Next Article in Journal
Using Modified Remote Sensing Imagery to Interpret Changes in Cultivated Land under Saline-Alkali Conditions
Next Article in Special Issue
Water and Carbon Footprint of Wine: Methodology Review and Application to a Case Study
Previous Article in Journal
The Development and Full-Scale Experimental Validation of an Optimal Water Treatment Solution in Improving Chiller Performances
Previous Article in Special Issue
Reuse and Upcycling of Municipal Waste for ZEB Envelope Design in European Urban Areas
 
 
Search for Articles:
Title / Keyword
Author / Affiliation / Email
Journal
Article Type
 
 
Advanced Search
 
Section
Special Issue
Volume
Issue
Number
Page
 
Journals
Sustainability
Volume 8
Issue 7
10.3390/su8070618
sustainability-logo
Submit to this Journal Review for this Journal Propose a Special Issue
Article Menu

Article Menu

share Share announcement Help format_quote Cite question_answer Discuss in SciProfiles thumb_up
...
Endorse textsms
...
Comment
first_page
settings
Order Article Reprints
Font Type:
Arial Georgia Verdana
Font Size:
Aa Aa Aa
Line Spacing:
Column Width:
Background:
Article

LED Lighting for Indoor Sports Facilities: Can Its Use Be Considered as Sustainable Solution from a Techno-Economic Standpoint?

by
Fabio Fantozzi
,
Francesco Leccese
,
Giacomo Salvadori
*,
Michele Rocca
and
Marco Garofalo
Lighting and Acoustic Laboratory (LIA), Department of Energy, Systems, Territory and Constructions Engineering, University of Pisa, Largo Lucio Lazzarino, Pisa 56122, Italy
*
Author to whom correspondence should be addressed.
Sustainability 2016, 8(7), 618; https://doi.org/10.3390/su8070618
Submission received: 24 May 2016 / Revised: 24 June 2016 / Accepted: 27 June 2016 / Published: 30 June 2016
(This article belongs to the Special Issue 16th CIRIAF National Congress – Sustainable Development, Environment and Human Health Protection)
Browse Figures
Versions Notes

Abstract

:
In this paper, the authors propose a techno-economic comparative analysis between different lighting solutions, using, respectively, floodlight with metal halide lamps, luminaires with fluorescent lamps and LED floodlights. The comparison is aimed to identify general criteria for assessing the techno-economic sustainability of the use of LED lighting for indoor sports facilities, since this solution is very often proposed to achieve a reduction of the electrical power for lighting. From a technical standpoint, the analysis takes into particular consideration the aspects related to the satisfaction of lighting requirements, safety and energy efficiency. From an economic standpoint the investment, the operating and the maintenance costs are evaluated. To make comparisons on an economic basis, specific indicators are used. From the obtained results it is possible to highlight as the solution that uses the LED floodlights is characterized by highest energy efficiency. This solution requires a smaller number of luminaires and it has limited maintenance costs compared to the other solutions, but it has high investment costs, which involve reasonable payback times only when the sports facility is used intensively and for competitions of high level.

1. Introduction

Sports participation fulfills important social functions among children, adolescents and adults [1]. In a large number of countries, the number of sports facilities has grown over the last two decades, both in the public and private domain [2,3,4,5,6].
In Italy, there are about 150,000 sports facilities, according to the census carried out by the Italian National Olympic Committee (CONI) and updated in 2003 by the National Council for Economy and Labor (CNEL), from which emerges the high degree of obsolescence and age of the sports facilities [7,8]. Of Italian sports facilities, 62.5% were built before 1981 and 30% between 1981 and 1990. The main interventions implemented on the sports facilities are, for the most part (over 60%), intended to the refurbishment of the existing assets. In relation to the interventions aimed to improve energy efficiency, the main energy consumptions of the indoor sports facilities are due to the lighting of the playing fields and to domestic hot water production. It is evident that the reduction of the energy consumption for lighting can be achieved through the reduction of the installed power of the lamps and the better distribution of the luminaires [9]. In this case, a detailed study of the lighting systems is very important in order to increase the energetic and economic sustainability of sports facilities [10,11,12,13,14,15,16].
Requirements for artificial lighting of sports facilities are introduced in Europe by EN 12193 [17]. In Italy, the CONI takes the same parameters in the national guidelines [18]: “CONI regulations for sports facilities”. In sports facilities, the lighting system is commonly realized with one of the following solutions, which are characterized by the use of different types of luminaires [19]: floodlights with metal halide lamps (MH), luminaires with tubular fluorescent lamps (FL) and LED floodlights. The first two solutions are widely used, while the LED solution is poorly diffused because its recent adoption. Nowadays the use of LED is often proposed to achieve an immediate reduction of the electrical installed power, both for the realization of new facilities and for the refurbishment of existing facilities [20,21,22].
In this paper, the authors propose a techno-economic comparative analysis between the three different lighting solutions, in order to identify general criteria for assessing the techno-economic sustainability of LED lighting solution for the indoor sports facilities. From a technical standpoint, the analysis takes into particular consideration the aspects related to the satisfaction of the lighting requirements, the safety and the energy efficiency. From an economic standpoint the investment, the operating and the maintenance costs are evaluated. To make comparisons on an economic basis, specific indicators are used such as: Net Present Value (NPV) and simple Pay-Back Time (PBT). The discussion is based on the analysis of the results obtained from a case study, however the considerations made by the authors can be easily extended to all sports halls built with an arch structure covered by membrane, as shown in Figure 1, widespread in Italy and Europe.

