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Alotaibi, B.S.; Khalifa, K.R.M.; Abuhussain, M.A.; Dodo, Y.A.; Alshenaifi, M.; Yahuza, M.S.; Algamadi, M.; Al-Tamimi, N.; Maghrabi, A.; Abba, S.I. Renewable-Based Solar Energy of Cyprus and Saudi Arabia. Encyclopedia. Available online: https://encyclopedia.pub/entry/51243 (accessed on 03 July 2024).
Alotaibi BS, Khalifa KRM, Abuhussain MA, Dodo YA, Alshenaifi M, Yahuza MS, et al. Renewable-Based Solar Energy of Cyprus and Saudi Arabia. Encyclopedia. Available at: https://encyclopedia.pub/entry/51243. Accessed July 03, 2024.
Alotaibi, Badr Saad, Khaled Ramah Mohammed Khalifa, Mohammed Awad Abuhussain, Yakubu Aminu Dodo, Mohammad Alshenaifi, Mukhtar Sabiu Yahuza, Mohammed Algamadi, Nedhal Al-Tamimi, Ammar Maghrabi, Sani. I. Abba. "Renewable-Based Solar Energy of Cyprus and Saudi Arabia" Encyclopedia, https://encyclopedia.pub/entry/51243 (accessed July 03, 2024).
Alotaibi, B.S., Khalifa, K.R.M., Abuhussain, M.A., Dodo, Y.A., Alshenaifi, M., Yahuza, M.S., Algamadi, M., Al-Tamimi, N., Maghrabi, A., & Abba, S.I. (2023, November 07). Renewable-Based Solar Energy of Cyprus and Saudi Arabia. In Encyclopedia. https://encyclopedia.pub/entry/51243
Alotaibi, Badr Saad, et al. "Renewable-Based Solar Energy of Cyprus and Saudi Arabia." Encyclopedia. Web. 07 November, 2023.
Renewable-Based Solar Energy of Cyprus and Saudi Arabia
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This entry is adapted from the peer-reviewed paper 10.3390/pr11102887

The use of solar energy as an alternative source of energy is a natural reflection of technological progress to meet the growing needs of modern life applications. Since solar energy is a relatively new scientific field, specialized research centers have been established to conduct theoretical and applied experiments and to employ the various available resources in order to achieve the desired goal of renewable energy sources in their various uses.

solar energy urban furniture Dr. Fazil Kucuk Park Nicosia

1. Introduction

The use of solar energy as an alternative source of energy is a natural reflection of technological progress to meet the growing needs of modern life applications. Since solar energy is a relatively new scientific field, specialized research centers have been established to conduct theoretical and applied experiments and to employ the various available resources in order to achieve the desired goal of renewable energy sources in their various uses [1]. The incorporation and use of solar energy in urban furniture is a sustainable and innovative approach to urban design and can reduce the carbon footprint and environmental impact of urban furniture, while offering benefits that are cost-effective, practical, and aesthetic [2]. This has helped in the development of viable and environmentally friendly technologies in this field, and the development of these sources is of strategic importance for any country.
Cyprus is one of the countries that is exposed to large amounts of solar radiation for long hours throughout the year, and the abundance of solar energy in Cyprus imposes the idea of using the sun as a source of electrical energy. Therefore, a study was initiated to examine the possibility of relying more on natural energy sources as an alternative to commercial sources. Humans interact with the surrounding environment in terms of functionality and aesthetics, and one of these environmental elements is urban furniture, which needs to keep up with modern technology and keep an eye on the latest technological developments in both design and function [3]. Hence, the research problem arose by asking: What is the role of solar energy and its relationship to urban furniture?
The importance of the research lies in relying on a source of energy that is available all over the world, especially in Cyprus, which enjoys bright sunshine for long periods of time, which can be a benefit. Also, delving into such a topic contributes to creating a knowledge base on the possibility of using solar energy in urban furniture.

