Experience the true power with our Terranova home inverter series which are manufactured with lithium-ion batteries as their energy storage source.
Know MoreAn industrial Uninterruptible Power Supply (UPS) is a critical component in various industries to ensure continuous and reliable power to critical equipment and systems.
Know MoreExplore our range of Solar PCU Series designed to efficiently manage and utilize solar power in conjunction with other power sources, such as the grid or a backup generator.
Know MoreExperience the power when Luxury meets the quality and safety with our Terranova smart wall mounted inverter which will provide you complete comfort during the power shutdowns.
Know MoreOur comprehensive Battery Energy Storage Systems offer scalable solutions for residential, commercial, and industrial applications, ensuring a reliable and constant power supply.
Know MoreExplore our range of Solar Battery Packs designed to harness the power of the sun for sustainable and eco-friendly energy solutions for different applications.
Know MoreEnhance your operations with our Material Handling Equipment powered by advanced energy solutions, ensuring efficiency and sustainability.
Know MoreElectric Vehicle (EV) battery packs are critical components in electric vehicles, providing the energy required to power the electric motor and drive the vehicle.
Know MoreTerranova prides itself on supporting OEM’s in a variety of other industries. We specialize in building Lithium Ferro Phosphate battery packs for a wide range of applications and are confident that we will meet your custom power solutions.
Know MoreExperience the true power with our Terranova home inverter series which are manufactured with lithium-ion batteries as their energy storage source. These inverters play a crucial role in residential buildings by converting direct current (DC) electricity from lithium battery or other sources into alternating current (AC) electricity, which is suitable for powering household appliances.
An industrial Uninterruptible Power Supply (UPS) is a critical component in various industries to
ensure continuous and reliable power to critical equipment and systems. Unlike standard
consumer-grade UPS units, industrial UPS systems are designed to meet the demanding
requirements of industrial applications where power disruptions can lead to significant financial
losses, safety hazards, or production downtime.
Uninterruptible Power Supplies (UPS) play a crucial role in various industries due to their ability to
provide a continuous and stable power supply, even in the face of electrical disturbances or
outages. The importance of UPS in industries can be highlighted by several key factors:
In industrial settings, there are often critical and sensitive equipment such as servers, data storage, control systems, and machinery. A sudden power outage or voltage fluctuation can damage or disrupt the operation of these devices. UPS systems provide a buffer against such power-related issues, offering protection for valuable industrial equipment.
Downtime in industrial processes can be extremely costly. UPS systems ensure that essential equipment remains powered during brief outages or until backup power sources, such as generators, come online. This helps prevent disruptions to manufacturing processes, data loss, and other operational inefficiencies.
In industries that rely heavily on computer systems and data storage, sudden power interruptions can lead to data corruption or loss. UPS units provide sufficient time for orderly shutdown procedures, safeguarding against data integrity issues and potential system failures.
In certain industrial processes, the sudden loss of power can pose safety risks. For example, in chemical or manufacturing plants, an unexpected power outage could compromise the integrity of ongoing processes, leading to hazardous situations. UPS systems contribute to maintaining a safe working environment by ensuring that critical safety systems remain operational.
Many industrial processes are continuous and require a stable power supply for optimal performance. UPS units contribute to the continuity of these processes by preventing disruptions caused by power fluctuations or outages.
UPS systems often include voltage regulation features, ensuring that the power supplied to connected equipment remains within acceptable voltage levels. This helps in stabilizing the power quality and protecting sensitive electronic devices from voltage spikes or sags.
Certain industries, such as telecommunications, healthcare, and transportation, rely on critical infrastructure that must operate continuously. UPS units provide a reliable power source for critical equipment, ensuring that essential services remain operational.
In some industries, compliance with regulatory standards is mandatory. UPS systems can help industries meet these standards by providing the necessary backup power and protection for critical equipment.
While the upfront cost of installing UPS systems may be a consideration, the long-term benefits can result in cost savings. Avoiding downtime, preventing equipment damage, and ensuring data integrity contribute to improved operational efficiency and reduced financial losses.
Terranova Industrial UPS are ranging from 5KVA-75KVA Offline/Online
A Solar Power Conditioning Unit (PCU) is a device designed to efficiently manage and utilize solar power in conjunction with other power sources, such as the grid or a backup generator. It plays a crucial role in solar power systems, ensuring that the power generated from solar panels is effectively integrated into the overall power supply. Here are key features and functions of a Solar PCU:
A Solar PCU is responsible for converting the direct current (DC) electricity generated by solar panels into usable alternating current (AC) electricity. This conversion is essential for powering standard electrical devices and appliances.
