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Chemical Engineering Plant Design 1
Costing of Ethylene Oxide Plant
CHE 4181
By: Abdullah Kurdi
Khalid Almansoori
Nasser Almakhmari
Report Submitted: 12/2/2015
Instructor: Dr. Jonathan Whitlow
1
Table of Content
Summery 2
Capital Cost 3
I. Methodology 4
II. Results 7
Manufacturing Cost 8
I. Methodology 9
II. Results 10
Profitability
I. Methodology 14
II. Results 15
References 16
Appendix A: Detailed Capital Cost Information 17
Appendix B: Manufacturing Cost Detailed Calculations 18
Appendix C: Electricity Price Extrapolation 22
Appendix D: Profitability Detailed Calculations 23
2
Summery
The following report shows and discusses the methodology for the costing of a chemical
plant. The plant discussed specifically in this report is an Ethylene Oxide Production Plant (1).
The costing of a chemical plant has three main section: the capital cost, the manufacturing cost,
and the profitability. Each of the three sections is described on its own, and all results are shown.
Sample calculations and specific results are available in the Appendix section of this report for
demonstration and clarification. A supporting electronic spreadsheet, showing all the calculations
and graphs, is uploaded on the Canvas.fit.edu website.
In summary, the cost of an ethylene oxide production plant has been estimated; it has a
capacity of producing 130,318 metric tons annually. The plant needs a total capital cost of $
1,077,715,000 and has an estimated $577,785,000 for manufacturing cost. The land cost is
projected to be 5 million, and it is expected that the construction period will take two years; and
operation will start on the third year. If the plant doubles the production rate of ethylene oxide,
from the current specified one (1), the breakeven point is estimated to be between the fifth and
sixth year of operation.
3
Capital Cost
The following section discusses the capital cost of the production plant of Ethylene Oxide
using the methodology discussed in appendix A of the Analysis, Synthesis and Design of
Chemical Processes, by Turton(1); the appendix consists of several sources and helpful
parameters in estimating the cost of process equipment. The capital cost is basically the sum
of the costs of all process units. It is important to note that the data used in the calculations
are based on a survey of equipment manufacturers that were taken in the year of 2001(2); the
average Chemical Engineering capital Cost Index (CEPCI) in 2001 was 397, and it must be
used to account for inflation (2). The CEPCI for the year 2016 was given by Dr. Whitlow as
604 and was used to update the total capital cost to the year 2016. There were some
assumptions made in the design, all of which are mentioned in the following Table 1.
Table 1: Assumptions Made in Calculating the Cost of certain Equipment
Unit Assumptions
Over Design Factor A safety over design factor of 10 %
Heat Exchangers
The pressures in the in the tube side
were the same as the inlet pressure of
the process multiplied by 10%
The pressures in the shell side were
chosen to be 35 psi because it was
assumed to be cooling water and
multiplied by 10 %
Some heat exchangers found to have
capacity not within the range. The
capacity was forced to be within the
range by dividing by lowest possible
number of exchangers. The final cost
was multiplied also by the number of
exchangers.
4
Table 1 (Cont.): Assumptions Made in Calculating the Cost of certain Equipment
Unit Assumptions
Reactors
Reactors are modeled as Heat
Exchangers – Floating Head
Effective diameter is the diameter of
the reactor using the volume and height
Vessels
Some of Towers were modeled as
Process Vessels (vertical).
The assumptions were made to find
𝐹𝑃,𝑉𝑒𝑠𝑠𝑒𝑙, FM, B1, and B2. B1 and B2
were found in Ethylene oxide table(1)
Costing Correction to the year 2016 Linear extrapolation between 2001 and
2010, then using the line equation to
get the 2016 index number
I. Capital Methodology
Purchased Equipment Cost
The following equation was used for calculating the purchased cost of the equipment,
assuming ambient operating pressure and using carbon steel construction (2):
𝑙𝑜𝑔10𝐶𝑝𝑜 = 𝐾1 + 𝐾2 𝑙𝑜𝑔10(𝐴) + 𝐾3 [𝑙𝑜𝑔10(𝐴)]2
𝐶𝑝𝑜: Purchased cost
A: Capacity or size parameter for the equipment
K1, K2, and K3: given constants in Turton (2)
5
Purchased Equipment Cost (for capacities out of the range)
The following correction was used to accommodate the capacity values that were out of
the range of specifications mentioned in Turton (2):
𝐶𝑎 = 𝐶𝑏 (𝐴𝑎
𝐴𝑏)
2
Where Ca is the cost of the equipment with the out of range capacity, Cb is the cost of the
equipment at the maximum capacity, Aa is the out of range capacity value, and Ab is the
maximum capacity value.
