Have Any Questions?
+1 (416) 333-9306
Mail Us
info@penergy3.com
Our Working Hours
Mon - Fri: 09:00 - 17:00
+1 (416) 333-9306
info@penergy3.com
Mon - Fri: 09:00 - 17:00
PE3 or Penergy3.com is a cutting-edge company specializing in the conversion of end-of-life plastics into clean, road-ready fuels using innovative pyrolysis technology. Our closed-loop system ensures zero emissions while generating valuable fuel products from waste plastics.
Our state-of-the-art plant utilizes pyrolysis to convert garbage plastics, excluding PVC, into usable fuels. The plastics are subjected to high temperatures in a turbine combustor operating at 1200 degrees Celsius, breaking them down into gases, liquids, and solid residues. Through a specific recipe format, we achieve consistent Ultra Low Sulfur Diesel (ULSD) and Unleaded Gasoline (ULP) that meet ASTM requirements for road-ready fuel.
Each machine in our plant has a footprint of 7500 square feet and can consume 55 tons per day of garbage plastics, ensuring efficient and high-volume production of clean fuels.
For every ton of plastics converted, there is a 75/25% split between ULSD and ULP fuels. Additionally, a non-condensable gas byproduct is captured to yield the heat units required to power the entire system's heat and electrical needs.
Our closed-loop system ensures zero emissions, contributing to a cleaner environment. By utilizing garbage plastics found in the sea, land, or landfills, we not only reduce plastic waste but also promote recycling initiatives.
With each ton of plastics converted, the PE3 plant yields approximately 10,890 gallons of ULSD and 3,630 gallons of ULP per day, totaling 14,520 gallons/day of fuel. This translates to approximately 1,937,356,410 BTUs/day or 23.66 MW/day, providing a substantial energy output in an environmentally friendly manner.
By collaborating with PE3, businesses and communities can contribute to sustainable waste management practices while also gaining access to valuable, road-ready fuels. Our innovative technology offers a profitable and environmentally friendly solution to plastic waste challenges.
An Aerothermal ice rink utilizes an air-source heat pump, also known as an Aerothermal system, to efficiently regulate the ice surface temperature. This system extracts heat from the ambient air to heat or cool the ice.
Aerothermal heating provides an energy-efficient solution for maintaining the ice surface temperature. By utilizing the heat in the surrounding air, it helps reduce operational costs and contributes to sustainable ice rink management.
Yes, Aerothermal ice rinks can be designed to operate year-round. The system can be reversed to provide cooling during warmer months, allowing for diverse usage beyond traditional ice-related activities.
Aerothermal ice rinks are considered environmentally friendly as they leverage ambient air for temperature control, reducing reliance on traditional heating and cooling methods. This results in lower energy consumption and reduced environmental impact.
While the initial installation costs of Aerothermal systems may be competitive, their long-term cost-effectiveness stems from lower energy consumption and operational efficiency. Aerothermal ice rinks can offer savings over time compared to traditional systems.
An Aerothermal HVAC system, also known as an air-source heat pump, uses ambient air to provide both heating and cooling for residential and commercial buildings.
Aerothermal heating involves extracting heat from the outside air and transferring it into a building using a refrigerant-based heat pump.
Yes, Aerothermal systems can be reversed to provide cooling during warm weather. They transfer heat from the building to the outside air.
The main components include an outdoor unit (containing a compressor and heat exchanger), an indoor unit (evaporator), and a distribution system (ductwork or wall-mounted units).
Yes, Aerothermal systems are energy-efficient, especially in moderate climates. They can provide more energy-efficient heating compared to traditional resistance heating systems.
While they use electricity, Aerothermal systems are considered environmentally friendly as they produce fewer greenhouse gas emissions compared to traditional heating systems.
Aerothermal systems are designed to operate quietly. Modern units have features to minimize noise, and proper installation can further reduce sound levels.
The lifespan of an Aerothermal system is typically around 15 to 20 years, with proper maintenance. Regular servicing can extend the system's life.
Aerothermal systems are versatile and can be used in various climates, but their efficiency may decrease in extremely cold climates.
Aerothermal systems generally require regular maintenance, including filter changes and periodic inspections. Proper maintenance ensures optimal performance.
