TH32619B - The process of liquefying biomaterials by thermal chemical decomposition resulting in energy. - Google Patents

Abstract

Thermal decomposition process for the production of volatile compounds for external burner or liquefaction of solid biomass which characteristics and conditions that were not previously known to be used. Thermal chemical decomposition is carried out. Single-bed fluidization of inert materials operating at near atmospheric pressure, relative low temperature, long gas-solid residence time. and moderate heating rates. The distribution of thermal decomposition products of solids (carbon) and gases under these conditions is characteristic. The resulting effluent can immediately cool each one. to produce large volumes of liquids added to low carbon yields or The volatile outflow is available in each burner. or a second burner to It is produced as the heat energy of the system that provides specific efficiency. In the use of instantaneous refrigeration, the instantaneous cooling liquid has a composition similar to with the so-called The heat dissipation process of the earlier Renaissance Specific conditions will cause High throughput liquids can be produced in a form that is energy efficient. The low state of austerity compared to previous methods makes the process easier to design. and upgrade to better This will lead to lower costs and lower operating costs as they can be easily controlled.

Claims (4)

1. the process for thermal decomposition of biomass. Torn to pieces Consisting of (a) biomass conductivity That tear into small pieces sufficiently to its size Will not limit the production of combustible vapor. Aerosol and significant gases Which will lead into guess A thermal decomposition reactor with a bed of inert material. More than one ratio of height to width (b) Fundamentally upward conduction of non-oxidizing gas through bed (211) at linear speed in order to achieve automatic cleaning and filtering of the produced carbon. And fluidizing Of the bed of an inert material to form a fluidized bed (211) (c) indirectly heated the deep fluidized bed (211), that is, a non-oxidizing gas. Which basically And fluidized bed The temperature in the range 360 to 490 degrees Celsius and gas that does not Oxidizing basically And the deep fluidized bed will cause chemical decomposition due to thermal Of biomass to produce a fluid flow in the reactor Which consists of Hot carbon particles and volatiles, ie aerosols and vapors, and (d) removal of washed and filtered carbon particles from The current flowing in the reactor is flowing out. Where the deep fluidside bed Will be sufficiently deep That is the residency time of the gas that is not. The basic oxidizing time in the reactor (205) is over 2 seconds. 2. Process according to claim 1, where the residual time of the non-oxidizing gas is Dice, which is typically greater than 2 seconds and less than or equal to 25 seconds 3. Process according to claim 1, where a deep fluidized bed (211) Such was heated. By the method of heat transfer between hot gas and deep fluidized bed 4. The process according to claim 1, whereby non-oxidizing gases are fundamentally The temperature is 430 ํ. 5. Process according to claim 1, where the velocity of the non-oxidizing gas is Which is basically through a deep fluidized bed (211) ranged from 10 to 80 centimeters per second. 6. Process according to claim 1, where the deep fluidized bed pressure (211) will be in the range of -100 + 100 kPa. 7. Process according to claim 1, where the mass ratio of the non-oxidizing gas Dice, which is essentially less than 2: 1. 8. Process according to claim 1, where biomass consists of particles with Designation to the minimum, less than or equal to 3 mm 9. Process according to claim 1, where carbon is deposited and in the machine. Producing gas from carbon (301) is at temperatures over 700 ํ C and contains carbon cleaning. Carbon dioxide, water vapor and mixtures of carbon dioxide gas And steam or relative volume Digests air to make carbon gas 1 0. Process according to claim 1, where carbon is deposited and in the machine Producing gas from carbon (301) is at temperatures over 700 ํ C and contains carbon cleaning. Carbon dioxide, water vapor and mixtures of carbon dioxide gas And steam or relative volume 1 1. Process according to claim 1, where the carbon that is deposited in and in the carbon-based converter (301) is at a temperature greater than 700 ° C, for sufficient time to reach a certain temperature. Volume reduction Of carbon by heat annealing 1 2. Process according to the clause 1 consists of adding oxygen or air to the bottom of the deep fluidized bed (211), that is, there is a Biomass entry point 1 3. Process according to claim 1, where the particle size of the material in the deep fluidized bed (211) of the inert material ranges from -20 to +100 mesh (mesh) 1 4.Processes for thermal decomposition of mass A bio that has been torn to shreds To produce a liquid with a composition similar to the liquid produced This is achieved through fast neutron decay, consisting of (a) the conduct of biomass that shredded its size to be small enough to not go away. Limit the production of vapor that can be condensed. Significantly introduced into the reactor of decomposition. Chemistry due to heat (205) with a deep fluidized bed (211) of inert material with the ratio of height For more than one width (b) Conduct of non-oxidizing gas which is fundamentally upward through Deep fluidized bed (211) at linear speed to achieve automatic cleaning and filtration of the produced carbon and fluidizing. Of inert material to form a deep fluidized bed (c) Deep fluidized bed (211) indirect