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Article

Transient-Flow Induced Compressed Air Energy Storage (TI-CAES) System towards New Energy Concept

1
Department of Civil Engineering and Architecture, CERIS, Instituto Superior Técnico, Universidade de Lisboa, 1049-001 Lisbon, Portugal
2
Hydraulics and Environment Department, Laboratório Nacional de Engenharia Civil (LNEC), 1049-001 Lisbon, Portugal
3
Department of Civil and Environmental Engineering, University of Perugia, G. Duranti 93, 06125 Perugia, Italy
*
Author to whom correspondence should be addressed.
Water 2020, 12(2), 601; https://doi.org/10.3390/w12020601
Submission received: 24 January 2020 / Revised: 17 February 2020 / Accepted: 19 February 2020 / Published: 22 February 2020
(This article belongs to the Special Issue Environmental Hydraulics Research)

Abstract

:
In recent years, interest has increased in new renewable energy solutions for climate change mitigation and increasing the efficiency and sustainability of water systems. Hydropower still has the biggest share due to its compatibility, reliability and flexibility. This study presents one such technology recently examined at Instituto Superior Técnico based on a transient-flow induced compressed air energy storage (TI-CAES) system, which takes advantage of a compressed air vessel (CAV). The CAV can produce extra required pressure head, by compressing air, to be used for either hydropower generation using a water turbine in a gravity system or to be exploited in a pumping system. The results show a controlled behaviour of the system in storing the pressure surge as compressed air inside a vessel. Considerable power values are achieved as well, while the input work is practically neglected. Higher power values are attained for bigger air volumes. The TI-CAES offers an efficient and flexible solution that can be exploited in exiting water systems without putting the system at risk. The induced transients in the compressed air allow a constant outflow discharge characteristic, making the energy storage available in the CAV to be used as a pump storage hydropower solution.

1. Introduction

The history of using the energy of water is comparable with the history of human civilization. In recent decades, the generated power from water (hydropower) has been increased considerably as a significant source of renewable energy. Worldwide generation from hydropower, which varies each year with shifts in weather patterns and other local conditions, was an estimated 1292 GW (4200 TWh) in 2018, which is about 25.6% of the global electricity generation and 15.9% of renewable electricity (Figure 1) [1]. Pumped-storage hydropower (PSH) systems have played an essential role in the flexibility of renewable energy sources such as the integration of wind and solar energies. The global PSH installed capacity in 2018 was 160.3 GW, which increased by about 1% during the year [2]. The hydropower capacity has been growing quite rapidly during the last few decades and the forecasts show that it will remain the world’s primary source of renewable power in 2024. Hydropower will account for 10% of the total increase in renewable capacity based on a forecast for the period of 2019 to 2024 by the International Energy Agency (IEA) [3]. The main source of renewable electricity in Europe is provided by hydropower, with an estimated electricity generation of 643 TWh (pump-storage not included), which accounts for 17% of the total generation [1]. Despite the fact that most of the European countries do not provide good potential in the hydropower generation field due to their flat landscape, some countries, like Norway, Russia and Portugal, can provide a good contribution in hydropower energy generation [4].
Traditionally, hydropower facilities can appear in different types, namely impoundment (storage), pumped-storage, run-of-river, offshore hydropower plants and inline solutions in the water sector. Hydropower potential can be categorized in terms of the installed capacity as large (>10 MW), small (<10 MW), mini (<1 MW), micro (<0.1 MW) and pico (<0.005 MW) [4]. Indeed, many of the potential hydropower spots cannot be exploited as a result of technical and economic reasons, but this estimation proves the huge potential behind the hydropower energy generation [4]. Traditional and large hydropower plants are mostly of the impoundment type, which calls for large financial investment. In addition, the development of large hydropower plants can trigger big environmental impacts and requires specific topographical conditions. For this reason, this study mostly focuses on less expensive technologies.
Apart from the traditional hydropower types, which are mostly of large potential types, some new lower potential types have been introduced and examined recently. Among them, PSH has been very promising. This system takes advantage of off-peak electricity to transfer water to the upper reservoir using a pump and then produces electricity from the potential energy of water during peak hours [5,6,7]. PSH is currently the most common form of on-grid electricity storage, with an operating condition which is very well fitted to reversible turbomachines, namely Francis or pumps as turbines (PATs) [8]. The recent increasing influence of variable renewable energy sources forces innovations in energy storage technologies [9]. This has been the main motivation behind other PSH types, such as underwater PSH (UPSH), which some studies have shown can be competitive with conventional PSH and compressed air energy storage (CAES) systems. In UPSH, seawater acts as an upper reservoir and an underwater tank has the role of a lower reservoir working with the same concept of a conventional PSH [9].
Accordingly, the novel renewable energies should be designed on the basis of new technologies and small decentralized hydropower plants to decrease the investment costs and increase the reliability and flexibility of the renewable source by making it less dependent on climate factors [10,11,12]. There is a huge untouched potential in the micro-hydropower category with low and medium heads available in different water conveyance systems [13]. In that sense, energy recovery in potable water networks (urban, rural), irrigation water networks and wastewater and process industry systems received a lot of attention. For this purpose, the pump as turbine (PAT) systems have been recently under consideration and increasing studies have come out addressing different aspects of that [14,15]. PATs are hydraulic pumps that operate in reverse mode for energy production purposes by means of a connected induction motor working as a generator [9]. The operational cost of a PAT is five to 10 times lower than that of a conventional turbine [16]. However, the contribution to renewable energy sources is very slight, which may come from the lack of knowledge, some institutional barrier for implementation and interest. But lately, several studies have been published, mostly examining the PAT application in the water sector through the REDAWN project. In a study [17], a hybrid solution of leakage reduction and energy recovery using PATs was analysed in rural water distribution networks in Ireland, showing the significant contribution of generated power in local energy demand. Another study [18] focused on the off-grid PAT combined with a self-excited induction generator, which led to a boost in system efficiency of 20%.
Besides rural and urban water networks, irrigation water networks also have provided great potential in energy recovery, where a substantial amount of energy used for water distribution can be recovered [19]. The energy harvesting in irrigation water networks is relatively a new area, with very challenging concerns because of the flow variation. Still, studies show that high potential exists in this area [20,21,22]. Although studies have shown that conventional turbines (Francis, Pelton, Kaplan, Turgo, and crossflow) can still compete with new emerging technologies, the new technologies might provide more economic solutions due to a modular design [23]. However, new unconventional hydropower solutions are putting a new spin on hydropower generation for future energy generation [24].
Recently, the CAES systems were considered as a proper solution for geographical conditions in which PSH and PATs cannot be implemented. The first test of a CAES system was in 1949 by Stal Laval, when he registered the first patent of CAES to store energy in the form of compressed air in underground caverns. The basic concept of a CAES is based on stored compressed air which is released to generate energy when needed [25]. Currently, two large capacity plants exist in Germany and the USA, but a lot of studies are appearing in the literature focusing on different solutions, such as the thermodynamic behaviour and hybrid solutions, along with some novel conceptual ideas. A lot of studies have focused on the thermodynamic inspection of CAES systems which have led to the development of different types of CAES system, such as advanced adiabatic CAES (AA-CAES), isothermal CAES (I-CAES), adiabatic CAES (A-CAES) or others [26,27].
In two recent studies, a hybrid solution was proposed to assess the combination of PSH and CAES (pumped hydro CAES or PH-CAES). These studies [28,29] presented an experimental investigation of a PH-CAES system operating using a Pelton turbine. The reported efficiency for the PH-CAES system was 45% and the authors claimed that, unlike conventional CAES systems, this system works with constant power [28,29]. In another study, a new concept for the CAES system was a geographically independent system which was proposed and tested in the laboratory. The feasibility of the concept was proved while reporting the experimental electrical roundtrip efficiency and hydraulic (thermodynamic) efficiency of 24% and 97%, respectively. The authors mentioned the energy loss in the machinery as the main reason for a low electrical roundtrip efficiency [30]. Also, some new concepts for using compressed air have been tackled by some researchers, either in underground caverns or underwater inflatable balloons [31]. Also, another study was published to evaluate the dynamic behaviour of air-water for pressure storage and recovery [32].
Correspondingly, this study aims to present a new conceptual idea of energy storage/recovery using Transient Flow-Induced Compressed Air Energy Storage (TI-CAES). The transient flow is induced in the system by creating a waterhammer event, which has been widely studied and addressed in the literature from different aspects [33,34], giving enough knowledge to employ it for this purpose. For that, experimental data were collected in a system composed of a water pipeline, a compressed air vessel (CAV) and some valves. The results of experimental investigations are used to assess two ideas: (a) generating energy by means of a water turbine; (b) pumping water using the stored pressure inside the entrapped air.

