FI125974B - Method and system for treating biomass-containing material - Google Patents

Description

The present invention relates to a method and system for treating material containing biomass

The invention relates to a method and system for treating material containing biomass.

Background of the Invention

The use of biomass in various refineries, such as biofuel or boiler fuel, is a growing trend. For example, peat or other reasonably easy-to-process biomass is typically used in further processing plants. In order to recover wood that may otherwise be degraded in forests, such as stumps and felling waste, so-called "lumber" has also been favored in further processing. energy wood, which has proven to be more difficult to use than previously used materials.

Stumps and other energy wood often also contain material that is problematic in terms of material handling, such as rocks of different sizes, sand and clay, which can cause various problems in further processing plants. Stones, sand, clays and similar non-combustible material may be carried along with stumps and other combustible energy wood as a loose material and, for example, stones may also be partially or wholly contained within the stump. These problematic materials also directly reduce the production efficiency, such as in combustion boilers, as non-combustible materials, they reduce the combustion efficiency.

The prior art use of energy wood as a fuel for a combustion boiler has mainly functioned by leading the energy wood to the combustion boiler. However, a typical processing plant will withstand rather large stones. For example, combustion boilers typically exhibit particularly harmful problems when non-combustible material clogs the grate or similar structures and ash removal devices. Prior art attempts have been made to avoid these problems by crushing energy wood and the large rocks that accompany it before the processing plant. In this way, too, the effect of non-combustible materials such as rocks, clays or sand on production efficiency cannot be sufficiently reduced. In addition, large stones may break down said crusher or increase its maintenance.

Another problem with using biomass as an energy source for a refinery is that the dry matter content of the biomass supplied to the refinery may at times be so low that it is no longer profitable to use said biomass. For example, using particularly moist energy wood as fuel is generally not viable, especially in combustion boilers.

FI111097B1 discloses a biofuel drying process of at least two stages to produce a fuel of uniform moisture content. Humidity is measured as a continuous process from the biofuel flow. Based on the measurement results, the following heat source is selected and adjusted.

There is currently no proper quality management system in place for the supply of energy wood biomass which could encourage biomass suppliers to bring the highest quality material for further processing. In contrast, the current system, which typically pays biomass directly based on the total weight of the load, does not take into account the particular weight of non-combustible or otherwise unsuitable material such as wet wood or rocks.

To perform quality control in the laboratory, a small sample is often analyzed and should represent the load received for handling or crushing. However, such an analysis rarely actually describes the quality of the load, inter alia because it is virtually impossible to take a representative sample of the load containing, for example, large strains and parts of the stump that would represent the quality of the load as a whole. In addition, analyzing such a sample usually takes at least a day and requires additional work. Because of these factors, the standard of quality control in the prior art is typically quite poor.

In practice, the prior art approach may lead to a situation where the further use of biomass, in particular energy wood, for example as fuel for boilers or for biofuel production, may not be cost-effective or even profitable.

There would thus be a need in the industry for a solution to the above problem so that the quality of the biomass supplied could be monitored more effectively than previously known.

BRIEF SUMMARY OF THE INVENTION The object of the present invention is to solve the above problem so that the monitoring of the quality of biomass can be carried out more efficiently. An advantageous embodiment of the invention is intended to solve the problem so that the quality of the biomass supplied can provide quality feedback to the biomass supplier. According to a preferred embodiment of the invention, monitoring biomass quality could determine the price of biomass per load so that the price of good quality biomass would be higher than the price of poor quality biomass.

A process for treating biomass-containing material according to the invention is set forth in claim 1. The system for treating biomass-containing material according to the invention is set forth in claim 13.

The quality of the biomass supplied in the solution described above can be monitored more effectively than previously known. Quality feedback can also provide a more accurate estimate of the reward for the material delivered and encourage the quality of the material delivered.

The biomass supplied in the system as disclosed is treated as needed for further biomass treatment, such as the use of biomass in the production of biofuel or as a boiler fuel. In the system, the material is also analyzed so that the properties of the material can be determined e.g. for determining the energy content of the material and / or for quality control.

