NL1029909C2 - Torrefaction process for treating biomass in order to produce biofuel, carried out at pressure chosen so that liquid water is present in torrefaction reactor - Google Patents

Abstract

The pressure in a torrefaction reactor (2) is chosen so that water in liquid form is present. Treating biomass comprises supplying the biomass to a reactor for torrefaction (i.e. mild pyrolysis) by heating in a low oxygen atmosphere at a pressure chosen so that water in liquid form is present in the reactor. Independent claims are also included for the following: (A) a treatment apparatus for carrying out the above process, the reactor being provided with a pressurized vessel which allows an overpressure to be produced inside it so that torrefaction can be carried out in the presence of liquid water; and (B) producing biofuel with the aid of the above process.

Description

Title: Method and device for treating biomass.

The invention relates to a method for treating biomass, comprising: - providing a torrefaction reactor, in which biomass can be accommodated, - supplying biomass to the torrefaction reactor, - torrifying the biomass in the torrefaction reactor by heating the biomass to a torrefaction temperature in a low-oxygen environment of the torrefaction reactor.

Such a method is known. The environmentally-friendly energy extraction from biomass is receiving increasing attention as a result of the climate problem and the depletion of fossil energy sources. Biomass is present in biodegradable industrial and household waste, such as organic waste and waste paper. Biodegradable products, waste and residues from agriculture and other industries also contain biomass, for example mown grass and prunings.

The generation of sustainable energy through direct co-firing of biomass in power plants is economically attractive. For this, the biomass must be ground or pulverized into small particles, which is often difficult due to the fibrous structure of biomass. For example, tough wood chips can only be milled at high costs.

Torrefaction is a thermochemical pre-treatment method for biomass. Torrefaction can be applied to any biomass. According to the known treatment method, the biomass is heated in a low-oxygen or oxygen-free gaseous environment under atmospheric pressure to a temperature of 200-320 ° C. The lack of oxygen prevents the biomass from burning. Instead, "yarn" of the biomass occurs, giving rise to loss of mass through degassing. Usually the mass loss is around 30%, while the energy value reduces only 10%. The fuel produced by torrefaction therefore has a higher combustion value.

Chemical modifications of the biomass structure also occur during torrefaction. The biomass loses its mechanical strength and resilience, which greatly improves the grindability. In addition, torrified biomass 10299Q9-2 is hydrophobic, so that it remains dry and is insensitive to atmospheric humidity. During storage of the fuel produced by torrefaction, the risk of rotting and forcing is minimal.

Untreated, much biomass is relatively wet. The biomass generally contains unbound and (loosely) bound water. The bound or loose water is present in the natural biomass itself. For example, vegetable biomass, such as prunings and cut grass, naturally contains a significant amount of moisture. The water content of the biomass can moreover be increased by washing out to reduce the salt content of the biomass.

The removal of salts is desirable because salts in the biomass fuel lead more quickly to corrosion in the boiler of the power plant.

These salts also reduce the quality of the ashes produced during combustion of the biomass fuel, which makes reuse of those ashes more difficult.

The water-soluble salts are removable by washing out. In particular, washing out can be applied to biomass of vegetable origin, such as straw. In addition, the biomass is allowed to rain wet prior to harvesting. The salts present in the biomass can therefore at least partially dissolve in the rainwater. i

The rainwater then drains the dissolved salts. However, washing out or an alternative water treatment causes a very wet biomass.

According to the known pre-treatment method, the wet biomass is thermally dried prior to feeding to the torrefaction reactor. This is necessary in connection with the raising of the temperature to the torrefaction temperature of 200-320 ° C. Due to the thermal drying, the water mainly evaporates from the biomass. For example, the dried biomass has a moisture content of 15% or the biomass is 85% dry. However, the evaporation of the moisture from the biomass requires a considerable amount of energy, which adversely affects the efficiency of the entire pre-treatment method. In practice, the energy required for drying is more than twice to five times as high as the energy requirement for torrification. The efficiency is therefore largely determined by the energy required for drying. In practice, wet biomass often proves to be unusable for energy production due to the high dewatering costs. This applies in particular to biomass that is very wet as a result of washing out or an alternative water treatment.

1029909-3

An object of the invention is to provide a method for treating biomass, the efficiency of which is improved.

This object is achieved according to the invention in that the heating of the biomass in the torrefaction reactor is carried out under such a pressure that water is present in the torrefaction reactor in a liquid manner. According to the invention, the "wet" biomass is supplied to the torrefaction reactor without prior drying. The pressure is so high that water in the torrefaction reactor does not substantially evaporate during torrefaction - at the temperature of 200-320 ° C required for torrefaction, water remains substantially liquid. The liquid water forms the heat carrier. After the biomass 10 has been subjected to torrefaction during a residence period in the torrefaction reactor, the temperature or pressure is lowered. During the torrification, the biomass has become hydrophobic due to its chemical changes. If the torrified biomass is subsequently removed from the torrefaction reactor, the torrified biomass will "sweat out". The torrefaction gases produced press the water out of the biomass, causing the biomass to dry. Despite the water environment in the torrefaction reactor, the process of the invention provides a dewatered or dry, torrified biomass fuel.

