Renewable

Heat exchanger integrated into the construction concrete structures of buildings, in the part where there is a concrete structure under the terrain.

This system allows geothermal activation of concrete foundation structures, underground walls, or Milan walls. Activated concrete structures serve as a geothermal absorber for supplying the building with heat and cold directly from their foundations.

The energy capacity of concrete underground structures basically depends on their volume.

– Suitable for low-temperature heating and cooling of buildings.

Heat exchanger for the use of the energy of the plot at a depth of 1-4 m below the surface of the terrain. Energokoše are a suitable solution for energy-independent houses located on smaller plots and are suitable for places where it is not possible to drill to greater depths.

– Basket diameter 2.4m/1.4m, height 2-2.7m, storage directly in the ground.

– Two types of basket sizes (150/200m pipe 32×2.9mm)

– The efficiency of Energokoš is influenced by the proportion of solar emitting energy and soil moisture.

– Suitable for low-temperature heating and cooling of buildings.

– Without the need for geological surveys or permits.

Heat exchanger integrated into the building foundations of buildings that are built on base piles for static reasons.

This system allows geothermal activation of both prefabricated concrete foundation piles, drilling and worm piles, or pilots concreted directly on the construction site. Energopilots serve as a geothermal absorber for supplying heat and cold to buildings directly from their foundations.

The capacity of energopilots basically depends on the cross-section of the pilot reinforcement skeleton.

– Suitable for low-temperature heating and cooling of buildings.

Heat exchanger for the use of the energy of the plot at a depth from 100m and below its surface. Extensive land is not required for installation and is a suitable solution for energy-independent houses.

– Constant temperature from 15m below ground and geothermal gradient 3°C/100m.

– Bore diameter 150-220mm, borehole depth in the range of 80-400m.

– Borehole spacing ideally 10m.

– The efficiency of the borehole is influenced by the geological subsoil and the quality of the injection mixture and the overall design.

– Suitable for low-temperature heating and cooling of buildings.

– The need for geological surveys, and a report or a mining permit.

– Geothermal borehole power ranges from 10 to 70 W/m, but can also reach 100 W/m.

Prefabricated heat exchanger for the use of the energy of the plot at a depth of 6-12 m below its surface. Extensive land is not required for installation and is a suitable solution for energy-independent houses, when it is necessary to limit the depth of the well. Functionality depends on the occurrence of groundwater.

– Ideal installation using a hollow worm drill.

– Diameter 260/360 mm, borehole depth 6/12m (other on request)

– Prefabricates have a pressure test with a certificate.

– The efficiency of the well is influenced by geological subsoil and the occurrence of groundwater.

– Suitable for low-temperature heating and cooling of buildings.

– The need for geological survey and report.

Heat exchanger for the use of the thermal energy of the plot at a depth below the building base plate. Area collectors under the foundation plate are a suitable solution for energy independent houses where the built-up area is the same as the size of the building plot.

– Diameter of special PE RC pipe d32-110, storage directly into the ground.

– Performance depends on the dimensions of the built-up area.

– Suitable for low-temperature heating and cooling of buildings.

– Without the need for geological surveys, and a report or permit.

 

Use of thermal energy of wastewater in sewer pipes under the surface of the terrain. PKS Thermpipe is a suitable solution for sewer networks not only of energy independent houses.

Wastewater has thermal potential and the PKS Thermpipe system is the logical and economical solution for its use.  At the same time, heat is also obtained from the soil that surrounds the sewer pipes in the ground.

PKS Thermpipe is further connected to an energy processing device in the technical room of the house.

The efficiency of the system is influenced by the location of the sewerage system, the temperature of the wastewater and the proportion of solar-emitting energy.

Use of thermal energy of your building plot for buildings whose concrete structure is built under the ground.

This system allows geothermal activation of concrete foundation structures, underground walls, or Milan walls. Activated concrete structures serve as a geothermal absorber for supplying the building with heat and cold directly from their foundations.

The advantage is lower input costs than for separate geothermal wells.

Use of the thermal energy of your plot at a depth of 1-4 m below the surface of the terrain. Energokoše are suitable for smaller plots and places where it is not possible to drill to greater depths.

Thanks to the conical shape of Energokoše, the volume of land is used even in a relatively small area of the garden. The advantage is easy installation without costly drilling.

Conical Energokoše are stored in the excavation and subsequently they are included back with earth. Energy-treatments are further connected to the power processing equipment in the engine room of your house.

The amount of Energokoš depends on the energy requirement. Installation is not subject to special permission.

Use of thermal energy of your building site under the surface of the terrain for buildings that are built on base piles for static reasons.

This system allows geothermal activation of both prefabricated concrete foundation piles, drilling and worm piles, or pilots concreted directly on the construction site. Energopilots serve as a geothermal absorber for supplying heat and cold to buildings directly from their foundations.

The advantage is lower input costs than for separate geothermal wells.

Use of the thermal energy of your plot at a depth of 6-12 m below its surface. Shallow geothermal borehole is the solution for situations where it is necessary to limit the depth of the well. It is suitable for places with the appearance of groundwater, and at the same time this technology does not lay claim to a large plot of land. The number of wells depends on the energy requirement of the house.

Vertical Thermpipe are 6m or 12m prefabricated elements that are installed in a drilled crevice on a diameter of 26 or 36 cm. Shallow borehole is further connected to the power processing equipment in your engine room. Drilling is subject to a report to the competent authority.

Use of the thermal energy of your plot at a depth of 100m and below its surface. Geothermal borehole has the advantage of an almost constant heat source, and at the same time this technology does not lay claim to a large plot of land. The number and depth of wells depends on the energy requirement of the house.

