DK178681B1 - Apparatus for production of compressed biomass members and method for start-up of the apparatus - Google Patents

Abstract

The apparatus (1) comprises a plurality of press units (2), each press unit (2) comprising a stationary matrix (19) with a press channel (6) and a linearly reciprocating piston (20) arranged coaxially with the press channel (6) for pushing biomass into the press channel (6) and for compression of the biomass in the press channel (6) during forward piston motion. The press units (2) are arranged in a horizontal plane (4) in a star configuration around a centre (5) with the piston motion being radial from the centre. For start-up conditions, the forward end point of the reciprocating motion of the pistons (20) is adjusted rearwards before running of the apparatus and gradually returned forward, only once the apparatus is running.

Description

Apparatus for production of compressed biomass members and method for start-up of the apparatus

FIELD OF THE INVENTION

The present invention relates to an apparatus for producing compressed biomass members. The apparatus comprises a plurality of press units in which a reciprocating piston compresses biomass in a matrix. The press units are arranged in a horizontal plane in a star pattern. The present invention also relates to a start-up method for the apparatus.

BACKGROUND OF THE INVENTION

Increased demand of sustainable fuel sources has put pressure on facilities using oil and coal for heat and electricity production. One of the available fuel sources is biomass, including material containing cellulose and lignin. In order to increase com-petiveness of various forms of biomass, it is of high interest to increase the energy efficacy of the biomass, for example by torrefaction, which includes a partial burning process with reduced or no oxygen availability. Torrefied material is typically cut or ground into small pieces and compressed during an extrusion process. The pellets or briquettes produced by extrusion have mechanical properties that are similar to coal, why the material is useful for existing plants that are designed for burning coal.

In order to produce sufficient amounts of biofuel, extruders are needed with high capacity to fulfil the demands while at the same time having relatively low energy consumption, as the latter influences the final price of the pellets. All these factors have to be considered for a competitive product. For this reason, efforts are ongoing to improve the technology of presses and extruders in the direction of high production capacity at low production costs.

Extruders with compressing pistons that compress biomass and push the material into the extruder are known in the art. German patent DEI02009015210 by Perdekamp discloses a press for production of pellets containing material based on cellulose or lignin. An eccentric drive reciprocates a set of three pistons into corresponding channels in a matrix such that the material is compressed into pellets by each thrust of the pistons, and the pellets are released from the matrix at the opposite end of the channels. By spindles, the distance of the matrix relatively to the pistons can be adjusted for regulating the distance by which the pistons enter the channels. This function is used to vary the pressure force on the pellets. In order to increase the speed and capacity of the press, a plurality of press units are arranged in a star configuration. A circular plate is provided at the centre of the star with an eccentric connector that is connected to each piston. Rotation of the circular plate causes the eccentric connector to perform a circular motion which drives the pistons one after the other.

The star principle of the various press units with the movable matrix implies a complicated and expensive setup, because each press unit comprises several spindles for driving the corresponding matrix. In addition, the spindle arrangement requires lateral space, which is disadvantageous when a high spatial density of press units is desired for high production capacity. It would be desirable to simplify the system in order to reduce production and maintenance costs as well as risk for breakdown.

International patent application WO97/16305 discloses a press unit with eight pistons arranged in a star pattern and fastened to a rotating disc. Eccentric rotation of the disc presses sequentially one after the other of the pistons into a consecutive channels. Alternatively, an oval plate presses onto the back end of the pistons sequentially, thus always pressing two opposite pistons into a channel.

DESCRIPTION / SUMMARY OF THE INVENTION

It is therefore the objective of the invention to provide a general improvement in the art. It is a specific objective to provide a biomass press and extruder that has a simple, reliable and robust construction. This objective is achieved with an apparatus for producing compressed biomass members as described in the following.

