TH86823A - Fire extinguishing system by using low-pressure and high-speed spray pipes. - Google Patents

Abstract

DC60 (22/11/16) fire extinguishing system was revealed. The system will consist of a compressed gas source. And origin Pressure liquid At least one injection tube will have fluid exchange with Compressed gas sources and pressurized liquid sources The injection tube is used to generate a gas stream which is atomized and carried. Along with the liquid to the gas stream, and the result is It will release a stream of liquid and gas into the fire. Methods of operating the system will also be revealed. The method consists of generating a gas current preceding the first shock wave. And the second ball by using a spray hose, which is then atomized And carry the liquid to mix with gas in front of any wave To create a flow of liquid and gas And released that stream to the fire Methods are also included. Go to creation Diamond from multiple bumps In the flow of liquids and gases released from the corrective spray hose 11/22/2016, a fire extinguishing system was revealed. The system consists of a compressed gas source and a source. Pressure liquid One or more of the injection tubes are exchanged with the compressed gas source and the pressurized fluid source. The injection tube is used to generate a gas stream. Which was atomized and carried away Along with the liquid to the gas stream, and as a result, a stream of liquid and gas is released into the fire. Methods of operating the system are disclosed, with methods consisting of gas flow preceded by a first shock wave. And the second child using a hose inject Which will be atomized And carry the liquid to mix with gas in front of any wave To create a flow of liquid and gas And released that stream to the fire Methodology also includes building Diamond from multiple shocks in a fluid and gas stream that is released from the injection tube. ------------------------ Revised Invention Summary 15/03/2016 Fire extinguishing system has been revealed. The system consists of a compressed gas source and a source. Pressure liquid At least one of the injection pipes is exchanged with a compressed gas source. And the source of pressurized liquid The injection tube is used to generate a gas stream. Which was atomized and carried away Along with the liquid to the gas stream, and as a result, the liquid-gas stream is released into the fire. Methods of operation are disclosed, with the method comprising gas flow preceded by a first shock wave. And the second child using a hose inject Which will be atomized And carry the liquid to mix with gas in front of any wave To create a flow of liquid and gas And released that stream to the fire Methodology also includes building Diamond from multiple shocks in a fluid and gas stream that is released from the injection tube. -------------------------------------------- Fire extinguishing system has been revealed. up The system will consist of a compressed gas source. And the source of pressurized liquid At least one injection tube will have fluid exchange with Compressed gas source And the source of pressurized liquid The injection tube is used to generate a gas stream which is atomized and carried along with the liquid to the gas stream, and the result is Will release a stream of liquid and gas into the fire How to operate the system will also be disclosed. The method consists in generating a gas stream preceding the first and second shock waves by means of a hose, which is atomized. And carry the liquid to mix with gas in front of any wave To create a stream of liquid and gas And released the stream to the fire Methods are also included. To create diamonds from multiple shocks in a stream of liquid and gas released from the injection tube

Claims (9)

Claims (all) which will not appear on the advertisement page: edit 11/22/2016 1. Methods for operating a fire extinguishing system where such a system has a spray hose consisting of: a nozzle with an open cylinder between the inlet and outlet. The inlet of the said nozzle Which connects the liquid to the compressed gas source Such an outlet, which has a diameter; A hose which is separated from the said nozzle and connects the fluid to the compressed gas source. Such a pipe with an outlet opening is positioned adjacent to the outlet of the said nozzle; Reflecting surfaces are positioned facing the outlet of the nozzle, with a gap between them. The reflective surface consists of a flat surface directed perpendicular to the nozzle. Such a flat surface with a wet area defined by the smallest diameter approximately equal to Such outlet diameter; The methods include: releasing the liquid from the said outlet holes; The release of the gas from the outlet of the said nozzle, which also causes the gas flow. Supersonic; Producing in front of the first shock wave between the outlet pipe and the reflected surface Where the gas is moving from slow to supersonic speed. Then hit the wet area; Causing a second shock wave in front of the reflected surface Such gas which Moving across such wet areas And the speed increases to supersonic speed between the wave pages Impact of the first one against the second