Geothermal probes are stored in the drilled slit with a maximum diameter of 22cm and are subsequently connected to the earth's meat by the injection mixture.  Geothermal borehole is further connected to the power processing equipment in your engine room.

Drilling is subject to a report to the competent authority. When drilling to greater depths, a high-level permit is required.

Use of the thermal energy of your property at a depth below the foundation plate of the building. The area collectors under the base plate are suitable for buildings where the built-up area is the same as the size of the building plot.

Horizontal distributions in 100m lengths are stored in the trench and are subsequently built up with a standard foundation plate. The area collectors are further connected to the power processing equipment in the engine room of your building.

The length of the wiring depends on the dimensions of the built-up area and the energy requirement of the building.

Use of thermal energy of wastewater in sewer pipes under the surface of the terrain. PKS Thermpipe is a suitable solution for sewer networks not only of energy independent houses.

Wastewater has thermal potential and the PKS Thermpipe system is the logical and economical solution for its use.  At the same time, heat is also obtained from the soil that surrounds the sewer pipes in the ground.

PKS Thermpipe is further connected to an energy processing device in the technical room of the house.

The efficiency of the system is influenced by the location of the sewerage system, the temperature of the wastewater and the proportion of solar-emitting energy.

This unit allows you to draw thermal energy from the air that is always around us. If possible, this unit can be located on the roof, façade, or on the grounds of the building.

The advantage of this unit is high efficiency, quiet operation with patented defrosting technology, which increases the coefficient of seasonal performance.

The outdoor air unit is further connected to the heat pump in the technical room of the building.

– Hydraulic connection without refrigerant.

– System functionality at temperatures up to -15°C.

– Ziehl-Abegg axial fan with high performance and quiet operation

- Fan speed control system

– Built-in system for hybrid use of the unit
– Patented defrosting technology
– Possibility of connecting multiple units to the jump

 

This unit allows you to draw thermal energy from the air that is always around us. If possible, this unit can be located on the roof, façade, or on the grounds of the building.

Thanks to our experience in developing innovative technologies, our outdoor unit boasts very quiet operation, high efficiency and a fan with controlled speed.

The compact design of the unit and its sparing design are complemented by patented defrosting technology. This is manifested by increased seasonal performance.

It also includes protection for operation in extreme weather conditions. This is also demonstrated by the guaranteed functionality of the system at temperatures of -15°C.

The outdoor air unit is further connected to the heat pump in the technical room of your building.

Heat exchanger for energy utilization of surface water sources in the vicinity of the realization. The Lima system is a suitable solution for energy-independent houses located around ponds, rivers or lakes.

For the required higher performance, the possibility of connecting several Units of the Lima system into the series.

– Installation by immersion in surface water.

– Temperature range -10°C to +40°C.

– Suitable for low-temperature heating and cooling of buildings.

– Installation is subject to approval by the administrator of a specific water source.

– Compact dimensions 1070x1120mm

Heat exchanger for the use of energy of underground water sources under the terrain of the plot. The system is a suitable solution for energy-independent houses located on plots that are rich in the appearance of groundwater.

For the required higher performance, the possibility of connecting several Units of the Lima system into the series.

– Principle of groundwater pumping in two wells.

– Groundwater temperature is constant year-round 7-12°C.

– Suitable for low-temperature heating and cooling of buildings.

– Installation is subject to approval by the administrator of a specific water source.

The use of thermal energy from ponds, lakes and rivers near your house. Lima is a special system for receiving energy from surface waters. The compact design is ideal for quick and easy installation.

Lima is made of eco-plastic with a long service life. For components, materials specially developed for rapid heat transfer are used. Lima is further connected to the power processing equipment in the engine room of your house.

For the required higher performance, the possibility of connecting several units of the Lima system in series. The installation is subject to approval by the administrator of a particular water source.

The use of thermal energy from groundwater beneath the surface of your property. This system for receiving thermal energy works on the principle of pumping groundwater from one well to another.

In the excavated boreholes of wider diameters, scabs are inserted, equipped with filter hoses and seals at the top. In the first well there is a submersible pump that pumps water into the power processing equipment. There, thermal energy is used, and through the second well the water is again soaked back into the ground.

The system for pumping geothermal energy from water achieves the highest heating effects. The system is suitable for places where there is enough groundwater. This system is not maintenance-free compared to others.

Installation is subject to permission by the administrator of a particular water source.

Hybrid system

This system allows you to cleverly draw thermal energy from air, earth or water depending on seasonal conditions and current energy efficiency.

It is therefore possible to choose from several principles of energy pumping. For example, it is possible to combine geothermal borehole with an outdoor air unit.  The advantage is economically used geothermal and aerothermal energy at different times of the year.

The hybrid system gives you the opportunity to reduce the number of geothermal wells or their depth. Also, in case of lack of space on the plot for a surface collector, the air unit can serve as a power reserve.

A plus of this system is also the more efficient regeneration of the earth's subsoil. In summer, excess thermal energy is passed back to the country from which it was pumped in the winter months.

These systems are connected to a hybrid heat pump in the technical room of the building.

Hybrid system

This system allows you to cleverly draw thermal energy from air, earth or water depending on seasonal conditions and current energy efficiency.

It is therefore possible to choose from several principles of energy pumping. For example, it is possible to combine geothermal borehole with an outdoor air unit.  The advantage is economically used geothermal and aerothermal energy at different times of the year.

The hybrid system gives you the opportunity to reduce the number of geothermal wells or their depth. Also, in case of lack of space on the plot for a surface collector, the air unit can serve as a power reserve.

A plus of this system is also the more efficient regeneration of the earth's subsoil. In summer, excess thermal energy is passed back to the country from which it was pumped in the winter months.

These systems are connected to a hybrid heat pump in the technical room of the building.