Improved performance of hybrid photovoltaic-trigeneration systems over photovoltaic-cogen systems including effects of battery storage

This paper presents the hybridization of CHP(Combined Heat and Power)with PV(Photovoltaic)and CCHP(Combined Cooling Heat and Power)with PV. It even explains the several advantages of using CHP+PV hybrid systems and CCHP+PV hybrid systems over conventional systems. Moreover, PV-Cogen and PV-trigen are found to be more effective at reducing emissions compared to conventional systems.

NOTES:-

Review of PV(Photovoltaic)

-In PV technology solar energy is directly converted to electricity. The efficiency is only about 6-20%.

-The PV has irregularities due to local weather conditions. Thus, PV technology is not consistent throughout the year. So, PV technology is combined with CHP unit.

Review of CHP(Combined Heat and Power)

-The CHP unit uses fuel like natural gas, bio-gas etc to generate electricity.

-The co-generation unit also produces thermal energy which is harnessed by a heat exchanger and utilized

Review of Battery Energy

-Battery is a storage device.

-Whenever excess electricity is generated by the hybrid system, it is stored in the battery and it is utilized during the time when the CHP and PV unit fails to meet the requirement.

Hybrid System(PV+CHP+battery)

-Electricity generated by the PV and Cogeneration unit is used to meet electric requirements. The waste heat is harnessed by heat exchanger to provide hot water and space heating.

-Whenever, excess electricity is generated it is stored in the batteries which is used to supply electricity when PV+CHP unit fails to meet requirements.

ADVANTAGES:

  • GHG(Green House Gas) emission reduction.
  • High efficiency as most of the waste heat is utilized for heating water, space heating etc.
  • Improved performance.
  • Higher normalized power indices.
Hybrid System(PV+CCHP+battery)

-In CHP there is still some amount of waste heat. So, in order to overcome this limitation PV-CCHP hybrid system are used.

-In CCHP, the remaining waste heat from the CHP is utilized by the system for air-conditioning(space cooling).

ADVANTAGES:

  • Substantial GHG emission reduction.
  • Very high efficiency(higher than PV+CHP hybrid system)
  • Improved performance than CHP.
  • Higher normalized power indices than CHP.

Dispatch strategy and model for hybrid photovoltaic and trigeneration power systems

This paper purposes the dispatch strategy for hybrid system PV+CCHP that accounts for electric, space cooling and space heating. The CCHP(Combined Cooling and Heat Power) system is used to reduce the waste heat produced from CHP system. This has resulted in improving the performance by 50% over PV-CHP unit. Due to intermittency of PV technology CHP unit is combined with PV. To overcome the limitations of the CHP unit, PV+CCHP hybrid system is used. This paper explains the significant improvement in performance available in PV-CCHP systems over PV-CHP system.

NOTES:-

-Electricity is generated by both PV and CHP unit but in order to improve the performance storage devices for electricity and thermal loads are connected with PV+CHP hybrid units.

  • Inverter is used to convert DC output from PV and battery to AC outputs which are compatible with loads.
  • Excess AC output produced from CHP is stored in the battery.
Parallel configuration:

In this configuration, inverter(it is used to convert DC output from PV and battery to AC outputs) and CHP unit is connected in parallel.

The advantage of using parallel configuration are:

  • Reduction of capacity of inverter and CHP unit.
  • Better supply-demand correlation.
  • Maximized CHP fuel efficiency.
  • Minimized CHP maintenance costs.
Series configuration:

In series configuration inverter and CHP are connected in series. It is easy to implement, but has several flaws,

  • Lower overall system efficiencies (due to inverter and battery losses).
  • Larger inverter size.
  • A limited control of the CHP unit.
Dispatch Strategy:
  • This strategy is used to control the system in order to meet the electric and thermal load requirements.
  • The thermal output tend to be larger than electrical output in CHP. So, this strategy tends to meet the electrical requirements first, then the thermal requirements
  • When it produces excess of power, it is stored in the battery. Moreover, if batteries is at their maximum State Of Charge(SOC), then electricity is either dumped into the ground or it is penetrated into the grid. If there is excess thermal energy it is dumped as waste gas through exhaust.

Optimal Scheduling of Hybrid CCHP and PV Operation for Shopping Complex Load

This paper purposes economic optimal operation of combined cooling heating and power (CCHP) and photovoltaic solar (PV) hybrid system. The system which is simulated consists of a CCHP system, a PV system, an auxiliary boiler, an absorption chiller, a heat storage tank, and utility grids. The advantage of using CCHP, compared with conventional generation, is that it utilizes the waste heat to satisfy the thermal demand. The favorable operation of CCHP helps to minimize the operating cost and retain their investment as early as possible. There is even no fuel consumption which helps in conserving the environment.

