GB2623135A - Fire simulation control system - Google Patents

Abstract

A fire simulation control system (1) for use in fire training having a frame (2) with a plurality of distribution ports (6, 8) for allowing the passage of gas, the distribution ports being one or more inlets (6) for connecting to a gas supply (2) and two or more outlets (8) for connection to one or more replicate devices (10) used to simulate a real fire scenario. The system (1) includes a control means (14), pressure detection means (18), pressure indication means (17) for indicating the pressure level at each distribution port (6, 8) and regulation means (22) to aid the prevention of overpressure in the system (1). Therefore the fire simulation control system (1) enables necessary control over gas flow and helps to determine whether there is a failure somewhere in the system (1) to prevent the occurrence of a serious accident.

Description

Fire Simulation Control System The present invention relates to fire training systems. In particular, the present invention relates to a fire simulation rig comprising a control and safety system.

Fire simulation rigs are used to provide fire safety training which involves providing a controlled flame to a range of purpose-built products that replicate equipment/test devices used on a daily basis in commercial and domestic settings. The controlled flame is typically provided using a supply of gas (usually LPG contained in a gas cylinder) and ignition means such as a blow torch. The gas supply is typically remote from the replicate equipment and therefore remote from the flames. The size and duration of the flames can be controlled by an operator using a valve to increase or decrease the amount of gas being supplied to the replicate equipment. The more gas supplied, the bigger the flame. Trainees are required to select and utilise an appropriate extinguishing means to extinguish the flames while the operator observes the technique of the trainee as they extinguish the flames. If the operator is satisfied with the trainee's technique, they gradually reduce the gas supply until the flame has been fully removed.

In many countries, fire safety training is a legal requirement in the workplace. However, most workplaces do not have the means or personnel to provide in-house training and therefore employ the services of a qualified fire safety instructor to visit the workplace and provide on-site fire training using a fire simulation rig. Due to the requirement of being compact and transportable, there is lack of control and regulation mechanisms provided on these rigs. In addition, the frequent transportation of these units often results in the rigs and associated equipment becoming neglected and faulty and the current rigs and equipment used do not provide the necessary means to carry out appropriate quality checks on these systems. The result is that any gas overpressure or gas leak in the system may go undetected. A gas leak left undetected can result in asphyxiation or, especially during fire training, may become ignited causing a fire or an explosion. Therefore, there is a need to provide a fire simulation rig having appropriate control and regulation mechanisms.

It is a therefore an object of the present invention to provide a fire simulation rig operable to prevent gas leaks or gas over pressure.

It is a further object of the present invention to provide a fire simulation rig to enable increased control and regulation of gas delivery during fire safety training.

It is a further object of the present invention to provide a fire simulation rig having means to enable appropriate quality checks.

Further aspects of the present invention will become apparent from the ensuing

description which is given by way of example only.

According to the invention, there is provided a fire simulation control system comprising a frame, the frame comprising two or more distribution ports for allowing the passage of fluid, the two or more distribution ports being one or more inlets configurable to connect to a fluid supply and one or more outlets.

Advantageously, one or more replicate devices can be provided with a fluid supply necessary to create flames during fire safety training. By replicate devices, we mean purpose-built items designed to replicate equipment used on a daily basis in commercial or domestic settings such as replicate computer screens, replicate waste paper bins, replicate oil spill trays etc. Replicate devices may also be known as test devices.

Preferably, the one or more outlets are connectable to a fluid delivery means.

Ideally, the one or more outlets are connectable to one or more replicate devices. Preferably, the fire simulation control system comprises a fluid flow path for guiding fluid flow.

Preferably, the fluid is a flammable fluid.

Ideally, the fluid is a combustible gas.

Preferably, the fluid is a liquid petroleum gas (LPG).

Preferably, the fluid is propane.

Ideally, in use, the fluid flow path extends between the fluid supply and the fluid delivery means connected to the one or more outlets or between the fluid supply and one or more replicate devices.

Preferably, the frame comprises a fluid flow path for guiding fluid flow.

Ideally, the fluid flow path of the frame extends from the one or more inlets connectable to a fluid supply to the one or more outlets connectable to a fluid delivery means.

Preferably, the fire simulation control system comprises a plurality of inlets.

Ideally, the frame comprises a plurality of inlets.

Preferably, the fire simulation control system comprises a plurality of outlets.

Ideally, the frame comprises a plurality of outlets.

Preferably, the fire simulation control system is operable by an operator to completely shut down the system upon any indication of a fault thereby enhancing the safety of the system.

By completely shut down, we mean to stop the flow of fluid through all parts of the system and/or fluid flow path.

Preferably, the fire simulation control system comprises a control means for controlling fluid flow at one or more locations along the fluid flow path.

Preferably, the control means is configurable to control fluid pressure at one or more locations along the fluid flow path.

Ideally, the control means is configurable to control the fluid pressure at each distribution port.

Preferably, the control means is configurable to control fluid pressure at the distribution ports separately or collectively.

Ideally, the control means is configurable to control the flow of fluid through the fluid flow path.

Ideally, the control means is configurable to control the flow of fluid through each distribution port.

Preferably, the control means is configurable to control the flow of fluid through the distribution ports separately or collectively.

Preferably, the control means comprises two or more valves.

Ideally, the control means comprises a plurality of valves.

Preferably, the valves being configurable to control the flow and/or pressure of fluid at each distribution port.

Ideally, the number of valves corresponding to the number of distribution ports such that there is a valve at each distribution port for controlling the flow and/or pressure of fluid at each distribution port.

Preferably, the control means comprises a valve located at each distribution port to control the flow and/or pressure of fluid at each distribution port.

Preferably, the control means comprises an inlet valve at each inlet to control the flow and/or pressure of fluid through each inlet.

Preferably, the control means comprises an outlet valve at each outlet for controlling the flow and/or pressure of fluid through each outlet.

Preferably, each valve is configurable to move from a first configuration, wherein fluid flow is blocked, towards a second configuration, wherein fluid flow is permitted, and vice versa.

Ideally, each valve is capable of being in a configuration between the first configuration and the second configuration, wherein partial fluid flow is permitted.

Preferably, fluid pressure at each distribution port will be in direct correlation with fluid flow. Ideally, as fluid flow through a distribution port increases so does the pressure at that distribution port. Ideally, as fluid flow through a distribution port decreases so does the pressure at that distribution port.

Advantageously, the control means thereby enables an operator to control the pressure of the fluid at each distribution port.

Preferably, each valve is configurable to enable increased fluid flow as it is moved from the first configuration towards the second configuration.

Ideally, each valve is configurable to enable increased fluid pressure as it is moved from the first configuration towards the second configuration.

Preferably, each valve is configurable to enable decreased fluid flow as it is moved from the second configuration towards the first configuration.

Ideally, each valve is configurable to enable decreased fluid pressure as it is moved from the second configuration towards the first configuration.

Advantageously, this enables gradual increase or decrease in fluid pressure.

