Our inverter, battery and generator installation in Bagan service delivers a single, coordinated power system for hotels, resorts, restaurants, clinics, schools, and residences across Old Bagan, Nyaung-U, and New Bagan. Instead of treating each device as a separate project, we design and install them as one integrated platform—clean changeover, smart charging, proper protection, and clear labeling—so you get quiet reliability during normal hours and predictable backup when the grid drops. The result is less diesel waste, longer battery life, and fewer nuisance trips in a region where tourism schedules and seasonal heat leave little room for electrical drama.
Every project starts with a site survey and load study. We record your peak and base loads over typical weekdays and high-season weekends, then categorize circuits into essential (reception, POS, networking, refrigeration, lighting, security) and non-essential (laundry heaters, some HVAC, decorative lighting). From there, we size the inverter for continuous and surge demands, choose a battery capacity that rides through typical outage windows, and specify a generator rating that supports both essential loads and battery charging without wet-stacking or overload. This planning phase includes a single-line diagram that shows how utility, inverter, battery, and generator interact through an automatic transfer switch (ATS) and your distribution boards, so owners, caretakers, and inspectors can follow the logic at a glance.
Design turns those choices into safe, buildable details. The ATS and interlocks are arranged so back-feeding cannot occur, and so generator starts are clean rather than “brown.” We allocate a dedicated essential-loads sub-board, keeping heavy, non-critical circuits on the utility/generator path and freeing your battery to protect revenue-critical systems. Cable sizes are calculated for ampacity and voltage drop using real route lengths, and protective devices (MCB/MCCB, RCD/RCBO, surge protection on both AC and DC sides) are coordinated for selectivity—meaning a fault trips only the affected branch. Earthing and bonding are designed as a low-resistance network that ties equipment frames, racks, and metallic services together, reducing touch-voltage risks and improving surge performance during storms that roll across the Ayeyarwady plain.
On the DC side, lithium iron phosphate (LFP) batteries are common for their cycle life and safety. We integrate the battery management system (BMS) with the inverter so charge and discharge limits follow temperature and state-of-charge, and so the generator can be prevented from “topping off” unnecessarily. For hybrid sites that later plan to add solar, we reserve conduits, breaker ways, and wall space for PV combiners and a future hybrid inverter input. On the AC side, we set charge windows to favor low-tariff hours, cap charge current to protect small generators, and configure export/anti-islanding rules where required. In multi-building properties, we coordinate cable paths and labeling standards so staff can operate isolation points without guesswork, day or night.
Installation is methodical and tidy because maintenance lives with what we build. Battery racks are secured with safe working clearances and ventilation; inverters are mounted away from heat and dust; generator cabling and control lines are routed in mechanical protection with strain relief; and all penetrations are sealed with compatible fire-stopping or weatherproofing. Conduits are UV-stable and clipped for long runs. Before any panel is closed, we test insulation resistance and polarity. Distribution boards are dressed with ferrules and spacing that aids cooling, and directory cards are written in plain language tied to room names and equipment rather than opaque circuit numbers.
Commissioning is a checklist, not a guess. We verify phase rotation, earth continuity, and RCD trips; confirm surge protection indicators; log inverter parameters; and test live transitions: utility → inverter, inverter → generator, and generator → utility. Under controlled load, we simulate grid loss to ensure the essential-loads board stays alive without flicker and that non-essentials remain parked. Battery charge/discharge rules are tuned to your tariff and typical outage duration, protecting cycle life while ensuring cold rooms, networking, and POS stay online. You receive test sheets, as-built drawings, the single-line diagram, breaker schedules, warranty cards, and a maintenance plan covering periodic torque checks, filter changes, coolant inspections, and a pre-monsoon thermal scan.
Because approvals and expectations evolve, we align our work with recognized low-voltage practice while following domestic guidance. For authoritative updates and policy resources relevant to engineering in Myanmar, consult the Government’s Ministry of Science and Technology portal: https://myanmar.gov.mm/ministry-of-science-and-technology. Grounding methods, protective device choices, and documentation standards benefit from anchoring to official sources, which keeps inspections straightforward for properties within heritage-sensitive zones around Bagan.
Financially, integration pays for itself when done right. Hotels and restaurants with daytime peaks save by prioritizing inverter efficiency and shaping loads into solar hours if PV is planned later; clinics and guesthouses that suffer evening outages benefit from modest, well-targeted battery capacity rather than oversized generators running lightly loaded. We present brand options across budgets but never compromise on protection devices, earthing quality, or ATS logic. We also leave room for growth—spare breaker ways, labeled conduits, and open communication ports—so future batteries, solar inputs, or an upgraded generator can be added cleanly instead of as a patchwork.
From survey to handover, our hybrid power system integration in Bagan replaces noise and uncertainty with a calm, predictable backbone for your operations—quiet when it should be, decisive when it must be, and documented so anyone on your team can run it safely.