2. System Description

A schematic drawing of the experimental system is presented in Figure 2, showing the auxiliary components for the purpose of this study. The system is composed of PVC pipes with a nominal diameter of 63 mm and the nominal pressure of 16 bar connecting two hydro-pneumatic tanks. By means of recirculating the flow, a steady-state flow condition is established. The data acquisition system records the pressure values and also the velocity profiles. The pressure sampling is done using S-10 WIKA pressure transducers, with the maximum sampling error of ±0.5% as reported by the manufacturer [35]. The velocity profiles are measured by an ultrasonic doppler velocimetry (UDV) system from MET-FLOW offering an accuracy of ±1 ms [36]. The sampling rates for pressure and velocity measurements were 910 and 10 Hz, respectively. Three pressure transducers were installed in the system, as shown in Figure 2. In the measurements, the charging/discharging flow rate and pressure were recorded for different steady-state velocities in the main pipeline (represented by Reynolds (Re) number in the current paper) and the volumes of air inside the CAV. A volume fraction ratio (VFR) has been defined as the volume of air over the volume of CAV in percentage to express the volume of air inside the CAV. The CAV can operate through two different approaches, i.e., the electricity dispatch system by means of a hydro-turbine (Figure 2a) and the pumping system (Figure 2b). The transient flow is induced into the system by the action of BV-01, a ball valve manoeuvred by an electro-pneumatic actuator from +GF+ company [37].
The system can be used to generate energy using a hydro turbine, when the CAV works in two stages, i.e., water charge and discharge (Figure 2a). In the water charge stage, the BV-01 is actuated in a closed/open action to induce a waterhammer into the system. A pressure surge will be propagated in the system by the upsurge occurrence travelling in the upstream direction. As a result of the pressure surge and the special arrangement of CV-01 and CV-02 in the system, the backflow will be directed towards the CAV. The pressure of air in the CAV ( p a i r ), which initially was equal to the atmospheric pressure, will increase due to the compression of the air. In the water discharge stage, since the BV-02 is in open position, the compressed air starts to expand and consequently expels water through BV-02. The charge and discharge stages can be performed frequently. In this study, 9 charge/discharge stages were examined, meaning 9 waterhammer event occurrences.
On the other hand, the system might work for pumping (Figure 2b). For that, the CAV operates as well in the charge and discharge stages. In the charge stage, the BV-01 closes and opens to create upsurges. The pressure surge will be stored in the CAV (because the BV-02 is closed). The waterhammer action is repeated until the desired or maximum pressure is reached inside the CAV. Then, the BV-02 will be opened, allowing compressed air to expand and drive water out of the CAV. Depending on the pressure of the air, it can elevate water to a significant differential level or compensate head losses in a pumping system.
The current study focuses on the energy generation idea (Figure 2a), in which the transient effect includes 9 consecutive waterhammer events taking a total time of 18 s. This effect is created by the closing/opening action of BV-01, taking 0.4 s (0.2 s for each opening or closing action). The major measuring parameters in this system are the main pipeline pressure, the air pressure, the air volume (displayed by VFR), the flow velocity and the CAV outlet flow rate. The measured range for major parameters of TI-CAES system in the current experimental tests is presented in Table 1. The initial pressure of the whole system has been set to the atmospheric pressure. The pressure in the main pipeline starts fluctuating upon starting the transient event. When the transient event finishes, the pressure in the main pipeline returns to the initial condition. The flow condition before and after the transient event should be the same.

