EP3103632A1 - Device for processing biomass, in particular mechanical drying of vegetable biomass - Google Patents

Abstract

The invention relates to a device for the treatment of biomass, in particular for the mechanical drying of vegetable biomass. For this purpose, the device has a pressure chamber (1) which can be charged with biomass via a feed shaft (23) and emptied via a waste outlet (24). In the pressure chamber (1) a pressure plate (7) is arranged, which is for compacting the biomass by means of a feed unit against the pressure plate (7) opposite end wall (3) of the pressure chamber (1) movable. In addition, the device has means for discharging the liquid phase emerging from the biomass during compaction. According to the invention with respect to the direction of movement of the biomass first pivot bearing (13) is provided, on which the pressure plate (7) is mounted with its first edge, and a second pivot bearing (14) on which the pressure plate (7) with its opposite the first edge second edge is mounted, wherein at least the first pivot bearing (13) transversely to the plane of the pressure plate (7) is displaceable.

Description

Device for the treatment of biomass, in particular for the mechanical drying of vegetable biomass

The invention relates to a device for the treatment of biomass according to the preamble of patent claim 1.

In the industrial processing of substances of plant origin usually cause by-products, which are often disposed of as waste or thermally recycled. By way of example, the forestry and wood industry called, where in the context of wood-winning or wood processing processes by-products such as bark, branch wood, rinds, wood chips, sawdust and the like arise. Some of these by-products can be used for the production of semi-finished products such as chipboard, but a large proportion is used thermally as a bioenergy source in the form of wood chips and pellets, with substances still contained in the by-products being lost unused. The same applies to other types of biomass such as fruits, sugar cane and beet, palm and the like.

The invention is therefore based on the object biomass, as it is produced as a byproduct in industrial production processes, further to better exploit the biomass underlying value creation potential.

This object is achieved by a device having the features of patent claim 1.

Advantageous embodiments will be apparent from the dependent claims.

A basic idea of the invention consists in separating the liquid phase present in the biomass as far as possible by mechanical compaction of the biomass. This reduces the intrinsic moisture content of the biomass, which at the same time causes an increase in the calorific value. This proves to be a great advantage, especially with a subsequent thermal utilization of the treated solid phase. The emerging in the course of compaction from the biomass liquid phase is collected for further processing, the numerous substances contained therein depending on their material Composition can be used for the respective purpose. The liquid phase of the biomass is thus made usable for the first time as valuable material.

Compared with devices which only thermally process the biomass, it is thus possible for a device according to the invention to tap the potential inherent in the biomass much better. At the same time, a device according to the invention is distinguished by a faster and more cost-effective preparation, which constitutes a decisive economic advantage over known devices.

It proves to be an advantage, moreover, that hardly any heat is introduced into the biomass in a device according to the invention during the treatment of the crop. This feature also extends the field of application of a device according to the invention to heat-sensitive biomass.

In a simple embodiment of the invention, the first pivot bearing of the pressure plate for compressing the biomass is displaceable and formed the second pivot bearing stationary. However, preferred is an embodiment with two sliding pivot bearings. This makes it possible to move the pressure plate also translationally in the pressure chamber, so that over the entire pressure surface of the pressure plate, a uniform pressure on the biomass can be exercised.

Preferably, the feed of the pressure plate is achieved with hydraulically driven cylinder piston units with which high feed forces can be generated at finely differentiated control. If a hydraulic cylinder-piston unit is also used for the advance of the lower pivot bearing, the first and second cylinder-piston unit can share components of the hydraulic drive and the control, which increases the economic efficiency of the invention. In addition to hydraulic drives and mechanical drives such as spindle drives are within the scope of the invention.

According to an advantageous embodiment of the invention, the first Cylinder piston unit and second cylinder piston unit independently operable. This opens up the possibility of subjecting the printing plate in the course of the movement for compressing the biomass different movement sequences, ranging from a pure translational movement or a pure pivoting movement to any superposition of translational motion and pivoting movement. This makes it possible to adapt the processing to the respective properties of the biomass. But also for maintenance and repair work, the pressure plate can be brought into a favorable position for the maintenance staff.