2. Solar Energy and Urban Furniture

The solar system consists of two main components that work as one unit to generate electrical energy: the solar panels and the supporting system. The solar panels consist of a number of parts, solar modules that contain a group of solar cells, while the specifications vary for the supporting system according to the requirements of the loads and the requirements of the methods of connecting the systems. The two fundamental components of a solar system are as follows:
Solar panels: There are several solar modules in it, and the solar cells. It is the tiniest component of the whole.
The support system: It includes a charger, an energy reservoir, a power inverter, a supporting structure, and the cables that connect them.
As cities try to lessen their dependency on fossil fuels and implement solar energy, it is playing a bigger role in urban furniture thanks to more ecological practices. Cities can use renewable energy by incorporating solar panels into exterior fixtures like benches, trash cans, and streetlights [4]. Urban furniture driven by sunlight can assist lower energy expenses over time, which is one of its main advantages. For instance, a study by [5] discovered that a bus stop powered by solar can save up to 40% on power expenses compared to conventional bus stops. Similarly, solar-powered streetlights can provide reliable and sustainable lighting for urban areas while also reducing carbon emissions [4]. Additionally, solar-powered urban pieces of furniture could offer a number of other advantages, such as offering electrical device charging stations or decreasing waste using solar-powered garbage compactors [6]. Moreover, a lot of localities provide grants and rewards for renewable energy projects, which could help with the upfront cost of installing solar-powered urban furniture (see Figure 1).
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Figure 1. The general parts of the solar system [7].

3. Integrating Solar Energy in Urban Furniture Elements

As a renewable energy source for urban furniture, solar energy is gaining popularity. This is because solar panels may be incorporated into many types of urban furniture designs, such as streetlights and benches, to offer a source of sustainable and clean energy [8]. Urban furniture that uses solar energy may function without using conventional energy sources, lowering greenhouse gas emissions and the total carbon footprint of cities [9]. Additionally, outdoor lighting and charging stations may be made more affordable and low-maintenance by using solar-powered urban furniture. A complete collection of solar-powered urban furniture initiatives was acquired after a thorough analysis of the literature, which included books, newspaper articles, conference papers, and websites. This collection is a useful tool for creating a basic classification scheme for different types of urban furniture that may be created and incorporated using solar technology. Examples of solar-powered urban furniture that may be included and created in public parks include the following.

3.1. Solar Lighting

Solar lighting is a form of lighting that illuminates outdoor areas by harnessing the energy of the sun. Solar lighting has greatly increased in popularity over the past several years due to the rising demand for environmentally friendly and energy-efficient lighting. In addition to having financial advantages, solar illumination has major environmental advantages. Solar illumination may help lessen carbon impact by employing natural light, an emission-free and endlessly renewable resource [10]. Solar illumination may be installed with little physical disruption because it does not need to be connected to the electricity grid, making it perfect for ecologically sensitive areas, parks, and holy places [11].
There are several types of solar lighting systems. These include:
Solar garden lights: These are small, decorative lights that are used to light up pathways, flower beds, and other outdoor spaces (see Figure 2c).
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Figure 2. Various uses of solar lighting in public places. (a) Solar path lights [12]. (b) Solar flood lights [13]. (c) Solar garden lights [14]. (d) Solar spotlights [15]. Source: [16].
Solar path lights: Solar path lights are larger light fixtures designed to illuminate pathways and green spaces. Usually mounted on poles, these lights are equipped with a light-time-control sensor, allowing them to automatically adjust lighting based on environmental conditions (see Figure 2a).
Solar flood lights: These are powerful lights that are used to light up large areas, such as sports fields, parking lots, and construction sites (see Figure 2b).
Solar spotlights: These are small, powerful lights that are used to highlight specific areas, such as trees, statues, or buildings (see Figure 2d).