The apparatus comprises a plurality of press units, for example three, six, or nine, in a stationary frame. Each press unit comprises a matrix with a press channel and a linearly reciprocating piston arranged coaxially with the press channel for pushing biomass into the press channel and for compressing the biomass in the press channel during forward piston motion. For example, the piston is arranged for a reciprocating forward and backward piston motion into and out of the press channel, although this is not necessary, and it may suffice that the front end of the piston approaches the press channel in close proximity without entering the press channel. The press units are arranged in a horizontal plane in a star pattern around a centre with the piston motion being radial from the centre. In contrast to the aforementioned German patent DE102009015210 by Perdekamp, the matrix is arranged stationary. Such stationary matrices save space for the press units due to a simpler setup, which allows a higher number of press units being arranged in relatively tight space. This is an advantage for construction of robust and compact machines with high production capacities. The avoidance of spindle drives for movable matrices also reduces the risk for breakdown.

The apparatus comprises a driving member for driving the pistons. The driving member is configured for a first mode of motion, which is an eccentric motion along a circular path around the centre, which is provided by an eccentric drive unit. The eccentric drive unit comprises a rotational element with an eccentric connection to the driving member for causing the eccentric first mode of motion of the driving member by rotation of the rotational element.

For example, the driving member comprises a plurality of connection points arranged on a circle, optionally arranged in a single plane identical to the above-mentioned horizontal plane or in a single plane parallel to it. Each piston is connected to only one of these connection points by a piston rod. The piston rod has a first rod end and a second rod end. The first rod end is connected rotationally to the piston. For each piston, or for each piston but one, the second rod end is rotationally fastened to the driving member at one of the connection points.

In the case, where each piston but one is connected rotationally to the connection points, and one single piston rod is connected non-rotational to a connection point on the driving member, the configuration resembles the principles of a typical radial engine. However, as will be described below, there have also been found technical solutions where all piston rods are rotationally fastened to the driving member. In the latter case, a different delimitation arrangement is necessary for delimiting the angular excursion of the driving member in order to prevent the driving member to rotate to a degree where the piston rods get stuck. In both embodiments, the eccentric drive unit only rotates back and forth in an eccentric wiggling movement over a fraction of a circle, similarly to the corresponding motion of the crank disc in a radial engine.

In one example, the motion delimiting arrangement comprises a plurality of rollers with identical outer roller diameter and distributed spatially in a horizontal plane, each roller being provided inside one of a plurality of identical rings distributed correspondingly and with a ring diameter larger than the roller diameter. For example, the number of rollers and rings are three, optionally arranged according to an equilateral triangle. This way, the first mode of motion is limited by the relative circular movement between the rings and the rollers abutting each other along the inner surfaces of the rings. In some embodiments, rings are connected to the frame, for example by a flange, and the cooperating rollers are connected to the driving member for following the first mode of motion together with the driving member. Alternatively, the rings are connected to the driving member and the rollers are connected to the frame, for example by a flange.

Another example for a delimiting arrangement comprises excursion stoppers provided on either side of the piston rods on the driving unit. Such excursion stoppers limit the rotation of the driving unit to predetermined angles between the piston rods and the driving unit. An example of such excursion stoppers are stop pins as disclosed in US patent application US2010/0107637 by Schoell describing a Waste Heat Engine.

The reciprocating motion of the piston comprises a forward end point and a backward end point. In a further embodiment, the forward end point is adjustable by an adjustment mechanism. In the case, where the piston is arranged for entering the press channel, the forward end point is determining the insertion depth of the piston into the press channel. In the case, where the piston is not arranged for entering the press channel, the forward end point determines the minimum distance to the press channel inlet. Such an adjustment mechanism is useful for adjusting the compression strength per thrust and allows regulation of the force on the equipment when using various materials for production of the biomass members.

