example of draft proposal for design project

PRODUCTION OF 10,000 METRIC TONNES PER YEAR OF AZELAIC ACID PLANT

SIDDIQ FADZIL BIN HAMZAH 2008297852

MAHDIAH BINTI YUSMADI 2008297746

ZULIAANIDA BINTI ZOHARI 2009652496

WAN NADZIRAH BTE WAN BADRUL HISHAM 2008297848

AHMAD MAHYUDDIN BIN MOHD MOHTAR 2008790647

A report submitted in partial fulfillment of the requirement for the award of Bachelor Engineering (Hons.) in Chemical Engineering

FACULTY OF CHEMICAL ENGINERRING UNIVERSITI TEKNOLOGI MARA

SHAH ALAM

CONTENTS

TITLE PAGE

CHAPTER l PRODUCTION OF AZELAIC ACID

1.1 Introduction 4

1.2 process Background 6

1.2.1 Ozonolysis 6

1.2.2 Stoichiometric Reaction 7

1.2.3 Chemically Catalyzed reaction 8 1.2.4 Biocatalytic Transformation 10

1.3 Process Selection 11

1.3.1 Comparison of process 11

1.3.2 Selection of Process 12

1.4 Application / Usage of Azelaic Acid 14

1.5 Process Details 15

1.5.1 Oxygen Generation Process 15 1.5.2 Ozone Generation and Oleic Acid

Absorption Process 18

1.5.3 Oleic Acid Ozonides Oxidation Process 19 1.5.4 Pelargonic Acid Distillation process 20 1.5.5 Azelaic Acid distillation Process 21 CHAPTER ll MARKET ANALYSIS

2.1 Introduction 22

2.2 Global Fats and Oil Production 23

2.3 World Consumption of Fats and Oils 23 2.4 World Consumption of Fatty Acid 25

2.5 Demand of Azelaic Acid 27

2.6 Import and Export Prices of Raw Material

and Products 28

2.7 Prices of Raw Material and product 36

CHAPTER lll SITE LOCATION

3.1 Introduction 48

3.2 Factors for Site Location 48

3.3 Proposed Site Location 52

3.4 Evaluation of Site Selection 55

CHAPTER 1

PROCESS INTRODUCTION

1.1 INTRODUCTION

Azelaic acid, with the formula (CH2)7(CO2H)2 is a saturated dicarboxylic acid exists as a white powder. Nowadays, Azelaic acid (AA) is commercially used as component in a series of applications such as polyamides, polyesters, pharmaceuticals, plasticizers, lubricants, or hydraulic fluids. It is utilized for food packaging (e.g., paper, film, and foil laminates), in electronics (e.g., flexible printed circuit board, coil insulation), textiles (e.g., footwear, interlining for labels, and emblems), and automotive (e.g., coatings, upholstered car seats, construction of sun visors) industries. Noted that, AA has superior solubility in organic solvents and water compared to other even chain C4–C12 dicarboxylic acids, which is advantageous in the formulation of high solids or solvent free systems. Polyamide 6.9 obtained from hexamethylendiamine and AA is characterized by low water absorptionand high-dimensional stability.

The total production of AA amounts to several 1000 tons/year. Nowadays, AA is technically produced by oxidative cleavage of oleic acid (OA) via ozonolysis. Besides, pelargonic acid (PA) is formed as a by-product in stoichiometric amounts. During the reaction pathway of ozonolysis, a primary ozonide is formed from OA and ozone via 1,3 cycloaddition,which is converted to a secondary ozonide. This 1,2,4-trioxolane can be oxidized to carboxylic acids under oxidative reaction conditions (Figure 1) .

Remarkably, various efforts have been done during the last years to improve the process or to find unpatented solutions. As demonstrated in the paragraphs below, alternatives to ozonolysis are highly requested due to huge energy demand ofthe process, to toxicity of ozone, and safety risks. Therefore direct methods of C––C double bond cleavage of OA to AAand PA and multi-step processes were developed whereas the latter include epoxidation and ring-opening to 9,10-dihydroxystearicacid (DSA) or metathesis. Furthermore, Wacker-type oxidations to ketocarboxylic acids were reported. These intermediates could be cleaved forming di- and monocarboxylic acids. In addition, biocatalyticmethods were reported for synthesis of AA .The advantages and disadvantages of all demonstratedmethods with regard to production in a technical scale is discussed in the next paragraphs.Preferred adducts for the synthesis of AA and its monomethyl ester (MMA) were OA and MO but also ricinoleicacid (RA) from castor oil.

1.2 PROCESS BACKGROUND

1.2.1 OZONOLYSIS

From the existed patent at current time, the total production of AA amounts to several 1000 tons/year. Industrially, AA is technically produces by oxidative cleavage of oleic acid (OA) via ozonolysis with pelargonic acid (PA) is formed as a by-product in stoichiometric amounts.

Figure 1.1 shows a commercial process for the production of azelaic acid from oleic acid.

1) 𝑂_{2) 𝑂}3/ 𝑂2 20−40 °𝐶

2 70−100 °𝐶 CH3 – (CH2)7 – CH = CH – (CH2)7 – COOH

Oleic acid

CH3 – (CH2)7 – COOH + HOOC - (CH2)7 – COOH

Oleic acid is cleaved by ozonolysis ( O3 concentration in the air: 1.0

vol%) at 20-40°C in pelargonic acid and water. The alkene residence time is about 10 min. The ozonide is then cleaved with oxygen at 70-110°C. Pelargonic and azelaic acids are separated from higher boiling point compounds by subsequent distillation. Azelaic acid is subjected to extraction to remove monocarboxylic acids; disillation of the extractant finally yields pure acids.

1.2.2 STOICHIOMETRIC REACTIONS

In producing azelaic acid (AA), used oxidants were nitric acid, permanganate, and dichromate. Despite of OA, RA, castor oil, and Vernonia galamensis seed oil containing vernolic acid radicals were investigated as the feedstock for the synthesis of AA. By using such oxidants, the yield of AA increased up tp 67-87% using phase transfer catalyst, emulsifiers alone, or in combination with ultrasonic treatment and permanganate as oxidants due to an improved mass transfer through phase boundaries.

Two stage methods were also described; OA was transferred to DSA by Cl2/NaOH which was cleaved to AA using chromic acid. Diepoxy-

tetrahydroxystearic acids were cleaved under strongly alkaline conditions to 29 and 43% AA respectively.

Nevertheless, these strong oxidants applied in multiple surpluses, showed insufficient product selectivity. Besides, it was found that product of chain degradation were often found beside other by-product to a higher extent. Thus, yield of the desired products of AA and PA are not competitive.

As for a newly research in Japan claimed an interesting approach with regard to ‘green chemistry’ and a environmentally kindly alternative to heavy metal oxidants. MO was cleaved in H2O2 /H2Ounder subcritical

Drawbacks of the afromentioned process were high energy consumption and corrosion problems.

1.2.3 CHEMICALLY CATALYZED REACTION

1.2.3.1 DIRECT CLEAVAGE OF MONOENIC FATTY ACIDS AND ESTERS

For the method of direct cleavage, strong oxidants were used which are currently not acceptable in terms of sustainable chemistry and economy. As for the example, the cleavage of castor oil using HNO3 as oxidant and ammonium vanadate or MnO as catalysts resulted in an unsatisfying selectivity toward the desired AA (15-16%). Based on Travis et. al and Borhan and co-workers isolated 80% MMA in the cleavage of MO with O2O4/oxone in DMF. Despite the high yield and selectivity, the method seems not to be technically feasible because of the toxicity and volatility of OsO4 and the formation of waste products from oxone.

