A system for improving a steam oil ratio (SOR) includes a direct steam generator (DSG) boiler fluidly coupled with a downhole portion of a steam system via at least a DSG outlet, wherein the DSG boiler is configured to schedule super-heat delivered to the downhole portion to optimize the SOR associated with the system.

An atmospheric pressure water ion generating device is arranged in a triphase organic matter pyrolysis system which includes a steam generating device and a pyrolysis and carbonization reaction device. The water ion generating device includes a connecting pipe connected with the steam generating device, and having an interior that is penetrated, a heating tube having a first end connected with the connecting pipe and having an interior provided with an air channel, and a spraying head connected with a second end of the heating tube, and having an interior that is tapered. The air channel has a surface provided with an alloy catalyst layer. The spraying head is provided with a nozzle which is connected with the pyrolysis and carbonization reaction device.

Transition castings are disclosed which comprise a steam tube and a water tube, which are joined together by membranes. A heat transfer fin extends from the membrane and abuts the water tube. The steam tube bends such that an upper end is on one side of the water tube, and a lower end is on an opposite side of the water tube. The transition castings are used in a transition section of a boiler in which the furnace is divided into a lower furnace and an upper furnace. The lower furnace uses water-cooled membrane walls, while the upper furnace uses steam-cooled membrane walls that act as superheating surfaces. The transition casting joins the lower furnace and the upper furnace together.

A system includes a heat recovery steam generator (HRSG) having a plurality of evaporator sections. At least one evaporator section includes a forced circulation evaporator configured to generate a saturated steam, a once-through evaporator configured to generate a first superheated steam, and a first superheater configured to receive the saturated steam and the first superheated steam.

A system includes a heat recovery steam generator (HRSG) having a plurality of evaporator sections. At least one evaporator section includes a forced circulation evaporator configured to generate a saturated steam, a once-through evaporator configured to generate a first superheated steam, and a first superheater configured to receive the saturated steam and the first superheated steam.

Provided is a process for producing an automotive glass with a member in a highly efficient and space-saving manner. The process for producing an automotive glass with a member comprises bonding together an adhesion surface of an adherend and an adhesion surface of an automotive glass using an adhesive, and then curing the adhesive using a superheated steam generator, thereby attaching the adherend to the automotive glass; wherein the superheated steam generator comprises (1) a boiler part for generating steam, (2) a superheating unit for superheating the steam generated in the boiler part, and (3) a superheated steam vessel equipped internally with one or more heaters and one or more superheated steam outlets for discharging the superheated steam supplied from the superheating unit; and wherein the step of curing the adhesive is performed by covering the adherend placed on the automotive glass with the superheated steam vessel, spraying the superheated steam from the one or more superheated steam outlets to the adherend, and then spraying dry gas.

A method and a device for generating superheated steam from a working medium, which includes the following steps: feeding of a working medium in the liquid phase to a specific heating tube and temperature regulation of the specific heating tube. Furthermore, the specific heating tube is temperature-regulated with a defined amount of thermal energy, as a result of which superheated steam is formed in the specific heating tube from the working medium fed in the liquid phase, the superheated steam then departing from the specific heating tube.

A process for enhancing boiling to generate steam and superheated-steam by using renewable energy from Concentrated Solar Power. Steam can generate electricity, heating and cooling, sterilization, and other processes and products. The embodiment is made of a light weight small assembly and rotates on the X and Y axis to align with the solar radiation. The assembly has a steam generation unit (28) with Fresnel lenses affixed to concentrate the solar radiation and generate heat. The focal point of the radiation being concentrated is directed to the inner side of a glass tube (30) covered with nanoparticles. The surface area being heated by the solar radiation is increased by the use of nano articles. Water atomization/aerosol unit (60) creates reduced size water droplets that are channeled to glass tube (30) and put into contact with the heated nanoparticles. The atomized/aerosol water droplets help reduce heat dissipation.

A system for improving a steam oil ratio (SOR) includes a direct steam generator (DSG) boiler fluidly coupled with a downhole portion of a steam system via at least a DSG outlet, wherein the DSG boiler is configured to schedule super-heat delivered to the downhole portion to optimize the SOR associated with the system.

The present invention relates to a high-temperature reheater anti-friction device for anti-friction of metal tubes on a heated surface of a high-temperature reheater adjacent to a soot blower, has a hole-type tube clamp arranged on a metal tube of a heated surface of a high-temperature reheater, an anti-friction box and an anti-friction cover. Compared with the prior art, the present invention has the advantages of reduced maintenance workload of the unit and prolonged service life of the metal tube.