Hytronity

Sustainability and Profitability start with the Design. Providing for the Serviceability of battery storage systems is the best way to utilize materials over a long period of time. Hytronity's illustration points out: Before a current battery is available to the customer, statistically more than 15% of the material had to be recycled – within the first 5 years of use, this figure rises to 20%. This not only reduces the ecological benefit, but is also reflected in the customer's bill and additionally drives up the risk costs after the warranty expires. These burdens can be significantly lowered by minimizing the amount of materials to be scrapped in the event of a defect. Repairability and Reconfigurability at Cell Level generate Great Leverage to increase Ecological and Economic Benefits. Hytronity is addressing these benefits in the development of its #ecocone Battery Technology. #Battery #Swappability Hytronity #ecocone #ExtendedLife #Maintainability #Repairability #Reconfigurability #Serviceability #Sustainability #CleanEnergy #SecondLife

Reduce the Ownership Costs of Batteries - Extend their Lifetime - Simplify their Service! Hytronity is proud to finalize its second research project and to start the development of the New Battery Technology #ecocone. The #ecocone technology ensures the Swappability of every single cell of a High Voltage Battery and is a milestone on the way to Sustainable Clean Energy Storage Systems. #ecocone Simplifies battery Production, Enables cell Upgrades as well as a Second Life for the cells in systems with other industry standards and Ensures more Efficient Material Separation in recycling. #ecocone makes Sustainability a Product Philosophy. #Battery #Swappability Hytronity #ecocone #ExtendedLife #Servicability #Sustainability #CleanEnergy

Batteries? Hydrogen? Or stand alone Solar? There are many opinions on the optimal design of Sustainable Systems for Clean Energy - Hytronity's analysis addresses these and provides a data-based indication for the Balanced Use of Storage Technologies in tandem with Photovoltaic Electricity. The carbon footprint of on-demand electricity is one of the key parameters for the environmental compatibility of its supply. Similar to the price, this parameter reflects all influencing factors from raw material extraction, refining, plant construction, operation and logistics. Hytronity's diagram illustrates that decentralized Batteries and Hydrogen storage systems can contribute significantly to the Sustainability of the energy supply and considerably increase the benefits of Photovoltaic Systems. The combination of Batteries for daily storage with Hydrogen loops for storage over longer periods of time makes the Photovoltaic Potential fully available. #Hydrogen #Battery #Solar Hytronity #Sustainability #CleanEnergy #CarbonFootprint

Hydrogen and Battery Storage - Hytronity's analysis shows the Economic Importance of the balanced combination of both Sustainable Technologies and gives a first indication of how a high level of environmental compatibility can be achieved. In good correlation - more sustainability and lower material costs go hand in hand. This is because lower material costs are often an expression of less impact on nature and lower energy consumption in mining and processing. Furthermore, the use of materials defines the most substantial share of the carbon footprint as well as of the costs of industrially manufactured systems. Therefore, Sustainable Systems for Sustainable Applications are the basis for economic advantages in competition. Hytronity is pursuing this path. #Hydrogen #Battery Hytronity #Costs #Sustainability #CleanEnergy

The Low Material Effort of Hydrogen Storages is advantageous for the long-term buffering of energy, while the Simpler electrochemical Conversion in Batteries enables effective access to short-term power. Hytronity's visualization of the state of the art illustrates the complementary advantages of both technologies. A balanced Combination of Hydrogen and Battery Systems therefore enables Optimum Storages for Clean Energy. The energy density provides a top view of the material effort necessary to store an unit of energy. The material effort itself significantly determines sustainability, costs and investments. The variable energy to power ratio ensures that the two important performance aspects of energy and power are given equal consideration. Although both technologies have a broad and overlapping range of applications due to many other requirements, the diagram clearly shows key areas of preference. Outside the competitive area with moderate energy to power ratios, the lead of each more efficient technology is about one order of magnitude. Furthermore, the process flow design of hydrogen cycles allows an independent definition of energy and power, while the steady state design of batteries leads to an additional limitation to a maximum technological energy to power ratio of less than 10 h. This means that the design remains unchanged even if higher energy to power ratios are required. #Hydrogen #Battery Hytronity #Sustainability #CleanEnergy

The fascination around the power of gas began thousands of years before the first durable pressure cylinder became available. Now It’s Time For The Next Step: Flat Storage Design is the key to many applications - other markets have already taken this route. Inspired by the principles of Advanced Technologies, Hytronity's #monocab technology solves the challenges of efficient and safe structures for Free Form High Pressure Tanks. #monocab fits the infrastructure for all standards of Compressed Hydrogen. #monocab opens the path for the development of Compact and Sustainable Hydrogen Storages and their Smart Integration into a wide range of applications. #Hydrogen #HydrogenSafetyIntegrated Hytronity #monocab #ConformalStorage #Sustainability #CleanEnergy

Moderate Power and High Energy Density regardless of weather and season - Solar and Hydrogen are the perfect pair for a consistent supply of Clean Energy. The integration of Hytronity's #monocab technology is the next step towards Grid-Friendly Clean Energy Systems. #Hydrogen #HydrogenSafetyIntegrated Hytronity #monocab #Sustainability #CleanEnergy #Solar

High Standards already exist to ensure the Safe Use of Compressed Hydrogen. However, due to the possibility of avalanche-like propagation of initially small defects, there remains a residual risk of significant damage. Therefore, Hytronity adopts Avalanche-Proof Design Principles from semiconductor science to significantly improve their Intrinsic Safety and Simplify the Operation of Compressed Hydrogen Storage. #Hydrogen #BurstPressure #AvalancheProof #HydrogenSafetyIntegrated #Safety Hytronity #monocab #Sustainability #CleanEnergy

Handling Energy means Controlling its Release. Hytronity recognizes its responsibility to develop Hydrogen Storage Technologies for safe and robust handling. We believe that a broader range of applications with higher energy density must go hand in hand with the Next Level of Safety Strategies. To achieve this goal, we are launching the project - hydrogen . SAFETY INTEGRATED - and welcome partners who want to go one step further with us. #Hydrogen #HydrogenSafetyIntegrated #Safety Hytronity #monocab #Sustainability #CleanEnergy

Integral Solutions for Compressed Hydrogen Storage will increase the Range of Commercial Vehicles. Hytronity’s #monocab technology makes this potential accessible. #Hydrogen #ConformalStorage Hytronity #monocab #EnergyDensity #Range #Sustainability #CleanEnergy