shock wave And slow down after passing through In front of the second such shock wave The transfer of the liquid is mixed with the gas near the second shock wave. In order to create a flow between liquid and gas; And the flow of the liquid and gas away from the spray pipe 2. Procedure according to claim 1, where the system consists of: several compressed gas cylinders that produce a compressed gas source; Multiple control valves Each of which corresponds to each of these compressed gas cylinders; A supervisory loop communicates with such a control valve. Be aware of the opening and closing status of such a control valve; And that method consists of monitoring the said control valve status and maintaining the valve The control is always on during the operation of the said system. 3. Method according to claim 1, which consists of creating a diamond resulting from Bumps in such a stream of liquid and gas 4. Method according to claim 1, consisting of excessive expansion of gas flow. At high speed after exiting the said nozzle 5. Method according to claim 1, which consists of supplying gas to such inlet pipe as well. The pressure is between approximately 29 psia and approximately 60 psia. 6. Method for claim No. 1, which consists of supplying liquid to the said pipe with The pressure value is between approximately 1 psig to approximately 50 psig. 7. The procedure under claim 1 will also consist of mixing the liquid with gas. It is close to the front of the first shock wave. 8. Method according to claim 1, whereby the flow of the fluid will not separate from the reflected surface. 9. Method for claim No. 1 will also consist of no sound energy generated from the injection pipe. Such, in addition to the noise of moving at high speeds 1 0. The method of claim 1 will also consist of inducing momentum in the flow of Gas at such high speed 1 1. Method for claim No. 1 will also consist of the flow of liquefaction to gas. It hit a speed of about 1,200 feet per minute at a distance of about 18 inches from the pipe. 2. The method under claim 1 will also consist of the flow of liquid and gas. It hit a speed of about 700 feet per minute at a distance of about 8 feet from the pipe. 3. Method for claim No. 1 will also consist of creating a flow pattern from the injection pipe. It has a predetermined angle by defining the beveled portion of the reflected surface. Around such a flat surface 1 4. The method according to claim 1, which consists of adding the liquid to the gas using the difference between the pressure in the gas and the atmospheric pressure 1. 5. Method according to claim 1, which consists of mixing the said liquid with the said gas and making the said liquid droplets with a diameter of less than 20 micrometers 1. 6. Method according to claim 1, which consists of adding an oxygen-free smoke layer to the gas. And carry the smoke layer with the liquid-gas stream of the said hose 1 7.Method of claim 1 consists of emission of inert gas from the said outlet pipe 1. 8. Method according to claim 1, which consists of the release of an inert gas mixture with The chemical reaction exits the outlet pipe 1. 9.Method according to claim 18, where the gas mixture consists of air 2. 0. Methods for operating a fire extinguishing system where such a system will have a spray hose consisting of: a nozzle with an open cylinder between the inlet and outlet. The inlet of the said nozzle Which connects the liquid to the compressed gas source. Such an outlet, which has a diameter; A hose which is separated from the said nozzle and connects the fluid to the compressed gas source. The pipe with the outlet hole is positioned next to the nozzle outlet; Reflecting surfaces are positioned facing the outlet of the nozzle, with a gap between them. The reflective surface consists of a flat surface directed perpendicular to the nozzle. Such a flat surface with a wet area defined by the smallest diameter approximately equal to Such outlet diameter; The above methods will consist of; The release of the said liquid from the said outlet; The release of the gas from the outlet of the said nozzle, which also causes the gas flow. Supersonic; Producing in front of the first shock wave between the outlet pipe and the reflected surface Where the gas is moving from slow to supersonic speed. And then hits the wet surface; Causing a second shock wave in front of the reflected surface Such gas which Moving across such wet areas And the speed increases to supersonic speed between the wave pages The first one hit in front of the second shock wave. And slow down after passing through the face The second shock wave The transfer of the liquid is mixed in the gas at one of the shockwave faces to Causing a current between liquid and gas; And the flow of the liquid and gas away from the spray tube 2 1. The method of claim 20 also consists of having the liquid being carried along with the The gas, which is close to the second shockwave 2 2. The procedure in claim 20 also consists of having the liquid being carried along with the The gas, which is close to the front of the first shock wave 2 3. The method of claim 20 also consists of adding an anaerobic layer of smoke to the