Optimal model development of energy hub to supply water, heating and electrical demands of a cement factory

Accepted Manuscript Optimal model development of energy hub to supply water, heating and electrical demands of a cement factory Mostafa Mostafavi Sani, Alireza Noorpoor, Majid Shafie-Pour Motlagh PII:

S0360-5442(19)30447-5

DOI:

https://doi.org/10.1016/j.energy.2019.03.043

Reference:

EGY 14879

To appear in:

Energy

Received Date: 11 July 2018 Revised Date:

5 March 2019

Accepted Date: 7 March 2019

Please cite this article as: Sani MM, Noorpoor A, Shafie-Pour Motlagh M, Optimal model development of energy hub to supply water, heating and electrical demands of a cement factory, Energy (2019), doi: https://doi.org/10.1016/j.energy.2019.03.043. This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final form. Please note that during the production process errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain.

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Optimal model development of energy hub to supply water, heating and electrical demands of a cement factory

1

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Mostafa Mostafavi Sani1, Alireza Noorpoor1*, Majid Shafie-Pour Motlagh1 School of Environment, College of Engineering, University of Tehran, Tehran, Iran

Abstract

This paper uses the energy hub concept to meet the electricity, heat and water demand of a

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cement plant. Given the cement plant’s high potential for waste heat recovery so the use of recycled waste heat was compared to a state where such waste heat was not used by taking

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exergy, economic and environmental analyzes into account. The proposed energy hub consists of electricity, heat and desalinated water production equipment. Energy hub is optimized based on the Genetic Algorithm (GA) with the goal of supplying demand, as well as reducing costs and pollutants and increasing the exergy efficiency which ultimately will be selected using the concept of an energy hub at its optimal capacity. By comparing the two energy supplying

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systems of the current case study and optimal energy hub, results showed that the Total Annual Cost (TAC) level decreased by about 37,000 $/year and exergy efficiency increased by 36%. CO2 emission will also decrease by about 21,620 tons/year. Moreover, in the energy hub concept, the waste heat recovery and ignoring waste heat scenarios were compared. Results

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indicate that upon optimization, the average of TAC when waste heat is recovered, is 27% of the condition when waste heat is ignored.

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Keywords: Energy hub; Multi-Effect Desalination (MED); Reverse Osmosis (RO); Total Annual Cost (TAC); Genetic Algorithm.

*

Corresponding author: Alireza Noorpoor, Associate Professor, School of Environment, College of Engineering, University of Tehran, Tel: +98-021-66476132 E-mail address: [email protected]

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Nomenclature List of acronyms

v

Dispatch factors (-)

Combined-Cycle Power Plant

Vw

Permeate velocity [m/s]

CHP

Combined Heat and Power

wp

Pump Power (kW)

CRF

Capital Recovery Factor

Z&

Capital cost rate ($/year)

CTGs

Combustion Turbine Generators

Zk

Component purchase cost ($)

EW

Energy consumption per Water production in RO

ZO&M

Operation and Maintenance Cost

GOR

Gained Output Ratio

Subscripts

GT

Gas Turbine

amb

LHV

Lower Heat Value (kJ/kg)

b

MED

Multi-Effect Desalination

ORC

Organic Rankine Cycle

PAR

Peak to Average Ration

SC Ambient brine

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NSGA

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CCPP

boi

Boiler

bp

Brine Pump

CC

Combustion Chamber

ch

Chemical

CV

Control Volume

Non dominated elitist and rapid Sorting Genetic

Algorithm Natural Gas

MSF

Multi-stage flash distillation

D

Distraction

SDI

Silt Density Index

dmn

Demand

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NG

Total Annual Cost ($/year)

e

Exergy

WHO

World Health Organization

em

emission

extra

Waste heat from cement plant

Water permeability coefficient [kg/m2·s·Pa]

f

Feed

Solute transport coefficient [kg/m2·s]

h

Heat

Coupling matrix

hot

Hot water

Salt concentration [ppm]

hpp

High Pressure Pump

Cw

Brine concentration [kg/m3]

i

inlet

CC

RO capital cost subsystems

m

Material

d

Feed channel equivalent diameter [m]

max Boi Maximum Boiler

A B Cij C

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List of symbols

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TAC

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ds

Distance from the ideal point

NG

Natural Gas

Ds

Solute diffusivity [m2/s]

p

Permeate stream

e, ex

Exergy (kJ/kg)

pu

Ex

Exergy flow (kW)

Sc

EWRO

Electrical consumption per water production

pipeline Pipe line

Fij

Non-dimensionalize objective indexes

Ph

Physical

Q

Heat Sell

Material correction factor

S

Jw

Local permeate flux [kg/m2·s]

ST

Js

Local solute flux [kg/m2·s]

SW

K

Mass transfer coefficient [m/s]

L

Output loads of the hub

LDe

Output electrical loads of the hub (kW)

LDh

Output heat loads of the hub (kW)

LDw

Steam Turbine Sea Water

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f

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Interest rate

Schmidt number

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int

Pump

Sea Water Intake and Pre-treatment

T

Turbine

trf

Transfer

u

Number of exergy carrier

Output water loads of the hub (kW)

x

objective’s index

N

Operation hours in a year

w

Membrane wall

mf

Feed water flow rate (kg/s)

z

index for each Pareto front point

mhot

Hot water flow rate (L/s)

0

P

Input carriers of the hub

Greek symbols

PE

Exchanging electricity of the hub (kW)

α,β,ω,ε

Type of energy carrier

Exchanging heat of the hub (kW)

η

Efficiency

Exchanging water of the hub (kW)

ρ

Density (kg/ m3), Integer Numbers

Input vector of the hub

ξ

Chemical exergy/energy ratio

Output vector of the hub

ε

Total cycle exergy efficiency (-)

Q

Heat flow (kW)

τ

Hours of operation per year (h)

QB

Brine flow rate (m3/h)

φf

Fuel cost ($/kg)

QP

permeate flow rate (m3/h)

φe,s

Selling electricity cost ($/kWh)

PW Pi Pj

EP

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PH

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SWIP

Standard Situation

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Recovery (%)

ρp

Density of the permeate [kg/m3]

Re 

Reynolds number

π

Osmotic pressure [MPa]

Membrane area (m2)

φe,b

Buying electricity cost ($/kWh)

Thot

Hot water temperatures (˚C)

ψem

Pollutant emission cost ($/kg)

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RRO

1. Introduction

The point of confrontation energy carriers, conversion equipment, energy storage and energy

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demand is known as the energy hub. The energy hub is a new and promising concept to

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optimally manage multiple energy carrier systems. The energy hub has significant potential for realizing energy system models and moves towards sustainable multi-energy systems [1]. Energy hub utilization will lead to 1) reduction in energy consumption 2) simplicity and high accuracy in multiple system carrier analysis and assessment 3) increased reliability 4) multi-dimensional analysis of energy systems (technical, economic, environmental). The main element in defining

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energy networks is the energy hub. Numerous researches have been conducted on the hub. A residential energy hub model was proposed by Brahman et al. [2] that obtains solar radiation, natural gas (NG) and electricity as inputs to provide cooling, heating and electricity at its output

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port. An optimization issue was dealt with regarding electrical and thermal energy management

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with the aim of reducing total energy costs of customer’s input in terms of NOx, CO2 and SOx emissions. Mohammadi et al. [3] addressed the advantages of integrating options such as smart technologies, storage systems, multi-generation systems, renewable energy resources, distributed energy resources and demand side management by proposing the smart energy hubs concept. In order to utilize zero emissions renewable sources into dispatchable combined cycle power plants, Bahrami et al. [4] fabricated a real time energy hub scheduling issue within a dynamic pricing market. The interaction of the energy hub is modelled in the form of a precise potential game for

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energy hub payment optimization purposes concerning gas and electricity utilities. The results of the simulations indicate that the suggested algorithm may enhance the average payoff of the energy hub by 18.8%. Moreover, companies that provide energy services may enhance energy

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network technical performances through a reduction of the peak to average ration i.e. PAR for gas and electricity by 7% and 27%, correspondingly. AIRafea et al. [5] proposed a modern energy hub. For this energy hub, hydrogen is introduced as an energy vector to replace coal fired

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Nanticoke power plant. With the addition of hydrogen into natural gases as a fuel for combined cycle power plants, additional costs and annual revenue reduction will be the consequences. CO2

