Aug. 19, 2024
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Concerned about rising energy costs? Want a high-efficiency heating and cooling solution at a reasonable cost?
EVI Air to Water Heat Pump
is the best choiceHeat pumps are a proven technology that has been used for decades, both in Canada and globally, to efficiently provide heating, cooling, and hot water to buildings.
The Hydron-Aire EVI Air to Water Heat Pump is Manitoba&#;s most efficient air source solution on the market today. It has approximately 3 to 4 times greater thermal efficiency than natural gas and uses innovative hydronic technology to supply energy to your home, including:
&#; Both heating and cooling; no need for a separate air conditioning unit
&#; Radiant floor heating and cooling
&#; Domestic hot water
Together, these products create a system that allows for multiple comfort zones to be maintained more efficiently than traditional systems. EVi is suitable for residential and commercial new builds or retrofits.
Let us design the perfect solution for your next project!
Discover Our Products &#;As the world collectively shifts towards sustainable solutions, industries are seeking innovative ways to reduce their environmental impact. In the realm of heating and cooling, the Enhanced Vapor Injection (EVI) heat pump has emerged as a promising technology. Hydron Aire Ltd., a pioneer in HVAC solutions, is at the forefront of this revolution.
Contact us to discuss your requirements of Eco-friendly heating evi heat pump solution. Our experienced sales team can help you identify the options that best suit your needs.
Enhanced Vapor Injection Heat Pumps are a remarkable advancement in heating technology. They build upon the foundation of traditional heat pumps, enhancing efficiency and performance, especially in colder climates. Unlike standard heat pumps, EVI heat pumps are designed to extract heat from the environment even when outdoor temperatures plummet, making them ideal for regions with harsh winters.
Higher Efficiency: EVI heat pumps are designed to operate efficiently even in extreme conditions. By using advanced refrigeration cycles and compressor technologies, they can extract heat from the outdoor air and deliver it indoors, even when temperatures are well below freezing. This results in consistent and reliable heating performance.
Energy Savings: The improved efficiency of EVI heat pumps translates to energy savings for consumers. By utilizing a heat source that is readily available&#;ambient air&#;the technology significantly reduces reliance on fossil fuels for heating, thus lowering carbon emissions and energy costs.
Environmental Friendliness: With the world&#;s growing concern for the environment, switching to EVI heat pumps aligns with sustainability goals. These systems have a lower carbon footprint compared to traditional heating methods, making them a greener choice for residential and commercial spaces.
Versatility: EVI heat pumps offer both heating and cooling capabilities, providing year-round comfort. This dual functionality eliminates the need for separate heating and cooling systems, saving space and installation costs.
Longevity: Thanks to advancements in technology and design, EVI heat pumps are built to last. With proper maintenance, they can serve consumers reliably for many years, providing a high return on investment.
Potential Savings Over Time: Despite the initial investment, the energy savings offered by EVI heat pumps can offset the higher upfront costs. Over time, lower energy bills can contribute to a positive return on investment.
Hydron Aire Ltd.&#;s EVI air to water heat pumps present a remarkable opportunity for consumers to embrace an efficient, eco-friendly, and sustainable heating solution. While the initial investment and maintenance costs may require consideration, the long-term benefits&#;including energy savings, environmental consciousness, and year-round comfort&#;make the switch to EVI heat pumps a promising choice for a brighter and greener future. As technology continues to advance, EVI heat pumps could very well define the future of heating and cooling.
As shown in the above schematic, the liquid out of the condenser is separated into two parts. A smaller part of the liquid (i), is expanded through
an additional expansion valve, and then directed (or flows) into a counter-flow plate heat exchanger, HX. The main part of the liquid out of the
condenser (m), is then cooled down through the economizer while evaporating and superheating the injection mass flow. This additional plate
heat exchanger, more generally called economizer, acts therefore as a sub cooler for the main mass flow (m) and as an evaporator for the injection
mass flow. Superheated vapor is then injected into the intermediate vapor injection port in the scroll compressor.
The additional subcooling increases the evaporator capacity by reducing the temperature of the liquid from TLI to TLO, thus reducing its enthalpy.
The additional condenser mass flow (i), increases the heating capacity by the same amount.
Efficiency with vapor injection scroll compressor cycle is higher than that of a conventional single stage scroll delivering the same capacity because
the added capacity is achieved with proportionally less power. The injection mass flow created in the subcooling process is compressed only from
the higher inter-stage pressure rather than from the lower suction pressure.
The additional Sub-cooling effect of EVI configuration allows heat pump to draw heat from the outdoor at lower outdoor temperatures. That
could explain why DC inverter (Non EVI) Heat Pumps operate between -20&#;C and 45&#;C (Outdoor BD Temperatures) while DC Inverter EVI Heat
Pumps operate between -25&#;C and 45&#;C (Outdoor BD Temperatures).
For more information, please visit Inverter technology evi heat pump China.
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