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130
STUDY ONUTILIZINGOFINDUSTRIAL–AGRICULTURALWASTEIN
THE BUILDINGCONSTRUCTIONINDUSTRY
Vu Hai Yen
Department of Environment and Biotechnology, Ho Chi Minh City University of Technology
TÓM TẮT
Việt Nam có những lợi thế về sản xuất nông nghiệp. Hằng năm lƣợng phế thải dƣ
thừa trong quá trình chế biến các sản phẩm nông sản, thực phẩm rất lớn. Với việc sản
xuất đƣợc hơn 38,5 triệu tấn lúa trong năm 2009, chỉ riêng rơm, rạ, vỏ trấu thải ra trong
quá trình thu hoạch, xay xát thành hạt gạo đã có khối lƣợng cả chục triệu tấn. Tuy
nhiên, so với tiềm năng dồi dào của nguồn phụ, phế thải trong nông nghiệp hiện nay thì
những công trình nghiên cứu, ứng dụng còn rất khiêm tốn. Lƣợng vỏ trấu, rơm rạ, xơ
dừa, mùn cƣa thải đƣợc tận dụng không nhiều, phần xả thải ra các kênh rạch, sông ngòi
chiếm tỷ lệ khá cao. Bên cạnh đó, một ngành công nghiệp cũng rất đáng lƣu ý về chất
thải đó là ngành công nghiệp giấy. Công nghệ sản xuất giấy là một công nghệ tiêu thụ
nhiều nƣớc. Tùy thuộc vào công nghệ và sản phẩm, lƣợng nƣớc cần thiết để sản xuất
một tấn giấy dao động khoảng 200-500 m
3
. Nƣớc sử dụng trong quá trình rửa nguyên
liệu, nấu ăn, làm sạch, xeo giấy và sản xuất hơi nƣớc. Trong bùn thải rất khó xử lý bởi
thành phần đa dạng và phức tạp, hầu hết chứa cellulose và lignin, thành phần rất bền
vững và khó bị phân hủy. Vì vậy, để tận dụng bùn làm vật liệu xây dựng cũng là một sự
quan tâm nghiên cứu đáng kể.
Nghiên cứu này sử dụng từ các vật liệu là phế phẩm công – nông nghiệp nhƣ vỏ
trấu, xơ dừa và bùn từ hệ thống xử lý nƣớc thải nhà máy giấy để trộn với xi măng, cát
và nƣớc (tỷ lệ pha trộn 1 phần xi măng: 3 cát phần: ½ phần nƣớc) để sản xuất vữa. Mẫu
đƣợc pha trộn vào hỗn hợp tỷ lệ các thành phần khác nhau để thay thế chức năng của
các chất phụ gia nhƣ chất kết dính xi măng, bao gồm 4 nghiệm thức 5, 10, 15, 20% của
xi măng bằng phế thải. Trộn mẫu vữa vào khuôn 40x40x160 mm, sau đó các khuôn
đƣợc đặt trong nƣớc ở nhiệt độ 27 ± 2
0
C trong 28 ngày. Sau đó mẫu đƣợc đƣa đo độ bền
nén, độ bền uốn, lực cắt và độ hấp thụ nƣớc. Kết quả cho thấy các mẫu vữa đƣợc trộn
với tỷ lệ phế phẩm thay thế 10 - 15% xi măng, đạt tiêu chuẩn về độ bền nén, uốn, lực
cắt và độ thấm nƣớc. Đây là một kết quả tích cực trong việc tái chế và sử dụng chất thải
để sản xuất vật liệu hữu ích để tiết kiệm nguồn lực, phát triển theo định hƣớng - sinh
thái công nghiệp.