3. Parametric Analysis

The pressure variation in the entrapped air within the CAV is recorded, and demonstrates the charge and discharge stages through pressure spikes (Figure 3). The pressure spikes caused by the compression of the air under the waterhammer action shows different values and a fluctuation behaviour based on the air size (represented by VFR) and Re of the pipeline flow. Two pressure variation results are presented in Figure 3 for a constant Re = 155,000, showing quite different fluctuation and minimum pressure values when compared to the initial pressure ( p 0 ).
It was analysed how the mentioned different pressure consequences can affect the functionality of the TI-CAES system. For that, a thermodynamic approach was used to analyse the pressure data. Thermodynamic behaviour in closed air vessels is traditionally modelled using the polytropic equation:
p a i r . a i r n = constant ,
where p a i r and a i r represent the air-phase pressure and volume, respectively [38]. n is a real number known as the polytropic exponent which includes the heat transfer and depends on the type of thermodynamic process (usually for isothermal process n = 1 and for adiabatic process n = 1.4) [39]. In order to define the n value, one should first determine the type of the thermodynamic process. Previous studies proved that, for rapid transitions, the process is close to adiabatic with zero heat transfer [39,40,41,42,43,44,45,46]. However, in this kind of transient, an average value of n = 1.2 is suggested [35,43], because of the different behaviour of the transient phenomenon from the beginning of the process to the end. In the study [39], it was demonstrated that, for medium and big air volumes, the polytropic exponent n = 1.2 gives very good agreement with the measured pressures. According to this, the new volume of air, changing due to transient ( t r ) and corresponding to the new pressure surge ( p t r ), is calculated using Equation (2).
t r = 0 · ( p 0 p t r ) 1 / n ,
where p 0 and 0 stand for the initial pressure and volume, respectively. Hence, t r corresponds to a new volume due to changing the pressure from p 0 to p t r . Based on that, the pressure–volume diagram for different volumes of air inside the CAV is plotted in Figure 4. It demonstrates that bigger changes in the air volume correspond to higher VFRs.
The area below each pressure–volume curve shows the work done by the expansion of air for a specific VFR. In Figure 5, the works done for bigger VFRs are greater than those with smaller VFRs, promising a higher hydraulic power generation.
The hydraulic power can be determined by integrating the work over the charge and discharge time. It can be calculated using Equation (3).
P h y d = W d t = Q . p a i r ,
where W is the work and Q is the flow rate. Two approaches can be tackled in the calculation of p a i r since it is fluctuating during the time as shown in Figure 3. Either p a i r can be considered as the integration of the pressure variation graph over time or a function of time. For the first approach, the integral of p a i r along the time was calculated for different tests using Equation (4), in which p int stands for integrated pressure values.
p int = 1 t t r 0 t t r p a i r d t ,
The resulting integrated pressure values were divided by t t r (the total transient events’ duration) to achieve an average pressure. The attained average pressures are presented in Figure 6a for different VFRs and Re numbers. Despite very high peaks for smaller VFRs, as shown in Figure 6b, the average pressure is lower, and the highest average pressure belongs to 10% < VFR < 60%. For each VFR, pressure results of seven different Re numbers are shown in Figure 6a, starting from low Re to high Re, including 36 × 103, 56 × 103, 75 × 103, 93 × 103, 115 × 103, 132 × 103, and 155 × 103.
In the second approach, the hydraulic power can be calculated using Equation (3) considering p a i r as a function of time (Figure 7). The resulting power will be a function of time, as presented in Figure 7. As is evident in this figure, by increasing the VFR (i.e., increasing the air volume) the maximum spikes of achieved power are decreased. But, on the other hand, the minimum attained power with time is higher. The maximum attained hydraulic power is 90.08 W, which is a power related to VFR = 8.33% and Re = 155,000.
The hydraulic power of CAV was estimated using Equation (3) when the p a i r is calculated from both abovementioned approaches. Both calculation approaches were found, as expected, to give the same values of power as in Figure 8. Considering the small volume of CAV in these experiments (4.7 L), and also the very short time associated to the transient events (only 18 s), the achieved power can be a significant and promising value for higher Re numbers.

4. Recovery Flow Behaviour

To approach the energy recovery concept in the TI-CAES system, it is important to verify the consistency of the main pipeline flow with less perturbation and possible dissipative effects when inducing waterhammer events. For this purpose, the velocity profile in the transient was recorded by means of ultrasonic doppler velocimetry (UDV) [47] to see how the waterhammer action affects the flow characteristics. As studied by Brunone and Berni [48], for a constant flows rate, the shape of velocity profile in a fast transient condition is very different from the steady-state one. Figure 9 shows the plot of the variation of velocity profiles based on a 0.2 s interval. The time intervals that were selected were small enough to show the variations of the velocity profiles in detail during the transient. In the majority of the cases, the flow returns to the initial condition in around 1.2 s.
By calculating the velocity differences between a transient mean velocity ( V 1 ) and the initial mean velocity ( V 0 ) and dividing it by maximum initial velocity as | ( V 1 V 0 ) / ( V max ) 0 | , an index for the velocity change can be achieved for further evaluation. It can help us to understand how much the velocity is going to change with time and provide information about the dissipative effects associated to flow velocity. This parameter is plotted in Figure 10 for all the tests and time steps of 0.8, 1.0, 1.2 and 1.4 s from the beginning of the transient event. The selected time steps are the closest time steps to the initial conditions, making the comparison easier. As can be seen in Figure 10a–d, the velocity index is very small after 1 s from the beginning of the transient event, proving the recovery of initial flow conditions. Also, it can be deducted that the initial condition recovery occurs better for higher Re numbers.
As a general conclusion, the initial flow velocity recovery with time is plotted in Figure 10e, showing the highest difference in the time of valve closure (0.2 s) and recovering the flow very fast upon re-opening the valve. As a result, the flow change during the current transient event can be recuperated with almost neglected dissipative effects for the main flow conditions.