Ideally, in the first configuration the valve is closed.

Ideally, in the second configuration, the valve is in a fully opened position.

Preferably, when the valve is between the first configuration and second configuration, the valve is partially opened.

Preferably, the control means comprises actuation means associated with each valve to enable movement of each valve towards, away from and between the first configuration and the second configuration. Advantageously, this enables operation of each valve to open, partially open or close, as required. Further advantageously, this allows an operator to enable full flow, no flow or partial flow of fluid through a distribution port.

Alternatively, or additionally, the control means comprises actuation means associated with two or more of the valves to enable simultaneous actuation of two or more valves.

Preferably, the control means is manually operated.

Preferably, the fire simulation control system comprises pressure detection means for detecting fluid pressure at one or more locations of the fire simulation control system and/or at one or more locations along the fluid flow pathway.

Preferably, the pressure detection means is configurable to detect fluid pressure at one or more of the distribution ports.

Ideally, the pressure detection means is configurable to detect the pressure at each of the plurality of the distribution ports.

Ideally, the pressure detection means is configurable to detect fluid pressure at each distribution port.

Ideally, the pressure detection means comprises an inlet pressure detection means associated with each inlet.

Ideally, the pressure detection means comprises an outlet pressure detection means associated with each outlet.

Preferably, the pressure detection means comprises pressure indication means associated with the one or more distribution ports for indicating the pressure level at the one or more distribution ports to the operator.

Preferably, the pressure detection means comprises a pressure indication means associated with each distribution port for indicating the pressure level at each distribution port.

Advantageously, this provides fluid pressure feedback to the operator. Thereby, this enables better or more accurate control being used throughout the system. Further advantageously, this prevents fluid overpressure or under pressure from the fluid supply or within the fire simulation control system going undetected. This is comparison to systems without pressure indicators whereby the operator is unaware of the pressure throughout the system and/or being delivered downstream.

Preferably, the pressure detection means comprises a plurality of pressure indication means.

Ideally, each of the plurality of pressure indication means is associated with a single distribution port to enable indication of the pressure level at each distribution port.

Additionally, or alternatively, a single pressure indication means is associated with each distribution port and is configurable to enable indication of pressure at each distribution port.

Preferably, the pressure indication means is configurable to provide a visual indication of the relative pressure.

Ideally, the pressure indication means comprises a dial.

Preferably, the pressure detection means comprises one or more pressure gauges associated with one or more of the distribution ports.

Ideally, the pressure detection means comprises a plurality of pressure gauges, each pressure gauge being associated with a distribution port.

Preferably, the number of pressure gauges corresponds to the number of distribution ports Preferably, the pressure detection means comprises a pressure gauge associated with each distribution port.

Preferably, the pressure detection means is located on or is formed as part of the frame. Ideally, the pressure indication means is located on or is formed as part of the frame.

Preferably, the fire simulation control system comprises regulation means configurable to regulate, reduce and/or fix fluid flow and/or pressure at one or more locations on the fire simulation control system and/or along fluid flow path.

Ideally, the regulation means is configurable to regulate, reduce and/or fix the pressure of fluid as it is passing between the one or more inlets and the one or more outlets, in use.

Advantageously, the regulation means enables better control over fluid flow and/or pressure within the system. Thereby, the regulation means prevents the occurrence of fluid overpressure or under pressure within the fire simulation control system.

Preferably, in use, the regulation means is configurable to regulate, reduce and/or fix the pressure of fluid receivable from a fluid supply to an optimal pressure for use in the fire simulation control system.

Preferably, the regulation means is configurable to reduce fluid pressure from high pressure to an optimal pressure. Advantageously, this enables use of the a safe and workable pressure level.

Ideally, the regulation means is configurable to reduce fluid pressure from high pressure to medium pressure.

Preferably, the regulation means is configurable to maintain optimum fluid pressure within the fire simulation control system and/or being supplied to the fire simulation control system.

Preferably, the regulation means comprises a regulator configurable to regulate, reduce and/or fix fluid pressure at one or more locations along the fluid flow path.

Ideally, the regulator is configurable to regulate, reduce and/or fix the pressure of fluid receivable from a fluid supply to an optimal pressure for use in the fire simulation control system.

Ideally, the regulator is configurable to reduce fluid pressure from high pressure to medium pressure.

Preferably, the regulation means comprises a high-pressure regulator having a fixed outlet pressure.

Preferably, the fixed outlet pressure is between 0.5-1.5 bar.

Ideally, the fixed outlet pressure is between 0.5-1 bar.

Ideally, the fixed outlet pressure is approximately 0.75 bar.

Preferably, the regulation means comprises one or more shut off valves configurable to shut off fluid flow at one or more locations along the fluid flow-path when fluid pressure is at a pre-determined level.

By at a pre-determined level, we mean when fluid pressure reaches, exceeds, fails to reach or drops below a pre-determined value.

Ideally, the regulation means comprises an overpressure shut off valve configurable to stop the flow of fluid when the pressure reaches or exceeds a predetermined pressure value.

Preferably, the overpressure shut off valve is configurable to stop the flow of fluid when pressure reaches or exceeds 1.5 bar, in use.

Ideally, the regulation means comprises an under pressure shut off valve configurable to stop the flow of fluid when the pressure fails to reach or drops to or below a pre-determined pressure value.

Advantageously, the regulation means enables automatic shut off of fluid flow upon overpressure or under pressure detection. Thereby, the regulation means increases the reliability and safety of the fire simulation control system and prevents use of the fire simulation control system when conditions are unsafe. This is in comparison to fire simulation control systems without a shut off valve wherein the system would continue to operate in a sub-optimal or dangerous condition.

Preferably, the regulation means is provided at a location that is upstream in the fluid flow path to enable regulation of fluid flow and/or pressure at an early stage and/or to enable detection of overpressure or under pressure at an early stage.

Ideally, the regulation means is located between the one or more inlets and the one or more outlets.

Alternatively, in use, the regulation means is located between the fluid supply and the at least one inlet connected to the fluid supply.

Ideally, the regulation means is located along the pipe between the hose connected to the fluid supply and the at least one inlet.

Preferably, the regulation means is located on or is formed as part of the frame. Preferably, the fire simulation control system comprises a leak detection means configured to detect a fluid leak at one or more points along the fluid flow path.

Preferably, the leak detection means comprises indication means for indicating when a leak is detected.

Advantageously, this enables an operator to determine if fluid is being released unintentionally into the surrounding environment.

Preferably, the fire simulation means comprises a level detector configurable to connect to the fluid supply and detect fluid levels within the supply.

Preferably, the level detector comprises indication means to indicate fluid levels within the fluid supply to the operator.

Advantageously, the level detector means enables an operator to determine fluid levels in the fluid supply during or prior to beginning the fire safety training. Thereby, this enables appropriate planning for the fluid safety training such that mechanisms can be put in place to allow safe refilling or changing of the fluid supply, if required.

