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Description
The main features of the range are:
- Units capable of providing water at 75°C even with temperatures of -10°C and below.
- Designed with robustness, reliability, and low maintenance costs as key principles.
- Refrigerant R1243ze, HFO with a GWP close to zero, meaning virtually CO2 emissions-free and thus with long-term market viability.
- Durable semi-hermetic compressors.
- Refrigeration coils made of copper tubing with aluminium fins with anti-corrosion treatment.
- Refrigeration circuit in a closed and insulated compartment to protect it from weather-related wear and to prevent heat loss.
- Components and circuits that are easily repairable and cost-effective to maintain.
- Stainless steel brazed plate heat exchanger.
- Evaporation pressure control through continuous variable fan speed (EC).
- Electronic control with Modbus and IP communication (allows free remote management via a web browser) and a remote-mountable display with natural language messages. Stores historical data on machine operation and alerts.
- Digital flow meter integrated into the electronic control, allowing verification of correct water flow at all times.
Versions with mechanical power modulation (cylinder unloading) and inverter, with continuous modulation through frequency variation.
THE HEAT PUMP, KEY IN THE FIGHT AGAINST CLIMATE CHANGE
The heat pump plays a crucial role in decarbonising human activity and combating climate change for three reasons. Firstly, it harnesses heat from renewable sources, such as the atmosphere and ground, which ultimately derives from the sun. Secondly, the energy powering heat pumps is not derived 100% from fossil fuels, as with traditional heating systems; “zero emissions” electricity now accounts for more than 75% of the national total. Thirdly, heat pumps have a significantly higher primary energy efficiency than traditional heating systems.
Their efficiency in heat production and transfer makes heat pumps a vital alternative for more sustainable heating and cooling systems. Promoting their use advances us towards a cleaner, more resilient energy future, reducing our dependence on fossil fuels and mitigating climate change. Thus, the widespread adoption of heat pumps is a fundamental step towards greener, more responsible energy production.
THE NEED FOR HIGH-TEMPERATURE HEAT PUMPS
The availability and low cost of traditional heating systems have hindered the widespread development of high-temperature heat pumps, capable of producing water at temperatures between 55 and 75°C (and above). However, the growing awareness of the planet’s climate situation and the need to reduce greenhouse gas emissions, particularly CO2, has driven the development of these machines to meet domestic, commercial, and industrial needs for DHW production and other heating services.
