A novel two-chamber design for thermal boilers is presented in this document. The boiler uses spiral-shaped tubes with conical and flat portions which form a combustion chamber. The use of a direct flame burner causes exhaust gas turbulence and increases the gas pressure in the main chamber. The high-pressure gases, which have lost their kinetic energy due to collision with spirals, leave the main chamber and enter into the secondary chamber, where their energy is used to preheat inlet water. The control of distance between spirals, the reverse flow of exhaust gases in the chambers, and the specific geometry of the spirals maximize boiler efficiency,

A novel two-chamber design for thermal boilers is presented in this document. The boiler uses spiral-shaped tubes with conical and flat portions which form a combustion chamber. The use of a direct flame burner causes exhaust gas turbulence and increases the gas pressure in the main chamber. The high-pressure gases, which have lost their kinetic energy due to collision with spirals, leave the main chamber and enter into the secondary chamber, where their energy is used to preheat inlet water. The control of distance between spirals, the reverse flow of exhaust gases in the chambers, and the specific geometry of the spirals maximize boiler efficiency,

A hand held steamer having a housing with an opening for injecting steam into an interior of the housing. A core is positioned in the interior of the housing. The core has holes for receiving the steam into an interior of the core. Spacers center the core within the interior of the housing, thereby forming a chamber in the interior of the housing around an exterior of the core. A device in need of sanitization can be placed in the interior of the core. A source of dry vapor steam is attached to the opening in the housing and the steam is injected into the interior of the housing, around the exterior of the core, and into the interior of the core. The steam sanitizes the surface of the device without damaging the rest of the device, as a result of uniform distribution of steam around the device.

A hand held steamer having a housing with an opening for injecting steam into an interior of the housing. A core is positioned in the interior of the housing. The core has holes for receiving the steam into an interior of the core. Spacers center the core within the interior of the housing, thereby forming a chamber in the interior of the housing around an exterior of the core. A device in need of sanitization can be placed in the interior of the core. A source of dry vapor steam is attached to the opening in the housing and the steam is injected into the interior of the housing, around the exterior of the core, and into the interior of the core. The steam sanitizes the surface of the device without damaging the rest of the device, as a result of uniform distribution of steam around the device.

A hand held steamer having a housing with an opening for injecting steam into an interior of the housing. A core is positioned in the interior of the housing. The core has holes for receiving the steam into an interior of the core. Spacers center the core within the interior of the housing, thereby forming a chamber in the interior of the housing around an exterior of the core. A device in need of sanitization can be placed in the interior of the core. A source of dry vapor steam is attached to the opening in the housing and the steam is injected into the interior of the housing, around the exterior of the core, and into the interior of the core. The steam sanitizes the surface of the device without damaging the rest of the device, as a result of uniform distribution of steam around the device.

A hand held steamer having a housing with an opening for injecting steam into an interior of the housing. A core is positioned in the interior of the housing. The core has holes for receiving the steam into an interior of the core. Spacers center the core within the interior of the housing, thereby forming a chamber in the interior of the housing around an exterior of the core. A device in need of sanitization can be placed in the interior of the core. A source of dry vapor steam is attached to the opening in the housing and the steam is injected into the interior of the housing, around the exterior of the core, and into the interior of the core. The steam sanitizes the surface of the device without damaging the rest of the device, as a result of uniform distribution of steam around the device.

The present invention discloses a saturated water explosive device, including a water intake pipe, a flow splitter for splitting a high-pressure liquid, a flow baffle for baffling the high-pressure liquid, a heat receiver having a cavity defined inside, a pillar connected with the heat receiver by a micro-channel wherein the high-pressure liquid is heated to be high-temperature saturated water, and a heat source for heating the cavity. High-pressure water is heated to produce high-temperature high-pressure saturated water, and then by using the saturated water explosive device of the present invention, the produced high-temperature high-pressure saturated water instantaneously explodes as being heated, and a high-temperature high-pressure steam flow is produced due to rapid vaporization, and expansion and is used as a power source.

The present invention discloses a saturated water explosive device, including a water intake pipe, a flow splitter for splitting a high-pressure liquid, a flow baffle for baffling the high-pressure liquid, a heat receiver having a cavity defined inside, a pillar connected with the heat receiver by a micro-channel wherein the high-pressure liquid is heated to be high-temperature saturated water, and a heat source for heating the cavity. High-pressure water is heated to produce high-temperature high-pressure saturated water, and then by using the saturated water explosive device of the present invention, the produced high-temperature high-pressure saturated water instantaneously explodes as being heated, and a high-temperature high-pressure steam flow is produced due to rapid vaporization, and expansion and is used as a power source.

A steam generating device has a handle and a nozzle or pad attached to the handle for treating a surface. The handle includes a heat exchanger, a water reservoir, a fluid conduit in fluid communication with the water reservoir and heat exchanger, and a fluid delivery system for moving water from the water reservoir, through the fluid conduit, and into the heat exchanger. A fuel powered heater is positioned on a side of the wall of the heat exchanger opposite the interior space of the heat exchanger. A first section of the wall of the heat exchanger transfers heat from the heater to water located in the heat exchanger for generating steam from the water located in the heat exchanger. A second section of the wall of the heat exchanger includes an opening that allows steam to exit the heat exchanger and handle and flow through the nozzle or pad.

A steam generating device has a handle and a nozzle or pad attached to the handle for treating a surface. The handle includes a heat exchanger, a water reservoir, a fluid conduit in fluid communication with the water reservoir and heat exchanger, and a fluid delivery system for moving water from the water reservoir, through the fluid conduit, and into the heat exchanger. A fuel powered heater is positioned on a side of the wall of the heat exchanger opposite the interior space of the heat exchanger. A first section of the wall of the heat exchanger transfers heat from the heater to water located in the heat exchanger for generating steam from the water located in the heat exchanger. A second section of the wall of the heat exchanger includes an opening that allows steam to exit the heat exchanger and handle and flow through the nozzle or pad.