Preferably, the fire simulation means comprises a temperature sensor to detect whether temperatures internal to the fluid supply or surrounding the fluid supply are at an optimum or safe level.

Advantageously, this prevents use of the system in unsafe environments where there is an increased risk of accidents occurring.

Preferably, the leak detector and/or level detector comprise a temperature sensor configurable to detect the presence of a leak or to detect fluid levels, respectively.

Ideally, the leak detector, level detector and/or temperature sensor are connectable to the fluid supply.

Advantageously, this prevents use of an unsafe fluid supply. Further advantageously, this enables detection of leaks, low fluid levels and poor environmental conditions at an early stage.

Preferably, the fire simulation control system comprises a combined leak detector, level detector and/or temperature sensor.

Advantageously, this increases the compactness of the system. Further advantageously, this increases the ease of transportation of the system. This is in comparison to bulky systems that are difficult to transport.

Ideally, the combined leak detector, level detector and/or temperature sensor is connectable to the fluid supply.

Preferably, the fire simulator system comprises a fluid delivery means configurable to conned to an inlet and/or outlet and to deliver fluid throughout the fluid flow path.

Preferably, the fluid delivery means comprises one or more conduits.

Preferably, the frame comprises one or more conduits.

Preferably, the fluid delivery means comprises one or more hoses.

Preferably, the one or more hoses are configurable to withstand high pressure levels. Most preferably, the one or more hoses are configurable to withstand high pressure levels of fluid.

Ideally, the one or more hoses are configurable to withstand the highest level of pressure that the fluid supply can produce.

Advantageously, this means that the hoses will not split due to high pressure levels. Ideally, the one or more hoses are configurable to withstand 20 bar pressure. Preferably, the one or more hoses are configurable to enable fluid delivery of LPG in gas and/or liquid form.

Preferably, the one or more hoses are configurable to maintain their structure during overpressure or under pressure conditions.

Preferably, the one or more hoses comprise a smooth outer layer.

Preferably the one or more hoses are formed from rubber.

Preferably, the outer layer of the one or more hoses is formed from rubber.

Advantageously, this enables easy identification of damage, rips and/or tears on in the one or more hoses. This is in comparison to braided hoses or hoses covered in an external sheath of material having uneven and rough surfaces such that it is difficult to see if the hose has been damaged.

Preferably, the fluid delivery means comprises one or more pipes.

Preferably, the frame comprises one or more pipes.

Preferably, the one or more pipes are formed from a non-combustible material.

Advantageously, the material will not ignite.

Preferably, the one or more pipes are formed from stainless steel.

Preferably, the one or more pipes are formed as part of the frame.

Preferably, the fluid delivery system comprises one or more chambers. Preferably, the frame comprises one or more chambers.

Preferably, the fluid delivery system comprises one or more manifolds. Ideally, the one or more manifolds are located on the frame.

Preferably, the frame comprises one or more manifolds.

Preferably, the one or more manifolds connect the one or more inlets to the one or more outlets. Most preferably, the one or more manifolds connect an inlet to two or more outlets.

Preferably, the one or more manifolds comprise a chamber.

Ideally, one or more of the distribution ports are in fluid communication with the chamber of the one or more manifolds.

Preferably, in use, fluid can flow into the chamber from one or more distribution ports and out of the chamber via one or more other distribution ports.

Advantageously, this enables fluid flowing from one distribution port to be distributed to two or more distribution ports, as required, without the need for complex piping and pathways.

Preferably, the chamber connects the one or more inlets to the one or more outlets. Most preferably, the chamber connects an inlet to two or more outlets.

Preferably, the fire simulation control system comprises ignition means configurable to ignite fluid being delivered to one or more replicate devices.

Preferably, the ignition means is configurable to generate a spark.

Preferably, the ignition means is configurable to generate a flame.

Preferably, the ignition means is connectable to the one or more outlets to receive a supply of fluid.

Preferably, the ignition means is configurable to receive fluid from the fluid supply via an additional outlet of the fire simulation control system and/or fluid delivery means.

Ideally, the additional outlet may or may not comprise pressure detection means. Ideally, the additional outlet comprises control means to enable control of fluid flow through the additional outlet.

Preferably, the control means is a valve.

Preferably, the ignition means is configurable to be stored on the frame.

Preferably, the ignition means is a hand-held ignition means. Preferably, the ignition means comprises a handle.

Preferably, the ignition means comprises a torch head. Ideally, the torch head being configurable to produce a flame Preferably, the ignition means comprises actuation means configurable to actuate spark and/or flame production.

Ideally, the actuation means is locatable on or near the handle.

Advantageously, this enables one handed use of the ignition means.

Preferably, the ignition means comprises an elongate shaft extending between the handle and the torch head.

Advantageously, this enables the operator to maintain a safe distance from the torch head Preferably, the ignition means comprises a trigger torch.

Preferably, the frame comprises a base.

Preferably, the frame comprises one or more support elements for supporting the base off the ground.

Preferably, the one or more support elements comprise one or more legs.

Preferably, the frame comprises one or more wheels for enabling movement of the frame.

Preferably, the one or more support elements comprises one or more wheels.

Ideally, the frame comprises two or more wheels.

Advantageously, the one or more wheels enable easy manoeuvring and transportation of the frame.

Preferably, the frame comprises a handle for manoeuvring the frame.

Preferably, all or most of the frame is a one-piece unit.

Advantageously, this reduces the risk of one or more parts of the frame getting misplaced or stolen.

Alternatively, the frame is modular.

Preferably, the frame comprises a fluid supply support means for supporting the fluid supply thereon.

Preferably, the fluid supply support means is configurable to support the fluid supply off the ground.

Advantageously, this prevents damage to the fluid supply container. Further advantageously, this prevents the fluid supply container being exposed to ground temperatures and/or wet conditions.

Preferably, the fluid support means is located on the base of the frame. Advantageously, this enables easy transfer of the fluid supply container onto the frame. Preferably, the fluid supply support means comprises a receptacle for receiving a fluid supply container therein.

Preferably, the receptacle is located on the base of the frame.

Preferably, the receptacle is shaped and sized to correspond to a fluid supply container. Ideally, the fluid supply is a propane gas cylinder.

Preferably, the frame comprises an ignition means support for supporting the ignition means off the ground when it is not in use.

Ideally, the frame comprises a receptacle for receiving the torch head of the ignition means.

Preferably, the receptacle is shaped and sized to correspond to the torch head.

Preferably, the torch head receptacle is located on the base of the frame. Advantageously, this means that the handle of the ignition means is approximately at hand height. Therefore, this means that the operator does not need to bend down to pick up or store the ignition means.

Alternatively, the ignition means may be stored on or attached to the frame in any other suitable manner.

Preferably, the frame comprises a control panel.

Preferably, the control means is located on the control panel.

Preferably, all or some of the one or more pressure detection means and/or pressure indication means are located on the control panel.