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and NOx emission credits will also increase. In order to start increasing annual revenue, electricity should be sold at 0.12 $/kWh with hydrogen at 3.7% in fuel of combined-cycle power plant (CCPP). To maximize the employment of waste heat from coal fired thermal plants for the benefit of factories in the vicinity, Togawa et al. [6] proposed a stimulation process model that

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integrates land use control, technology systems and spatial analysis. The acquired results showed that waste heat systems exhibited several environmental advantages compared to the individual boiler system. By employing waste heat, the consumption of fuel oil is reduced by 16.05 TJ/year

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and there is a CO2 emissions reduction of 1204 tons per year. Another solution to reduce energy consumption and environmental consequences is to use waste

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heat from factories and to implement a comprehensive integrated system in remote areas suffering from water shortages. This paper addresses waste heat from a cement plant. The process of producing cement is extremely energy intensive with approximately 3-4 GJ energy consumption for each ton of produced cement. Furthermore, Iran is the fourth largest cement manufacturer in the world after China, India and the USA with an annual production of 75 million tons [7]. 40% to 60% of cement production costs are accredited to energy consumption

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[8]. 3% of energy production is accredited to the cement industry in Iran [9]. Within a cement factory, electrical energy is 25% of the total energy consumption while heat energy accounts for approximately 75% of total energy consumption [10]. In the case of integrated systems and the

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use of waste heat, the work of Salimi and Amidpour [11] can be referred to, which, based on the R-curve, examined the integration of different water desalination systems. Mokhtari et al. [12] proposed the gas turbine (GT) +MED+RO water desalination method based on exergy and

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thermo-economics analysis for the Persian Gulf region. The system was designed on the basis of the simultaneous generation of electricity and water and could reduce total water production

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costs. Muhammad Wakil Shahzad et al. [13] proposed a combination of absorption and RO systems based on low temperature industrial heat sources or heat from the sun to address lack of water in the Persian Gulf region, which resulted in 81% efficiency and energy consumption of 1.76 kWh/m3. Arash Nemati et al. [14] utilized waste heat from a large diesel ship engine to

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produce desalinated seawater. On the basis of the radiation curve amidst optimization, the obtained efficiency was 37% and the cost of exergy destruction was 60 $/GJ. Reynolds et al. [15] suggested a district energy management optimization strategy for the optimization of district heat

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generated from a multi vector energy center. The outcomes show the possible gain when energy is managed in a holistic state, taking both supply and demand into account as well as multiple

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energy vectors. Moeini-Aghtaie et al. [16] proposed an online economic dispatch for multiple energy carriers to achieve a probabilistic economic dispatch optimization model. This model is addressed using a stable optimization mechanism i.e. multi-agent genetic algorithm with an advantageous property of finding the global optima of the economic dispatch issue. Ko et al. [17] recommended a method for the optimization of an energy system whilst concurrently reducing life cycle cost and increasing renewable energy penetration as well as reducing annual

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greenhouse gas discharge. A non-dominated elitist and rapid Sorting Genetic (NSGA) is used for the purpose of multi objective optimization. The Pareto-optimal solution evolution based on the variations in the technical, economic and environmental objective functions via generations is

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examined. Kampouropoulose [18] suggested a method and associated software tools to derive the optimal energy flow pertaining to a multi-carrier system to meet energy needs and reduce a number of defined optimization criterion on the basis of the Genetic Algorithm.

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Given that fifty-nine percent of drinking water is supplied from the sea through desalination processes [19], various methods have been developed for the production of freshwater from the

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sea across the world. Energy expenditures (thermal, electricity) in water desalination systems are as follows: RO
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this capacity [21, 22]. The energy used for RO system is dependent on the salinity of the water as well as the system used for energy recovery. For seawater, the energy consumption with and without the recycling device is 12 and 4 kWh/m3, respectively. However, with the development

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and improved performance of RO systems, the price of desalinated water has decreased from 2 $/m3 to roughly 0.8 $/m3[19, 23]. However, the MED thermal water desalination system is still

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developing and has retained its position across the world. MED system has a heating energy consumption of 71.7 kWh and electricity consumption of 2.3 kWh [24]. Considering the high energy consumption of water desalination systems as well as rising fresh water demand (from 77.4 in 2014 to 92 million in 2018), this technology has become a major source of CO2 emissions [24]. In this regard, CO2 production is estimated at 100 million tons per year [19, 24]. In other words, for each cubic meter of fresh water, about 3 kg of greenhouse gas is produced

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[25, 26]. The increasing trend in 2040 will bring greenhouse gas emissions to 218 tons per year and an approximate temperature increase of 2 °C [27, 28]. Due to the high energy consumption of RO and MED, in order to 1) reduce costs 2) reduce greenhouse gas production 3) increase

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productivity and 4) reduce gas and oil consumption in energy rich areas (such as the Persian Gulf), waste heat from factories can be used to produce desalinated water and meet regional demands (power generation and water heating). The existence of rich gas and oil resources has

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led to industrial development in this region. Also, population dispersion in the Persian Gulf due to weather conditions as well as the existence of various islands in the area has become an issue

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for governments to meet the existing energy demand of residents. In regard to the water production along with other energy requirements is an energy-intensive process, it is logical to define an energy hub.

In the case study, the consumption requirements of various energy carriers in the cement factory

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and in the nearby city should be satisfied. Thus, energy production and consumption management as well as the selection of equipment with optimal capacity are considered. In addition, the priority in energy systems is to maximize efficiency. In this research, the optimal

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utilization of waste heat in the cement factory which increases efficiency and reduces costs and emissions is taken into account. However, due to the lack of water desalination systems in

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the current state, drinking water is transported to the place of consumption through tankers, which, in addition to production and transportation costs, entails accessibility and sanitation issues. In this study, by constructing desalination systems, electricity and heat generation at the place of consumption has not only significantly contributed to the supply of energy carriers, but also improved energy efficiency whilst reducing costs and emissions through optimal operation. In regard to the aforementioned points and the necessity to supply multiple energy carriers

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including electricity, heat and desalinated water, the case study is modelled using the concept of energy hub. In order to supply energy carriers with minimum costs and emissions along with maximum exergy efficiency, a methodology is presented in Fig. 1. According to this figure,

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the decision making variables and inputs amidst the modelling section are entered to the system

energy carriers in each of the energy hub equipment.

Weather condition

Inputs

Dispatch factors

Decision Variables

RRO

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Text

Design Hub

Demands

System of equations (Table 2)

Text

Mhot

EWRO QBoiler

Design factors

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Thot

CHP Model

Outputs

PeCHP, PeST, PeRO QCHP, QST, Qb mRO, mMED Text

     

Genetic Algorithm

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of equation to determine production and consumption variables for electricity, heat, and water

PE, PSW, PH Total investment cost

O&M Cost

Objective function

Capacities

TAC

Boiler Model

Objective function

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EP

Exergy efficiency

MED Model RO Model ST Model CO2 Emission Number of Equipment

Fig. 1. Description of modelling methodology

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Upon modelling each of the equipment and determining energy production and consumption,

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quantity and capacity of equipment, operation and maintenance costs, and quantity of produced emissions, the TAC can be created. Moreover, exergy efficiency may also be extracted. Non dominated elitist and rapid Sorting Genetic Algorithm (NSGA-II) was implemented to present a

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series of Pareto multiple optimal solutions. Changes in optimal value sensitivity analysis, exergy efficiency and TAC as well as changes in design factors were assessed. Finally, upon integrated

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optimization of the energy hub with the purpose of reducing costs and increasing exergy efficiency, the optimal capacity of the equipment and assigned energy carriers are determined. By assessing various papers on energy hubs and separating the subject areas of these papers (Table 1), some of the research novelties are mentioned below:

Coupling matrix parameters such as efficiencies, recoveries and gained output ratio

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•

(GOR)are included variables by considering design parameters; •

Water flow is defined as an energy carrier in the energy hub, such that two water

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desalination systems consisting of MED and RO are simultaneously utilized to provide the means for optimal electricity and heat allocation to produce the required desalinated

•

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water upon optimization;

Considering multi-objective optimization in terms of exergy efficiency and total annual

cost in an energy hub system with self-consumption.

