WO2016070985A1 - Fire training unit - Google Patents

Abstract

The invention relates to a fire training unit (2) comprising at least two containers (4), at least one contact region (6) between in each case two of the containers (4), the outer surfaces (8) of said containers adjoining in the associated contact region (6), a passage (10) in every contact region (6) between the associated containers (4), and a fire unit (12) in every container (4).

Description

 Fire training system

description

The invention relates to a fire training system.

Fire training systems are basically known from the prior art.

A fire training system includes, for example, a container in which a fire unit is arranged. For example, the fire unit may be configured to burn gas in the gas phase. The

Fire training system thus serves to simulate a fire or a fire.

If such a fire is simulated by means of a fire training system, can

Firefighters are practicing extinguishing this fire. The firefighters can try different techniques repeatedly and internalize the most appropriate technology for them.

The container of a fire training system is used to limit the space in which a fire is to be simulated. This makes it possible to repeatedly cause comparable fires that lead to comparable training situations, firefighters.

Containers for fire training systems have proven themselves in practice, as they can be transported from one location to another on a mobile basis. Because of the mobile transport of the containers, training can always be offered where there is a need to train firefighters.

CONFIRMATION COPY However, the use of a container for a fire training system also has disadvantages. Because of the limited space of a container, this space can be clear for the practicing people, which does not usually correspond to a real fire situation. In the case of repeated deletion of a simulated fire, predictable fire events can also occur, which reduces the training effect of the person to be trained.

In practice, therefore, so-called fire homes have proven to be useful. These fire homes are solid and stationary designed houses in which separate rooms are formed, in each room different fires can be simulated. Due to the stationary design of such fire houses, however, it is necessary that the practicing people, even if they do not live or work in close proximity to the fire, take the path to the fire to take such an exercise. In addition, such fire homes are very expensive due to their stationary design. Because with every simulation of a fire, at least parts of the fire house can be worn out. The renewal of the fire, at least the parts just mentioned, causes not inconsiderable costs. Finally, a redesign of the interiors of a fire house is virtually impossible, so that a repetitive effect can occur in practicing people.

The invention is therefore based on the object to provide a cost-effective fire training system, with the different fire situations are as easy to adjust.

The stated object is achieved by a fire training system having the features of claim 1.

Thus, a fire training system with at least two containers is provided, at least one contact area between in each case two of the containers which in each case have one of their outer sides in the associated contact region contiguous, one passage in each contact area between the associated containers, and one fire unit in each container.

Containers are basically known from the prior art. The container can be understood as a container, in particular as a cuboid container. At least one outer side may be provided with access to the interior of the container. The access can be opened or closed by means of a door. In addition, further openings may be provided for each or at least one container in order to enable and / or control a supply of fresh air and / or the discharge of exhaust gas. One of these variants of the container, for example, the so-called ISO container. This has heat-resistant outer walls, in particular of metal. In addition, doors may be provided longitudinally on an end face to provide access to the container.

For the fire training system at least two, preferably three or more containers are provided. The containers may have at least substantially the same external dimensions. In addition, the containers can be designed to be stackable.

Two of the containers adjoin one another with one of their outer sides. For example, the containers may have the same longitudinal orientation, and border each other with one of their respective outer sides. Alternatively it can be provided that two containers are arranged with their respective longitudinal orientation perpendicular to each other. In this case, an end-side outer surface of one container adjoins the longitudinal outer surface of the other container. By each two of the containers adjoin one another with one of their respective outer side, there forms a respective contact area associated with the two containers.

In order to be able to set as many different fire situations and / or the complexity of a fire, a passage in each contact area between the associated containers is provided. The passage is thus in the area where two containers adjoin each other. Thus, the containers can create spaces that can not be surveyed from any position in one of the containers. In particular, the containers can be designed such that different arrangements are possible in each case to each other. For example, if the containers were arranged one behind the other in the longitudinal direction for the simulation of a fire situation, the containers can be arranged at right angles to one another to simulate another fire situation. Besides, it is intended that in every container. a fire unit is. By providing a fire unit for each container, different fire situations can be adjusted. For example, if three or four containers are used for the fire training system, for example, the first container adjacent to the second container, the second container adjacent to the third container and the third container adjacent to the fourth container. Between each adjacent containers a passage is provided. In other words, a passage is provided between the first container and the second container, another passage between the second container and the third container, and a third passage between the third container and the fourth container. Preferably, at least two of the containers are arranged perpendicular to each other. This forms an in the base L-shaped and / or at least not tubular space, which is difficult to survey. If the fire units in the containers are also operated at different times and / or with a time delay, a large number of fire situations can be adjusted.