Description of the drawings

The invention will now be explained in more detail with reference to the accompanying drawing, in which Figure 1 shows a system for receiving biomass and determining energy content according to an embodiment.

DETAILED DESCRIPTION OF THE INVENTION For the purposes of this application, the term "non-combustible material" means any non-combustible material, such as metal, demolition waste (e.g. concrete or asphalt) and mineral soil (e.g. rock, sand, gravel and clay). Of these, rocks are usually particularly problematic. decompose equipment, as well as clay, which binds water to the material. Metal, too, can cause problems with both the crusher and further processing if not identified and removed from the incoming material.

For the purposes of this application, the term "biomass" means any material of biological origin suitable for use in the production of biofuel or as a boiler fuel. Biomass is typically virgin material or waste material from plants such as trees or grasses. In particular, biomass comprises wood-based materials. forest fuel. Forest fuels include, for example, wood, bark, wood chips, logging residue from thinning or clearing, stumps, twigs and twigs. In this application, instead of the term "forest fuel", the term "energy wood" is used, which both mean the same thing in this application.

In the context of this application, the term "supplied material" refers to material containing at least part of the biomass.

The term "higher calorific value" means the calorific value of the material at 100% solids. For the purposes of this application, the term "lower calorific value" means the calorific value of the biomass delivered at the moisture content to which the biomass is delivered. The term "calorific value", as used herein, means the higher calorific value unless otherwise stated.

In order to modify the material to the desired particle size and composition, mechanical treatment of the material supplied is used, with particular reference to the crusher or chipper used to produce the crushed or chipped material. One or more conveyors or portions of the conveyor which are located prior to the aforementioned mechanical treatment leading to material directly or indirectly to mechanical treatment are referred to herein as first conveyor 3. One or more conveyors or portions of the conveyor which are located after said mechanical treatment to conduct material away from mechanical treatment, for example to a further processing plant, is referred to in this application as a second conveyor. Em. the conveyors, or at least some of them, may be, for example, a belt conveyor.

The energy wood loads supplied contain not only energy wood but also harmful non-combustible material. For example, carrier loads, i.e. loads comprising stumps, typically include rocks of different sizes, which can occur both loose rocks and possibly rocks within the stumps. In turn, non-combustible material comes to the logging residue, especially because logging residue is typically stored on the roadside to wait for transportation. In this case, the lower layers of the energy wood store are in contact with the soil. In addition, it is possible for stones to be placed on top of the pile containing logging residues. In this case, these weighted stones may end up shipped with the energy wood.

Figure 1 shows a preferred exemplary system for receiving and processing material, including determining the energy content of the material. The figure shows the delivered material 1, the delivered material store 2, the first conveyor 3, the measuring and measuring devices 4, 14, 15 and 16 including one or more of: non-combustible material size detection 4, non-combustible material measurement 16, combustible material quantity measurement 15, The system further comprises a mechanical treatment apparatus 5, a first wreck 6, a second conveyor 7, measuring and measuring devices 8, 17, 18, 19 including one or more of: non-combustible material measurement 8, combustible material measurement 17, a combustible material particle size identification 18, a non-combustible material particle size identification 19, a moisture content measurement 13, and a second wreck 11 and a finished crushed or chipped 10 or other by-product. Figure 1 also shows a further processing plant 9 and wet material drying 12. The system also has an intermediate storage 20 of treated material, if required.

The system, or subsystem thereof, may be located away from, or in the vicinity of, a processing plant so that material is transported to the system and the transfer distance to further processing is short. The system may be permanently in place, but it may also apply to mobile systems that operate near the point where the material is obtained. Thus, it is also possible to apply, for example, mobile crushing or chopping systems containing the aforementioned measurements and conveyors or to which these measuring devices and conveyors can be connected.

