1. Introduction
Olefins manufacturing is the third largest petrochemical industry after others like ammonia manufacturing and petroleum refining. Polyethylene has been extensively applied in industries chemicals and other related products are been manufactured all round the world [1].
Polyethylene is used as starting material for the production products such as: cosmetics, plastics, solvents etc. having a high market demand with production rate of 150,000,000 tons/year and this production rate has been predicted to rise by 3.5 percent in the next five years [2]. A large amount of polyethylene is used for producing plastics which contains polymer chains of ethylene units in its numerous chain lengths. [3] researched on non-catalytic pyrolysis of ethane to ethylene in the presence of CO2 with or without limited CO2. Both presence and absence of limited CO2 in the pyrolysis of ethane to ethylene at process conditions of 750˚C-900˚C, space velocities of 1500-9000 per hour and CO2/C2H6 and O2/C2H6 nude ratios (0-2.0 and 0-3.0 respectively), and ethane conversion increases [4]. The activation of ethane in the presence of C02 increases the formation of ethylene but not oxidation of ethane.
[5] researched on Ethylene production plant design 700 metric tons per day of ethylene production plant was carried using 140,010 lb/hr of 10% butane which was fed with 100% of 8174 lb/hr ethane recycled from the furnace reactor. Other products obtained were propylene, gasoline and high-pressure steam products are subsequently sold [6]. The expectation of the ethylene plant is to profit 160 million over a 10 yrs operation period and a returned investment of 16%. The plant was expected to 8400 hrs a year of 0.96 operating factors. The capital investment of the plant was $28,000,000 and $16,000,000 per year of auxiliary equipment and gave an annual operating cost of $20,500 per yr.
[7] worked on simulation and analysis of ethane cracking process. Coiled tubular reactors were used for the processing and cracking of light hydrocarbons (Ethane, propane, n-butane and their mixtures) at high temperatures and short residence times to obtained ethylene as the main product. The simulation of the industrial reactor unit with ethane as a feedstock for the molecular reaction scheme of 8 components and five (5) reactions was done. The predicted models result using plant data were compared with the industrial data and gave small derivations interns of pressure and temperature but negligible deviation with concentration. Also, the profile of temperatures and concentration for both models results and industrial results agrees.
[8] Ethylene is of great importance to the petrochemical industry where varieties of products such as bottles, housewares, antifreeze, food containers, pipes, carpets, toys, film, etc., the various chemicals produced from ethylene as raw material include: vinyl acetate, ethylene oxide, ethyl benzene, polyethylene, ethylene dichloride etc.
[9] Polyvinyl chloride which is a byproduct of polyethylene accounts for about 70% usage in construction materials, pipe fittings, windows etc. and about 30% is used in making cable wires, coating surfaces and plastic manufacture.
[10] worked on how ethylene can be obtained from natural gas through the method of oxidative coupling of methane and cold energy of LNG. Liquefied Natural Gas was used as feedstock for the oxidative coupling of methane and thereafter through cryogenic distillation process, ethylene was obtained, it was discovered that production cost of ethylene greatly depends on the market price of LNG and NG which was shown through the difference in price of LNG/NG as well as other co-products affects the cost of production of ethylene.
Worldwide production rate of Polyethylene is known to be about 85 metric ton/year due to its high demand and usage [11]. Figure 1 shows the process flow diagram for the production of polyethylene, it consists of three reactors namely: polymerization reactor operating at 6.5 bar and 50.7˚C, loop reactor operating at 6.5 bar 70.9˚C and finally gas phase reactor operating at 6.5 bar and 70.9˚C.
The purpose of this research is to design and simulate a process plant for the production of polyethylene using Aspen Hsys Veesion 8.8 software.
2. Materials and Methods
2.1. Materials
The Materials used in this work are Data from Indorama Eleme Petrochemicals Limited which includes:
1) Detailed process flow diagram.
2) Inlet feed operating conditions.
3) Comprehensive feed compositions.
4) Utilities.
5) Aspen Hysys Version 8.8 software.
6) Laptop.
Figure 1. PFD of polyethylene plant production.
7) Chemical Engineering related Handbooks etc.
2.2. Methods
The methods used to accomplish this research are outlined as follows:
1) Perform material and energy balance on each equipment unit using the principles of conservation of mass and energy.
2) Build the Hysys process model of the plant.
3) Carry out sensitivity analysis.
1) The material balance equation for each equipment unit can be written as follows:
(1)
The energy balance equation for each eqipment unit can be written as follows:
(2)
2) Hysys model
This involves building of the plant model into hysys for both the single and multiple reactor cases as shown in Figure 2 and Figure 3 respectively.
3. Results and Discussion
3.1. Material Balance Result
The material balance results are presented in Tables 1-6 for all the various streams and units.