Also, in start-up situations, the retraction of the forward end point of the pistons is an advantage, seeing that start-up with hardened material in the press channels otherwise can be difficult due to the star configuration, where always some of the pistons are on their way forward during the first mode of motion. For start-up conditions, the forward end point of the piston can be adjusted backwards prior to start-up and then adjusted forward, once the apparatus is running. In practice, the forward end point of the piston is adjusted backwards by the adjustment mechanism for reducing the insertion depth of the pistons or for preventing the pistons to enter the channels during start-up. Then, the apparatus is started and the driving member is set into the eccentric motion, which activates the pistons into the reciprocating movement. While driving of the driving member, the forward end point is gradually adjusted forward in order to gradually press more biomass into the press channel. The rearward adjustment of the forward end point prior to start of the machine and the subsequent forward return of the forward end point when the machine is running allows the machine to gain inertia for overcoming the resistance in the extruder channel. In comparison to the star like prior art machine of German patent DE102009015210 by Perdekamp, a forward movement of the matrix away from the piston is not possible, as the matrix is stationary in the above described apparatus. Therefore, an adjustment mechanism for temporary rearward adjustment of the forward end point of the reciprocating motion of the piston is useful.

Accordingly, in further embodiments, the adjustment mechanism is provided by a second mode of motion of the driving member, the second mode of motion being independent of the first mode of motion. For example, this can be achieved by providing an actuator inside the piston for reducing the length of the piston by pulling the front part of the piston towards the rear part and thereby adjusting the forward end point rearwards away from the press channel. Another adjustment mechanism is found in providing piston rods with an actuator that changes the length of the piston rod, which also leads to a rearward adjustment of the forward end point. These two systems can also be combined. A further alternative technical solution is provided by rotation of the driving member in the horizontal plane, wherein the rotation is limited to a fraction of the angular distance between adjacent connection points. Rotation of the driving member results in adjustment of the angle of the piston rod relatively to the driving member and relatively to the piston. Due to this angular offset of the piston rod, the distance between the driving member and the rear of the piston is adjusted. If the driving member is rotated towards an increased angle between the piston rod and the direction of reciprocation, the piston is retracted and the forward end point thereby adjusted rearwards. For example, the driving unit is rotated by the second mode of motion from one angular position to a second position, which results in a change of distance between the forward end point of the reciprocating piston motion and the press channel. The adjustment of the angle of the driving member by the second mode of motion results in an angular offset for the range of angles during the first mode of motion.

Coming back to the optional connection of the rollers or rings to a flange, for example a triangular arrangement of rings, the flange is in advantageously part of the adjustment mechanism where the flange is rotationally fastened to the stationary frame. Rotating the flange in the second mode of motion about the centre by a fraction of the angular distance between adjacent connection points, also, rotates the plurality of rings that are fastened to the flange. The rollers that are fastened to the driving unit and are positioned inside the rings, consequently, follow this angular offset of the rings about the centre, which is turn also gives the driving unit an angular offset by the same angle. For example, for nine connection points, the angular equidistance between adjacent connection points is 40 degrees, and the angular offset by second mode of motion would typically be limited to between 10 and 15 degrees or roughly between 1/4 and 1/3 of the angular equidistance between adjacent connection points. Generally, the fraction of the angular equidistance between adjacent connection points is less than 1/2, and typically between 1/4 and 1/2, for example between 1/4 and 1/3.

In a practical embodiment, the flange is rotationally fastened to the stationary frame, and an actuator system connects the stationary frame with the flange, such that activation of the actuator system rotates the flange in the horizontal plane about the centre in order to provide the angular offset by the second mode of motion. For example, the actuator system comprises a plurality of linear actuators arranged off centred relatively to the centre and with the linear actuation direction being substantially tangential to a circle about the centre. In a practical embodiment, the actuators are fastened with one end to the stationary frame and with their opposite end to the flange.

Each of the channels comprises a channel inlet at a first channel end and a channel outlet at a second, opposite channel end for extrusion of the biomass in compacted form. The pistons are arranged for pushing the compressed biomass members from the channel inlet through the channels and out of the channels at the channel outlet by their repeated forward motion. Optionally, for increased compression, each of the channels is tapering towards the channel outlet for additional compression of the biomass during pushing of the biomass through the channel by the piston.