2. Lighting Requirements in Sports Facilities

The lighting system in a sports facility should ensure good visual conditions for players, athletes, referees, spectators, and (if present) for TV shots. To achieve adequate lighting conditions is necessary to optimize the perception of visual information during the performance of sports events, maintaining the correct levels of visual performance and provide an acceptable level of visual comfort. The lighting requirements for indoor sports facilities are specified in Europe, in the Technical Standard EN 12193 [17]. In addition to the lighting requirements, it is important also a verification of the photobiological safety and the health effects of the lighting sources, to whose emissions the athletes can be exposed for several hours a day [23,24,25,26], in accordance to what should be done for other environments intended for the permanence of people [27,28,29,30].
The main parameters influencing the luminous environment, with reference to the artificial lighting for indoor sports facilities, are: horizontal average maintained illuminance, illuminance uniformity, color rendering index of the lamps and discomfort glare. To take into account the various needs of the different levels of play and the different viewing distances, depending on the sports facility capacity, three lighting classes (LC) are defined [17]: LC I (international competitions), LC II (national competitions), LC III (training). The minimum requirements of lighting parameters are variable in function of the considered combination between sport and lighting class. Table 1 shows the geometric dimensions of the playing fields, the values of the horizontal average maintained illuminance (Em), the minimum value of the illuminance uniformity (U0) and the minimum value of the color rendering index (Ra), for the three lighting classes and for three sports, which are considered as significant: volleyball, basketball and tennis. The specified lighting requirements should be satisfied at least on the calculation grid, that usually correspond to the playing field.
From Table 1 it is possible to notice that the values, which have to be satisfied, increase with the lighting class, because a growing perception of visual information is request with the increase of speed of the game actions. The correct perception of fast moving objects generally requires illuminance levels higher than that for fixed objects, typical of indoor workplaces.
In Italy, the National Federal Regulations provide additional information and details [31,32,33]. Some regulations give minimum values for the horizontal average maintained illuminance, which generally are higher than those reported in Table 1. In some cases, in addition to the identification of the illumination values, the methodologies of verifications and trials of the lighting systems are explained.

3. Case Study Description

The techno-economic analysis on the lighting systems were carried out for a sports hall with a structure of laminated wood arches, covered by a membrane with PVC sheets, in which a polyvalent playing field was inserted, as shown in Figure 1 (Section 1). This type of structure is widespread in Italy for volleyball, basketball and tennis. Considering that the values of the lighting parameters (see Table 1) are referred to the playing field and considering that the sports halls have big volumes with very distant envelope surfaces each other, lighting design is not significantly affected by the reflection of the envelope surfaces. The results obtained from the analysis can therefore be generalized, with good approximation, to all sports halls with construction features similar to the case study.
The structure in laminated wood arches used as case study has the following dimensions: 30 m wide, 45 m long and 13 m height. The sports hall dimensions are such as to allow the carrying out the sports of volleyball, basketball and tennis, and the installation of removable stands for a maximum capacity of 230 spectators. The reflection coefficients (ρ) of the main surfaces of the sport hall are the following: laminated wood arches (1600 m2) ρ = 52%; sports floor (1300 m2) ρ = 22%; Internal cover sheet (2562 m2) ρ = 86%; tribunes (350 m2) ρ = 70%.
The lighting system is commonly made by using one of three types of luminaires: high-power floodlights with metal halide lamps (MH), luminaires with tubular fluorescent lamps (FL), and LED floodlights (LED). The first two solutions are widely used and usually they are provided "turnkey" together with the lighting design by the luminaires installer, while the LED solution is less used and requires a case by case analysis. In Table 2, the technical data of typical examples of these luminaires are reported, one for each different type. In this work, a complete lighting design was carried out, through the lighting simulation software Dialux 4.12 (DIAL GmbH, Lüdenscheid, Germany, www.dial.de). The aim of the design was to define lighting system configurations able to satisfy the minimum lighting requirements listed in Table 1, according to the Technical Standard EN 12193 [17], using the three different type of luminaires.
In Table 3, the function of the lighting class and for all the considered sports, are specified: the number of the luminaires (N) and the overall electrical power (P) of the lighting system configuration, the value of horizontal average maintained illuminance (Em) and the illuminance uniformity (U0), which are, together with the usage time, the parameters mostly influencing the annual energy consumptions for artificial lighting.
From the analysis of the data shown in Table 3 and from the comparison between Table 1, Table 2 and Table 3, it can be observed that:
  • the lighting requirements fixed for the parameters Em and U0 are satisfied by all the lighting system configurations (compare Table 1 with Table 3);
  • the minimum values required for the parameter Ra are satisfied by all the considered lamps (compare Table 1 with Table 2);
  • the lighting system configurations with LED floodlights, if compared to similar configurations that use other luminaires, are characterized by the lowest number of luminaires and the lowest electrical installed power for lighting (see Table 3).
From the simulations results it was also possible to verify that all types of luminaires are able to satisfy, for the main directions of views, the UGR maximum values fixed for the different lighting classes and sports. However, the analysis of the glare in dynamic and very demanding visual conditions, such as those that occur during sport participation, requires advanced and very detailed assessments, which are beyond the scope of this paper.
In order to make the techno-economic evaluations on the lighting systems, the data in Table 3 for Tennis are used, because they are characterized by the maximum number of luminaires and the maximum installed electric power.