Flows of the gas and carries the smoke layer with the liquid-gas stream 2 4. Fire extinguishing system consisting of: compressed gas source; Pressurized liquid source: One or more spray tubes for atomizing liquids and discharging them. Flowing with the said gas on the fire; A gas pipe which provides fluid exchange between the source of the compressed gas. With such a hose; Water pipe network, separated from the said gas pipe, the said water pipe network provided. Communicates the fluid between the source of the pressurized fluid and the pipe; The first valve in the gas line that controls the pressure and flow of the gas to the pipe; The second valve in the pipeline that controls fluid pressure and flow. It goes into the said hose; A pressure transducer which measures the pressure inside a gas pipe; A fire detection device that will be positioned close to the spray hose; The hose consists of: a nozzle with inlet and outlet, and an open cylinder between the inlet and outlet, the inlet that connects the liquid to the first such valve. The aforementioned outlet, diameter: a pipe, which is separated from the said nozzle and is connected to the fluid communication with the second valve. Such pipes with outlet holes separated from and positioned adjacent to the outlet of the said nozzle; The reflective surface is positioned facing the nozzle exit. Reflection surface Which is positioned with a space relative to the outlet of the said nozzle and which has a The first surface consisting of a flat surface that will travel perpendicular to the said nozzle. And the second surface at It consists of an angled surface around the flat surface. Such a flat surface with an exposed wet area. Determined by the smallest diameter approximately equal to the said outlet diameter; And the control system communicates with the aforementioned first and second valves. Pressure converter Such equipment and fire detectors. The control system receives a signal from the processor. Such pressure and fire detectors And will open the said valve in response to Signs of a fire from the fire detector 2 5. The system according to claim 24 will also consist of: Multiple compressed gas cylinders. It consists of the compressed gas source and the high pressure hoses with multiple inlet and outlet through which the fluid is transferred between the compressed gas cylinder. As mentioned with the first such valve 2 6. The system according to Clause 25 also consists of Multiple control valves Each of which corresponds to each of these compressed gas cylinders; And the monitoring ring to communicate with the said control system and the said control valve in the waiting Monitor the opening and closing status of the control valve 2. 7. System according to claim 24, where the nozzle is a nozzle with a convergent surface 2. 8.System according to claim 24 where the outlet pipe will have a diameter between approximately 1/8 inch and approximately 1 inch 2. 9. System according to claim 24, with the said exit holes between approximately 1/32 inch and approximately 1/8 inch. 0. System according to claim 24 where such reflected surface will have a gap from the outlet pipe. With a distance of approximately 1/10 inch to approximately 3/4 of an inch. 1. System according to claim 24, where the angled surface part has a reverse angle, which is Between approximately 15 degrees and approximately 45 degrees measured from the said flat surface 3 2. System according to claim 24, where such exit holes are at a distance from the outlet pipe. These are the distances between approximately 1/64 of an inch and about 1/8 in. 3. 3. System according to claim 24, where such a nozzle will be adjusted to work at the gas pressure. They are between approximately 29 psia to approximately 60 psia 3 4. System according to claim 24, where the pipes are adjusted to work at the pressure The liquid is between approximately 1 psia to approximately 50 psig 3. 5. System according to claim 24, where the pipe is angular directed toward the said nozzle 3. 6. The system according to claim 24 also contains many such exit holes 3. 7. Extinguishing system consisting of: compressed gas source; Source of pressurized liquid; One or more spray tubes to atomize liquids and discharge them to Flowing with the said gas on the fire; A gas pipe which provides fluid exchange between the source of the compressed gas. With such a hose; Water pipe network, separated from the said gas pipe, such water pipe network provided. Communicates the fluid between the source of the pressurized fluid and the pipe; The first valve in the gas line that controls the pressure and flow of the gas to the pipe; The second valve in the pipeline that controls the pressure and flow of the liquid. It goes into the said hose; A pressure regulator which measures the pressure inside the said gas pipe; A fire detection device that will be positioned close to the spray hose; The hose consists of: a nozzle with inlet and outlet, and an open cylinder between the inlet and outlet, the inlet that connects the liquid to the first such valve. Such an outlet, which has a diameter; A hose which is separated from the said nozzle and the fluid communication