Pressure Factors for Process Vessels
𝐹𝑃,𝑉𝑒𝑠𝑠𝑒𝑙
(𝑃 + 1) ∗ 𝐷2[850 − 0.6(𝑃 + 1)]
+ 0.00315
0.0063
The previous equation was used to determine the pressure factors for Vessels and
Towers. P is the pressers in barg, and D is the diameter in meter. There are three Towers and
one Vessel; two of the towers are the same, and the third one has a different operating
pressure and diameter. The values of 𝐹𝑃,𝑉𝑒𝑠𝑠𝑒𝑙𝑠 were found to effects the cost due to the high
pressure factors value (2).
Pressure Factor for other Process Equipment
The pressure factor, FP, for other equipment such as Pumps, Heat Exchangers,
Compressors, and Reactors in the plant was found using the following equation:
𝑙𝑜𝑔10𝐹𝑝 = 𝐶1 + 𝐶2 𝑙𝑜𝑔10(𝑃) + 𝐶3 [𝑙𝑜𝑔10(𝑃)]2
P: Design pressure in barg
C1, C2, and C3: given constants in Table A.2 in Turton (2)
6
Material Factors for Heat Exchangers, Process Vessels, and Pumps
The values of the material factors, FM, for heat exchangers, process vessels and pumps
are obtained from figure A.18 in Turton (2) and the identification numbers are also listed in
Table A.3 in Turton (2)
Bare Module Factor for Heat Exchangers, Process Vessels, and Pumps
𝐶𝐵𝑀 = 𝐶𝑝𝑜𝐹𝐵𝑀 = 𝐶𝑝
𝑜(𝐵1 + 𝐵2𝐹𝑀𝐹𝑝)
CPo: Purchased Cost
FBM: Bare module factor
B1 and B2; Given constants in Table A.4 in Turton (2)
FM: Material Factor
Fp: Pressure Factor
Bare Module and Material Factors for the Remaining Process Equipment
The values of the Bare Module and Material Factors, FBM and FM for the remaining
equipment can be found using Figure A.19 and Table A.6 in Turton (2).
Bare Module Cost for Sieve Trays
In the case of Sieve trays, the bare Module cost is calculated differently; the value of CBM
is obtained using the following equation:
𝐶𝐵𝑀 = 𝐶𝑝𝑜𝑁𝐹𝐵𝑀𝐹𝑞
CPo: Purchased Cost
N: number of trays
FBM: Bare module factor
Fq: Quantity factor for trays
The quantity factor for trays, Fq, for N ≥ 20: Fq = 1
7
Costing Correction to 2016
𝐶𝑎 = 𝐶𝑏 (𝐴𝑎
𝐴𝑏)
2
Where Ca is the cost of the equipment in 2016, Cb is the cost of the equipment in 2001,
Aa is the CEPCI in 2016 given by Dr. Whitlow to be 605, as a fixed assumption, and Ab is
the CEPCI in 2001.
II. Capital Results
The following Table 2 shows the total costs of the equipment used in the plant.
Table 2: Total Cost of Equipment
Equipment Total Cost (2016) Percentage of
Capital Cost
Pump $51,000 0.005%
Vessel (horizontal) $264,000 0.024%
Heat Exchangers $906,300,000 84.095%
Compressors $260,000 0.024%
Towers $166,000,000 15.403%
Sieve Trays $4,640,000 0.431%
Reactors $200,000 0.019%
The total capital cost is $ 1,077,715,000. From Table 2, it can be noticed that the Heat
Exchangers govern the majority of the capital cost with 84.095 %, and the second large cost is
for the Towers, occupying 15.403 % of the total capital cost.
A more detailed costing for each unit is presented in Appendix A of this report.
8
Manufacturing Cost
After calculating the capital investment needed to build the Ethylene Oxide plant, the
operational investment is to be determined. There are three types of manufacturing costs to
take into account: Direct Manufacturing costs, Fixed manufacturing costs, and General
Expenses.