NOTES:-

System Description

-Energy Management System(EMS) consists of:

  • CCHP:

-CCHP system generates electricity as well as heat. Electricity is supplied to the load while heat is supplied to absorption chillers to convert it into cool air.

-It is based on the gas turbine technology. It uses natural gas as the primary source.

  • PV+Utility grid:

Whenever there is shortage of supply from the CCHP system, PV+utility grid compensate for it.

  • Heat Storage tank:

-If CCHP unit produce excessive heat than the demand then heat storage tank stores the excessive heat produced from the CCHP unit.

-It will discharge the heat when CCHP unit cannot fulfill the thermal demand.

  • Flowchart working:

-Carbon-di-oxide gas emission is calculated(using linear calculation) by considering output power, fuel cost, thermal and electrical demand, energy price to verify the quality of CO2 gas.

-After that the time will be updated to the next interval and the system will operate continuously.

Institutional scale operational symbiosis of photovoltaic and cogeneration energy systems

The GHG (Green House Gas) emissions have caused increased in carbon concentration in atmosphere. The GHG emission are caused due to combustion of fossil fuels like coal, oil and natural gas. Most of its energy is wasted while converting it into electricity. The GHG emission can be controlled by efficiently use of fossil fuels, use renewable energy resources, or by using CHP(Combined Heat and Power).

This paper mainly discusses on three design scenarios 1) single cogeneration + photovoltaic, 2) double cogeneration + photovoltaic, 3)single cogeneration + photovoltaic + storage. The paper also shows that how requirement of natural gas is lowered by above scenarios. The consumption of natural gas consumption can be improved by hybridizing solar with cogeneration.

NOTES:-

Reduction of GHG:

The GHG emission can be reduced by 2 ways:-

1.Efficient use of fossil fuels:

  • By utilizing waste heat produced from the fossil fuel. The waste heat is utilized for space heating or water heating. This is called cogeneration or CHP. Further the waste heat can also be utilized for air cooling. This is called tri-generation or CCHP.

2.Renewable energy:

  • By using photovoltaic technology which directly converts sunlight into electricity. It has limitation due to weather irregularities.

So, PV+CHP can be combined to increase the efficiency of the system and reduction of the GHG emission.

CHP system:
  • In CHP prime mover converts chemical energy into electrical energy. The maximum efficiency obtained from this is 50% and remaining is wasted in the form of heat. Using heat ex-changers this heat can be utilized for space heating and water heating. Thus, efficiency can be increased.. The electrical efficiency is 35% and thermal efficiency is 50%. Hence, there is less fuel consumption.
  • The efficiency of CHP is given by:

n=(Q+E)/Q0

where: Q:heat energy. E:Electrical energy. Q0:heat content of the fuel.

  • The base load of the system is considered to be about 300kW. During evening the peak load is increased to 600kW. The load utilized during summer and winters are also different.
  • The electrical efficiency from natural gas is between 30%-40%. In this 90% of the heat loss is utlized for hot water and air cooling.

The block diagram of the CHP system configuration scheme has been provided in the paper.

PV Technology:
  • It consists of PV panels which converts photons from sunlight directly into electrical energy.
  • The output of the PV panels is DC, but the requirement for grid and appliances is AC. So, inverter is connected to convert DC to AC in order to meet the requirement.
  • The solar panels are mounted on the roof of the hospital. The tilt angle of solar panel was kept at 10 degrees. 0.5m space was kept between the panels for maintenance purpose.
Design of PV+CHP hybrid system:

The main purpose is to increase the efficiency by utilizing most of the waste heat, in order to increase the efficiency,thermal energy consumption can be reduced by installing heat control mechanism which can be done by the CHP system. PV+CHP hybrid system is used.


Scenarios:

-Scenario 1:Single PV+CHP

  • This scenario explains how the CHP unit is capable of satisfying hospitals base load requirement.
  • PV technology does not fulfill the hospitals load requirement, so CHP unit helps to overcome the loads shortcomings. During the night-time the CHP unit helps to meet the hospitals load requirement.
  • During certain months of the year, there is excess electricity generated by PV+CHP unit. This excess electricity is fed back into the grid.
  • Scenario 1 fulfills 76% of the hospitals load requirements.