For smoothly guided linear movement of the pistons, optionally, the pistons are provided in abutment with ball bearings or roller bearings. This is in contrast to the typical sliding bearings that are used in this type of machines.

As mentioned above, the eccentric drive unit comprising a rotational element with an eccentric connection to the driving member for causing the eccentric first mode of motion of the driving member by rotation of the rotational element. Advantageously, the rotational element is arranged rotational about a rotation axis at the centre, and the eccentric connection comprises a circular member with an eccentric centre that is offset from the rotation axis. The eccentrically offset circular member is connected to the driving member for eccentric first mode of motion. For example the circular member is provided inside the driving member with a roller bearing or ball bearing between the circular member and the driving unit. Optionally, the circular member, the driving member and the bearings there between are all arranged in a horizontal plane. For example, the rotational element is driven by a flywheel that is driven by electrical motors.

In a further embodiment, the apparatus is modular with modular extensions, where each module comprises an equal number of press units, for example two, three or four. For example, the apparatus is provided in a first modular form with three press units. In a second step, this is extended to six units or to nine units. The plurality of press units are advantageously arranged with identical angular distance between adjacent press units and in a horizontal plane. It has been found that multiples of three are useful for good balance, although also multiples of two, four or five is possible. Once, the apparatus has been extended to a suitable maximum number of press units, for example nine press units in one horizontal plane, the apparatus can be further extended to accommodate even further press units in a second horizontal plane, above or below the first horizontal plane.

SHORT DESCRIPTION OF THE DRAWINGS

The invention will be explained in more detail with reference to the drawing, where FIG. 1 illustrates an apparatus for producing compressed biomass members in a) top view and b) side view; FIG. 2 illustrates an adjustment mechanism for retraction of the pistons in a) a first extreme angular orientation and b) a second extreme angular orientation;

DETAILED DESCRIPTION / PREFERRED EMBODIMENT FIG. la is top view and FIG. lb in side view of an apparatus 1 for producing compressed biomass members. A plurality of press units 2 are provided in a stationary floor 54 based frame 3 and arranged in a horizontal plane 4 in a star-configuration around a centre 5. The number of press units 2 is nine in FIG. la as an example but can be different. For the nine press units 2, three electrical motors 7 are provided, each of the motors 7 comprising a belt pulley 8 with a belt 9 pulling a flywheel which is driving the compression in the press units 2. For feeding the press units 2 with biomass, biomass in provided from a feeding facility, typically a feed conveyor, into a container 11 is provided above the press units 2. Various transporters 13, 14 are used to feed biomass from the feed container 11 into the press units 2. Once, the biomass has been compressed into a solid member, for example a pellet or briquette, it is extruded from the press channel 6 onto a conveyor 55 that extends in a circle around the frame 3 below the outlets of the press channels 6. The conveyor 55 collects the compressed members and conveys these to a facility for further handling, for example storage or packing facility. For adjustment of the back pressure in order to promote compaction, a back pressure adjustment mechanism 56 is provided at the exit of the press unit 2.

The illustrated apparatus 1 is optionally provided modular in the sense that it can be operated with three, six, or nine press units 2 in the same plane 4. Further planes with three, six, or nine units can be placed in a second plane on top of the shown plane in order to increase the capacity. Each of the motors 7 is dimensioned for being strong enough for driving at least three press units 2, such that for a modular apparatus with only three or six press units 2, one or two motors 7, respectively, are used. Alternatively, instead of multiples of three press units, the apparatus can also be constructed with multiple of two press units.

Inside the feed container 11, there are provided container outlets 12 with horizontal screw conveyors 13 that take out biomass from the feed container 11 and convey it to a vertical screw conveyor 14 that is feeding the biomass into an accumulation chamber 15 for compression. The screw conveyors 13, 14 are driven by small electrical motors 17a, 17b, one for each conveyor 13, 14. The vertical screw conveyor 14 transports the biomass downwards into the accumulation chamber 15 that connects with the inlet of the press channel 6 inside the matrix 19, which is stationary mounted onto the end flange 16 of the accumulation chamber 15. The end flange 16 is stationary with respect to the frame 3.

