Kolant Smart Mushroom cultivation heat pump and growing cabin
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Allows for setting different controllable growth environment time ranges and curves for different products.
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Automatically adjusts temperature , humidity, CO2 concentration, light exposure time , automatic irrigation , fresh air supply , and sterilization
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Less Manual Work, Smarter Management:
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Интеллектуальное управление через Wi-Fi
Мы получили сертификаты: TUV ISO9001, ISO45001 (здоровье и безопасность), ISO14001 (окружающая среда), TUV EN14825 (A+++), TUV CE , TUV CB, 38 патентов на технику производства, 66 сертификатов о наградах от правительства.
The heat pump for mushroom cultivation drives the compressor with electricity to absorb heat from the outside air, which is then released into the cultivation shed through the condenser. Meanwhile, it can adjust humidity, accurately maintaining the constant temperature and humidity environment required for mushroom growth, featuring energy efficiency and stable temperature control.
The core feature of the integrated planting heat pump unit is that it integrates heating, cooling, dehumidification and other functions, which can accurately regulate the planting environment and is more energy-efficient compared with traditional equipment.
Highly integrated functions, simplifying the system
There is no need to separately match air conditioners, dehumidifiers, boilers and other equipment; one machine can meet the core needs for temperature and humidity during the planting process.
Some models can also be equipped with additional fresh air and air purification functions, reducing the risk of pests and diseases in the planting environment.
Precisely controllable environment, adapting to crop needs
Wide temperature control range: According to the needs of different crops (such as leafy vegetables, flowers, seedlings), the ambient temperature can be stabilized in the range of 5℃-35℃ or even wider, without being affected by external weather.
More efficient humidity regulation: Through internal circulation dehumidification of the system, it avoids severe temperature fluctuations caused by traditional dehumidification methods and keeps the ambient humidity stable in the suitable range of 40%-80%.
Energy conservation and consumption reduction, lowering long-term costs
Mushrooms have extremely high demands on environmental parameters such as temperature, humidity, and CO₂ concentration. The core value of the all-in-one machine lies in solving environmental control issues in one stop.
Automatically adjusts temperature , humidity
It can precisely adjust the temperature (usually controlled between 5-25℃) and humidity (80%-95%) according to the growth stages of different mushroom varieties (such as avoiding yield reduction or quality degradation caused by environmental fluctuations.
CO₂ concentration adjustment
Some high-end models are equipped with a built-in CO₂ enrichment or ventilation system, which meets the gas environment needs of mushroom mycelium and fruiting body growth, and promotes the improvement of growth rate and yield.
Automatic operation
Automatic operation: No frequent manual adjustment is required. After setting parameters through the intelligent panel, it operates automatically, reducing labor input, and is especially suitable for large-scale cultivation scenarios.
Light exposure
Equipped with an ultra-wide spectrum lighting configuration, it can control light of different wavelengths and durations according to different mushroom species and different growth stages, providing better lighting needs, improving light utilization efficiency, and promoting the increase of mushroom yield and quality.
Automatic irrigation
The combined humidification method using ultrasonic waves and high-pressure micro-mist features strong humidification intensity, high efficiency, small water mist particles, and uniform distribution, which can meet the humidity requirements of different types of mushrooms.
Fresh air supply , and sterilization
It provides clean fresh air, which undergoes sterilization treatment to eliminate harmful substances such as flying insects, dust, and miscellaneous bacteria. At the same time, it controls the indoor carbon dioxide concentration to create an environment suitable for mushroom growth. An intelligent variable-frequency fan is adopted, which can input fresh air on demand for energy-saving optimization
WIFI Control system
Equipped with built-in WIFI functionality, this device enables seamless remote control of the planting equipment and offers real-time monitoring of key environmental parameters in the grow room. You can check and track the ambient temperature, relative humidity, and CO2 concentration anytime and anywhere, with accurate data feedback to ensure the optimal growing environment for plants and precise regulation of cultivation conditions.