-Scenario 2:Double PV+CHP

  • In this scenario 2 CHP unit are coupled with each other. Double PV+CHP is more effective but is very costly due to high maintenance cost compared to scenario 1.
  • It fulfills 93% of the energy requirement of the load, also whatever excess electricity is generated throughout the year is fed back into the grids.
  • As there is no means to store heat energy,it does not completely fulfill the hospitals thermal requirement.


-Scenario 3:Single CHP + PV + Storage

  • In scenario 3 it overcomes the shortcoming and low performance of scenario 1 and it is not as costly as in scenario 2. This is almost similar to scenario 2.
  • The battery is used to smooth out the electrical load. But this scenario has shortcoming that it has low thermal supply made available to the hospital.


Observations:
  • It can be observed that using hybrid system helps to improve the energy performance.
  • By installing PV array helps in reducing the run time of the CHP to meet load, which in turn reduces natural gas use and green house gas emission.
  • Producing energy on site is far more efficient then producing energy at power plant which involves transmission losses of around 26%


Hybrid PV-CHP Distributed System: design aspects and realization

The distributed generating system uses renewable energy, but due to the intermittency of the renewable energy they are combined with hybrid plants to combine more energy. This paper focuses on hybrid plants which uses internal combustion engine with cogeneration or tri-generation and PV technology. This paper also put light on analysing the power flow control strategies. Due to very low efficeincy of PV technology they are combined with conventional non-renewable ones to improve the performance and efficiency.

NOTES:-

There are three families for Distributed Generation System (DGS):

Standalone Systems (SAS):
  • This are used to supply to remote locations which are not connected to the main grid. in such case they usually combine one or more renewable energy sources with conventional energy sources. The hybrid system assure uninterrupted power supply even when renewable energy does not operate.


Grid connected systems (GCS):
  • They operate in only grid connected mode. They are connected with one or more renewable sources.
  • By using one or more energy sources provides higher stability of power supply.
  • In GCS very small storage is equipped, in order to contribute system transient stability.


Mixed operating mode systems (MOS).:
  • They operate in grid connection mode combined with one or more renewable sources along with storage device(Battery).
  • The battery is used to supply energy during emergency period.


Hybrid System Configuration.:
  • In this PV is combined with CHP unit. It is also equipped water heat storage.
  • CHP unit has small size battery and braking resistance which are shunt connected.
  • The shunt element have three functions.

a) They allow CHP to start even in the absence of the mains.

b) they allow to store excess energy in the standalone mode.

c)They provide transient stability to the CHP system.

If shunt unit is not connected then:

a) We obtain poor dynamic response.

b)In standalone mode, if there is demand for increase in load, it wont be able to fulfill the requirement.


Hybrid system components:

- CHP unit:

  • The natural gas, fuel for Internal Combustion Engine(ICE) to generate mechanical energy by combustion of fuel. The Induction machine connected to ICE converts mechanical energy to electrical energy.
  • Thermal recovery unit recovers thermal energy using heat exchanger. The heat generated during the process produces hot water which is stored in water heat storage. The heat storage unit has temperature sensors.


- PV unit:

  • It has different PV arrays. The output is DC which is connectedd to the common DC-bus. Chopper(DC-DC converter) is used. The DC is converted to AC(inverter).


- Battery Bank:

  • It is connected to the DC-bus. This Bi-directional Chopper. So, it can supply power in both directions, form DC bus to battery during charging of battery and from battery to DC bus during discharging.
  • There are two charging steps:

1) Constant current-Bulk condition.

2) Constant Voltage- Boost condition.


-Supervisor control unit:

It has two main tasks:

  • Controls input of PV, CHP and Battery bank.
  • Controls heat storage unit and battery power flow.

There are two operation modes:

1) Normal operation mode: In this mode the whatever power PV unit is generated is fed into the load. The CHP unit priority is to satisfy thermal demand. If CHP generates more power than required by heat demand, it stores it in battery bank.

2) Standalone operation: In this mode grid is not connected. The hybrid system gives priority to fulfill the electric demand. Advantage is this operation does not require energy storage device.

The mode changing is controlled by supervisor control unit.


Simulations of greenhouse gas emission reductions from low-cost hybrid solar photovoltaic and cogeneration systems for new communities

This paper focuses on reduction of GHG(Green House Gas) emission and life cycle cost by optimizing the PV-CHP system. The conventional energy can be replaced by PV-CHP hybrid systems in order to reduce green house gas emission. In this paper simulation and optimization model has been developed multiobjective genetic algorithm called Photovoltaic Tri-generation Optimization Model(PVTOM).