A preferred embodiment of the invention provides that the biomass is pressed in the course of Gutaufbereitung of the pressure plate against a perforated die. In this way, short flow paths for the liquid phase contained in the biomass are achieved until they exit, with the further advantage that the liquid phase is very quickly and efficiently separated from the biomass. If the perforated die becomes clogged in the course of the material preparation, it can be replaced by another without much effort and time to resume operation.

These advantages come increasingly to bear when, in a further development of the invention, the liquid phase is collected and discharged in a channel system in the end wall of the pressure chamber. The influence of the compaction of the biomass on the flow resistance is further minimized.

According to an advantageous embodiment of the invention, the first cylinder piston unit is set back relative to the second cylinder piston unit in the direction of the rear wall. This results in the inlet region of the pressure chamber greater flexibility in the motion control of the printing plate, which can be driven in this way relatively far in the direction of the rear wall. In order thereby not to limit the working range of the pressure plate in the area of action of the first cylinder piston unit, the first cylinder piston unit may have a larger piston stroke than the second Cylinder piston unit.

Favor is also an embodiment of the invention, in which the Guteinlauf and / or Gutauslauf opens directly in the region of the end wall or optionally in the region of the perforated die into the pressure chamber. In this way, the biomass is brought directly into the sphere of action between the perforated die and the printing plate, resulting in short travel paths of the printing plate and thus short cycle times in the crop processing.

In a further preferred embodiment of the invention, the printing plate, relative to the direction of movement of the biomass different pressure surface areas, each with a different inclination relative to the end wall of the pressure chamber in order to influence the movement of the biomass during compaction by the pressure plate. For example, the first area of the pressure surface can be inclined more towards the end wall in order to counteract a movement of the biomass in the course of the compression back into the product inlet. Alternatively or additionally, it is possible to incline the edge region of the pressure surface assigned to the material outlet to the rear wall in order to create a flow channel for the biomass together with the end wall or optionally with the perforated matrix.

The invention will be explained in more detail below with reference to embodiments illustrated in the drawings, wherein further features and advantages of the invention will become apparent. Identical reference symbols are used for the same or functionally identical features of different embodiments, provided that this facilitates the understanding.

• Fig. 1 in schematischer Darstellung einen Schnitt durch eine erste Ausführungsform einer erfindungsgemäßen Vorrichtung,
• Fig. 2 eine Vorderansicht auf die in Fig. 1 dargestellte Vorrichtung, und
• Fig. 3 wiederum in schematischer Darstellung einen Schnitt durch eine zweite Ausführungsform einer erfindungsgemäßer Vorrichtung.

It shows

• Fig. 1 a schematic representation of a section through a first embodiment of a device according to the invention,
• Fig. 2 a front view of the in Fig. 1 illustrated device, and
• Fig. 3 again in a schematic representation of a section through a second embodiment of an inventive device.

The Fig. 1 and 2 show a first embodiment of the invention, in which the biomass flows through the device substantially vertically from top to bottom. The device has a cylindrical pressure chamber 1, which is formed by two plane-parallel to the plane of representation in mutually light distance from each other extending side walls 2, which are interconnected at their lateral ends by an end wall 3 and a rear wall 4. The side walls 2, the end wall 3 and the rear wall 4 are held in a machine base frame 5, which is supported by vertical supports 6 on the ground.

Within the pressure chamber 1 a displaceable in the horizontal direction pressure plate 7 is arranged, which extends from the one side wall 2 to the opposite side wall and the pressure chamber 1 facing the pressure surface in the clear distance of the end wall 3 opposite. In the upper region, the pressure surface is inclined relative to the central region in the direction of the pressure chamber 1, in the lower edge region, however, in the direction of the rear wall 4. At the rear side of the pressure plate 7 facing away from the pressure surface, an upper pivot bearing with a horizontal upper bearing axis 13 is seen in the upper edge region and underneath a lower pivot bearing lying in the lower edge region with a horizontal lower bearing axis fourteenth

The inventive device further comprises an upper cylinder piston unit 8 and an axially parallel arranged lower cylinder piston unit 9. The two cylinder piston units 8 and 9 are with their cylinders 10, 10 'each rigidly anchored in the rear wall 4, wherein the upper cylinder 10 relative to the lower cylinder 10th 'is set back and has a relation to the lower piston 10' larger piston stroke. The parallel movable piston 11, 11 'of the cylinder piston units 8 and 9 hingedly connect to the pivot bearing on the back of the pressure plate 7, to which the movable piston 11, 11' at their free end in each case a bearing lug 12, 12 ', which is rotatable sits on the upper bearing axle 13 and lower bearing shaft 14. When synchronously extending piston stroke of the two cylinder piston units 8 and 9, the pressure plate 7 performs a translational movement, at different piston stroke a pure pivoting movement or a combination of translatory movement and pivoting movement.

