Guide to Biomass comminution: material properties, machinery, principles of the process and fundamentals of process modelling


Bachelor Thesis, 2011

68 Pages, Grade: 1,5


Excerpt


Table of contents

1. INTRODUCTION
1.1 General
1.2 Comminution as one unit operation in the Biofuel supply chain
1.3 Structure of biomass - wood as an example
1.4 Elementary mechanics in the comminution process
1.5 Comminution machinery

2. MODEL INTRODUCTION
2.1 The reason for making model
2.2 Models valid for brittle materials
2.3 Identification of reliable parameters for the model
2.4 Measuring the specific energy

3. QUALITATIVE CHIPPING MODEL
3.1 Derivation of the qualitative model for chipping

4. RESULTS AND DISCUSSION
4.1 Coefficients for the equations

5. CONCLUSIONS

Bibliography

APPENDIX A - different classifications of biomass comminution equipment

APPENDIX B - technical specification of properties for solid biofuels

APPENDIX C - Janka Hardness and Dry density for some Softwoods and Hardwoods

APPENDIX D - Janka Hardness and Moisture Content

APPENDIX E - different models of chippers and their basic parameters

1. INTRODUCTION

1.1 General

Comminution is a process in which solid materials are reduced in size. Fibre is a morphological term for a substance characterised by its high ratio of length to cross sectional area, fineness and flexibility.

Fibrous material is that kind of material that consist of fibres. In most of the cases fibrous materials that are being comminuted are composite materials. These are the materials that consist of two or more constituent materials which have significantly different properties and remain separate and distinct within the structure. Properties of the composite material are determined not only by the constituents, but also by the way that they are combined.

Comminution of fibrous materials has many different applications. Usually comminuted fibrous materials are of biological origin. Main reason for comminution is to enable bigger surface of comminuted materials necessary for further processing.

The most common applications are:

- Food industry - comminution of food in order to enable highest possible surface of ingredients in order to perform the most efficient and effective reaction between them. It should be mentioned that eating process itself also starts with a comminution. People chew food to enable new surface for digestion enzymes. Most of the people had an opportunity to find out how does digestion reaction proceed in their stomach if they do not chew food properly (especially one that is hard to digest).
- Pulp and paper industry - paper is made of cellulose fibres from ligno-cellulosic biomass (wood). The goal is to keep the fibres unharmed as much as possible. Though they need to be separated from hemicelluloses and lignin. In order to make that separation possible, by chemical and thermal reaction or mechanical actions, more surface has to be enabled for the process.
- Particleboard industry - comminution is made both in order to get the new surface for adhesives, and to achieve relatively uniform size of the particles.
- Bioenergy - comminution is important in order to enable new surface either for biofuel upgrade like gasification (conversion via chemical reactions) or for better and more complete combustion (combustion is also a chemical reaction). It’s also necessary for other type of fuel upgrade - pelletizing. It’s a physical process and in general it’s about biomass compaction. To make compaction possible structure needs to be broken down first.

This study focus mainly on woody biomass comminution for Bioenergy applications.

According to (I. M. Petre, 2006) there are three distinguished results of biomass comminution:

a) particle sizing and classifying (coarse and intermediate size reduction)
b) particle shaping
c) breaking connections between different material components

1.2 Comminution as one unit operation in the Biofuel supply chain

When biomass is used as an energy source in most of the cases comminution is necessary. It is possible to use biomass in the forms of the full logs, and it has been done in a small scale home appliances. But because of the low efficiency and other problems like high level of CO and volatile emissions it’s definitely not recommended option.

It’s justified to say that comminution is placed in biofuel supply chain and it’s always placed in-between biomass harvest and combustion stage. As previously stated some form of comminution is necessary to achieve efficient combustion. It goes well with common sense because combustion is a chemical reaction and comminution enables new surface for that reaction to happen so achieving better efficiency of the reaction is totally logical conclusion.

In general any other operations between biomass harvest and utilisation are aiming in enabling biomass to be used by the technology of the device where biomass is utilised - mostly boiler. The goal is to utilise it in the most efficient way. Combustion reaction seems to be quite simple when one uses macroscopic approach and analyses input and output only, without detailed look into things that happen inside reactor - namely combustion chamber. To make reaction happen two reactants must be at hand - fuel and oxygen. Both need to be delivered into reactor in a way that allows to control amount of both in order to control the reaction.