NOTES:-

Methodology:-
  • PVTOM helps to minimize the GHG emission and life cycle cost(capital investment, fuel cost, replacement cost).This hybrid system only emits GHG from CHP unit.
  • PVTOM requires 5 inputs to simulate and optimize PV-trigeneration.

1. Hourly solar global and diffuse irradiation.

2. Hourly ambient temperature.

3. Hourly data for household’s appliance and lighting (AL) load.

4. Hourly data for household’s domestic hot water (DHW) load.

5. Hourly data for household’s space heating (SH) load.

These inputs are used to calculate the performance of PV–CHP to meet the thermal and electrical demands.

  • CHP unit generates more thermal output than electrical. So, first electrical demands are fulfilled than thermal demands are taken into consideration. If there is excess electrical energy, it is fed into the batteries. When battery reaches its maximum state of charge it is fed into the grid or into the ground.
  • The optimizer are based on the eight variables:

1. Selection of CHP.

2. Selection of PV panel.

3. Selection of battery.

4. Number of CHP units.

5. Number of PV panels connected in series.

6. Number of PV strings connected in parallel.

7. Number of battery units connected in series.

8. Number of battery strings connected in parallel.

  • The life cycle cost of the system is mathematically expressed as the sum of the the initial capital costs, the discounted operational costs, the replacement costs and penalty.
  • The table 3 in the paper provides the optimized CHP+PV unit for data selection.


A model for optimal energy planning of a commercial building integrating solar and cogeneration systems

This paper focuses on integrating cogeneration, solar and conventional sources in order to minimizing life cycle cost (maintenance cost, fuel cost etc) to meet the energy demand(electricity, heating and cooling). The paper also proposes on optimal investment planning and optimal operating strategies of the energy systems. In conventional energy sources there is not much space for energy planning and optimization of energy.This paper proposes a linear programming model to minimize the life-cycle costs of meeting the building energy demand (power, heating, cooling) by integrating renewable and traditional energy sources.

NOTES

Cogeneration system are widely known as alternative because of their high efficiency.

PV Systems
  • Location of study has been selected and hour by hour power output of silicon crystal is noted.
  • The expected lifetime of the PV system is 20 years.
Cogeneration Technologies

Three types of cogeneration technologies:

a) MT(Micor-turbine): It converts high energy gas steam runs electrical generator. Electrical efficiency is 23%-29% and overall efficiency is 64%-74%. Its benefits are easy installation, high reliability, reduced noise and vibration.

b) ICE(Internal Combustion Engine): They have electrical efficiency between 25% to 48% and overall efficiency is between 75-85%.

c) SOFC(Solid Oxide Fuel Cells): It works on electrochemical process to exploit energy present in natural gas to produce electricity. Electrical efficiency is about 43% and overall efficiency is between 74%-85%. It has high power to heat ratio.

Mathematical Model

1. Inputs:

  • Power, Heating, Cooling demand.
  • Economic data: Capital cost, residual value, operating costs, Maintenance costs.
  • System Characteristics:

- Cogeneration Systems: Power to Heat Ratio, Fuel consumption.

- Boiler: Max min operating region and COP (Coefficient of performance).

- Grid: Price per kWh

- Solar systems: solar radiation and output per systems.

2. Variables:

  • Solar System: Number of panels installed.
  • Cogeneration,thermal and cooling systems: No. of units involved and their outputs.

3. Objective function: It is to minimize the life cycle costs of meeting the power, thermal and cooling demands.

4. Constraints: Three types of constraints-

  • Demand for power.
  • Demand for heat.
  • Demand for cooling.
Results
  • The solar and cogeneration hybrid systems are capable of reaching thermal and electrical efficiency.

Combined cooling,heating and power systems:A survey

This paper focuses on working of the CCHP system. The advantages and analyses of the components of the system are presented in this paper. Control system optimization and sizing of the system is also summarized in this paper.

NOTES

  • Power Generation Unit: Use to supply electricity to the grid. The heat is produced as the by-product. This is utilized to meet heat and cooling demand. Three types of energy can be supplied simultaneously.
  • There are 3 advantages using this system: High efficiency, Less GHG emission, high reliability.
  • By adopting absorption chiller and boiler the heat which is released as by product can be utilized for heating and cooling without using electricity.
  • In conventional SP systems,approximately two-thirds of the fuel used to generate electricity is wasted in the form of rejected heat.By introducing thermally activated technologies, the electric load for cooling is shifted to the thermal load,which can be fully or partially achieved by absorbing or adsorbing

the discard heat from the prime mover.

