Kolant Solar PV direct drive Solar Heat Pump
Photovoltaic and network power are connected to heat pump power supply at the same time, and the green power is directly driven. No need inverter or transformer to change solar DC electricity to AC power. So the efficiency will be higher than normal heat pump. The green solar power can be tracked in real time and given priority. When the photovoltaic output is insufficient, the electricity network power can be automatically introduced to ensure the stability of the unit. When there is no solar electricity at all, it can be driven only by grid power, and the system can be intelligently controlled and supervised remotely. In the whole process, no need battery.
Kolant Cross-industry integrated new energy
uses innovative green energy modes such as solar power generation, wind energy storage and photovoltaic power storage with heat pump energy consumption, realizing seamless switching between dual power inputs, giving priority to photovoltaic energy without secondary conversion, greatly reducing the energy consumption . Kolant solar PV direct drive heat pump is the first choice for green energy saving.
Kolant Enthalpy-Increasing and Inverter technology
Ultra-low temperature and more energy-saving at -35℃ stable operation,
multi-energy integration scheme,
quieter and more comfortable,
multi-noise reduction,
less temperature fluctuation.
Kolant Solar PV direct drive solar heat pump Striking characters distinguishing from other products.
Sunny mode, zero electricity cost for cooling/heating and DHW.
When the weather is sunny, and the photovoltaic system can fully meet all the electricity demand, realizing “zero electricity fee” for cooling/heating. Intelligent compensation system for photovoltaic power generation in power grid
Cloudy mode, intelligent compensation, zero worry.
In rainy weather, when the sunshine is insufficient, the photovoltaic system provides a power grid to supplement photovoltaic power generation and sub-supply, and intelligently compensates the commercial power to ensure the stable operation of the unit.
Night mode, direct power supply from power grid.
During the night, the photovoltaic power generation system does not generate electricity, and the power grid compensates the power grid to supplement all the power supply of photovoltaic power generation, and the energy consumption is equivalent to that of the conventional inverter heat pump.
Wifi control
El sistema de control de la bomba de calor se puede controlar a distancia mediante APP móvil a través del servidor en la nube
Save Energy
Saves 75% power consumption compared with traditional electric water heater,0 cost during sunny day, .
Environmental
Environmentally-friendly refrigerants R410A/R32, and the COP energy efficiency ratio is as high as 10 when running at low speed.
Stable
The water and electricity are separated, and multiple protections are provided. It still runs stably in the cold climate of-35 C with ultra-low noise and a full DC fan motor, which has a longer service life.
All in one
The heat pump has a dedicated high-efficiency compressor to realize the three functions of heating, cooling and hot water.
Modbus
Incorpora el protocolo Modbus para que el distribuidor o el cliente puedan utilizar cualquier otro controlador para controlar la bomba de calor.
Bomba de calor solar fotovoltaica de accionamiento directo Especificación
| Modelos | Temperatura del aire/temperatura del agua de salida | GFRB-85H/N8 -BBPEEVI | COP | GFRB-110H/N8 -BBPEEVI | COP | GFRB-150H/N8 -BBPEEVI | COP | GFRB-185H/N8 -BBPEEVI | COP | GFRB-240H/N8 -BBPEEVI | COP |
| Heating capacity/Power input (KW) | a A20/W35°C | 10.6/1.89 | 5.61 | 14.42/2.88 | 5.01 | 21.1/3.89 | 5.42 | 22.8/4.4 | 5.18 | 29.5/6.01 | 4.91 |
| a A7/W35°C | 8.59/1.87 | 4.59 | 10.6/2.55 | 4.16 | 14.7/3.31 | 4.44 | 18.8/4.4 | 4.27 | 23.1/5.34 | 4.33 | |
| a A7/W45°C | 7.91/2.23 | 3.55 | 9.97/3.14 | 3.18 | 13.5/4.1 | 3.29 | 17.8/5.24 | 3.4 | 22.6/6.11 | 3.7 | |
| a A2/W35°C | 7.65/1.81 | 4.23 | 9.54/2.49 | 3.83 | 13.08/3.21 | 4.07 | 16.92/4.31 | 3.93 | 20.29/5.38 | 3.77 | |
| a A2/W45°C | 7.04/2.15 | 3.27 | 8.97/3.06 | 2.93 | 12.02/3.97 | 3.03 | 16/5.12 | 3.13 | 18.7/6.4 | 2.92 | |
| a A-12/W41°C | 5.9/2.45 | 2.41 | 6.3/2.7 | 2.33 | 10.2/4.35 | 2.34 | 11.6/5.04 | 2.3 | 14.7/5.88 | 2.5 | |
| a A-20/W41°C | 5.4/2.56 | 2.11 | 5.61/2.72 | 2.06 | 8.9/4.23 | 2.1 | 10.5/4.97 | 2.11 | 13.7/5.78 | 2.37 | |
| Cooling Capacity/Power input(KW) | a A35/ W18ºC | 9.2/2.7 | 3.41 | 11/3.3 | 3.33 | 13.9/4.2 | 3.31 | 15.6/4.8 | 3.25 | 20.1/6.2 | 3.24 |
| a A35/W7ºC | 7.2/2.73 | 2.64 | 8.6/3.4 | 2.53 | 9.8/3.77 | 2.6 | 10.5/4.2 | 2.5 | 13.5/5.09 | 2.65 | |
| Max.current (A) | 18 | 19 | 28 | 14.3 | 18.1 | ||||||
| Max power input | 4KW | 5KW | 6KW | 7KW | 9KW | ||||||
| Solar working max voltage | 340VDC | ||||||||||
| Suministro eléctrico | 230V/50~60HZ | 400V/50~60HZ | 400V/50~60HZ | ||||||||
| Max.Outlet water temperature | 60oC | ||||||||||
| Working temperature range (°C) | -30 ~ 43 | ||||||||||
| Circuito refrigerante | Refrigerante | R32 | |||||||||
| DC Inverter compressor | MITSUBISHI | MITSUBISHI | MITSUBISHI | MITSUBISHI | MITSUBISHI | ||||||
| Intercambio de calor | Aleta de cobre y aluminio hidrófilo | ||||||||||
| Air flow (m3/h) | 2400 | 5800 | 6000 | 7000 | |||||||
| Circuito de agua | Intercambiador de calor | Intercambiador de calor de tubo en carcasa de alto rendimiento | |||||||||
| Inlet/Outlet pipe size | DN25(G1″) | DN25(G1″) | DN25(G1″) | DN25(G1″) | DN25(G1″) | ||||||
| Caudal de agua (m3/h) | ≥1.5 | ≥1.8 | ≥2.5 | ≥3 | ≥3.9 | ||||||
| presión permitida | ≤0,8MPa | ||||||||||
| Dimensiones de la unidad AnxAlxPr (mm) | 960*820*380 | 960*820*380 | 960*1270*380 | 960*1270*380 | 1030*1340*390 | ||||||
| Pakage dimensions WxHxD (mm) | 1040*940*502 | 1040*940*502 | 1040*1390*502 | 1040*1390*502 | 1115*1510*510 | ||||||
| Peso neto (Kg) | 68 | 68 | 108 | 108 | 128 | ||||||
| Peso bruto (Kg) | 85 | 85 | 125 | 125 | 145 | ||||||
| Nivel de ruido (dB(A)) | 56 | 56 | 59 | 59 | 60 | ||||||
| Loading quantity for 20’/40′ container | 44/88 | 44/88 | 22/44 | 22/44 | 22/44 | ||||||
Referencia del proyecto de instalación de la bomba de calor Kolant