1.2.3.2 TWO-STEP CATALYTIC CLEAVAGE OF OA OR MO

The method that was widely used is the epoxidation/ring opening of OA or MO using H2O2 and tungsten containing iso- or

heteropoly compounds followed by subsequent oxidative cleavage of the intermediate diol. Many advanced research had been carried in determining the best method. Based on Nuramat and Eli and Ayshemgul, OA and tungstic acid react in an ionic liquid. the cleavage of the diol was performed with peracetic acid, the obtained yield of AA was in the range of 39-46%. A chinese patent claimed the usage of isopropanol as solvent in first step and mentioned 75% yield of AA with the used of microwaves led to an improvement in AA up to 75-85% yield. Nevertheless, used oxidants such as peracidsare regarded as problematic in terms of ecology.

1.2.3.3 THREE-STEP CATALYTIC CONVERSION OF MO

The metathetic ethenolysis of MMA enebles a three-step procedure. The obtained terminal unsaturated 9-decenoic ester can be ketonized with a Wacker-type catalyst. Then the intermediate is cleaved by a Mn catalyst to a mixture of C8 and C9 dicarboxylic acid monoesters. Oxidants in both last two steps was O2.

Figure 1.2

Main reaction pathways for the cleavage of OA to PA. (A-direct cleavage,B-two

step route including formation of epoxidized oleic acid and/or DSA,C- tw step pathway involving metathesis of OA followed by cleavage of the intermediate,D-three step route including metathesis/formation of a ketocarboxylic acid/cleavage to AA)

1.2.4 BIOCATALYTIC TRANSFORMATION

Basically, different enzymes obtained from yeast and other microorganisms were successfully employed for the synthesis of AA. Both the oxidative degradation of C18 units and the oxidation of the terminal CH3 group of PA were investigated. Two patents described the

combination of enzymatic and chemical transformations. In the first step, the synthesis of dihydroxy fatty acid was performed using non-specified lipases. Whereas the second step, the cleavage of the diol with 60-70% yield of AA and PA, was carried out conventionally with peracid as oxidant in a Chinese patent.

The Fermentation of OA or triglycerides with Candida tropicalis enzymes to 1,19 nonadec-9-enoic acid followed by ozonolysis or chemically induces C=C cleavage to AA and PA with strong oxidants such as H2O2

was reported in US patent. The first step, fermentative oxidation of the terminal CH3 group took a very long time (about 110-180 hours) and

about 45-67% yield of diacid were obtained. The avoidance of PA during the chemically induced cleavage is seen as a advantage. The method is also useful for the oxidation of PA to AA. In this case, AA could be obtained directly via terminal fermentation oxidation. The drawback of the process may be the availability of PA.

1.3 PROCESS SELECTION

1.3.1 COMPARISON OF ADVANTAGE AND DISADVANTAGES

Table 1.1: Comparison of Advantages and disadvantages of method producing Azelaic Acid

ADVANTAGES DISADVANTAGES

1. OZONOLYSIS

1. Absence of environmentally critical waste from the oxidant

2. Good selectivity

3. Enable simple reprocessing of PA into ozone absorber to reduce viscosity of OA.

4. Yield up to 78-80%

5. Easy to generate ozone from commercialized oxygen

1. Huge energy demand 2. Toxicity of ozone 3. Safety risk

4. The obtained yield of AA was often lower

2. STOICHIOMETRIC REACTION 1. Yield up to 60-87%

(using phase transfer catalyst)

1. Use only for scientific interest 2. Not suitable for an industrial

application (regard to sustainability)

3. Insufficient product selectivity (strong oxidants applied in multiple surplus)

4. Yields of AA and PA are not competitive

3. CHEMICALLY CATALYZED REACTION

1. Strong oxidants were reported 1. but not acceptable interms of sustainable chemistry and economy

2. Waste products originating from oxidants are detrimental

3. Solvent used are problematic 4. Expensive cost of catalyst 4. BIOCATALYTIC TRANSFORMATION

1. Avoidance of PA formation 2. Oxidation of PA to AA

3. AA obtained directly via terminal fermentation oxidation

1. Availability of PA

1.3.2 SELECTION OF METHODS

Table 1.2: Survey on relevant methods described in scientific and patent literature for synthesis of AA

Substrate Oxidant YAA/MMA (%) Reported catalyst/catalyst precursor

Method Classification

OA Azone/O2 80 - Ozonolysis

MO Oxone 93 OsO4 Chemically

catalyzed reactions

OA NaIO4 Quant. KMnO4 Chemically

catalyzed reactions

Potassium oleate NaOCl Quant. RuO4 Chemically

catalyzed reactions MO NaIO4 (electrochemically regenerated) 62 RuCl3 Chemically catalyzed reactions OA H2O2 92 H3PW12O40/PTC a) Chemically catalyzed reactions MO H2O2 97b) Alkylated polyethylene-imine/ {PO4 [WO(O2)2]4}3- Chemically catalyzed reactions OA H2O2 / O2 56 1) H2WO4 ; 2) 2) H2WO4 / Co(acac)3 /N-hydroxyphthalimide Chemically catalyzed reactions OA O2c) 67 C. tropicalis Biocatalytic transformation a) _{Cetylpyridinium Chloride} b) _{Methyl 9-oxononanoate}

c)_{Transformation to 9-octadenedioic acid} Sources: (Kockritz & Martin, 2010)

Based on listed advantages and disadvantages, Stoichiometric reactions and Biocatalytic Transformations were eliminated straight away. A stoichiometric reaction is used only for scientific interest and not suitable for industrial application. In addition, yields of AA and PA are not competitive. Biocatalytic Transformation require the usage of different enzymes obtained from yeast and other microorganisms for the synthesis of AA, which would make it hard to handle the enzymes used for large production of AA.

Consider the remaining two alternatives. Chemically catalysed reactions with H2O2 as oxidant may produce larger yields of 92% of YAA/MMA. Meanwhile, Ozonolysis produce yields of 80% of YAA/MMA. The comparison of oxidant used for Ozonolysis method and chemically catalysed reactions has been made. Hydrogen peroxide is an environmentally benign oxidant because water is formed as the only by-product during oxidation. However, it was applied repeatedly in presence of a catalytic system of phosphoric acid/tungstate or tungstophosphoric acid and an ammonium phase transfer catalyst. Cost of H2O2 may be the drawback as well. In addition, the mixture of H2O2 raises uncertainty concerning the nature of the active species. Apart from that, about 50% of H2O2 decomposed unutilized, which make this method inefficient from the economical point of view.

Apart from that, the cost of catalyst is more expensive rather than to have ozone generator plant. Thus, it is preferable to have ozone generator in AA production plant instead of using catalyst. In Ozonolysis process, the high production of by-product, Pelargonic Acid (PA), is not a challenge because PA is recommended as viscosity reducers and ideal diluent; it does not interfere with the operation of the circulating oxygen system and requires no separate distillation. In other words, PA is recycled back that makes it unnecessary to introduce an additional chemical compound into the system to serve as diluent and viscosity reducer which result in reducing cost of chemical used. A practical alternative to ozonolysis was not found, even if high yields of AA were reported with H2O2 as environmentally benign oxidant. The best oxidant so far is Ozone.

A multitude of synthesis methods for AA is evaluated in terms of feasibility and sustainability. Up to now, no alternative to industrially employed ozonolysis of Oleic Acid (OA) was developed. Thus, the proposed method in producing Azelaic Acid (AA) is by Ozonolysis.

1.4 Application/Uses of Azelaic Acid

Azelaic acid (AA) is commercially used as component in a series of applications such as polyamides, polyesters, pharmaceuticals, cosmetics, plasticizers, lubricants, or hydraulic fluids (Kockritz & Martin, 2010). It is an excellent choice as a modifying agent in the production of co-polyester polymers. AA is utilized for many ranges of industries. 1.4.1 Food Packaging

In food packaging industry such as paper, film, and foil laminates use Azelaic Acid widely. The linear saturated polyesters are hard, semi-crystalline thermoplastics that are impact resistant even at low temperatures, smooth and have good wear resistance. Their glass temperatures are around 67-80⁰C and the melting temperature Tm = 255⁰C.