To make it work proper feeding mechanism is necessary. That’s the main place in the supply chain where comminution is necessary. Size of output material has to be adjusted to the feeding mechanism - utilising device technology. In case when next stage of supply chain is not combustion but for example densification of biomass, in order to make transportation more efficient by f. ex. pelletizing, same general rule applies. It’s because pelletizer has acceptable size range for biomass particles and only within that range can work properly.

On the other side of the comminution as an operation there is input size of the material. That depends highly on technology of the comminution device itself and would be a subject of more detailed discussion in further chapters of this study.

It’s possible that size difference between material from the first operation (harvest) and final operation is too big and more than one operation of comminution needs to be introduced because there is no suitable comminution device that can handle that difference singlehandly. There is also a possibility that second stage of comminution is introduced separately in order to use residues from the main process (Fig. 1.1).

In general no operation is 100% efficient and there are always residues available. Residues are present at basically every stage - even harvesting. Ratio of residues to output material is very operation dependent. In some cases amount of residues is big enough to make usage of those residues profitable.

It seems necessary to mention that the need of comminution might not be determined by purely technical issues. Sometimes comminution is chosen only to introduce residues into existing technology and is a cheaper substitute for right choice of the final utilisation unit in order to reduce the investment cost.

Figure 1.1 - Example of placing comminution operations in supply chain (L.J. Naimi, 2006)

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Table 1.1 - Different type of devices utilising biomass with respect to the input material requirements (L.J. Naimi, 2006)

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Table 1.1 shows some examples of input material size and properties for different devices. It shows high variability in terms of the acceptable input size. Other thing it shows is high variability in required moisture content. That means the drying as an operation in supply chain could also be present. That also indicates that biomass is highly variable material generally speaking.

One of the main question this study aims to answer is an existence of qualitative way to determine possibility to optimize biofuel supply chain by lowering energy consumption during the comminution stage.

1.3 Structure of biomass - wood as an example

Biomass has a composite structure. It consists of fibres which are made of cellulose and matrix that binds fibres together. Matrix consists of hemicelluloses and in case of ligno-cellulosic (woody) biomass also lignin. Biomass is highly anisotropic material which means that it has different properties, strongly depending on coordinates - namely fibre (cell wall) direction.

The most important thing about wood that should be understood is a basic fact that it has evolved for millions of years to serve three main functions in a plant as an organism (U.S. Forest Products Labolatory, 2010):

- conduction of water and nutrients from the roots to the leaves
- mechanical support of the plant body
- storage of bio-chemicals

“There is no property of wood, no matter physical, mechanical, chemical, biological or technological - that is not fundamentally derived from the fact that wood is formed to meet the needs of the living tree. By understanding the function of wood in the living tree, we can better understand the strengths and limitation it presents.” (U.S. Forest Products Labolatory, 2010)

In most of the cases wood is used as a material in terms of trees, when stumps and leaves are usually not utilised. In Bioenergy segment this statement is also true and in case of herbaceous biomass stalk is the main part being used (straw) and although it looks little bit different it’s designed by nature to meet the similar needs. Properties concerning comminution of woody biomass are to some extend true also for other types of biomass as well as other fibrous materials which are mostly of biomass origin.

Trunk of the tree (stem) is composed of various materials present in the concentric bands (U.S. Forest Products Labolatory, 2010):

- Outer bark (Fig. 1.2 - ob) provides mechanical protection of the softer inner bark and also helps to limit evaporative water loss.
- Inner bark (Fig. 1.2 - ib) it’s the tissue through which sugars (food) produced by photosynthesis are translocated from the leaves to the roots or growing parts of the tree. Minerals and nutrients are also transported from the roots to the green parts.
- Vascular cambium (Fig. 1.2 - vc) is the layer between bark and the wood that produces both of these tissues each year.
- Sapwood the active tissue which is responsible not only conduction of sap and water but also for storage and synthesis of photosynthate like starch and lipids.
- Heartwood is a darker-coloured wood in the middle of most trees. It’s not conductive and functions as a long term storage of biochemicals (extractives). Extractives are formed by parenchyma cells at the heartwood-sapwood boundary and then exuded through pits into adjacent cells (U.S. Forest Products Labolatory, 2010)[1].
- Pitch (Fig. 1.6 - p) is located at the very centre of the trunk and is the remnant of early growth of the trunk before it was formed.