From the second, opposite side of the accumulation chamber a piston, which will be explained in greater detail below, is coaxial with the press channel 6 and is reciprocating between a forward end point and a rearward end point through the chamber 15 towards the press channel 6. By reciprocation, the piston 20 presses repeatedly further biomass into the press channel 6 and the force on the biomass by the piston 20 com presses the biomass inside the press channel 6. The forward thrust of the piston 20 not only compresses the biomass inside the press channel 6 but also moves it forward towards the channel outlet for extrusion of the compressed biomass as compressed members, for example briquettes. FIG. 2a is a principle sketch of the pistons 20 and the driving unit 30. A driving member 30 with an eccentric first mode of motion is provided for driving the pistons 20. The driving member 30 comprises 3-9 connection points 31 arranged on a circle in a horizontal plane. Each piston 20 is connected to one of these connection points 31 by a piston rod 32. The first end 33 of the piston rod 32 has a first rotational connection 34 by which it connects rotationally to the rear part 26 of the piston 20. The second end 33’ of the piston rod 32 is rotationally fastened by a second rotational connection 34’ to the driving member 30 at one of the connection points 31.

As illustrated, the piston 20 does not enter the press channel 6, but the forward end point 20’ of the reciprocating motion is outside the press channel 6. This is necessary due to the tapering part 18 extending to the inlet of the press channel 6. The entering is also not necessary, as the screw conveyor 14 fills the accumulation chamber 15, and the piston 20 creates force on the biomass which pushes the biomass into the press channel 6, as the biomass cannot escape to anywhere else from the accumulation chamber 15. Alternatively, the tapering part 18 can be avoided, or the channel inlet comprises a cylindrical region deep enough for the piston 20 to enter, such that the forward end point 20’ of the reciprocating motion is inside the press channel 6, and the rearward end point is outside the channel 6 and in the accumulation chamber 15. However, by not forcing the piston 20 into the press channel 6 in the matrix 19, the requirement for dimensional precision is less strict, which production-wise is an advantage. As illustrated in FIG. 2a, the press channel 6 may have a tapering part for sideways compression of the biomass during extrusion. A first mode of motion of the driving unit 30 is provided by an eccentric drive unit 36, which comprises a flywheel (not shown). The flywheel is driven by belts 9 that are connected to the electrical motors 7.

The principle of the machine is similar to that of a radial engine. In a radial engine for airplanes, one of the piston rods has a rotational connection to the corresponding piston but does not have a rotational connection with the eccentric driving member. This is done in order to prevent rotation of the driving member into a position where all piston rods get stuck. The system according to the invention can be modified such that for each piston 20 but one, the second rod end 33’ is rotationally fastened to the driving member 30 at one of the connection points 31. Thus for the specific example above with the nine press units 2, all nine piston rods 32 would at their first end 33 have a first rotational connection 34 with the piston 20, but only eight of the nine piston rods 32 would have second a rotational connection 34’ at the second end 33’ with the driving member 30. The one piston rod having a rigid, non-rotational connection to the driving member 30 would prevent the driving member 30 from rotating into a blocking orientation. However, such a system where not all connections are identical suffers from non-symmetric wear, why a different stabilising system is described in the following.

As illustrated in FIG. 2a, the first mode of motion is delimited by a motion delimiting arrangement 47 comprising three rollers 48 arranged according to an equilateral triangle. Each roller 48 is limited in its motion by a ring 49. Whereas the rings 49 are connected to the frame via a flange 50, the rollers 48 are connected to the driving member 30. During the first mode of motion, which is attained during normal steady state pressing operation, the rings are stationary with respect to the frame. The eccentric movement of the driving unit 30 is limited by the movement of the rollers 48 inside the rings 49. This delimiting arrangement 47 prevents the driving unit 30 from rotating into an orientation in which the piston rods 32 get stuck. Due to the delimiting arrangement 47, it is possible that all piston rods 32 are connected rotational to the driving member 30 as illustrated in FIG. 2a.