These criteria make Azelaic Acid the most reliable component. 1.4.2 Cosmetics

Cosmetic uses Azelaic Acid to treat acne, reduce skin discoloration, prevent hair loss, and improve Rosacea (skin condition) by having the ability to kill the bacteria on the skin that causes them. Moreover, it is also able to break down and remove dead cells on the skin surface. The related product are Desertliving Cistanche Herb Extract, Echinacea extract, Epimedium extract, Flaxseed extract, Garlic extract, Ginkgo Biloba extract, Ginseng extract, Mulberry Fruit extract, Pomegranate extract, Pueraria extract, Reishi Mushroom extract, Resveratrol, Saw palmetto fruit extract, Shitake mushroom extract, Tribulus Terrestris extract, Wlofberry extract (Agriculture Source, 2010).

1.4.3 Complexing Agent

Furthermore, Azelaic acid is finding increasing application as a complexing agent for lithium complex greases and synthetic lubricant ester base fluids in lubricant industry. 1.4.4 Electronics Industry

In electronics industry, flexible printed circuit board, coil insulation requires the use of Azelaic Acid as well. There is also high demand in textiles (e.g., footwear, interlining for labels, and emblems), and automotive (e.g., coatings, upholstered car seats, construction of sun visors) industries.

1.5 PROCESS DETAILS

1.5.1 Oxygen Generation Process

Figure 1.3: VPSA Oxygen Generator (Source: MVS Engineering)

This azelaic acid plant will used on-site oxygen generator because of the plant’s high usage of oxygen. In this plant, oxygen is used as feed gas for ozone generator, used for oxidation reaction and for waste and water treatment. Therefore, it is necessary for oxygen to be supplied continuously in large volume.

To provide sufficient oxygen demand for Azelaic acid plant Vacuum Pressure Swing Adsorption (VPSA) Oxygen generators are used. This process based on high efficiency adsorbent material and is low cost solution for high oxygen demand. VPSA is popular technique, a reliable and economic on-site supply method, used in producing oxygen from 250 to 5000 cubic meter per hour or more, with purity levels ranging from 90 to 95% (AIRMAX System Co., Ltd., 2010).

This process consists of two beds filled with molecular sieves that cycle alternately in production and in regeneration. Feed air pressure is generally 1.1 to 1.5 bar, which gives oxygen production at 1.05 to 1.3 bar. Regeneration of Molecular sieves is done by a vacuum pump 0.4 bar absolute pressure. The waste gas is 85% nitrogen and 15% oxygen which are vented to atmosphere. Product oxygen gas purity is 90 to 95%.

These two beds functioned as adsorbers. As feed air flow through one of these beds, the molecular sieve adsorbs nitrogen. The remaining oxygen passes through the vessel and exits as the product gas. Before the adsorber becomes saturated with nitrogen, the feed air is diverted to the second bed. The sieve in the first bed regenerates by desorbing the nitrogen through depressurization and purging it with oxygen from the second bed. This process is repeated in the second bed to complete a cycle that allows the oxygen generator to deliver a constant flow of product oxygen of 90 to 95% purity. Under normal operating conditions, the molecular sieve is completely regenerative and will last indefinitely.

The use of pure oxygen is preferred and recommended than the use of air because of the following reasons:

i. The process involves two steps which liquid and gas must be brought into sufficient intimate contact to react chemically. The presence of 80% inert nitrogen complicates the problem of contacting to prompt reaction.

ii. Ozone is more efficient being produced from ozonized oxygen than ozonized air.

iii. Ozone generator and equipment for oxidation process would be larger and slower reaction if air is used instead of oxygen because greater gas volume. iv. The presence of nitrogen tends to cause discoloration of finished product.

v. The gas tends to entrain some organic vapor. The use of air would increase volatilization losses.

VSPA Oxygen generator is acquired from MVS Engineering, New Delhi, India the leading manufacturer of VPSA Oxygen Plants based on the reviews and benefits of VSPA Oxygen Generator of the company.

Table 1.3: Reviews of VSPA Oxygen Generator Technology

Reviews Description

Well suited for larger capacities

 Lower power consumption in larger capacities (above 200

NM3/hr capacities).

Lower power

consumption

 Power consumption is only 0.45 KW per cubic meter of

Oxygen produced.

Lower output pressure  Direct Oxygen production pressure is up to 1.3 Bar.

 For higher Oxygen pressure requirement, Oxygen

compressor is added and supplied. Higher Investment  More costly to build.

 More efficient operation, extra cost is easily recovered in

short time Source: MVS Engineering

Table 1.4: Benefits of VSPA Oxygen Generator Technology

Benefits Description

reliable,

well-proven technology

 Has been used for several years and are operating successfully around the world.

 use molecular sieves from only well renowned and reputed suppliers

 Years of trouble free operation and long life from investment.

fast startup  These units can be turned ON and OFF

on-demand with the push of a single button.

 Only require 15 minutes to start producing high purity Oxygen.

modular design  allows easy transportation and easy installation of

the system

 Engineer is present at site to oversee installation and

also to assist with commissioning and training of personnel.

continuous, uninterrupted supply and guaranteed purity

 Independence of oxygen supplier.

 Guarantee of the purity of oxygen.

high quality  uses best quality molecular sieves

Table 1.5: Operating Conditions of Oxygen Generator Specification Range

Capacity 200 Nm3/hr to 5000 Nm3/hr

Purity 90% to 95%

Pressure Up to 1.3-Bar without oxygen booster compressor Dew Point (-) 40°C

1.5.2 Ozone Generation and Oleic Acid Ozone Absorption Process

Oxgen generates from VSPA Oxygen Generator then fed to ozone Generator to produce ozone. Ozone produced is then fed to the ozone absorber. OA is fed through the feed tank and then to the ozone absorber, in which the oleic acid is flowed counter currently to a continuous flow of oxygen gas that contain ozone. The ozonized oxygen gas is fed to the absorber which the oxygen circulates.

For 1000 kg of OA, 9700 kg of ozonized oxygen are employed. The circulating oxygen is then fed to absorber, which its ozone content is absorbed by OA. Then, the oxygen gas, now substantially devoid of ozone, passes through the electrostatic precipator, in which organic matter that may have been picked up in the absorber is electrostatically precipitated. The purified oxygen gas is then passes through compression pump, to cooler and dehydrator, which all moisture is removed from the oxygen gas. Oxygen gas is drawn from the system through valve, to the ozonide decomposing system.

The primary ozonide reaction in the ozone absorber is as follow:

H3C(CH2)7CH=CH(CH2)7COOH + O3 → CH3(CH2)7C-O-O-O-C(CH2)7COOH Oleic Acid + Ozone → Oleic Acid Ozonide

The oleic acid ozonides are then scisson to produce secondary ozonide. The secondary ozonide reaction in the ozone absorber is as follow:

[H3C(CH2)7-C=O+-O- O=C-(CH2)7COOH] → [H3C(CH2)7-C=O+-O- O=C-(CH2)7COOH] →

Table 1.6: Ratio of OA and ozonized oxygen in the ozone absorber

OA Ozonized oxygen

Feed stream 1000 kg (basis) 9700 kg

Ratio 1 9.7≈10

Table 1.7: Operating Conditions of Ozone Absorber

Specification Range

Temperature 20°C - 40°C

Diluent Recycled Pelargonic Acid

Residence time 10 minutes

1.5.3 Oleic Acid Ozonides Oxidation Process

The ozonide decomposing system comprises series reactors, which the OA ozonides are reacted with the oxygen gas. The total numbers of the series reactors are depending on the size of the reactors, the rate of the flow of ozonides and their decomposition products and the efficiency of the agitation in effecting contact between the oxygen gas and the liquid being treated. The ozonized OA is treated with oxygen gas for a period of approximately six hours. The ozonides are heated to temperature between 70 - 110°C which the ozonides decompose. Both the scission of ozonides and the oxidation of aldehydes are exothermic reactions producing sufficient heat to maintain temperature of 95 °C.