Figure 2. Hysys model for single CSTR for polyethylene plant.
Figure 3. Hysys model for multiple CSTRs for polyethylene plant.
Table 1. Comparison of material balance results of hysys simulation with manual calculation for compression unit.
Table 2. Comparison of material balance results of hysys simulation with manual calculation for cooling unit.
Table 3. Comparison of material balance results of hysys simulation with manual calculation for splitting unit.
Table 4. Comparison of material balance results of hysys simulation with manual calculation for conversion reactor unit.
Table 5. Comparison of material balance results of hysys simulation with manual calculation for mixing unit.
Table 6. Comparison of material balance results of hysys simulation with manual calculation for CSTR unit.
3.2. Energy Balance Result
The energy balance results are presented in Tables 7-12 for all the various streams and units.
Table 7. Comparison of energy balance results of hysys simulation with manual calculation for compression unit.
Table 8. Comparison of material balance results of hysys simulation with manual calculation for cooling unit.
Table 9. Comparison of energy balance results of hysys simulation with manual calculation for splitting unit.
Table 10. Comparison of energy balance results of hysys simulation with manual calculation for conversion reactor unit.
Table 11. Comparison of energy balance results of hysys simulation with manual calculation for mixing unit.
Table 12. Comparison of energy balance results of hysys simulation with manual calculation for cstr unit.
3.3. Conversion Results
The Conversion results of the reactor conditions for both the multiple CSTRs and Single CSTR is presented below.
3.3.1. Multiple CSTR Results
Table 13. CSTR 1 conditions at 40% conversion.
Table 14. CSTR 2 conditions at 50% conversion.
Table 15. CSTR 3 conditions at 60% conversion.
Table 16. CSTR 4 conditions at 80% conversion.
Table 17. CSTR 5 conditions at 90% conversion.
3.3.2. Sizing Results
1) Single CSTR Result
Table 18. Single CSTR conditions at 90% conversion.
2) Multiple Reactor Sizing
The size of the multiple CSTRs are fixed and hence the size is the same throughout
From Tables 13-20 above, we observed that using multiple CSTRs in series at different conversions almost equals using a single CSTR at the same final conversion except that it leads to a non-isothermal behavior as temperature is not controlled as in the case of using multiple CSTRs in series.
3.4. Parameters for Compressor Sizing at 90% Conversion
The sizing of the four compressors at 90% conversion is given in Tables 21-24 below.
From Tables 21-24, we observe that a single CSTR requires a large volume at the same conversion with a multiple CSTRs in Series. The space time of the single CSTR is higher than that of the Multiple CSTR in since it just a single reactor so more time is spent to process a given volume of feed.
3.5. Sensitivity Analysis
A sensitivity analysis was performed to determine the effect of the following functional parameters given below.
3.5.1. Variation of Fractional Conversion with Height of Reactor
Figure 4 shows that the height of reactor increases with an increase in Fractional conversion. The increment is as a result of the formation of products along the height of the rector.
3.5.2. Variation of Fractional Conversion with Volume of Reactor
Figure 5 shows how Fractional Conversion is Changing with the Volume of the Reactor, as the volume of the Reactor increases so does the Fractional conversion until it reaches its maximum value of 0.9.
3.5.3. Temperature and Pressure Progression
Figure 6 shows the behavior of Temperature with Fractional conversion, As the Temperature of the Reactor increases so does the fractional conversion as a result of the Heat of reaction released to form products which can either be exothermic or endothermic. When it is endothermic heat is absorbed from the environment but when it is exothermic heat is released to the environment.
3.5.4. Pressure Variation with Fractional Conversion
This is also seen to behaving like the Temperature graph where an increase in the pressure of the reactor also brings about increase in Fractional conversion as shown in Figure 7.
3.5.5. Variation of Space Time with Fractional Conversion
Space time is also an important functional parameter in the design of continuous reactors. The space time gives the information of the amount of time required to process a given volume of feed at inlet conditions.
Figure 4. Variation of fractional conversion with reactor height.
Figure 5. Variation of fractional conversion versus reactor volume.
Figure 6. Temperature variation with fractional conversion.
Figure 7. Variation of pressure with fractional conversion.
Figure 8. Space time variations with fractional conversion.
Figure 9. Heat load variation along reactor height.
Figure 8 shows that as the space time of the reactor increases, the fractional conversion of the propane to propene also increase. Hence, it could be concluded from the plot that the conversion is directly proportional to the total amount of time spent by the reacting species in the reactor. The more time the reacting species spend in the reactor, the more the yield of products.
3.5.6. Heat Load
The heat load is the amount of heat required in maintaining the temperature of the reaction process. It could be seen from Figure 9 that the fractional conversion is decreasing with an increase in the heat generated per unit volume as the reaction progresses.