heating, i.e., fundamentally non-oxidizing gas and fluidized bed temperatures in the range 360 to 490. C. And non-oxidizing gas. Basic Dizing and Fluidized Bed This will cause chemical decomposition due to the heat of biomass to produce a flow in a fluid reactor, which consists of Hot carbon particles and volatiles, ie aerosols and vapors, and (d) removal of washed and filtered carbon particles from The current flowing in the reactor is flowing out. (e) Aerosol gasification And the vapor immediately cooled with cold liquid To partially turn the vapor and aerosols into a liquid, that is, the vapor and aerosols do not come into contact with the surface. The coolers are immediately dried (403) where temperatures are in the range of 100 to 360 ํ where the fluidized bed depth (211) is sufficiently deep. Time of residence of non-gas The basic oxidizing process in the reactor (205) is greater than 2 seconds 1 5. The process of claim 14, where the rapidly cooling fluid is Quickly, it is cooled to liquid bio-oil 1 6. Process according to claim 14, where the cold liquid is liquid. Inert 1 7. Process according to claim 14, where the cooling liquid is liquid. The cold that was imminently reacting to such vapor and aerosols when it was condensed. 1 8. Process according to claim 14, where the fundamentally non-oxidizing gas is a fluidized product gas. Which is recycled Which immediately after cooling will be 1 9. Process according to claim 14, where the speed of the non-oxidizing gas Dizing is basically in the range of 10 to 80 centimeters per second. Mass ratio of The gas per biomass is less than 2: 1 and the smallest biomass size is less. Greater than or equal to 3 mm, and where carbon is deposited and placed in a carbon gasifier (301) at temperatures above 700 ° C is sufficient to reduce the volume of carbon by heat annealing. The processes for thermal decomposition of biomass. Which is shredded to produce combustible gases, vapors and aerosols with elements similar to gases, vapors and aerosols produced by fast neutron decomposition processes, consisting of (a) mass conductivity. biological That rips its size to be small enough that it doesn't Significantly limit the production of flammable gas, vapor and aerosol. Into the reactor of the Thermally decomposed (205) with a deep fluidized bed (211) of inert material with the ratio More than one height per width (b) Conduction of the non-oxidizing gas that is fundamentally upward through a deep fluidized bed (211) at linear speed in order to wash and filter the carbon produced by Automatic and The fluidized bed of an inert material to form a deep fluidized bed (C) Indirectly heated fluidized bed (211) is a gas that Does not oxidize Basic and fluidized bed The temperature is in the range 360 to 490 ํ and non Oxidizing which basically And the deep fluidized bed will cause chemical decomposition due to flashover. Hot of bio To produce a fluid flow in the reactor, which consists of Hot carbon particles and volatiles, ie aerosols and vapors, and (d) removal of washed and filtered carbon particles from The current flowing in the reactor is flowing out. (e) Hot gas injection Aerosols and vapor from the reactor enter the system. The second combustion that will be burned to produce heat. Where the fluidized bed is sufficiently deep is the non-gas residue time. The oxidizing effect occurs primarily in the reactor over 2 s 2 1. The process according to claim 20, where the velocity of the non-oxidizing gas is Dice, which is basically in the range of 10 to 80 centimeters per second. Mass ratio of gas to Such biomass is less than 2: 1 and the smallest size of biomass particles is less than or equal to 3 mm, and where carbon is deposited and placed in a carbon fuel converter. At temperatures above 700 ํ in sufficient time to reduce the volume of carbon by heat annealing. 2.Devices for thermal chemical decomposition of mass particles A bio that has been torn to shreds To produce a liquid with a composition similar to the liquid produced It is obtained from fast neutron decay consisting of (a) thermally heated fluidized bed reactors. Of inert material With more than one height to width ratio Gas inlet at the bottom of it for Fundamentally non-oxidizing gas is carried upward through the bed of the inert material to form a Deep fluidized bed Top transfer line Its for removal of the fluid coming out of the substance. Evaporation and carbon deposition pathways for Accumulated carbon from the reactor and (b) a burner for gas burning. And cause a gas from And (c) a heat exchanger connected to the aforementioned deep fluidized bed and to the flue gas heated from the burner for heating Hot follow 2 3. The equipment according to claim 22 consists of (a) a liquid rapid cooling device with a side inlet. On top of it is connected to the above line of transfer And the exit is on the side of it Liquid tank Produced with a coupling inlet to the aforementioned rapid cooling outlet for Accumulates the rapidly cooling liquid in it, the inlet of the coolers strongly Quick, fluid coupled to a production fluid outlet to drive A liquid to cool rapidly and to use it for cooling the evaporative fluid. Fast down From a thermal decomposition reactor and a nearby recycle gas outlet. Bottom of it (b) The recycling line coupled to the recovered gas outlet. Use a new cleaner To receive the gas released from such a rapid cooling machine And lead the gas into the gas inlet of the reactor 2 4. Equipment according to claim 22 consists of a second burner connected to a pair. Against such a transfer line operating with combustible gas, vapor and aerosols from the reactor of the Decomposes chemically due to such heat.