is connected to the second valve. The pipe with a separate outlet opening and positioned next to the nozzle outlet; The reflective surface is positioned facing the nozzle exit. Reflection surface Which is positioned with a space relative to the outlet of the said nozzle and which has a The first surface consisting of a flat surface that will travel perpendicular to the said nozzle. And the second surface at It consists of a curved surface surrounding it. Such a flat surface with a fixed wet area. Raised by the smallest diameter approximately equal to the said outlet diameter; And the control system communicates with the aforementioned first and second valves. Pressure converter Such equipment and fire detectors. The control system receives a signal from the processor. Such pressure and fire detectors And will open the said valve in response to Signs of a fire from such fire detectors -------------------------- Revised 3/15/2016 1. A method for operating a fire extinguishing system where such a system has a hose consisting of: a nozzle with an open cylinder between the inlet and outlet. The inlet part of the said nozzle, which Connect the liquid to the compressed gas source. Such an outlet, which has a diameter; A hose that is separated from the said nozzle and connects the fluid to the compressed gas source, the pipe with an outlet opening positioned adjacent to the outlet of the said nozzle; Reflecting surfaces are positioned facing the outlet of the said nozzles with a gap between them. The reflex surface, which is composed of a flat surface that is directed perpendicular to the nozzle, Such where the wet area is defined by the smallest diameter approximately equal to the said outlet diameter; The methods include: releasing the liquid from the said outlet holes; The release of such gas from the outlet of such a nozzle, which causes a supersonic gas flow; Creating in front of the first shock wave between the outlet pipe and the reflected surface where The gas moves from slow to supersonic speed. And to hit such wet areas; Causing a second shock wave in front of the reflected surface The gas that passes through Skip that wet area And the speed increases to supersonic speed between the front of the first shock wave With the face of the second such shock wave And slow down after passing through the second shock wave, carrying the liquid mixed in the gas near the second shock wave. To form a flow between liquid and gas; And the flow of the liquid and gas away from the spray pipe 2. Method according to claim 1, where the system consists of: several compressed gas cylinders. Which causes a compressed gas source of pressure; Multiple control valves, which but Each act in relation to each such compressed gas cylinder; A supervisory loop communicates with such a control valve in surveillance. The state of opening and closing of such control valves; And such an approach is to monitor the state of such control valves and to maintain control valves. It is always on during the operation of the said system. 3. Method according to claim 1, which consists of creating a diamond resulting from Bumps in such a stream of liquid and gas 4. Method according to claim 1, which also consists of causing excessive gas flow. High speed after exiting the said nozzle 5. Method according to claim 1, which consists of supplying gas to such inlet pipe by pressure. Between approximately 29 psia and approximately 60 psia 6. Method according to claim 1, which consists of supplying liquid to the said pipe with appropriate pressure. Values are between approximately 1 psig to approximately 50 psig. 7. The procedure under claim 1 will also consist of mixing the liquid with the said gas. Near the front of the first shock wave 8. Method according to claim 1, whereby the flow of the fluid will not separate from the reflected surface. 9. Method under claim No. 1 will also consist of no sound energy generation from the said injection pipe. In addition to the noise of moving at high speeds 1 The method of claim 1 will also consist of creating momentum in the gas flow. Such high speed 1 1. Method for claim No. 1 will also consist of the flow of liquefaction to gas. It hit a speed of about 1,200 feet per minute at a distance of about 18 inches from the pipe. 2. The method under claim 1 will also consist of the flow of the liquid and gas. At about 700 feet per minute at a distance of about 8 feet from the aforementioned hose, 1 3. The method of claim No. 1 will also consist of creating a flow pattern from the said hose. Which has a predetermined angle by defining the beveled portion of the pew reflection around the flat surface 1 4. The method according to claim 1, which consists of adding the liquid to the gas using the difference between the pressure in the gas and the atmospheric pressure 1. 5. Method under claim No. 1, which consists of mixing the said liquid with the said gas. And the liquid is aerosol droplets with a diameter of less than 20 μm 1 6. Method according to claim 1, which consists of adding an oxygen-free smoke layer to the said gas. And carry that smoke layer with the liquid-gas stream of the aforementioned hose 1 7.Method of claim 1 consists of emission of inert gas from the said outlet pipe 1. 