Depending on the nature and type of the material 1 supplied and also on the needs of the further processing plant 9, the delivered material 1 may be guided either to the delivered material storage 2 or to the first conveyor 3 or even directly to the second conveyor 7. There may be one or more repositories of supplied material 2 in the system and each repository of supplied material 2 may be either a short-term interim storage or a longer-term storage. It may also be possible that the delivered material 1 is always unloaded directly in connection with the conveyor so that there are no stores of the supplied material 2 in the system.

The delivered material 1 may be unloaded directly in connection with the second conveyor 7, for example if the supplied material load does not contain material which would require mechanical treatment 5 to ensure cost-effectiveness or operation of the further processing plant 5. Such material conveyed directly to the second conveyor 7 peat.

Material is delivered to the system, eg by trucks or trains. The material load delivered must be weighed before use. The load can be weighed, for example, in connection with the delivery of the material, by weighing the weight of the vehicle carrying the material load, both with and without load. Alternatively or additionally, means for measuring the weight of the load can be provided either in a separate space or, for example, in connection with one or more conveyors 3, 7 of the material.

In a preferred embodiment, the material is conveyed by conveyors in a continuous stream, for example, past measuring equipment, and the necessary measurements are made continuously and targeting the by-pass biomass. The conveyor feeds material into, for example, a crusher or chipper and out of mechanical treatment. Wrecks 6 and 11 may also be formed by conveyors and / or warehouses.

According to one embodiment, the particle size and / or amount of non-combustible material delivered on the first conveyor 3, e.g. rocks, is measured prior to mechanical treatment 5. Preferably at least the particle size of the non-combustible material is identified to identify large rocks and similar large bodies. crusher or chipper. Preferably, in order to identify all or almost all of the harmful stones, the non-combustible material identification 4 prior to mechanical treatment 5 must be substantially continuous. Measurement 4 for identifying non-combustible material is particularly necessary when using stumps or other similar energy wood, typically containing rock material, in a further processing plant 9. In addition to stones, in some cases it may be necessary to measure the amount of metal and / or the size of the metal supplied with the material 1 before mechanical treatment 5.

Measurements 4 for detecting non-combustible material allow for reacting to harmful objects in such a way that the load on the mechanical treatment device, such as a crusher or chopper, can be reduced, while the need for maintenance is reduced. This can be done, for example, by directing the detected harmful objects, e.g., a stream of material containing stones from the first conveyor 3 to the first wreck 6, whereby said stones do not end up in mechanical treatment 5. This can be done for material containing stones larger than the set size (ie a predetermined other songs. Alternatively, the mechanical treatment 5 may be stopped for the time that the malicious bodies override the mechanical treatment 5. In this way, unsuitable material may be removed from the system, e.g.

According to a preferred example, the quality of the material supplied is measured in addition to or instead of non-combustible material measurements. For example, by measuring the size of the combustible material, it may be possible to detect e.g. the size of the stumps, for example the actual piece size and / or the dispersion size of the pre-crushed stumps. This is useful, for example, when the size of the combustible material may influence the pricing of the material supplied, typically particularly for strains. For non-strains, it is often useful to measure the size of the combustible material, since the size of the material delivered to the downstream processing plant typically has an impact on the operation of the plant, for example, by uniformity in quality of material delivered.

According to one example, the size of the combustible material of the supplied biomass 1 on the first conveyor 3 is measured by a measuring apparatus 14 prior to mechanical treatment 5. Hereby the settings of the crusher or chopper can be adjusted according to the size so that the combustible material after mechanical treatment 5 is as uniform as possible. Apart from the large particle sizes, it is also good to detect very small particle sizes before mechanical treatment 5, since too fine material can interfere with the functioning of the system.

Alternatively, or additionally, the particle size of the combustible material measured prior to mechanical treatment may be used in the quality management system to tell the material size of the material delivered to the material supplier. In addition, this information can be used as one of the parameters affecting the cost of the delivered load.

According to one example, the material size 1 supplied also measures the size of the combustible material after the mechanical treatment 5, preferably in connection with the second conveyor 7. Here, not only the lump size of the treated material but also the actual lump size of the material passed through the treatment can be observed. This particle size has an effect, for example, on the use of material in the production of biofuel or as fuel for a boiler and can be used as a single control parameter.