Preferably, the frame comprises a hood configurable to protect the control panel from dust, rain and/or direct sun.

Advantageously, this prevents the control panel from becoming damaged.

Preferably, the frame comprises a body portion located between the base and the control panel of the frame.

Preferably, the body portion is an elongate body portion that extends between the base and the control panel.

Preferably, the body portion comprises one or more frame members extending between the base and the control panel.

Preferably, the one or more frame members extend vertically or substantially vertically between the base and the control panel.

Ideally, the frame comprises one or more cross members extending between two or 10 more frame members.

Preferably, the frame comprises a back board.

Preferably, the back board extends across one or more frame members and/or between two or more frame members.

Preferably, the back board extends all or most of the length between the base and the control panel.

Advantageously, this provides a barrier between the open flames in the replicate devices and the fluid supply container. Further advantageously, this provides a surface for branding and/or marketing materials.

Preferably, the frame comprises one or more openings to provide a path for a fluid delivery means.

Ideally, the one or more openings are located on the back board of the frame. Preferably, the one or more openings comprise abutment means to prevent tearing or friction on a fluid delivery means.

Ideally, the abutment means comprises a rubber cover around the perimeter of the one or more openings.

Preferably, the fire simulation means comprises connection means for enabling connection between one or more distribution ports and a fluid delivery means.

Preferably, the one or more connection means comprises quick coupling means. Ideally, the one or more connection means comprise quick release means for enabling quick disconnection.

Preferably, the one or more connection means are suitable for single hand use. Preferably, the one or more connection means are configurable for coupling and release using one hand.

Advantageously, this enables the easy of coupling and release. This is in comparison to connection means requiring the use of two hands and complicated coupling. For example, this is in relation to couplings having an external sleeve that must be moved to enable coupling and/or release.

Preferably, the quick coupling means comprises a plug and socket connection members and/or male/female connection members.

Preferably, the quick coupling means comprises a button locking system.

Advantageously, this obviates the need for external sleeves as can be seen in other couplings of the prior art. Further advantageously, this enables the coupling components to be checked for dirt or debris. Further advantageously, this enables the operator to see the connection between coupling components. This is in comparison to couplings comprising an external sleeve which cover the joint between the coupling components, in use.

Preferably, the quick release means comprises a push button configurable to cause disconnection upon actuation.

Preferably, the fire simulation control system comprises tamper resistant means for preventing or detecting tampering on one or more parts of the fire simulation control system.

Advantageously, this prevents the use and sale of unsafe equipment.

Preferably, the tamper resistant means comprises one or more layers of shrink-wrapped material at one or both ends of the hoses of the fluid delivery means. Ideally, in the event of tampering, the one or more layers will be ripped or damaged.

Preferably, one or more parts of the fire simulation control system comprise identification means to enable traceability of that part.

Advantageously, this prevents the use and sale of unsafe replicas. Further advantageously, this enables determination of part origin which in-turn encourages better manufacture and transport of parts.

Preferably, at least one inlet is connectable to the fluid supply via a fluid delivery means.

Ideally, the inlet is connectable to the fluid supply via a pipe and/or a hose connectable to the fluid supply.

Preferably, the at least one inlet is located on the frame of the fire simulation control system.

Preferably, the at least one inlet connectable to the fluid supply is connected to the one or more outlets via a fluid delivery means.

Preferably, the one or more outlets are located on the frame.

Ideally, the at least one inlet is connected to the one or more outlets via the one or more manifolds.

Preferably, at least one outlet is connected to one or more replicate devices via a fluid delivery means.

Ideally, the at least one outlet is connected to the one or more replicate devices via one or more hoses and/or one or more pipes.

Preferably, the ignition means is connectable to at least one outlet to receive a fluid supply therefrom for generating a flame.

Preferably, the fire simulation control system comprises one or more replicate devices configurable to receive fluid supply from the fluid delivery means.

Preferably, the one or more replicate devices are formed from a non-combustible material.

Ideally, the one or more replicate devices are shaped and sized to correspond to equipment used on a daily basis in commercial and domestic settings.

Advantageously, this enables the creation of realistic scenarios for fire training. Preferably, the one or more replicate devices comprise one or more distribution ports connectable to the one or more outlets of the frame to receive fluid supply therefrom.

Ideally, the one or more replicate devices comprise one or more inlets connectable to the one or more outlets of the frame to receive fluid supply therefrom.

Preferably, the fire simulation control system comprises one or more storage means suitable to protect one or more component parts of the fire simulation control system when being stored and/or transported.

Advantageously, this protects the one or more components parts when being stored and/or transported.

Preferably, the one or more storage means is shaped and sized to correspond to the one or more component parts to be stored.

Advantageously, shaping the one or more storage means to correspond to the one or more component parts enables easy identification of the parts when they are being stored and transported. Further advantageously, this prevents the one or more components parts from being stored and/or transported incorrectly or in a poor condition.

Preferably, the frame comprises an ancillary support means extending laterally from the control panel of the frame.

Ideally, the ancillary support means is configurable to support all or a portion of the one or more hoses or any other items.

Advantageously, this enables a tidier work environment. This is in comparison to frames without ancillary support means.

The invention will be more clearly understood from the following description of some embodiments thereof, given by way of example only, with reference to the accompanying drawings, in which: Figure 1 is a front view of the frame of the fire simulation control system according to the present invention.

Figure 2 is a side view of the frame of the fire simulation control system according to the present invention.

Figure 3 is a top view of the frame of the fire simulation control system according to the present invention Figure 4 is a bottom view of the frame of the fire simulation control system according to the present invention.

Figure 5 is a perspective view of the manifold of the fire simulation control system according to the present invention.

Figure 6 is a perspective view of the fire simulation control system according to the present invention.

Figure 7 is a second perspective view of the fire simulation control system according to the present invention.

Figure 8 is a perspective view of a portion of the fire simulation control system, in use.

Figure 9 is a perspective view of a fire simulation control system including one or more replicate devices.

Figure 10 illustrates the fluid flow path of the fire simulation control system according to the present invention, in use.

Referring to the drawings, there is shown a fire simulation control system, indicated generally by reference numeral 1. The fire simulation control system having a frame 2 and the frame 2 having distribution ports 6, 8 for allowing the passage of fluid. In the drawings provided, the frame has four distribution ports 6, 8. The distribution ports being an inlet 6 configured to connect to a fluid supply 20 and three outlets 8 (8a, 8b, Sc). However, there may be more or less distribution ports, inlets and/or outlets. One or more replicate devices 10 can be provided with a fluid supply necessary to create flames during fire safety training. By replicate devices, we mean purpose-built items designed to replicate equipment used on a daily basis in commercial or domestic settings such as replicate computer screens, replicate waste paper bins, replicate oil spill trays etc. The outlets 8 are connectable to a fluid delivery arrangement 12. The outlets 8 are connectable to one or more replicate devices 10. The fire simulation control system 1 has a fluid flow path 3 for guiding fluid flow. The fluid a liquid petroleum gas (LPG) such as propane.