4. Techno-Economic Comparisons between Lighting Systems

The comparisons between the different lighting systems are addressed in this work on techno-economic standpoint. The economic analyses were conducted for a reference period of 20 years. Before introducing the results, it is necessary to provide information on the economic items considered for the calculation. For the three lighting systems were calculated: the initial investment cost (I0), the operating cost (Co), and the maintenance cost (Cm). The parameter I0 is given by the product of the number of installed luminaires (N) and their unit cost. The comparisons were done considering the realization of the lighting system with: its own funds and a bank financing. In the first case, I0 is placed to the year of realization of the lighting system, while in the second case the mortgage payment is considered in the annual outflows. The mortgage payments were calculated using a fixed rate equal to 3.5% [35]. The parameter Co is due to the energy consumptions when the lighting system is switched-on and it depends on: the electrical installed power for lighting (P), the usage time and the hourly rate of electrical energy (estimated at 0.18 €/kWh [36] according to the Italian Regulation Authority for Electricity, Gas and Water). The parameter Cm depends on the frequency of the maintenance works for the luminaires, which are necessary in order to guarantee that the lighting requirements are satisfied (see Table 1). This parameter was evaluated as International Commission on illumination (CIE) [34]: Cm = Nr∙Cu, where Nr is the number of replaced lamps during the scheduled maintenance and Cu is the all-comprehensive unit cost of lamp (that takes into account the supply, installation and disposal costs usually applied in Italy). The frequency of the scheduled maintenance varies in function of the lamp type and it is equal to 1, 6 and 14 years respectively for MH, FL and LED. The determination of this frequency for each lamp is influenced by the lighting requirements, which need to be satisfied, and by the technical data about the lamp survival and lamp lumen maintenance factor provided by the manufacturers (see Table 2). The frequency of the scheduled maintenance of 14 years for LED was determined considering conservatively an accidental failure of 10% of the installed LED floodlights at the 70% of the reference period (20 years) [37]. Co and Cm are referred to different years, respect to the year of the realization of the lighting system (base year). For this reason, they have to be reported to the base year by discounting procedure. The discounting procedure depends on discount rate (r). The discount rate is defined as the rate at which the investment revenues and costs are discounted in order to calculate its present value. For the realization of the lighting system with its own funds, a discount rate equal to 2% was considered [38], while for the use of a bank financing, the discount rate assumes the same value of the interest rate (3.5%). The discounting of the individual cost parameter was done by using the following equation: Cd = Ck/(1 + r)k, where Cd (€) is the discounted cash flow, Ck (€) is the cash flow expected in the k year and r is the discount rate.
In order to consider the different usages of the lighting system, according to the different lighting classes, multiple scenarios have been defined. Each scenario is characterized by a total annual usage time of the lighting system equal to 2000 h [39] divided into smaller fractions of time, for which the lighting system is used to satisfy different lighting classes. The assumed scenarios are defined in Table 4, where the total usage time and the usage times for each lighting class are indicated.
In order to evaluate the sustainability of the different lighting systems, the data contained in Table 3 were used. In the following sections, two techno-economic evaluations are discussed: the first (Section 4.1) is referred to the realization of the lighting systems in a sports hall of new construction, the second (Section 4.2) is referred to the refurbishment of the lighting system in an existing sports hall.