As the ozonides and their decomposition products pass from one reactor to reactor, the rate of oxidation tends to fall thus it is desirable to supply heat to the last reactor to maintain temperature suitable for efficient oxidation. The desirable heating or cooling devices on the reactors depends on the number of reactor used, the rate of flow and the efficiency of the agitation. For each kilogram of ozonized OA treated, 0.1 kg of oxygen gas of substantially 98% purity is employed. The oxidation reaction of oleic acid ozonides to AA and PA is as follow:

CH3(CH2)7C-O-O-O-C(CH2)7COOH + O2 → HOOC-(CH2)7-COOH + CH3(CH2)7-COOH Oleic acid ozonides → Azelaic Acid + Pelargonic Acid

Table 1.8: Operating condition of ozonide decomposing system

System Series reactors

Number of reactors Depends on size, ozonides and decomposition products flow rate, efficiency of agitators

Reaction time 6 hours

Reaction temperature Between 70-110°C or maintain at 95° Ratio oxygen to

Ozonized OA 1:10

Yield of AA 80%

1.5.4 Pelargonic Acid Distillation Process

From the last reactor, the mixed oxidation products are passed through distillation column (DC) where PA is distilled. The operation is performed by maintaining DC temperature of 230°C and a vacuum of 25 mm of mercury. PA is then condensed and removed from DC to PA storage tank. Some of the PA from the DC is recycled in the system to dilute the OA and OA ozonides. PA is recycled to the absorber to reduce the viscosity of the ozonides in the absorber. Valve is installed to control the amount of recycled PA. For 1000 kg of OA treated, 40% of this amount is PA recovery. The total PA recovery amount to 900 kg, that is 500 kg used for dilution of the OA and 400 kg of new PA freshly produced from the OA being processes.

PA is used as viscosity reducer and diluents because because:

i. PA is end product if the process, unnecessary to introduce new chemical as a diluent or viscosity reducer.

ii. Does not interfere with the operation of circulating oxygen system iii. Requires no separate distillation

Table 1.9: Operating conditions of first DC

Temperature 230°C

pressure Vacuum of 25 mm mercury

PA recovery (basis: 1000 pounds OA treated)

40%

1.5.5 Azelaic Acid Distillation Process

The mixed oxidation products now stripped of PA is carried to second DC in which other volatile acids are distilled from the non-volatile waste products. This operation is performed at a temperature of 270°C with pressure of 3-4 mm of mercury. The volatile products are condensed and passed to a mixed acid storage tank. The non-volatile pitch which remains is removed. The mixed acids include AA and wide variety of undetermined identity, compromises 15 to 20% of the mixed oxidation products.

Table 1.10: Operating conditions of second DC

Temperature 270°C

pressure 3-4 mm mercury

1.5.6 Azelaic Acid Extraction Process

Then, AA and the waste acids are separated. From the mixed acid storage tank, the acids are fed through extractor where the AA is extracted with hot water at temperature of 95°C. The water is then drawn off and evaporated leaving a residue of 52% AA based on 1000 kg OA. The water insoluble acids which remain after withdrawal of water containing 18% of AA base on 1000 kg of OA treated. Waste acids that do not dissolve in hot water are removed from the extractor. The hot water containing AA is fed through the evaporator, which the water is removed from the AA. Then, AA in molten condition is fed to the flaker, and to the AA storage tank.

Table 1.11: Operating conditions of extractor

Temperature of hot water 95°C

Composition of AA 52% AA residue, 18% AA remains from water insoluble acids

CHAPTER 2

MARKET ANALYSIS

2.1 Introduction

In Malaysia. The palm oil processing industry has grown to become the most important agro-based industry in the country, characterized mainly by the palm oil refining and fractionation sectors producing a wide variety of semi and fully processed palm oil products. Utilization of palm oil and palm kernel oil in high value added products in oleochemicals has made good progress, although prospects for further rapid increases are very food especially with the continued support of the Malaysian government in terms of providing cross cultural and institutional support facilities and other incentives.

Although 90% of palm oil produced is used in the production of food, there is increasing potential for its use in another sector, mainly in oleochemicals which currently utilizes 2% of palm oil in production of oleochemicals. Presently, it is estimated that only 10% of the world’s oleochemicals are manufactured from palm oil and palm oil kernel. Progress in oleochemicals industry in Malaysia has been made at a steady pace. The Malaysian oleochemicals industry, being an export oriented industry, exported more than 95% of its total output.

2.2 Global Fats and Oil Production

Oleochemicals are generally chemical products derived from animal or vegetable triglycerides, even if they contain elements of petrochemical origin. The worldwide production of fats and oils are shown in Figure 1. Based on the Figure, the highest country that produces fat and oil such as azelaic acid is China with 17 million tones. This fat and oil is produced for several applications such as for the production of fatty acid based chemical and for food applications. Vegetable oil production is app 8 M tonnes, most of which is soy. Malaysia produces 15 million tonnes of oil and fats. Market demands for chemical uses have been normally tied to economic activity which is projected 2% annual growth.

2.3 World Consumption of Fats and Oils

China, Malaysia, the United States, the European Union, Indonesia, India, Brazil and Argentina are notable fats and oils producing countries, and China, the European Union and India are notable high-demand areas that must supplement regional production through imports. The following graph shows world consumption by country/region:

Source: http://www.sriconsulting.com/CEH/Public/Reports/220.5000/

Global fats and oils consumption will grow at an average annual rate of 4%, mainly as a result of growth in China and India. Growing economies, large populations and improving incomes will increase per capita demand for oils and fats in these countries. Also, demand for biofuels (mainly from rapeseed and palm oils) will increase demand in Europe. In the United States, fats and oils consumption will grow only slightly, at 1–2% per year.

In the United States, product substitution will continue within the fats and oils industry. Soybean oil has shown and will continue to show growth. Tallow and grease will show only slight growth as a result of increased substitution with healthier vegetable oils. Tall oil will decrease slightly as a result of a decline in the pulp and paper industry. Corn oil is expected to increase as a result of increased ethanol production and more feed uses. Butter and lard consumption will also increase because of an expected increase in pork production.

The United States remains the world’s largest producer and consumer (slightly ahead of China) of the world’s most voluminous oil—soybean oil. U.S. soybean oil now faces severe export competition from low-cost production in other countries, notably Argentina and Brazil and Western European countries, which have increased production of this commodity oil in recent years.

As a whole, EU countries are among the world’s largest consumers of fats and oils and must import over 32% of their annual demand. In 2004, EU consumption totaled almost 20 million metric tons, of which 72% was accounted for by Germany, Italy, Spain, the United Kingdom and France. The CIS and Eastern European countries must also augment domestic production with imports.

Japan imports the majority of its vegetable oils either as raw materials (such as vegetable seeds) or as final products. However, most animal fats and marine oils are produced from domestic sources. Crude tall oil is no longer supplied from the domestic pulp industry and must be imported.

2.4 World Consumption of Fatty Acids

In recent years, the buildup of significant fatty acids production capacity has continued in Southeast Asia. Companies in these countries formed joint ventures with U.S., Western European and Japanese fatty acid producers, with production being exported to the parent companies in the United States, Western Europe and Japan. Recently, parent companies have shifted much of the production to these Southeast Asia sites, where overall production costs are often lower.