If the driving member is delimited by a piston rod being fixed in one end, the motion of these 3 points will describe a perfect circle, when the eccentric driving unit 36 is rotated. Thus, it is possible to delimit the driving member 30 by attaching a roller to each of the 3 points, and letting each roller 48 run inside a rings 49 as a fixed circular race.

An alternative arrangement implies rings 49 connected to the driving member 30 and rollers 48 connected to the frame 3 at stationary positions. The embodiment of FIG 2a is one example of a possibility for delimiting the rotational degree of freedom for the driving unit 30, although also other arrangements are possible, as long as there are provided end stops for the rotation of the driving member.

However, one further advantage of the roller 48 and ring 49 combination becomes apparent below, motivated by a start-up condition of the apparatus 1 after production break, where the biomass in the accumulation chambers 15 and press channels 6 imply a tough resistance against the pistons 20 moving forward.

The reciprocating motion of the piston 20 comprises a forward end point 20’ and a backward end point. In a further embodiment, the forward end point 20’ is adjustable by an adjustment mechanism. In the case, where the piston 20 is entering the press channel 6, the forward end point is determining the insertion depth of the piston 20 into the press channel 6. In the case, where the piston 20 is not entering the press channel 6, the forward end point determines the minimum distance to the press channel inlet 24. Such an adjustment mechanism is useful for adjusting the compression strength per thrust and allows regulation of the force on the equipment when using various materials for production of the biomass members. Also, in start-up situations, the retraction of the forward end point of the pistons 20 is an advantage, seeing that start-up with hardened material in the press channels 6 otherwise can be difficult due to the star configuration, where some of the pistons 20 are always on their way forward during the first mode of motion. For start-up conditions, forward end point of the piston can be adjusted backwards prior to start-up and then adjusted forward, once the apparatus is running.

In practice, the forward end point of the piston is adjusted backwards by the adjustment mechanism for reducing the insertion depth of the pistons 20 or for preventing the pistons 20 to enter the channels 6 during start-up. Then, the apparatus 1 is started and the driving member 30 is set into the eccentric motion, which activates the pistons 20 into the reciprocating movement. While driving of the driving member 30, the forward end point 20’ is gradually adjusted forward in order to gradually press more bi- omass into the press channel 6. The rearward adjustment of the forward end point 20’ prior to start of the machine and the subsequent forward return of the forward end point when the machine is running allows the machine to gain inertia for overcoming the resistance in the extruder channel.

For example, the adjustment of the forward end point 20’ of the reciprocation can be achieved by providing an actuator inside the piston 20 for reducing the length of the piston 20. An actuator could, thus, be used to shorten the overall length of the piston 20 and thereby pull the front part 25 rearwards away from the press channel 6. Another adjustment mechanism is found is providing piston rods 32 with an actuator that changes the length of the piston rod 32. By reducing the length of the piston rod 32, the piston 20 is retracted. These two systems, which are not illustrated but mentioned as examples in general, can also be combined.

An even further adjustment mechanism is described in more detail in the following with reference to FIG. 2b. In this case, the circular rings 49, which delimit the motion of the driving member 30, are arranged fixed to a flange 50 which is rotatable about the centre 5 over a minor angle in a horizontal plane relatively to the frame 3. This rotation is a second mode of motion of the driving unit 30 and is independent of the first mode of motion. Whereas the first mode of motion of the driving unit 30 during production of compressed biomass members is a steady and repeated eccentric wiggling around a circle, the second mode of motion is obtained by an actuator system that rotates the flange 50 into an angular offset by only a fraction of the angular distance between adjacent connection points 31. The result of doing this is seen in FIG. 2b as compared to FIG. 2a, wherein FIG. 2a shows the geometry and forward end point 20’ of the pistons and the corresponding angular orientation of the piston rods 32 before the second mode of motion is carried out, and image 2b shows the geometry and forward ends point 20’ of the pistons 20 after the retraction of the pistons 20.

