Our Core Solutions
Resilience Mode™ — Energy Storage + Back-up
Appliance | Power(kW) | Hours Used | Energy (kWh) |
|---|---|---|---|
Washington, DC | 58 | 63% | |
Philadelphia | 58 | 53% | |
New York | 60 | 43% |
Power that waits for the unexpected.
Objective: Keeps homes and businesses running through outages with reliable battery backup. Ideal for residential, retail, and offices looking for 24/7 energy resilience.
Use Cases: Small commercial office in a suburban area prone to 4–6 grid outages annually.
Load & System Assumptions
-
Daily Energy Consumption: 50 kWh
-
Critical Load During Outage: 20 kWh
-
Battery System Designed For:
-
30 kWh usable capacity
-
80% DoD, so total battery size is approx. 37.5 kWh
-
10–20% SoC held in reserve for system protection and real emergencies
-
Load Breakdown (Day)
Appliance
Power (kW)
Hours Used
Energy (kWh)
LED Lighting (office)
0.5
6
3.0
Server & Router
0.3
24
7.2
Air Conditioning (1.5 HP)
1.2
4
4.8
Computers (x5)
1.0
4
4.0
Emergency Lighting & Misc
0.25
4
1.0
Total (Critical)
-
-
20.0
Battery System Design
Component
Battery Bank
Inverter / PCS
EMS
Battery Type
SoC Strategy
Mounting / Enclosure
Communication / Remote
Spec / Rationale
37.5 kWh gross capacity (80% DoD = 30 kWh usable)
5–10 kW rating for smooth switchover and handling peak critical loads
Configured for outage detection + smart prioritisation of loads during discharge
LFP (LiFePO₄), deep cycle, low degradation across fewer yearly cycles
Always keep 20–30% SoC buffer for unexpected extended outages
Indoor or weatherproof cabinet near DB for seamless integration
Remote interface to monitor SoC, alert in case of grid failure
Battery System Design
Component
Battery Bank
Inverter / PCS
EMS
Battery Type
SoC Strategy
Mounting / Enclosure
Communication / Remote
Spec / Rationale
37.5 kWh gross capacity (80% DoD = 30 kWh usable)
5–10 kW rating for smooth switchover and handling peak critical loads
Configured for outage detection + smart prioritisation of loads during discharge
LFP (LiFePO₄), deep cycle, low degradation across fewer yearly cycles
Always keep 20–30% SoC buffer for unexpected extended outages
Indoor or weatherproof cabinet near DB for seamless integration
Remote interface to monitor SoC, alert in case of grid failure
Distinction From Other Use Cases
Aspect
Objective
Battery Usage Pattern
System Sizing Logic
Charging Mode
Design Priority
Unique Setup Needs
Energy Storage + Backup
Blackout resilience (event-based usage)
Infrequent, shallow-to-mid discharge (only during outages)
Sized for critical load × hours of autonomy (not daily cycling)
Charges from solar and/or off-peak grid when available
Reliability, switchover speed, and backup priority management
Seamless switchover (via hybrid inverter or ATS), emergency EMS protocol
Distinction From Other Use Cases
Aspect
Objective
Battery Usage Pattern
System Sizing Logic
Charging Mode
Design Priority
Unique Setup Needs
Energy Storage + Backup
Blackout resilience (event-based usage)
Infrequent, shallow-to-mid discharge (only during outages)
Sized for critical load × hours of autonomy (not daily cycling)
Charges from solar and/or off-peak grid when available
Reliability, switchover speed, and backup priority management
Seamless switchover (via hybrid inverter or ATS), emergency EMS protocol
This system is not optimised for daily cost saving, unlike Load Control or Peak Shaving. It is a resilience-focused design with minimal battery cycling and a strong emphasis on availability and fast switchover.
