The 9m Commercial Street 6-in-1 with Display is a grid-powered integrated smart pole engineered for commercial-street deployment — optimized for municipalities, developers, and EPC contractors that need six core functions on a single pole: 120W LED lighting, 4K camera surveillance, environmental sensing, an LED information display, WiFi connectivity, and an IP public-audio column. Built on a 9m octagonal tapered steel pole with IP66 protection, 170 lm/W luminous efficacy, a recommended 28m pole spacing, and wind-speed resistance exceeding 150 km/h, this configuration is optimized for high-foot-traffic walkways, retail streets, campuses, mixed-use districts, and commercial roads adjacent to transit.
Compared with conventional streetlight approaches consisting of one passive pole, one separate CCTV mast, one wall-mounted speaker, one standalone air-quality node, and one separate digital-signage structure, this integrated design reduces visible street furniture by up to 60%, cuts trenching interfaces by 30–40%, and consolidates maintenance dispatch points from five asset types into a single asset location. According to IEA's smart-city electrification pathways and IRENA's urban-efficiency research, integrated controls and LED modernization typically save 50–70% of lighting energy use versus legacy HID. NREL and municipal digital-infrastructure studies also consistently show that network-based monitoring reduces outage response time by more than 20% versus non-connected assets. Buyers reviewing alternatives can browse all Smart Streetlight (10-in-1 Multi-function Pole) products to compare 6m–15m heights and 3-in-1 through 10-in-1 module configurations.
This model is part of the MAXLUMI Smart Streetlight (10-in-1 Multi-function Pole) product line, but the installed configuration here is selected as a 6-in-1 package. This is tuned for commercial-street needs where digital communications and public-space monitoring are more important than EV charging or edge-gateway expansion. The pole structure uses hot-dip galvanized steel with a fluorocarbon coating exterior, in typical wall thickness ranges of 3–6 mm. The octagonal tapered geometry balances structural rigidity, cable-routing volume, and urban aesthetics over a 25-year design life. The power architecture is AC 220/380 V grid supply rather than solar — suitable for dense urban roads with reliable utility access and for display loads operating 10–18 hours per day.
The integrated module set consists of one LED luminaire, one AI camera, one environmental sensor package, one outdoor LED display, one WiFi AP, and one IP speaker column — all mounted and wired as a coordinated system. From a project perspective, developers can specify a single SKU family, a single foundation interface, a single vertical asset ID, and a single maintenance workflow instead of coordinating six separate vendors. The LED fixture is rated at 120W and delivers approximately 20,400 lumens at 170 lm/W — suitable for collector roads, retail boulevards, and commercial frontage roads at a 9m mounting height and average 28m spacing.
At the top of the pole and on side arms, the lighting subsystem uses a modular LED luminaire aligned with IEC 60598 luminaire safety requirements and IEC 62722 LED luminaire performance principles. The surveillance subsystem typically uses a 4K AI-assisted camera with PTZ (pan-tilt-zoom) capability supporting up to 20× optical zoom and 50 m IR night-vision — though the exact camera selection may vary by project between fixed and PTZ options depending on budget and analytics scope. The environmental package measures up to eight parameters, typically including PM2.5, PM10, temperature, humidity, noise, O₃, NO₂, and wind-speed-related values. This enables local air-quality dashboards and city monitoring for compliance.
The communications layer supports WiFi 6, optional 4G/5G uplink, and LoRaWAN integration in broader smart-city deployments. In this 6-in-1 commercial configuration, WiFi is typically used for public access, tenant-zone services, or maintenance connectivity. Actual concurrent-user design is often configured for 100–500+ users depending on AP model, backhaul bandwidth, and local policy control. The LED display module is commonly built around a P4 1024 × 512 mm outdoor display, enabling roadway messages, district branding, announcements, event promotions, and urgent information delivery via 24/7 remote content scheduling.
From a lighting-design perspective, the 120W luminaire and 28m spacing target assume a commercial-road layout where one pole can cover approximately 784 m² of plan area before overlap and photometric correction. Actual roadway illuminance depends on lane width, setback, mounting outreach, road-surface reflectivity, and target lux. However, in many commercial-street projects this class replaces legacy 250W–400W HID fixtures while reducing connected lighting load by 52–70%. CCT is configurable within the typical 3000K–6500K range; 4000K is often selected for retail and mixed-use streets because it balances visual comfort with camera-friendly color rendering.