In use, the fluid flow path extends between the fluid supply 20 and the fluid delivery arrangement 12 connected to the outlets 8 or between the fluid supply 20 and one or more replicate devices 10. The frame 2, has a fluid flow path 7 which forms part of fluid flow path 3. The fire simulation control system 1 has a control arrangement 14 for controlling fluid flow at one or more locations along the fluid flow path. The control arrangement 14 is configured to control fluid pressure at one or more locations along the fluid flow path. The control arrangement 14 is configured to control the fluid pressure at each distribution port 6, 8. The control arrangement 14 is configured to control fluid pressure at the distribution ports 6, 8 separately or collectively. The control arrangement 14 is configured to control the flow of fluid through the fluid flow path. The control arrangement 14 is configured to control the flow of fluid through each distribution port 8, 6. The control arrangement 14 is configured such that the flow of fluid through each of the distribution ports 6, 8 can be controlled independent of the other distribution ports 6, 8. The control arrangement 14 has a plurality of valves 15, the valves being configured to control the pressure of fluid at each distribution port 6, 8. The number of valves corresponds to the number of distribution ports 6, 8 such that there is a valve at each distribution port 6, 8 for controlling the flow and/or pressure of fluid at each distribution port 6, S. Therefore, the control arrangement 14 has an inlet valve 15a at inlet 6 to control the flow and/or pressure of fluid through inlet 6 and an outlet valve 15b at each outlet 8a, 8b, Sc for controlling the flow and/or pressure of fluid through each outlet 8a, 8b, Sc. Each valve is configured to move from a first configuration, wherein fluid flow is blocked, towards a second configuration, wherein fluid flow is permitted, and vice versa. Each valve is also capable of being in a configuration between the first configuration and the second configuration, wherein partial fluid flow is permitted. Fluid pressure at each distribution port 6, 8 is in direct correlation with fluid flow such that as fluid flow through a distribution port 6, 8 increases so does the pressure at that distribution port, and, as fluid flow through a distribution port 6, 8 decreases so does the pressure at that distribution port 6, 8. The control arrangement 14 thereby enables an operator to control the pressure of the fluid at each distribution port 6, 8. Each valve is configured to enable increased fluid flow and pressure as it is moved from the first configuration towards the second configuration and each valve is configured to enable decreased fluid flow and pressure as it is moved from the second configuration towards the first configuration. This enables gradual increase or decrease in fluid pressure.

The control arrangement 14 has an actuation arrangement 16 associated with each valve to enable movement of each valve towards, away from and between the first configuration and the second configuration. This enables operation of each valve to open, partially open or close, as required. Further, this allows an operator to enable full flow, no flow or partial flow of fluid through a distribution port 6, 8. The actuation arrangement 16 has a handle which can be moved from a first configuration towards a second configuration to enable manual control of the valve from a first configuration towards a second configuration.

The fire simulation control system 1 has a pressure detection arrangement 18 for detecting fluid pressure at one or more locations along the fluid flow pathway. The pressure detection arrangement 18 is configured to detect fluid pressure at each of the distribution ports 6, 8. The pressure detection arrangement 18 has an inlet pressure detection arrangement 18a associated with the inlet 6 and outlet pressure detection arrangements 18b, 18c, 18d associated with each outlet 8a, 8b, 8c. The pressure detection arrangement 18 has a pressure indication arrangement 17 associated with each of the distribution ports 6, 8 for indicating the pressure level at each of the distribution ports 6, 8. This provides fluid pressure feedback to the operator and enables better or more accurate control of pressure being used throughout the system. Further, this prevents fluid overpressure or under pressure from the fluid supply 20 or within the fire simulation control system 1 going undetected. This is comparison to systems without pressure indicators whereby the operator is unaware of the pressure throughout the system and/or being delivered downstream. The pressure detection arrangement 18 provided in the drawings has a pressure gauge associated with each of the distribution ports, the pressure gauges having a dial to indicate the pressure level. An example of such pressure gauge includes RS PRO Bourdon Tube Pressure gauge having a liquid filling.

The fire simulation control system 1 has a regulation arrangement 22 configured to regulate, reduce and/or fix fluid flow and/or pressure at one or more locations along the fluid flow path. The regulation arrangement 22 is configured to regulate, reduce and/or fix the pressure of fluid as it is passing between the inlet 6 and the outlets 8a, 8b, 8c, in use. The regulation arrangement 22 enables better control over fluid flow and/or pressure within the system 1. Thereby, the regulation arrangement 22 prevents the occurrence of fluid overpressure or under pressure within the fire simulation control system 1. In use, the regulation arrangement 22 is configured to regulate, reduce and/or fix the pressure of fluid receivable from a fluid supply 20 to an optimal pressure for use in the fire simulation control system 1. In particular, the regulation arrangement is configured to reduce fluid pressure from high pressure level to a medium pressure level. The regulation arrangement has a regulator 22b for regulating, reducing and/or fixing the pressure of fluid. An example of a regulation arrangement 22 is the Clesse APZ400 1st Stage 40kg/hr Propane High Pressure Regulator. The regulation arrangement 22 has an overpressure shut off valve 22a configured to stop the flow of fluid when the pressure reaches or exceeds a predetermined pressure value. The regulation arrangement 22 enables automatic shut off of fluid flow upon overpressure detection. Thereby, the regulation arrangement 22 increases the reliability and safety of the fire simulation control system 1 and prevents use of the fire simulation control system 1 when conditions are unsafe. This is in comparison to fire simulation control systems 1 without a shut off valve wherein the system would continue to operate in a sub-optimal or dangerous condition. Regulators such as the Clesse APZ400 1st Stage 40kg/hr Propane High Pressure Regulator may come with an OPSO (overpressure shut off valve). The regulation arrangement 22 is provided at a location that is upstream in the fluid flow path to enable regulation of fluid flow and/or pressure at an early stage and/or to enable detection of overpressure or under pressure at an early stage. In use, the regulation arrangement 22 is located between the fluid supply 20 and the at least one inlet 6 connected to the fluid supply 20. The regulation arrangement 22 is located along a pipe 24 between a hose 26 connected to the fluid supply and the inlet 6.