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Table 1. review of various papers on energy hubs* Coupling matrix arrays

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*

Industrial

2018

Residential

2018

Applications Optimization

Energy

2018

Economical

2018

Exergy

2018

Environmental

2017

Reliability

2016

Constant

2015

Variable

2015

Natural gas

2015

Hydrogen

2015

Water

2014

Cooling

2014

M. Geidl et al. [41] R. Evins et al. [29] A. Sharif et al. [30] M. Rastegar et al. [31] A. Maroufmashat et al. [32] A. Maroufmashat et al. [33] F. Brahman et al. [2] A. Najafi et al. [34] M. Majidi et al. [35] V. Davatgaran et al. [36] S. Amiri et al. [37] J. Teodoro et al. [38] R. Ghaffarpour et al. [39] M. Aghamohamadi et al. [40]

Heating

2007

Authors

Power

Year

Analyses

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Energy hub carriers

Objective functions

Cost & Emission Emission Cost Cost Cost Cost & Emission Cost & Emission Cost Cost & Emission Cost Cost & Reliability

In the table above, the filled in boxes represent the studies conducted in that field. As evident, variable arrays for the coupling matrix are not considered in any previous studies.

Cost Cost Cost

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2. Thermal modeling 2.1.Energy Hub In order to achieve an integrated system, a modeling and analysis framework for multi-carrier

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energy systems must be developed. The current model is between converter devices based on the efficiency of the output-to-input ratio. When there are numerous outputs, a conversion matrix or coupling matrix is defined which represents the transformation of energy carriers from the input

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to the hub outputs. If necessary, storage devices are used that take time and energy into account [41]. The energy conversion between different energy hub ports is typically shown using a

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coupling matrix (C). The relationship between different input and output ports for an example hub is shown in Fig. 2.

piα pψi pi

• • •

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ω

pαj p βj • • •

pωj

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Fig. 2. Relationship between the input and output ports of an energy hub with a Cij coupling matrix [41]

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The exchangeable power in inlet and outlet ports are expressed by Pi and Pj vectors respectively and these power vectors are related via the coupling matrix by the following equations. In this equation, the Cij is the coupling matrix array which according to the characteristics of the existing elements, associate the hub inputs and outputs (Eq. (1)) [41].    ⋯  "    ⋱ ⋮ * ⋮ + = 0  ⋮ + ⋮      ⋯     $%%%%&%%%%' 

()

)

(1)

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There are two important properties in the coupling matrix arrays: 1- According to the energy conservation law, energy is converted from one form to another, but in the process of conversion, there is also some energy wasted, so all coupling matrix arrays fall

0 ≤  ≤ 1

∀(3, 5)78

/

and

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into the maximum or minimum values according to the following equation (Eq. (2)) [41]. 9, : 7 ;

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In this equation:

∀(3, 5) 7 8 = <(1,2), (3,4), … A , 9, :, B 7 ; =
(2)

(3)

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2- According to the total energy conservation law, all outputs converted from a given input must be less than or equal to the input value. Therefore, the total arrays of each column in the coupling matrix must be less than or equal to the relation below (Eq. (4)) [41]. / 

≤1

∀(3, 5)78

9, : 7 ;

(4)

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0 ≤ ∑/PQ 

If the output loads of the hub are represented by L and the input carriers of the hub are represented by P, the previous equation can be rewritten as follows:

S

(

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R  ⋯   ⋱ ⋮ +* ⋮ + * ⋮ +=* ⋮ R   ⋯    $%%%%&%%%%'

(5)



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As long as the coupling matrix elements, known as an efficiency of energy hub equipment, have constant and independent values, Eq. (5) is linear. However, considering the dependence of the equipment efficiency on the input energy, this equation will be nonlinear [41]. Since one type of input energy into the hub may be split into several parts and enters various converters within the hub, coefficients named dispatch factors are defined which represent the amount of input energy assigned to each of the hub convertors. In multi-input and multi-output

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hubs, the number of coupling matrix elements depends on the dispatch factors as well as the converter equipment efficiency. Fig. 3 shows the industrial plant configuration evaluation for this section. Commercially available water oriented industry technology is the basis of this design.

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This plant consists of a MED for potable water production, RO plant, steam turbine, and combustion turbine generators (CTGs) and a boiler. The plant scope is identified and specified according to the aim of this research and multigenerational factors. An alternative energy source

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and high efficiency are proven properties of this plant to minimize CO2 emissions. Fig. 3 presents thermal plant overall system flow. Three varying potential energy sources were taken

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into account. Waste heat in cement plant is the first source. The second source is exhausted gas from the GT stack. The third source is heat energy from the boiler. Electrical load requirements for the energy hub can be met using energy sources such as electrical grid, steam turbine, and GT systems. The dispatch factors vMED, vBoi, vCHP, vST and vRO are in interval at all times [0, 1]. As

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previously stated, the energy hub model is considered for multi-energy carrier systems and represents continuity equations by considering a control volume such that each input energy carrier to the system is multiplied by the coupling matrix coefficient, exhibiting its influence on

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the considered output load so that the sum of these inputs determines the output load by taking the energy hub productions and consumptions into account. The important point is that the

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output loads are known as specified quantity in each energy hub which ultimately, by expanding the equations (Table 2) and implementing decision variables and assumptions for each equipment and energy converters, the required input energy to the system, the coupling matrix coefficients, and hence the capacities of each equipment can be determined. The decision variables for each equipment and dispatch factors are related to the considered objective function in optimization and will be determined accordingly. Thermal, electrical and water loads along

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with waste heat from the cement plant are shown as LDH, LDe, LDW and Qextra respectively which are determined according to Fig. 5 and section 5. Section 7.1 shows decision parameter values, vMED, vBo, vST, vRO, RRO, Thot, Mhot, EWRO, Qmax,Boi which are determined by the GA

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optimization method given their limits. The values of GT efficiency (ηCHP) and steam cycle efficiency (ηST) are obtained according to the reference curve of the power plant characteristics. The GOR value will also be determined from section 2.3 from the Thot and Mhot decision

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variables. According to Table 2, 12 variables can be determined from 12 equations and the energy hub can be obtained. In order to further highlight the aforementioned points, Fig. 1

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depicts a schematic of the paper’s modelling process. Based on this diagram, the weather condition along with the water, electricity, and heat demands as well as the decision variables are entered to the system equation shown in Table 2 as known values. All energy vectors pertaining to the energy equipment are specified in the hub. These values are entered in the equipment

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modelling process. The output determines the equipment’s capacity, their quantity and other required parameters relevant to the TAC and exergy efficiency. Finally, by optimizing this model, the design factor, equipment and their quantities for the optimal objective functions will

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be determined.

In Table 2, row 1 of the energy continuity equation for electric current is presented in Fig. 3. In

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GT power generators and steam turbines, these inputs should be equal to electrical consumption of RO and the power consumption of the hub. Rows 2 and 3 are auxiliary equations that are extracted according to their definition. In row 4 of this table, the hub water affinity equation is presented. The water produced by the RO and MED system should be equal to the demand for water.

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Ex& Heat , χ

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EP

TE D

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Ex& Power , χ

Ex&Water , χ

Ex&dmn ,1

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Ex&NG

LD H

Fig. 3. Schematic view of energy hub used in case study

LDe

Ex&dmn,2

LDW

Ex&dmn ,3

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Table 2. Design equation for energy hub model [6].

4 5 6 7

8 9 10

11

^YZ + ^_W` + Ua − R[ = 0

^YZ , ^_W` , Ua

^YZ = ]YZ (^_W` + Ua ) ^YZ = ]_W` (^YZ + Ua )

b(T − bUV + bc + T − b_W` + bWdef" − R[T = 0 bc = ]gh (b(T − bUV + T − b_W` + bWdef" ) DYZ = KNYZ ^YZ b(T =

(1 − i(T ) D(T i(T

jkl =

^_W` 2326 n5 b_W` 1 nH

bUV =

DUV iUV

](T

R[

b(T , bUV , bc , T

bWdef" , R[T

i(T

]UV

]YZ

]_W` ]gh

KNYZ

iUV

jkl

EP

12

DUV = ]UV (D(T + W − DYZ )

Decision variables

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3

D(T = ](T (DUV + W − DYZ )

D(T , DUV , W , DYZ

Specified quantity R[\

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2

D(T + DUV + W − DYZ − R[\ = 0

Unspecified quantity

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1

Equations

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Row

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In row 7, the heat produced by the GT, boiler and waste heat from the cement plant are heat generators in the hub, which should provide the heat required by the steam turbine, MED and hub thermal demand. Also, the current (PE), water (PSW) and heat (PH) input to the hub from the grid or the output from the hub to the grid can be placed with a positive and negative sign respectively. All equations of rows 2, 3, 4, 5, 6, and 8 are defined by dispatch factors vCHP, vST, vRO, vMED and vBoi which are decision variables and determine the amount of energy distribution in

each of the energy carriers within the hub equipment.