The pole itself is specified as a 9m octagonal design. This format is widely used in municipal infrastructure thanks to favorable torsional rigidity and relatively simple bracket mounting. Wind resistance is rated above 150 km/h, particularly relevant for coastal and typhoon-exposed commercial districts when foundation design is properly engineered. System protection rating is IP66 with an operating temperature range of −40 °C to +55 °C. With proper gasketing, coatings, and surge-protection packages, the system can therefore be deployed across cold continental climates, hot desert cities, and humid tropical walkways.
Electrical integration typically includes breakers, distribution cables, surge protection, grounding, and smart-control interfaces. On commercial streets with frequent switching cycles and variable pedestrian activity, intelligent scheduling can reduce lighting operating time or dimming output by 20–40% during low-traffic hours. Compared with non-networked sodium-vapor streetlights, annual energy savings often reach 55–68% depending on baseline wattage, annual operating hours of approximately 4,000–4,380, and local dimming strategy. Buyers can configure a system online to compare display sizes, camera types, sensor packages, and communications options.
The lighting module is rated at 120W and delivers approximately 20,400 lm at 170 lm/W. This is significantly higher efficiency than many legacy roadway luminaires rated at 90–120 lm/W. Such efficiency lowers feeder load, reduces lifecycle energy cost, and decreases thermal stress inside the luminaire enclosure. For a typical 12-hour-per-day operating schedule, pre-dimming per-pole annual consumption is approximately 525.6 kWh. Applying an average 30% dimming profile during 6 nighttime hours can reduce consumption by an additional 10–15%.
The camera subsystem supports urban security, traffic observation, and incident verification from a single 9m mounting height. A 4K PTZ camera with 20× zoom and 50 m infrared capability monitors intersections, curb-loading zones, and pedestrian flows more effectively than low-mounted wall cameras at 3–4 m height. Combined with AI analytics, it can support line-crossing detection, perimeter alerts, crowd-density estimation, and event-playback retention from 7 to 90 days (varying with storage architecture and local data governance).
The environmental node typically combines eight sensing channels in a single enclosure — reducing the need for a separate air-quality station, which can cost 2–5× more when deployed independently. Variables commonly measured include PM2.5, PM10, temperature, humidity, noise, O₃, NO₂, and wind-speed-related values. In commercial districts, this data can support ESG reporting at 1–15-minute intervals, public-health dashboards, and tenant communications, with trend data exportable to cloud platforms and city APIs.
The outdoor display adds a revenue and communications layer that conventional streetlights cannot provide. A typical P4 1024 × 512 mm screen can be used for district announcements, wayfinding, event scheduling, safety notices, and paid digital advertising in 10–30-second slots. For operators running 20–100 poles, even modest advertising utilization can offset a meaningful portion of annual O&M cost. Display brightness, content scheduling, and remote diagnostics are managed centrally, reducing site visits to 1–3 per location per year.
The WiFi module fits commercial-street environments where visitors expect mobile connectivity and operators need a digital services layer. Based on WiFi 6 architecture and appropriate backhaul, a single AP can support 100–500+ concurrent users depending on throughput policy, RF environment, and authentication method. In mixed-use streetscapes it supports customer engagement, smart-parking interfaces, QR campaigns, and maintenance access without requiring a second communications mast. For broader background on integrated urban connectivity, reference the MAXLUMI knowledge center.
The IP speaker column delivers public announcements, scheduled messaging, and emergency broadcasts through network-managed audio endpoints, typically configured at 30W–60W. On commercial streets it supports evacuation guidance, event audio, parking guidance, or timer-based district messaging with audible coverage of 50–150 m depending on ambient noise and mounting orientation. Compared with standalone PA poles, integration eliminates separate support structures and simplifies IP addressing, power distribution, and maintenance inventory by consolidating six functions into a single asset.
The key B2B advantage of this product is centralized monitoring of lighting, security, environmental data, display content, and communications status from a single platform. Operators can check online/offline status, energy consumption, fault alarms, playback snapshots, and environmental trends at intervals as short as 60 seconds. For portfolios of 50, 100, or 250 poles, this reduces manual-inspection frequency and supports SLA-based maintenance planning. According to industry practice referenced by BloombergNEF, IEA, and urban-digitalization frameworks, remote diagnostics can cut unplanned downtime by 15–30% compared with non-connected public assets.