Từ khóa: vỏ trấu, xơ dừa, bùn thải giấy, phụ gia, vật liệu xây dựng
INTRODUCTION
Vietnam has advantages inagricultural production. Annual amount of excess wasteinthe
processing ofagricultural products, food is great. With the production of more than 38.5 million
tons of rice in 2009, only straw, rice husk waste during harvesting, the rice mill had tens of millions
of tons of mass. However, compared with abundant potential sources of secondary, agricultural
waste, the current study, the application is still modest. The amount of rice hulls, rice straw, coconut
fiber, sawdust could be used without much waste, thewaste discharged into the canals, rivers and a
high proportion, causing environmental pollution. Therefore, the utilization of this waste material to
be useful not only meant for recycling, but also sustainable development, conserving resources and
limiting climate change. In addition, some types ofindustrialwaste and pollution also need to be
processed. Technology of paper production is one ofthe polluting technology inthe creation of
large sludge treatment difficult. Sludge with a high cellulose and lignin, create more suspended
solids, black, odor, foam, high BOD and COD very difficult to handle. Paper recycling is a
necessity, however, the reverse of this action is generated sludge including sludge inthe process of
inking and finally thewaste must be buried into the ground.
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Currently, there are many directions for recycling ofindustrial wastes - is agriculture, such
as combustion boiler, as fertilizer In particular, this waste for recycling as construction materials
is also a considerable flow direction mind. This experiment was conducted with three subjects: rice
hulls, coconut fiber and sludge from wastewater treatment systems for the paper industryof
building materials. The aim ofthe project not only aims to make use ofwaste products - agriculture,
but also save natural resources, sustainable development
RESEARCH OBJECTIVE AND CONTENT
Research objective
This study aims to be making sample from mixing mortar to build models ofagricultural
waste products including rice husk, coconut fiber and sludge from wastewater treatment system of
the paper mill with cement, sand and water.
Research
The experiment included the following:
- Handling pre - determine the composition, physical and chemical properties ofwaste
samples.
- Determine the composition and properties of mixed materials: cement, sand and water
- Mixing cement, sand, water and paper sludge under different treatments with mortar model
for certification includes cement, sand and water.
- Determining the physical properties of cement mortar mixed paper sludge: density, water
permeability, compressive strength, bending strength with the traditional cement mortar.
RESEARCH METHODS
Determining the composition and preliminary treatment ofwaste product
Before performing experiments, have been identified: The origin arise, the primary features of
the sample or faulty products (size, color, smell, humidity, )
Rice husk taken from Duc Hoa District of Long An Province. After removing the husks inthe
dry state, foam, lightweight, and many impurities such as straw, hotel, land, gravel Coconut from
Hoc Mon District, Ho Chi Minh City. Sludge from the sedimentation tanks ofthe Binh An paper
factory.
(a) (b) (c)
Figure 1 The original agricultural-industrial waste
a) Rice husk ; b) Coconut coir ; c) Paper mill sludge
The samples were separated out impurities. Mud was deposited samples and dehydration.
Sample drying temperature 105
0
C until constant weight. Crushed sample and sieve samples through
0.25 mm sieve size. For rice husk and coconut fiber samples are heated at a temperature of 950
0
C to
remove carbon inthe sample composition.
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(a) (b)
Figure 2. Theagricultural–industrialwaste after preparation
a) Rice husk ; b) Coconut coir
Determination of physical and chemical properties ofwaste
The waste samples after pretreatment were measured indicators physical chemistry.
+ Physical properties: density, moisture content, specific surface area, components nuts
+ Chemical properties: activity level, calcium absorption, the composition of organic /
inorganic / ash ofthe material.
Using experiments to determine the physical and chemical properties of waste
Experiment type
Criteria
Sieves experiment
TCXDVN311-2004
Determine the physical and chemical properties
Calcium absorption
TCXDVN311-2004
TCVN 3735-1982
Water properties determination
Mixed water is domestic water. Mixed water is determined some parameters: pH, TDS, TSS,
Cl
-
, SO
3
2-
, CO
3
2-
.
Cement properties determination
Cement use is multi-standard cement of Holcim Vietnam company. This cement meets the
demand of TCXDVN311-2004 standard.
Sand properties determination
ISO Sand must comply with the provisions of gradation and moisture content. The
materialsand mix available for each plastic bag with 1350g 5g weight used for packaging not
affect the strength test results. The experiment uses standard sand was distributed by Ha Tien 1
Cement Company.
