Optimization of binder addition and compression load for pelletization ...

December, 2014

Int J Agric & Biol Eng

Open Access at http://www.ijabe.org

Vol. 7 No. 6

67

Optimization of binder addition and compression load for pelletization of wheat straw using response surface methodology Lu Donghui1, Lope G. Tabil2, Wang Decheng1*, Wang Guanghui1, Wang Zhiqin1 (1. College of Engineering, China Agricultural University, Beijing 100083, China; 2. Department of Chemical and Biological Engineering, University of Saskatchewan, Saskatoon S7N 5A9 SK, Canada) Abstract: Densification is required for efficiently handling and transporting biomass as feedstock for biofuel production. Binders can enhance straw pellet strength and improve the pellet performance.

The present investigation aimed to optimize

binders and compression load for wheat straw pelletization using a single pelleting unit. Response surface methodology was employed by using a four-factor, five-level central composite design with wood residue (%, w/w), bentonite (%, w/w), crude glycerol (%, w/w), and compression load (N) as process parameters. of pelleting, and pellet density were the response variables.

The pellet tensile strength, specific energy consumption

The higher heating value, ash content of the pellet product and the

cost of the feedstock were also considered in optimizing binder addition. adequate for binder analysis and optimization.

The developed model fitted the data and was

Wheat straw pellet, with the addition of 30% wood residue, 0.80% bentonite,

and 3.42% crude glycerol, in addition to 4 000 N of compressive load, was identified as optimal with good performance of pellet tensile strength (1.14 MPa), specific energy consumption (32.6 kJ/kg), and pellet density (1 094 kg/m3) as well as low ash content (6.13%) and high heating value (18.64 MJ/kg).

Confirmation tests indicated high accuracy of the model.

Keywords: biomass, wheat straw pellet, binder, wood residue, bentonite, crude glycerol, RSM, compression load DOI: 10.3965/j.ijabe.20140706.009 Citation: Lu D H, Tabil L G, Wang D C, Wang G H, Wang Z Q. pelletization of wheat straw using response surface methodology.

1

Introduction

Optimization of binder addition and compression load for Int J Agric & Biol Eng, 2014; 7(6): 67－78.

handle or transport. 

Logistics cost is often high due to



the great distance between the origin of biomass and the Agricultural residues, the largest available biomass [1]

location for energy production[2].

Densification of

resource in the world for bioenergy production , are

biomass into pellets can significantly reduce the cost of

environmental-friendly feedstock with huge potential for

handling, transportation, and storage[3].

sustainable energy production.

However, agricultural

calorific value and physical properties can be improved,

straw has low bulk density which does not make it easy to

and the size and shape of biomass can be made uniform

Received date: 2014-02-24 Accepted date: 2014-11-23 Biographies: Lu Donghui, PhD, research interests: postharvest processing, processing and densification of agricultural material to biofuel, life cycle assessment of biomass fuel system. Tel: +86-10-62737147, Fax: +86-10-62737208, Email: lvdonghui.cau@ gmail.com. Lope G. Tabil, PhD, PEng, Professor, research interests: pelleting of feeds and forage and optimization of the process involved in feed and forage processing; physical properties

[email protected]. Wang Guanghui, PhD, Associate Professor, research interests: drying and densification technology of biomass; manure processing; grassland improvement mechanization. Tel: +86-10-62737845, Email: [email protected]. Wang Zhiqin, PhD, Associate Professor, research interest: techno-economic analysis of agricultural bioenergy system. Tel: +86-10-62737845, Email: [email protected]. *Corresponding author: Wang Decheng, PhD, Professor,

of agricultural materials and postharvest technology of agricultural crops; bioprocess engineering; value-added engineering and postharvest handling of crops; storage, drying and cooling of biological materials; infrared spectroscopy; biomass processing and utilization. Tel: +1-306-9665317, Fax: +1-306-9665334, Email:

research interests: postharvest processing, practaculture machine, processing and densification of agricultural material. Mailing address: P.O. Box 134, No.17 Qinghuadonglu, Beijing, 100083, China. Tel: +86-10-62737208, Fax: +86-10-62737208, Email: [email protected].

The volumetric

68

December, 2014

Int J Agric & Biol Eng

through densification[4].

