The present invention relates to a spray head, in particular a fire suppression spray head comprising at least one nozzle through which fire suppressant material (such as water) can be sprayed.
Fire suppression systems which use nozzles are known. For example, U.S. Pat. No. 4,356,870 describes a water spray fire protection system for hoods over cooking units which comprises spray nozzles on the lower ends of water pipes which are connected to a water supply pipe. A disadvantage of such systems is that they are relatively complex and therefore relatively expensive to install.
The present invention is made with this in mind.
In one aspect, the present invention provides a fire suppression spray head for attaching to a sink assembly comprising a sink, a tap, a work surface adjacent the sink, a cupboard underneath the sink and at least one cupboard door. The spray head has at least one nozzle for spraying fire suppressant material received from a supply of fire suppressant material. The spray head is configured to be attached to a part of the sink assembly.
In another aspect, the present invention provides a fire suppression spray head for attaching to a work surface. The spray head has at least one nozzle for spraying fire suppressant material received from a supply of fire suppressant material. The spray head is configured to be attached to the work surface.
By the spray head being configured to be attached to a part of the sink assembly or work surface, the spray head can be easily and simply installed with a relatively small amount of additional piping. For example, the spray head can be simply connected to an existing water supply pipe under the sink or for a washing machine. Furthermore, the spray head can be retro-fitted to existing sink assemblies. Accordingly, a relatively inexpensive and/or unobtrusive fire suppression solution can be provided.
Other aspects of the present invention will be appreciated from the following description and accompanying claims.
Embodiments of the present invention will now be described, by way of example only, with reference to the accompanying drawings in which like reference numerals are used to depict like parts. In the drawings:
a-7c and 8a-8b illustrate the structure of an embodiment of a spray head;
a-16b illustrates the structure of an embodiment of a spray head;
a-17d and 18a-18d illustrate the manifold and cover which make up an embodiment of a spray head;
a-20b illustrates the cover and the caps.
In the present disclosure the term “fire suppression” is used to encompass other terms which may be used when describing suppressing, controlling or extinguishing fires. In particular “fire suppression” is used to encompass the terms “fire suppression”, “fire control” and “fire extinguishment”, although for the purposes of the present disclosure these terms can be used interchangeably unless a specific instance indicates otherwise. The term “sink” is used to encompass both “sinks” and “basins”, and indeed these terms can be used interchangeably. Similarly, the term “tap” is used to encompass both “taps” and “faucets” and again these terms can be used interchangeably.
In some applications, “fire control” is used to describe a steady reduction in the heat release rate resulting in a lower controlled level of burning/limitation of fire growth and protection of structure (by cooling of objects, fire gases and/or pre-wetting adjacent combustibles) and “fire extinguishment” is used to describe a sharp reduction in heat release rate leading to complete elimination of any flaming or smoldering fire. The spray head of the present disclosure can be used in these applications.
In describing the arrangements shown in the figures, where the same reference numeral has been used to describe the same part in an earlier figure, the part will not be described again although it should be appreciated that the relevant earlier description applies, where appropriate.
Referring to the Figures,
Underneath the sink, a pressure generator, in this example a pump 34, is connected through pipe or hose 38 to the nozzles 14 of the spray head. The pump 34 is also connected through pipe or hoses 28, 32 to the cold water supply 26. Accordingly, pump 34 is activatable to supply fire suppressant material (in this example water) to the nozzles 14 of the spray head 12.
Cold water supply 26 is also connected through pipe 30 to the tap to provide cold water. Hot water supply 22 is connected to the tap 16 through pipe 24 to provide hot water.
Spray head 12 has a central aperture through which pipes 24 and 40 can pass. The spray head sits around or surrounds the base of the tap 16.
Fire suppression and/or initiation device(s) are provided in the form of detector 40 and pump control 36. The detector 40 comprises a transmitter and the pump control comprises a receiver. Detector 40 is arranged to detect a fire and in response transmit via the transmitter a signal to the pump control 36. In response to receiving via its receiver the signal the control 36 is arranged to activate the pump and supply water from water supply 26 to the nozzles 14. Water is sprayed out of nozzles 14 to suppress or control or extinguish the fire.
Referring now to
Air or pneumatic atomising nozzles are available from Lechler Ltd., 1 Fell Street, Newhall, Sheffield, South Yorkshire S9 2TP.
In the arrangement of
Referring now to
Pump 34 has a water filter 44 to filter the water received from water supply 26. Pipe or hose 38 connects the pump to the nozzles 14 of the spray head 12 at the front of the sink.