4.1. Energy and Economic Analysis of the Realization of the Lighting System in a Sports Hall of New Construction

When the lighting system in a sports hall of new construction has to be realized, the total management cost of the lighting system (CT) can be estimated as CT = I0 + Co + Cm. In this paper, I0, Co, and Cm were calculated for all the defined scenarios and considering the three different type of luminaires (MH, FL, LED, see Table 2).
Table 5 shows the calculation results for the scenarios 1, 2 and 3 and using a discount rate equal to 2%. The calculation results for scenarios 4, 5 and 6 are not reported because they are very similar to those of scenario 3. In the sixth column of Table 5, the values of the normalized management cost Cm,n are reported. They were obtained dividing the values of Cm by the number of years between two consecutive scheduled maintenances. The values of Cm,n are useful in order to have an immediate comparison between the maintenance costs of the different systems, but in order to correctly applied the discounting procedure the values of Cm were considered in the calculation. The last column of Table 5 reports the values of the primary energy consumption in tons of equivalent oil (toe). For the calculation of tons of equivalent oil, the Italian Regulation Authority for Electricity Gas and Water [40,41] gives the value of the conversion factor for the electrical energy into primary energy, estimated in 0.187 × 10−3 toe/kWh.
Considering the values shown in Table 5, the trends of CT in function of time is shown in Figure 2 for the scenario 1. From the trends of CT it can be observed that the lighting system with MH, despite having the lower cost of initial investment (I0 = 13.4 k€), reach at the twentieth year the higher value of CT (209.6 k€, higher than 2.33 times the lighting system with LED and 1.75 times lighting system with FL). This behavior is caused by the high operating cost, due to high energy consumption, and the high maintenance cost.
The lighting system with LED is characterized by the maximum value of the initial cost (I0 = 36.9 k€) and the related trend of CT has a weak inclination from the horizontal axis, due to the reduced operating and maintenance costs. For this reason, the total management cost is the lowest among all (CT = 97.5 k€). The lighting system with FL has an intermediate trend and reach, at the twentieth year, a total management cost higher than the lighting solution with LED. With reference to the total management cost of the solution with MH, the lighting system with LED allows a simple payback time (PBT) of the higher initial investment cost, equal to 3.5 years, while the lighting system with FL allows a PBT of 1.7 years (see Figure 2).
In Figure 3, for an immediate comparison of the obtained results, CT values reached at twentieth year are reported for different scenarios, both in the case of realization of the lighting system by own funds and in the case of bank financing.
From the Figure 3 it is possible to notice that the lighting system with MH, in all the analyzed cases and for all the considered scenarios, has the highest values of CT and therefore a low economic sustainability. More difficult is the comparison between the lighting systems with LED and FL. Despite the clear differences in energy consumptions (see Table 5), the CT values, reached at twentieth year, of these two lighting systems does not present, for all the scenarios, economical differences with significant relevance, because the lighting system with LED has the lower operating and maintenance costs, but also an higher initial investment cost.
It is important to point out that the greater difference between the values of CT for lighting systems with MH and with LED is reached in the Scenario 1, which provides for the maximum use of the lighting systems. Obviously, increasing the exploitation of the artificial lighting (in terms of the product between the number of luminaires switched-on and the usage time), the lower operating and maintenance costs have a more significant influence on the value of CT. Higher is the use of the sports hall and more attractive is the use of a lighting system with LED.

4.2. Economic Analysis of the Refurbishment of the Lighting System in an Existing Sports Hall

In this section, the refurbishment of the lighting system in an existing sports hall is analyzed. Therefore, in addition to the initial investment, the operating and the maintenance costs, the benefits that can be achieved through the refurbishment of the system are taken into consideration from the economic point of view. The expected benefits were assessed in terms economic benefit for the electrical energy saving (Bo) during the analyzed period and for the different maintenance associated with the different type of lamps (Bm). For each evaluation, there are both the incoming and outgoing cash flows and it is possible to calculate the payback time (PBT) and the net present value (NPV) [38]. The intervention of refurbishment is sustainable when NPV has positive values during the analyzed period. The following were considered: refurbishment of MH with LED (MH-LED), refurbishment of FL with LED (FL-LED), refurbishment of MH with FL (MH-FL).
The evaluations are carried out on the lighting systems able to meet the minimum lighting requirements fixed by the technical standards (see Table 1). The economic analysis has carried out considering the 6 operating scenarios (see Section 4, Table 4) and a reference period equal to 20 years. Table 6 shows the results obtained for the considered economic parameters for each scenario.
In Figure 4, the trend of NPV in function of the time is shown, in the case of the refurbishment of MH with LED, realized with an investment by own funds. The economic benefit, linked to the refurbishment, is higher as much as the value of NPV is higher. The time for which NPV = 0 corresponds to the PBT. In the specific case, it is possible to note that the PBT varies from a minimum of 6 years (scenario 1) to a maximum of 16.5 years (scenario 6). The refurbishment of MH with LED is always profitable for each analyzed scenario, because the NPV value always assumes a positive value at twentieth year.
In Figure 5, for in an immediate comparison of the obtained results, NPV values reached at twentieth year are reported for the different scenarios. In Figure 5, it can be observed that the replacement of MH with LED can always be economically viable. The maximum benefit is achieved for the scenario 1, when the sports hall and the lighting system are exploited intensively (see Section 4). For this scenario the reduced installed power of the LED, combined with their long life time, allows a significant reduction of the operating and maintenance costs, permitting to recover the initial investment cost in a short time and ensuring high benefits in economic terms (see also Figure 4, scenario 1). In contrast, the replacement of FL with LED does not reach, for any scenario, positive NPV values, therefore it is not a recommended solution from an economic point of view. If a discount rate of 4% (instead 2%) is considered, the same trends are obtained.
In Figure 6, NPV values reached in the twentieth year are reported for the replacement of MH floodlights with LED floodlights and with FL luminaires. From the observation of the Figure 6, it can be noticed that the replacement of MH floodlights with LED floodlights, despite a sharp drop in energy consumption, shows situations (see Scenario 6) for which NPV slightly exceeds the null value. The replacement of MH floodlights with FL luminaires, which are characterized by positive values of NPV for all the analyzed scenarios, shows NPV values higher than those obtained for the refurbishment with LED floodlights.