Open Access at http://www.ijabe.org

The lack of natural binder in

the agricultural straw is one of the important reasons for

act as a lubricant during pelleting and its addition could potentially enhance the heating value of biomass pellets.

poorly formed pellets which are often dusty, difficult to [4]

handle, and costly to manufacture .

Vol. 7 No. 6

Response surface methodology (RSM) is a statistical

Some pretreatment

tool based on the multivariate non-linear model, which is

methods have been explored to improve the durability

useful in analyzing various parameters affecting the

[5-8]

By controlling the

process[16]. Process optimization is based on the

processing method and related parameters, high quality

simultaneous combination of all goals for the responses

pellets could be produced. Binder addition is a method

and factors. RSM has been widely used in development

employed in this study.

of new processes and the optimization of their

and strength of biomass pellets

.

Optimization of binder addition

for the pelletization process is one of the most important

performance[17].

steps in the development of an efficient and cost-effective energy conservation strategy using biomass.

In the present study, the optimization of the addition of binders and applied compression load during wheat

Lignin is one kind of natural binder for biomass [9]

straw pellet production was conducted by using RSM.

densification . Wood residue with high lignin content

The objective of this study is to determine the most

can act as a potential binder for wheat straw densification.

promising binder combination and compression load for

The heating value of wheat straw pellets can be

wheat straw pelletization by maximizing pellet strength,

potentially improved with the addition of wood residue

minimizing energy consumption of pelleting, and

because

maximizing pellet density.

of

its

higher

heating

value.

It

is

environmentally friendly to recycle wood residue, which also can solve a disposal problem by using them to make biofuel[10]. Ståhl and Berghel[10] investigated the effect of mixing sawdust and rapeseed cake to make pellets.

Heating value, ash content

and binder cost is also considered.

2 2.1

Materials and methods Materials and pelletization experimental setup

They reported that the durability of the pellets increased

The details of the processes and experimental single

proportionally with an increase in the amount of sawdust.

pellet unit in these experiments are presented in an earlier

[9]

Kaliyan and Morey

suggested that biological binders

paper[18].

A brief description of the process and

such as sawdust (more than 20% by weight) can help

equipment is as below. Wheat straw (Triticum aestivum

improve the quality of the densified product.

L.) was acquired in the form of small square bales with

Colloidal hydrated magnesium aluminum silicate clay

dimensions of 0.45 m×0.35 m×1.00 m from the Central

or bentonite had been used for making durable feed

Butte area (50.83°N, 106.51°W) in Saskatchewan,

[11]

pellets

.

Bentonite added at a rate of 2.6% can reduce

dust generation of feed pellets

[12]

.

Bentonite has been

reportedly used at an inclusion rate of 5.0% to produce [11]

alfalfa pellets which can improve pellet durability

.

Canada, which was harvested in the fall of 2011. Bentonite was obtained from Canadian Clay Products, Inc. (Wilcox, SK, Canada).

Crude glycerol was acquired

from Milligan Bio-Tech, Inc. (Foam Lake, SK, Canada).

Crude glycerol, a byproduct of the transesterification

Wood residue was purchased in the form of soft wood

process in the biodiesel industry, is an additive

shavings with 60% spruce and 40% pine from Western

considered in this study.

Wood Shavings, Inc. (Saskatoon, SK, Canada).

One kilogram of crude

glycerol is co-produced for every 10 kg biodiesel produced

[13]

.

Wheat straw and wood residue samples were first

There is a positive expectation for

ground using a hammer mill (Serial no. 6M13688; Glen

glycerol’s production with the spread of biodiesel

Mills Inc., Maywood, NJ, USA) powered by a 1.5 kW

[14]

production plants

so that crude glycerol supply may

electric motor which was connected to a dust collector

Crude glycerol is an energy

(Model No. DC-202B, House of Tools, Saskatoon, SK,

with a higher heating value compared to

Canada) to control dust during operation, provide

agricultural biomass or wood residue. Glycerol could

flowability of the ground biomass through the hammer

exceed its demand. source

[15]

December, 2014

Lu D H, et al. Optimization of binder addition and compression load for wheat straw pelletization

Vol. 7 No. 6

69

mill, and collect the ground biomass.