Due to its modular design with a plurality of containers, the fire training system according to the invention offers the possibility of operating the fire training system at different locations. After a certain period of use, the fire training system can be transported from one location to another to restart the fire training system. In addition, it is possible to change the arrangement of the container to each other after a certain period of operation to adjust new border situations. If, for example, three containers have been provided for the firing trainer, which are initially arranged in an L-shape relative to one another, then the three containers can be arranged in a T-shaped manner after a certain time to form a new space for the fires, so that the practicing firefighters become new See fire situations exposed. This increases the exercise effect.

A preferred embodiment of the fire training system is characterized in that the fire units differ by their respective type of fire. Thus, it is possible that the fire unit of a container from the fire unit of another, especially adjacent container, differs. By providing a different fire unit for each container, the respectively associated type of fire can be limited to the container, at least substantially, in which the respective fire unit is arranged. So it can be made a concentration of different types of fire on the container. This facilitates the control of the fire training system. In addition, it improves the safety of the fire training system, since the persons to be monitored can assign potential hazards to certain containers of the fire training system. In particular, monitoring units, in particular sensors, may be provided for the respective containers in order to effectively design the monitoring of the firing system.

Basically, a fuel burned with a fire unit. This may be, for example, gas, wood, coal and / or another substance. The type of fire therefore characterizes the fire unit by the particular fuel to be burned and / or the way the respective fuel is burned. Because in practice it has been found that with the combustion of, for example, gas different fires can be simulated. This depends, for example, on the state of aggregation of the gas. By way of example, LPG can be used to simulate a very large flame, in particular a "flashover." Gas in gaseous form burns with a significantly smaller flame, and is usually not suitable for generating the "flashover" mentioned above. A further advantageous embodiment of the fire training system is characterized in that one of the fire units is configured as a gas combustion unit. The use of gas for the at least one fire unit has proven to be particularly advantageous in practice. If a fire unit is supplied with gas as fuel, this is referred to as a gas combustion unit. The generation of a flame and / or a fire with a gas combustion unit can be controlled particularly easily by controlling the volume flow and / or the mass flow of gas to the gas combustion unit. Thus, different sized flames can be generated. In addition, the fire or the fire of a gas combustion unit can be particularly. quickly stop by stopping the gas flow to the gas combustion unit. A gas combustion unit is therefore particularly easy to control. This increases the safety of the fire training system.

A further advantageous embodiment of the fire training system is characterized in that one of the fire units is configured as a solid combustion unit. Solids may be, for example, wood, coal and / or the like. If solid is burned in the fire unit, this is referred to as a solid combustion unit. Solid combustion units have proven to be advantageous in practice to readjust as practical fire situations. Because with the combustion of a solid is often caused a large amount of smoke, which greatly reduces the visibility in each container. With the large amount of smoke and thus reduced visibility, the orientation ability can be practiced and improved. This is especially true while a corresponding fire is burning. By connecting two of the containers through a passageway, two different fires can be simulated in a space spanned by two containers. This is particularly relevant in practice, because such fires occur in a similar way in reality and require a skilled handling to allow safe extinguishment of the gas. A further advantageous embodiment of the fire training system is characterized in that one of the fire units is designed to generate water vapor and / or smoke. To generate steam, a ^"flame by combustion of gas can be provided in a water bath. This technology is in principle from the prior art. The development of a large amount of water vapor corresponding to a practical case of a real fire. Thus, by A further advantageous embodiment of the fire training system is characterized by a fire control unit which has a communication connection to the at least one of the fire units, ie if a fire unit is connected to a fire control unit by an associated communication connection, this fire unit can be operated by the fire control unit Preferably, several or all fire units are connected to the fire control unit by means of communication links. a gas supply, in particular by a gas tank, may be provided. Controlled by the fire control unit, the gas flow to the gas combustion unit and / or controlled by a sensor, the combustion of the gas combustion. Analogous embodiments may be provided for the solid combustion unit and / or the fire unit for generating steam and / or smoke. Particularly preferred is between each of the fire units of the fire training system and the fire control unit one each _. associated communication connection provided. The fire units can therefore be controlled and / or monitored by the common fire control unit. This allows the simulation of staggered fires by the majority of fire units, fires with different fire intensities can be caused.

