bottom wall 16. With the gas measuring devices 38, therefore, a larger area is monitored for gas. Should it now come to a gas outlet of liquid gas and / or gaseous gas through the opening 14 in the bottom wall 16, which is then distributed by wind or other artificial volume flow of air in the environment, this is detected by the gas monitoring unit 36 and the associated gas measuring devices 38. A corresponding information is transmitted to the control unit 30. For this purpose, the gas measuring devices 38 may be connected by appropriate communication lines and / or by a radio link to the control unit 30. The control unit 30 then closes the valves 56, 60 in the supply lines 54, 58 to the two outlets 10, 12. This prevents that there is a further outflow of gas and / or uncontrolled combustion from the gas.

LIST OF REFERENCE NUMBERS

R1 radius

 R2 radius

 2 fire training system

4 fire chamber

 6 fire unit

 8 gas supply unit

10 first outlet

 12 second outlet

 14 opening

 16 bottom wall

 18 leg element

 20 opening in side wall

22 side wall

 24 door

 26 sensor

 28 fire sensor

 30 control unit

 32 gas sensor

 36 gas monitoring unit

38 gas meter

 40 chimney

 42 transverse wall

 44 technical room

 46 pipe element

 48 opening

 50 pipe element

 52 opening

 54 supply line

 56 valve

 58 supply line

 60 valve

Claims

claims

1. fire training system (2) with

 a. a fire chamber (4) and

 b. a in the fire chamber (4) arranged fire unit (6), the i. can be connected to a gas supply unit (8) ii. a first outlet (10) for gaseous gas from the gas supply unit (8),

 characterized in that

 c. the fire unit (6) has a second outlet (12) for liquid gas from the gas supply unit (8), and

 d. the fire chamber (4) within a predetermined radius (R1) around the fire unit (6) has at least one opening (14) in a bottom wall (16) of the fire chamber (4).

2. fire training system (2) according to the preceding claim, characterized in that the at least one opening (14) in the bottom wall (16) of the fire chamber (4) leads into an environment outside of the fire chamber.

3. fire training system (2) according to one of the preceding claims, characterized in that on the outside over the bottom wall (16) of the fire chamber (4) outstanding leg elements (18) are provided.

A fire practice system (2) according to one of the preceding claims, characterized by an opening (20) in a side wall (22) of the fire chamber (4), a door (24) associated with the fire chamber (4) for opening or closing the opening (20), and a sensor (26) for monitoring the door or opening (24).

5. fire training system (2) according to any one of the preceding claims, characterized in that the fire unit (6) has a sensor (28) for fire monitoring at the first outlet (10).

6. fire training system (2) according to the preceding claim, characterized in that the sensor (28) for monitoring a fire at the first (10) and the second outlet (12) is configured.

7. fire training system (2) according to the preceding claim, characterized in that the fire training system (2) has a control unit (30) for controlling and / or monitoring the fire unit (6).

8. fire training system (2) according to one of the preceding claims, characterized in that the second outlet (12) above the first outlet (10) is arranged.

9. fire training system (2) according to any one of the preceding claims, characterized in that on and / or under the bottom wall (16) of the fire chamber (4), a gas sensor (32) is provided.

10. fire training system (2) according to one of the preceding claims 4 to 9, characterized in that between the control unit (30) and the at least one sensor (32) each having a communication connection is formed.

11. fire training system (2) according to any one of the preceding claims, characterized in that the fire training system (2) has at least one gas monitoring unit (36) outside the fire chamber (4) in an environment with a maximum radius (R2) of 15 meters the at least one opening (14) of the bottom wall (16) of the fire chamber (4) is or are arranged.

12. fire training system (2) according to the preceding claim, characterized in that between the control unit (30) and the at least one gas monitoring unit (36) each have a communication connection is formed.

13. fire training system (2) according to any one of the preceding claims, characterized in that the fire unit (6) on the inside on a side wall (22) of the fire chamber (4) is fixed.