The fire simulation control system 1 has a leak detection arrangement 30 configured to detect a fluid leak at one or more points along the fluid flow path. The leak detection arrangement 30 has leak indication arrangement 31 for indicating when a leak is detected. The leak indication arrangement 31 provides visual indication. In particular, the leak indication arrangement 31 will display a colour to indicate the presence of a leak, for example the leak indication arrangement will display a red colour to indicate that there is a problem with using the supply 20 to which it is connected, in use. The leak indication arrangement 31 will display a second colour to indicate the absence of a leak or to indicate that the supply 20 is safe for use. For example, the second colour may be green. This enables an operator to determine if fluid is being released unintentionally into the surrounding environment. An example of an appropriate leak detection arrangement is the Gaslow Adaptor Gauge -Propane. The fire simulation control system 1 has a level detector configured to connect to the fluid supply and detect fluid levels within the supply 20. The level detector has indication means to indicate fluid levels within the fluid supply 20 to the operator. The level detector arrangement enables an operator to determine fluid levels in the fluid supply 20 during or prior to beginning the fire safety training. Thereby, this enables appropriate planning for the fluid safety training such that mechanisms can be put in place to allow safe refilling or changing of the fluid supply 20, if required. The fire simulation control system 1 has a temperature sensor to detect whether temperatures internal to the fluid supply 20 or surrounding the fluid supply 20 are at an optimum or safe level. This prevents use of the system 1 in unsafe environments where there is an increased risk of accidents occurring. The leak detector 30 and/or level detector have a temperature sensor configured to detect the presence of a leak or to detect fluid levels, respectively. The leak detector 30, level detector and/or temperature sensor are connectable to the fluid supply 20. This prevents use of an unsafe fluid supply. Further, this enables detection of leaks, low fluid levels and poor environmental conditions at an early stage. The fire simulation control system 1 has a combined leak detector, level detector and/or temperature sensor 30. This increases the compactness of the system. Further, this increases the ease of transportation of the system 1. This is in comparison to bulky systems that are difficult to transport.

The fire simulator system 1 has a fluid delivery arrangement 12 configured to connect to the inlet 6 and/or one or more of the outlets 8a, 8b, 8c and to deliver fluid throughout the fluid flow path. The fluid delivery arrangement 12 has one or more hoses 12, the one or more hoses 12a being configured to withstand the highest level of pressure that the fluid supply 20 can produce. This means that the hoses 12a will not split due to high pressure levels. The one or more hoses 12a are also configured to maintain their structure during overpressure or under pressure conditions. The one or more hoses 12 have a smooth outer layer and are formed from rubber. This enables easy identification of damage, rips and/or tears on the one or more hoses 12a. This is in comparison to braided hoses or hoses covered in an external sheath of material having uneven and rough surfaces such that it is difficult to see if the hose has been damaged. An example of a suitable hose is the RS Pro Long Rubber Hose.

The fluid delivery arrangement 12 has one or more pipes 12b located on or formed as part of the frame 2. The one or more pipes 12b are formed from a non-combustible material such as stainless steel. This means that the material will not ignite.

The fluid delivery arrangement 12 has one or more chambers located on or formed as part of the frame 2. The fluid delivery arrangement 12 has one or more manifolds 12c located on or formed as part of the frame 12. The one or more manifolds 12c connect the inlet 6 to the outlets 8a, 8b and Sc. The one or more manifolds 12c have a chamber 13. One or more of the distribution ports 6, 8 are in fluid communication with the chamber 13 of the one or more manifolds 12c. In the figures, there is shown one manifold 12c. In use, fluid can flow into the chamber 13 from one or more distribution ports 6 and out of the chamber via one or more other distribution ports 8a, 8b, 8c. This enables fluid flowing from one distribution port to be distributed to two or more distribution ports, as required, without the need for complex piping and pathways.

The fire simulation control system 1 has an ignition arrangement 32 configured to ignite fluid being delivered to one or more replicate devices 10, the ignition arrangement 32 bring configured to generate a spark for flame production. The ignition arrangement 32 is connectable to an additional outlet 9 of the fire simulation control system 1, via the fluid delivery arrangement, to receive a supply of fluid. The additional outlet 9 having a control arrangement 11 including a valve 19 to enable control of fluid flow through the additional outlet 9. The ignition arrangement 32 is configured to be stored on the frame 2. The ignition arrangement 32 is a hand-held ignition arrangement 32 having a handle 34 and a torch head 36. The torch head 36 is configured to produce a flame. The ignition arrangement 32 has actuation arrangement 40 configured to actuate a spark and/or flame production. The actuation arrangement 40 is locatable on or near the handle 34. This enables one handed use of the ignition arrangement 32. The ignition arrangement has an elongate shaft 38 extending between the handle 34 and the torch head 36. This enables the operator to maintain a safe distance from the torch head 36. The ignition arrangement 32 is a trigger torch such as the Ideal-Performance Piezo Ignition Turbo special burner.

The frame 2 has a base 40 and one or more support elements 42 for supporting the base 40 off the ground, in use. The one or more support elements 42 being one or more legs. The frame 2 also has one or more wheels 44 for enabling movement of the frame 2 for facilitating manoeuvring and transportation of the frame 2. The frame 2 has a handle 46 also for facilitating manoeuvring the frame 2. All or most of the frame 2 is a one-piece unit to reduce the risk of one or more parts of the frame 2 getting misplaced or stolen. However, the frame may be modular. The frame has a fluid supply support arrangement 48 for supporting the fluid supply 20 thereon so that the fluid supply 20 is supported off the ground. This prevents damage to the fluid supply container 20. Further, this prevents the fluid supply container 20 being exposed to ground temperatures and/or wet conditions. The fluid supply support arrangement 48 is located on the base 40 of the frame 2 to enable easy transfer of the fluid supply container 20 onto the frame 2. This is in comparison to the fluid supply support arrangement being located on a part of the frame that requires the container to be lifted higher than the base 40. The fluid supply support arrangement 48 has a receptacle 48a for receiving a fluid supply container 20 therein, the receptacle 48a being shaped and sized to correspond to a fluid supply container 20. Referring to the drawings, the fluid supply 20 illustrated is a propane gas cylinder.

The frame 2 further has an ignition arrangement support for supporting the ignition arrangement 32 off the ground when it is not in use. The frame 2 has a receptacle 50 for receiving the torch head 36 of the ignition arrangement 32, the receptacle 50 being shaped and sized to correspond to the torch head 36. The torch head receptacle 50 is located on the base 40 of the frame 2. This means that the handle 34 of the ignition arrangement 32 is approximately at hand height when the ignition arrangement 32 is being stored in the receptacle 50. Therefore, this means that the operator does not need to bend down to pick up or store the ignition arrangement 32.

The frame 2 has a control panel indicated by reference numeral 5, the control arrangement 14 being located on the control panel 5. All or some of the pressure detection arrangements and/or pressure indication arrangements 17 are located on the control panel 5. The frame also has a hood 52 for protecting the control panel 5 from dust, rain and/or direct sun. This prevents the control panel 5 from becoming damaged. The frame 2 has a body portion 54 located between the base 40 and the control panel 5 of the frame 2. The body portion 54 is an elongate body portion that extends between the base 40 and the control panel 5. The body portion 54 has one or more frame members 56 extending between the base 40 and the control panel 5. The one or more frame members 56 extend vertically or substantially vertically between the base 40 and the control panel 5 and one or more cross members 58 extending between two or more frame members 56. The frame 2 has a back board 60 which extends across one or more frame members 56 and/or between two or more frame members 56. The back board 60 extends all or most of the length between the base 40 and the control panel 5 to provide a barrier between the open flames in the replicate devices 10 and the fluid supply container 20. The backboard 60 also provides a surface for branding and/or marketing materials.