8. Method according to claim 1, which consists of the release of an inert gas mixture with The chemical reaction exits the outlet pipe 1. 9.Method according to claim 18, where the gas mixture consists of air 2. 0. Methods for operating a fire extinguishing system where such a system will have a spray hose consisting of: a nozzle with an open cylinder between the inlet and outlet. The inlet part of the said nozzle, which Connect the fluid to the compressed gas source. Such an outlet, which has a diameter; A hose which is separated from the said nozzle and connects the fluid to the compressed gas source. In which the outlet opening is positioned adjacent to the outlet of the said nozzle; Reflecting surfaces are positioned facing the inlet exit of the said nozzle, with a gap between them. The reflex surface, which consists of a flat surface that is directed perpendicular to the nozzle, a flat surface. Such where the wet area is defined by the smallest diameter approximately equal to the said outlet diameter; The above methods will consist of; The release of the said liquid from the said outlet; The release of such gas from the outlet of such a nozzle, which causes a supersonic gas flow; Creating in front of the first shock wave between the outlet pipe and the reflected surface where The gas moves from slow to supersonic speed. And then hits the wet surface; Creating a second wave front at the reflected surface The gas that passes through Skip that wet area And the speed increases to supersonic speed between the front of the first shockwave and In front of the second such shock wave And slow down after passing through the shock wave to cause The transfer of the liquid is mixed in the gas at one of the shockwave faces to cause Flow between liquid and gas; And the flow of the liquid and gas away from the spray tube 2 1. The method of claim 20 also consists of getting the liquid to be carried with the gas. It is located near the front of the second shockwave 2. 2. The procedure under claim 20 also consists of getting the liquid to be carried with the gas. It is located near the front of the first shock wave 2 3. Fire extinguishing system consisting of; Compressed gas source, pressure; Pressurized Liquid Source: One or more spray tubes for liquefying liquids and allowing them to flow. Along with the said gas on the fire; A gas pipe which provides for the exchange of fluid between the source of the compressed gas and the pipe; The water pipe network, which defines the exchange of fluid between sources of pressurized fluid. With such a hose; The first valve in a gas line that controls the pressure and flow of the gas to the pipe; The second valve in the pipeline that controls the pressure and flow rate of the liquid. Into the said hose; A pressure transducer which measures the pressure inside a gas pipe; A fire detection device that will be positioned close to the spray hose; The hose consists of: a nozzle with inlet and outlet, and an open cylinder between the inlet and outlet, the inlet that connects the liquid to the first such valve. Such a diameter outlet: a pipe which is separated from the said nozzle and is connected to the fluid communication with the second aforementioned valve. Those with a separate outlet hole from and in a position adjacent to the said nozzle outlet; The reflective surface is positioned facing the nozzle exit. Such reflective surfaces, which Is positioned with a gap in relation to the outlet of the said nozzle and which has the first surface segment to It consists of a flat surface that is directed perpendicular to the said nozzle. And the two surface parts that comprise the surface Tilted at an angle around the flat surface Such a flat surface with a wet area that is defined by The smallest diameter approximately equal to the said exit diameter; And the control system communicates with the aforementioned first and second valves. Such a pressure converter and Such equipment to detect fire The control system receives a signal from it and Such equipment to detect fire And will open the valve in response to a fire indication. From the aforementioned fire detectors 2 4. The system according to claim 23 will also consist of: Multiple compressed gas cylinders. It consists of the source of the compressed gas and the high-pressure hoses with multiple inlet and outlet through which the fluid is transferred between the compressed gas cylinder. With the first such valve 2 5. The system according to Clause 24 also includes Multiple control valves Each of which works in relation to each such compressed gas cylinder and The monitoring ring communicates with the said control system and the said control valve. Be aware of the opening and closing status of the aforementioned control valve 2 6. System according to claim 23, where the nozzle will be a nozzle with a converging surface 2. 7. System according to claim 23, where the outlet pipe will have a diameter between approximately 1/8 inch and approximately 1 inch 2. 8. System according to claim 23, where the opening holes are between approximately 1/32 inch and approximately 1/8 inch 2. 