Figure 1.2 - Macroscopic view of a transverse section of a trunk (U.S. Forest Products Labolatory, 2010)

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Among the woody biomass we can distinguish two major types softwood and hardwood.

Softwood are those species that come from gymnosperms (mostly coniferous). They have more simple basic structure than hardwoods because they have only two cell types and relatively little variation in structure between these cell types.

Hardwoods come from angiosperm. They are much more complicated in terms of their structure because they have greater number of basic cell types and far greater degree of variability within the cell types.

There are two basic cell orientation systems in wood structure - axial and radial. Axial cells have their long axes running parallel to the long axis of the organ (stem). It’s being used as a long distance transport. Radial cells are oriented like radius in a circle, from pitch to the bark.

Figure 1.3 - Growth of wood scheme (J.M. Dinwoodie, 1996)

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In wood science there are three main perspectives distinguished that are being used in description of wood:

- Transverse plane of section (the cross section) which shows face that is exposed when a tree is cut down (Fig. 1.5 - H).
- Radial plane runs in pitch to bark direction and is parallel to the axial system. It provides information about longitudinal changes in the stem from pith to bark (Fig. 1.5 - A).
- Tangential plane is parallel to any tangent line that would touch the cylinder and it goes along the length of the cylinder (Fig. 1.5 - A).

Other concept which is often used in wood science descriptions is grain. It’s a direction of longitude axis of cell walls which is in most cases parallel to the longitude axis of a stem.

Figure 1.4 - Different sections of wood (J.M. Dinwoodie, 1996)

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Cell wall give wood majority of its’ properties (U.S. Forest Products Labolatory, 2010), (J.M. Dinwoodie, 1996).

It consists of three main regions:

- middle lamella
- primary wall
- secondary wall (S1, S2 and S3 layers)

Figure 1.5 - Macroscopic and microscopic view of different planes in the wood (U.S. Forest Products Labolatory, 2010)

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Figure 1.6 - Cut away drawing of cell wall (U.S. Forest Products Labolatory, 2010)

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In each region cell wall consists of three major components: cellulose, hemicelluloses and lignin.

Cellulose contains repeating units of β 1-4 linked D-glucose - is a glucose polymer. Number of glucose units (degree of polymerisation) is variable and depends on the region of the cell. In secondary cell wall it could be 8 000 - 10 000 (Dinwoodie, 2000)[2], while in primary cell wall degree of polymerisation varies between 2 000 and 4000 (Dinwoodie, 2000)[3]. Cellulose is a core and dominant in quantity part of microfibrill which have threadlike shape. Cellulose mostly formed in crystalline structures is binded with hemicelluloses, with lignin on the outer surface. Microfibrills are differently oriented in different parts of cell wall and they may have different angle of orientation with respect to the cell long axis.

Cell wall has a composite structure itself - microfibrills (that consist mainly of cellulose) are placed in the matrix that consist of hemicelluloses and lignin (Fig 1.7).

Hemicellulose is heterogeneous class of polymers containing glucose, galactose, mannose, xylose and other sugars (A. Bruce, 1998). Both degree of crystallisation and the degree of polymerisation (approx. 200) of hemicellulose are generally low (Dinwoodie, 2000).

Lignin is a complex, three dimensional, aromatic molecule that consists of phenyl groups. It is non crystalline, hydrophobic and its main constituent of composite matrix of woody biomass. Lignin is a brittle material and its’ presence in middle lamella provides adhesion between the cells.

Figure 1.7 - Models of a microfibrill (Dinwoodie, 2000)

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Table 1.2 -Microfibrillar orientation and percentage thickness of the cell wall layers in spruce (Picea abies) (Dinwoodie, 2000)

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Table 1.3 - Chemical composition of wood (Dinwoodie, 2000)

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The primary wall is characterised by random orientation of cellulose microfibrills, where any microfibrill angle from 0° to 90° with respect to long axis of the cell, ma be present. In cells in wood the primary cell wall is thin and generally speaking indistinguishable from the middle lamella. Middle lamella of two adjacent cells cannot be cannot be distinguished (U.S. Forest Products Labolatory, 2010).