Yes, Aerothermal systems can be used in conjunction with other heating methods, such as electric resistance heating or backup fossil fuel systems, for increased efficiency.
Many locations offer incentives, rebates, or tax credits for installing energy-efficient Aerothermal HVAC systems, making them more cost-effective.
Yes, Aerothermal systems are often suitable for retrofitting existing buildings. Proper sizing and installation are crucial for optimal performance.
Some Aerothermal systems can be configured to provide hot water in addition to space heating and cooling.
The payback period for Aerothermal systems varies but is often relatively short, depending on factors such as energy prices, system efficiency, and available incentives.
A Geothermal HVAC system uses the Earth's consistent temperature to heat and cool buildings. It relies on a network of underground pipes filled with a heat transfer fluid to exchange heat with the ground.
Geothermal heating involves extracting heat from the Earth through the geothermal loop and transferring it to the building using a heat pump.
Yes, geothermal systems can be reversed to provide cooling during hot weather. They transfer heat from the building to the cooler Earth.
The main components include a heat pump, a ground heat exchanger (geothermal loop), and a distribution system (ductwork or radiant heating/cooling).
Geothermal wells can vary in depth, but they are typically drilled between 100 to 400 feet deep, depending on factors like soil and rock conditions.
Yes, geothermal systems are considered environmentally friendly as they use renewable energy from the Earth and have lower carbon emissions compared to traditional HVAC systems.
Geothermal systems can achieve significant energy savings, typically between 25% to 50% compared to traditional HVAC systems.
Geothermal systems have a longer lifespan than traditional HVAC systems, often exceeding 20 years for the heat pump and 50 years for the ground loop
Geothermal systems have a longer lifespan than traditional HVAC systems, often exceeding 20 years for the heat pump and 50 years for the ground loop
Geothermal systems are typically quieter than traditional air-source heat pumps as the noisy components are located underground.
Geothermal systems generally require less maintenance than traditional systems. The underground components are durable, and the systems have fewer moving parts.
Yes, geothermal systems can be integrated with solar power to create a hybrid system, further reducing energy costs.
In many locations, there are incentives, rebates, and tax credits available for installing geothermal HVAC systems, making them more financially attractive.
Yes, existing buildings can be retrofitted with geothermal systems. The feasibility depends on available space and soil conditions.
The payback period for geothermal systems varies but is often around 5 to 10 years, considering energy savings and available incentives.
Certainly! Here are 5 frequently asked questions (FAQs) about geothermal process refrigeration and heat recovery along with their answers:
Geothermal process refrigeration and heat recovery involve utilizing geothermal energy to drive refrigeration processes while simultaneously recovering and utilizing waste heat for other applications.
Geothermal heat is harnessed to drive the refrigeration cycle for cooling purposes. The waste heat generated during this process is captured and utilized for heating or other industrial processes, enhancing overall energy efficiency.
Various industrial processes, including food processing, manufacturing, and greenhouse operations, can benefit from geothermal heat recovery. The captured waste heat can be used for space heating, water heating, or other applications.
Geothermal heat recovery is environmentally friendly as it maximizes the use of renewable geothermal energy and minimizes the reliance on conventional heating and cooling methods, resulting in reduced carbon emissions.
While geothermal resources are more abundant in certain regions, geothermal process refrigeration and heat recovery can be adapted to various locations. The feasibility depends on geological conditions and the specific needs of the industrial processes.
Aerothermal process refrigeration and heat recovery involve using air-source heat pumps to drive refrigeration processes while simultaneously capturing and utilizing waste heat for other industrial applications.
Air-source heat pumps extract heat from the surrounding air to drive the refrigeration cycle for cooling. The waste heat generated during this process is recovered and used for additional heating or other industrial processes.
Various industrial processes, such as manufacturing and heating applications, can benefit from aerothermal heat recovery. The captured waste heat can be utilized for space heating, water heating, or other thermal processes.
Aerothermal heat recovery is considered environmentally friendly as it maximizes the use of renewable energy from the air, reducing reliance on conventional heating and cooling methods and lowering carbon emissions.
Aerothermal systems can be adapted to various locations, making them versatile. However, their efficiency may vary based on climate conditions, and factors like temperature extremes can impact performance.