9. System according to claim 23 where the reflected surface will have a gap from the said outlet pipe. With a distance between approximately 1/10 inch to approximately 3/4 inch 3 0. System according to claim 23, where the angled surface part has a reverse angle between approximately 15 degrees and approximately 45 degrees measured from the said flat surface 3. 1. System according to claim 23, where the said exit hole is the distance from the said outlet pipe. It is the distance between about 1/64 of an inch to about 1/8 in. 3. 2. System according to claim 23, where the nozzle will be adjusted to work at the gas pressure value. Between approximately 29 psia to approximately 60 psia 3 3. System according to claim 23, where the pipes will be adjusted to work at the fluid pressure value. Between approximately 1 psia and approximately 50 psig 3. 4.The system according to claim 23, wherein the nozzle is directed angular to the nozzle 3. 5. The system according to claim 23 also contains many such exit holes 3. 6. Extinguishing system consisting of: compressed gas source; Source of pressurized liquid; One or more spray tubes to atomize liquids and let them flow. Along with the said gas on the fire; A gas pipe which provides for the exchange of fluid between the source of the compressed gas and the pipe; A water pipe network, which defines the exchange of fluid between the generation of the pressurized fluid. With such injections; The first valve in the gas line that controls the pressure and flow of the gas to the pipe; The second valve in the pipeline that controls the pressure and flow rate of the liquid. Into the said hose; A pressure regulator which measures the pressure inside the said gas pipe; A fire detection device that will be positioned close to the spray hose; The injection tube consists of; The nozzle with inlet and outlet and the open cylinder is between the inlet and outlet, the inlet, which connects the liquid to the first such valve. Such an outlet, which has a diameter; A hose which is separated from the said nozzle and the fluid communication is connected to the second valve. That have a separate outlet hole and positioned next to the nozzle outlet; The reflective surface is positioned facing the nozzle exit. Such reflective surfaces, which Is positioned with a gap in relation to the outlet of the said nozzle and which has the first surface segment to It consists of a flat surface that is directed perpendicular to the said nozzle. And the second surface part that consists of Curved around such a flat surface. Such a flat surface with a wet area that is defined by a small diameter. The most approximately equal to the aforementioned outlet diameter; And the control system communicates with the aforementioned first and second valves. Such a pressure converter and Such equipment to detect fire The control system receives a signal from it and Such equipment to detect fire And will open the valve in response to a fire indication. From the aforementioned combustible fuel detector 3 7. The method of claim 20 also consists of adding an anaerobic layer of smoke into the flow. Of the said gas and carry the smoke layer with the gas-gas stream 3 8. The method according to claim 23 also consists of a closed-end slot positioned within the surface. Echo it 3 9. The system according to claim 36 also consists of a closed-end slot positioned within the surface. Echo such -------------------------------------------------- 1. Fire fighting system which consists of Compressed gas source Pressurized liquid source One or more spray tubes for atomizing and releasing liquids. It flows with the said gas on the fire. A gas tube which provides fluid exchange between compressed gas sources. With the said hose A water pipe network, which determines the exchange of fluid between sources The fluid presses the said pressure on the pipe. The first valve in such a gas line that controls the pressure and flow of the gas. Into the said hose The second valve in the pipeline that controls the pressure and flow rate of the The liquid goes into the said tube. A pressure transducer which measures the pressure inside a gas pipe. Fire detectors are positioned close to the hose and the control system communicates with the first and second valves, the pressure modulator and the fire detectors. The control system receives signals from Such a pressure regulator and a fire detector And will open the said valve to Responds to signs of fire. From the fire detectors, the control system activates the first such valve in order to maintain a predetermined pressure level. Inside the gas pipe for the operation of the said hose 2. The system according to Clause 1 will also consist of Several compressed gas cylinders, comprising the source of the compressed gas, and multiple high-pressure hoses, where fluid is transferred between the compressed gas cylinders. The pressure on the first such valve 3. The system according to Clause 2 will also consist of Multiple control valves Each of them works in relation to each such compressed gas cylinder and the supervisory loop to communicate with the control system and Such a control valve to monitor the on-off state of the control valve. 