5. Dimensional Analysis

In this section, the Buckingham pi theorem is exploited to study the transient hydraulic behaviour caused in the CAV. The flow is based on the pressure with the same liquid (water) being adopted in the model and prototype. So, on the basis of dimensional analysis, a scale factor is defined by:
λ L = L m ( variable in the model ) L p ( variable in the prototype ) ,
where λ is defined as a scale parameter of model dimension over prototype dimension. The subscripts m and p stand for model and prototype, respectively.
The CAV (as an air vessel) can be reproduced similarly to a reservoir, where the gravity force is the main predominant force. The parameters, demonstrated in Table 2, are important in the operation of the CAV in the TI-CAES model functionality (represented by subscript: m):
Applying dimensional analysis is possible to forecast the characteristic parameters for different length-scales, supposing the similarity law applied only to the CAV operation, since dimensions and characteristics of the model were obtained based on the Froude and Allievi similarity, and the effect of viscosity forces on the combined friction effect of the flow inside the tank and inertia forces were neglected. Hence, from the basic equations of dimensionless variables, the compatibility between the Froude and Allievi criteria is obtained by imposing that the elastic wave velocity scale ( λ c ), and the liquid velocity scale ( λ V ); both are equal to λ L 1 / 2 . This criterion corresponds to the assumption that the Mach number (V/c) is constant [49]. Therefore, for example, with λ L = 1/10, it was necessary to ensure, in the experimental installation, a slower speed than the prototype. Thus, for the wave speed of 1000 m/s in a prototype, the equivalent in the experimental installation should be 316 m/s. This reduction has been achieved by selecting PVC material for the pipe. Failure to comply with Reynolds’ criterion leads to the unit pressure drop not being similar. However, given that the objective of the study is the analysis of the total integrated pressure ( p int ) that occurs in the transient time, it is assumed that the effect of friction losses are not relevant for this type of study, as proved in former research [49].
In this context, by putting different variable scales as a function of the size, one can get the following scales for different parameters based on Froude similarity:
Velocity scale: V m ( g L m ) 1 / 2 = V p ( g L p ) 1 / 2 V m V p = ( g L m ) 1 / 2 ( g L p ) 1 / 2 λ V = λ L 1 / 2 , (6)
Time scale: L = V . t λ L = λ V . λ t λ t = λ L λ V λ t = λ L 1 / 2 , (7)
Acceleration scale: a = d V d t λ a = λ V λ t λ a = 1 , (8)
Flow rate scale: Q = V . A λ Q = λ V . λ L 2 λ Q = λ L 5 / 2 , (9)
Mass scale: m = ρ . λ m = λ ρ . λ L 3 λ m = λ L 3 , (10)
Force scale: F = m . a λ F = λ m . λ a λ F = λ L 3 , (11)
Pressure scale: p = F S λ p = λ F λ L 2 λ p = λ L , (12)
Energy scale: E = F . L λ E = λ F . λ L λ E = λ L 4 , (13)
Power scale: P = E t λ P = λ E λ t λ P = λ L 7 / 2 , (14)
As a result, the transient or waterhammer event time, flow rate, power and energy in the prototype can be calculated using the following equations:
( t t r ) p = ( t t r ) m λ t = ( t t r ) m λ L 1 / 2 ,
( p a i r ) p = ( p a i r ) m λ p = ( p a i r ) m λ L ,
( Q o u t ) p = ( Q o u t ) m λ Q = ( Q o u t ) m λ L 5 / 2 ,
( P h y d ) p = ( P h y d ) m λ P = ( P h y d ) m λ L 7 / 2 ,
( E ) p = ( E ) m λ E = ( E ) m λ L 4 ,
The measured values of pressure and flow rate related to Re = 155,000 (corresponding to highest achieved power) along with physical specifications of the experimental system were used to calculate the hydraulic power (the same data as Figure 8) and energy of the system, as shown in Table 3. The data for different air volumes (VFRs) are presented in Table 3 to be comparable with later scaled-up data of prototypes.
The experimental values shown in Table 3 are used to calculate the scaled-up values for three length-scales of 1/10, 1/20 and 1/25 presented in Table 4, Table 5 and Table 6 for the same Re = 155,000, demonstrating an estimation of the installed power and available energy for the respective prototypes.

6. Discussion

The results presented in the current study are based on measurements in an experimental model and a set of properly developed analyses. This study inspected the TI-CAES idea from different aspects and reported different achievements, most importantly the amount of attainable hydraulic power. The presented data for three different prototypes demonstrate encouraging values of hydraulic power having the maximum values of 131.33, 1485.79 and 3244.46 in kW for the length-scales of 1/10, 1/20 and 1/25, respectively, while the maximum power of the model was equal to 41 W. The power grew considerably by increasing the length-scale, as can be seen in the comparison of the length-scales of 1/20 and 1/25 in Figure 11, when the maximum power growth is more than double, changing from 1485.79 to 3244.46.
Isolating the CAV from the main pipeline, to observe the behaviour of air in charge/discharge phases, it can be concluded the CAV behaviour does not depend on the Re number. This has been justified earlier in the discussions of Section 5, since the friction factor effect in the CAV can be omitted. However, the CAV receives influence from the main pipeline in each waterhammer event. So, as presented in Figure 8, the Re number in the main pipeline will affect the output hydraulic power. The above results showed the outcomes only for a Re = 155,000, this being the highest tested one. In order to have an idea of how the hydraulic power varies for different Re numbers (i.e., different flow velocities in the main pipeline), a dimensionless parameter is defined as Equation (20) by removing the effect of CAV volume and maximum pressure:
( P dim ) m = ( P hyd ) m CAV × 1 ( t w h ) m ( p max ) m ,
where ( p max ) m is the maximum recorded p air for each individual test in the experimental system. The dimensionless graph in Figure 12 shows that for VFRs < 20%, the power in different prototype scales does not depend on the Re numbers of the main pipeline flow. Nevertheless, bigger VFRs are more impressionable and therefore for VFRs > 20%, the power will be more dependent on the Re number of the main pipeline flow.
The results show that the CAV is working in charge/discharge cycles by the compression/expansion of the air after each waterhammer occurrence. The charge/discharge action of the CAV includes two pressure values of p 0 (the initial pressure) and p t r (the transient pressure in each cycle). Small VFRs produce very high peaks, as presented in Figure 3, creating the expectation to have higher powers for small VFRs. In fact, due to the direct relation between hydraulic power and pressure, the variation of power during the transient time will also include high power peaks for small VFRs, as presented in Figure 7. Regardless, the total hydraulic power during the test time calculated based on an integrated pressure value (see Figure 6) will be higher for bigger VFRs. In fact, for big VFRs, the air–water interface encounters a big displacement upon receiving the first pressure surge. Since the time interval between waterhammer repetitions is small, the available time is not enough for the air–water interface to return to the initial position and as a result, the initial pressure ( p 0 ) is not recovered (see Figure 3b). This will be repeated in the next entrance of the pressure surges into the CAV as well. So, after a while, the pressure of the whole CAV increases, leading to less displacement but a higher pressurized CAV system that generates greater outlet flow rate and consequently hydraulic power. This issue has been proved also via the expansion work analysis in Figure 5.
In another part of the study, the consistency of the main pipeline flow was studied as another significant parameter in the feasibility of the TI-CAES, verifying a very short-lasting change in the velocity profile of the main pipeline. In addition, the maximum flow rate taken from the main pipeline was equal to 0.29 L/s (as shown in Table 3), indicating a total volume of about 5 L for the tested transient time (i.e., 18 s). These values are less than 4% of the main pipeline flow and the corresponding volume for Re = 155,000, which confirms the flow consistency and limited perturbation again.