According to a preferred example, the particle size of the non-combustible material is measured both before and after mechanical treatment. In this case, one can e.g. effectively adjust the operation of eg a crusher or chopper and / or detect any maintenance needed. This allows the equipment to be serviced more optimally at regular intervals, so that it is not necessary to shut down the equipment for maintenance as often as is known in the art, but the equipment can be serviced whenever performance begins to deteriorate. This also improves the predictability of the operation of the mechanical treatment equipment.

Apart from the particle size, the amount of combustible material can also be measured before and after mechanical treatment 5.

According to one example, the material 1 supplied is preferably subjected to moisture conveyance measurement 13, combustible material particle size measurement 18, combustible material volume measurement 17, non-combustible material particle size measurement 19, or non-combustible material quantity measurement 8 in connection with the second conveyor 7. Measurements 8, 13, 17, 18 or 19 may be performed on the delivered material 1 in connection with the second conveyor 7, regardless of whether the supplied material 1 is passed through mechanical treatment 5 or whether the supplied material 1 is fed directly to the second conveyor 7. Preferably, these measurements 8, 13, 17, 18 and 19 are made at least for the energy wood supplied to the refinery, and often these measurements are made for all material 1 supplied.

It is advantageous to measure the moisture content 13 of the supplied material 1 only at the above step in connection with the second conveyor 7, since moisture measurements are typically most reliable in measuring moisture from a small fraction. According to moisture content measurements 13, too wet material, such as too wet energy wood, can be diverted to, for example, drying 12 of wet material or to another wreck 11. It is not necessary to burn too wet material, since the incineration costs of such material are generally higher than the economic benefits of incineration. In some cases, drying the material may also be unprofitable. Such particularly wet material is typically, for example, branches of trees left in the forest for an extended period of time.

It is often necessary to measure the amount of non-combustible material at this stage with the second conveyor 7, whether the amount of non-combustible material has already been measured before mechanical treatment 5 or whether the delivered material 1 is led directly to the second conveyor 7. By measuring the amount of non-combustible material 8 in connection with the second conveyor 7, it is possible to determine which part of the delivered material 1 is non-combustible and thereby determine the dry value of the dry matter of the delivered material 1. In this case, poor quality material containing a particularly high amount of non-combustible material, the incineration of which is not economically viable, may be diverted to, for example, another wreck 11 or, for example, a by-product.

According to a preferred example, the moisture content measurements 13 and the amount of non-combustible material 8 or the amount of combustible material 17 of the supplied material 1 are used to form the moisture value and the dry mass quality value of the delivered material 1. The moisture value can be, for example, the dry matter content of the material from moisture content measurement 13, for example as a percentage. The dry matter quality value can be used, for example, as a percentage of the total amount of biomass supplied, for example, as a percentage of the amount of combustible material obtained from non-combustible material. The quality value can also be, for example, classical, whereby material meeting predefined thresholds is always classified in a particular quality class.

By combining the moisture value with the dry matter quality value and combining both of these with the weight of the material delivered, essentially real-time energy content for the whole material can be obtained as feedback data. The energy content can thus be determined separately for each material load supplied to the system. The dry matter quality value of the material preferably takes into account not only the proportion of non-combustible and / or combustible material observed after mechanical treatment but also the amount of combustible and / or non-combustible material introduced into the first wreck 6 prior to mechanical treatment.

One or more of the measurement data obtained from the measurements described above is stored in a computer system 21 where the measurement data can be processed and combined into reports, for example a report with quality feedback 22. The computer system also serves the other system and control shown in FIG. According to another example, the measurement data is further transmitted to a separate computer system 23 where the measurement data can be processed and combined into reports, for example a report with quality feedback 24. The quality feedback system including computer system 21 and / or computer system 23 may also be physically separate from other system utilizing telecommunication connections. In this case, the measurement feedback and other collected information about the material load or material is transmitted to the quality feedback system so that a report can be provided to the material supplier. Report 22 is, for example, load-specific quality feedback, and report 24 includes, for example, quality feedback values based on computation algorithms, formulas, or results obtained by combining measurement results. The computer system may be, for example, a computer related to the mechanical processing equipment, to which also the measurement data obtained from the measuring devices and also other information, such as material load identification data, are transmitted.