Reducing Cultivation Expenses in the Long Term
Significantly reduce energy costs Compared with traditional electric heating and gas boilers, the heating efficiency of heat pumps is 3-4 times that of electric heating and more than 30% more energy-efficient than gas boilers. Taking a 1000㎡ greenhouse as an example, the monthly electricity/gas fees for winter heating can be saved by 5,000-10,000 yuan, and the annual energy cost can be reduced by 40%-60%.
Increase crop yield and commodity rate A stable temperature and humidity environment can reduce yield losses caused by extreme weather (such as low-temperature freezing damage, high temperature and high humidity) and reduce the incidence of diseases and pests. Under normal circumstances, the yield of vegetables can be increased by 15%-30%, and the flowering rate and quality compliance rate of flowers can be increased by more than 20%, directly increasing sales revenue.
Prolong the planting cycle and achieve off-season profits Not restricted by external climate, it is possible to grow heat-loving crops (such as tomatoes, cucumbers) in winter and cool-loving crops (such as lettuce, strawberries) in summer, seizing the high-price period of the off-season market. The profit per product can usually be increased by 50%-100%.
Приложения
Технические данные
| Модель | KRF-360H/SN2-BPEEVI | KRF-210*2H/SN2-EVI | KRF-150H/N2-BPEEVI | KRF-250H/N2-BPEEVI | ||||
| Источник питания | 380V~50HZ | 380V~50HZ | 380V~50HZ | 380V~50HZ | ||||
| Стандартная мощность нагрева | 36,0 кВт | Условия испытания A7/6°C A30/35°C |
42.0 kW | Условия испытания | 15.6 kW | Условия испытания A7/6°C A30/35°C |
25,0 кВт | Условия испытания A7/6°C A30/35°C |
| Номинальная входная мощность | 10,0 кВт | 11.7 kW | A7/6°C | 4.19 kW | 6,75 кВт | |||
| КС | 3.6 | 3.6 | A30/35°C | 3.72 | 3.7 | |||
| Low ambient heating capacity | 25,0 кВт | Условия испытания A-12/-°C A30/35°C |
29.0 kW | Условия испытания | 10,6 кВт | Условия испытания A-12/-°C A30/35°C |
17,0 кВт | Условия испытания A-12/-°C A30/35°C |
| Low ambient input power | 10,6 кВт | 12.3 kW | A-12/-°C | 4.4 kW | 7.08 кВт | |||
| Low ambient COP | 2.36 | 2.36 | A30/35°C | 2.41 | 2.4 | |||
| Номинальная холодопроизводительность | 31,0 кВт | Условия испытания A35/24°C A24/19°C |
36,0 кВт | Условия испытания | 15.0 kW | Условия испытания A35/24°C A24/19°C |
24,0 кВт | Условия испытания A35/24°C A24/19°C |
| Номинальная потребляемая мощность охлаждения | 12,2 кВт | 14.1 kW | A35/24°C | 5.66 kW | 9.16 кВт | |||
| Номинальный EER охлаждения | 2.55 | 2.55 | A24/19°C | 2.65 | 2.62 | |||
| Максимальный рабочий ток | 18.8A | 28A | 28A | 14.1A | ||||
| Максимальная рабочая потребляемая мощность | 12,5 кВт | 16.5kW | 16.5kW | 9,23 кВт | ||||
| Класс водонепроницаемости | IPX4 | IPX4 | IPX4 | IPX4 | ||||
| Защита от поражения электрическим током | I | I | I | I | ||||
| Допустимое давление нагнетания/всасывания | 4.2MPa/1.5MPa | 4.2MPa/1.5MPa | 4.2MPa/1.5MPa | 4.2MPa/1.5MPa | ||||
| Максимальное высокое/низкое давление | 4.2MPa/1.5MPa | 4.2MPa/1.5MPa | 4.2MPa/1.5MPa | 4.2MPa/1.5MPa | ||||
| Шум | 65 дБ (A) | 65 дБ (A) | 65 дБ (A) | 60 dB | ||||
| Тип/объем хладагента | R410a/7000g | R410a/4000g*2 | R410a/4000g | R410a/6300g | ||||
| Размер блока | 1808*800*1346mm | 1993*923*1456mm | 1035*860*1840mm | 1035*860*1840mm | ||||
| Вес единицы | 170 кг | 360 kg | 122 kg | 135 kg | ||||
