Functions
Heating:
In heating mode, the heat pump absorbs low-temperature heat energy from the external environment, such as air, water, or soil.
By compressing the working fluid, raising its temperature, and then releasing high-temperature heat energy, the heat pump elevates the indoor temperature in a building or contributes to a hot water system.
This makes the heat pump an efficient heating system, particularly in warmer climates where low-temperature heat can be extracted from the air or water.
Cooling:
In cooling mode, the operation of the heat pump is reversed, absorbing high-temperature heat energy from the indoor environment.
Through the expansion and evaporation of the working fluid, high-temperature heat energy is absorbed and carried away, then released into the external environment.
This process lowers the indoor temperature, providing air conditioning. The cooling function enables the heat pump to be a year-round device, offering cooling services in the summer.
Hot Water Supply:
The heat pump can also be used for producing hot water, suitable for residential hot water supply or commercial hot water systems.
In this mode, the heat pump absorbs heat energy from the environment, uses it to heat water, and then delivers the heated water to places requiring hot water, such as bathrooms or kitchens.
This functionality makes the heat pump an environmentally friendly and efficient solution for hot water supply, replacing traditional water heaters.
Advantage
Utilization of Renewable Energy:
The system harnesses solar energy through photovoltaic panels, converting it into electrical energy. This means that the primary energy source for the system is renewable and pollution-free solar energy, contributing to a reduction in dependence on finite resources and lowering greenhouse gas emissions.
Efficient Energy Utilization:
By employing heat pump technology to extract low-temperature heat energy from the environment and upgrading it to high-temperature heat energy for heating, cooling, or hot water, the system achieves relatively high energy utilization efficiency.
Energy Saving and Reduced Consumption:
Compared to traditional heating, air conditioning, and water heating systems, photovoltaic solar thermal pump systems are typically more energy-efficient. The system can flexibly switch between heating and cooling modes, providing the same or higher levels of comfort with lower energy consumption.
Year-Round Performance:
The system has year-round performance capabilities, providing heating during the colder seasons and cooling during the warmer seasons. This makes the photovoltaic solar thermal pump system a versatile, year-round energy solution.
Lower Energy Bills:
By harnessing solar energy and combining it with heat pump technology, the system can significantly reduce energy bills. The natural absorption of solar energy allows the heat pump to provide comfort while reducing reliance on the conventional power grid.
Environmentally Friendly:
The use of a photovoltaic solar thermal pump system reduces the demand for fossil fuels, helping to lower greenhouse gas emissions, mitigate the impacts of climate change, and contribute to a more environmentally friendly approach.
Sustainable Development:
Adopting a photovoltaic solar thermal pump system aligns with the principles of sustainable development, guiding society toward a more sustainable future in terms of energy.
Solar Panels Suggested Connection table
The Solar Panels Quantity For Each Horse Power Heat Pump
1.The above data is for reference only, the specific data is subject to actual product
2.ln the best case, the electricity generated by photovoltaic panels meets 90% of the consumption of heat pumps
3.Single phase Max DC 400V Input / Minimum DC 200V nput / Three phase Max DC 600V Input / Minimum DC 300V input
Heat Pump Parameters
DC Inverter heat pump | FLM-AH-002HC32 | FLM-AH-003HC32 | FLM-AH-005HC32S | FLM-AH-006HC32S | |
Heating capacity (A7C/W35C) | w | 8200 | 11000 | 16500 | 20000 |
Input power (A7C/W35C) | w | 1880 | 2600 | 3850 | 4650 |
Rated setting water temperature | °C | DHW: 45℃ / Heating: 35℃ / Cooling: 18℃ | |||
Voltage | v/hz | 220V-240V - 50Hz- 1N | 380V-415V ~ 50Hz~ 3N | ||
Max water outlet temperature | °C | 60℃ | |||
Refrigeration | R32 | R32 | R32 | R32 | |
Control mode | Heating / Cooling / DHW / Heating+DHW/ Cooling+DHW | ||||
Compressor | Panasonic DC Inverter Compressor | ||||
Operation ambient temperature | (-25℃ -- 43℃) | (-25℃ -- 43℃) | (-25℃ -- 43℃) | (-25℃ -- 43℃) |