According to an exemplary embodiment, material, preferably energy wood, is conveyed by a conveyor, such as a car or train, to a unloading conveyor to which material 1 supplied is either completely or in appropriate batches unloaded from said conveyor. The unloading conveyor may then transfer the load, for example, to either the first conveyor 3, the second conveyor 7, or to the warehouse 2 of the material delivered. The material 1 supplied may be transported either manually or automated. Material delivered by means of transport may also be temporarily stored in the system and fed to the system.

In one particular example, a solution is applied in which the material 1 supplied is automatically identified. In some cases, when using the supplied material store 2, in particular if there is more than one load of material 1 in the same delivered material store 2, it may be desirable to add a sufficient number of identifiable units to each delivered material load. The identification unit may be, for example, a microchip containing the cargo identification information, such as a Radio Frequency Identifier (RFID) or a similar solution. By using microchips or other identifiable units, the source of the supplied material 1 can be identified at a relatively low cost, even though the supplied material load would for some time stand in the same material store 2 with several other supplied material loads.

According to a preferred example, the system comprises one or more of the following sub-steps, either partially or totally: 1. Initial steps: weighing the material 1 delivered and determining the weight of the load, gross, for example by weighing the conveyor with and without load; from a separate scales or scales attached to at least one conveyor, record the gross and / or net weight of the load, identify the load, possibly automatically, e.g. by means of ID, possibly add concrete identification to the load, e.g. one or more units containing credentials.

2. Storing and transferring the delivered material 1 to the conveyor 3 or 7: the load is led to the delivered material warehouse 2, or the load is directed to the first conveyor 3 or second conveyor 7 from the warehouse or directly from the load, the load conveyed to the conveyor is identified.

3. Prior to mechanical treatment: detection of non-combustible material 4: detection of rock size, or particularly large amount of non-combustible material, or metal detection, prevention of breakage of mechanical treatment 5 equipment by measurement of non-combustible material, when measurements exceed pre-defined limits: a part of the material containing the bodies exceeding the limit is led to the first wreck 6, or mechanical treatment 5 is stopped while removing the material above the limit, or mechanical treatment 5 is stopped and the material above the limit is guided past mechanical treatment, 5, Detection of combustible material particle size 14, Identification of biomass delivered particle size: preferably by essentially continuous measurement, adjustable by mechanical treatment equipment operating parameters according to the size of the material, for example, so that the particle size after processing is as uniform as possible, identifying the amount of combustible material 15.

4. Post-mechanical operations that can be performed on material conveyed through mechanical processing and / or material fed directly to the second conveyor: the material load is directed to the second conveyor 7, moisture content measurements 13 are preferably performed as substantially continuous measurement: - if the instantaneous moisture content of a predetermined limit value: - a portion of the material exceeding the limit value is conducted to the wet material drying 12, or - the excess portion material is fed to a second shell 11, the average moisture content of the material 1 supplied is determined by measured moisture contents, measurements of the amount of combustible material 17 preferably as a substantially continuous measurement: - if the amount of non-combustible material exceeds a predetermined threshold: or - the excess of the material is recycled to a by-product, the average content of non-combustible material delivered 1 is determined by measurement of the quantities of non-combustible material, if not measured, identification of the size of the combustible material: preferably, performs a substantially continuous measurement, - adjusting the operating parameters of the mechanical treatment equipment 5 on the basis of the piece size data measured after treatment, - detecting the need for maintenance of the equipment by measuring piece size data before and after the mechanical treatment.