There has been an increase in global fatty acid demand as a result of end-use consumption growth, as well as strong oleochemicals (fatty acids, fatty alcohol, glycerin, etc.) growth and competition, particularly in Asia. Whether used as such or in the form of various derivatives, fatty acids are ultimately consumed in a wide variety of end-use industries. The economic growth of many of these industries (e.g., rubber, plastics and detergents) is often a good indicator of the overall economic performance of a region. The following pie chart shows world consumption of natural fatty acids:

Source: http://www.sriconsulting.com/CEH/Public/Reports/657.5000/

Among the trends in the industry are the following:

 Use of oil and fat feedstocks in place of petroleum-based feedstocks to produce biofuels, plastics, etc. will create competition for fatty acids production/supply, and affect pricing. However, this use will largely be dependent on crude oil prices and whether switching costs make sense.

 Tax credits/subsidies or environmental legislation can create can create competitive advantage for biofuels over fatty acids production in teerms of securing raw materials.

2.5 Demand of Azelaic Acid

Table 2.1 Demand of Azelaic Acid

Country Demand (tones/year)

2006 2011 2016 2021 2026 2031 United States 11700 14625 18281 22852 28564 35706 Europe 800 1000 1250 1563 1953 2441 Japan 900 1 125 1406 1758 2197 2747

The need for increased azelaic acid capacity is due to growth in existing and new market segments such as packaging (paper, film & foil laminates), automotive (coatings, upholstered car seats, construction of sun visors), textiles (footwear, interlining for labels and emblems) and electronics (flexible printed circuit board, coil insulation). Azelaic acids have superior solubility in solvents and water than other commercially available even-chain carbon (C4 - C12) dicarboxylic acids, which is a highly desired property in the formulation of high solids or solvent free systems.

0 5000 10000 15000 20000 25000 30000 35000 40000 2006 2011 2016 2021 2026 2031 D e m an d (t o n n e s/yea r) Year United States Europe Japan

The current market volume for azelaic acid is 11,700 tonnes/year in the United States, 800 tonnes/year in Europe and 900 tonnes/year in Japan. This market is growing at a pace of 5 to 6% yearly (Vannozzi, 2006). The demand of azelaic acid for every five years can be seen in Figure 2.4.

2.6 Import and Export Prices for Raw Materials and Products 2.6.1 Oleic Acid Country Price (RM/kg) 2009 2010 2011 World 8.06 9.44 13.23 China 8.48 5.75 6.45 South Korea - - 9.41 Japan 5.94 8.83 10.88 United States 14.87 20.81 31.82 Singapore 7.26 9.79 11.37 India - - 58.63 Belgium - - 22.41 France - 111.48 - Germany 32.43 - - Netherlands - 3.66 - Sweden 8.70 85.47 - Switzerland 9.18 9.28 - United Kingdom 9.25 - - Taiwan - - 3.18 Thailand 6.49 - - Australia - - 7.80 Source: MATRADE, 2011

According to Figure 2.5, Malaysia’s import of oleic acid from Germany indicates the highest price with RM 32.43 per kg and followed by United States with RM 14.87 per kg. The lowest price of Malaysia’s import of oleic acid is from Japan with RM 5.94 per kg.

The highest price of Malaysia’s import of oleic acid is from France in 2010 with average price of RM111.48 per kg and this is the highest average price among the three consecutive years. Sweden is the second highest in 2010 with average price of RM 85.47 per kg and the lowest average price for Malaysia’s import of oleic acid is from Netherlands with the average price of RM 3.66 per kg.

In 2011, Malaysia’s import of oleic acid from India with RM 58.63 per kg and it is the highest average price for recent year. United States stated the second highest average price for Malaysia’s import of oleic acid which is RM 31.82 per kg. The cheapest average price is from Taiwan with RM 3.18 per kg. Malaysia’s import of oleic acid from China, Japan, United States and Singapore are consistent in the three consecutive years. 0 20 40 60 80 100 120 2009 2010 2011 P ri ce /k g (R M ) Year China Korea, South Japan United States Singapore India Belgium France Germany Netherlands Sweden Switzerland United Kingdom

Figure 2.6 showed the average price trend for Malaysia’s import of oleic acid. The average price for Malaysia’s import of oleic acid increased with the year. This is due to the increase of other cost such as transportation, high demand of oleic acid and etc. Year 2009, the world average of Malaysia’s import of oleic acid is RM 8.06 per kg and encounters a slight increase in 2010 to RM 9.44 per kg. In 2011, the price showed rapid increase to RM 13.23 per kg. 0 2 4 6 8 10 12 14 2009 2010 2011 A ve ra ge P ri ce (R M /k g) Year

Source: MATRADE,2011 3 3.5 4 4.5 5 2009 2010 2011

A

ve

ra

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P

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(R

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)

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Trending Price of Oleic Acid

Country Price (RM/kg) 2009 2010 2011 World 3.61 4.47 3.22 Korea, South - - 16.73 Brazil - - 8.65 Pakistan 12.79 2.00 6.84 Netherlands 5.25 5.58 Japan 7.42 5.73 5.32 United States - - 5.02 Australia - 4.08 4.98 Germany 3.61 4.47 4.19 Taiwan - 6.50 3.43 China 5.68 4.72 3.22 Hong Kong - 10.97 - India - 2.57 -

Figure 2.7 Average price of Malaysia Oleic Acid Exports

Figure 2.8 Malaysia Exports of Oleic Acid (pricing unit)

The above chart shows the value of Malaysian exports of OA to the external countries. Based on year 2009, obviously the exports of OA is quite low which the supply is made to only four countries noted Pakistan, Japan and China with price of OA per kg are 12.79, 7.42 and 5.68 respectively. For year 2010, the exports value increased as the supply market increased as well. From the pie chart, the highest demand is from Hong Kong with 10.97 (MYR) per kg of OA. Whereas on the recent years in 2011, the exports of OA maintained its supply market with slightly a change in supplied countries with the highest demand comes from South Korea with 16.73 (MYR) of OA per kg.

Basically, the priced of supplied OA will depend on the current market also the demand from the respected country. Comparing the three recent pie chart of year 2009, 2010 and 2011, the exports of OA are increasing which shows the OA is currently needed in particular industry. As in ozonolysis process to produce AA, OA is the main raw material that will be react with ozone in order to obtain AA. Azelaic Acid (AA) is a chemical product that industrially used such in for food packaging, automotive and electronics. 0 2 4 6 8 10 12 14 2009 2010 2011 P ri ce (R M /k g) Year Korea, South Brazil Pakistan Netherlands Japan United States Australia Germany Taiwan China

Based on the price trending of Malaysia Oleic Acid exports data, from the constructed graph, obviously the price of OA is fluctuated. At year 2009, the average price of OA is 3.61 (MYR) per kg whereas at year 2010, the price increased to 4.47 (MYR) per kg. At the current year, 2011 the price is slightly decreased to 4.19 (MYR) from the previous year. We can also conclude from the graph that the export of OA is decreasing. Many factors might affect the trend such as the current stock market also the less demand of OA from the worldwide industry.