(a) (b) (c)
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(d) (e) (f)
Figure 3. Materials and tools. a) Paper mill slude, b) Sludge quantity, c) Cement
quantity, d) Standard sand, e) Sand quantity, f) Water quantity.
Mortar mixing preparation (TCVN 6016-1995, ISO 679-89)
Prepare 4 samples including mortar mix of materials: cement, sample waste, sand, water,
waste paper sludge which replaced 5, 10, 15, 20% cement.
The rate of sample volume consists of a traditional mortar part cement, three parts sand
and half the standard is water (ratio water / cement = 0.5).
For each batch will include: 450g 2 g cement., 1350 5 g sand and 225g 1g water can
make 3 samples.
Batch quantity
Cement, sand, water are at room temperature. Cement and sand should be balanced with an
accuracy of 0.01 g. When adding water, 225ml tube automatic, accurate 1ml.
Sample was mixed into thewaste form under the following treatments:
Sample
Weight (g)
Cement (g)
Sand (g)
Water (g)
Waste (g)
DC
450
1350
225
0
G-5
427,5
1350
225
22,5
G-10
405
1350
225
45
G-15
382,5
1350
225
67,5
G-20
360
1350
225
90
DC is the form for certification: samples only cement, sand and water, no waste.
Form 4 G-5, G-10, G-15, G-20 left: using waste instead turn 5, 10, 15, 20% cement.
For sample 0 (traditional ratio): The rate of water / cement = 0.5
Figure 4. Mortar mixers and molds of size 40 x 40 x 160 mm.
Mixing
Pour into blender and add cement. Run right and run the mixer at low speed, 30 seconds after
adding sand slowly during 30 seconds. Turn the mixer and the machine runs at high speed, continue
mixing for 30 seconds more. Stop mixer 90 seconds. Within the first 15 seconds using sticking
plaster flying rubber rakes inthe mortar, mortar and earthing bottom vegetation inthe middle.
Continue mixing at high speed for 60 seconds.
Casting sample
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Prismatic specimen size 40 x 40 x 160mm conducted after casting prepared mortar. Mold and
hopper tightly sandwiched goals tie, use a small shovel properly, contact one or two times to the
first spraying plaster molds for each compartment so that each compartment Stage 2 class. Then
plaster the first impacted by the ballast 60. Pour more plaster Monday, smaller aircraft are used in
mortar and plaster impacted by a further 60. Gently lift off the mold and remove the funnel into the
semiconductor. Rid of excess mortar with a metal bar to create a tricked stucco surface.
Maintenance of test samples
Brushing off excess mortar onthe edge of campus. This immediately put up the price of mold
horizontally in moist air or room inthe closet. Exposure to moisture to the surface ofthe mold.
Mold not overlap. Each mold will be removed from its place at the appropriate time for removing
the mold. After removing the mold samples are marked and packed in water inthe reservoir proper.
After sample preparation is finished, all samples were soaked in water temperature t = 27 ± 2
0
C in
28 days + 8 hour. For each mixing ratio, taking three samples. Results are calculated from the
average value.
Material is experienced 4 parameter: a) Compressive strength, b) Splitting tensile strength, c)
Water absorption, d) Density.
Density determination
Using density flask. Density is determinated:
In that:
a
(g/cm
3
, T/m
3
) is the mass of a unit volume material assumption
materials in special status fully. The volume ofthe material is 40 x 40 x 160 mm =
256 000 mm
3
= 256 cm
3
.
G: material weight (g)
m
1
: the volume of material and inthe same volume of water (g)
m
2
: water volume inthe same volume (g)
Water absorption determination (TCVN 3113, 1997, BS 1881, Part 112: 1983, BSI, 1983a)
Samples were dried in drying 24 hours, should determine the amount of C (kg). Then,
samples were soaked in water during 24 hour. Sampling from the water, weight loss E (kg).