7. Conclusions

The current research offers a new idea of a transientflow-induced compressed air energy storage system called TI-CAES. The main motivation behind this idea was decreasing the energy dependency in pressurized infrastructures and water systems by taking advantage of transient flow and compressibility nature of the air. Currently, hydro-power renewable energy sources hold the biggest share in renewable sources. Existing water systems supply the relevant capacity to increase the current share of hydro-power sources, diminishing the energy dependency and environmental impacts associated.
In this context, the feasibility of the TI-CAES system has been examined using an experimental system. The valve closure is always longer than critical closure time to avoid high values of pressure surges. This research presented an extensive analysis of different parameters to introduce the behaviour of the system and also verify the feasibility. Consequently, the major achievements of this study can be stated as:
  • The system showed a very controlled behaviour under the pressure surge occurrence, where the pressure surge can be stored in the form of compressed air in a vessel. The maximum pressure in the main pipeline is slightly higher than the maximum pressure of the air that provides a reliable calculation and prediction of the system.
  • The attained hydraulic power consists of considerable values, while the amount of input work to induce pressure surge into the system is negligible. This fact promises a high-efficiency system in which most of the parts usually exist in advance in a water system. Hence, the initial investment will not be large to set-up a TI-CAES system in an existing water system.
  • The analysis proved that the perturbation created in the main pipeline flow will be short-lasting and insignificant as changes in velocity profiles proved. The results show that the initial velocity of the main flow can be recovered in a very short time. Also, it was found that the velocity recovery and perturbation elimination is better for higher Reynolds numbers, making the TI-CAES system a better solution for water system with high Reynolds numbers.
  • It was shown that higher VFRs will provide considerably higher power values. In addition, higher VFRs will not provide extreme pressure peaks, which is an important advantage increasing the safety measures of the system. So, bigger air volumes provide a safe and economic energy recovery attitude due to very controlled pressure spikes while offering significant work done by air expansion.
  • The results show the TI-CAES concept offers a flexible, geography independent and efficient system that can provide high hydraulic power due to suppling a very high extra pressure head in the form of pressurized air.
No technical challenge regarding the implementation of TI-CAES in a real system has been encountered. However, further implementation in technical scale is required to verify the achieved values.

Author Contributions

The authors M.B. and H.M.R. contributed to the development of the idea and writing the paper; M.B. did the experimental tests with A.D.’s support; Results are analysed with the contribution of M.B., H.M.R., M.T.V. and B.B. All authors have read and agreed to the published version of the manuscript.

Funding

This work was supported by the Fundação para a Ciência e Tecnologia (FCT), Portugal under grant number PD/BD/114459/2016.

Acknowledgments

Authors would like to thank CERIS (Civil Engineering, Research, and Innovation for Sustainability) Centre from Instituto Superior Técnico, Universidade de Lisboa, Portugal, for providing the experimental facilities and also the European project REDAWN (Reducing Energy Dependency in Atlantic Area Water Networks) EAPA_198/2016 from INTERREG ATLANTIC AREA PROGRAMME 2014–2020.

Conflicts of Interest

The authors declare no conflict of interest. The funding sponsors had no role in the design of the study; in the collection, analyses and interpretation of data; in the writing of the manuscript; and in the decision to publish the results.

Nomenclature

Symbols
a acceleration [m/s2]
c wave speed [m/s]
D pipe diameter [m]
E energy [N.m]
F force [N]
g gravitational acceleration [m/s2]
L length [m]
m mass [kg]
n polytropic exponent [–]
p pressure [bar] or [kPa]
P hydraulic power [W] or [kW]
volume [m3]
W work [N.m]
t time [s]
Q flow rate [L/s] or [m3/s]
V flow velocity [m/s]
Indices
air air inside CAV
dim dimensionless value
0 initial (at time zero)
hyd hydraulic
int integrated value
L length
m model
max maximum value
out outlet
p prototype
tr related to transient condition
Greek letters
γ specific weight [N/m3]
λ scale factor
ρ fluid density [kg/m3]
Abbreviations
AA-CAES Advanced Adiabatic Compressed Air Energy Storage
BVBall Valve
CAESCompressed Air Energy Storage
CAVCompressed Air Vessel
CVCheck Valve
DAData Acquisition system
HTHydro-pneumatic Tank
PATPump as Turbine
PH-CAESPumped Hydro Compressed Air Energy Storage
PSHPumped-Storage Hydropower
PTPressure Transducer
ReReynolds number
TI-CAESTransient-flow Induced Compressed Air Energy Storage
UDVUltrasonic Doppler Velocimetry
UPSHUnderwater Pumped-storage Hydropower
VFRVolume Fraction Ratio