3.2. Solar Public Art

The use of solar energy in artwork is an innovative and exciting way to incorporate sustainability and environmental awareness into artistic expression. Solar energy has been utilized for centuries as a source of inspiration for artists, but with the advent of modern solar technology, artists have been able to incorporate this renewable energy source into their work in new and exciting ways. One example of urban furniture that utilizes a renewable energy source, specifically solar energy, is the Love Solar Tree Ross, designed by Ross Lovegrove and produced by Artemide (see Figure 3a–d). This solar tree was showcased during a design week in front of MAK, a contemporary art museum in Vienna that operates on solar energy. The solar energy is harvested from a photovoltaic system and used to power LED lighting, with the goal of reducing environmental impact ([17]. Additionally, a hypothetical solar-powered project is the “Mango” design by [18] Adam Miklosi, (2012) which took inspiration from India’s heavy monsoon rains and brilliant sunlight. This architectural idea intends to capture and use rainfall for drainage while also capturing solar energy through leaves like those on a mango tree [17].
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Figure 3. Some examples of public art using solar garden light. (a) Solar Tree-Ross [19]. (b) Public art decorative solar street lamps [14]. (c) Mango leaf—Adam Miklosi [18]. (d) Solar sculpture [20].

3.3. Solar Benches

A creative way to use solar power in public spaces is to include it in the seating. Solar-powered furniture can offer a practical and environmentally friendly way for users to access Wi-Fi or charge their devices while also offering a relaxing place to sit. Strong solar charging stations called ConnecTables are appropriate for both commercial and domestic use in public areas, including college campuses, office buildings, outdoors shopping malls, and theme parks. These places of charging can be linked together to form a mini-grid that can supply power during protracted power outages (see Figure 4a–d). Each model features two solar panels with a minimum output of 250 watts each, each of which may provide up to 500 watts of energy. In bad weather, ConnecTables require little upkeep, and their electrical parts are completely enclosed to provide user security and vandalism defense. In addition to being made of stainless steel, it has an architectural design [21].
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Figure 4. Integration of solar panels in the seating. (a) Wi-Fi-enabled charger smart benches: solar-powered bench [22]. (b) Tennessee University solar picnic bench [23]. (c) Street furniture, urban furniture, bench designs [24]. (d) Solar tree development in Israel [25].

3.4. Solar Rubbish Bins

Photovoltaic (PV) panels convert sunshine into power, which is then stored in batteries, to power solar-powered garbage cans. The internal compactor of the garbage-collecting can is then fueled by the previously conserved energy. The garbage gets compressed in the can, as a result lowering its volume and enabling it to hold more rubbish. There are various advantages to using solar energy in trash cans. First, since there is no longer a need for rubbish to be transported (see Figure 5a,b), it reduces the carbon impact of rubbish collection by using trucks driven by diesel instead of gasoline. Second, it lessens the frequency of garbage collection because more waste may be held in a given volume thanks to compaction. As a result, fewer trucks are required for waste collection, which lowers the price of transportation. The compacting of the debris inhibits the wind from dispersing it around the area, which can assist curb littering [26].
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Figure 5. Sophisticated, solar-powered trash compactors compress garbage. (a) RAY solar-powered waste compactor bin. Source: [6]. (b) Solar energy street outdoor sensor dustbin advertising smart bin [27].

3.5. Solar Billboard

Solar-powered billboards for outdoor advertising use solar energy to power their lighting and display systems, making them sustainable and environmentally friendly. They operate by generating electricity from solar panels, which lowers the energy expenses and carbon footprint of the businesses that use them [28]. As a result, sunlight billboards are gaining popularity among companies looking for more eco-friendly and economical advertising strategies. Solar billboards have the benefit of being accessible in places where conventional billboards might not be possible owing to a lack of availability of electricity, as well as to being ecologically beneficial. They also require less upkeep than conventional billboards because they do not require constant replacement of their light bulbs or connection to a power source (see Figure 6).
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Figure 6. Solar billboard. (a) [29]. (b) [30].