For example, in the present embodiment with nine connection points 31, the equiangular distance between the connection points is 360/9=40 degrees. The angle that the three rings are moved is a fraction of the angular distance between adjacent connection points 31. The two drawings in FIG. 2a and FIG. 2b show the two extreme angu- lar positions for the second mode of motion. It is seen that the angular distance between the two extreme positions of FIG. 2a and FIG. 2b, respectively, is less than half the angular distance between the connection points 31. Typically, it is between 1/4 and 1/3 of the angular distance between the connection points 31.

It is observed that the pistons in FIG. 2b are retracted relatively to the pistons in FIG. 2a. In an upstart situation, the forward end point 20’ of the reciprocation of the pistons 20 is retracted first by rotating the flange 50 with the rings 49 about the centre 5 into one of the extreme positions by the second mode of motion, then the motors 7 are started to rotate the flywheel and the connected driving unit 30 in the first mode of motion. The rotation of the set of the flange 50 with the rings 49 about the centre 5 yields an angular offset of the piston rods for the first mode of motion. In this position, the pistons 20 have sufficient space such that they do not immediately start compressing the remains of the biomass in the press channel 6. Once, the apparatus is running, the actuator system is activated to return set of rings 49 to the other angular extreme orientation, which is used for normal production operation with the forward end point of the reciprocation being in proximity of the inlet of the press channel 6 for maximum advance of the pistons 20. This change can be done smoothly and slowly in case that the biomass that remains in the press channels 6 has hardened and has to be pushed out gradually before smooth and steady operation of the production, where the driving unit 30 and pistons 20 work only in the first mode of operation.

Reference numbers in drawings 1 apparatus 2 press units 3 frame 4 horizontal plane through centre 5 5 centre of star press 6 press channel 7 electrical motors 8 belt pulley 9 belt 11 feed container 12 transporters 13 horizontal screw conveyor for extraction of biomass from container 11 14 vertical screw conveyor feeding biomass into chamber 15 15 accumulation chamber for compression 16 flange of chamber 15 for mount of press channel 6 17a, 17b small motors for screw conveyors 13, 14 19 matrix 20 piston 20’ forward end point of piston movement 23 bearings for piston 24 channel inlet 25 piston front part 26 piston rear part 30 driving member 31 connection points on driving member 30 32 piston rod 33 first end of piston rod 32 33’ second end of piston rod 32 34 first rotational connection between first end 33 of piston rod and rear part 26 of piston 34’ second rotational connection between second end 33’ of piston rod and driving member 30 36 eccentric drive unit 37 axle of eccentric drive unit 36 47 delimiting arrangement for delimiting the angular movement of the driving member 30 48 roller fixed to driving member 30 49 ring 50 flange 54 floor 55 conveyor for transport of briquettes or pellets after extrusion 56 adjustment mechanism for back pressure on briquette

Claims (9)