2.6.2 Oxygen

Table 2.4 Average Prices of Malaysia Export of Oxygen

Country Price (RM/m3) 2009 2010 2011 World 181.58 422.09 541.56 Indonesia - 649.40 1,062.79 Brunei Darussalam 790.64 543.94 653.02 Singapore 139.90 381.32 322.30 Philippines - 445.41 - Thailand - 423.06 - Source : MATRADE,2011

Figure 2.9 Average price of Malaysia Oxygen Exports 0 100 200 300 400 500 600 2009 2010 2011

A

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3

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Based on the price trending of oxygen, over the past three years, the price of oxygen is currently increased. At year 2009, the price of exported O2 is 181.58 (MYR) while at year 2010, the price is at 422.09 per m3 (MYR). On the recent year, 2011 shows the highest price which is at 541.56 (MYR) per m3 of O2. Obviously, the demand of O2 from Malaysia is increasing as well as the price goes up. The record showed that Malaysia supplied O2 to Indonesia with the highest price at 1062.79 (MYR) per m3 in 2011. It can be conclude that Malaysia has the high availability of supplied O2 to its respected country.

Figure 2.10 Average Prices of Malaysia Export of Oxygen

Based on the chart above, the average price of Malaysia’s export of oxygen in 2009 only to two countries which are Brunei Darussalam and Singapore with Brunei has the highest average price which is RM 790.64 per m3. In 2010, Indonesia recorded the highest average price with RM 649.40 per m3 and on that year, Malaysia export of oxygen to various countries compared to 2009 and 2011. The highest average price for Malaysia’s export of oxygen to Indonesia is the highest with RM 1,062.79 per m3 _and the lowest is Singapore with RM 322.30 per m3.

0 200 400 600 800 1000 1200 2009 2010 2011 P ri ce (R M /m 3) Year Indonesia Brunei Darussalam Singapore Philippines Thailand

2.6.3 Azelaic Acid

Country Average Price (RM/kg)

2009 2010 2011 World 10.44 20.97 8.22 Greece - - 5.52 South Korea 23.89 - 12.30 India 25.14 25.33 - Indonesia 3.95 17.02 - Taiwan 23.37 - - Source: MATRADE, 2011

Based on Figure 2.11 that showed the average prices for Malaysia’s export of azelaic acid, Malaysia only export azelaic acid to four countries and it decreases as the year increased. In 2009, the highest average price that Malaysia export is to India with the average price of RM 25.14 per kg and the lowest price is Indonesia with RM 3.95 per kg. The next year, Malaysia only exports azelaic acid to two countries which are India and Indonesia with the highest average price is India with the average price of RM

0 5 10 15 20 25 30 2009 2010 2011 P ri ce (R M /k g) Year Greece Korea, South India Indonesia Taiwan Table 2.5 Average Prices for Malaysia’s Export of Azelaic Acid

25.33 per kg. In 2011, Malaysia’s export of azelaic acid to Greece and South Korea with the highest average price of export is to South Korea with RM 12.30 per kg. Based on the analysis, the demand of azelaic acid for export is less.

As shown in Figure 2.12, the average price for Malaysia’s export of azelaic acid is unstable. In 2009, the average price indicated RM 10.44 per kg. The next year, it increases rapidly and almost doubled from the average price of the previous year. Then, it encounters a slight decrease in 2011 to RM 8.22 per kg.

2.7 Price of Raw Materials and Products

2.7.1 Price of Raw Materials

Raw Material Price (RM/kg) Source Country

Oleic acid

3.38 http://www.icis.com England

13.41 http://www.chemistrystore.com United States 4.62 http://www.alibaba.com China 0 5 10 15 20 25 2009 2010 2011 P ri ce (R M /k g) Year

Figure 2.12 Average Price Trend for Malaysia’s Export of azelaic Acid

2.7.2 Price of Products

Products Price (RM/kg) Source Country

Azelaic acid

310.27 http://www.alibaba.com China 250.72 http://chemicalland21.com Indonesia 348.17 http://www.coleparmer.com United States

Pelargonic acid

156.70 http://chemicalland21.com Korea 14.73 http://www.made-in-china.com China 205.89 http://www.tcieurope.eu Europe

2.8 Breakeven Analysis

Breakeven analysis is the most common tools used in evaluating economic feasibility of a new enterprise or product. The break-even point (BEP) is the point at which revenue is exactly equal to costs. At this point, no profit is made and no losses are incurred. BEP can be expressed in terms of unit sales or currency sales. BEP indicate the level of sales that are required to cover costs. Sales above that number result in profit and sales below that number result in a loss.

Breakeven analysis is based on two types of costs, fixed costs (FC) and variable costs (VC). FC are overhead-type expenses that are constant and do not change as the level of output changes. VC are not constant and do change with the level of output. Therefore, VC is often stated on a per unit basis. The total of FC and VC is total cost (TC).

When doing BEP, selling price, FC and VC are assumed fixed. Profit is the difference between selling price and TC. In reality, the selling price, FC or VC will not remain constant resulting in a change in the BEP. Thus, BEP must be calculated on a regular basis to reflect changes in costs and prices and in order to maintain profitability or make adjustments in the product line. There are three basics information needed to evaluate a BEP:

i. average per unit sales price ii. average per unit VC

iii. average annual FC

The basic equation for determining BEP unit is:

BEP = 𝐴𝑣𝑒𝑟𝑎𝑔𝑒 𝐴𝑛𝑛𝑢𝑎𝑙 𝐹𝐶

𝐴𝑣𝑒𝑟𝑎𝑔𝑒 𝑃𝑒𝑟 𝑈𝑛𝑖𝑡 𝑆𝑎𝑙𝑒𝑠 𝑃𝑟𝑖𝑐𝑒 −𝐴𝑣𝑒𝑟𝑎𝑔𝑒 𝑃𝑒𝑟 𝑈𝑛𝑖 𝑡 𝑉𝐶 The basic equation for determining breakeven sales:

Breakeven sales = 𝐴𝑛𝑛𝑢𝑎𝑙 𝐹𝑖𝑥𝑒𝑑 𝐶𝑜𝑠𝑡

1−(𝐴𝑣𝑒𝑟𝑎𝑔𝑒 𝑃𝑒𝑟 𝑈𝑛𝑖𝑡 𝑉𝐶 ÷ 𝐴𝑣𝑒𝑟𝑎𝑔𝑒 𝑃𝑒𝑟 𝑈𝑛𝑖𝑡 𝑆𝑎𝑙𝑒𝑠 𝑃𝑟𝑖𝑐𝑒 )

Breakeven analysis is used in the evaluation of a new venture, in this case, the production of Azelaic Acid. Success takes time. Many new business venture operate at a loss, at a point below break-even) in the early stages of business. Knowing the price or volume necessary to breakeven is critical to evaluating the tie-frame in which losses are permissible. The breakeven is also an excellent benchmark by which a company’s short-term goals can be measured or tracked. Breakeven analysis mandates that cost can be analyzed. It also keeps a focus on the connection between production and marketing.

2.8.1 Factor Affecting the Cost of Production

There are many factors that influenced the cost of producing chemicals. Table 2.8 showed the list of important cost involved and can be divided into three categories:

Table 2.8 The List of Important Cost

Factor Description

1. Fixed Costs Factors not affected by the level of production

1.1 Depreciation Costs related with the physical plant (buildings, equipment, etc.). Legal operating expenses for tax purposes.

1.2 Local taxes and insurances

Costs related with property and liability insurance. Based on plant location and severity of the process.

1.3 Plant overhead costs

Costs related with the operation of auxiliary facilities supporting the manufacturing process involving payroll and accounting services, fire protection and safety services, medical services, cafeteria and any recreations facilities, payroll overhead and employee benefits, general engineering, etc.

2. Variable Costs Factors that vary with the rate of production

2.1 Raw materials Costs of chemical feed stocks required by the process. 2.2 Waste treatments Costs of waste treatment.

2.3 Utilities Cost of utilities required by process (water, electrical power, etc.).

2.4 Operating labor Costs of personnel required for plant operations 2.5 Direct supervisory

and clerical labor

Costs of labor and materials associated with the maintenance.

2.6 Maintenance and repairs

Costs of labor and materials associated with maintenance.