Direct Costs are dependent on production rate, and it includes raw materials, utilities,
labor, waste treatment, supplies, maintenance, lab charges, and patents & royalties. Fixed
costs are independent of production rate, and it includes taxes & insurance and plant
overhead. Finally general expenses costs are loosely tied to the production rate, and it
includes sales and marketing, research & development and administrative costs.
The following report shows the manufacturing cost for the ethylene oxide plant, using the
methodology stated in Turton(2).
9
I. Manufacturing Methodology
Utility Cost:
In this section, the expenses associated with electricity, cooling water, process steam and
many other utilities are accounted for. It is important to note that the cost of utilities are
dependent on both inflation and energy cost. The main utilities needed in the plant are
electricity, cooling water, high pressure steam and boiling feed water; these utilities are used
in the plant in the heat exchangers, reactors and compressors. Table 3 shows the total amount
of each utility needed in the plant annually, and the price and annual cost of each utility. For
the cost of electricity, the cost was linearly extrapolated using the data found in the U.S.
Energy Information Administration (3) to find the estimated price in 2016. All the calculation
that are involved in the manufacturing cost of ethylene oxide plant are presented in Appendix
B. For cooling water, high pressure steam and boiling feed water. The cooling water cost was
based on the total annual increase in the cost of electricity between 2006 and 2015. The high
pressure steam and the boiler feed water are based on the total annual increase between 2009
and 2015 for natural gas. The data presented in Appendix C shows the linear extrapolation
that was used the electricity cost.
10
II. Manufacturing Results
The following Table 3 shows a summary of the costs included in the manufacturing of
the plant.
Table 3: Summary of the Costs included in the Manufacturing Cost
Direct Manufacturing Costs $401,419,00
Direct Supervisory and Clerical Labor $193,000
Maintenance and Repairs $64,654,000
Fixed Manufacturing Cost $74,033,000
Local taxes and Insurance $34,483,000
Plant Overhead costs $39,551,000
Raw Materials $21,732,000
Utilities $286,330,000
Operating Labor $1,071,000
Waste treatment $250,000
Lab Charges $161,000
Patents and Royalties $17,334,000
Fixed Capital Investment $1,077,564,000
Cost of Manufacturing $577,785,000
General Expenses $102,334,000
Administration Costs $9,925,000
Distribution and Selling Costs $63,557,000
Research and Development $28,890,000
Form Table 3, the total manufacturing cost of the plant is $577,785,000 while the fix
capital investment is $1,077,564,000. The direct manufacturing cost is $401,419,000; the fixed
manufacturing cost is $74,033,000 and the general expenses have a total of $102,334,000.
11
Figure 1: Direct Costs Distribution
Figure 1 above shows the distribution of the direct costs between its elements; it can be
noticed that utilities take a large part of the pie chart with a 73.13% of the total direct cost. The
second largest cost is for the maintenance and repairs of the plant which occupies 16.51% of the
pie chart. The third largest segment in the pie chart is for raw materials occupying 5.55% of the
direct costs. Patents and royalties occupy 4.43%, while operating labor, waste treatment, and lab
charges occupy 0.27%, 0.06% and 0.04% respectively.
16.51%
5.55%
73.13%
0.27%
0.06%0.04%
4.43%
Direct Costs
Maintenance and Repairs
Raw Materials
Utilities
Operating Labor
Waste treatment
Lab Charges
Patents and Royalties
12
The following Table 4 shows the utility cost of each utility needed in the plant annually.
Table 4: Price, Total Amount, and Cost Annually Needed for Utilities
Cost (2016 $) Total Amount Needed Cost ($/yr) in 2016
Electricity ($/kW-hr) 0.0718 3,100,000,000 $225,000,000
Cooling water ($/kg) 0.0000175 116,600,000,000 $2,000,000
High Pressure Steam ($/kg) 0.01459 4,000,000,000 $140,000,000
Boiler Feed Water ($/kg) 0.00119 205,600,000 $600,000
The total utility cost, from Table 3, is $286,330,000. It can be noticed from Table 4 that
the cost of electricity occupies a large part of the total with 78.58 % of the cost. The next
largest utility is high pressure steam with a total cost of $140,000,000, which is 20.63% of
the total utility cost.
