LED light

• Working principle of solar street lights using PIR sensors

  Jan 23, 2026

  PIR (Passive Infrared) sensors are a core energy-saving component for solar street lights, designed for low-traffic areas (sidewalks, rural lanes, park trails). They work by detecting the infrared radiation emitted by human/animal bodies (no active radiation output, hence "passive") and collaborating with the solar street light’s core control system (light control, charge-discharge controller) to achieve the classic "dim light standby, full bright when motion detected, delayed dim after motion" mode.       This design maximizes battery energy utilization (saving 60%–80% power compared to constant bright mode) and prolongs the service life of batteries and LED lamps—the PIR sensor never works alone, it is fully integrated with light control (photoresistor) and the solar charge-discharge controller (the "brain" of the light), and all power is supplied by the solar battery (charged by the solar panel during the day).   Core Components of the PIR Solar Street Light System   The PIR function relies on the synergy of 5 key parts, with the PIR sensor module consisting of a dual-element infrared probe + Fresnel lens (the core of motion detection):   Solar panel: Converts sunlight into electricity to charge the lithium battery (LiFePO4 is the mainstream for solar street lights). Lithium battery: Stores electrical energy for night lighting. PIR sensor module: Dual-element probe + Fresnel lens + signal amplification circuit (detects human/animal motion). Solar charge-discharge controller: Integrates light control, PIR signal processing, power switching, and battery protection (the core of system coordination). LED light source: Realizes power switching (dim light/full bright).   Step-by-Step Working Principle   The entire working process is divided into Daytime Charging & PIR Dormancy and Night Lighting & PIR Motion Detection, with light control as the fundamental trigger switch (to avoid PIR misoperation during the day).   Phase 1: Daytime – Solar Charging + PIR Sensor Dormancy   When the ambient illuminance (sunlight) is higher than the preset light control threshold (50–100 lux, adjustable), the photoresistor in the controller sends a "daytime" signal to the main control chip. The controller cuts off the power supply to the LED light and PIR sensor module, putting the PIR sensor into deep dormancy (no power consumption, no motion detection) to avoid misoperation by sunlight, birds, or falling leaves. The solar panel converts sunlight into DC power, and the controller performs constant current/constant voltage charging for the lithium battery (with overcharge, overvoltage, and short-circuit protection) to store energy for night use.     Phase 2: Night – Light Control Trigger + PIR Standby (Dim Light Mode)   When the ambient illuminance drops to the night light control threshold (5–15 lux, adjustable, e.g., after sunset), the photoresistor sends a "nighttime" signal to the controller. The controller immediately activates the PIR sensor module (puts it into low-power standby detection) and supplies a small current to the LED light, making it enter dim light standby mode (10%–30% of the rated power, e.g., 10W for a 100W street light). This dim light provides basic safety illumination and ensures the PIR sensor is ready for detection. At this stage, the PIR sensor module is in low-power detection state (power consumption <1mA): the Fresnel lens focuses the ambient infrared radiation on the dual-element infrared probe, and the probe continuously collects the static infrared radiation of the surrounding environment (e.g., walls, trees, roads) as the "baseline signal".   