Water absorption (%) =
100
EC
x
C
E: wet weight (kg)
C: dried weight (kg)
Compressive strength and splitting tensile strength determination
Experiment
Criteria
Compressive strength
TCVN 6016 - 1995, ISO 679 - 89
Splitting tensile strength
TCVN 6016 - 1995, ISO 679 - 89
Determination of splitting tensile strength
Place the prism model onthe side of testing machines with a title onthe title and knee roller
axis perpendicular to the sample of titles knee. Set the vertical load by the load roller to the opposite
side ofthe prism load and increase speed gradually to 50 ± 10N / s until fracture model.
Moisture needed for the half prism to try to bring stability when compressed.
Using this formula:
In which:
F: load is placed between the sample broken prism, calculated by (N)
l: distance between the knee is entitled, calculated (mm)
b: the next section ofthe square prism, calculated in (mm)
Determination of compressive strength
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Try half the strength ofthe prisms onthe face side of mold exposure
Place side of half prism into the middle ofthe plates with mismatch than ± 0.5 mm, and placed
horizontally so that the end face ofthe prism protruding outside the plates, or cheek pressed about
10mm.
Slowly with increasing load speed 2400 ± 200 N / s during the sample until destroyed. Using
this formula:
Fn : is the maximum load at sample destroyed, calculated as (N)
A: section under compression, calculated by (mm
2
: 40 x 40 = a 600mm
2
)
RESEARCH RESULT AND DISCUSSION
Material reviews
Cement material particles are mixed wastes less material finer than grains of pure cement.
Paper mill sludge samples are less smooth.
(a) (b)
(c) (d)
Figure 5. Material structure. (a) Cement, (b) Paper mill sludge, (c) Rice husk, (d) Coconut coir
Physical and chemical properties of material
Due to high water absorption of waste, should the country be mixed into the mortar samples is
higher than standard, so the ratio will be lower than normal grout material.
Sample
Density (kg/m
3
)
DC
G-5
G-10
G-15
G-20
Rice husk
390
381
376
355
324
Coconut coir
390
389
382
377
375
Paper mill
sludge
390
370
350
321
309
Rice husk samples have very high calcium absorption and can be completely used as additives
for mortar, helps increase the durability and waterproof.
Parameter
Unit
Sample
Rice husk
Coconut coir
Paper mill sludge
Moisture
*
%
7,8
15,1
8,8
Calcium absorption
Mg
156,24
99,17
82,83
*: Moisture: in room pressure and temperature.
Results showed that rice husk ash samples had very strong activity levels (mg CaO due to
adsorption by 1 mg samples were greater than 150mg). Coconut fiber and paper sludge major
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component ofthe cellulose so it is lime adsorption capacity at its average level. In addition, the
moisture content of coconut fiber and paper sludge is also higher than rice husk.
Water absorption
More and more the amount ofwaste water absorption ofthe material increased.
Sample
Water absorption (%)
DC
G-5
G-10
G-15
G-20
Rice husk
5,12
6,15
7,23
9,11
10,24
Coconut coir
5,12
7,34
9,25
11,37
13,66
Paper mill
sludge
5,12
8,31
11,56
14,34
18,78
Water uptake by the higher ash husk coir husk ash is very fine particles and light so the
surface area of water absorbed by a large husk ash. Coconut ingredients and nuts and it also weighs
more than rice husk ash, small surface area of water absorption so that the decrease.
Physical properties of mixed material (TCVN 6290-1997)
Figure 6. Sample G-10 and G-20 of rice husk after 28 days.
Figure 7. Sample G-10 and G-20 of coconut coir after 28 days.
Compressive strength
After 28 days, increased compression ratio decreases when mixed waste increased. It is because
water inthe material increases, leading to reduced gravity.
Splitting tensile strength
Similar to compression, bending ofthe material decreases when increasing the percentage of mixed
waste. It was found that when mixing a high percentage ofwaste increases the absorption of water
reduces the adhesive properties, decreased strength.