5. Conclusive Remarks

The recent European directives on energy efficiency and the resulting national regulations are leading to a gradual reduction of global energy consumption in buildings. The energy consumption for lighting is becoming increasingly important, especially in sports facilities. In recent years, the trend is to replace the traditional lighting luminaires with LED, which have a constant evolution of lighting features.
In this study, the authors analyze, from the techno-economic standpoint, different lighting solutions for the realization of new lighting systems and for the refurbishment of existing lighting systems in sports facilities, in order to guide the design choices. Different energy and economic analysis were carried out, considering the initial investments, the operating costs, the maintenance costs and the primary energy consumptions.
By techno-economic evaluations could be observed that the use of LED floodlights allows an immediate reduction of the primary energy consumptions for lighting.
In the case of the realization of the lighting system in a sports hall of new construction, the use of LED floodlights allows percentage reductions of the primary energy consumption till to 52% and to 32% if compared respectively to the use of MH floodlights and FL luminaires. The use of LED floodlights usually requires a smaller number of luminaires and it is characterized by limited maintenance cost compared to the other solutions, but it is characterized also by high investment cost, which involve reasonable payback times only when the sports facility is used intensively and for competitions of high level. Indeed, increasing the exploitation of the artificial lighting (in terms of the product between the number of luminaires switched-on and the usage time), the lower operating and maintenance costs of the LED have a more significant influence on the total management cost.
In the case of refurbishment of the lighting system in an existing sports hall, the replacement of MH floodlights with LED floodlights, despite a sharp drop in energy consumption, shows situations for which the net present value (NPV) slightly exceeds the null value. The replacement of MH floodlights with FL luminaires, which is characterized by positive values of NPV for all the analyzed scenarios, shows NPV values higher than those obtained for the refurbishment with LED floodlights.
In any case, the choice of the light sources and of the luminaires should always be preceded by detailed lighting evaluations (i.e., illuminance levels, glare phenomena, photobiological safety, health effects, etc.), in order to verify that all the lighting requirements, fixed by the technical standards, are satisfied.

Author Contributions

The authors contribute equally to this work. Fabio Fantozzi, Francesco Leccese, Giacomo Salvadori, Michele Rocca and Marco Garofalo conceived and designed the research activity, performed the analytical calculations, analyzed the results, wrote the paper.

Conflicts of Interest

The authors declare no conflict of interest.