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2.2.RO modeling Two modeling methods for the RO system are proposed by FILMTEC [44]. The first method is

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element to element. In the second method, if the feed quality, temperature, and intensity of the purified water flow and the number of elements are known, the average value is used to calculate the feed pressure and quality of purified water. If instead of the number of elements, the feed pressure is specified, the number of elements is obtained through several integration equations.

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The design equations for the FILMTEC SW30 8-inch elements are given in the references [44].

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In this paper, considering the demand for water and the maximum water quality required based on the World Health Organization (WHO) standard for drinking water [45], the required water recovery, 6 elements per pressure vessel, membrane type selection (SW30XLE-400i) and water flow intensity and a silt density index (SDI) of under 3 [44], and the amount of power assigned to the RO can be determined based on the amount of feed pressure. The mean value method is

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considered. In regard to the hub, by determining the amount of power, the pressure can be determined based on the equation below [44]. ^qr (r − "sc ) 8iop

(6)

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q = Nop

In this model, the Pelton turbine has been used as an energy recovery system. According to Eq.

[44].

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(7), the amount of energy required by the RO system can be determined in accordance to Eq. (8)

Nq V =

^q c (c − op ) 8hpe iV

Nqt\e = Nqop − NqV

The basic equations in designing RO system are available in Appendix A.

(7) (8)

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2.3.MED modeling According to reference [43] where a multi-effect distillation system is assessed as experimental characterization, a number of empirical equations are extracted in order to assess the

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performance of the system under off-design conditions. In addition, the impact of the key parameters variation where the MED plant is controlled (inlet hot water flow rate (mhot) and temperature (Thot)) on GOR and freshwater production were evaluated with an empirical

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campaign of 82 tests. The MED plant steady state results working at off-design circumstances are addressed in a state which presents: The Thot and the mhot effect on the production of distillate (mMED) and on the plant GOR. The MED modeling equations are presented in this

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section. Eq. (9) and Eq. (10) are valid for 60 ≤ uvhe ≤ 74 ℃ and 7 ≤ ^vhe ≤ 14 U [43]. } ) ^_W` = −0.273 + (0.008409 uvhe ) − (0.04452 ^vhe ) + (0.0003093 uvhe − } ) (0.002485 ^vhe + (0.001969 uvhe ^vhe )

S

(9)

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} ) jkl_W` = 648.2 − (26.74 uvhe ) − (16.45 ^vhe ) + (0.3842 uvhe + ~ ) } ) (0.3137 uvhe ^vhe ) + (0.5995 ^vhe − (0.001835 uvhe −

(10)

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~ ) } } (0.002371 uvhe ^vhe ) − (0.01844 ^vhe − (0.0001411 uvhe ^vhe )

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The latter parameter determines the thermal efficiency of a MED plant (GOR) and it is expressed in Table 2. (row 12). Where mMED is the distillate production (L/s); Gain origin ration (GOR) (-); hot water temperatures (Thot), and the hot water flow rate (mhot); Qhot Heat consumed by MED. Moreover, in Table 3, the operation conditions for each system in the optimal scenario involving waste heat recovery are presented.

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Table 3. The operating conditions of the energy hub [57, 63 and 64]

GT

Boiler

1 64.35 11.54 9.56 115 1 86 10 0.098 90 36 4028.7 48550 0.65 2.75 0.0982

Pipeline length

m

1900

Ambient temperature Ambient pressure Salinity of Seawater

°C kPa ppm [mg/kg]

298 100 42000

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ST

Fuel

-

1200 6

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Water transfer Ambient

L/s (-) (-) kJ/kg (-) (-) kg/s % % kW kJ/kg kg/m3 kgCO2/kgfuel kg/s

$

Value 0.9965 37.2

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MED

Unit (-) m2

RI PT

RO

Parameters Salt rejection Active RO membrane area Membrane element cost, estimation Element (type SW30XLE-400) Number of membranes in each pressure pipe Number of steps in RO Hot water inlet temperature Hot water flow rate GOR Air-fuel ratio Hot gas Specific Heat Isotropic turbine efficiency Compressor pressure ratio Fuel consumption Efficiency in full load mode Efficiency in full load mode Heat Consumption Lower Heating Value (LHV) NG density m CO2 Fuel consumption

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Component

2.4.Pumping system

A pumping system is necessary to transfer water. Eq. (11) shows the system’s energy consumption in Ppu (Mj/h) [6]. op =

H × ^qefr × C × 1000} × 60} ηop

(11)

ACCEPTED MANUSCRIPT Such that g is the gravitational acceleration (m/s2), ηop denotes pumping efficiency ratio i.e.

0.75, ^qefr represents media flux in terms of kg/s and H is the lifting height in terms of (m). According to the Darcye-Weisbach equation, Eq. (12) expresses the lifting height [6]: R ]} × +n [ 2H

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C=‚×

(12)

Such that L is the length of the pipeline (m), D is the internal diameter of the pipeline (m), v

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denotes media velocity (m/s), g denotes gravitational acceleration (m/s2), f represents coefficient of friction loss, and k denotes friction loss via local resistance.

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3. Exergy analysis

Exergy analysis can aid in developing strategies and guidelines for the effective use of energy in various systems. Exergy can be divided into four categories. Two prominent types of exergy are physical exergy and chemical exergy. In this study, potential exergy and kinetic exergy are

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hypothesized as negligible. The physical exergy equals the maximum workable flow of matter and is determined by a process from the initial state or an environment that only involves heat exchange with its surroundings. Chemical exergy occurs by the exit of chemical compounds

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from a system of chemical equilibrium [46]. Chemical exergy is part of the exergy in the combustion process. By using the first and second law of thermodynamics, the following exergy

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equilibrium is obtained [47-49].

ƒK„(… u‡ ƒ‹(… = †(1 − ) bq ˆ − ‰Nq − Š‡ Œ + † ^q ˆ D − † ^q \ D\ − K„q ` ƒF u ƒF \

(13)

Or Exq  + † mq ‘ ex’ = † mq ” ex” + Exq• + Exq – ’

”

(14)

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The χ parameter indicates that when exergy flow is outside the control volume shown in Fig. 3 and enters the system (χ=Buy), it is considered positive in equations and if exergy flow exits volume control (χ=Cell) it is shown as negative in equations.

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In Fig. 3, exergy flow is calculated as: K„q˜™ = ^qr,Vhe"š RC‹ ›

Where parameter ξ is defined as follows for NG [47]:

ov —v K„qa"e\f = K„qa"e\f + K„qa"e\f

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Water flow exergy is equal to [50]:

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œ 0.0698 › = 1.033 + 0.0169 − „ „

(15)

(16)

(17)

—v Where K„qa"e\f and K„qa"e\f are water physical exergy and chemical exergy respectively and are ov

K„q = (1 −

uh )b q uv v

K„qh\f = Nq

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calculated in [50]. Heat exergy and electricity are calculated based on Eq. (18) and Eq. (19) [51]:

(18) (19)

~ q ∑˜ ∑˜ ežŸ K„o,e ežŸ(∑pžŸ K„ st,p ) ¡e = q ∑˜ ∑˜ ežŸ(^qr,(T RC‹ + Kc ) ¡e ežŸ K„r,e

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;=

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Finally, hub exergy efficiency is calculated based on Eq. (20) [51]:

(20)

If u=1, heat exergy of the demand heat flow is calculated as follows [52]: Kq st,p = ‰1 −

u‡ Œ Cq uv  st

(21)

If u=2, electricity demand exergy is calculated as follows [51]: Kq st,} = Kq¢

(22)

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If u=3, water demand exergy is calculated as follows [50]:  st Kq st,~ = Kqa"e\f = ^q"e\f K„q"e\f

(23)

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4. Economic analysis Economic analysis is required to select equipment and coefficients stated in the hub section. In economic analysis, equipment costs and maintenance costs are calculated according to the utilized equipment. Eq. (24) is used to estimate MED costs [52]:

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_W` = £_W` lÅ + £Z&_

(24)

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In this equation, C = 81430.27 $ according the reference [53] and £Z&_ is calculated by Eq. (25)

[25].