Load Breakdown (Day)
Appliance
Power (kW)
Hours Used
Energy (kWh)
LED Lighting (office)
0.5
6
3.0
Server & Router
0.3
24
7.2
Air Conditioning (1.5 HP)
1.2
4
4.8
Computers (x5)
1.0
4
4.0
Emergency Lighting & Misc
0.25
4
1.0
Total (Critical)
-
-
20.0
Smart Load Sync™ — Power Continuity + Load Control
Distinction From Other Use Cases
Aspect
Power Continuity + Load Control
Objective
Shift load away from peak periods & stabilise operations
Battery Usage Pattern
Daily, shallow to medium discharge, timed cycles
System Sizing Logic
Based on kWh to be shifted during high-tariff or unstable windows
Charging Mode
Scheduled, from grid or solar
Design Priority
Automation, reliability, and price arbitrage
Unique Setup Needs
Pre-set EMS schedule, high-speed inverter response (≤50 ms), load mapping for control
Balance your load. Boost your efficiency.
Objective: Dynamically manages power flow to critical equipment, ensuring no disruptions from unstable grids or high-demand cycles. Perfect for clinics, telcos, or automated systems.
Use Cases: A medium-sized factory operating on a Time-of-Use (TOU) tariff structure with frequent load fluctuation and afternoon peak pricing. Factory processes require constant voltage, and interruptions or under-voltage can spoil materials or stop production lines.
Load & System Assumptions
-
Total Daily Load: 800 kWh/day
-
High Tariff Peak Period: 1 PM – 5 PM (4 hours)
-
Target Load Shifting: Offset 200 kWh during this period via battery
-
Grid Unreliability: Minor dips and voltage fluctuations
Load Breakdown (Day)
Appliance
Power (kW)
Hours Used
Daily Consumption (kWh)
Refrigerated Storage (x3)
15
24
360
HVAC, Dehumidifiers
10
16
160
Lighting
3
12
36
Mixing and Processing Machines
40
6
240
Total
-
-
796
Targeted Load Control Period (1–5 PM):
Assume peak load rises to 70 kW, factory wants to shed/control 50 kW for 4 hours = 200 kWh.
Battery System Design
Component
Spec / Rationale
Battery Bank
200 kWh × 1.2 safety margin = 240 kWh gross, 80% DoD = 192 kWh usable
C-Rating (Discharge Rate)
0.5C → Allows discharge of 120 kW over 4 hours if needed
Inverter / PCS
At least 100 kW rated inverter for fast response and load coverage
EMS
Pre-programmed with TOU schedule, automatic discharge during peak pricing
Battery Type
LFP, moderate-depth cycle, long life (designed for frequent daily cycling)
SoC Strategy
Operates between 40–90% SoC to allow both charge/discharge room
Load Priority Logic
Secondary loads (compressors, non-time-critical HVAC) offloaded to battery
Battery System Design
Component
Battery Bank
C-Rating (Discharge Rate)
Inverter / PCS
EMS
Battery Type
SoC Strategy
Load Priority Logic
Spec / Rationale
200 kWh × 1.2 safety margin = 240 kWh gross, 80% DoD = 192 kWh usable
0.5C → Allows discharge of 120 kW over 4 hours if needed
At least 100 kW rated inverter for fast response and load coverage
Pre-programmed with TOU schedule, automatic discharge during peak pricing
LFP, moderate-depth cycle, long life (designed for frequent daily cycling)
Operates between 40–90% SoC to allow both charge/discharge room
Secondary loads (compressors, non-time-critical HVAC) offloaded to battery
Battery Usage Logic
-
Charge Period: 11 PM – 6 AM (off-peak tariff) or solar mid-day
-
Discharge Period: 1 PM – 5 PM (peak tariff)
-
Target: Load shaving and continuity — not backup
-
Cycle Count: 300+ cycles/year
Distinction From Other Use Cases
Aspect
Objective
Battery Usage Pattern
System Sizing Logic
Charging Mode
Design Priority
Unique Setup Needs
Power Continuity + Load Control
Shift load away from peak periods & stabilise operations
Daily, shallow to medium discharge, timed cycles
Based on kWh to be shifted during high-tariff or unstable windows
Scheduled, from grid or solar
Automation, reliability, and price arbitrage
Pre-set EMS schedule, high-speed inverter response (≤50 ms), load mapping for control
Load Breakdown (Day)
Appliance
Power (kW)
Hours Used
Daily Consumption (kWh)
Refrigerated Storage (x3)
15
24
360
HVAC, Dehumidifiers
10
16
160
Lighting
3
12
36
Mixing and Processing Machines
40
6
240
Total
-
-
796
This system is optimised for daily use and ROI from tariff savings. It does not prioritise blackout protection but instead focuses on flattening the load curve and ensuring voltage consistency for industrial machines.