The frame 2 has one or more openings 62 to provide a path for a fluid delivery means 12, the one or more openings 62 being located on the back board 60 of the frame 2. The one or more openings 62 have an abutment arrangement 64 to prevent tearing or friction on the fluid delivery arrangement 12. The abutment arrangement 64 has a rubber cover around the perimeter of the one or more openings 62.

The fire simulation control system 1 has one or more connection arrangements 66 for enabling connection between one or more distribution ports 6, 8 and a fluid delivery arrangement 12. The one or more connection arrangements 66 having a quick coupling arrangement 68 for enabling quick connection and a quick release arrangement 70 for enabling quick disconnection. The one or more connection arrangements 66 being suitable for single hand use so that coupling and release can be performed using one hand. This increases the ease and speed of coupling and release. This is in comparison to connection arrangements requiring the use of two hands and complicated coupling. For example, this is in relation to couplings having an external sleeve that must be moved to enable coupling and/or release.

The quick coupling arrangement 68 has plug 68a and socket 68b connection members. In use, the plug 68a is located on one of the components to be joined and the socket 68b on the other as illustrated in figure 5, the plug 68a is fixed to the hose 12a and the socket 68b is fixed to the pipe 12b to enable connection between the hose 12a and pipe 12b. The quick coupling arrangement 68 has a button locking system. This obviates the need for external sleeves as can be seen in other couplings of the prior art and enables the coupling components to be checked for dirt or debris. Further, this enables the operator to see the connection between coupling components. This is in comparison to couplings comprising an external sleeve which cover the joint between the coupling components, in use. The quick release arrangement 70 has a push button 70a configured to cause disconnection upon actuation.

The fire simulation control system 1 has a tamper resistant arrangement 72 for preventing or detecting tampering on one or more parts of the fire simulation control system 1. This prevents the use and sale of unsafe equipment. The tamper resistant arrangement 72 has one or more layers of shrink-wrapped material 74 at one or both ends of the hoses 12a of the fluid delivery arrangement 12. As illustrated in figure 5, the tamper resistant arrangement 72 has at least two layers 74a, 74b of material shrink wrapped around one end of the hose 12a. In the event of tampering, the one or more layers 74a, 74b will be ripped or damaged. One or more parts of the fire simulation control system 1 have an identification arrangement to enable traceability of that part. This prevents the use and sale of unsafe replicas. Further, this enables determination of part origin which in-tum encourages better manufacture and transport of parts.

In use, at least one inlet 6 is connected to the fluid supply 20 via a fluid delivery arrangement 12 having a hose 12a and/or a pipe 12b. Referring to figures 8 and 9, the inlet 6 is connected to the fluid supply 20 via a pipe 12a and a hose 12b -the pipe extends between the inlet 6 on the manifold 12c and the hose 12a, the hose 12a is extends between the pipe 12b and the fluid supply 20.

The at least one inlet 6 is connectable to the fluid supply 20 is connected to the one or more outlets 8 via a fluid delivery arrangement 12. The one or more outlets 8 are located on the frame 2. Referring to figures 5, 6 and 8, the inlet 6 is connected to the outlets 8 via the manifolds 12c. Fluid flow passes into chamber 13 of the manifold 12c via the inlet 6 and flows out of the chamber 13 via one or more of the outlets 8a, 8b, 8c, if the valve associated with that outlet is open.

At least one outlet 8 is connected to one or more replicate devices 10 via a fluid delivery arrangement 12 having one or more hoses 12a and/or one or more pipes 12b. Referring to figure 8, is connected to oil spill tray 10a via a pipe 12b and a hose 12a. In particular, the outlet 8a is connected to a pipe 12b which extends between the outlet 8a and a hose 12a and the hose 12a extends between the pipe 12b and the oil spill tray 10a. The ignition arrangement 32 is connectable to outlet 9 to receive a fluid supply therefrom for generating a flame.

The fire simulation control system 1 has one or more replicate devices 10 configured to receive fluid supply from the fluid delivery arrangement 12. The one or more replicate devices 10 are formed from a non-combustible material and are shaped and sized to correspond to equipment used on a daily basis in commercial and domestic settings. This enables the creation of realistic scenarios for fire training. The fire simulation control system 1 has a replicate oil spill tray 10a, a replicate tv/computer screen 10b and a replicate combustion engine 10c. The one or more replicate devices having one or more distribution ports 21 for connecting to the outlets 8 to receive fluid supply therefrom. The distribution ports 21 are inlets and are connectable to the outlets 8 via the fluid delivery arrangement 12. Replicate devices may also be referred to as test devices.

The fire simulation control system 1 has one or more storage arrangements suitable to protect one or more component parts of the fire simulation control system 1 when being stored and/or transported. The one or more storage arrangements are shaped and sized to correspond to the one or more component parts to be stored. Referring to figure 10, storage arrangement 76 for storing one or more hoses 12a is shaped and sized to accommodate the hoses 12a in a wrapped configuration. Shaping the one or more storage arrangements 76 to correspond to the one or more component parts enables easy identification of the parts when they are being stored and transported. Further, this prevents the one or more components parts from being stored and/or transported incorrectly or in a poor condition.

The frame 2 has an ancillary support arrangement 55 extending laterally from the control panel 5 of the frame 2. The ancillary support arrangement 55 is configured to support all or a portion of the one or more hoses 12 or any other items. This enables a tidier work environment.

Referring to figure 11, which illustrates the fluid flow path 3 of the fire simulation control system and the fluid flow path 7 of the frame 2, in use, fluid flows from the fluid supply 20 where a leak detector 30 is connected and into fluid delivery arrangement 12 such as a hose 12c. The hose 12c may be connected to a further fluid delivery arrangement 12 forming part of the frame such as a pipe 12b via a connection arrangement 66. Alternatively, the hose 12a may be directly connected to the frame 2 or inlet 6. Prior to reaching inlet 6, the fluid by passes a regulation arrangement 22 which may reduce the pressure of the fluid and/or shut off the fluid flow in the event of overpressure. Fluid in the fluid delivery arrangement 12 flows towards an inlet valve 15a, if the valve is an open or partially open configuration, fluid is free to flow through inlet 6. If the valve is closed, fluid flow is blocked. Pressure detector 18a associated with inlet 6 reads the fluid pressure level at the inlet 6 and pressure indication arrangement 17 signals this to the operator. The operator may choose to increase or decrease fluid pressure at the inlet 6 using actuation arrangement 16 of the control arrangement 14 to change the configuration of the valve 15a to open further or close further.

