Solar LED street light guide – watts, battery and panel
Solar LED street light guide – watts, battery and panel
Introduction
Street lighting is not one size fits all – from highways and expressways to local roads, alleys, crosswalks and even bike lanes, different types of roads have very different lighting requirements. But no matter the scenario, these types of streets need proper lighting to ensure the safety of those who use them. Solar LED street lights and AC street lights are the two main options. This article will focus on the main advantages of solar LED street lights in road lighting, and how to correctly choose the right solar LED street lights (check to find more ZGSM solar street lights) for your project. This requires you to understand the lighting and requirements of different types of streets, and how solar lighting can meet the lighting requirements of the corresponding roads. At the same time, we will also focus on the scientific configuration method of solar street light wattage and battery capacity.
Why go with solar LED street light?
Street lights can achieve fast, accurate and comfortable visibility at night, which is helpful in reducing nighttime traffic accidents, improving traffic flow, and promoting nighttime commercial activities and the use of public facilities. In recent years, the demand for street lights in the city has mainly shifted to solar LED street lights. ZGSM believes that the reason why solar LED street lights are widely used is precisely because of these three core advantages – efficient lighting, convenient installation, energy saving and environmental protection.
Solar street lights now mostly use LED as the light source, which is usually equipped with 220lm/W and higher LED chips, so the overall light efficiency can currently be close to 200lm/W. This allows solar LED street lights to illuminate the road with lower wattage. With reasonable light distribution (What’s light distribution?), we can achieve 50W or even lower wattage to achieve M2 lighting class for main road lighting. These characteristics make the application of solar LED street lights more extensive.
The installation of solar LED street lights does not rely on traditional power grids, so the installation of solar street lights saves the need for cable trench excavation, distribution cabinet installation and transformer installation, etc. This makes solar LED street lights have great potential for application in rural areas, mountainous areas, grasslands and islands with imperfect infrastructure. In addition, its installation cost can also be greatly reduced.
Solar street lights absorb solar energy through panels and store electricity in batteries through controllers, and power LED light sources at night, which makes solar LED street lights independent of traditional fossil fuels. Taking a 50W solar street light as an example, it can reduce 150kg CO₂ emissions per year (PS: Taking thermal power as an example, 1KWH of power generation has a carbon emission of 0.7KG). Such a huge reduction in emissions is of great significance to the protection of today’s increasingly deteriorating natural environment. The figure below shows the basic composition and working principle of solar energy.
Lighting requirement for your roadway lighting
Roads can be divided into different types according to their functions and design standards. Expressways are long-distance, high-speed inter-city or cross-regional traffic arteries. They are fully enclosed (no intersections) and have high speed limits (for example, 100-120 km/h in China). Expressways are fast passages within cities or suburbs. They are usually fully enclosed roads (or only a few intersections) and have high speed limits, usually 80-100 km/h. Urban main roads are the main traffic arteries in the city, connecting the centers of various regions. These roads are usually 4-8 lanes in two directions, with isolation islands in the middle, and speed limits of 60-80 km/h; secondary main roads assist trunk roads in diverting traffic, connecting residential areas, commercial areas, industrial areas and public service areas; branch roads are used for short-distance travel within residential/commercial areas, usually 2-3 lanes in two directions, and speed limits are usually 40 km/h; rural roads connect villages, houses and farmland, with relatively few vehicles, and speed limits are usually 30 km/h. These roads together form a complex transportation network between cities, between cities and rural areas, and within cities/rural areas.
Different roads have been introduced, so are the lighting requirements for different types of roads fixed? Normally, if the speed limit is fixed, the traffic volume, traffic composition, intersection density, the presence of parked vehicles and the ambient brightness are the same, the lighting requirements for the same road type are fixed. However, when there are different parameters, the lighting standards will also be different. For example, on both main city roads with speed limits of 80km/h and 60km/h, the lighting requirements for the former are higher than those for the latter, because the speed is faster and better lighting is needed to help the driver see the road conditions clearly. For example, for urban branch roads, the lighting requirements for roads where parking is allowed are higher than those for roads where parking is not allowed, because vehicles parked next to them will interfere with the driver’s ability to see the road conditions clearly, so better lighting is needed to reduce driving risks. So is there any way to help municipal departments determine lighting standards? The answer is yes, and EN13201-1(More details about EN13201 for street lighting design) provides a clear method.
The lighting standards involved in motor vehicle road lighting include brightness level (luminance) and uniformity, illumination level around the road and residual glare limit. If the project has clear requirements for these, the lighting design (lighting simulation) can be carried out according to these requirements. If there are no requirements, it can be selected by referring to the standard EN13201-1. At this time, the parameters we consider include: speed, traffic volume, traffic composition, lane separation, intersection density, parked vehicles, ambient brightness, difficulty of navigation task/visual guidance/traffic control. For example, for a road with a design speed of 80km/h, the weight value is 1. If traffic volume is high, then the weight value is 1. If the carriageway isn’t separated(without median island), then the weight value is 1. And the junction density is <3/km, then this weight value is 0. The road is without parked vehicles, then this weight value is 1. And for other weight value we supposed that they are all 0.
| Parameter | Options | Description | Weighting Value VW | ||
| Design speed or speed limit | Very high | v ≥ 100 km/h | 2 | ||
| High | 70 < v < 100 km/h | 1 | |||
| Moderate | 40 < v ≤ 70 km/h | -1 | |||
| Low | v ≤ 40 km/h | -2 | |||
| Traffic volume | Motorways, multilane routes | Two lane routes | |||
| High | > 65 % of maximum capacity | > 45 % of maximum capacity | 1 | ||
| Moderate | 35 % – 65 % of maximum capacity | 15 % – 45 % of maximum capacity | 0 | ||
| Low | < 35 % of maximum capacity | < 15 % of maximum capacity | -1 | ||
| Traffic composition | Mixed with high percentage of non-motorised | 2 | |||
| Mixed | 1 | ||||
| Motorised only | 0 | ||||
| Separation of carriageway | No | 1 | |||
| Yes | 0 | ||||
| Junction density | Intersection/km | Interchanges, distance between bridges, km | |||
| High | > 3 | < 3 | 1 | ||
| Moderate | ≤ 3 | ≥ 3 | 0 | ||
| Parked vehicles | Present | 1 | |||
| Not present | 0 | ||||
| Ambient luminosity | High | shopping windows, advertisement expressions, sport fields, station areas, storage areas | 1 | ||
| Moderate | normal situation | 0 | |||
| Low | -1 | ||||
| Navigational task | Very difficult | 2 | |||
| Difficult | 1 | ||||
| Easy | 0 | ||||