£_W` =  ^qÆf\¢v "e\f

RO system costs are set according to Table 4.

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Table 4. RO system costs equations [25].

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Component Capital cost of the seawater intake and pre-treatment Capital cost of high pressure pump and pre-treatment

Pump

CCUa¦ = 996 (mr 24)‡.§

Equation

CC¨©© = 52 (mvoo ΔPr )

CC¬© = aŸ (mVΔP)¯° f . ϕ² 1 − 糟 ¯´ ϕ² = 1 + ‰ Œ 1 − ηŸ cast iron = 1 f = µ Steel = 1.41

f :Material correction factor, here: f = 1.41

ϕ² : First law efficiency correction factor $

aŸ = 549.13 ÀÁÂ.ÃÄ ،a} = 0.71 ،a~ = 3 ،糟 = 0.8

(25)

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Other hub costs are set according to Table 5: Table 5. The cost functions for each equipment of energy hub [54, 55].

GT

Cost function ZÈÉ = (−0.014 ™V + 600)™V ZÊÉ = 1200 UV

Steam Turbine

‡.§Í ZË̒ = 205bqgh š\f

Boiler

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Component

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Economic parameters are determined based on reference [54, 55] shown in Table 5. The cost of the transmission line is also determined by Eq. (26) with the unit of $/m [6].

where D is the media pipe diameter (m).

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efr,o o\š t\ = 0.9734 (32000 + 213000 [)

(26)

By using assumptions for Eq. (11) and Eq. (12), the necessary costs, efr , CO2 emissions flow

correspondingly:

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efr,op = L\ × op

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pertaining to the functionality of a pumping system are represented by Eq. (27) and Eq. (28),

^—h},efr = D\s × op

(27)

(28)

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Such that ce denotes generation cost within a power plant in terms of ($/MJ), eem represents the CO2 emission factor in terms of (kgCO2/MJ). Finally, TAC is calculated based on Eq. (29) [54]: uÎ Ï$МDEMÑ = _W` + YZ + ™V + UV + gh + efr + ∑˜ ežŸÒKc Ó\,c − K¢ Ó\,¢ + ^qr,ehe"š RC‹rp\š Ór + 3600 ^—h} Ô\s Õ ¡

(29)

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Table 6. Values of economic parameters [60, 61, 62] Unit %

Value 10

Operation years (n)

Year

20

Hour

8760

3

$/m $/kWh $/kWh $/kWh $/m3 $/kg CO2

0.5 0.015 0.045 0.001 0.002 0.02086

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Operation hours in a year (N) Cost of fuel Electricity sales price Electricity purchase price Heating cost Desalinated water cost CO2 emission factor (ψem)

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Economic parameters Interest rate (int)

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Table 6 presents cost parameters. τ is an hour time period and N is equal to 8760 hours. Capital recovery factor (CRF) is dependent on equipment estimated life and interest rates and is written

lÅ =

3GF (1 + 3GF)Ö\"f (1 + 3GF)Ö\"f − 1

(30)

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as [52]:

Where ‘year’ is the system service life and int is the interest rate.

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5. Case study

A diagram of the cement plant in the city of Qeshm is presented in Fig. 4. Fig. 4-a and Fig. 4-

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b show the clinker production process and the cement plant’s curing stage. In Fig. 4-a, upon combining and grinding the primary raw material, it is entered from point 1 to the preheater and after passing through the cyclones, its moisture is removed and the limestone is calcified. Then, it enters the kiln at point 2. The raw materials are cooked in the kiln and converted to a clinker prior to be transferred to a clinker cooler to cool down (clinker point 3). There are fans installed at the bottom of the clinker cooler which absorb most of the hot clinker heat and exhaust it through its upper duct. Also, in Fig. 4-b, the potential points for heat recovery from the cement

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factory are shown. One of the points where it is possible to utilize waste heat is the suspension preheater boiler (SP boiler), where the hot gas from the kiln runs upwards in the opposite direction of the raw materials, transferring some of its heat. However, a large part of the heat in

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the SP boiler is still recoverable. The resulting gases thermal energy (317 °C) that may be recovered using SP boiler is 1532 kW. Clinker has to be cooled upon being baked at 1200 °C temperature. Gases from the clinker cooler exhibit a second heat source which is recovered using

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an after quenching chamber boiler (AQC) (approximately 4088 kW) [57, 58]. Table 7 describes the characteristics of these points. Since the city of Khaledin, located on the island of Qeshm is

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close to the cement plant, its water demand to supply its 1396 population is shown in Fig. 5. The demand for consumed water (kg/s) for each hour during the year for Khaledin is determined which should be supplied by the energy hub. Also, Fig. 5 presents the cement factory’s consumption of electricity (kW) for each hour during the year. Since the variances in

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consumption in various hours of the year are insignificant in relation to the consumption level, the average annual consumption for all hours can be considered. Also, the distance between the cement factory and the city of Thurian with 2339 populations is approximately 1.9 km, which

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will allow the transfer and sales of excess water to the city. In regard to the case study, the lack of implementing technology and the inconsistency between investment costs and local prices are

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the main reasons for not using renewable energies. Also, due to inaccessibility to sufficient historical data in this paper in addition to considering the constant loading profile and national grid as a backup in storing energy, the uncertainty was not considered. Another reason that diminishes the need for uncertainty analysis is that some equipment such as desalination systems utilize variety of technologies (MED and RO) and the use of an electricity energy carrier for the RO system and thermal energy carrier for the MED system will aid in decreasing uncertainty.

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Table 7. Qeshm cement plant gas condition [57] Mass flow rate (kg/s)

290

21.4

311 215 93 99

15.9

15.9

15.9

21.4

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Clinker cooler exhaust Preheater exhaust SP boiler exhaust Stack exhaust AQC boiler exhaust

Temperature (˚C)

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Parameter

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Point

Fig. 4. Schematic of heat utilization potential in Qeshm cement plant

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Fig. 5. Values of electrical loads and water consumption

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6. Optimization

GA (Evolution) is an algorithm based on repetition. The strategy of this algorithm is to apply a random search to determine an optimal solution. In principle, the simple method of biological evolution is to emulate the evolutionary characteristics of a population of individuals in which

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the individual consists of decision variables values for a potential optimized solution. The decision variables and optimization variables are given in Table 8. The objective functions of this optimization are Eq. (20) and Eq. (29) which determine the hub’s exergy efficiency and

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economic parameter, respectively.

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Table 8. Design parameters and their range of variation for the optimization procedure.

CHP Power dispatch factor MED Water dispatch factor Boiler Heat dispatch factor Steam Turbine Power dispatch factor RO Water dispatch factor Water recovery rate (RO) Hot water inlet temperature (MED) Hot water flow rate (MED) Power consumption per Water Desalinated (RO) Maximum Heat Produced by Boiler

Parameter vCHP (-) vMED (-) vBoi (-) vST (-) vRO (-) RRO (%) Thot (°C) Mhot (L.s-1) EWRO(kJ/kg)

Lower bound 0 0 0 0 0 0.3 60 7 0.1

Upper bound 1 1 1 1 1 0.85 74 14 8

Qmax,Boi (kW)

100

3000

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A decision making process should be employed to select a single optimal point from the present points on the Pareto front. Such a process is typically based on engineering experiences where the importance of every decision making objective is highlighted. An assumed point taking the

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role of an ideal point is usually used to determine the final decision making process. When two objective functions are individually optimized whilst disregarding other objective functions, the compositions of these values symbolizes the ideal point or ideal objective point. Fig. 6 presents

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the usual Pareto front in addition to the ideal point to maximize the first objective whilst minimizing the second objective. It is evident that it is not possible to achieve both objectives at

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optimal points concurrently. The closest Pareto frontier point to the ideal point may be chosen as the final optimal solution because the ideal point is not a solution that is placed on the Pareto frontier. Prior to this, the objectives are non-dimensionalized. LINMAP, linear programming techniques for multidimensional preferences analysis method is implemented to non-

t Å×d =

Å×d ss Ø∑מŸ(Å×d )}

°

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dimensionalize the objectives in this paper by employing the following equation [59]: (31)

Such that z is the index for each Pareto front point, x is each objective’s index and mm displays

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the Pareto front’s number of points. Hence, the distance for each Pareto front point from the ideal

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point is attained [59]: }

t ƒ× = ن(Å×d − Å t \"š,d )} džŸ

(32)

Such that ideal is ideal objective function index. Thus, the value of distance for each Pareto frontier point is derived via the equation stated above and optimal point leading to minimum d is chosen as final optimal solution.