Figure 2: Fixed Manufacturing Cost Distribution
From Table 3, the total fixed manufacturing cost is $74,033,000; Figure 2 shows the
distribution of the cost between the local taxes and insurance and the plant overhead costs, which
occupy 53% and 47% respectively.
47%53%
Fixed Manufacturing Costs
Local taxes and
Insurance
Plant Overhead costs
13
Figure 3: General Expenses Distribution
From Table 3, the general expenses in the plant have a total of $102,334,000; this total is
divided by the administration costs, 10%, research and development, 28%, and the distribution
and selling cost, 62% of the total expenses.
10%
62%
28%
General Expenses
Administration Costs
Distribution and Selling Costs
Research and Development
14
Profitability
I. Profitability Methodology:
Profitability of the ethylene oxide plant was determined through several steps. The
product annual flow rate and the cost of the product were calculated in order to find the
revenue. Some assumptions were made in the profitability calculation; details are shown in
Appendix D. The land cost was assumed to be equal to 5 million dollars. In addition, the
annual interest rate was assumed to be 6 %. The revenue was assumed to increases by 5 %
annually, and the operation cost by 2 % annually. The tax rate was assumed to be 25%; while
the working capital was assumed to be 15% of the fixed capital investment. The construction
period was assumed to be two years, with an expected plant life time of ten years.
It was noticed that there is no breakeven point when the product flow rate is as given. An
assumption was made in order to find a breakeven point which was doubling the annual
production of the product, ethylene oxide. The total cost of doubling the ethylene oxide was
found to be $1.120 billion. The cost of ethylene oxide was found using linear extrapolation
from the costing data found for the years 2009-2011 and assuming a fixed annual increase of
15.64% (6).
15
II. Profitability Results:
Figure 4: Cumulative Future vs. Time
Based on Figure 4 above, it can be concluded that the breakeven point is going to be
between the fifth and sixth year of operation. The revenue in the sixth year will be $
671,100,000.
It is important to note that this prediction assumes the doubling of the production of
ethylene oxide, i.e. twice the output flow rate specified.
The discounted cash flow rate of return (DCFROR) was found to be at a 27.31% annually
interest rate.
-$3,000,000,000
-$2,000,000,000
-$1,000,000,000
$0
$1,000,000,000
$2,000,000,000
$3,000,000,000
$4,000,000,000
$5,000,000,000
$6,000,000,000
0 1 2 3 4 5 6 7 8 9 10 11 12
Cash
Flo
w
Time (years)
Discrete Cash Flow
16
References
1) Analysis, Synthesis and Design of Chemical Processes, by Turton, Baillie, Whiting,
Shaeiwitz & Bhattacharyya 4th Edition, Prentice Hall, 2012, Ethylene Oxide Production,
Unit 700.
2) Analysis, Synthesis and Design of Chemical Processes, by Turton, Baillie, Whiting,
Shaeiwitz & Bhattacharyya 4th Edition, Prentice Hall, 2012
3) U.S. Energy Information Administration, Electric Power Monthly, August 2015, Table
5.3. Average Price of Electricity to Ultimate Customers
4) 51-9011 Chemical Equipment Operators and Tenders." U.S. Bureau of Labor Statistics.
U.S. Bureau of Labor Statistics. Web. 2 Dec. 2015.
5) "Ethylene | Prices, News & Market Analysis | ICIS.com." Ethylene | Prices, News &
Market Analysis | ICIS.com. Web. 2 Dec. 2015.
6) Nigam, Shirish. "Impact of Crude Oil Price Trends on Feed Additives' Prices." Engormix.
Animal Feed, 26 May 2011. Web. 1 Dec. 2015.
7) "CHE_4181_Economics_Profitability_2015.pptx." 16 Nov. 2015. Lecture.