References

  1. Prins, R.G.; Mohnen, S.M.; van Lenthe, F.J.; Brug, J.; Oenema, A. Are neighbourhood social capital and availability of sports facilities related to sports participation among Dutch adolescents? Int. J. Behav. Nutr. Phys. Activ. 2012, 9. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  2. Fried, G. Managing Sport Facilities, 3rd ed.; Human Kinetics: Champaign, IL, USA, 2015; pp. 1–440. [Google Scholar]
  3. Kozma, G.; Pénzes, J.; Molnár, E. Spatial development of sports facilities in Hungarian cities of county rank. Bull. Geogr. Socio-econ. Ser. 2016, 31, 37–44. [Google Scholar]
  4. Barghchi, M.; Bt Omar, D.; Aman, M.S.; Ling, H.L.O.; Marzukhi, M.A. Sports facilities development: A case study of Malaysia. In Proceedings of the ISBEIA—IEEE Symposium on Business, Engineering and Industrial Applications, Langkawi, Malaysia, 25–28 September 2011; pp. 426–430.
  5. Rafossa, K.; Troelsenb, J. Sports facilities for all? The financing, distribution and use of sports facilities in Scandinavian countries. Sport Soc. Cult. Commer. Media Politics 2010, 13, 643–656. [Google Scholar] [CrossRef]
  6. Harger, K.; Humphreys, B.R.; Ross, A. Do New Sports Facilities Attract New Businesses? J. Sports Econ. 2016, 17, 483–500. [Google Scholar] [CrossRef]
  7. ISTAT; CONI; ICS. Census of Sports Facilities in 1989; ISTAT: Rome, Italy, 1991. [Google Scholar]
  8. National Council for Economy and Labour. The Situation of Sports Facilities in Italy to 2003; National Council for Economy and Labour: Rome, Italy, 2005. [Google Scholar]
  9. Fantozzi, F.; Leccese, F.; Salvadori, G.; Rocca, M.; Capranelli, I. Opportunities for Energy Savings with Interventions on the Lighting Systems of Historical Buildings (The Case of “Palazzo Medici” in Pisa, Italy). In Proceedings of the 17th IEEE International Conference on Environment and Electrical Engineering, Florence, Italy, 6–8 June 2016; pp. 1076–1081.
  10. Artuso, P.; Santangeli, A. Energy solutions for sports facilities. Intern. J. Hydrog. Energy 2008, 33, 3182–3187. [Google Scholar] [CrossRef]
  11. El-Kadi, A.E.-W.M.A.; Fanny, M.A. Architectural designs and thermal performances of school sports-hall. Appl. Energy 2003, 76, 289–303. [Google Scholar] [CrossRef]
  12. Trianti-Stourna, E.; Spyropoulou, K.; Theofylaktos, C.; Droutsa, K.; Balaras, C.A.; Santamouris, M.; Asimakopoulos, D.N.; Lazaropoulou, G.; Papanikolaou, N. Energy conservation strategies for sports centers: Part A. Sports Hall. Energy Build. 1998, 27, 109–122. [Google Scholar] [CrossRef]
  13. Trianti-Stourna, E.; Spyropoulou, K.; Theofylaktos, C.; Droutsa, K.; Balaras, C.A.; Santamouris, M.; Asimakopoulos, D.N.; Lazaropoulou, G.; Papanikolaou, N. Energy conservation strategies for sports centers: Part B. Swimming Pools. Energy Build. 1998, 27, 123–135. [Google Scholar] [CrossRef]
  14. Beuskera, E.; Stoya, C.; Pollalisb, S.N. Estimation model and benchmarks for heating energy consumption of schools and sport facilities in Germany. Build. Environ. 2012, 49, 324–335. [Google Scholar] [CrossRef]
  15. Boussabaine, A.H. A comparative approach for modelling the cost of energy in sport facilities. Facilities 2001, 19, 194–203. [Google Scholar] [CrossRef]
  16. Asdrubali, F.; Baldinelli, G.; Bianchi, F.; Sambuco, S. A comparison between environmental sustainability rating systems LEED and ITACA for residential buildings. Build. Environ. 2015, 86, 98–108. [Google Scholar] [CrossRef]
  17. European Committee for Standardization. EN 12193, Light and Lighting—Sports Lighting; European Committee for Standardization: Brussels, Belgium, 2007. [Google Scholar]
  18. Italian National Olympic Committee. CONI Regulations for Sports Facilities; Italian National Olympic Committee: Rome, Italy, 2008; Available online: http://www.coni.it/it/impianti/norme-e-regolamenti.html (accessed on 15 March 2016). (In Italian)
  19. Sports Facilities. Light solutions that inspire. Available online: http://www.osram.com/sport (accessed on 18 May 2016).
  20. Khan, N.; Abas, N. Comparative study of energy saving light sources. Renew. Sustain. Energy Rev. 2011, 15, 296–309. [Google Scholar] [CrossRef]
  21. Aman, M.M.; Jasmona, G.B.; Mokhlisa, H.; Bakarb, A.H.A. Analysis of the performance of domestic lighting lamps. Energy Policy 2013, 52, 482–500. [Google Scholar] [CrossRef]
  22. Gana, C.K.; Sapara, A.F.; Muna, Y.C.; Chongb, K.E. Techno-Economic Analysis of LED Lighting: A Case Study in UTeM’s Faculty Building. Procedia Eng. 2013, 53, 208–216. [Google Scholar] [CrossRef]
  23. Leccese, F.; Vandelanotte, V.; Salvadori, G.; Rocca, M. Blue light hazard and risk group classification of 8 W LED tubes, replacing fluorescent tubes, through optical radiation measurements. Sustainability 2015, 7, 13454–13468. [Google Scholar] [CrossRef]
  24. Bisegna, F.; Burattini, C.; Li Rosi, O.; Blaso, L.; Fumagalli, S. Non visual effects of light: An overview and an Italian experience. Energy Procedia 2015, 78, 723–728. [Google Scholar]
  25. Ferlazzo, F.; Piccardi, L.; Burattini, C.; Barbalace, M.; Giannini, A.M.; Bisegna, F. Effects of new light sources on task switching and mental rotation performance. J. Environ. Psychol. 2014, 39, 92–100. [Google Scholar] [CrossRef]
  26. Leccese, F.; Salvadori, G.; Casini, M.; Bertozzi, M. Lighting of indoor work places: Risk assessment procedure. WIT Trans. Inform. Commun. Technol. 2012, 44, 89–101. [Google Scholar]
  27. Leccese, F.; Corucci, T.; Salvadori, G.; Rocca, M.; Vandelanotte, V. Evaluation of optical radiation emissions by a measurement campaign on LED sources for general lighting. In Proceedings of the 16 IEEE International Conference on Environment and Electrical Engineering, Rome, Italy, 10–13 June 2015; pp. 689–694.
  28. Berlov, D.N.; Baranova, T.I.; Bisegna, F.; Pavlova, L.P.; Aladov, A.V.; Zakgeim, A.L.; Mizerov, M.N.; Chiligina, Y.A. Research perspectives of the influence of lighting modes on changes of human functional state by means of ‘smart lighting’. In Proceedings of the 16 IEEE International Conference on Environment and Electrical Engineering, Rome, Italy, 10–13 June 2015; pp. 1426–1430.
  29. Leccese, F.; Salvadori, G.; Casini, M.; Bertozzi, M. Analysis and measurements of artificial optical radiation (AOR) emitted by lighting sources found in offices. Sustainability 2014, 6, 5941–5954. [Google Scholar] [CrossRef]
  30. Bonner, R.; O’Hagan, J.B.; Khazova, M. Assessment of personal exposures to optical radiation in large entertainment venues. Radiat. Prot. Dosim. 2012, 149, 225–237. [Google Scholar] [CrossRef] [PubMed]
  31. Italian Volleyball Federation. Game Rules for 2015–2016; Italian Volleyball Federation: Rome, Italy, 2014; Available online: http://www.federvolley.it/CMS/upload/Regole_di_Gioco_2015_16(3).pdf (accessed on 15 March 2016). (In Italian)
  32. Italian Basketball Federation. Sports Facilities Regulation Where Basketball Is Practiced; Italian Basketball Federation: Rome, Italy, 2015; Available online: http://www.fip.it/public/statuto/regolamento%20impianti%20sportivi%20ultimo%202015.pdf (accessed on 15 March 2016). (In Italian)
  33. Italian Tennis Federation. Rules of Tennis; Italian Tennis Federation: Rome, Italy, 2016; Available online: http://www.federtennis.it/PDF/REGOLE%20DI%20TENNIS.pdf (accessed on 15 March 2016). (In Italian)
  34. International Commission on illumination (CIE). CIE 97, Technical Report—Guide on the Maintenance of Indoor Electric Lighting Systems; CIE: Vienna, Austria, 2005. [Google Scholar]
  35. Il Sole 24 Ore, Observatory rate. Available online: http://mutuionline.24oreborsaonline.ilsole24ore.com (accessed on 15 March 2016).
  36. Italian Regulation Authority for Electricity Gas and Water. Economic Conditions for Customers in the Protected Market. Available online: http://www.autorita.energia.it/it/dati/condec.htm (accessed on 15 March 2016). (In Italian)