5. Provide quality feedback, for example as report 22: Quality feedback can be, for example, per load and / or over a period of time, including one or more of the following information: - Weight of material 1 delivered, and - Moisture content, such as moisture content. representing the dry matter content of the material delivered (%), - the dry mass quality value calculated on the basis of the average non-combustible or combustible material content representing the percentage of combustible material in the total material content, - higher and / or lower calorific value; the size of the combustible material.

specific measures to be taken if the amount of load rejects (total wrecks and possibly by-product) exceeds a predetermined threshold (too much wet material and / or too much unburned material), feedback to the load supplier on the quality of the load and / or time period, through a quality feedback application and / or a vendor server, the ability to influence the load supplier through delivery specification, the delivery specification can serve as a tool for planning the supplier's own operations.

6. Determine Quality Feedback Values, eg Report 23: Provide Feedback on Quality of Material Delivered to Load Provider eg by Load or for Agreed Time Period, Feedback eg through Special Quality Feedback Application and / or Provider Server, e.g. Computer System 21 or Computer System 23 for example, one or more of the following quality feedback values for the load supplier: moisture content of the material delivered (based on total load and / or combustible material), quality value of the load (eg grade and / or fraction of combustible material), size of combustible material delivered, amount of combustible material , size of delivered non-combustible material, amount of delivered non-combustible material, upper calorific value of biomass delivered, lower calorific value of biomass delivered, material delivered monetary value, energy content of delivered biomass (MWh and / or MWh / t) in dry matter, and / or energy content of delivered load (MWh and / or MWh / t) on arrival.

the delivery specification can serve as an aid to the supplier's own planning of activities, any special measures to be taken if the amount of load reject (total wreckage and possibly also by-product) exceeds a predefined threshold (too much too wet material and / or too much unburned material).

The price to be paid for the material delivered may be based, for example, on the weight of the load, the moisture content, the calorific value and the dry mass quality value. In addition, other factors may be taken into account, such as the size of the material delivered (non-combustible and / or combustible material). When determining the price to be paid for the load, for example, MWh rates may be used, whereby one or more of the quality feedback values mentioned above are preferably taken into account. According to a preferred example, the determination of rates takes into account: - the amount of combustible material in the load (s) which may be formed, for example, by the weight of the material supplied (1) and the dry mass quality value, or / or the (lower) calorific value MWh / t), which may be formed, for example, by taking into account the amount of combustible material in the load (s) delivered, the moisture content (%) of the load delivered, and / or the higher calorific value of the dry matter, for example. constant (on the order of 5 MWh / t).

The price paid for the load may therefore be influenced by, for example: all said quality feedback values, according to a preferred example, the price to be paid is influenced at least by the weight (s) of the biomass, the quality value of dry mass, the moisture value and / or the effective calorific value of the biomass (MWh / t). In this way, good quality energy wood can be rewarded at a better price than the supplier, whereby good quality energy wood material is to the benefit of both the supplier and the downstream processing plant.

According to a preferred embodiment, the quality feedback system is capable of recovering any measured information provided to the system. In addition, the quality feedback system is able to provide, inexpensively, not only measurement results, but also data generated by combining measurement data with other data. This information, or at least some of it, can be returned to the biomass production head via a quality feedback system. Preferably, such feedback information can also be used to verify the accuracy of the measurements.

The value of the load reject can be any predetermined value. From a cost-effectiveness point of view, a suitable reject limit may be, for example, a maximum of 10-12% of the load.

A lower heat value coefficient of the load can be formed, for example, if the higher heat value coefficient and the total moisture of the material at the arrival space are known. For example, for wood and peat, the lower calorific value can be calculated using the following formula:

Qnet (ar) = Qnet (d) x (100-Mar) / 100- (E (H 2 O) / y) x Mar, where

Qnet (ar) is the lower calorific value (MJ / kg),

Qnet (d) is the upper calorific value (MJ / kg), typically about 5 for wood,

Mar is the total moisture in the inlet space (%) weighted by the mass of moist fuel, typically about 50, E (H2O) is the amount of heat needed to evaporate water (for example at 25 ° C about 0.02443 MJ / kg) and y is the conversion factor from MJ to kW to 3.6, which is 3.6.