Phase 3: Motion Detection – PIR Trigger + LED Full Bright   This is the core working step of the PIR sensor, relying on the infrared temperature difference and motion change between the human/animal body and the environment:   When a person/animal (with a body temperature of ~37℃ for humans) moves into the PIR detection range (5–15m, adjustable) and angle (120°–180°, adjustable), the Fresnel lens focuses their body infrared radiation (λ=8–14μm, the most sensitive band for PIR sensors) onto the dual-element probe. The dual-element probe detects a sudden change in infrared radiation intensity (the temperature of the human body is much higher than the ambient environment, forming a clear infrared temperature difference) and a spatial displacement signal (caused by movement). The probe converts this physical change into a weak electrical signal (μV level). The signal amplification circuit in the PIR module amplifies the weak electrical signal and sends a "motion detected" trigger signal to the solar charge-discharge controller. The controller immediately switches the LED power supply circuit, increasing the current to the rated full power (e.g., 100W) – the street light instantly turns to full bright for high-brightness illumination.       Phase 4: Motion Disappears – Delayed Full Bright + Restore Dim Light   To avoid frequent on/off of the street light (caused by short-term motion) and improve user experience, the PIR system has a customizable delay function:   When the person/animal moves out of the PIR detection range, the probe no longer detects infrared temperature difference and motion changes, and the trigger signal is cut off. The controller does not switch back to dim light immediately, but maintains LED full bright for a preset delay time (30s–5min, factory adjustable or on-site settable via the controller). After the delay time ends, the controller cuts the LED power supply current and restores the dim light standby mode, and the PIR sensor returns to low-power detection to wait for the next motion trigger.   Phase 5: Dawn – Light Control Shutdown + PIR Dormancy   When the ambient illuminance rises above the daytime light control threshold at dawn, the controller repeats Phase 1: cuts off power to the LED and PIR sensor, the PIR enters deep dormancy, and the solar panel resumes charging the battery—completing a full working cycle.   Key Design Features of PIR Sensors in Solar Street Lights (Anti-Misoperation & Customization)   Dual-element probe anti-misoperation: The dual-element design only responds to changing infrared signals (motion). Static heat sources (e.g., street lamps, hot water pipes, stationary animals) will not trigger the sensor, avoiding false full bright. Fresnel lens for wide detection: The lens focuses scattered infrared radiation onto the probe, expanding the detection range (5–15m) and angle (120°–180°), and ensures the sensor can detect motion even at an installation height of 3–6m (standard for solar street lights). All parameters adjustable: Detection range, detection angle, delay time, and dim light/full bright power ratio can all be set via the solar controller to adapt to different scenarios (e.g., shorten delay time in remote rural areas, expand detection range in community sidewalks). Time control superposition (optional): Mid-to-high-end models can superimpose time control with PIR: e.g., after 2 AM (lowest traffic), the dim light power is further reduced (5% of rated power) or the delay time is shortened (30s) to save more energy for the battery.   Core Advantages of This Design for Solar Street Lights   Maximize energy saving: Avoids constant full bright, significantly reduces battery power consumption, and ensures the street light can work continuously for 3–7 rainy days (a key selling point of solar street lights). Extend component life: Lower average working power reduces the heat generation of LED lamps and the discharge depth of lithium batteries, prolonging their service life. Low maintenance: PIR sensor modules have no moving parts, low power consumption, and high stability (service life >5 years), matching the overall service life of solar street lights. Cost-effective: PIR sensors are low-cost and easy to integrate into the solar controller, with no additional wiring required—suitable for mass application in low-traffic areas.       Typical Application Scenarios     PIR solar street lights are the first choice for areas with uneven and low pedestrian/vehicle flow, such as rural village roads, community footpaths, park trails, factory peripheral roads, sidewalks, and mountain roads. For high-traffic areas (municipal main roads, commercial blocks), PIR is usually replaced with microwave (radar) sensors (wider detection, anti-interference, suitable for vehicles and pedestrians).