3.6. Solar Electric Bike Stations

An efficient strategy to encourage environmentally friendly transportation and lessen cities’ carbon footprint is to use solar electricity for bicycle parking [31]. Solar-powered bicycle parking structures can offer a source of renewable energy for illumination, security, and even electric bicycle charging stations [32]. Solar-powered bicycle parking can be less expensive and more environmentally friendly than standard parking structures that rely on grid electricity [33]. By generating their own energy, solar-powered bicycle parking facilities can reduce or eliminate electricity bills, making them a more financially feasible option in the long run [31]. Furthermore, the use of solar energy in bicycle parking can enhance the safety and convenience of cyclists. With solar-powered lighting and security systems, bicycle parking facilities can provide a safer environment for cyclists to park their bikes, particularly in areas with limited lighting or high crime rates [34] (see Figure 7a,b).
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Figure 7. Use of solar energy in bicycle parking. (a) Solar bikes [35]. (b) Small solar bike: [36].

3.7. Solar Pergola

A solar pergola is a solar-panel roof, used to cover a relaxation area in a park, which generates renewable energy in a novel method; it also provides a more seamless and different choice for implementing solar electricity while people relax under the pergola. This solar energy generated using the pergolas not only creates a lovely and useful outdoor living area, but the energy generated might also power some or all of the park, while reducing additional utility costs [37]. As a way to harness solar power and encourage sustainability, solar panels are being integrated into a wider range of structures. With their open framework design and aesthetic appeal, pergolas offer a great way to use solar power in park settings. Solar panels can be integrated into pergolas to capture sunlight and convert it into clean, renewable electricity, which lessens reliance on fossil fuels [38]. Pergolas with solar panels integrated offer practical benefits in parks in addition to their capacity to generate energy (see Figure 8a–c). They provide visitors to parks with shade and cover, improving the comfort and usability of outdoor spaces, especially in hot weather or during downpours. Additionally, the solar panels serve as a shield, protecting the pergola structure, and the amount of maintenance needed is decreased thanks to this protective function.
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Figure 8. Use of solar pergola in a park. (a) Solar roof [39]. (b) Pergola in India [40]. (c) Solar pergola in Portland [41].

3.8. Solar Water Fountain

A novel approach to encourage sustainability and improve the functionality of park environments is the incorporation of solar panels into water fountains. Water fountains with integrated solar panels provide a way to use the sun’s clean, renewable energy. These panels offer a sustainable power source for running water features by capturing sunlight and converting it into electricity [42]. The electricity produced can be used to run any additional water filtration or circulation systems, lighting systems, and fountain pumps. This integration lessens the park’s reliance on conventional grid electricity, improving the park’s overall environmental sustainability. Water fountains with solar panels integrated into them can look better and function better. Modern solar panels can be seamlessly integrated into fountain structures without detracting from their aesthetic appeal because they come in a variety of sizes and designs (see Figure 9a–c). Additionally, the flexibility in fountain placement within the park is provided by the ability to operate independently of electrical infrastructure, allowing for imaginative and intelligent design [42].
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Figure 9. Use of solar water fountains in a park. (a) LED ornamental solar power outdoor [15]. (b) Air pump [43]. (c) Solar panel water fountain [44].

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Subjects: Green & Sustainable Science & Technology
Contributors MDPI registered users' name will be linked to their SciProfiles pages. To register with us, please refer to https://encyclopedia.pub/register :
Badr Saad Alotaibi
,
Khaled Ramah Mohammed Khalifa
,
Mohammed Awad Abuhussain
,
Yakubu Aminu Dodo
,
Mohammad Alshenaifi
,
Mukhtar Sabiu Yahuza
,
Mohammed Algamadi
,
Nedhal Al-Tamimi
,
Ammar Maghrabi
,
Sani. I. Abba
View Times: 233
Revisions: 2 times (View History)
Update Date: 10 Nov 2023
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