  37. US Department of Energy—Office of energy efficiency and renewable energy. PNNL-SA-97534, Building Technologies Program—Solid State Lighting Technology Fact Sheet—Lifetime and Reliability; US Department of Energy: Washington, DC, USA, 2013. Available online: ssl.energy.gov (accessed on 15 June 2016).
  38. Dall’O’, G. Operating Instructions for the Energy and Environmental Audits of Buildings, 1st ed.; Edizioni Ambiente: Milano, Italy, 2011; pp. 299–313. [Google Scholar]
  39. European Committee for Standardization. EN 15193, Energy Performance of Buildings—Energy Requirements for Lighting; European Committee for Standardization: Brussels, Belgium, 2007. [Google Scholar]
  40. Italian Regulatory Authority for Electricity Gas and Water. Resolution EEN 3/08 Official Gazette of the Italian Republic. No. 100 of 29 April 2008. Available online: http://www.autorita.energia.it/it/docs/08/003-08een.htm (accessed on 15 March 2016). (In Italian)
  41. Ministry of Economic Development. Circular Energy Manager 14 December 2014 rev.; Ministry of Economic Development: Rome, Italy, 2014.
Sustainability 08 00618 g001 1024
Figure 1. Examples of Italian sports halls, built with an arch structure covered by membrane: (a) sports hall in Bologna; (b) sports hall in Barbianello (Pavia District); (c) sports hall in Ponsacco (Pisa District); (d) sports hall in Villafranca (Verona District); (e) sports hall in Millesimo (Savona District); (f) 3D view of the case study sports hall in Pisa (see also Section 3).
Figure 1. Examples of Italian sports halls, built with an arch structure covered by membrane: (a) sports hall in Bologna; (b) sports hall in Barbianello (Pavia District); (c) sports hall in Ponsacco (Pisa District); (d) sports hall in Villafranca (Verona District); (e) sports hall in Millesimo (Savona District); (f) 3D view of the case study sports hall in Pisa (see also Section 3).
Sustainability 08 00618 g001
Sustainability 08 00618 g002 1024
Figure 2. Trend of CT discounted values in function of time, for lighting systems with different luminaires: results of scenario 1.
Figure 2. Trend of CT discounted values in function of time, for lighting systems with different luminaires: results of scenario 1.
Sustainability 08 00618 g002
Sustainability 08 00618 g003 1024
Figure 3. Comparison between the CT values, reached at twentieth year.
Figure 3. Comparison between the CT values, reached at twentieth year.
Sustainability 08 00618 g003
Sustainability 08 00618 g004 1024
Figure 4. Evaluation of MH Floodlights replacement with LED Floodlights: trends of NPV in function of the time (investment by own founds, r = 2%).
Figure 4. Evaluation of MH Floodlights replacement with LED Floodlights: trends of NPV in function of the time (investment by own founds, r = 2%).
Sustainability 08 00618 g004
Sustainability 08 00618 g005 1024
Figure 5. NPV values for MH floodlights and FL luminaires replacement with LED floodlight (investment by own founds, r = 2%).
Figure 5. NPV values for MH floodlights and FL luminaires replacement with LED floodlight (investment by own founds, r = 2%).
Sustainability 08 00618 g005
Sustainability 08 00618 g006 1024
Figure 6. NPV values obtained for different MH floodlights replacement.
Figure 6. NPV values obtained for different MH floodlights replacement.
Sustainability 08 00618 g006
Table
Table 1. Lighting requirements for indoor sports facilities according to different lighting classes and to different sports [17].
Table 1. Lighting requirements for indoor sports facilities according to different lighting classes and to different sports [17].
Lighting Requirements 1
Volleyball-BasketballTennis
LCEm (lx)U0RaUGRlimEm (lx)U0RaUGRlim
I7500.7060227500.706022
II5000.7060225000.706022
III2000.5020223000.502022
1 Playing fields of the following dimensions (width × length): 15 m × 28 m for Volleyball, 15 m × 24 m for Basketball, 18 m × 36 m for Tennis.
Table
Table 2. Main technical features of the considered luminaires (data declared by the manufacturers).
Table 2. Main technical features of the considered luminaires (data declared by the manufacturers).
LuminairesMHFLLED
Sustainability 08 00618 i001 Sustainability 08 00618 i002 Sustainability 08 00618 i003
Type of LampsMetal HalideFluorescentLED
Numbers of Lamps1420
Electrical input power (W)428340284
Optical efficiency (%)719697
Single Lamp Properties
Electrical nominal power (W)4008014.2
Luminous Flux (klm)35.06.81.5
Color Temperature (K)550040004000
Color Rendering Index928080
Lamp survival factor0.83 *0.90 **0.90 ***
Lamp lumen maintenance factor0.99 *0.99 **1.00 ***
* evaluated at 2000 h; ** evaluated at 12,000 h; *** evaluated at 40,000 h.
Table
Table 3. Lighting system configurations: summary of the results obtained from the simulations.
Table 3. Lighting system configurations: summary of the results obtained from the simulations.
SportLCLighting System Configuration 1
MHFLLED
N (-)P (kW)Em (lx)U0 (-)N (-)P (kW)Em (lx)U0 (-)N (-)P (kW)Em (lx)U0 (-)
VolleyballI3615.47520.933210.97670.76288.07700.86
II2410.35400.78248.25020.82205.75530.90
III166.83300.79165.43300.84123.43040.71
BasketballI4017.17840.833612.27640.78288.07710.83
II2410.35330.79289.55240.83205.75470.90
III166.83290.81165.43170.86123.43100.77
TennisI4017.17550.774013.67520.73288.07510.84
II2410.35400.71289.55050.78205.75290.82
III166.83110.71165.43000.78123.43090.72
1 For all the system configurations, the following maintenance factors (MF) have been considered, according to the calculation method described in International Commission on illumination (CIE) [34]: MF = 0.7 for MH, MF = 0.8 for FL, MF = 0.8 for LED. For the calculation the following assumptions have been done: clean environment, elapsed time between cleanings of the lamps equal to 0.5 years, technical data about the lamp survival and lamp lumen maintenance factor provided by the manufacturers.
Table
Table 4. Definition of the lighting scenarios in function of the usage times of the sports hall.
Table 4. Definition of the lighting scenarios in function of the usage times of the sports hall.
ScenarioAnnual Usage Time for Each LC (h)
LC ILC IILC IIITotal
12000--2000
2--2000
3 2001800
42001800-
5200-1800
6701301800
Table
Table 5. Calculation results: evaluated technical and economical parameters in function of the Scenario for different luminaires.
Table 5. Calculation results: evaluated technical and economical parameters in function of the Scenario for different luminaires.
ScenarioLuminaireI0 (€)Co (€/year)Cm *Cm,n (€/year)toe (toe/year)
1MH13,3716115375737576.2
FL22,166448232405404.6
LED36,892291136892642.9
2MH53482508150315032.6
FL8865199212962162.0
LED15,811124815811131.3
3MH13,3712726150315033.1
FL22,166216812962162.2
LED36,892136026351881.5
* FL: €/6 years; MH: €/year; LED: €/10 years.
Table
Table 6. Calculation results: evaluated technical and economical parameters in function of the Scenario for different luminaires.
Table 6. Calculation results: evaluated technical and economical parameters in function of the Scenario for different luminaires.
ScenarioLuminairesI0 (€)Co (€/year)Cm *Cm,n (€/year)Bo (€/year)Bm **
1MH-LED36,8922911368926461323757
FL-LED36,8922911368926444943240
MH-FL22,1644494324054061323757
2MH-LED15,8111248158111325151503
FL-LED15,8111248158111319971296
MH-FL88651997129621625151503
3MH-LED26,3521335263518826561503
FL-LED26,3521335263518821341296
MH-FL15,5152134129621626561503
4MH-LED36,8922169368926441492630
FL-LED36,8922169368926434832268
MH-FL22,1643483226837841492630
5MH-LED36,8921418368926428772630
FL-LED36,8921418368926422471296
MH-FL22,1642247129621628772630
6MH-LED36,8921360368926427331503
FL-LED36,8921360368926421741296
MH-FL22,1642174129621627331503
* MH-LED: €/10 year; FL-LED: €/10 years; MH-FL: €/6 year; ** MH-LED: €/year; FL-LED: €/6 years; MH-FL: €/year.