According to the invention, drying prior to torrefaction is therefore superfluous - the "wet" biomass is fed directly to the torrefaction reactor, in which torrefaction takes place in water. The energy required for the process according to the invention comprises only the energy for applying the pressure in the pressure vessel of the torrefaction reactor as well as the energy for raising the water temperature to the desired torrefaction temperature. In contrast to the known pre-treatment method, energy for evaporating water does not have to be supplied to dry the biomass. The energy saving associated with this is considerable, so that the efficiency of the method according to the invention improves.

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A further advantage of the method according to the invention is that undesired salts in the biomass mainly dissolve during liquid water centrifugation and are subsequently removed during "sweating out". If the biomass fuel produced according to the invention is co-fired, this reduces the risk of corrosion in the combustion plant of the power plant, for example. The removal of salts, such as chlorine, furthermore has a favorable effect on the ash quality, so that the ash produced is suitable for reuse.

According to the invention, the torrefaction temperature, to which the biomass in the torrefaction reactor is heated, will generally be in the range of 200-320 ° C. If the temperature is above 320 ° C, pyrolysis will occur instead of torrefaction.

According to the invention, it is preferable that during the torrification the pressure in the torrefaction reactor is in the range of 20 to 90 bar. At such a pressure in the torrefaction reactor formed as a pressure vessel, water will substantially not evaporate despite the high temperature in the desired torrefaction range of 200-320 ° C. Liquid water remains present in the torrefaction reactor, so that the torrification of the biomass is carried out in liquid water.

According to the invention, the residence time of the biomass in the torrefaction reactor can depend on the requirements for the biomass fuel treated by torrefaction. For example, during torrification, the biomass remains in the torrefaction reactor for at least 30 minutes, preferably at least 60 minutes. In that case, substantially all of the biomass in the torrefaction reactor is sufficiently tumdled, i.e. the biomass fuel produced has favorable properties, for example with regard to grindability and storage.

According to the invention, water can be heated to the torrefaction temperature under such a pressure that the water remains substantially liquid, and wherein the liquid water with the torrefaction temperature is supplied to the torrefaction reactor. It is possible here for the liquid water with the torrefaction temperature to be brought directly into contact with the biomass supplied to the torrefaction reactor for heating said biomass to the torrefaction temperature.

This makes heating the biomass to the desired torrefaction temperature in liquid water simple.

In a preferred embodiment of the method according to the invention, the biomass is allowed to cool to a temperature of less than 100 ° C, preferably to room temperature, after torrification of the biomass. Preferably, the cooling of the biomass is carried out in a cooling unit, wherein water flows through the cooling unit as cooling medium to cool the torrified biomass, and wherein the water heated by the biomass is supplied to the torrefaction reactor. As a result, the heat energy of the water, apart from losses, is retained for heating the water to the torrefaction temperature. M.a.w. the energy for raising the water temperature to the desired torrefaction temperature can largely be recovered. This is favorable for the efficiency of the method according to the invention.

! Also according to the invention the pressure will generally be reduced to atmospheric pressure after torrification of the biomass. Preferably, the lowering of the pressure is carried out after the lowering of the temperature. During torrification, decomposition reactions occur that make the biomass hydrophobic. After lowering the temperature and pressure to atmospheric conditions, the torrefaction gases produced expel the water from the hydrophobic biomass. This "exudation" of the biomass provides a dewatered or dry biomass fuel.

Lowering the temperature of the biomass and / or the ambient pressure around the biomass can take place in the torrefaction reactor itself or in separate devices. It is possible, for example, for the pressure to be lowered to be carried out in an expansion vessel, and torrefaction gases and moisture are produced during the pressure release in the expansion vessel. In that case the torrefaction gases can be supplied to a combustion unit, in which the torrefaction gases are burned to hot flue gases, and wherein the hot flue gases are supplied to a heat exchanger for heating the water to be supplied to the torrefaction reactor. This optimally uses the energy of the torrefaction gases.

In a special embodiment of the method according to the invention, the water discharged from the torrefaction reactor and the water discharged from the expansion vessel are combined in a purification device for removing contaminants, such as inorganic components. The use of the purification device, however, depends on the concentrations of contaminating components in the supplied biomass.