References

  1. IHA (International Hydropower Association). Hydropower Status Report: Sector Trends and Insights. 2019. Available online: https://www.hydropower.org/status2019 (accessed on 13 May 2019).
  2. REN21. Renewables Global Status Report. 2019. Available online: https://www.ren21.net/wp-content/uploads/2019/05/gsr_2019_full_report_en.pdf (accessed on 13 January 2020).
  3. IEA (International Energy Agency). Renewables: market analysis and forecast from 2019 to 2024, Paris. 2019. Available online: https://www.iea.org/reports/renewables-2019 (accessed on 13 January 2020).
  4. Hoes, O.A.C.; Meijer, L.J.J.; Van der Ent, R.J.; Van de Giesen, N.C. Systematic high-resolution assessment of global hydropower potential. PLoS ONE 2017, 12, e0171844. [Google Scholar] [CrossRef] [PubMed]
  5. Vieira, F.; Ramos, H.M. Hybrid solution and pump-storage optimization in water supply system efficiency: A case study. Energy Policy 2008, 36, 4142–4148. [Google Scholar] [CrossRef]
  6. Vieira, F.; Ramos, H.M.; Covas, D.I.C.; Almeida, A.B. Pump-Storage optimization with renewable energy production in water supply systems. In Proceedings of the 4th International Conference on Water and Wastewater Pumping Stations, BHR Group, Cranfield, UK, 17–18 June 2008. [Google Scholar]
  7. Ramos, H.M.; Amaral, M.P.; Covas, D.I.C. Pumped-storage solution towards energy efficiency and sustainability: Portugal contribution and real case studies. J. Water Resour. Prot. 2014, 6, 1099. [Google Scholar] [CrossRef] [Green Version]
  8. Morabito, A.; Oliveira e Silva, G.; Hendrick, P. Deriaz pump-turbine for pumped hydro energy storage and micro applications. J. Energy Storage 2019, 24. [Google Scholar] [CrossRef]
  9. Kougias, I.; Aggidis, G.; Avellan, F.; Deniz, S.; Lundin, U.; Moro, A.; Muntean, S.; Novara, D.; Pérez-Díaz, J.I.; Quaranta, E.; et al. Analysis of emerging technologies in the hydropower sector. Renew. Sustain. Energy Rev. 2019, 113. [Google Scholar] [CrossRef]
  10. Ramos, H.M. Guidelines for Design of Small Hydropower Plants, 1st ed.; WREAN (Western Regional Energy Agency & Network) and DED (Department of Economic Development): Belfast, North Ireland, 2000. [Google Scholar]
  11. Vieira, F.; Ramos, H.M. Optimization of operational planning for wind/hydro hybrid water supply systems. Renew. Energy 2009, 34, 928–936. [Google Scholar] [CrossRef]
  12. Pérez-Sánchez, M.; Sánchez-Romero, F.J.; Ramos, H.M.; López-Jiménez, P.A. Energy recovery in existing water networks: Towards greater sustainability. Water 2017, 9, 97. [Google Scholar] [CrossRef] [Green Version]
  13. Ramos, H.M.; Zilhao, M.; López-Jiménez, P.A.; Pérez-Sánchez, M. Sustainable water-energy nexus in the optimization of the BBC golf-course using renewable energies. Urban Water J. 2019, 16, 215–224. [Google Scholar] [CrossRef]
  14. Pérez-Sánchez, M.; Sánchez-Romero, F.J.; López-Jiménez, P.A.; Ramos, H.M. PATs selection towards sustainability in irrigation networks: Simulated annealing as a water management tool. Renew. Energy 2018, 116, 234–249. [Google Scholar] [CrossRef]
  15. Carravetta, A.; Derakhshan Houreh, S.; Ramos, H.M. Pumps as Turbines; Springer Tracts in Mechanical Engineering; Springer: Cham, Switzerland, 2018. [Google Scholar] [CrossRef]
  16. Novara, D.; Derakhshan, S.; McNabola, A.; Ramos, H.M. Estimation of unit cost and maximum efficiency for pumps as turbines. In Proceedings of the 9th Eastern European IWA Young Water Professionals, Budapest, Hungary, 24–27 May 2017. [Google Scholar]
  17. García, I.F.; Ferras, D.; McNabola, A. Potential of energy recovery and water saving using micro-hydropower in rural water distribution networks. J. Water Resour. Plan. Manag. 2019, 145. [Google Scholar] [CrossRef]
  18. Fernandes, J.F.P.; Pérez-Sánchez, M.; Ferreira da Silva, F.; López-Jiménez, P.A.; Ramos, H.M.; Branco, P.J.C. Optimal energy efficiency of isolated PAT systems by SEIG excitation tuning. Energy Convers. Manag. 2019, 183, 391–405. [Google Scholar] [CrossRef]
  19. Morillo, J.G.; McNabola, A.; Camacho, E.; Montesinos, P.; Rodríguez Díaz, J.A. Hydro-power energy recovery in pressurized irrigation networks: A case study of an Irrigation District in the South of Spain. Agric. Water Manag. 2018, 204, 17–27. [Google Scholar] [CrossRef]
  20. Chacón, M.C.; Rodríguez Díaz, J.A.; Morillo, J.G.; McNabola, A. Hydropower energy recovery in irrigation networks: Validation of a methodology for flow prediction and pump as turbine selection. Renew. Energy 2020, 147, 1728–1738. [Google Scholar] [CrossRef]
  21. Pérez-Sánchez, M.; Sánchez-Romero, F.J.; Ramos, H.M.; López-Jiménez, P.A. Modeling Irrigation Networks for the Quantification of Potential Energy Recovering: A Case Study. Water 2016, 8, 234. [Google Scholar] [CrossRef] [Green Version]
  22. Pérez-Sánchez, M.; Sánchez-Romero, F.J.; Ramos, H.M.; López-Jiménez, P.A. Optimization Strategy for Improving the Energy Efficiency of Irrigation Systems by Micro Hydropower: Practical Application. Water 2017, 9, 799. [Google Scholar] [CrossRef] [Green Version]
  23. Sari, M.A.; Badruzzaman, M.; Cherchi, C.; Swindle, M.; Ajami, N.; Jacangelo, G. Recent innovations and trends in in-conduit hydropower technologies and their applications in water distribution systems. J. Environ. Manag. 2018, 228, 416–428. [Google Scholar] [CrossRef]
  24. Timilsina, A.B.; Mulligan, S.; Bajracharya, T.R. Water vortex hydropower technology: A state-of-the-art review of developmental trends. Clean Technol. Environ. Policy 2018, 20, 1737–1760. [Google Scholar] [CrossRef]
  25. Chen, H.; Zhang, X.; Liu, J.; Tan, C. Compressed Air Energy Storage, Energy Storage - Technologies and Applications, Ahmed Faheem Zobaa, IntechOpen. Available online: https://www.intechopen.com/books/energy-storage-technologies-and-applications/compressed-air-energy-storage (accessed on 13 January 2020). [CrossRef] [Green Version]
  26. Zhang, Y.; Yang, K.; Li, X.; Xu, J. The thermodynamic effect of thermal energy storage on compressed air energy storage system. Renew. Energy 2013, 50, 227–235. [Google Scholar] [CrossRef]
  27. Grazzini, G.; Milazzo, A. Thermodynamic analysis of CAES/TES systems for renewable energy plants. Renew. Energy 2008, 33, 1998–2006. [Google Scholar] [CrossRef]