The remaining cell wall domain is called secondary cell wall. It’s composed of three layers:

S1 is characterised by high microfibrill angles and is quite thin. Cellulose microfibrills are laid down in a helical fashion and the angle between the mean microfibrill direction and the long axis of the cell is between 50° to 70°.

The next layer - S2 - is arguably the most important cell wall layer in determining the properties of the cell and, thus, the wood properties at a macroscopic level (U.S. Forest Products Labolatory, 2010)[4]. This is the thickest secondary cell wall layer. It’s characterised by a lower percentage of lignin and a low microfibrill angle - 5° to 30°.

S3 is a relatively thin layer with high microfibrill angle and the lowest percentage of the lignin. It’s because there has to be adhesion between the water molecules and the cell walls to conduct water. Lignin is a hydrophobic macromolecule so its low concentration in S3 makes adhesion of water possible and thus facilitates transpiration (U.S. Forest Products Labolatory, 2010).

It seems to be quite evident that properties of wood as a material would have ultimate meaning in terms of energy expense in the comminution process. It is quite clear that woods’ mechanical properties are highly determined by its fibrous and porous structure.

Figure 1.8 - The transverse and tangential–longitudinal faces of Sitka spruce. Microscope magnification x60 (Moore, 2011)

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1.4 Elementary mechanics in the comminution process

Reduction of the material’s particle size means that large particles or lumps are fractured into smaller particles. Fractures have to be initiated i.e. external forces have to be applied to the particle. The actual size reduction depends on the amount of stress applied to the particle, the rate at which it’s applied and the manner in which it’s applied (Size reduction solutions for hard to reduce materials, 2002).

It’s well known from material sciences that there three fundamental types of stresses: compression, tension and shear. It happens a lot that they occur in a kind of typical configuration that could be distinguished from any other. Bending might be considered as one of them - in microscopic scale it’s just combination on compression stresses on one side of the material sample and tension stress on the other. Since it’s easy to distinguish and appearance in real life cases is pretty common, bending stress is recognised in material science.

There are few types of actions that may be used to apply stress necessary to inflict fracture to the particle. Each of them is a combination of fundamental stresses. They could be distinguished during conceptual studies, although it’s not so easy in terms of real life comminution machinery, since they tend to occur together during the process. This would be discussed further in the study in the part that describes comminution machineries at present.

One may distinguish (I. M. Petre, 2006):

- cutting
- shearing
- tearing
- impact stress
- compression and friction (f. ex. in a disc milling)

Comminution process in any of machinery available nowadays involves at least one. Usually it’s a combination of few. There is no possibility at present to quantify the exact influence from each of the actions in real device comminution process, but seems possible to estimate which could be dominant just by analyzing geometry of the tools in a comminution device and the way they interact with comminuted material.

Figure 1.9 - Types of actions and corresponding particle shapes (I. M. Petre, 2006) illustration not visible in this excerpt

[...]


[1] refers to Hillis 1996

[2] refers to Goring and Timell 1962

[3] refers to Simson and Timell 1978

[4] refers to Panshin and deZeeuw 1980 and Kretschmann and others 1998

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Details

Title
Guide to Biomass comminution: material properties, machinery, principles of the process and fundamentals of process modelling
College
Linnaeus University  (Bioenergy technology)
Grade
1,5
Author
Year
2011
Pages
68
Catalog Number
V193175
ISBN (eBook)
9783656184621
ISBN (Book)
9783656186205
File size
4732 KB
Language
English
Notes
Note: 4.5 entspricht lt. dt. Notensystem 1,5
Keywords
biofuel, chipping, bioenergy, biomass
Quote paper
Lukasz Niedzwiecki (Author), 2011, Guide to Biomass comminution: material properties, machinery, principles of the process and fundamentals of process modelling, Munich, GRIN Verlag, https://www.grin.com/document/193175

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