The invention also relates to a device for treating biomass, comprising a torrefaction reactor for receiving biomass, an inlet for supplying biomass to the torrefaction reactor, an outlet for discharging biomass to the torrefaction reactor, which device is provided of heating means for heating the biomass, as well as means for providing a low-oxygen environment in the torrefaction reactor. According to the invention, the torrefaction reactor is provided with a pressure vessel in which such an overpressure is prevalent that torrefaction can be carried out in the pressure vessel in the presence of liquid water. The pressure vessel is preferably resistant to a pressure of 20-90 bar.

The invention will now be further elucidated with reference to an exemplary embodiment shown in the drawing.

Figure 1 shows a schematic process diagram of the method according to the invention.

The method according to the invention is essentially applicable for all biomass fuels. In particular, the method according to the invention is suitable for (too) wet biomass, such as reed pests, sewage sludge or GFT waste and for biomass with a relatively large amount of alkali metals and chlorine, such as grass. j

In Figure 1, the apparatus for treating biomass is indicated in its entirety by 1. In this exemplary embodiment, the apparatus for treating biomass 1 comprises a torrefaction reactor 2, which according to the invention is formed as: 15 a pressure vessel, as well as a cooling unit 3 and an expansion vessel 4. j

The torrefaction reactor 2 designed as a pressure vessel has an inlet 6 for supplying biomass and an outlet 7 for discharging torrified biomass. The pressure vessel 2 further has a water inlet 9 for supplying liquid water which has been heated under pressure to a set torrefaction temperature. The torrefaction temperature set is between 200-320 ° C. The pressure of the hot water is so high that the water remains substantially liquid. The minimum pressure in the water supply 9, at which the water has not yet evaporated, depends on the set torrefaction temperature. In connection with the torrefaction temperature between 200-320 ° C, this pressure will be in the range of 20-90 bar.

Substantially the same overpressure will prevail in the torrefaction reactor 2. In the torrefaction reactor 2, the supplied biomass is brought into contact with the (very) hot, liquid water. The water therefore heats the biomass to the set torrefaction temperature. The torrefaction reactor 2 further determines a low-oxygen or oxygen-free space, so that the biomass is subjected to torrefaction. Torrification changes the chemical structure of the biomass such that the biomass becomes hydrophobic. At the same time, the heat exchange with the biomass to be heated in the torrefaction reactor 2 will cool the hot water, for example to below 50 ° C.

1029909-7 i

As a result of the contact of the (very) hot, liquid water with the biomass, dehydration also occurs, i.e. the water absorbs salts present in the biomass, such as potassium and chlorine. The water cooled by heat exchange, in which the undesired salts have been dissolved, then leaves the torrefaction reactor 2 via a water discharge 10. According to the invention, the salts are thus removed from the biomass by washing out in the torrefaction reactor 2. The removal of such salts is important because these salts adversely affect the quality of the ashes after burning the biomass. If the salts have been removed, improved reuse of the ashes is possible.

The outlet 7 of the torrefaction reactor 2 is connected to the cooling unit 3. The same overpressure prevails in the cooling unit 3 as in the torrefaction reactor 2. In this exemplary embodiment, the cooling unit 3 is designed as a pressure vessel. The torrified biomass discharged from the torrefaction reactor 2 enters the cooling unit 3 via the outlet 7. The cooling unit 3 has a coolant inlet 13 for supplying a coolant 15 to the cooling unit 3 and a coolant outlet 14 for discharging that coolant from the cooling unit 3. The coolant is, for example, water. This water flows through the cooling unit 3 in heat-exchanging contact with the torrified biomass. The torrified biomass cools down, while the temperature of the water rises. The cooling unit 3 therefore forms a heat exchanger. The cooling unit 3 cools the torrified biomass in this exemplary embodiment to a temperature lower than 70 ° C, preferably to a temperature lower than 50 ° C or 30 ° C.

The water discharged via the coolant outlet 14, which has been slightly heated by heat exchange with the hot biomass, is connected via a heat exchanger or boiler 20 to the water inlet 9 of the torrefaction reactor 2. The energy of the heated water from the cooling unit 3 thereby becomes useful which increases the efficiency of the pretreatment method according to the invention. The cooling unit 3 further comprises a drain 11 for discharging the cooled torrified biomass. This outlet 11 is connected to the expansion vessel 4.

In the expansion tank 4, the cooled torrified biomass can expand until the atmospheric pressure is reached. While the pressure drops from 20-90 bar excess pressure to atmospheric pressure, the torrefaction gases released squeeze the water from the particles of the biomass, which is hydrophobic due to the torrefaction. The expulsion of the water from the biomass can be referred to as "exudation" of the biomass. This results in a dry biomass fuel, which is removable from the expansion tank 4 via a fuel outlet 17 for discharging the dry biomass fuel. This biomass fuel treated according to the invention is excellently grindable, has a relatively high energy density and is suitable for long-term storage.