A further advantageous embodiment of the fire training system is characterized in that at least one passage is associated with a door, by means of which the associated passage can be opened or closed, so that at least two fire chambers are formed by the containers. On both sides of the passage thus forms a fire chamber in each of the two corresponding containers. The two fire chambers are connected by the closable passage. It can therefore be simulated fires in which the passage is opened by means of the door, which influence the fires in the two fire chambers. However, it is also possible that the door is closed, so that fires can be simulated separately in the two fire chambers. For the door adjustable stops can be provided so that a pivoting direction for the door to open or close changeable or determinable. The stops can also serve to lock the door in the closed state. The fire chambers extending laterally to the passage or the door can in each case be formed by at least one container or several containers.

A further advantageous embodiment of the fire training system is characterized in that at least three containers are provided. At least two of the containers form a continuous fire chamber. A continuous fire chamber formed by at least two containers has for this purpose at least one passage between the respectively adjacent containers, wherein the at least one passage is unlockable and / or unsealable. By at least two containers form the continuous fire chamber, and each container is assigned a fire unit, at least two fire units are provided in the continuous fire chamber. In particular, the at least two fire units in the continuous fire chamber of different types of fire. Thus, fire situations can be simulated, which are particularly practical. For example, it is possible that one of the fire units is designed as a solid combustion unit. For example, wood may be burned and / or used to generate smoke. The further fire unit in the continuous fire chamber can for example be designed as a gas combustion unit to simulate another type of fire in the same fire chamber. Such fires are in practice difficult to erase and are therefore particularly well suited for practice or simulation.

A further advantageous embodiment of the fire training system is characterized in that the containers are designed like a module. Each container can thus form a module. The containers may each have at least substantially the same external dimensions. This ensures that the containers are modularly connected to each other. For this purpose, connecting elements can be provided on the container, which are suitable for the modular connection of two or more containers. The modular design of the container ensures that several containers can be arranged in different configurations to each other. For example, three containers may be L-shaped or T-shaped with respect to each other. Another embodiment of the arrangement of three containers is for example a Z-shaped arrangement. Due to the modular design of the container different fire situations can be simulated and different interior arrangements are constructed. A further advantageous embodiment of the fire training system is characterized in that a retaining wall is provided which projects from a container outer wall inwardly into the associated interior of the container. For example, the retaining wall may extend downwardly from a ceiling wall of a container towards the bottom wall of the container. In this case, the retaining wall extends only over part of the cross-sectional area of the interior of the container. For example, the retaining wall may extend to an upper third of the cross-sectional area of the interior space of the container. The containment wall can be used to limit as much as possible the emissions of fire and / or smoke created by a fire unit in the container in a part of the container. For example, if solid, such as wood, is burned and / or charred by the fire unit, producing smoke, which then rises to the ceiling, the retaining wall at least partially prevents the smoke from penetrating another area of the container and / or through the passage into an adjacent container. However, the flow of smoke into an adjacent container can only be limitedly stopped by the retaining wall. However, it has been found in practice that the retaining wall acts effectively at least in an initial time. With the retaining wall, therefore, special fire situations can be simulated in which smoke first concentrates in one area of a room and then penetrates to other rooms.

A further advantageous embodiment of the fire training system is characterized in that the retaining wall is fixed with a hinge to the container outer wall, in particular the container ceiling, wherein the retaining wall between a first state in which the retaining wall extends away from the container outer wall in a second State in which the retaining wall is folded up against the container outer wall, is movable. Previously, the advantages were explained when the retaining wall extends into the interior of the container. Corresponding advantages are therefore also apparent when the retaining wall is in the first state. In the second state, the retaining wall was folded up against the container outer wall. For example, the retaining wall can be folded up against the container ceiling. In this case, the effect explained in the previous section is not achieved. Rather, smoke, for example, can spread freely within the container. For certain simulations of fires, this is also desired. By the retaining wall is fixed with the hinge to the container outer wall, so can be simulated different fire situations, in particular depending on the state of the retaining wall.

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 show: a schematic cross-sectional view of the firing system,

Fig. 2 is a schematic cross-sectional view of two separate containers arranged for a fire training system, and

Fig. 3 is a schematic interior view of a container of

 Fire training system.