A screen size of

USA) universal testing machine compressed the sample

3.2 mm was used in the hammer mill.

The particle size

at a speed of 50 mm/min.

analysis of wheat straw grinds and wood residue grinds was conducted using ASABE Standard S319.3

[19]

.

A

The cylindrical die was slip

fitted into a stainless steel base with a hole matching the outer diameter of die.

This steel base allowed the

Ro-Tap sieve shaker (W. S. Tyler Inc., Mentor, OH, USA)

plunger to move straight down with no lateral movement

and U.S. sieve numbers 16, 20, 30, 50, 70, and 100 (sieve

during pelletization.

opening sizes: 1.190, 0.841, 0.595, 0.297, 0.210, and

loaded into the cylindrical die for each run. Compressive

0.149 mm, respectively) were used for the particle size

force applied can be adjusted by changing the program.

analysis in 3 replicates. The mean geometric particle

After compression and achieving the pre-set load, the

size of wood residue grinds and wheat straw grinds was

plunger was stopped and held in position for 60 s. Then

(1.022±0.017) mm and (0.858±0.001) mm, respectively.

the pellet was ejected from the die at a speed of

As the geometric particle size of wood waste grinds was

50 mm/min using the plunger after the base plate was

larger than wheat straw grinds, the geometric particle size

removed.

of wood residue grinds was adjusted by changing the

recorded using the Bluehill software (Version 2.12,

mass percentage on sieve no.16 by using the formula

Illinois Tool Works, Inc., 2010). The single pelletization

suggested in the ASABE Standard S319.3

[19]

to obtain the

Approximately 0.5 g sample was

The force-displacement curve and data was

process was replicated eight times for each sample.

same geometric mean diameter with wheat straw grinds. The adjusted mass percentage of particles retained on each sieve size was presented in an earlier paper[18].

In

brief, the average percentage of wood particles on sieve number 16 was changed from 61.77% to 41.27%, and the average percentages of wood particles on other sieves were increased slightly and accordingly.

Wood residue

samples were recreated by mixing grinds from each sieve with the adjusted proportion. The moisture content of the ground material and the pretreated wood residue samples were measured using oven drying at 103±2ºC for 24 h

[20]

1. Plunger 2. Cylindrical die 3. Heating element 4. Base plate 5. Pellet sample 6. Base

in three replicates.

Figure 1

The average initial moisture contents of the wheat straw grinds and the softwood grinds were 7.30% (w.b.) and

2.2

Schematic diagram of the single pellet unit

Experimental design

The moisture content of

Based on the results of an earlier study[18], bentonite,

wheat straw grinds and wood residue grinds were both

wood residue, and crude glycerol performed well as

adjusted to a range from 9% to10% by spraying water.

binders or additives.

Then the samples were kept in air-tight plastic bags for

pellet strength and reducing energy consumption.

one week to allow for moisture equilibration.

residue can increase the pellet strength, density, and

6.66% (w.b.), respectively.

Wheat straw samples were pelleted in a single pelleting unit (Figure 1) used in previous research

[21-26]

Bentonite is good at improving

heating value of wheat straw pellets.

Wood

Crude glycerol can

.

significantly increase the heating value of the straw pellet.

In brief, the device is composed of a steel cylindrical die

So, in this work these three binders were combined as a

with an internal diameter of 6.35 mm and a length of

mixed binder to improve pellet quality.

125 mm.

A heating element maintaining the die wall

compression load for pelleting was also considered to be

temperature at 95±1°C was wrapped on the outside of the

a factor and then the interaction between adding binder

die. A plunger connected to the upper moving crosshead

and energy consumption would be observed more clearly.

of an Instron Model 3366 (Instron Corp., Norwood, MA,

Pellet tensile strength, specific energy consumption of

In addition, the

70

December, 2014

Int J Agric & Biol Eng

Open Access at http://www.ijabe.org

Vol. 7 No. 6

pelleting, and pellet density were chosen to be responses

Pellets were firstly cut diametrically into approximately

because strength, energy, and density are three of the

2 mm thick specimens and placed longitudinally at the

most important characteristics for evaluating pellet

centre of the base plate for testing.

quality.