Measurements of lump size from the connection of one or more conveyors may be made by measuring lump size of combustible material and / or lump size of non-combustible material.

Preferably, both the size of the non-combustible material and the size of the combustible material are measured such that both measurements are made before and after mechanical treatment.

Measurement of non-combustible material can be made, for example, by means of sound interpretation, electromagnetic radiation and / or image interpretation (interpretation of the particle size). For example, metal can be measured with metal detectors and separated from other material, for example, in the same way as other non-combustible material, or by magnets, for example. The moisture content can be measured, for example, by irradiating the material entering the conveyor with a radioactive or IR source, which results in the amount of water molecules being known, i.e. the moisture content of the material. The measurements made may be carried out by measuring devices and methods known per se, which are now applied in the system and method described above. Preferably, one or more measurements are performed as continuous measurement of the material flow.

Using the system of the invention, material can be processed which is delivered to a variety of production plants, such as biofuel production and boiler fuel.

The invention is not limited to the examples set forth in the drawings and the foregoing description, but instead is characterized by what is set forth in the following claims.

Claims (23)

A method for treating material containing biomass, the method comprising directing the material to a conveyor (3, 7) and, with the aid of a conveyor, to a mechanical treatment plant (5) and / or a further processing plant, comprising measuring the moisture content (13) , characterized in that the method measures the particle size (4, 19) of non-combustible material and the amount (8, 16) of non-combustible material in connection with said conveyor (3, 7) and feeds the material to further processing and / or mechanical processing (5) controlled material, or at least one material controlled other than a further processing plant or mechanical processing equipment (5). A method according to claim 1, characterized in that said method is directed to said mechanical treatment apparatus (5) using biomass-containing material on a first conveyor (3), measuring at least the particle size of non-combustible material with said measuring device (4) before said apparatus (5), and on the basis of the measurement (4), whether said measured material is discharged from the first conveyor (3) or is led through the first conveyor (3) to the mechanical treatment apparatus (5) for crushing. Method according to Claim 1 or 2, characterized in that the method measures the size (18) and / or the amount (17) of combustible material of the material stream adjacent to the second conveyor (7) such that at least some of the material is fed to a further processing plant. and / or controlling the quality of the material to be sent to the further processing plant based on the size and / or volume measurements of the combustible material. Method according to one of Claims 1 to 3, characterized in that the material is conveyed by a first conveyor (3) to a mechanical treatment apparatus (5) by which at least part of the material is crushed before the material is conveyed from the mechanical processing apparatus (5) to the second conveyor (7). Method according to one of Claims 1 to 4, characterized in that, when the measurements indicate that the particle size of the non-combustible material and / or the amount of non-combustible material exceeds a predetermined limit value, at least one of the following operations is carried out: or - stopping the machining device (5) for such a time that the harmful material has left the first conveyor (3) leading to said machining device (5). Method according to one of Claims 1 to 5, characterized in that the method: determines the weight of said material, determines the proportion of combustible and / or non-combustible material in the conveyor (3, 7), determines the moisture content of the material in the conveyor (3, 7); the method further comprises: determining the energy content of said material on the basis of the information determined in the preceding steps and the higher calorific value. A method according to any one of claims 1 to 6, characterized by generating feedback information in a quality feedback system, wherein the quality feedback system provides data as at least one of said measurement results, and wherein said quality feedback system is capable of returning feedback information containing information from at least said measurement. A method according to any one of claims 1 to 7, characterized in that the method provides quality feedback data from the supplied biomass-containing material by feeding the material feedback data to the quality feedback system. . Method according to Claim 7 or 8, characterized in that the method provides one or more of the following information on the delivered material to the quality feedback system: proportion of combustible material to delivered material, proportion of non-combustible material to delivered material, combustible material particle size, unburnt material particle size, moisture content or dry matter content, the upper calorific value of the combustible material, the method returning one or more of the following data as quality feedback data: delivered material energy value at arrival, material suitable for further processing, delivered material quality value, non-combustible material size. A method according to any one of claims 7 to 