FIG. 1 shows the firing system 2 in a schematic cross section. The fire training system 2 comprises three containers 4, namely a first container 4a, a second container 4b and a third container 4c. The containers 4a, 4b, 4c are T-shaped to each other. For this purpose, one end-side outer side 8 of the first container 4a adjoins an end-side outer side 8 of the second container 4b. The two containers 4a, 4b thus border each other with one of their outer sides 8. The transition from the two containers 4a, 4b forms a contact region 6 between the two containers 4a, 4b. At the respective outer side 8 of the two containers 4a, 4b doors 28 are arranged. With the doors 28, an opening can be created on the respective outer side 8 of a container 4 in order to ensure a passage to an adjacent container 4. As can be seen from FIG. 1, the first container 4a and the second container 4b are aligned adjacent to each other with their respective outer side 8, the doors 28 of each of the two containers 4a, 4b being open, so that a passage 10 is provided in the contact region 6 between the two containers 4a, 4b arises. With the passage 10, the inner spaces 30 of the first container 4a and the second container 4b form a common fire chamber 20. For in each of the two containers 4a, 4b at least one fire unit 12 is arranged in each case. For example, a gas combustion unit is provided as the fire unit 12 in the first container 4a. In order to supply this fire unit 12 with gas, a gas supply unit 32, in particular a gas tank with gas, may be provided. The Gas supply unit 32 is connected via corresponding fluid lines with the fire unit 12 of the first container 4a. In the second container 4b, a fire unit 12 configured as a solid combustion unit may be provided. With this fire unit 12, for example, wood can be burned and / or charred to create the strongest possible smoke.

It has previously been explained that the first container 4a and the second container 4b adjoin one another, and in the resulting contact region 6, a passage 10 is provided. The containers 4 and 4a, 4b are designed like a module. It is therefore also possible for other outer sides 8 of the containers 4, 4a, 4b to adjoin one another in order to form another contact region 6 or passage 10. By way of example, this will be explained with the further, third container 4c. An end face 8 of the container 4c borders on a longitudinal side 8 of the second container 4b. In this case, the second container 4b is provided with a door 18 on the longitudinal outer wall. The frontal side 8 of the third container 4c is preferably open. If the third container 4c now arranged with the frontal opening in the region of the door 18 in the longitudinal outer side 8 of the second container 4b, formed in the contact region 6 between the second container 4b and the third container 4c, a passage 10. This passage 10 can by means of the door 18 are opened or closed. If the door 18 is closed, the interior spaces 30 of the first container 4a and of the second container 4b form a fire chamber 20. A further fire chamber 20 is formed by the interior 30 of the third container 4c. In other words, the fire training system 2 illustrated in FIG. 1 has at least essentially two fire chambers 20. Alternatively, it may be provided that the door 18 is open. In this case, the interiors of the containers 4a, 4b and 4c connect. If the door 18 is permanently open, the firing system 2 has a combustion chamber 20 extending over the inner spaces 30 of the containers 4a, 4b and 4c.

Analogous to the first container 4a and the second container 4b, a fire unit 12 may be provided for the third container 4c. It can be the types of fire of the fire units 12 of the containers 4a, 4b, 4c respectively differ. Thus, it is possible that the fire unit 12 of the third container 4c is designed to generate water vapor. In this case, gas can be burned in a water bath, which then generates water vapor at the outlet of the combustion products.

From Figure 2, the modular design of the container 4 and 4a, 4b can be seen. The containers 4a, 4b have at least substantially the same dimensions. Thus, it is possible that the containers 4a, 4b can be mechanically coupled to each other. With a coupling of the containers 4a, 4b each border an outer side 8 of a container 4a and an outer side 8 of the other container 4b to each other. On which outer sides 8, the corresponding coupling is executed, can be adapted in practice to the desired fire simulation. Thus, it is possible, for example, that fire simulations are first carried out by arranging a plurality of containers 4 in an L-shape. If, after the exercise, the spatial relationships are known, a rearrangement of the arrangement of the containers 4 can be carried out so that the containers 4 or 4a, 4b are arranged, for example, in a T-shape or in a Z-shape relative to each other.