  hot Tags : PIR sensors solar street lights solar street lights control Solar Street lights PIR Solar Street Light System solar panel street lights PIR Sensors in Solar Street Lights LED light solar street lighting solar street lights Working principle

  Read More
• 5 Key Factors to Consider Before Buying Solar Garden Street Lights

  Dec 11, 2025

  When purchasing solar garden street lights for international markets, balancing performance, durability, compliance, and cost-effectiveness is critical. Below are the 5 key factors tailored to global sales, project deployment, and end-user needs, with professional insights to support your business decisions:       1. Solar Panel & Battery System: Core Power Reliability The energy storage system directly determines the light’s performance and lifespan—two critical selling points in international markets.   Solar Panel Type & Efficiency: Prioritize monocrystalline silicon panels (conversion efficiency: 18–23%) for high energy yield, ideal for regions with limited sunlight (e.g., Northern Europe, Canada). Polycrystalline panels (15–18%) are cost-effective for sun-rich areas (e.g., Middle East, Australia). Ensure compliance with international standards: IEC 61215 (solar panel durability) and IEC 61730 (safety), as European, American, and Southeast Asian markets require these certifications for customs clearance. Battery Technology & Capacity: Opt for lithium-ion (LiFePO4) batteries over lead-acid batteries: longer cycle life (3,000+ cycles vs. 500–800 cycles), lighter weight (easier installation), and higher safety (no acid leakage). LiFePO4 is preferred in EU/US markets due to environmental regulations (RoHS compliance). Match battery capacity to usage needs: Calculate based on "daily energy consumption × backup days (3–7 days for rainy seasons)". For example, a 30W LED light (12V) running 8 hours/day needs a 100Ah LiFePO4 battery for 5 days of backup. Charge Controller: Choose MPPT (Maximum Power Point Tracking) controllers (efficiency: 95%+) over PWM (80–85%)—MPPT optimizes energy capture, a key advantage in regions with variable sunlight (e.g., South America, Southeast Asia).       2. Lighting Performance: Adapt to Global Scenarios International clients (e.g., municipal governments, residential communities, commercial projects) have diverse requirements for brightness, color temperature, and coverage.   LED Light Source Specifications: Power range: 10–60W for garden/street use; ensure high luminous efficacy (≥130lm/W) to meet energy-saving standards (e.g., EU ErP, US ENERGY STAR). Color temperature: 3000K–4000K (warm white to natural white) is universally acceptable—3000K for residential gardens (cozy atmosphere), 4000K for streets/parks (clear visibility). CRI (Color Rendering Index): ≥80 for true color representation, a must for high-end projects (e.g., European villa communities, tourist resorts). Operating Modes & Durability: Offer multi-mode options: Light control (auto-on at dusk/auto-off at dawn), time control (6/8/10 hours adjustable), and motion sensor (brightness boost when motion detected) to cater to different usage scenarios (e.g., sensor mode for remote areas to save energy). Ensure stable performance: LED lifespan ≥50,000 hours (5–8 years of use), reducing replacement costs for overseas clients.   3. Weather Resistance & Durability: Meet Global Climate Challenges Solar lights must withstand extreme weather conditions across regions—this is a non-negotiable factor for international trust.   Protection Grade: Minimum IP65 (waterproof, dustproof) for general use; upgrade to IP67 for coastal areas (salt spray resistance) or rainy regions (e.g., India, Brazil). For snowy areas (e.g., Canada, Northern Europe), ensure the housing can bear snow loads (≥20kg/m²). Material & Structural Design: Use corrosion-resistant materials: Aluminum alloy housing (lightweight, heat-dissipating) or stainless steel (for coastal/salty environments). Avoid plastic housings for long-term outdoor use. Temperature adaptability: Operate within -20°C to +65°C (LiFePO4 batteries perform better than lead-acid in low temperatures) to cover most global climates (excluding polar regions). Wind Resistance: Design for wind speeds up to 120km/h (common in hurricane-prone areas like the Caribbean, Southeast Asia) to prevent structural damage.   4. Certification & Compliance: Clear Customs & Gain Trust International markets have strict product certification requirements—non-compliant products risk being rejected at customs or losing market access.   Mandatory Certifications by Region: EU: CE (safety, EMC), RoHS (restriction of hazardous substances), ErP (energy efficiency). US: FCC (electromagnetic compatibility), UL/cUL (safety), ENERGY STAR (energy efficiency for premium markets). Southeast Asia: TISI (Thailand), SIRIM (Malaysia), BPS (Indonesia)—verify local standards for each target country. Middle East: SASO (Saudi Arabia), ESMA (UAE)—ensure compliance with Gulf Cooperation Council (GCC) standards. Environmental Compliance: LiFePO4 batteries are RoHS-compliant, while lead-acid batteries may face restrictions in EU/US due to environmental concerns. Highlight "zero carbon emission" and "recyclable materials" in marketing—key selling points for eco-conscious markets.       5. Cost-Effectiveness & After-Sales Support: Win Long-Term Partnerships Overseas clients focus not only on initial investment but also on long-term maintenance and ROI (Return on Investment).   Total Cost of Ownership (TCO): Emphasize solar energy savings: No electricity bills, 80% lower operating costs than grid-powered lights. Calculate ROI for clients (typically 2–3 years) to justify the higher initial price. Compare with competitors: Highlight longer battery life (LiFePO4 vs. lead-acid) and lower replacement frequency to reduce TCO. Warranty & After-Sales Service: Offer a competitive warranty: 2–3 years for the entire system, 5–10 years for solar panels (industry standard), and 3–5 years for LiFePO4 batteries. Provide global support: Multilingual installation manuals, video tutorials, and local spare parts supply (critical for large projects). For remote regions, partner with local distributors to offer on-site maintenance. Customization Flexibility: Adapt to client needs (e.g., logo printing, specific color temperatures, pole height matching) to stand out in competitive markets (e.g., EU’s high-end residential sector, Africa’s municipal projects).   Final Tips for Global Sales Prioritize region-specific customization: For example, add anti-theft features (lockable battery compartment) for markets with high theft risks (e.g., parts of Africa, Latin America); enhance UV resistance for sun-intensive regions. Highlight smart functions (e.g., IoT remote monitoring, dimming control) for tech-savvy markets (e.g., EU, US, Japan)—these features increase product value and differentiate from low-cost competitors.

  hot Tags : solar lights Solar garden lights LED light Solar garden street lights LiFePO4 batteries garden lights LED garden Light Garden street lights RoHS-compliant garden lights monocrystalline silicon panels garden Light

  Read More
• How an All-in-one Solar Street Light typically works? How Does lt Work?