17
Appendix A: Detailed Capital Cost Information
Table 5: Cost of Each Piece of Equipment
Equipment Unit # Cost (2016 $)
Pump P-701 A/B $50,623
Vessel (horizontal) V-701 $264,033
Heat Exchangers
E-701 $5,176,300
E-702 $86,965,925
E-703 $171,762,029
E-704 $202,704,703
E-705 $201,336,855
E-706 $207,954,249
E-707 $18,322,587
E-708 $10,368,570
E-709 $1,675,570
Compressors
C-701 A/B $66,018
C-702 A/B $81,291
C-703 A/B $75,561
C-704 A/B $15,808
C-705 A/B $15,808
Towers T-701 $10,640,056
T-702 $10,640,056
T-703 $144,608,451
Sieve Trays T-701 $793,233
T-702 $793,233
T-703 $3,053,945
Reactors R-701 $99,514
R-702 $99,514
Table 6: Total Capital Cost
Total Module Cost (2001) Total Module Cost (2016)
$664,274,660 $1,077,563,932
18
Appendix B: Manufacturing Cost Detailed Calculations
Operating labor Cost:
As shown in Table (1), there are 52 weeks in one year, 3 weeks for vacation, 8 hours in
each shift, and 5 shift per week. To calculate the total hours per year, the number of week should
be 49 by subtracting 52 from 3. Calculating Total hour is by Multiplying 8 × 5 × 49 = 1960
and total hour/year is 24 × 365 = 8760. To obtain the number of operator hired for each
operators is by using this equation (Total hours of operation / Total hour/year) which gives
8760
1960=4.5 and this number should be rounded to 5.
𝑁𝑂𝐿 = √6.29 + 31.7𝑃2 + 0.23𝑁𝑛𝑝 (1)
This Equation (1) represent the number of operators per shift. P is the number of steps
involving particulate solids handling. Nnp is the number of steps not involving particulate solids
handling. P will be zero because there are no solids that need handling such as no transportation
or Particulate removal. Nnp is the number of none particulate process includes reactors, towers,
compressor, and heat exchanger, Pump and Vessel are not included (2). Nnp will be 19. Putting P
and Nnp in the equation of 𝑁𝑂𝐿 will give 3.265 and this number should be rounded to 4.
Labor Wages and Total number of operators are needed to calculate the COL . Annual
Labor wages were found to be 52500$ in 2014(2). The Annual labor wages in 2016 is $53550 by
assuming 2 percent increasing from 2014. To calculate the total number of operators is by using
this equation 𝑁𝑂𝐿 × # 𝑜𝑓 𝑜𝑝𝑒𝑟𝑎𝑡𝑜𝑟 ℎ𝑖𝑟𝑒𝑑 𝑓𝑜𝑟 𝑒𝑎𝑐ℎ 𝑜𝑝𝑒𝑟𝑎𝑡𝑜𝑟 = 5 × 4 = 20.
COL = The Annual labor wages × Total number of operators = 1,071,000 $
19
Table 7: Operating labor cost variable
Number of week in year 52
Number of weeks for vacation 3
Number of shift per week 5
Hours each shift 8
Total hours /year 1960
Total hours of operation 8760
Number of operator hired for each operator 4.5
NOL 4
Annual mean Wages in 2016 53,550
Total number of operators 20
COL $1,071,000
Cost of Raw Materials:
The raw materials in the Ethylene Oxide production are Ethylene, air, and process water.
The mass flowrate of ethylene was given in the process description. Moreover, the price of
ethylene was found to be 39 $/tonne therefore the mass flowrate was converted in tonne / year in
order to find the final cost in unit of $/year. The cost of the process water and air were calculated
using the same methodology. Since air does not affect the reaction of producing ethylene oxide,
the source of air was considered to be from the atmosphere.
Ethylene: The price of ethylene was found to be equal to 39 $/tonne.
Air: the price of air was assumed to be equal to zero
Process water: it was assumed to be hot water. The price of process water found to be equal to
29.97 $/tonne
Cost of Waste treatment
Waste water: the only waste of the process is water. Using the given mass flow rate. The price
found to be equal to 0.041$/tonne.
20
Direct Manufacturing Costs:
The direct manufacturing cost was calculated by summing the following:
CRM + CWT + CUT + 1.33 COL + 0.03 COM + 0.069 FCL
Where
CRM is the cost of raw materials
CWT is the cost of waste treatment
CUT is the cost of utilities
COL is the cost of operating labor
FCL is the fixed capital cost
COM is cost of manufacturing
Using the correlation above, the direct manufacturing cost found to be $ 489,242,558.
Direct Supervisory and Clerical Labor:
The Direct Supervisory and Clerical Labor was calculated using the formula below.