2.7 Operating supplies Costs of miscellaneous supplies that support daily operation excluded raw materials. (Chart paper, lubricants, filters, respirators and protective clothing for operators, etc.).

2.8 Laboratory charges Costs of routine and special laboratory tests required for product quality control and troubleshooting.

2.9 Patents and royalties

Cost of using patented or licensed technology.

3. General Expenses Costs related with an overhead burden that is necessary to carry out business functions.

3.1 administration costs

Costs for administration.

3.2 distribution and selling costs

Costs of sales and marketing required to sell products.

3.3 research and development

Costs of research activities related to the process and product.

The equation used to evaluate the total cost of manufacturing using these costs: Total cost of production (COP) = FC + VC + General Expenses (GE)

The COP is determined when the following costs are known or can be estimated: i. Fixed capital investments (FCI):

This represents the fixed capital investment to build the plant minus the cost of land and represent the depreciable capital investment.

ii. Cost of operating labor (COL) iii. Cost of utilities (CUT)

iv. Cost of waste treatment (CWT) v. Cost of raw materials (CRW)

Table 2.9 showed the multiplication factors for estimating manufacturing cost: Table 2.9 Multiplication Factors for Estimating Production Cost

Cost Item Multiplying Factor

1. Variable Cost (VC)

Raw materials CRW

Waste treatment CWT

Utilities CUT

Operating labor COL

Direct supervisory and clerical labor 0.18COL

maintenance and repairs 0.06FCI

operating supplies 0.009FCI

laboratory charges 0.15COL

patent and royalties 0.03COM

Total VC CRW + CWT + CUT + 1.33COL +

1..33COM + 0.069FCI Fixed Cost (FC)

Depreciation 0.1FCI

Local taxes and insurances 0.032FCI

plant overhead costs 0.708COL + 0.036FCI

total FC 0.708COL + 0.068FCI + depreciation

3. General Expenses

administration costs 0.177COL + 0.009FCI

distribution and selling costs 0.11COM

2.8.2 Cost Estimation

2.8.2.1 Total Capital Investment

Estimation of Purchased Equipment Cost, E

Equipment Quantity Estimated Cost (RM)

Total Estimated Cost (RM) 1 Storage tank 5 351362 1756810 2 Absorber 1 272899.5 272899.5 3 Reactor 3 528918.6 1586756 4 Distillation Column 3 515789.4 1547368 5 Evaporator 1 287591.7 287591.7 6 Heat Exchanger 8 28446.57 227572.5 7 Electrostatic Precipator 1 1857064 1857064 9 Oxygen Generator 1 5000000 5000000 10 Ozone Generator 1 2500000 2500000 11 Flaker 1 150673 150673 15186735 Total E = RM 15,186, 735

Estimation of Total Building Cost (B)

Direct Plant Cost Fraction Total (RM)

Installation 0.39E 5922826.462 Instrumentation 0.28E 4252285.665 Electrical 0.1E 1518673.452 Piping 0.31E 4707887.701 Building 0.22E 3341081.594 Expansion 0.1E 1518673.452

Service facilities 0.55E 8352703.985

29614132.31 Total B = RM 29,614, 132

Estimation of Land Price (L)

Land Price/Area = RM 14/ft2 (land price for Tanjung Langsat Industrial Complex) Proposed Plant Size = 10 acre, 1 acre = 43560 ft2

Land Price = RM 14/ft2 × 10 acre × 43560 ft2/acre = RM 6098400

Total Direct Plant Cost, D

= E + B + L

= RM 15,186, 735 + RM 29,614,132 + RM 6098400 = RM 50, 899, 267

Indirect Plant Cost, I

Engineering and Supervision = 0.32E = 0.32(RM 15,186, 735) = RM 4, 859, 754 Construction Expenses = 0.34E = 0.34(RM 15,186, 735) = RM 5, 163, 488 Total I = RM 4, 859, 754 + RM 5, 163, 488 = RM 10, 023, 242

Total Direct and Indirect Cost, D+I

= RM 50, 899, 267 + RM 10, 023, 242 = RM 60, 922, 509

Total Capital Investment

D+I = RM 60, 922, 509

Contractors fee’s = 0.05(D+I) = RM 3, 046,125 Contingency = 0.10(D+I) = RM 6, 092, 251 FCI = (D+I) (1 + 0.05 + 0.10) = RM 70, 060, 885 Working Capital Cost = 0.10(FCI) = RM 7, 006, 089

Total Capital Investment = FCI + Working Capital Cost

= RM 77, 066, 974 2.8.3 Estimation of Total Product Cost

2.8.3.1 Production Cost

Production Cost = FC + VC + General Expenses Fixed Cost (10 – 20% total product cost)

Cost Item Multiplying Factor Estimated cost

Depreciation 0.1FCI RM 7, 006, 089

Local taxes and insurances 0.032FCI RM 2, 241, 948

plant overhead costs 0.708COL + 0.036FCI 0.708COL + RM 2, 522, 192

Let product cost be ‘X’

COL = 15% of total product cost

Total FC = Depreciation + Local taxes and insurances + plant overhead cost = RM 7, 006, 089 + RM 2, 241, 948 + 0.708(0.15X) + RM 2, 522, 192 = RM 11, 770, 229 + 0.1062X

Variable Cost (60% total product cost)

1. VC Estimated Cost

Raw materials CRW = 0.25X 0.25X

Waste treatment CWT = 0.10X 0.10X

Utilities CUT = 0.10X 0.10X

Operating labor COL = 0.10X 0.10X

Direct supervisory and clerical labor

0.18COL = 0.18(0.15X) 0.027X

maintenance and repairs 0.06FCI RM 4, 203, 653

operating supplies 0.009FCI RM 630, 548

laboratory charges 0.15COL = 0.15(0.15X) 0.025X patent and royalties 0.03COM / 0.05X 0.05X

Total VC

= CRW + CWT + CUT + COL + direct supervisory and clerical labor + maintenance and repairs + operating supplies + laboratory charges + patent and royalties

= 0.25X + 3(0.1X) +0.027X + RM 4, 203, 653 + RM 630, 548 + 0.025X + 0.05X = 0.662X + 4, 834, 201

General Expenses

Cost Item Multiplying Factor Estimated Cost

administration costs 0.177COL + 0.009FCI / 0.5COL 0.5(0.10X) distribution and selling

costs

0.11COM / 0.10X 0.10X

research and development

0.05COM / 0.03X 0.03X

GE = administration costs + distribution and selling costs + research and development

= 0.5(0.10X) + 0.10X + 0.03X = 0.18X

Total Production Cost (COP) = Total FC + Total VC + GE

= RM 11, 770, 229 + 0.1062X + 0.662X + 4, 834, 201 + 0.18X = RM 16, 604, 430 + 0.9482X

2.8.4 Breakeven Calculation

COP = RM 16, 604, 430 + 0.9482X

Raw material cost, CRM = 0.25X Production Data

Raw material Oleic Acid

Price (RM/kg) 3.38

Price (RM/tonne) 3380

Usage demand (tonne/year) ≈ 1,500

Cost (RM/year) 5, 070, 000

Products Azelaic Acid

Price (RM/kg) 80

Price (RM/tonne) 80,000

Production demand (tonne/year) ≈ 1,000

Sales (RM/year) 80, 000, 000

2.8.4.1 First Method

CRM = 0.25X

RM 5, 070, 000 = 0.25X

X (total product cost) = RM 20, 280, 000

COP = RM 16, 604, 430 + 0.9482X, X = RM 20, 280, 000

COP = RM 35, 833, 926

Breakeven point is achieved when sales is equal to COP. The number of sales (N) to reach breakeven point:

Product price × N = COP

RM 80, 000(N) = RM 35, 833, 926

Therefore, the production volume must be higher than 448 tonne per year for the production of azelaic acid to gain profits.