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Fig. 6. Pareto optimal front for energy hub According to [56], some of the essential characteristics of genetic optimization algorithms are:

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(1) The generality of the formulation.

(2) Robustness, in the sense of avoiding local optima, looking for global optimal points. (3) The capability of handling multiple objectives.

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(4) Computational efficiency decision variables.

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6.1. Parameter tuning

In this paper, the decision parameters are assumed values which can be changed within an acceptable and specific range as well as exerting significant effect on objective functions in order to minimize the TAC and maximize the exergy efficiency upon optimization. These values are initially determined from the concept model and related formulas. Ultimately, their effects on the objectives are assessed such that through final selection, by making changes in a specified range, the optimized acceptable values can converge to the results of the equations. Dispatch factors are

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among the variables used in all energy hub studies to achieve optimal energy flows in control volume associated with energy hubs. Rows 1, 2, 3, 5 and 6 of Table 2 in the paper, are related to the design equation for the energy hub model, which is dedicated to decision variables vCHP, vST,

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vRO, vMED and vBoiler, respectively. Each dispatch factor represents the production or consumption capacity share of the system in relation to the overall energy carrier production or consumption share and thus is a determining parameter in the energy hub’s internal equipment capacities and

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input energy carriers. For this purpose, the sensitivity analysis for each of these variables in

and TAC are provided in Appendix B.

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relation to the objective function and key values of energy hub output such as exergy efficiency

In this study, the results of the objective function from two-objective optimization of the energy hub for different algorithms parameters in this case study are presented in Table B-1. The resulting values from the genetic algorithm parameters in Table B-1 are extracted according to

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reference [61] to analyze the sensitivity of the objective functions. Each result is presented upon best in 3 times run. As evident, the best results are obtained at levels 4 and 5 which have the least TAC with highest exergy efficiency. From these two levels, level 5 exhibited the most optimal

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results with population size 150, mutation 0.03 and crossover 0.8 and its parameters were

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selected for system outputs.

7. Validation

Validation indicates that the model is a logical representation of an actual system in order to assess the actual system activity with enough fidelity to analyze the main goals. Each model typically analyzes a specific problem and presents various system components in different levels of abstraction. As a result, there is a model of different levels of validity for various system components, which together, examines the system behavior. There are three separate aspects for

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most models which should be assessed during model validation: Assumptions, Input parameter and Output values. For this purpose, in order to achieve full validation of the energy hub, validation of each equipment model should be considered to attain validation of the integrated

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energy hub system which does not yet exist. Thus, each equipment should be validated separately. 7.1. RO

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For the purpose of validating the written code, ROSA software was implemented for plug system. Validation was achieved via a system where water volumetric flow rate and salt

Table 9 presents the validation results.

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concentration are 40 m3/h and 4049 ppm, respectively. The sample was modeled in two stages.

Table 9. The validation results of ROSA software Modeling results

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Parameters

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Produced freshwater in stage 1 (ppm) Produced freshwater in stage 2 (ppm) Production of fresh water in each stage 1 (m3/h) Production of fresh water in each stage 2 (m3/h) Feed pressure (MPa) Recovery

ROSA software results

Error (%)

21.94

23.50

7.1

59.52

65.58

10.1

40.12

40.83

1.7

19.87

19.17

3.5

3.53

3.77

6.7

46.0

46.0

0

7.2. MED

Parametric equations were successfully achieved in reference [43] prior to be statistically validated to predict the GOR and distillation production as a function of various input parameters via an extensive validation range. Moreover, the presented empirical model in the section 2.3

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stemming from the extensive empirical results has been compared with reference [52] (Fig. 7). This comparison was conducted under conditions where the values of mf and Tf were within the acceptable range of the empirical model. This comparison shows that the empirical model has

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minor differences with the numerical results, and the relevant errors are acceptable in terms of empirical model application. 7.2. Gas Turbine and Steam Turbine

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The model applied in the gas turbine and steam turbine was based on reference [48].

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Fig. 7. MED model validation with a valid model in various hot water inlet temperatures

8. Results

The Pareto curve is derived from two-objective optimization, and in order to achieve optimal decision variables and optimal objective function values, the two-objective functions will be TAC and exergy efficiency. The genetic algorithm categorizes the solution space into a feasible domain and infeasible domain. The frontier between these two regions is the Pareto curve. Each

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of the points created result from the decision variables that leads to the determination of the objective functions’ values depicted on the Pareto curve. Each resulting point is an optimal point. The ideal point on this curve is the point with the lowest TAC and highest exergy efficiency.

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This point is in the infeasible domain. The point of the curve that is closest to this point is called the best point. Fig. 6-a shows the optimum Pareto front results for two objective functions.

The acquired results show that two chosen objective functions i.e. energy efficiency and TAC

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differ in the optimal state. Attempts to enhance energy efficiency will increase TAC in both cases and vice versa. The confliction trend in the optimal state should be highlighted via multi-

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objective optimization. Increases in energy efficiency increases optimal TAC with the increment slope significantly increasing for maximum energy efficiency. Thus, the energy hub is not economically viable for maximum energy efficiency. The developer should choose the final optimal point according to the significance of each objective. Additionally, the optimum Pareto

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point is influenced by optimal results acquired in the energy hub. Table 8 lists ten design factors i.e. decision variables along with relevant variation ranges in order to maximize energy efficiency value while minimizing TAC. Fig. 6-b illustrates optimal Pareto fronts with and

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without waste heat recovery stemming from the cement plant. The acquired results show that when waste heat is included, the optimal Pareto front is completely dominated by the optimal

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results that exclude heat recovery. According to Fig. 6-b, exergy efficiency in all locations with waste heat recovery is greater compared to the without waste heat recovery whilst exhibiting lower TAC. According to Table 10, the exergy efficiency increased by an average of 20% in the case of without waste heat recovery compared to waste heat recovery case while its TAC function decreased by 72.6%. Moreover, the effect of optimization with the concept of energy hub was shown in a case study in Table 10. In this regard, the effect of the optimal energy hub

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system was compared with the current system (with considering energy recovery from the cement factory). In this table, the exergy efficiency and TAC for the current system are shown along with the energy recovery from the cement plant. According to this comparison, in the

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optimal mode, the exergy efficiency increased by 29.6% and TAC decreased by 19.3%. This illustrates the impact of using the concept of energy hub with the optimal allocation of energy carriers and the addition of new energy equipment.

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Pareto optimal fronts for input values given in Table 9.

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Table 10. The optimum values of exergy efficiency and the TAC for the design points A–C in

With using energy hub concept Parameter ηex (-)

A 0.78 2553476

B (Best Point) 0.7445 1104138

C 0.727 1059092

Without heat recovery Best Point 0.616 4036266.47

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TAC ($/ year)

With Waste heat recovery

Current system with heat recovery 0.5741 1368827.47

The use of heat loss improves both objective functions. In regard to the TAC function, it should be stated that the high potential of heat loss in the cement plant has led the energy hub to utilize

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this cheap energy to not only self-sufficiently reduce part of the electricity, heat, and fresh water production costs, but also reduce O&M costs. Concerning the exergy efficiency function, it

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should be stated that directly reducing fuel consumption according to Eq. (20) will effect exergy efficiency and increase this objective function. A decision making process is implemented to select the final solution from optimal Pareto front points. This process is conducted on the basis of engineering experiences and the significance of every objective for the decision makers. Fig. 6-a shows that at design point A (78%) there is maximum exergy efficiency exists and the TAC is highest at this point. Furthermore, at design

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point C, the minimum TAC is achieved (1059092 $/year) along with the lowest exergy efficiency value (72.7%). The optimal exergy efficiency state as a single objective function is at design point A. The optimal condition where TAC is a single objective function is at design

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point C. Table 10 lists the optimal values for two objectives regarding five usual points from AC (Pareto optimal fronts) for the input values stated in Table 11. Also, Table 11 shows that, moving from the point C to point A, the vMED value is approximately 6% of its initial value,

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which indicates a decrease in annual costs and an increase in exergy efficiency for the use of MED desalinating water entailing less use of the RO system.