Via pressure lines 15, the cylinder piston units 8 and 9 are connected to a pump 16 of a hydraulic unit 17, to which the control unit 18 is mounted for controlling the device. The two cylinder piston units 8 and 9 are independently controllable.

At the pressure chamber 1 facing side of the end wall 3 is a large area a Lochmatrize 19 with a plurality of horizontal through holes 20 at. In the area of the passage openings 20, the end wall 3 has a number of vertically and mutually parallel channels 21, the depth of which increases in the direction of the lower edge of the end wall 3. An obliquely extending outlet 22 connects to the channels 21 at the bottom.

To feed the pressure chamber 1 with biomass, a supply shaft 23 is provided at the top of the device, through which the biomass passes into the pressure chamber 1. Guteinlauf 23 and Gutauslauf 24 are aligned with each other and open directly in the area in front of the perforated die 19 in the pressure chamber 1. The material flow through a device according to the invention is therefore substantially straight from top to bottom along the hole die 19.

For proper use, a device according to the invention is first brought into a starting position for a working cycle by the piston 11 of the upper cylinder piston unit 8 is retracted, for example in the upper cylinder 10; If appropriate, the piston 11 'of the lower cylinder piston unit 9 can also be extended out of the cylinder 10. As a result, the pressure plate 7 acquires an inclined position in which the lower edge of the pressure plate 7 narrows the available flow cross section in the pressure chamber 1, while the upper edge lies outside the cross section of the feed shaft 23. In this position, the pressure plate 7, the feed of the device with biomass, which is the free space between the Side walls 2, the perforated die 19 and the pressure plate 7 fills.

Then there is a first compression of the feed by the piston 11 of the upper cylinder piston unit 8 is extended, while the piston 11 'of the lower cylinder piston unit 9 remains unchanged in its position. As soon as the pressure plate 7 has assumed an approximately plane-parallel position relative to the perforated die 19, both cylinder-piston units 8 and 9 are operated in parallel, which leads to the pressure plate 7 moving in the direction of the parallel displacement of the pressure plate 7 Lochmatrize 19 a residual compression of the biomass is effected.

The emerging in the course of increasing compression of the biomass liquid phase passes through the through holes 20 on the back of the perforated die 10, where it is collected in the channels 21 and directed to the outlet 22. The solid phase, however, leaves the device via the Gutauslauf 24 after the pressure plate 7 has been moved by retracting both pistons 11, 11 'of the cylinder piston units 8 and 9 in the direction of the rear wall 4.

Fig. 3 represents an embodiment of the invention with horizontal material flow. The horizontally extending cylindrical pressure chamber 1 is formed by a bottom wall 25 two plane-parallel side walls 26 and a top wall 27. At the right in the representation of the end of the pressure chamber 1 can be seen a vertical feed chute 23, which opens into the pressure chamber 1. In the axial extension of the pressure chamber 1 via the feed chute 23, a piston-like conveying element 28 is arranged, which can be moved in the pressure chamber 1 according to the double arrow 29 back and forth.

Downstream of the feed chute 23 there is initially connected a cylindrical pressure chamber section 30 with a precompressor function, which is then followed by a region 31 where the final compression takes place. In the region 31 of the final compression, a compressor unit 32 is arranged, which is substantially under the Fig. 1 and 2 described corresponds. The compressor unit 32 has a first one, based on the material flow Cylinder piston unit 8 and second cylinder piston unit 9, the movable piston 11, 11 'as under the Fig. 1 and 2 described wearing a pressure plate 7. By individual control of the cylinder piston units 8 and 9, the pressure plate 7 can be pivoted in the pressure chamber 1 and / or moved parallel to the plane in order to narrow or widen the cross section of the pressure chamber 1. At the area 31 of the Gutauslauf 24 connects.