9, characterized in that the method provides an input to the quality feedback system of a piece size of non-combustible and / or combustible material, wherein the quality feedback information comprises at least said piece size information. A method according to any one of claims 7 to 10, characterized in that the method provides input of at least the moisture content of said supplied material, the amount of combustible or non-combustible material and the higher calorific value of the combustible material. Method according to one of Claims 7 to 11, characterized in that the method determines and sets quality return information as one or more of the following: monetary value of delivered material, energy content of the delivered material on arrival, energy content of the delivered material suitable for further processing, weight of delivered material , the quality value of the material delivered, or the moisture content of the material supplied. A system for treating material containing biomass comprising at least one conveyor (3, 7) and measuring means (13) for measuring the moisture content of a material stream in connection with the conveyor (3, 7), characterized in that the system comprises measuring means (4, 8, 16). 19) for measuring the amount of non-combustible material and measuring the size of the non-combustible material from the material stream adjacent to said conveyor (3, 7), wherein - at least one conveyor (3, 7) is arranged to operate on said measurements for conveying said material to a further processing plant and / or ), and the system further comprises a conveying apparatus for transferring said material from the conveyor (3, 7) to at least one other location, such as a wreck (6, 11) or for drying wet material (12) based on at least one of said measurements. System according to Claim 13, characterized in that the system comprises a first conveyor (3) arranged to conduct a material stream to said mechanical treatment apparatus (5) and measuring means (4) for measuring the size of unburnt material from the material stream and transferring material from the first conveyor. 3) to the wreck (6) before the mechanical treatment apparatus (5) when said measured value (4) exceeds a predetermined limit value. A system according to claim 13 or 14, characterized in that the system comprises a second conveyor (7) for feeding material to a further processing plant, measuring means for measuring the size and / or amount of combustible material from the material stream associated with the second conveyor (7) and regulating means to adjust the quality of the material based on at least one measurement performed. System according to Claim 13, 14 or 15, characterized in that the system comprises a first conveyor (3) for conveying material to the mechanical treatment plant (5) and a second conveyor (7) for conveying material from the mechanical processing plant (5) to a further processing plant. System according to one of Claims 13 to 16, characterized in that the system comprises means for stopping the mechanical apparatus (5) on the basis of at least one measurement made of non-combustible material. A system according to any one of claims 13 to 17, characterized in that the system comprises means for measuring the weight of said material, means for measuring the combustible and / or non-combustible portion of said material in connection with the first and / or second conveyor (3, 7) a connection between the first and / or second conveyor (3, 7), and means for determining the energy content based on the higher calorific value and measured data. A system according to any one of claims 13 to 18, characterized in that the system further comprises a quality feedback system for providing quality feedback information on the delivered biomass material and for which said quality feedback system is provided for input of specific characteristics of said supplied material. based on the data, a quality feedback report that includes quality data generated from said input data on said biomass-supplied material. A system according to claim 19, characterized in that one or more of the following information about the material supplied is provided to the quality feedback system: the proportion of combustible material in the delivered material, the proportion of non-combustible material in the delivered material, the combustible material particle size, non-combustible material content, or dry matter content, higher calorific value of the combustible material, and that the quality feedback information comprises one or more of the following: monetary value of delivered material, energy content of the material delivered at inception, energy content of further material, quality value of material delivered, size of combustible material. A system according to claim 19 or 20, characterized in that a piece size of non-combustible and / or combustible material is provided for input to the system, wherein the quality feedback information comprises at least the piece size input data. A system according to any one of claims 19 to 21, characterized in that at least the moisture content of the supplied material, the amount of combustible or non-combustible material and the higher calorific value of the combustible material are provided for input to the system. A system according to any one of claims 19 to 22, characterized in that the system is adapted to define and set quality return information as one or more of the following: monetary value of delivered material, energy content of the material delivered at arrival, energy content of the higher heat value coefficient of the material delivered, the quality value of the material supplied, or the moisture content of the material supplied.