2.8.4.1 Second Method

Total product cost for 15000 tonne of raw material = RM 20, 280, 000

Cost of product (RM/tonne) = RM 20, 280, 000/1500 tonne = RM 13, 520/tonne (Variable Cost) Total Cost (TC) = Fixed Cost (FC) + Variable Cost (VC)

TC = FC +VC(X), convert to straight line equation, Y = MX + C, where X is production quantity.

Cost Represent by Value

TC Y RM 35, 833, 926

FC C RM 16, 604, 430

VC(X) M(X) RM 13, 520 (X)

Total Cost Equation Total Revenue Equation Breakeven Point Equation Y = MX + C Y = 13520X + 16604430 Y = MX Y = 80, 000X Cost = Sales 13520X + 16604430 = 80000X 66480X = 16604430 X = 250

Figure 2.13 The Breakeven Chart From the breakeven chart,

Breakeven point = 250 tonne Actual Sales = 1000 tonne

Margin of safety = 1000 tonne – 250 tonne = 750 tonne 0 10000000 20000000 30000000 40000000 50000000 60000000 70000000 80000000 90000000 0 200 400 600 800 1000 1200 C os ts a nd R e v e nu e ( R M ) (output, tonne)

The Breakeven Chart

Total Cost (TC) Total Revenue (TR) PROFIT

CHAPTER 3

SITE LOCATION

3.1 FACTORS FOR SITE LOCATION

In setting up a plant, the location is one of the main factors for consideration. The major requirements for an azelaic acid plant are oleic acid and oxygen. Azelaic acid plants must locate close to oleic acid plants to reduce the transportation expenses, thus optimizing azelaic aicd production. The optimum location would be in industrial area where there are markets for azelaic acid.

Malaysia has designated area for industrial purposes, but not all has the necessities for setting up chemical plant. All information on this industrial area is obtained from Malaysia Industrial Development Authorities (MIDA). The factors for site selection are:

1. Location, with respect to marketing area 2. Raw materials availability and supplies 3. Transportation facilities

4. Availability of suitable land 5. Availability of labor

6. Availability of utilities (e.g. water, electricity) 7. Environmental impact and effluent disposal 8. Local community considerations.

9. Climate

10. Political strategies consideration 11. Taxation and legal restrictions

3.1.1 Location

Location of markets or distribution centers affects the cost of product distribution and time required for transporting. Close location to the major markets is an important factor in plant location, because it is advantageous for buyer to purchase from near-by sources. Azelaic acid is industrially used as component in a series of application such as polyamides, polyesters, pharmaceuticals, utilized for food packaging, in electronics, textiles, and automotive industries. Therefore, the azelaic acid plant should be located in close proximity to these industries.

3.1.2 Raw materials

The availability and supplies of raw material is one of the important aspects in the selection of a plant site. For the production process of azelaic acid, large volume of oleic acid and commercially pure oxygen are used, thus can reduce the transportation and storage charges. The price of the raw materials, distance from the suppliers, transportation expenses, availability and reliability of supply, purity of raw materials and storage requirement must be considered for raw materials.

3.1.3 Transportation facilities

The transportation factor is more important consideration in site selection. Transportation is used for raw materials, distribution of product, import and export purposes. Ideally, site should be selected close to at least two major form of transport (e.g. road, rail waterway or a seaport). Road transport is increasingly used because it is suitable for local distribution from plant or warehouse. For long distance transport of bulk chemicals, rail transport is cheaper. If possible, the plant site should be located to all three types of transportation.

3.1.4 Availability of suitable land

The characteristic of the land should be evaluated carefully for the proposed plant site. The topography of the tract of land structure must be considered because this affect the construction cost. The cost of the land, local building costs and living condition are important. Sufficient suitable land must be available and for future expansion. The land should be ideally flat, well drained and have suitable load-bearing characteristics. A full site evaluation should be conducted to determine the need for piling or other

foundations. In Malaysia, finding a suitable land is not a major issue because of availability of land in designated industrial area.

3.1.5 Availability of labors

Labors are needed for the construction and operation of the plant. Skilled construction workers are often brought in from outside the site area. Locally, there should be sufficient unskilled labor available and labor to operate the plant. When assessing the availability and suitability of the labor, local labor laws, trade union customs and restrictive practices must be taken into consideration.

3.1.6 Availability of utilities

Utilities are used for the services needed in the operation of production process. These services normally be supplied from central facility and includes water, fuel and electricity. Water is required for large industrial and general purpose. Water is used for cooling, washing, steam generation and as raw material in the production. Therefore, proposed plant must be located where there is availability of water supply.

Power and steam is required in most industrial plant and fuel is required to supply these utilities. Power, fuel and steam are necessary to run various equipments like generators, motors, plant lightning and general usage, thus considered as major factor in choosing plant site.

3.1.7 Environmental Impact and effluent disposal

A plant must provide effective disposal of effluent without any public nuisance. As all industries process produce waste products, permissible tolerance levels for various effluents and requirement for waste treatment facilities should be taken into consideration. The disposal of toxic and harmful effluent will be covered by local regulations, and authorities must be consulted during initial site survey to determine the standards that must be met.

3.1.8 Local community considerations

The proposed plant must fit in with and acceptable to the local community. Full consideration must be given to the safe location of the plant so that it does not impose significant risk to the community.

3.1.9 Climate

Adverse climate at site will increase cost because at extreme low temperature, the plant requires additional insulation and special heating equipment. Excessive humidity and hot temperatures pose serious problem and must be considered for site selection. At location with high wind loads or earthquake, stronger structures are needed. Malaysia has tropical weather, and is experienced throughout the year. It is never too hot because of its proximity to water. Thus, adverse climate is not a major factor in determining plant location in Malaysia.

3.1.10 Political and strategic considerations

Capital grants, tax concession and other inducements are often given by governments to direct new investment to preferred locations such as areas of high unemployment. The availability of such grants can be overriding consideration in site selection.

3.1.11 Taxation and legal restrictions

State and local tax rates on property income, unemployment insurance and similar items vary from one location to another. Similarly, local regulations on zoning, building codes, nuisance aspect and other facilities can have a major influence on the final choice of the plant site.

Based on study done in selecting specific site location, it can be simplified that consideration are based on two major factor which is primary and specific factor to contribute in finding process for site location.

Table 3.1: Contributing factors for operability and economic aspects

Primary Factor Specific Factor

Raw material availability for industry Availability of low cost labor and services Reasonable land price Effluents and waste disposal facilities

Source of utilities Incentive

Climate status Transportation facilities

3.2 PROPOSED SITE LOCATION

The production of acid azelaic is categorized as an oleochemical project. The plant must therefore be sited in a special zone provided by the government. We have chosen to build our plant in the industrial area near priority of raw materials, price of land, transportation, labor, utilities, political and strategic consideration. After conducting the feasibility and site survey, three (3) main locations have been short listed to be considered as strategic site location for the construction of an azelaic acid plant.

3.2.1 Tanjung Langsat Industrial Complex

Iskandar Malaysia is now enter Phase Two (2011-2015) development region or delivering phase of its strategic roadmap. Divided into three phases, Iskandar Regional Development Authority (IRDA) has planned with five flagship zones which Tanjung Langsat Industrial Complex located in Eastern Gate Development zone. There are total 40 oil refinery and oleochemical plants in Iskandar Malaysia where the majority are located between Pasir Gudang industrial Park and Tanjung Langsat Industrial Complex. The latter has a designated area for oleochemical known as Tanjung Langsat Palm Oil Industrial Cluster (POIC), which aims to spearhead palm oil downstream processing to complement and add further from existing refineries.