Peak Shield™ — Peak Shaving + Production Continuity
Slash peak charges. Power on without pause.
Objective: Absorbs high-demand spikes to lower your bills and keep industrial processes running smoothly. Essential for factories, cold storage, and logistics centres.
Use Cases: A food processing plant with chillers, motors, and packaging lines causing sharp spikes in load during certain intervals (e.g., chiller start-up). These spikes create Maximum Demand (MD) surcharges and risk brownouts or shutdowns if grid capacity is briefly exceeded.
Load & System Assumptions
-
Baseline Load: ~150 kW
-
Peak Load Events: ~250 kW during chiller start-up
-
Peak Duration: ~30 minutes/day
-
Target Shaved Load: 100 kW peak shaving
-
Grid Constraints: Grid transformer rated only up to 200 kW
Load Breakdown (Day)
Appliance
Power (kW)
Hours Used
Energy (kWh)
Chiller System (x3)
90
24
90
Conveyor Systems
40
10
20
Food Processors
60
8
40
Packaging Line
20
8
20
Lighting and Controls
5
24
5
Total Peak Load
-
-
~175–250 kW
Target to Shave
-
-
~100 kW for 0.5hr
Battery System Design
Component
Spec / Rationale
Battery Bank
100 kW × 0.5 hr = 50 kWh / 0.8 DoD = 62.5 kWh gross capacity
C-Rating (Discharge Rate)
2C or higher — must discharge 100 kW from a 62.5 kWh battery = fast response
Inverter / PCS
≥100 kW instantaneous output; fast ramp-up, grid sync
EMS
Uses real-time load monitoring and predictive dispatch logic
Battery Type
High-power LFP with thermal buffering; high throughput and response capabilities
SoC Strategy
Maintain 70–100% SoC range for guaranteed power during MD events
Battery System Design
Component
Battery Bank
C-Rating (Discharge Rate)
Inverter / PCS
EMS
Battery Type
SoC Strategy
Spec / Rationale
100 kW × 0.5 hr = 50 kWh / 0.8 DoD = 62.5 kWh gross capacity
2C or higher — must discharge 100 kW from a 62.5 kWh battery = fast response
≥100 kW instantaneous output; fast ramp-up, grid sync
Uses real-time load monitoring and predictive dispatch logic
High-power LFP with thermal buffering; high throughput and response capabilities
Maintain 70–100% SoC range for guaranteed power during MD events
Battery Usage Logic
-
Charge Period: Any time except peak intervals
-
Discharge Period: On-load spike detection (automated via EMS)
-
Frequency: Short-duration, high-intensity daily events
-
Cycle Count: <100 full cycles/year (mostly partial cycles)
-
Battery Lifespan: Can be extended with partial cycling and minimal DoD
Distinction From Other Use Cases
Aspect
Objective
Battery Usage Pattern
System Sizing Logic
Charging Mode
Design Priority
Unique Setup Needs
Peak Shaving + Production Continuity
Prevent demand spikes & penalties; protect production uptime
Short bursts of high power (high C-rate)
Based on peak shaving duration × shaved power (kW)
Rapid recovery post-discharge, usually from grid
Response speed, inverter oversizing, battery thermal control
High-discharge-rate batteries (≥2C), EMS with load threshold triggers
Load Breakdown (Day)
Appliance
Power (kW)
Hours Used
Peak Load Window (30mins)
Chiller System (x3)
90
24
9
Conveyor Systems
40
10
20
Food Processors
60
8
40
Packaging Line
20
8
20
Target to Shave
-
-
~100 kW for 0.5 hour
Lighting and Controls
5
24
5
Total Peak Load
-
-
~175–250 kW
This system acts like a “shock absorber” for power usage — shaving demand spikes that would otherwise trigger utility penalties or risk system trips. It’s all about speed and control, not energy storage capacity.
Distinction From Other Use Cases
Aspect
Peak Shaving + Production Continuity
Objective
Prevent demand spikes & penalties; protect production uptime
Battery Usage Pattern
Short bursts of high power (high C-rate)
System Sizing Logic
Based on peak shaving duration × shaved power (kW)
Charging Mode
Rapid recovery post-discharge, usually from grid
Design Priority
Response speed, inverter oversizing, battery thermal control
Unique Setup Needs
High-discharge-rate batteries (≥2C), EMS with load threshold triggers
GridFree Access™ — Remote Energy Enablement
Go beyond the grid.