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Table 11. The optimum values of design parameters for optimum selected points A–C in Pareto optimum front. With Waste heat recovery Parameter

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B (Best Point) 1 0.015 0.444 0.995 0.494 0.459 64.35 11.54 3.76 1777.6

C 1 0.316 0.48 0.999 0.234 0.468 64.7 11.98 3.8 1768.3

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vCHP (-) vMED (-) vBoi (-) vST (-) vRO (-) RRO (%) Thot (°C) Mhot (L.s-1) EWRO(kJ/( kg)) Qmax,Boi (kW)

A 0.997 0.02 0.547 0.76 0.51 0.45 64.4 11.59 4.28 1810.3

Without heat recovery Best Point 0.997 0.039 0.61 0.577 0.72 0.34 66.65 10.56 3.2 1511.66

In the RO system, high pressure water should be supplied between 60 bar to 80 bar to desalinate seawater. A greater power allocation to the RO system in the steady state water supply system increases the water supply pressure and increases the difference between water supply and osmotic pressure flux of the flowing water in each membrane, thus entailing increased system recovery and increased fresh water flow. The genetic algorithm has increased the production share of the system by increasing the power allocated to the RO.

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Also, a 25% reduction in the use of a steam turbine to generate electricity will increase TAC and exergy efficiency. The 42% reduction in the use of the steam turbine to generate electricity and an increase of 38% in the use of the auxiliary boiler indicates that in order to meet electricity

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demand, electricity should be bought from the grid and in order to meet heat demand, fuel consumption should be increased and bought from the natural gas grid.

Since the city of Khaledin that is located in the vicinity of the cement plant, has a specific

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population, as a result, the highest demand for energy carriers and heat is limited, resulting in the maximum sales of these two energy carriers through a hub of 6980 kW for electricity and 5723

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kW for heat. In the energy hub, urban water demand is considered as the demand for energy hubs. Results indicate that due to the high costs of water transfer and the distance from the nearest city (apart from the adjoining city) to the cement plant, there are no water sales outside the hub. Upon optimization and using the energy hub concept, the energy purchased from the

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factory has dropped from 3.2317 kg/s to 2.114 kg/s, indicating that part of the water is produced in the hub and utilized in the adjacent city (1.11 kg/s). Also, the energy hub is self-sustained in electricity maintenance, with the small amount exception, the remaining 2988 kW supplied by

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the GT and steam turbine. Due to the 5630 kW heat recovery from the cement plant, the majority (4856 kW) is sold outside the hub. Also, in order to supply the NG required by the GT and

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boiler, 0.0982 kg/s is consumed in the hub. In Table 11, it is noteworthy that the use of gas turbines is maximally utilized and due to the increased efficiency of the GT system, lower costs and reduced environmental pollutants, it is considered feasible.

Another factor in reducing TAC can be accredited to the utilization of the gas turbine. One of the features of this apparatus is its electricity and heat supply based on an initial production cost.

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Therefore, the genetic algorithm increases the role of this system in the energy hub leading to a reduction in the installation costs pertaining to other equipment such as a boiler. On the other hand, the confrontation between the heat loss of the cement plant and elimination of a boiler

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the gas turbine has led to a general reduction of TAC.

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from the system compared to the non-utilization of waste heat and increased fuel consumption in

temperature

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Fig. 8. The rate of exergy efficiency in energy hub at hot water flow rate and hot water

As shown in Fig. 8, it is evident that energy efficiency increases with Thot as expected. Considering the impact of QMED on energy efficiency, it is clear that energy efficiency slightly decreases for Low QMED (from 100 kW to 200 kW) while decreasing considerably (approximately 2.2%) for larger QMED. Such progressive decreases may be because of the evaporative process via the tube bundle that is closer to its hot water temperature design value

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(11.54 L/s). Due to the increases in thermal energy consumed, which is greater than the distillate production, an energy efficiency reduction is experienced by QMED that is over 200 kW. Also, by increasing the rate of Thot (from 60 °C to 74 °C), the exergy efficiency increases by

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1.5%. Fig. 9 shows vRO, vMED variations in terms of TAC for both waste heat recovery and without waste heat recovery. In this figure, with vMED variations from 0 to 1, TAC increases by an average of 3.1%. Also, vRO variations from 0 to 1 will increase TAC by an average of 2.5%

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and up from 1049362 $/year. The percentage of TAC variations for without waste heat recovery

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compared to waste heat recovery.

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remains the same. Moreover, the average TAC increase in without waste heat mode is 3.8%

Fig. 9. The rate of TAC in energy hub at hot water flow rate and hot water temperature

By increasing the allocated share of fresh water production to the RO system, it is evident that TAC costs have increased. In order to produce more water, the RO system requires higher water pressure from the intake water supply as well as higher water pressure. By allocating more

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energy to this component, the water pressure will increase. The main factor in increasing the RO costs according to Table 4 is the pre-treatment costs. In this state, by increasing the pre-treatment

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costs and its effect on the RO system, the TAC will increase.

Fig. 10. The rate of TAC in energy hub at hot water flow rate and hot water temperature

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Fig. 10 shows the variation in the price of water ($/m3) for three modes of production by RO,

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MED and the entire hub system, taking into account the share of each of the two water producers. From 0 to 0.4, the UPC change is 0.65%, while changes up to 1 will result in a 40% drop. By changing the value from 0 to 0.3, the UPC will drop by 23% and will change from 0.54 to 0.416. On the other hand, its reduction from 0.3 to 1 would be 11%. It is clear that changes in the share of water produced by each desalination system will not affect the production cost of other systems, and the cost of producing water will be higher if the unit is smaller. The process of changing the final price of water production in the energy hub system indicates that increasing

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the share of water production in both MED and RO systems reduces water production costs. Also, Fig. 10 shows that the price changes of the MED system are significantly high compared to the RO system. The MED system is considered for a specific capacity with equivalent

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investment costs whereas if it utilizes less heat than its nominal capacity, the production of fresh water is reduced in a fixed investment. Due to the reduction in fresh water production, the final water costs will significantly increase, in which case the investment cost is considered for the

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MED, but the system will not be utilizing its nominal capacity. This greatly effects the final price. On the other hand, the RO system can only control fresh water flow by reducing feed

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water pressure and the valves in the brine water pathway. As a result, in the RO system, price changes are only dependent on energy consumption prices and O&M, thus pertaining to price

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changes in this limited range.

Fig. 11. Variation of TAC versus ratio of price and energy carrier in energy hub

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Fig. 11 shows the sensitivity analysis conducted on key factors such as water price, heating and electricity. The results from this analysis highlighted the energy carrier with negative slope that may be supplied with other sources and acquired with a positive slope. The achieved results

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show that when water selling price increases, the TAC is significantly raised with constantly varying costs. The optimal system tends to function on the basis of water sales. The TAC will increase as much as 6.6% because of the raise in water price ration. In addition, Fig. 11 depicts

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that with higher heating sales price ration from -60% to 60%, overall system TAC will be reduced by 4%. Based on the data shown in Fig. 11, it is evident that an increase in electricity

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price has less influence on TAC in comparison to other energy carriers.

In the current system, the following resources are used to meet the demand of the consumption section. Electricity supply from the national grid (conventional centralized power plants on the island), fresh water produced from the RO system and heating based on current heat generators is

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dispersed for each consumer. Also, since the systems are designed to just meet the demands of consumers, purchases and sales with the grid are not considered. Table 12 presents the results of the basic parameters of the hub both in an optimal state and current state. In the optimal scenario,

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by recovery waste heat from the cement plant, heating, power and water generation in addition to optimizing energy flows and capacity of utilized equipment, fuel consumption will be reduced by

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over half whilst exergy efficiency will increase by 36%. Also, CO2 emission will drop by 21624 ton/year and TAC will decrease by about 37,000 $/year. In a more detailed assessment on each equipment, the results on Table 13 indicate that in the current state, the total amount of fresh water is supplied through the RO system and the electricity is supplied by the grid whilst by adopting the energy hub concept, 18% by MED, 33% by the RO system and 49% is supplied by the water grid. Moreover, part of the heat produced by GT and waste heat is consumed by the

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steam turbine and MED and the remainder is sold to the grid. On the other hand, about 50% of the plant’s electricity is supplied by the GT and 50% by the steam turbine. Fig. 12 presents changes in CO2 emissions for both cases of including and without energy hub for water and

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electricity energy carriers. In Iran, CO2 emissions resulting from grid electricity is 0.67 kg/kWh and CO2 emission resulting from natural gases is approximately 0.23 kg/kWh [65]. Also, the amount of CO2 emissions needed to produce heating was 0.38 kg/kWh [73] (an

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to produce each cubic meter of water [26].