  Feb 26, 2024

  An All-in-one Solar Street Light is a compact and integrated system that combines the solar panel, battery, LED light source, and control electronics into a single unit. It is designed to harness solar energy during the day and provide lighting at night without the need for external power sources or complex wiring.     Here's how an All-in-one Solar Street Light typically works: First: Core Integrated Components (All in One Housing) Every part works in tandem, and the all-in-one design streamlines installation and reduces failure points. All components are engineered for outdoor durability (IP65/IP67 waterproof/dustproof, temperature resistance):   High-efficiency monocrystalline/polycrystalline solar panel: Captures sunlight and converts it into direct current (DC) electricity via the photovoltaic effect. Built-in lithium battery pack: Stores the converted electrical energy for nighttime lighting (lithium iron phosphate batteries are the mainstream, for long cycle life and safety). High-brightness LED light source: The lighting core, low power consumption and high luminous efficiency—matches the solar system’s DC power supply directly. Integrated smart charge-discharge controller: The central control unit; it regulates charging current/voltage, protects the battery from overcharging/over-discharging/short circuits, and triggers automatic on/off/dimming of the LED. Light sensor (photoresistor): Detects ambient light intensity to signal the controller to switch the light on/off automatically.   Step-by-Step Working Principle (Fully Automated Cycle) The entire process runs 24/7 without human intervention—only dependent on natural light conditions and the controller’s pre-set programs: Photovoltaic Charging (Daytime): When sunlight irradiates the integrated solar panel, the photovoltaic effect converts solar energy into low-voltage DC electricity (12V/24V, standard for solar lights). The smart controller immediately regulates the voltage and current to a stable level, ensuring safe charging for the built-in lithium battery.  Energy Storage & Battery Protection: The regulated electricity is stored in the lithium battery pack. The controller’s built-in protection system continuously monitors the battery’s charge level, cutting off the charging circuit once the battery is fully charged to prevent overcharging (a major cause of battery aging). It also prevents deep discharge to extend battery life. Optional smart sensors/timers: Some models add motion sensors (PIR) or time controllers for energy saving (e.g., dim light when no one is near, set fixed lighting hours). Automatic Illumination Activation (Dusk): As the sun sets, the light sensor detects a drop in ambient light intensity to a pre-set threshold (usually 10-20 lux). It sends a signal to the controller, which immediately closes the discharge circuit and powers the integrated LED light source—the street light turns on automatically. Nighttime Lighting Operation: The stored electrical energy in the battery powers the LED for continuous outdoor lighting. High-quality all-in-one models feature intelligent dimming technology: the light stays at full brightness for the first few hours (peak traffic time), then automatically dims to 30-50% brightness in the late night/early morning to save energy—ensuring the light stays on until dawn even in low-sunlight conditions. Automatic Shutdown & Cycle Reset (Dawn): When the sun rises, the light sensor detects an increase in ambient light above the threshold and signals the controller to cut off the discharge circuit, turning off the LED. The system immediately resets and re-enters the charging phase, starting a new 24-hour cycle.     Additional Smart Operational Features (Mainstream for All-in-One Models)   To boost energy efficiency and system stability, most all-in-one solar street lights add these automated functions that work with the core cycle: Overcharge/over-discharge/short circuit protection: The controller safeguards all components from electrical damage, critical for outdoor harsh environments (rain, thunder, extreme temperatures).   PIR motion sensor (optional): For low-traffic areas (rural roads, parks), the light stays at low brightness by default; it switches to full brightness when a person/vehicle approaches, then reverts to low brightness after a few seconds—maximizing battery life.   Time control setting: The controller can be pre-programmed for fixed lighting hours (e.g., 6/8/10 hours) to match specific project needs.   Low-light energy saving mode: In prolonged rainy/cloudy weather with insufficient charging, the system automatically reduces lighting brightness or shortens lighting hours to ensure basic illumination.  

  hot Tags : All-in-One Solar Street Lights Solar street light Solar LED lights solar lights LED light All in One Housing street light IP67 waterproof Solar Street Lights led solar lights High-efficiency monocrystalline street light

  Read More