Sample
Symbol
Splitting tensile strength
(kG/cm
2
)
Compressive strength
(kG/cm
2
)
Compressive strength
reduction (%)
Rice husk
DC
6,85
41,30
0
G-5
6,78
39,51
4,36
G-10
6,23
37,93
8,16
G-15
5,91
32,52
21,26
G-20
4,12
24,61
40,41
Coconut
coir
DC
6,85
41,30
0
G-5
6,21
31,24
24,36
G-10
5,87
25,27
37,77
G-15
5,11
22,15
46,37
G-20
4,22
16,91
59,05
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-
The
ratio
of
waste
ceme
nt clinker phases to increase the proportion and magnitude decreases. Mixing mortar samples from
the husks down 4.36 to 40.41%, coconut fiber mortar samples decreased from 24.36 to 59.05%,
paper sludge mortar samples decreased from 14.21 to 41.43%. Because ofthe mixed waste into
cement, it will react with hydrated lime from the lime and the water free ofthe mineral calcium
silicate minerals are calculated to create sticky, slightly soluble or insoluble. Content of rice husk /
coir / paper mill sludge will make the intensity and mix ofwaste reduction depends on many factors
such as mineral composition, activity level, waste processing technology, the intensity of to produce
cement.
- Based on actual data can be seen that the strength of cement mortar produced from mixed
waste is greatly reduced intensity compared with traditional mortar samples. With such intensity,
only 10 samples% husks and paper sludge samples of 5% is standard. The other samples have not
reached the quality standard, so difficult that can be used for construction for the bearing structures
that can only be used for constructionofthe wall or walls. The volume of mixed cement mortar
samples and reducing waste than traditional models 100% mortar cement, so when put into
execution, it contributes significantly reduce the volume of work.
CONCLUSION
The experiment is still continuing. Nevertheless, through the survey is the first step could see
the positive signal from the process. The initial research results are as follows:
- - Samples of mixed waste to replace 5, 10, 15, 20% as cement ratio and compressive strength
of cement mortar significantly reduced from 4.36 to 40.41% for husk, from 24.36 to 59, 05% of
coconut fiber, 14.21 to 41.43% for paper sludge. However, this model still allows standard.
- Strength of cement mortar made from mixed waste is greatly reduced intensity compared
with traditional plaster models. With such intensity can not be used for construction for the bearing
structures that can only be used for wall construction or walls. Sample volume of cement mortar
mixed paper and sludge samples decreased more than 100% traditional mortar cement, so when put
into execution, it contributes significantly reduce the volume of work.
RECOMMENDATION
Inthe coming time, the research will continue to perform to perfection. Subsequent research,
the subject will perform a number of studies follows:
- Continue studies utilize sludge from wastewater treatment systems of paper machines
making concrete.
- Thestudy utilizes a number ofagricultural residue / additives to industrial activity inthe
construction materials.
REFERENCES
B. Ahmadi, W. Al-Khaja Utilization of paper waste sludge inthebuildingconstruction industry,
Department of Civil and Architectural Engineering, University of Bahrain, P.O. Box 32038,
Bahrain, 2000.
Hoang Thi Hanh, Experiment ofBuilding material, Ho Chi Minh City University, 2008.
Nguyen Xuan Hoang, Nguyen Bao Van, Tran Thanh Tuan, Pham Cam Nam, Study to use
diatomite making additives inbuilding material, Da Nang University, 2008.
Vu Hai Yen, Study using agriculturalwaste to produce building material, Ho Chi Minh City
University of Technology, 2010.
Paper
mill
sludge
DC
6,85
41,30
0
G-5
6,71
35,43
14,21
G-10
6,12
31,22
23,68
G-15
5,94
29,35
28,93
G-20
4,52
24,19
41,43
Criteria (TCVN 6260-1997)
14
. nghệ sinh học năm 2011 130 STUDY ON UTILIZING OF INDUSTRIAL – AGRICULTURAL WASTE IN THE BUILDING CONSTRUCTION INDUSTRY Vu Hai Yen Department of Environment and Biotechnology, Ho Chi Minh. limiting climate change. In addition, some types of industrial waste and pollution also need to be processed. Technology of paper production is one of the polluting technology in the creation of. million tons of rice in 2009, only straw, rice husk waste during harvesting, the rice mill had tens of millions of tons of mass. However, compared with abundant potential sources of secondary, agricultural