The cloud layer also supports user permissions, GIS visualization, log retention, and API export to municipal or private command centers. Lighting schedules can be grouped by district, displays can be updated by campaign, and alarms can escalate through 3–5 response-severity levels. For operators planning future upgrades, the modular architecture enables migration from 6-in-1 to a broader smart-pole ecosystem — for example, later adding gateways, emergency intercoms, or EV charging without replacing the entire 9m structure.
64 of these 9m 6-in-1 smart poles were deployed along a mixed-use commercial boulevard in the MENA region. Across a 1.8 km retail corridor, the recommended 28m spacing was applied — with denser placement at four intersections and two plaza nodes. The developer replaced legacy 250W HPS lighting, separate CCTV brackets, and standalone notice boards. After 12 months, lighting energy consumption was measured down by approximately 57%, average incident-verification time dropped from 18 minutes to 7 minutes, and the district used the LED display 14 hours per day for events, parking, and tenant messaging. The integrated approach reduced above-ground street furniture by more than 40% versus the prior multi-vendor concept.
This product is designed against smart-lighting and public-infrastructure standards. These include IEC 60598 for luminaires, IEC 62722 for LED luminaire performance, and EN 50556 — often referenced in smart-pole projects — for road-traffic-signal and related infrastructure integration logic. Structural design, grounding, surge protection, and installation details are finalized per project jurisdiction, but the base platform is suitable for commercial deployments with IP66 enclosure protection, −40 °C to +55 °C operation, and a 25-year design life. Reference guidance from NREL, IRENA, IEA, and Wood Mackenzie consistently supports the view that modular electrified infrastructure can be a lower lifecycle-cost path than fragmented single-function asset installations in urban environments.
Pricing available upon inquiry.
For engineers and procurement staff, the value of this product is standardization. Instead of issuing 4–6 separate packages for pole, lighting, surveillance, networking, signage, and public audio, buyers can secure a single integrated platform with coordinated interfaces. Module compatibility is delivered pre-tested, with EPC-delivery per-unit installation cost available upon inquiry. This reduces vendor-coordination burden, minimizes aesthetic inconsistency in the streetscape, and simplifies spare-parts planning over a 10–25-year operating window. To compare module combinations, browse all Smart Streetlight (10-in-1 Multi-function Pole) products or the topic library before finalizing specifications.
To specify the correct version, buyers should confirm pole quantity, road width, the 28m target spacing, camera retention policy, display content strategy, network uplink type, and the local electrical standard (220 V or 380 V). For 20–500-pole projects, MAXLUMI can support BOM optimization, drawing-finalization review, and phased delivery planning. If display dimension customization, alternative AP models, or fixed cameras in place of PTZ are required on commercial streets, configure a system online or request a custom quotation for a project-specific proposal within the stated pricing tier.
| Product Variant | 9m Commercial Street 6-in-1 with Display |
|---|---|
| Product Line | Smart Streetlight (10-in-1 Multi-function Pole) |
| Pole Height | 9 m |
| Pole Design | Octagonal tapered galvanized steel |
| LED Power | 120 W |
| Luminous Efficacy | 170 lm/W |
| Estimated Luminous Flux | 20400 lm |
| Integrated Modules | 6 in-1 |
| Included Modules | LED, Camera, Environmental Sensor, LED Display, WiFi, IP Speaker |
| Applications | Commercial street |
| Recommended Spacing | 28 m |
| Wind Speed Resistance | 150 km/h+ |
| IP Rating | IP66 |
| Operating Temperature | -40 to +55 °C |
| Communication | 4G/5G + LoRaWAN + WiFi 6 |
| Camera Performance | 4K AI PTZ, 20x optical zoom, 50m IR |
| Sensor Parameters | PM2.5, PM10, O3, NO2, noise, temperature, humidity, wind |
| Power Supply | AC 220/380V grid |
| Energy Savings | 55-68 % |
| Design Lifetime | 25 years |
Pricing available upon inquiry.
Custom design tailored to site conditions, capacity, and budget. Widewings' in-house EPC team consults directly.
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