  28. Camargos, P.L.T.; Pottie, D.L.F.; Ferreira, R.A.M.; Maia, T.A.C.; Porto, M.P. Experimental study of a PH-CAES system: Proof of concept. Energy 2018, 165, 630–638. [Google Scholar] [CrossRef]
  29. Pottie, D.L.F.; Ferreira, R.A.M.; Maia, T.A.C.; Porto, M.P. An alternative sequence of operation for Pumped-Hydro Compressed Air Energy Storage (PH-CAES) systems. Energy 2019. [Google Scholar] [CrossRef]
  30. Odukomaiya, A.; Abu-Heiba, A.; Graham, S.; Momen, A.M. Experimental and analytical evaluation of a hydro-pneumatic compressed-air Ground-Level Integrated Diverse Energy Storage (GLIDES) system. Appl. Energy 2018, 221, 75–85. [Google Scholar] [CrossRef] [Green Version]
  31. Storli, P.-T.; Lundström, T.S. A New Technical Concept for Water Management and Possible Uses in Future Water Systems. Water 2019, 11, 2528. [Google Scholar] [CrossRef] [Green Version]
  32. Besharat, M.; Viseu, M.T.; Ramos, H.M. Experimental study of air vessel behavior for energy storage or system protection in waterhammer events. Water 2017, 9, 63. [Google Scholar] [CrossRef] [Green Version]
  33. Triki, A.; Fersi, M. Further investigation on the water-hammer control branching strategy in pressurized steel-piping systems. Int. J. Press. Vessels Pip. 2018, 165, 135–144. [Google Scholar] [CrossRef]
  34. Triki, A.; Chaker, M.A. Compound technique -based inline design strategy for water-hammer control in steel pressurized-piping systems. Int. J. Press. Vessels Pip. 2019, 169, 188–203. [Google Scholar] [CrossRef]
  35. WIKA Data Sheet PE 81.01. 2018. Available online: https://en.wika.com/upload/DS_PE8101_en_co_1392.pdf (accessed on 13 January 2020).
  36. UVP-DUO User’s Guide; MET-FLOW. Release 5.2; Met-Flow SA: Lausanne, Switzerland, 2014; Available online: https://met-flow.com/support/download (accessed on 13 January 2020).
  37. George Fischer (GF) Piping Systems Datasheet Pneumatic Actuators PA 30–PA 90. Available online: https://www.gfps.com/appgate/ecat/common_flow/100022/AT/en/109564/109576/P120047/product.html (accessed on 13 January 2020).
  38. Wylie, E.B.; Streeter, V.L. Fluid Transients in Systems; Prentice Hall: New York, NY, USA, 1993. [Google Scholar]
  39. Besharat, M.; Ramos, H.M. Theorical and experimental analysis of pressure surge in a two-phase compressed air vessel. In Proceedings of the 12th International Conference on Pressure Surges, BHR Group, Dubline, Ireland, 18–20 November 2015; Available online: https://www.scopus.com/inward/record.uri?eid=2-s2.0-84966351254&partnerID=40&md5=4c831ebf8171ef3543b8add5064aa020 (accessed on 13 January 2020).
  40. Vereide, K.; Tekle, T.; Nielsen, T. Thermodynamic behavior and heat transfer in closed surge tanks for hydropower plants. J. Hydraul. Eng. 2015, 141. [Google Scholar] [CrossRef] [Green Version]
  41. Goodall, D.C.; Kjørholt, H.; Tekle, T.; Broch, E. Air cushion surge chambers for underground power plants. Int. Water Power Dam Constr. 1988, 40, 29–34. [Google Scholar]
  42. Steward, E.H.; Borg, J.E. Moose river air chamber design and performance. In Waterpower’89; U.S. Army Corps of Engineers; ASCE: Buffalo District, NY, USA, 1989; pp. 567–576. [Google Scholar]
  43. Svee, R. Surge chamber with enclosed compressed air cushion. In Proceedings of the First International Conference on Pressure Surges, Canterbury, UK, 10 September 1972; pp. 15–24. [Google Scholar]
  44. Zhou, L.; Liu, D.; Karney, B. Investigation of hydraulic transients of two entrapped air pockets in a water pipeline. J. Hydraul. Eng. 2013, 139. [Google Scholar] [CrossRef]
  45. Zhou, L.; Liu, D.; Karney, B.; Wang, P. Phenomenon of white mist in water rapidly filling pipeline with entrapped air pocket. J. Hydraul. Eng. 2013, 139. [Google Scholar] [CrossRef]
  46. Chaudhry, M.H. Applied Hydraulic Transients; Springer: New York, NY, USA, 2014. [Google Scholar]
  47. Simão, M.; Besharat, M.; Carravetta, A.; Ramos, H.M. Flow Velocity Distribution towards Flowmeter Accuracy: CFD, UDV, and Field Tests. Water 2018, 10, 1807. [Google Scholar] [CrossRef] [Green Version]
  48. Brunone, B.; Berni, A. Wall shear stress in transient turbulent pipe flow by local velocity measurement. J. Hydraul. Eng. 2010, 136. [Google Scholar] [CrossRef]
  49. Ramos, H.M. Simulação e Controlo de Transitórios Hidráulicos em Pequenos Aproveitamentos Hidroelétricos. Ph.D. Thesis, Civil Engineering, Instituto Superior Técnico, Universidade de Lisboa, Lisboa, Portugal, 1995. (In Portuguese). [Google Scholar]
Figure 1. (a) Hydropower capacity growth, (b) hydropower rank in the global electricity generation [1]
Figure 1. (a) Hydropower capacity growth, (b) hydropower rank in the global electricity generation [1]
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Figure 2. Experimental apparatus as part of the transient flow-induced compressed air energy storage (TI-CAES) system and energy conceptual ideas: (a) electricity dispatch; (b) pumping system.
Figure 2. Experimental apparatus as part of the transient flow-induced compressed air energy storage (TI-CAES) system and energy conceptual ideas: (a) electricity dispatch; (b) pumping system.
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Figure 3. Experimental pressure variation in charge/discharge stages of the CAV, for Re = 155,000: (a) volume fraction ratio (VFR) = 8.33%; (b) VFR = 66.67%.
Figure 3. Experimental pressure variation in charge/discharge stages of the CAV, for Re = 155,000: (a) volume fraction ratio (VFR) = 8.33%; (b) VFR = 66.67%.
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Figure 4. The pressure–volume diagram.
Figure 4. The pressure–volume diagram.
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Figure 5. The work done by the air expansion is the area below the pressure–volume graph in different VFRs.
Figure 5. The work done by the air expansion is the area below the pressure–volume graph in different VFRs.
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Figure 6. The concept of average and real-time air pressure: (a) average pressure for different VFR and Re numbers; (b) p a i r for VFR = 3.33% and Re = 155,000; (c) p a i r for VFR = 25.00% and Re = 155,000; (d) p a i r for VFR = 66.67% and Re = 155,000.
Figure 6. The concept of average and real-time air pressure: (a) average pressure for different VFR and Re numbers; (b) p a i r for VFR = 3.33% and Re = 155,000; (c) p a i r for VFR = 25.00% and Re = 155,000; (d) p a i r for VFR = 66.67% and Re = 155,000.