At the pressure chamber 1 facing side of the bottom wall 25, a perforated die 19 is again arranged, which has a plurality of passage openings 20 in the section 30 of the precompression and section 31 of the final compaction 20, on the back of the perforated die 19 in a number of axially parallel channels 21 at the Top of the bottom wall 25 open. The channels 21 have an increasing depth in the direction of the material flow and form at the end of the device an outlet 22 for the liquid phase of the biomass.

In operation, the device according to the invention is fed continuously via the feed chute 23 with biomass, which is then pushed by the oscillating conveyor element 28 in the region of the cylindrical portion 30 of the pressure chamber 1. In this case, the biomass undergoes a first compression, in which the liquid emerging from the material is withdrawn through the perforated die 19 and the channels 21 from the device.

The biomass thus precompressed is advanced by the subsequent feed material into the region 31 of the final compression, where it is compressed in sections by the pressure plate 7 with high force. The operation of the pressure plate 7 is already under the Fig. 1 and 2 described so that what is said there applies accordingly.

Alternatively, it is possible to use the pressure plate 7 as a fixed cross-sectional constriction, which, after it has been set to a predetermined press nip with the Lochmatrize 19 is no longer changed in position. The biomass is continuously compressed in the course of passing through the press nip, wherein the residual liquid present in the biomass in the manner described is separated.

Claims (14)

Apparatus for the treatment of biomass, in particular for the mechanical drying of vegetable biomass, comprising a pressure chamber (1) which can be fed with biomass via a feed shaft (23) and emptied via a waste outlet (24), wherein in the pressure chamber (1) a pressure plate (1) 7) is arranged, which is for compacting the biomass by means of a feed unit against the pressure plate (7) opposite end wall (3) of the pressure chamber (1) movable, and wherein the device means for discharging the exiting during the compression of the biomass liquid phase characterized by a reference to the direction of movement of the biomass first pivot bearing (13) on which the pressure plate (7) is mounted with its first edge, and a second pivot bearing (14) on which the pressure plate (7) with its the first Edge opposite second edge is mounted, wherein at least the first pivot bearing (13) transversely to the plane of the pressure plate (7) is displaceable. Apparatus according to claim 1, characterized in that also the second pivot bearing (14) transversely to the plane of the pressure plate (7) is displaceable. Apparatus according to claim 1 or 2, characterized in that the feed unit comprises a relative to the direction of movement of the biomass first cylinder piston unit (8) whose movable piston (11) is articulated on the first pivot bearing (13). Device according to one of claims 1 to 3, characterized in that the feed unit comprises a relative to the direction of movement of the biomass second cylinder piston unit (9) whose movable piston (11 ') on the second pivot bearing (14) is articulated. Apparatus according to claim 4, characterized in that the first cylinder piston unit (8) and the second cylinder piston unit (9) are actuated independently of each other. Device according to one of claims 1 to 5, characterized in that the means for deriving the liquid phase of the biomass comprise a perforated die (19) with through openings (20) arranged on the pressure chamber (1) facing side of the end wall (3) is. Device according to one of claims 1 to 6, characterized in that the means for discharging the liquid phase of the biomass comprise at least one open channel (21) on the side of the end wall (3) facing the pressure chamber (1). Device according to one of claims 4 to 7, characterized in that the first cylinder piston unit (8) relative to the second cylinder piston unit (9) in the direction of the rear wall (4) from the pressure chamber (1) is set back. Device according to one of claims 4 to 8, characterized in that the first cylinder piston unit (8) relative to the second cylinder piston unit (9) has a larger piston stroke. Device according to one of claims 1 to 9, characterized in that the Guteinlauf (23) opens directly in the region of the end wall (3) or Lochmatrize (19) in the pressure chamber (1). Device according to one of claims 1 to 10, characterized in that the Gutauslauf (24) opens directly in the region of the end wall (3) or the Lochmatrize (19) from the pressure chamber (1). Device according to one of claims 1 to 11, characterized in that the pressure chamber (1) facing the pressure surface of the pressure plate (7) relative to the direction of movement of the biomass different areas with different inclinations relative to the end wall (3). Apparatus according to claim 12, characterized in that with respect to the direction of movement of the biomass first region of the pressure surface with respect to the subsequent region of the pressure surface to the end wall (3) is inclined towards. Apparatus according to claim 12 or 13, characterized in that the relative to the direction of movement of the biomass last area of the printing surface with respect to the area lying in front of the printing surface to the rear wall (4) is inclined towards.

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