Direct Supervisory and Clerical Labor = 0.18 (Operating Labor)
Using the correlation above, the Direct Supervisory and Clerical Labor cost found to be $
192,780.
Maintenance and Repairs:
Maintenance and Repairs was calculated using the formula below.
Maintenance and Repairs = 0.06 (Fixed Capital Investment)
Using the correlation above, the Maintenance and Repairs cost found to be $ 65,870,122.
Fixed Manufacturing:
Fixed Manufacturing Cost = 0.708 (Operating Labor) + 0.068 (Fixed Capital Investment)
Using the correlation above, the Fixed Manufacturing cost found to be $ 78,411,073.
21
Local taxes and Insurance:
Local taxes and Insurance = 0.032 (Fixed Capital Investment)
Using the correlation above, Local taxes and Insurance cost found to be $ 35,130,732.
Plant Overhead costs:
Plant Overhead costs = 0.708 (Operating Labor) + 0.036 (Fixed Capital Investment)
Using the correlation above, the Plant Overhead costs cost found to be $ 40,280,314.
Lab Charges:
Lab Charges = 0.15 (Operating Labor)
Using the correlation above, the Lab Charges costs cost found to be $ 160,650.
Patents and Royalties:
Patents and Royalties = 0.03 (Cost of Manufacturing)
Using the correlation above, the Patents and Royalties costs cost found to be $
20,525,847.
Cost of Manufacturing :
COM = (1/0.81) (Raw Materials+ Waste treatment+ Utilities) + 2.215(Operating Labor) +…
…0.146FCI
Where FCI is Fixed Capital Investment
Using the correlation above, the Cost of Manufacturing found to be $ 684,194,901.
General Expenses:
General Expenses = 0.177 (Operating Labor) + 0.009((Fixed Capital Investment) + 0.16 (COM)
Using the correlation above, the Cost of Manufacturing found to be $ 119,541,270.
22
Administration Costs:
Administration Costs = 1.177 (Direct Supervisory and Clerical Labor) + 0.009 ( FCI)
Using the correlation above, the Administration Costs found to be $ 10,107,420.
Distribution and Selling Costs:
Distribution and Selling Costs = 0.11 (Raw Materials)
Using the correlation above, the Distribution and Selling Costs found to be $ 75,261,439.
Research and Development:
Research and Development = 0.05 (COM)
Using the correlation above, the Distribution and Selling Costs found to be $ 34,209,745.
Appendix C: Electricity Price Extrapolation
year cent/kW-
h
2005 5.73
2006 6.16
2007 6.39
2008 6.96
2009 6.83
2010 6.77
2011 6.82
2012 6.67
2013 6.89
2014 7.01
2015 6.89
2016 7.18
The data in the table was used to plot the correlation in the figure above and extrapolate linearly
to find the cost of electricity in 2016.
y = 0.0919x - 178.09
R² = 0.5915
5.0
5.5
6.0
6.5
7.0
7.5
2004 2006 2008 2010 2012 2014 2016
Pri
ce in
Cen
ts/k
W-h
r
Year
Price of Electricity
23
Appendix D: Profitability Detailed Calculations
1. Revenue Calculation:
To get the revenue calculation, we need to get the product price ($/MT) and also the
amount annually that the plant will produce (MT/year) to get the total price.
Total Price = Amount Annually × Price = 260635.2 MT
Year × 4298.23
$
MT
= 1,120,272,081 $
year
2. Taxes:
Taxes = (Revenue − Operating Cost − Depreciation) × Tax rate
= (1,120,272,081 − 577,784,528 − 107,576,393) × 0.25 = $108,682,790
3. After tax (Net Profit) :
Taxes = (Revenue − Operating Cost − Depreciation − Taxes)
= (1,120,272,081 − 577,784,528 − 107,576,393 − 108,682,790) = $108,682,790
4. Present Worth Discrete Cash Flow (P):
P = A [(1 + i)n − 1
i(1 + i)n] = −22,449,249 $ × [
(1 + 0.005)12 − 1
0.005(1 + 0.005)12] = −$260,836,294
Where A is the monthly distributed cash flow and 𝑖 is the Annual or monthly interest rate and
n is the annual or monthly period.
5. Future Worth Discrete Cash Flow (F):
F = P[(1 + i)n] = −$260,836,294 × (1 + 0.005)144 = −$534,910,243