In order to control the fire training system 2, a fire control unit 14 is provided. The fire control unit 14 is used to control the fire training system 2. In particular, the fire control unit 14 is used to control the fire units 12 of the container 4. It is envisaged that a common fire control unit 14 is provided for several containers 4. This can then control mass flows, valves and / or other mechanical elements. Thus, for example, provided for the gas combustion unit as a fire unit 12 for the first container 4a, that the fire control unit 14 controls valves with which a gas flow to said fire unit 12 of the first container 4a is controllable. Similarly, controllable elements of the other control units 12 of the second container 4b and the third container 4c may be controlled. By the central arrangement of the fire control unit 14 centrally different fire simulations for the entire fire training system 2 can be controlled. In this case, staggered fires can be controlled by the majority of the fire units 12 and / or the respective intensity. In addition, provision may be made for the fires to be monitored by means of the fire control unit 14. For this purpose, sensors may be provided in or on the containers 4a, 4b, 4c in order to monitor the respective fires in the containers 4a, 4b, 4c. The sensors may be, for example, temperature sensors. FIG. 3 shows a container 4 in a schematic representation, from which the interior 30 can be seen. In the interior 30 of the container 4, the fire unit 12 is arranged. This is, for example, a solid combustion unit. With this large amounts of flue gas can be caused. In order to prevent the large amount of flue gas spreading unhindered in the entire interior 30 of the container 4 or even through a passage 10 on the interior 30 of an adjacent container 4, a retaining wall 22 may be provided. This retaining wall 22 is preferably fastened on the inside to an outer wall 24 of the container 4 by means of at least one joint 26. Thus, the retaining wall 22 extends, for example, from the ceiling of the container 4 in the direction of the bottom of the container 4. In this case, the retaining wall 22 extends only over a portion of a cross section of the container 4. Firefighters who simulated fire, for example, caused by a solid combustion unit as Fire unit 12, to control and / or delete, can see under the retaining wall 22 to locate the fire. By means of the retaining wall 22, the concentration of the flue gas in a part of the inner space 30 can be increased, so that real fire situations with a higher density of flue gas can be simulated. By means of the joint 26, however, the retaining wall 22 can also be folded against the container outer wall 24 or the ceiling of the container 4. In this case, the flue gas caused by the fire unit 12 can propagate unhindered in the interior 30 of the container 4 and / or through a passage 10 in a adjacent interior 30 flow. This is then another fire situation, which is also suitable for practice.

LIST OF REFERENCE NUMBERS

2 fire training system

4 containers

 4a first container

4b second container

4c third container

6 contact area

 8 outside

 10 passage

 12 fire unit

 14 fire control unit

18 door

 20 fire chamber

 22 retaining wall

 24 container outer wall

26 joint

 28 door

 30 interior

 32 gas supply unit

Claims

claims

1. fire training system (2) with

 - at least two containers (4),

 - at least one contact region (6) between in each case two of the containers (4), which in each case adjoin one another in the associated contact region (6) with one of their outer sides (8),

 - A passage (10) in each contact area (6) between the associated containers (4), and

 - A fire unit (12) in each container (4).

2. fire training system (2) according to the preceding claim, characterized in that the fire units (12) differ by their respective kind of fire.

3. fire training system (2) according to the preceding claim, characterized in that one of the fire units (12) is designed as a gas combustion unit.

4. fire training system (2) according to one of the preceding claims 2 to 3, characterized in that one of the fire units (12) is designed as a solid combustion unit.

5. fire training system (2) according to one of the preceding claims 2 to 4, characterized in that one of the fire units (12) is designed for generating water vapor and / or smoke.

6. fire training system (2) according to any one of the preceding claims, characterized by a fire control unit (14) which has a communication connection to the at least one of the fire units (12).

7. fire training system (2) according to any one of the preceding claims, characterized in that at least one passage (10) is associated with a door (18, 28), by means of which the associated passage (10) can be opened or closed, so that from the containers (4) at least two fire chambers (20) are formed.

8. fire training system (2) according to any one of the preceding claims, characterized in that at least three containers (4) are provided, wherein at least two of the containers (4) form a continuous fire chamber (20).

9. fire training system (2) according to one of the preceding claims, characterized in that the containers (4) are designed in a modular manner.

10. fire training system (2) according to any one of the preceding claims, characterized by a retaining wall (22) of a container outer wall (24) inwardly into the associated interior space (30) of the container (4) protrudes.

11. fire training system (2) according to the preceding claim, characterized in that the retaining wall (22) with a hinge (26) on the container outer wall (24) is fixed, wherein the retaining wall (22) between a first state in which the Retaining wall (22) of the container outer wall (24) away, in a second state in which the retaining wall (22) is folded up against the container outer wall (24) is movable.