A system for recovery of thermal energy from a first closed cooling loop for cooling skid pipes is provided. The first closed cooling loop comprising a circulation fluid receiving thermal energy from said skid pipes, and a cooling source. The system being capable of measuring the temperature in said first closed cooling loop converting thermal energy into electricity. The system further including a flow control system arranged to control input of thermal energy into a power conversion module, wherein said flow control system is arranged to cut off said cooling source from said first closed cooling loop when the measured temperature is below a first predetermined threshold temperature (TsTART), such that said circulation fluid is directed to a hot side of said power conversion module only, to provide a thermal energy input into said power conversion module.

No new matter is added.

An improved apparatus for producing steel, including a lower furnace, an annular, water-cooled, fireproof lined cylindrical upper furnace, on which an upwardly closing conically tapering hat having openings can be placed. The smelting assembly is configured for the operational mode without melt flow and the operational mode with melt flow. To this end, at least one opening is provided in the conical furnace cover, through which opening at least one top lance can be introduced into the upper furnace. A plurality of sidewall injectors radially rotate around the cylindrical upper furnace in such a way that in a working position, the top lance and the sidewall injectors are directed onto a smelt level of a molten mass located in the lower furnace for refining.

The present invention provides a melting furnace capable of suppressing oxidation of molten materials and improving the quality of the molten materials. As shown in FIG. 3, a melting furnace 1 includes a melting portion 2 to which a metal material is supplied; a burner 4 for melting the metal material in the melting portion 2 into a molten material; a heating portion 5 that receives the molten material from the melting portion 2 to raise the temperature of the molten material; a temperature regulating portion 6 that receives the molten material from the heating portion 5 and stores the molten material; a separator 7 that separates the heating portion 5 and the temperature regulating portion 6, wherein the lower portion 70 of the separator 7 is immersed in the molten material to form, below the separator 7, an inlet 71 that allows the introduction of the molten material from the heating portion 5 into the temperature regulating portion 6; an immersion heater 10 wherein at least part of the immersion heater 10 is immersed in the molten material in the temperature regulating portion 6 to thereby heat the molten material; and a gas introduction path 72 that is formed in the separator 7, and that introduces combustion gas from the burner 4 into a space above the molten material in the temperature regulating portion 6; wherein the burner 4 is controlled so that the combustion gas has an oxygen concentration of 5% or less.

To provide a method with which it is possible to ascertain a gas concentration in a furnace rapidly, and to charge an amount of fuel and/or oxygen corresponding to the state within the furnace, and with which it is possible to reduce the device maintenance load. In order to solve the abovementioned problem, this method for analyzing components contained in flue exhaust gas of a furnace includes: a sampling step of collecting a portion of the flue exhaust gas from a flue; a dust removal step of using a centrifugal dust collecting device to separate out dust in the flue exhaust gas collected in the sampling step, to yield an analysis gas; a measuring step of measuring components in the analysis gas to obtain the concentration of carbon monoxide in the analysis gas; and an analysis gas discharging step of causing the analysis gas to be sucked by an ejector.

This disclosure provides a method of recycling heat during operation of a plant in which equipment for processing at least two different materials is co-located. The method comprises a first process for processing a first material and a second process for processing a second material. The second material has a melting point that is less than a melting point of the first material. During the first process, the first material is subjected to a first melting process and then subjected to a first cooling process that includes solidification of the first material. During the second process, the second material is subjected to a second melting process and then subjected to a second cooling process that includes solidification of the second material. The method comprises recovering heat from the first cooling process and using at least some of the heat as a heat source for the second melting process.

To preheat combustion air with gasification furnace flue gas, combustion air is flowed towards an inlet of a gasification furnace. The combustion air is heated using flue gas emitted from the gasification furnace. The flue gas is generated within the gasification furnace responsive to a gasification process. The heated combustion air is flowed into the inlet of the gasification furnace. The gasification process is implemented within the gasification furnace using the heated combustion air

A process and apparatus for drying materials inside a kiln that sends heat produced from a wood burning furnace through an air-to-air heat exchanger to separate the dirty particles from the wood burning process, after which the clean hot air enters the kiln to dry the materials.

A gasification reactor is provided. The reactor comprises a first gasification area, a second gasification area and a shared combustion area. The shared combustion area is set between the first and second gasification areas. Therein, the (present invention applies interconnected fluidized beds in gasification. The connecting piping between the first and second gasification areas are separately replaced with dense beds to be integrated for forming a single reactor. Thus, the present invention simplifies the system, saves the cost and reduces the operation difficulty.

The invention provides device for diversion of quenching exhaust gas and diversion method, exhaust gas chamber is located at top of quenching chamber; quenching chamber is fixedly connected to exhaust gas chamber through partition; support plate in lifting assembly is fixedly connected to side of partition, motor in exhaust assembly is fixedly connected to slider in lifting assembly, two adjacent sides of quenching chamber are fixedly connected to lower surface of support plate through triangular support frame; sealing brushes are located on two adjacent sides of exhaust chamber, gas detector is located inside exhaust chamber on one side near the top, exhaust cylinder is located at center of upper surface of top of exhaust chamber, first end of slider support column and motor support seat are respectively located on upper surface of support plate, second end is fixedly connected with lower surface of baffle through cylindrical hole of slider.

The present application provides a temperature control device for fluids, which comprises a furnace, a fluid pipe, a plurality of regenerative members, a burner, and an air control device. The burner heats the furnace to store heat to the regenerative members inside the furnace and conduct the thermal energy to the fluid pipe. The fluid pipi outputs a heated liquid. In addition, the regenerative members further produce and transport heated air to the air control device. The air control device converts the heated air to output cooled air.