Share and Cite

MDPI and ACS Style

Fantozzi, F.; Leccese, F.; Salvadori, G.; Rocca, M.; Garofalo, M. LED Lighting for Indoor Sports Facilities: Can Its Use Be Considered as Sustainable Solution from a Techno-Economic Standpoint? Sustainability 2016, 8, 618. https://doi.org/10.3390/su8070618

AMA Style

Fantozzi F, Leccese F, Salvadori G, Rocca M, Garofalo M. LED Lighting for Indoor Sports Facilities: Can Its Use Be Considered as Sustainable Solution from a Techno-Economic Standpoint? Sustainability. 2016; 8(7):618. https://doi.org/10.3390/su8070618

Chicago/Turabian Style

Fantozzi, Fabio, Francesco Leccese, Giacomo Salvadori, Michele Rocca, and Marco Garofalo. 2016. "LED Lighting for Indoor Sports Facilities: Can Its Use Be Considered as Sustainable Solution from a Techno-Economic Standpoint?" Sustainability 8, no. 7: 618. https://doi.org/10.3390/su8070618

APA Style

Fantozzi, F., Leccese, F., Salvadori, G., Rocca, M., & Garofalo, M. (2016). LED Lighting for Indoor Sports Facilities: Can Its Use Be Considered as Sustainable Solution from a Techno-Economic Standpoint? Sustainability, 8(7), 618. https://doi.org/10.3390/su8070618

Note that from the first issue of 2016, this journal uses article numbers instead of page numbers. See further details here.

Article Metrics

Back to TopTop