Objective: Delivers off-grid power for islands, plantations, and rural sites using solar + battery combos. A clean alternative where the grid doesn't reach.
Use Cases: An off-grid island resort with no utility access, historically dependent on diesel generators for all electricity. They now seek to integrate solar + BESS to reduce fuel reliance, stabilise energy delivery, and cut emissions/logistics cost.
Load & System Assumptions
-
Average Daily Load: 1,200 kWh/day
-
Peak Load: 100 kW
-
Solar Generation Window: 6:30 am – 6:30 pm
-
Solar Contribution Target: 60% of load = 720 kWh
-
Battery Autonomy Target: 1.5 MWh to support night-time and cloudy day loads
-
Diesel Genset: Used only as tertiary backup
Load Breakdown (Day)
Appliance
Power (kW)
Hours Used
Energy (kWh)
Guest Lodging (AC, lights, plugs)
50
16
800
Kitchen + Cold Storage
10
24
240
Water Pumps + Filtration
5
12
60
Admin, Security, Outdoor Lighting
5
20
100
Total
-
-
1,200
Distinction From Other Use Cases
Aspect
Remote Energy Access
Objective
Energy independence from the grid/genset
Battery Usage Pattern
Deep daily cycling for base load
System Sizing Logic
Based on daily load × days of autonomy / DoD
Charging Mode
Fully solar-based; needs oversized solar array to match cycles
Design Priority
Resilience, solar integration, and energy autonomy
Unique Setup Needs
Hybrid inverter, intelligent solar charging control, weather sync
Battery System Design
Component
Battery Bank
C-Rating (Discharge Rate)
Inverter / PCS
Hybrid Controller / MPPT
Battery Type
SoC Strategy
Spec / Rationale
1.5 MWh usable, assuming 80% DoD → requires ~1.9 MWh gross capacity
0.25–0.5C, low-intensity discharge over 12–16 hours
Continuous output capacity ≥ 100 kW (peak handling)
For managing variable solar input across the day
Long cycle life LFP or Lithium Titanate; designed for deep, daily cycles
Discharge from 100% to 20% daily, with full solar recharge during the next daylight cycle
Battery Usage Logic
-
Charge Period: Solar hours (10 am – 5 pm)
-
Discharge Period: Night-time (5 pm – 8 am) and rainy days
-
Frequency: 1 full cycle/day = ~365/year
-
Autonomy Days: 1.25 days of backup storage = 1.5 MWh
-
Cycle Strategy: Regular deep cycles with weather-aware load prediction
Distinction From Other Use Cases
Aspect
Objective
Battery Usage Pattern
System Sizing Logic
Charging Mode
Design Priority
Unique Setup Needs
Remote Energy Access
Energy independence from the grid/genset
Deep daily cycling for base load
Based on daily load × days of autonomy / DoD
Fully solar-based; needs oversized solar array to match cycles
Resilience, solar integration, and energy autonomy
Hybrid inverter, intelligent solar charging control, weather sync
Load Breakdown (Day)
Appliance
Power (kW)
Hours Used
Daily Use
(kWh)
Guest Lodging (AC, lights, plugs)
50
16
800
Kitchen + Cold Storage
10
24
240
Water Pumps + Filtration
5
12
60
Admin, Security, Outdoor Lighting
5
20
100
Total
-
-
1,200
This design transforms the site into a microgrid—a closed-loop system combining solar, battery, and minimal genset use. The key here is reliability and endurance, not peak shaving.
Component
Battery System Design
Spec / Rationale
Battery Bank
1.5 MWh usable, assuming 80% DoD → requires ~1.9 MWh gross capacity
C-Rating (Discharge Rate)
0.25–0.5C, low-intensity discharge over 12–16 hours
Inverter / PCS
Continuous output capacity ≥ 100 kW (peak handling)
Hybrid Controller / MPPT
For managing variable solar input across the day
Battery Type
Long cycle life LFP or Lithium Titanate; designed for deep, daily cycles
SoC Strategy
Discharge from 100% to 20% daily, with full solar recharge during the next daylight cycle