An apparatus (1) for producing compressed biomass blanks, wherein said apparatus comprises multiple compression units (2) in a stationary frame (3); each press unit comprising a matrix (19) having a pressure channel (6) and a linear reciprocating piston (20) arranged coaxially with the pressure channel (6) to push biomass into the pressure channel (6) ) and for compressing the biomass within the pressure channel (6) during the forward piston movement; wherein the pressure units (2) are arranged in a horizontal plane (4) in a star pattern around a center (5) with the piston moving radially from the center (5); wherein the matrix (19) is arranged stationary, the apparatus comprising a drive element (30) for driving the pistons (20), wherein the drive element (30) is configured for a first mode of movement which is an eccentric movement along a circular path around the center (5). ); wherein the first movement mode of the drive element (30) is provided by an eccentric drive unit (36), wherein the eccentric drive unit (36) comprises a rotating element (37) with an eccentric connection to the drive element (30) to cause the eccentric first movement mode of the drive element (30) by rotating the rotating member (37); wherein the drive element (30) comprises a plurality of connecting points (31) on a circle, each piston (20) being connected to only one of these connecting points (31) by means of a piston rod (32), characterized in that the piston rod (32) ) has a first rod end (33) and a second rod end (33 '), wherein the first rod end (33) is pivotally connected to the piston (20); wherein for each piston (20) or for each piston (20) except one, the other rod end (33 ') is pivotally attached to the drive element (30) at one of the connecting points (31). Apparatus according to claim 1, wherein the connection points (31) of the circle in a single plane are identical to the horizontal plane (4) or parallel to it. Apparatus according to claim 1 or 2, wherein the reciprocating movement of the piston (20) comprises a front end point (20 ') and a rear end point, wherein the front end point (20') is adjustable with an adjustment mechanism (50). . Apparatus according to claim 3, wherein the adjusting mechanism (50) is provided by a second movement mode of the drive element (30), the second movement mode being independent of the first movement mode; wherein the second mode of movement is a rotation of the drive element (30) in a single plane, the rotation being limited to a fraction of the angular distance between adjacent connecting points (31), to continue the rotation of the piston rod (32) by turning the drive element (30). relative to the piston (20). Apparatus according to any one of the preceding claims, wherein the second rod (33 ') for each piston (20) is pivotally attached to the drive element (30) at one of the connecting points (31); wherein the first motion mode is constrained by a motion limiting arrangement (47), wherein the motion limiting arrangement comprises a plurality of rollers (48) having identical outer roll diameters and spread in a horizontal plane, each roll (48) being provided within one of a plurality of identical rings (49) distributed correspondingly and with a ring diameter greater than the roller diameter so that the first mode of movement is limited by the relative circular motion between the rings (48) and the rollers (49) which move along the inner surfaces of the rings; wherein the rings (49) are connected to the frame (3) and where the cooperating rollers (48) are connected to the drive element (30) to follow the first mode of movement with the drive element (30) or where the rings (49) are connected to the drive element (30) and the rollers (48) are connected to the frame (3). Apparatus according to claim 5, wherein the rings (49) or the rollers (48) are respectively connected to the frame (3) via a flange (50) pivotally attached to the frame (3); and wherein the second mode of movement is provided by an actuator system, wherein the actuator system connects the stationary frame (3) to the flange (50) such that actuation of the actuator system rotates the flange (50) in the horizontal plane (4) around the center (5). Apparatus according to any one of the preceding claims, wherein each of the pressure channels (6) comprises a channel inlet (24) at a first channel end and a channel outlet at a second, opposite channel end for extrusion of the biomass in compressed form, wherein the pistons (20) are arranged to push the compressed biomas see items from the channel inlet (24) through the pressure channel (6) and out of the channels at the channel outlet by their repeated forward movement; wherein each of the pressure channels (6) comprises a portion (18) tapering towards the channel outlet for further compression of the biomass during pushing of the pulp (2) through the pressure channel (6). Apparatus according to any one of the preceding claims, wherein the pistons (20) are provided with ball or roller bearings for smoothly controlled linear movement of the pistons (20) by means of the bearings (23). A method for starting an apparatus (1) according to claim 3 or any of claims 4-8, if these are directly or indirectly dependent on claim 3, the method comprising: - moving the front end point (20 ') of the reciprocating movement of the plunger (20) backward by means of the adjustment mechanism (50) in another mode of movement; then starting the apparatus and driving the drive element (30) by the first motion mode, the first motion mode being independent of the second motion mode; - subsequently, while driving the drive element (30) in the first movement mode, by means of the adjustment mechanism (50) gradually moving the front end point forward by the second movement mode.