Conclusion

The CCHP,which can provide the cooling energy by adopting the thermally activated technology. To construct an economical and efficient CCHP system,facilities type should be determined first according to the local resources,and current and future energy market.


Modelling an off-grid integrated renewable energy system for rural electrification in India using photovoltaics and anaerobic digestion

This paper describes the deisgn optimization and techno-economic analysis of off grid hybrid systems to meet the electrical demand. It also focuses on different scenarios having different combination of electricity generation.

NOTES

  • PV+AD(Anaerobic digestion)+CHP+batteries were used for generation.
  • Several scenarios were investigated. The scenarios are:

A) PV + VRB þ DCeAC B) PV + Fuel Cell þ Electrolyser + H2 tank + DC-AC C) PV + VRB + DC-AC + AD + 1 CHP (Microturbine)

Working:

The block diagram in the paper shows the working of the the hybrid system.

It converts the sunlight into electrical energy. The output of the PV is DC. But the load requires the AC as input. In order to convert DC-AC inverter is connected. Moreover, if there is excessive energy generated is fed back to the battery. It is charged upto maximum SOC(State of Charge). If the PV is not able to fulfill the demand. CHP supplies the electrical energy. The by-product of CHP is heat. This waste heat can be utilized by for space heating or air conditioning using heat exchangers or space coolers. The controller block controls all the operation depending upon the electrical or heat depend. Moreover, if there is excessive electricity generated, it is either fed into the grid or stored in the battery which depends upon whether the system is off grid or grid connected.

Conclusions

The paper explains that scenario C has several advantages over other scenarios.


Genetic algorithm based optimization on modeling and design of hybrid renewable energy systems

This paper focuses on designing of hybrid system with solar PV as renewable source and microturbine based on genetic algorithm. System with more than one supply source has more reliability and energy security compared to system with only one energy source. This paper also focuses on sizing optimization of hybrid systems components in order to minimize cost of energy, minimizing pollutant emissions and maximizing utilization of the solar panels.

NOTES

Before performing the optimization, energy generated by each source can be calculated. This is done by mathematical modelling of each component, which requires climatic data.

Simulation
  • Block Diagram:

The bidirectional inverter is used to link AC bus and DC bus. Both the DC output from the PV panels and thee batteries are connected to the DC bus. The AC bus combines both the output of the microturbine and the load. The strategy is based on maximizing the utilization of PV systems. The energy generated by the PV panels is stored in the battery bank. If battery and PV does not satisfy the load demand, the energy will be supplied by the microturbine as a standby source. In certain cases the PV panel generates excess energy which is given to battery. When the battery gets fully charged, a dump load is used to consume excess energy. The microturbine operates only when the battery is discharged below its maximum allowable discharge level and there is no sufficient energy generated by the PV systems. This continues till the battery is recharged back. Recharging is done by rectifier which converts AC to DC. Loss of load probability is the ratio of Energy deficit to Load demand.

Energy deficit is the load demand which cannot be met by the generation or the storage element.


Control strategies and cycling demands for Li-ion storage batteries in residential micro-cogeneration systems

This paper focuses on residential microgeneration system consisting of PV, CHP and battery. The storage battery was simulated under various scenarios. The principle focus of this paper is to examine the details of the load demands placed on the battery in order to know their functionality, durability, economy and capacity.

NOTES

Several Cases were taken into consideration:

1)Grid + battery + PV ICE ON + MID 2)Grid + CHP + battery ICE ON + MID 3)Grid + CHP + PV + battery

For all the above cases, when PV or CHP unit exceeds the load demand. It charges the battery.The battery discharges during peak periods and charge during mid-peak and off grid periods. If PV+CHP unit produces excess energy even during peak periods, then the battery can be even charged during the ON-peak period. CHP unit can provide heat to thermal load without emitting waste heat. The flowchart in the paper is self explanatory, PV and CHP unit is used to provide energy to electrical load. The waste heat generated from the CHP is utilized by thermal loads, increasing the efficiency of the system. Moreover, whenever there is excess power generated by the PV and CHP unit is fed into the grid if its grid connected or it charges the battery if its off grid. By, including CHP with PV and battery helped to provide cost benefits.

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