Many Solar PCUs are equipped with battery charging capabilities. They can charge energy storage systems, such as batteries, during periods of sunlight. This stored energy can then be used during times when solar power generation is insufficient or during power outages.
Solar PCUs are often designed to work in tandem with the electrical grid. They can seamlessly switch between solar power, grid power, and stored energy from batteries as needed. This feature ensures a continuous and reliable power supply.
Solar PCUs incorporate inverters that convert DC power from solar panels and batteries into AC power suitable for running household or industrial appliances.
MPPT technology is commonly integrated into Solar PCUs. MPPT helps optimize the efficiency of solar panels by dynamically adjusting the operating point to extract the maximum power available under different environmental conditions.
Solar PCUs can manage and prioritize loads, ensuring that critical appliances receive power first. This feature is especially useful in off-grid or hybrid systems where power availability may be limited.
Solar PCUs should be scalable to accommodate the expansion of the solar power system. This is important for users who may want to add more solar panels or increase their energy storage capacity over time.
Solar PCUs are integral components of solar power systems, offering flexibility, reliability, and efficiency in harnessing solar energy for residential, commercial, and industrial applications. They contribute to sustainable energy practices and help reduce dependence on conventional power sources.
Experience the power when Luxury meets the quality and safety with our Terranova smart wall mounted inverter which will provide you complete comfort during the power shutdowns and provide your appliances the exact replication of main supply with our latest advanced technology.
Experience the power when Luxury meets the quality and safety with our Terranova smart wall mounted inverter which will provide you complete comfort during the power shutdowns and provide your appliances the exact replication of main supply with our latest advanced technology.
Experience the power when Luxury meets the quality and safety with our Terranova smart wall mounted inverter which will provide you complete comfort during the power shutdowns and provide your appliances the exact replication of main supply with our latest advanced technology.
A Battery Energy Storage System (BESS) is a technology that stores electrical energy in batteries for later use. It plays a crucial role in modern power systems by addressing the intermittent nature of renewable energy sources like solar and wind. BESS helps to store excess energy generated during periods of high renewable energy production and releases it when demand is high or when renewable sources are not actively generating electricity.
BESS can provide grid stability by smoothing out fluctuations in power supply and demand. It can respond quickly to changes in load or generation, helping to maintain a stable and reliable power system.
BESS facilitates the integration of renewable energy sources into the grid. It can store excess energy when renewable sources produce more electricity than is needed and release it when demand is high or when renewable generation is low.
BESS can be used to reduce peak demand on the electrical grid by discharging stored energy during periods of high demand. This can help utilities avoid the need for expensive peaker plants that are typically used to meet peak demand.
BESS can provide backup power in case of grid outages. It can be used to ensure a continuous power supply for critical facilities or to support the grid during emergencies.
BESS can respond rapidly to changes in frequency on the electrical grid, helping to regulate and stabilize the system.
BESS allows for the time-shifting of energy consumption. Excess energy generated during off-peak hours can be stored and used during peak demand periods.
Lithium-ion battery packs are widely used in solar applications for small and medium and larger energy storage. Battery packs play a crucial role in solar energy systems by storing excess energy generated during sunny periods for use during times when the sun is not shining, such as at night or on cloudy days. These batteries help ensure a continuous and reliable power supply .They offer several advantages over traditional lead-acid batteries, including higher energy density, longer cycle life, lighter weight, and better efficiency.
Different lithium-ion chemistries are available, each with its own set of characteristics. Common types include lithium iron phosphate (LiFePO4), lithium nickel manganese cobalt oxide (NMC), and lithium nickel cobalt aluminum oxide (NCA). LiFePO4 is often preferred for its safety and stability.
Determine the energy capacity you need based on your daily energy consumption and the duration of time you want the battery to supply power during periods without sunlight.
Ensure that the voltage of the lithium battery pack is compatible with your solar inverter and system requirements. Consider whether you need a specific series or parallel configuration to meet voltage and capacity needs.
Lithium-ion batteries generally have a longer cycle life compared to lead-acid batteries. Consider the number of charge-discharge cycles the battery pack can undergo before capacity significantly degrades.
Understand the recommended depth of discharge for the lithium-ion battery. Some batteries can be discharged more deeply than others without affecting their lifespan.
Consider the operating temperature range of the lithium battery pack. Some batteries perform better in specific temperature conditions, and thermal management systems may be necessary in extreme climates.
Look for built-in safety features, such as overcharge and discharge protection, thermal management systems, and a Battery Management System (BMS) to ensure the safe operation of the battery pack.
Ensure that the lithium battery pack is compatible with your solar inverter and other system components. Check for communication protocols such as Modbus or CAN bus for seamless integration.