4. System according to claim 1, where the aforementioned hose will consist of A nozzle with an inlet pipe connected to the first valve and an outlet pipe for use in Fluid exchange A pipe that is connected to the second valve for fluid exchange. The pipe will There is an outlet hole adjacent to the outlet pipe, and the reflection surface is positioned facing the said outlet pipe, with a gap between them. Directed perpendicular to the nozzle And the second surface portion attached to the first surface portion. And will go indefinitely The scene with the said nozzle The liquid is released from the opening and the gas is released from the nozzle outlet pipe. The liquid will be mixed with gas. It is then atomized to create a flow between the liquid and the gas. Which will affect The reflected surface and flows from the nozzle to the said fire. 5. System according to claim 4, where the nozzle is a nozzle with a convergent surface. 6. System according to claim 4, where the said outlet pipe has a diameter Between about 1/8 inch and about 1 inch. 7. System according to claim 4, with the aforementioned exit holes having Between about 1/32 of an inch and about 1/8 of an inch. 8. System according to claim 4, where the reflected surface will have a gap from the pipe. Such a solution with a distance of about 1/10 inch to about 3/4 of an inch 9. System according to claim 4, where the first surface area consists of The smooth surface and the second surface consist of an angled surface surrounding it. 0. System according to claim 9, where such a flat surface will have a diameter Approximately equal to the diameter of the said outlet pipe 1 1. System according to claim 9, where the angled surface part has a reverse angle, which has The value ranges from approximately 15 degrees to approximately 45 degrees, measured from such a smooth surface 1 2.The system according to claim 4, where the first surface part consists The flat surface and the second surface consist of a curved surface surrounding it. 3. System according to claim 4, where the reflected surface has an end resonant pipe. Closed, with the open end in the position facing the said outlet pipe 1 4. System according to claim 13, where the first part of the surface surrounds the pipe. Resonant as mentioned 1 5. System according to claim 14, where the second part of the surface surrounds Part of the first part of the surface 1 6. System according to claim 4, where the said exit hole is the distance from the pipe. The aforementioned exit is a distance between approximately 1/64 of an inch and approximately 1/8 of an inch. 7. The system according to claim 4, wherein the nozzle is adjusted to work at the pressure The gas value is between approximately 29 psia to approximately 60 psia 1. 8. System according to claim 4, where the pipes will be adjusted to work at The liquid is between approximately 1 psia to approximately 50 psia 1. 9. System according to claim 4, where the aforementioned hose will consist of A nozzle with an inlet pipe connected to the compressed gas source and the outlet pipe. For use in fluid exchange A pipe that is attached to the source of the pressurized fluid for use in fluid exchange.The pipe has an outlet hole positioned next to the outlet pipe and the reflection surface is positioned facing the outlet pipe. With a gap between them, the reflected surfaces are positioned in front of the first shockwave during The said outlet pipe to the reflecting surface. And the second shock wave face is close to the surface Is reflected by the predetermined pressure of the said gas delivered to the injection tube and Is released from the nozzle outlet pipe 2 0. System according to claim 19, whereby the pipes are placed in position and charged. Out, with the said liquid released from the opening, the outlet is carried with The gas is close to one of the two shockwave faces. 1. System according to claim 20, where such reflected surfaces are placed in Where the stock diamonds are formed in the flow between liquid and gas 2 2. System according to claim 20, where the said exit hole is positioned at In relation to the said outlet pipe To cause the liquid to be carried along with the gas, which Near in front of the second such shockwave 2 3. System according to claim 20, where the pipe is angular directed toward the said nozzle to cause the liquid to be carried along with the gas near the wave. Hitting that first ball 2 4. The system according to claim 19 shall consist of such nozzles of Will create an excessively inflated gas flow at high speed from the nozzle with the pressure at Has predefined 2 5. The system according to claim 19 will also consist of the aforementioned nozzles of The gas flow at such a high speed will not generate noise, in addition to noise. From gas flow at high speed 2 6. System according to claim 19, where the reflected surface consists of a part A flat surface directed towards the outlet pipe. And the surface with bevel surround The surface is smooth. The beveled surfaces determine the total angle of the flow pattern from Pipe 2 7.Methods for operating a fire fighting system The system has a hose consisting of a nozzle with an inlet pipe