Helpline: Aust 08-84105888 H2-Hybrid Australia Pty Ltd . e: sales@h2hybrid.au

Why Hydrogen?

Hydrogen is considered the most powerful and energy-rich fuel in existence. Notably, it is a sustainable fuel source that does not produce harmful pollutants. – Prof. Yull 

Oxy-hydrogen generationThe technology known as oxy-hydrogen generation, or HHO gas, is a revolutionary breakthrough that utilizes electrolysis to create a mixture of hydrogen and oxygen from water. This cutting-edge innovation has garnered considerable attention due to its potential to address various energy and environmental challenges of the 21st century. This article aims to delve into the intricacies of oxy-hydrogen generation, its numerous applications, advantages, and its role in shifting towards a sustainable energy future.

hydrogen

Understanding Oxy-Hydrogen Technology

Water can be broken down into its basic components of hydrogen and oxygen through a process known as oxy-hydrogen generation. This process involves running an electrical current through an electrolysis cell that contains two submerged electrodes, one positively charged (anode) and one negatively charged (cathode). When the electricity flows through the cell, it causes the water (H2O) to decompose into hydrogen and oxygen gases, which are then collected and stored for later use. The chemical reaction can be represented as 2H2O (liquid) = 2H2 (gas) + O2 (gas).

Applications of Oxy-Hydrogen Gas

1. Metalworking Applications: The oxy-hydrogen gas process has proven invaluable in the metal cutting and welding sectors. Its high-temperature flame, free from contaminants, enables efficient and precise cutting and welding of a range of metals.

2. Fuel Cells: The use of hydrogen produced from oxy-hydrogen generation in fuel cells enables the generation of electricity, providing a clean and renewable energy source for a variety of uses.3. Carbon Reduction: By utilizing oxy-hydrogen gas in combustion engines, we can curb our reliance on fossil fuels and significantly reduce carbon emissions. This transition can help mitigate the impact of climate change and promote a more sustainable future.

4. Industry: Oxy-hydrogen generators play a vital role in a variety of industrial applications such as glass production, chemical manufacturing, and healthcare facilities where a dependable and pure gas supply is needed.

Benefits of Oxy-Hydrogen Technology

1. Eco-friendly: The production of oxy-hydrogen generates no harmful substances, making it a clean and renewable energy option that helps decrease greenhouse gas emissions and minimize environmental harm.
2. Strong Energy Content: Oxy-hydrogen gas possesses a high energy content, rendering it an effective and adaptable energy source suitable for various purposes.
3. Secure: Oxy-hydrogen gas is easier to store and transport compared to compressed hydrogen gas, as it is created when needed and can be utilized without the need for high-pressure storage.
4. Energy Self-Sufficiency: The production of oxy-hydrogen enables decentralized hydrogen production, lessening reliance on imported fossil fuels and enhancing energy stability.

Hydrox Systems :

Hydrox Hydrogen Systems utilize the electrolysis technique to generate HHO gas. Through extensive research and development spanning more than ten years, we have enhanced the efficiency of this production method. By applying minimal electrical power, we are able to effectively separate the Hydrogen and Oxygen molecules in water. This has led to a significant efficiency improvement of more than 30% compared to traditional electrolysis cells. The key elements required for the production of HHO gas from water are Electrolyte and electricity.

The Oxy-hydrogen gas has different applications:

Enriching the air-fuel mixture of internal combustion engines with Oxy-Hydrogen gas significantly reduces carbon emissions by 78% and enhances fuel efficiency by up to 30%. Hydrogen also improves the combustion process in industrial settings, such as gas and CNG/LNG boilers, industrial furnaces, welding, and soldering of various materials. Additionally, hydrogen can be used for waste destruction, including medical and nuclear waste, and for heating purposes in both households and industries.

Hydrox Systems, (distributed in Australasia by H2-Hybrid ltd) is  top global manufacturer known for its Hydrogen Generators designed to cater to a wide range of requirements. Their products include Hydrogen- On-Demand Systems for a variety of vehicles and equipment like cars, vans, trucks, buses, diesel-powered gensets, Agro machinery, Marine vessels, construction machinery, and mining machinery.

What comes with Hydrox HHO Kits?

Reduction of Carbon Particles by 78%

Save up to 35% on fuel costs

Increased torque by 20%

 

Energy Density of some Combustibles

Source:  https://transportgeography.org/

Chemical Energy Content of some Fuels in MJkg

Information derived from the Energy density Extended Reference Table on Wikipedia was utilized.

Various types of fuels possess different levels of energy density, which can be quantified by the amount of energy released during combustion. Energy density refers to the quantity of energy that can be liberated by a specific mass or volume of fuel. This can be expressed as either gravimetric energy density (per of mass) or volumetric energy density (per unit of volume). Gravimetric energy density is important for comparing the energy efficiency of fuels, whereas volumetric energy density is crucial when evaluating transportation methods since storage capacity is required to carry the fuel needed to power a vehicle. The quality of a fuel is directly linked to its energy density, with higher quality fuels typically having greater energy density and lower chemical complexity. Gaseous fuels are considered high-quality, solid fuels are low-quality, and liquid fuels fall in between. Hydrogen, the simplest chemical element, boasts the highest energy density among fuels.

Gasoline, obtained through the process of refining crude oil, possesses significantly higher energy content compared to coal (twice that of lower grade bituminous coal) or wood (three times as much). Liquid natural gas (LNG) is predominantly made up of methane, while about 85% of natural gas consists of methane. Jet A-1 serves as the primary fuel choice for commercial jet aircraft, primarily consisting of kerosene along with various additives (such as antifreeze, antioxidant, and antistatic agents) to meet strict requirements for high-altitude and low-temperature conditions. On the other hand, Bunker C fuel, commonly used in maritime shipping, is considered one of the poorest quality liquid fuels but is suitable for powering large ship engines.

Even though methane and hydrogen contain more energy per unit volume compared to gasoline, their gaseous nature makes storage problematic. Additionally, hydrogen production involves energy-intensive synthesis. Achieving a 100% conversion rate would necessitate 100 hours to harness solar energy equal to 1 kg of gasoline per square meter. Ammonia (NH3) has been proposed as an alternative fuel option, particularly for maritime transport, because it can be stored in liquid form. However, it has roughly half the energy density of conventional fossil fuels like gasoline. Despite the lithium battery being one of the most effective electricity storage solutions, it can store only around 0.5 MJ per kilogram, highlighting the obstacles in developing electric vehicles. Nonetheless, advancements are being made, with certain lithium batteries approaching 1 MJ/kg.