Consider whether the lithium battery pack can be easily expanded or scaled to meet future energy storage needs
Battery packs used in Material Handling Equipment (MHE) play a crucial role in powering electric forklifts, pallet jacks, and other types of industrial vehicles. These battery packs are designed to provide reliable and efficient energy storage for the equipment's electric motors.
Lithium-ion batteries have a higher energy density than lead-acid batteries. This means they can store more energy in a smaller and lighter package. This is particularly advantageous in MHE, where weight and space considerations are critical for efficient operation.
Lithium-ion batteries typically have a longer cycle life compared to lead-acid batteries. They can endure a higher number of charge and discharge cycles before experiencing a significant decrease in performance. This results in a longer operational lifespan for lithium-ion batteries, reducing the frequency of replacements.
Lithium-ion batteries support fast charging capabilities, allowing MHE to spend less time idle during charging. This can significantly improve productivity in industrial settings where downtime directly affects operational efficiency.
Lithium-ion batteries are virtually maintenance-free. Unlike lead-acid batteries that require regular watering and equalization, lithium-ion batteries do not have such maintenance needs. This reduces the overall operational cost and effort associated with battery maintenance.
Lithium-ion batteries provide consistent power output throughout their discharge cycle. This means that as the battery discharges, there is no significant reduction in performance, allowing MHE to operate at full capacity until the battery is depleted. This contrasts with lead-acid batteries, which experience voltage drops as they discharge, affecting the equipment's performance.
Lithium-ion batteries have a compact and space-efficient design. This is especially beneficial in MHE, where space within the equipment is at a premium. The smaller size and lighter weight of lithium-ion batteries can lead to more flexible design options for MHE manufacturers
Lithium-ion batteries are known for their high charge and discharge efficiency. They can convert stored energy into usable power with minimal losses, resulting in more efficient energy utilization and reduced waste heat
Lithium-ion batteries generally have a lower environmental impact compared to lead-acid batteries. They contain fewer toxic materials, have a smaller carbon footprint, and are more easily recyclable.
Lithium-ion batteries can be partially charged without negatively impacting their performance or lifespan. This feature provides operational flexibility, allowing MHE operators to recharge the batteries as needed without waiting for a full discharge.
Electric Vehicle (EV) battery packs are critical components in electric vehicles, providing the energy
required to power the electric motor and drive the vehicle. Here are some key aspects and
advantages of EV battery packs:
The usage of lithium-ion batteries in the Electric Vehicle (EV) segment provides several advantages
compared to other types of batteries, particularly traditional lead-acid batteries. Here are some key
advantages.
Lithium-ion batteries have a high energy density, meaning they can store a significant amount of energy in a relatively lightweight and compact package. This is crucial for electric vehicles, as higher energy density translates to a longer driving range on a single charge.
Lithium-ion batteries are lightweight compared to other battery technologies. This reduces the overall weight of the electric vehicle, contributing to improved energy efficiency and handling.
The high energy density of lithium-ion batteries allows electric vehicles to achieve longer driving ranges on a single charge. This is a critical factor in the widespread adoption of electric vehicles, addressing concerns about "range anxiety."
Lithium-ion batteries support fast-charging capabilities, allowing electric vehicle owners to charge their vehicles quickly at compatible charging stations. Fast charging is essential for making EVs more convenient and practical for daily use.
Lithium-ion batteries deliver high power output, contributing to the acceleration and overall performance of electric vehicles. This is important for meeting the performance expectations of drivers and competing with traditional internal combustion engine vehicles.
Lithium-ion batteries are designed for durability and have a long lifecycle, meaning they can undergo a large number of charge-discharge cycles before experiencing a significant decrease in performance. This contributes to the long-term reliability of electric vehicles.
Lithium-ion batteries require less maintenance compared to traditional lead-acid batteries. They do not have the same maintenance needs, such as regular watering and equalization, making them more convenient for electric vehicle owners.
Lithium-ion batteries have a compact design and can be shaped to fit the available space in the vehicle more efficiently. This flexibility in design allows automakers to optimize the use of space within the vehicle.
While there are environmental concerns associated with the mining and production of lithium, lithium-ion batteries generally have a lower environmental impact compared to other battery technologies. Additionally, efforts are being made to improve recycling processes for lithium-ion batteries.
Customized battery packs are tailor-made energy storage solutions designed to meet specific requirements. They involve assembling individual batteries into a pack, often with features like shape, capacity, and voltage adjusted to suit particular applications, such as electric vehicles, medical devices, or consumer electronics. Tailoring these packs allows for optimized performance, size, and longevity based on the intended use.