Fluid flowing through the inlet 6 will flow towards outlets 8 (8a, 8b, 8c) and additional outlet 9 via the manifold 12c and will enter into the chamber 13 of the manifold 12c. If the outlet valve 15b associated with each outlet is in an open or partially open configuration, fluid will flow through the respective open outlets 8a, 8b, Sc. If the valve 15b associated with each outlet is closed then fluid will be blocked from flowing through that outlet 8a, 8b, Sc. It is possible for the outlet valve 15b of one outlet 8a to be open or partially open and the remaining valves 15b for the other outlets 8b, Sc to be closed because each outlet has its own associated valve 15b. Therefore, each outlet 8a, 8b, Sc can be operated independently of the others. Pressure detectors 18b, 18c and 18d associated with outlet 8a, 8b and Sc respectively reads the fluid pressure level at the outlets 8a, 8b and Sc and the pressure indication arrangement 17 of each pressure detector signals this to the operator. The operator may choose to increase or decrease fluid pressure any of the outlets 8a, 8b, Sc using actuation arrangement 16 associated with each of the outlets 8a, 8b, Sc to change the configuration of any of the outlet valves 15b to open further or close further. If the outlet valve 19 associated with the additional outlet 9 is open, fluid will flow through the outlet 9 to the ignition arrangement 32 via the fluid delivery arrangement 12 where the fluid can be used to generate a flame when required. The operator may choose to further open or further close valve 19 using control arrangement 11. Fluid flowing through the outlets 8a, 8b or Sc will flow towards one or more replicate devices 10 via the fluid delivery arrangement 12 and distribution ports 21 on the one or more replicate devices. Fluid flowing from the distribution ports 21 can be ignited using the ignition arrangement 32 to create flames for training. The flames are gradually reduced by a gradual reduction in the fluid flow through the outlet 8a, 8b or Sc by gradually moving the valve 15b towards a closed position using actuation arrangement 16.

Aspects of the present invention have been described by way of example only and it should be appreciated that additions and/or modifications may be made thereto without departing from the scope thereof as defined in the appended claims.

Claims (22)

1. Claims: 1 A fire simulation control system for use in fire training comprising: a frame having a plurality of distribution ports for allowing the passage of fluid, the plurality of distribution ports being one or more inlets configurable to connect to a fluid supply and two or more outlets for connection to one or more replicate devices; a fluid flow path for guiding fluid flow, the fluid being a combustible gas; a control means having a plurality of valves for controlling fluid pressure at the plurality of distribution ports, the number of valves corresponding to the number of distribution ports such that there is valve at each distribution port; pressure detection means for detecting the pressure level at each of the plurality of distribution ports, the pressure detection means comprising a pressure indication means associated with each distribution port for indicating the pressure level at each distribution port; regulation means for reducing fluid pressure at one or more locations along the fluid flow path, the regulation means being located between the one or more inlets and the two or more outlets, the regulation means comprising one or more shut-off valves configurable to shut off fluid flow at one or more locations along the fluid flow-path when fluid pressure exceeds a pre-determined level, whereby the control system is operable by an operator to completely shut down the system on any indication of a fault thereby enhancing the safety of the system.
2. 2 A fire simulation control system according to any preceding claim, wherein the fire simulation control system comprises a leak detection means for detecting a fluid leak at one or more points along the fluid flow path, the leak detection means comprising indication means for indicating when a leak is detected.
3. 3 A fire simulation control system according to any preceding claim, wherein each of the plurality of valves of the control means is capable of being moved from a first configuration, wherein fluid flow is blocked, towards a second configuration wherein fluid flow is permitted and wherein each valve is capable of being in a configuration between the first configuration and the second configuration, wherein partial flow is permitted.
4. 4 A fire simulation control system according to claim 3, wherein the control means comprises actuation means associated with each valve to enable movement of each valve towards, away from and between the first configuration and they second configuration.
5. 5 A fire simulation control system according to any preceding claim, wherein the pressure indication means is configured to provide a visual indication of the relative pressure.
6. 6 A fire simulation control system according to any preceding claim, wherein the pressure detection means comprises a pressure gauge associated with each distribution port.
7. 7 A fire simulation control system according to any preceding claim, wherein the regulation means comprises an overpressure shut off valve configured to stop the flow of fluid when the pressure reaches or exceeds a predetermined pressure value.
8. 8 A fire simulation control system according to any preceding claim, wherein the fluid flow path extends between the fluid supply and the one or more replicate devices, in use.
9. 9. A fire simulation control system according to any preceding claim, wherein the fire simulation control system comprises fluid delivery means.
10. 10. A fire simulation control system according to claim 9, wherein the fluid delivery means comprises one or more hoses, the one or more hoses comprising a smooth outer layer.
11. 11 A fire simulation control system according to claim 9 or 10, wherein the fluid delivery means comprises one or more manifolds, the one or more manifolds having a chamber connecting the one or more inlets to the two or more outlets such that in use, fluid flows into the chamber via the one or more inlets and out of the chamber via the two or more outlets.
12. 12. A fire simulation control system according to any preceding claim, wherein the fire simulation control system comprises ignition means for igniting fluid being delivered to one or more replicate devices.
13. 13 A fire simulation control system according to claim 12, wherein the fire simulation control system comprises an additional outlet and the ignition means being connectable to the additional outlet to receive a supply of fluid, the ignition means comprising a handle, a torch head and elongate shaft extending between the torch head.
14. 14. A fire simulation control system according to any preceding claim, wherein the frame comprises a base and one or more support elements for supporting the base off the ground.
15. A fire simulation control system according to claim 14, wherein the frame comprises a fluid supply support means for supporting a fluid supply container off the ground, the fluid supply support means being locatable on the base of the frame and having a receptacle for receiving a fluid supply container, the receptacle being sized and shaped to correspond to the fluid supply container.
16. 16. A fire simulation control system according to claim 15, wherein the receptacle is shaped and sized to correspond to a gas cylinder.
17. 17. A fire simulation control system according to any one of claims 14 to 16, wherein the frame comprises a control panel, an elongate body portion extending between the control panel and the base and a backboard extending most of the length of the body portion wherein, in use, the backboard provides a barrier between the flames in the replicate devices and the fluid supply.
18. 18. A fire simulation control system according to any preceding claim, wherein the frame comprises one or more wheels for enabling movement of the frame.
19. 19 A fire simulation control system according to any preceding claim, wherein the fire simulation control system comprises one or more connection means for enabling connection between one or more of the plurality of distribution ports and a fluid delivery means, wherein the one or more connection means are suitable for single hand use.
20. A fire simulation control system according to claim 19, wherein the one or more connection means comprises a quick release means for enabling quick disconnection, the quick release means comprising a push button configured to cause disconnection upon actuation.
21. 21 A fire simulation control system according to any one of claims 10 to 20, wherein the fire simulation control system comprises tamper resistant means for preventing or detecting tampering with one or more parts of the fire simulation control system, wherein the tamper resistant means comprises layers of shrink-wrapped material at one or both ends of the hoses of the fluid delivery means.
22. 22. A fire simulation control system according to any preceding claim, wherein one or more component parts of the fire simulation control system comprises identification means to enable traceability of the one or more parts.