connected to the compressed gas source and an outlet pipe. For use in fluid exchange A pipe that is attached to the source of the pressurized fluid for use in fluid exchange.The pipe has an outlet hole positioned next to the outlet pipe and the reflection surface is positioned facing the outlet pipe. With a gap between them, the method will consist of The release of the said fluid from the opening The release of such gas from the said outlet pipe. Induction in front of the first shock wave between the outlet pipe and the reflected surface, causing the second shock wave at the reflected surface. The transfer of the liquid to be mixed with the gas to create a liquid-gas stream and to move the liquid-gas out of the spray tube 2 8. Procedures according to Clause 27, whereby the system consists of Several compressed gas cylinders that form the source of such compressed gas. Multiple control valves Each one is attached to each such compressed gas cylinder. The monitoring ring communicates with the control valve for the monitoring of the And the method consists of monitoring the shutdown status of such control valves. And keeping control valves open at all times during the operation of such systems 2 9. Method according to claim 27 consists of creating diamonds from impacts. In the aforementioned liquid and gas flows 3 0.The method of claim 27 shall consist of the generation of a gas flow that Expanded excess size at high speed from the aforementioned nozzles 3. 1. The method under claim 27 consists of supplying gas to the inlet pipe. Such at a pressure between approximately 29 psia to approximately 60 psia 3. 2. Method for claim 27 consists of supplying liquid to pipes. This means that the pressure ranges between approximately 1 psia to approximately 50 psia 3. 3. The procedure under claim 27 will also consist of mixing the said liquid. With the gas near the front of the second shock wave 3 4. The procedure under claim 27 will also consist of mixing the said liquid. With the gas near the front of the first shockwave 3 5. Method of claim No. 27, where such fluid flows are not separated from 3 such reflective surfaces 6. Method for claim 27 will also consist of avoiding noise from Such a spray hose, which, in addition to noise from high speed gas flow 3 7. Method according to claim 36, where noise from gas flow with Such high speed has a frequency which is not more than about 6 kHz. 3. 8. The method of claim 27 will also consist of creating momentum in Gas flows at such high speed 3 9. Method according to claim 38 where such liquid and gas flows will have Approximately 1,200 feet per minute at a distance of approximately 18 inches from the said hose 4. 0. Method according to claim 38 where such liquid and gas flows will have Approximately 700 feet per minute at a distance of approximately 8 feet from the aforementioned spray hose 4. 1. The method of claim 27 will also consist of forming a flow pattern. From the aforementioned injection pipe with a predetermined angle by specifying the beveled part of the Such reflective surface 4 2. Method for claim 27 consists of adding liquid to the flow. Of the gas at such high speed by using the difference between the pressure in the gas flow with Such high speed with 4 atmospheric pressure 3. Method according to claim 27 consists of mixing the said liquid. With the gas flow at such high speed And turn the liquid into a droplets Which has a diameter of less than 20 micrometers 4 4. Method according to claim 27 consists of the application of an oxygen-free smoke layer. In this high-speed gas flow and carries the smoke layer with the fluid stream. As mentioned of the aforementioned spray hose 4 5. Method of claim 27 consists of emission of inert gas from pipes. Exit 4 6. Method according to claim 27 consists of emission of an inert gas mixture with The chemically active gas is exited from the outlet pipe 4. 7.Method according to claim 46, wherein the gas mixture consists of air 4. 8. Methods for operating a fire extinguishing system whereby the system has a hose consisting of a nozzle with an inlet pipe connected to the compressed gas source and an outlet pipe. For use in fluid exchange A pipe that is connected to the source of the pressurized fluid for use in fluid exchange.The pipe has an outlet hole positioned next to the outlet pipe. Reflecting surfaces are positioned facing the said outlet pipe, with gaps between them. The release of the said fluid from the opening The release of such gas from the outlet pipe, which also causes gas flow. High speed which extends beyond the size of the said nozzle The transfer of the liquid is mixed with the gas to create a liquid-gas stream and the flow of the liquid-gas out of the spray pipe. 9.The method for claim 48 also includes: Induction in front of the first shock wave between the outlet pipe and the reflected surface, causing the second shock wave at the reflection surface, and the transfer of the liquid mixed in the gas near the In front of the shock wave The first and the second one of the aforementioned ball 5 0. The method of claim 48 also consists of the formation of diamonds from multiple shocks in the liquid-gas stream from the hose.