The expansion vessel 4 further has a water outlet 16 for discharging the water produced during the "sweating out". The "sweating out" forms a further washing out of the biomass. By draining this water, the salt content of the biomass fuel continues to fall. According to the invention, the water-soluble salts containing the biomass supplied at 6 are largely removed from the produced biomass fuel.

The water discharged from the water outlet 10 and the water discharged from the water outlet 16 are combined in a purification device 30 for removing contaminants, such as inorganic components. The purified water leaves the purification device 30 via the water pipe 31. This purified water is preferably suitable for discharge at sea. After all, this water mainly contains salts that are not harmful to the marine environment. In particular, only substantially chloride, sulfate, potassium and sodium are dissolved in this water.

The expansion vessel 4 also has a gas outlet 15 for discharging the released torrefaction gases. The torrefaction gases released still have a considerable amount of energy. The gas outlet 15 is connected to a combustion unit 25, which comprises an air inlet 26 for supplying air. The combustion unit 25 produces hot flue gases by burning the torrefaction gases. The hot flue gases flow via a line 27 to the heat exchanger 20 for heating the water to the torrefaction temperature. The energy of the torrefaction gases is therefore used effectively.

The invention is of course not limited to the exemplary embodiment shown in the drawing. The person skilled in the art can, for example, make various modifications on the basis of already known processes that are within the scope of the invention.

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Claims (16)

A method for treating biomass, comprising: - providing a torrefaction reactor (2), in which biomass can be accommodated, 5. supplying biomass to the torrefaction reactor (2), - torrifying the biomass in the torrefaction reactor (2) by heating the biomass to a torrefaction temperature in a low-oxygen environment of the torrefaction reactor (2), characterized in that the heating of the biomass in the torrefaction reactor (2) is carried out under such a pressure that liquid water in the torrefaction reactor (2) is present. A method according to claim 1, wherein the torrefaction temperature, to which the biomass in the torrefaction reactor (2) is heated, is in the range 200-320 ° C. 15 The process according to claim 1 or 2, wherein during the torrification the pressure in the torrefaction reactor is in the range of 20 to 90 bar. 4. A method according to any one of the preceding claims, wherein during the torrification the biomass remains in the torrefaction reactor for at least 30 minutes, preferably at least 60 minutes. 5. A method according to any one of the preceding claims, wherein water is heated to the torrefaction temperature under such a pressure that the water remains substantially liquid, and wherein the liquid water with the torrefaction temperature is supplied to the torrefaction reactor (2). 6. Process according to claim 5, wherein the biomass supplied to the torrefaction reactor (2) is mixed with the liquid water to form a slurry, and wherein said slurry is supplied to the torrefaction reactor (2). > 029909- Method according to claim 5 or 6, wherein the liquid water with the torrefaction temperature is directly brought into contact with the biomass supplied to the torrefaction reactor (2) for heating said biomass to the torrefaction temperature. A method according to any one of the preceding claims, wherein after the biomass torrification, the biomass is cooled to a temperature of less than 100 ° C, preferably to room temperature. 9. Method as claimed in any of the foregoing claims, wherein cooling of the biomass is carried out in a cooling unit (3), wherein water flows as cooling agent through the cooling unit (3) for cooling the biomass, and wherein the biomass heated up by the biomass water is supplied to the torrefaction reactor (2). 10. A method according to any one of the preceding claims, wherein after the torrification of the biomass the pressure is reduced to atmospheric pressure. ; i | A method according to claim 10, wherein the pressure reduction is performed in an expansion vessel (4), and wherein torrefaction gases and moisture are produced during the pressure decrease in the expansion vessel (4). 20 The method of claim 11, wherein the torrefaction gases are fed to a combustion unit (25), wherein the torrefaction gases are burned to hot flue gases, and wherein the hot flue gases are fed to a heat exchanger (20) for heating it to the torrefaction reactor ( 2) water to be supplied. A method according to any of claims 10-12 as far as dependent on claim 7 or 8, wherein the lowering of the pressure is performed after the lowering of the temperature. 30 | A method according to any one of the preceding claims, wherein the water discharged from the torrefaction reactor (2) and the water discharged from the expansion vessel (4) are combined in a purification device (30) for removing contaminants. 15. Device for treating biomass, comprising a torrefaction reactor for receiving biomass, an inlet for supplying biomass to the torrefaction reactor, an outlet for discharging biomass to the torrefaction reactor, which device is provided with heating means for heating of the biomass, as well as means for providing a low-oxygen environment in the torrefaction reactor, characterized in that the torrefaction reactor is provided with a pressure vessel in which such an overpressure is prevalent that torrefaction can be carried out in the pressure vessel in the presence of liquid water . A method for manufacturing a biomass fuel, comprising a method for treating biomass according to any of claims 1-14. 15 f079909-