Referring now to
In some arrangements, a plurality of nozzles is provided with an approximate orifice size of in a range of 0.152-1.02 mm. This can achieve a fog spray pattern with high percentage of droplets under 50 microns in size.
In
In the illustrated example of
a shows a portion of hub 13 in a cross sectional view. Referring to
In a particular example, the micro nozzle component 52 produces a cone shaped fog spray pattern through a 90 degree spray pattern, with a high percentage of droplets under 50 microns in size. Suitable, micro nozzle components or micro nozzles are available from BETE Fog Nozzle, Inc. 50 Greenfield Street, Greenfield, Mass. 01301 USA (www.BETE.com) and include the PJ misting nozzle range.
b shows an alternative arrangement with an hour-glass shaped nozzle 14 in the hub. A high pressure coupling or nipple 54 connected to a high pressure hose is connectable to the nozzle 14. The other end of the high pressure tube is connectable to the pressure generator. The high pressure coupling is held in place by screws/bolts 56 and nuts 58.
c shows a pneumatic atomizing nozzle component 57 which has one hose 60′ for supplying air and another tube 60″ for supplying water. Varying the air and water pressures can achieve a range of spray patterns by changing the droplet size, degree of spray, distance and cone shape for example.
In
The spray head can be provided with nozzles of different sizes or types. That is, the spray head may be configurable so that a variety of separate, attachable components comprising the nozzles can be used with the same spray head and thus a variety of spray patterns can be achieved. Accordingly, the at least one nozzle can be configurable on installation so that the fire suppressant material can be directed towards the fire load.
Using pneumatic atomising nozzles provides one way of making the nozzles configurable. Another way in which one or more nozzles can be configurable on installation is by using different micro nozzle components such as the various different micro nozzles available from BETE Fog Nozzle, Inc.
Considerations when configuring the nozzles include selecting the droplet characteristics. For example, from an efficiency standpoint, the smaller the size of a droplet, the greater the surface area to volume ratio. The greater ratio translates to faster heat transfer and faster evaporation and results in energy being removed from the fire faster. As another example, a spiral nozzle design allows the largest droplets to migrate toward the outside of the pattern, thus providing protection to the smaller droplets allowing them to penetrate the target area.
The spray head can be made from any suitable material such as stainless steel, a chrome plated brass or zinc alloy. In some cases it maybe porcelain to match the sink.
a-b shows an example of an embodiment of spray head 12. Spray head 12 has a central aperture 59 through which water supply pipes can pass.
a shows a front view of the manifold 11.
a shows a plan view the cover 15.
In
a shows a front view of the cover 15 with the caps 17 open.
Embodiments of the invention have been described by way of example only. It will be appreciated that variations of the described embodiments may be made which are still within the scope of the invention.
For example, the nozzle can be used to produce fog, water or mist. Furthermore, gaseous or liquid fire suppressant materials can be used on there own or in combination and/or with water.
Features from the described arrangements may be used in combination with one another. For example, the arrangement of
A single spray head can surround the base of a combination hot and cold tap.
The sink may include a drainboard and the spray head may be attached to the drainboard.
The fire suppression detection and/or initiation device(s) can comprise one or more of a rate of rise heat detector, push button, ionization smoke alarm, optical smoke alarm, UV flame detector or a combination fire alarm.
The alarm may also be connected to a phone line. The device may have a visual or audio alarm to notify when maintenance is due.
The arrangement may be such that an additional spray head is provided to spray under the sink around the pressure generator (e.g pump).
The spray head can be used with a variety of systems. For example, it could be used with a deluge system (where the valve opens, water flows through the pipe work and discharges simultaneously through all the nozzles in the system), a dry pipe system (where the pipe work is charged with air or inert gas under pressure), high, medium, or low pressure system, an object protection system (where water is designed to discharge directly on to an object or hazard (e.g. a fat fryer)), a pre action system (where it is triggered by a fire in another room it is there to protect spread to the kitchen), a water mist system (where the spray is 90% of the flow-weighted cumulative volumetric distribution of water droplets is less than 100 microns, a water spray system (in principle a tradition sprinkler), a wet pipe system (in which the pipe work is always charged water) and, in particular, a volume protection system (where the discharge of water mist is designed to protect all hazards in a predefined volume).
Number | Date | Country | Kind |
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0821388.6 | Nov 2008 | GB | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/GB2009/002727 | 11/20/2009 | WO | 00 | 8/5/2011 |
Publishing Document | Publishing Date | Country | Kind |
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WO2010/058183 | 5/27/2010 | WO | A |
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Number | Date | Country | |
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20110284250 A1 | Nov 2011 | US |