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efficiency of 65% was assumed for the boilers). On the other hand, 3 kg of CO2 will be released

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Table 12. Comparison of results between basic parameters of the optimal scenario and current system on Qeshm Island Parameter Current system Optimized System UPC ($/m3) 0.6738 0.429 Fuel Consumption 4871668.6 2121120 (kg/year) CO2 Emission 224295000 202671000 (kgCO2/year) 38.1 74.45 ηex (%) TAC ($/year) 1141060 1104138

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224,295 208,000 193,236

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16,016

202,671

9,169

183

Water

Plant

Total

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Electricity

279

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CO2 Emission (ton/year)

240,000 220,000 200,000 180,000 160,000 140,000 120,000 100,000 80,000 60,000 40,000 20,000 0

Without Hub

With Hub

Fig. 12. Variation of CO2 emissions (kgCO2/year) and energy carrier with energy hub and current system

*

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Table 13. Assessment of the allocated demand in the hub and comparison with the current system Energy With Waste heat Component Current system carrier recovery MED 0.5828 Water (kg/s) RO 3.2317 1.0686 Grid 1.5804 Boiler 0 GT 3272.3 Heat (kW) Waste heat 5625 Grid -4700* GT 1493.7 Power (kW) Steam Turbine 1489.6 Grid 2988 7.76 In this table, the negative numbers indicate the amount of sales of energy carriers to the grid.

According to the reference [66], 900 tons of carbon dioxide are produced, for every 1,000 tons of cement, about half of which is related to the burning of fuel in the kiln and the other half to the

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calcining reaction in the preheater. As the amount of cement production in Qeshm cement factory is 231 thousand tons, about 208 thousand tons of carbon dioxide will be produced annually. Regarding heat recovery (5620 kW) at the cement plant which is equivalent to the

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reduced carbon dioxide for the recovered waste heat, carbon dioxide is declined by 7%. In the case of without energy hub, the CO2 gas produced is considered based on electricity, and water demand from the grid. The demand for electricity based on Fig. 5 is 2988 kW which produces

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16015 tons of CO2 per year. With the energy hub, upon optimization and heat recovery from the hub, the consumption of NG is 0.0982 kg/s equivalent to 9210 tons of CO2 per year for power

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generation in GT which is the main CO2 producer when using the energy hub. On the other hand, the primary energy of desalination systems is captured from the power and heat generated within the energy hub, it is therefore considered to be equivalent to the change in carbon dioxide emissions in the primary energy changes. Then, the amount of reduced water received from the

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grid and utilization of local desalinating systems was assessed. Also, the amount of CO2 generated through water transfer is addressed (Eq. (28)). Due to reduced water purchases from 3.2317 kg/s to 2.114 kg/s, and by taking into account the CO2 generated by the water

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transportation, the amount of generated CO2 from the water was reduced by 96 ton CO2 per year. Considering all energy carriers before and after optimization, the environmental impact of

year.

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producing 224 thousand tons of CO2 per year has been reduced to 202 thousand tons of CO2 per

9. Conclusions

In this paper, an amalgamation of water, power and heating generation systems were utilized to optimally develop a modern operational strategy called energy hub. The TAC for the energy hub and energy efficiency was optimized by taking into account the waste heat recovery from the

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cement plant. The proposed energy hub has the potential to supply of electrical, thermal and water loads. Results from this design were compared to the cases that without waste heat recovery. Moreover, all equipment will be selected using the concept of an energy hub at its best

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capacity. High energy consumption of major desalinated production processes, reduction of economic costs, reducing greenhouse gases in an integrated water, power and heat system and

factory as an energy hub.

•

After optimization, the exergy efficiency and TAC increased by 20% and decreased by 72.6% respectively.

•

CO2 emissions reduced from 16295 tons per year to 5329 tons per year upon utilizing the

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energy hub concept. •

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The acquired research results are presented below:

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increase the exergy efficiency, are the main reasons for utilizing and optimizing the cement

TAC increases and decreases moderately with increases in water and heating price while it is negligible due to the small amount of grid electricity purchased. The lower the share of water production, the higher the price of water per cubic meter

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•

•

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The following may be regarded as suggestions for the continuation of this research: Optimizing the use of the organic Rankine cycle (ORC) system and a comparison of

various working fluids to determine the optimal fluid for the purpose of electricity production from the cement plant’s heat recovery with the concept of an energy hub;

•

The use of hydrogen fuel or biogas to generate power and heat in a CHP and boiler;

•

Combining renewable systems such as wind turbines along with an energy hub for the cement plant to evaluate reduced costs.

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Appendix A- RO system equations In modeling the reverse osmosis system according to the mass transfer equations, it is evident

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that the water flow pressure and salt from the membrane are as presented in Eq. (A-1) and Eq. (A-2) and also the mean velocity in each membrane element is determined by Eq. (A-3). The salt concentration of the produced water is determined by Eq. (A-4). Also, the salt concentration in

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proximity to the wall is obtained according to the film theory by Eq. (A-5). In regard to the conjunction equation, Eq. (A-6) and Eq. (A-7) can be used for water and Eq. (A-8) can be used

Ú = Î × uÅ[‰r − o − Ú¢ = àá − o â

∆r Œ − (Ý − Ýo )] × 10ß 2

Ú + Ú¢ 8 Ú¢ o = × 1000 ‹ …ã r + c  = o + ( − o )D ä 2 bo = ‹ ×  bg = bÆ − bo bÆ r − bo o g = bg

(A-1) (A-2) (A-3) (A-4) (A-5) (A-6) (A-7) (A-8)

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‹ =

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for salt [12]:

In the equations above, A, B and Sw are the permeability coefficients for water, salt, membrane and its area, respectively. The equations that can be used to reduce the number of unknowns are as follows:

[¢ ƒ 0.0033 × b" × R… × æ ∆r = N × ƒ~ n = 0.04 × lD ‡.Íå × L ‡.~~ ×

(A-9) (A-10)

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…ã ç  è

and Ds is the permeability of salt (m /s), d is the distance between feeds, Qa is 2

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Where lD =

(A-11)

the average flow determined by Eq. (A-10). Lm is the membrane length and N is number of elements at each PV. π is osmosis pressure and C is salt concentration. In order to estimate the

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average pressure drop, the Hagan-Poiseuille equation is used. The Sherwood number is calculated by using Eq. (A-9) and Eq. (A-10) which is used to calculate the polarization of the

Appendix B-sensitivity analysis

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concentration.

The results from the sensitivity analysis in determining decision parameters in the genetic

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algorithm are presented below.

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Fig. B-1. Variation of objective functions versus dispatch factors in energy hub

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Fig. B-2. Variation of objective functions versus decision variables in energy hub

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Table B-1. The results of optimum objective functions for different algorithms parameters in operating condition Level 1 2 3 4 5 6 7 8 Population 50 50 100 100 150 150 200 200 Size Mutation 0.01 0.01 0.02 0.02 0.03 0.03 0.04 0.04 Probability Crossover 0.8 0.9 1 1.1 0.8 0.9 1 1.1 Probability TAC ($/year) 1212562 1197736 1277446 1168324 1104138 1122893 1121454 1158685 Exergy 73.16 77.51 73.61 75.308 74.45 72.302 73.582 76.25 Efficiency (%)

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Highlights •

Proposing of the modified energy hub model to analyze economic and environmental

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performance Finding the optimum range of variables based on TAC and exergy efficiency

•

Water is incorporated as an energy stream by simultaneously utilizing MED and RO.

•

The results of optimization are compared to the conventional mode.

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•