Response surface methodology (RSM), using a

plunger of the Instron were padded with blotting paper.

central composite factorial design (CCD) with four

Each of the specimens was pressed by the plunger of the

factors, six central points, and eight axial points, was used

Instron at a speed of 1 mm/min.

to design the experimental trials.

Design-Expert

displacement data were recorded and the fracture force

software, version 7.0 (Stat-Ease Inc., Minneapolis, MN,

was determined by choosing the point that the specimen

USA) was used to conduct the experimental design and

was split apart into two semi-circular segments.

the optimization.

strength of the pellet was determined and calculated using

performed.

A total of 30 experiments were

The order of the experiments was

randomized. Factors and their respective levels are

Equation (1)[21, 25].

-1

0

1

Wood residue/%

A

10

20

30

Bentonite/%

B

1

2

3

Glycerol%

C

2

4

6

D

2 000

3 000

4 000

thickness, m. 2.5

Specific energy consumption Energy consumption was calculated by integrating the

area under the force-displacement curve recorded by the computer.

Mixing binders with wheat straw Binders were directly mixed into wheat straw grinds

according to the experimental design except crude glycerol.

(1)

fracture, N; d is specimen diameter, m; l is specimen

Symbol

Compression load/N

2.3

2F

 dl

where: σx is tensile (horizontal) stress, Pa; F is load at

Code and level Independent variable

Tensile

This test was replicated eight times

x 

Experimental codes and actual levels of the independent variables

The force and

for each sample.

summarized in Table 1. Table 1

The base plate and

Then, it was converted to specific energy

values in MJ/t by dividing the pellet mass. 2.6

Crude glycerol was heated to above 160°C

Pellet density Immediately after the ejection of the pellet, its

using a hot plate and stirred with a mini size magnetic

dimensions were measured using a digital caliper.

stirrer at 220 r/min to reduce its viscosity before spraying

pellet mass was also measured.

it into wheat straw grinds. In order to achieve uniform

calculated using mass divided by pellet volume.

distribution of each material, the mixing was carried out

2.7

The

Pellet density was

Model development and diagnostics

for 15 min; after mixing, the samples were stored in

The Design-Expert software, version 7.0 (Stat-Ease

air-tight bags. Subsequent mixing was carried out every

Inc., Minneapolis, MN, USA) was used to create the

12 h for at least 72 h.

model and analyze data. The relationship between factors

2.4

(wood residue addition, bentonite addition, crude glycerol

Tensile strength of pellets The strength and durability of the densified products

addition, and compression load) and the responses (pellet

would help optimize the material, pretreatment, and

tensile strength, specific energy consumption, and pellet

[5]

equipment to produce high quality densified products .

density) was evaluated by the best fit model suggested by

Pellet tensile strength was determined in lieu of pellet

the Design Expert software.

durability because of the limited number of pellets

derived by excluding insignificant terms.

produced in single pelleting experiments.

Diagnostic Plots were conducted by the Design Expert

The tensile

strength of the single pellet was evaluated using the [21, 25]

diametral compression test

The Model

software as well.

A Dremel rotary tool

The main indicators demonstrating the significance

(Robert Bosch Tool Corp., Racine, WI, USA) with a

and adequacy of the model are: the modified models were

[25]

was used to cut the pellet

significant; the lack of fit was insignificant; the adjusted

due to the high strength of the binder-straw pellet.

and predicted R2 values were within 0.2 of each other; the

diamond cutting wheel bit

.

The modified models were

December, 2014

Lu D H, et al. Optimization of binder addition and compression load for wheat straw pelletization

Vol. 7 No. 6

71

adequate precision was over 4[27]; and all the residuals

was measured in three replicates using a Parr 1281

were random.

automatic isoperibol oxygen bomb calorimeter (Parr

good

Then the model is considered to give

predictions

for

average

outcomes.

The

Instrument Co., Moline, IL, USA) based upon ASTM

significance of model terms was estimated based on

D5865-03[28].

P-values at 95% confidence level.

using AOAC standard method 942.05[29].

2.8

on binder costs was gathered and also considered to be a

Optimization method The goals for optimization were set for both responses

and variables.

Other factors were also taken into

consideration during optimization.

These objectives

were input in the Design-Expert software, version 7.0 (Stat-Ease

Inc.,

Minneapolis,

MN,

USA).