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Figure 7. The hydraulic power and p a i r changing during transient for Re = 155,000 and: (a) VFR = 3.33%; (b) VFR = 16.67%; (c) VFR = 33.33%; (d) VFR = 66.67%.
Figure 7. The hydraulic power and p a i r changing during transient for Re = 155,000 and: (a) VFR = 3.33%; (b) VFR = 16.67%; (c) VFR = 33.33%; (d) VFR = 66.67%.
Water 12 00601 g007aWater 12 00601 g007b
Figure 8. The power production for experimental CAV volume based on integrated pressure values.
Figure 8. The power production for experimental CAV volume based on integrated pressure values.
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Figure 9. Velocity profiles along time: (a) Re = 58,000; (b) Re = 93,000; (c) Re = 132,000; (d) Re = 155,000.
Figure 9. Velocity profiles along time: (a) Re = 58,000; (b) Re = 93,000; (c) Re = 132,000; (d) Re = 155,000.
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Figure 10. Difference between the transient mean velocity (V1) and the initial mean velocity (V0) over the maximum initial velocity (Vmax)0 for all the tested conditions and time steps after starting the transient event as: (a) 0.8; (b) 1.0; (c) 1.2; (d) 1.4; (e) for more time.
Figure 10. Difference between the transient mean velocity (V1) and the initial mean velocity (V0) over the maximum initial velocity (Vmax)0 for all the tested conditions and time steps after starting the transient event as: (a) 0.8; (b) 1.0; (c) 1.2; (d) 1.4; (e) for more time.
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Figure 11. Hydraulic prototype power for different length-scales and VFRs.
Figure 11. Hydraulic prototype power for different length-scales and VFRs.
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Figure 12. Dimensionless power for different VFR and Re numbers in TI-CAES system.
Figure 12. Dimensionless power for different VFR and Re numbers in TI-CAES system.
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Table 1. System parameters summary.
Table 1. System parameters summary.
ParameterMeasuring Range
Pipe pressure [bar]0.00 to 6.62
Air pressure [bar]0.00 to 5.08
VFR [%]3.33 to 66.67
Flow Velocity [m/s]1.36 to 5.13
Flow Rate [L/s]1.76 to 7.43
Re number [–]36,000 to 155,000
Table 2. Major parameters for operation of CAV in TI-CAES model.
Table 2. Major parameters for operation of CAV in TI-CAES model.
ParametersDefinition
( t t r ) m time of transient (waterhammer) event
( C A V ) m volume of CAV
( a i r ) m volume of air inside CAV
( D ) m exit pipe diameter
( p a i r ) m air pressure inside CAV
( Q o u t ) m outlet flow from CAV
( P h y d ) m hydraulic power of CAV
( E ) m available energy in CAV
Table 3. Measured and calculated parameters in the laboratory model apparatus for different VFRs.
Table 3. Measured and calculated parameters in the laboratory model apparatus for different VFRs.
Parameters ( t t r ) m ( CAV ) m VFR ( air ) m ( D ) m ( p int ) m ( Q o u t ) m ( P hyd ) m ( E ) m
[s][m3][%][m3][m][kPa][m3/s][kW][kWh]
DimensionsTL3-L3LM L−1 T−2L3 T−1M L2 T−3M L2 T−2
Model Values180.00473.330.000160.02117.270.000100.011400.00006
5.000.00023125.040.000130.015630.00008
6.670.00031130.750.000160.020340.00010
8.330.00039133.090.000170.022920.00011
11.670.00054139.490.000200.028280.00014
16.670.00078140.210.000220.031160.00016
25.000.00116142.980.000250.035740.00018
33.330.00155146.700.000270.039120.00020
50.000.00233145.150.000290.041530.00021
66.670.00310137.860.000290.039600.00020
Table 4. Scaled-up parameters for a prototype with length-scale 1/10 and different VFRs.
Table 4. Scaled-up parameters for a prototype with length-scale 1/10 and different VFRs.
Parameters λ L ( t t r ) p ( CAV ) p VFR ( air ) m ( D ) m ( p air ) m ( Q o u t ) m ( P hyd ) m ( E ) m
[s][m3][%][m3][m][kPa][m3/s][kW][kWh]
Prototype Values1/1056.924.703.330.160.201172.650.0336.050.57
5.000.231250.370.0449.430.78
6.670.311307.460.0564.321.02
8.330.391330.940.0572.491.15
11.670.541394.850.0689.441.41
16.670.781402.080.0798.531.56
25.001.161429.770.08113.031.79
33.331.551467.000.08123.711.96
50.002.331451.500.09131.332.08
66.673.101378.600.09125.221.98
Table 5. Scaled-up parameters for a prototype with length-scale 1/20 and different VFRs.
Table 5. Scaled-up parameters for a prototype with length-scale 1/20 and different VFRs.
Parameters λ L ( t t r ) p ( CAV ) p VFR ( air ) m ( D ) m ( p air ) m ( Q o u t ) m ( P hyd ) m ( E ) m
[s][m3][%][m3][m][kPa][m3/s][kW][kWh]
Prototype Values1/2080.5037.603.331.240.402345.310.17407.899.12
5.001.862500.740.22559.1812.50
6.672.482614.920.28727.6416.27
8.333.102661.880.31820.0718.34
11.674.352789.710.361011.9422.63
16.676.212804.160.401114.7224.93
25.009.312859.540.451278.8328.60
33.3312.422934.000.481399.6031.30
50.0018.622903.010.511485.7933.22
66.6724.832757.210.511416.6531.68
Table 6. Scaled-up parameters for a prototype with length-scale 1/25 and different VFRs.
Table 6. Scaled-up parameters for a prototype with length-scale 1/25 and different VFRs.
Parameters λ L ( t t r ) p ( CAV ) p VFR ( air ) m ( D ) m ( p air ) m ( Q o u t ) m ( P hyd ) m ( E ) m
[s][m3][%][m3][m][kPa][m3/s][kW][kWh]
Prototype Values1/2590.0073.443.332.430.502931.630.30890.6922.27
5.003.643125.920.391221.0630.53
6.674.853268.640.491588.9239.72
8.336.063327.350.541790.7644.77
11.678.493487.140.632209.7355.24
16.6712.133505.200.692434.1660.85
25.0018.193574.430.782792.5269.81
33.3324.253667.500.833056.2576.41
50.0036.383628.760.893244.4681.11
66.6748.503446.510.903093.4877.34

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MDPI and ACS Style

Besharat, M.; Dadfar, A.; Viseu, M.T.; Brunone, B.; Ramos, H.M. Transient-Flow Induced Compressed Air Energy Storage (TI-CAES) System towards New Energy Concept. Water 2020, 12, 601. https://doi.org/10.3390/w12020601

AMA Style

Besharat M, Dadfar A, Viseu MT, Brunone B, Ramos HM. Transient-Flow Induced Compressed Air Energy Storage (TI-CAES) System towards New Energy Concept. Water. 2020; 12(2):601. https://doi.org/10.3390/w12020601

Chicago/Turabian Style

Besharat, Mohsen, Avin Dadfar, Maria Teresa Viseu, Bruno Brunone, and Helena M. Ramos. 2020. "Transient-Flow Induced Compressed Air Energy Storage (TI-CAES) System towards New Energy Concept" Water 12, no. 2: 601. https://doi.org/10.3390/w12020601

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