The

Design-Expert software was also used to draw the three-dimensional plot of response surfaces.

The total ash content was determined

factor in optimization.

Information

The cost data of the wheat straw

and binders were acquired by consulting companies selling these products.

3

Results and discussion The results of the experimental runs are shown in

Table 2. The mean pellet tensile strength varied from

Other factors (heating value, ash content, and cost)

0.69 to 1.24 MPa. The specific energy consumption for

were also considered to be minor factors that affect the

pelleting ranged from 18.6 to 36.6 MJ/t. Pellet density

final optimization.

varied from 883.0 to 1 105.6 kg/m3.

Table 2

The heating value of the samples

Mean values of pellet tensile strength, specific energy consumption and pellet density during the experimental runs

Run

Wood residue /%

Bentonite /%

Crude glycerol /%

Compression load /N

Tensile strength /MPa

Specific energy consumption /MJ·t-1

Pellet density /kg·m-3

1

30

1

2

2 000

0.89

26.0

1 010

2

20

2

4

3 000

0.97

31.0

1 052

3

30

1

6

4 000

0.88

31.8

1 071

4

20

0

4

3 000

0.91

33.8

1 041

5

30

1

2

4 000

1.24

33.5

1 071

6

20

2

4

3 000

0.92

30.1

1 050

7

10

1

6

4 000

0.80

33.5

1 055

8

20

2

4

3 000

0.97

29.5

1 062

9

20

2

8

3 000

0.81

27.5

1 029

10

40

2

4

3 000

1.04

30.1

1 075

11

30

3

2

2 000

1.01

24.8

1 017

12

0

2

4

3 000

0.93

30.7

1 071

13

20

2

4

1 000

0.77

18.6

883

14

10

3

6

4 000

0.74

31.8

1 055

15

20

2

4

3 000

0.91

29.8

1 057

16

10

1

2

2 000

0.86

26.3

991

17

10

3

2

4 000

1.09

33.9

1 106

18

30

3

2

4 000

1.11

31.7

1 104

19

20

2

0

3 000

0.98

33.6

1 029

20

10

1

6

2 000

0.80

26.4

1 009

21

10

3

6

2 000

0.95

27.0

1 004

22

20

2

4

3 000

0.86

29.6

1 065

23

20

2

4

5 000

1.15

36.1

1 077

24

10

3

2

2 000

1.09

25.2

1 012

25

20

4

4

3 000

1.03

28.9

1 072

26

30

3

6

4 000

0.77

30.3

1 071

27

10

1

2

4 000

1.09

36.6

1 069

28

30

3

6

2 000

0.87

24.1

9 91

29

20

2

4

3 000

0.97

29.9

1 059

30

30

1

6

2 000

0.69

27.0

980

72

December, 2014

3.1

Int J Agric & Biol Eng

Open Access at http://www.ijabe.org

for each model are all within 0.2, which represents good

Modeling and analysis of variance (ANOVA) Table 3 shows the ANOVA of the response surface 2

2

model, coefficient of determination (R ), adjusted R , and predicted R

2

of all the responses models. 2

The 2

differences between adjusted R and predicted R values Table 3

Vol. 7 No. 6

agreement of the models for the three responses. The adequate precision of the models is greater than 4 as shown in this table, indicating that the models were adequate.

Analysis of variance (ANOVA) for the response variables during pelletization of wheat straw

Response variable

Selected model*

R2

Adjusted R2

Predicted R2

Adequate precision

Tensile strength

2FI

0.83

0.78

0.70

16.07

Specific energy consumption

Quadratic

0.95

0.93

0.88

32.01

Pellet density

Quadratic

0.96

0.94

0.86

31.74

Note: * 2FI = 2 factor interaction model; Quadratic = Quadratic model.

Tables 4, 5, and 6 show the analysis of variance

Table 6

affected by binder used and compression load

(ANOVA) of the response variables (pellet tensile strength, specific energy consumption, and pellet density, respectively) as affected by the binders and interactions after stepwise regression. Table 4

Analysis of variance (ANOVA) of pellet tensile

strength as affected by binder used and compression load Sourceⅰ

Sum of squares

Degree of freedom

Mean square

F value

P value

Model

0.41

6

0.07

17.76