Investigation of Steady-State Heat Extraction Rates for Different Borehole Heat Exchanger Configurations from the Aspect of Implementation of New TurboCollector™ Pipe System Design

When considering implementation of shallow geothermal energy as a renewable source for heating and cooling of buildings, special care should be taken in the hydraulic design of the borehole heat exchanger system. Laminar flow can occur in pipes due to the usage of glycol mixtures at low temperature or inadequate flow rates. This can lead to lower heat extraction and rejection rates of the exchanger because of higher thermal resistance. Furthermore, by increasing the flow rate to achieve turbulent flow and satisfactory heat transfer rate can lead to an increase in the pressure drop of the system and oversizing of the circulation pump which leads to impairment of the seasonal coefficient of performance at the heat pump. The most frequently used borehole heat exchanger system in Europe is a double-loop pipe system with a smooth inner wall. Lately, development is focused on the implementation of a different configuration as well as with ribbed inner walls which ensures turbulent flow in the system, even at lower flow rates. At a location in Zagreb, standard and extended thermal response tests were conducted on three different heat exchanger configurations in the same geological environment. With a standard TRT test, thermogeological properties of the ground and thermal resistance of the borehole were determined for each smooth or turbulator pipe configuration. On the other hand, extended Steady-State Thermal Response Step Test (TRST) incorporates a series of power steps to determine borehole extraction rates at the defined steady-state heat transfer conditions of 0/–3 °C. When comparing most common exchanger, 2U-loop D32 smooth pipe, with novel 1U-loop D45 ribbed pipe, an increase in heat extraction of 6.5% can be observed. Also, when the same comparison is made with novel 2U-loop D32 ribbed pipe, an increase of 18.7% is achieved. Overall results show that heat exchangers with ribbed inner pipe wall have advantages over classic double-loop smooth pipe designs, in terms of greater steady-state heat extraction rate and more favorable hydraulic conditions.

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Investigation of Steady-State Heat Extraction Rates for Different Borehole Heat Exchanger Configuration from the Aspect of Implementation of New TurboCollectorTM Pipe System Design

10.20944/preprints201902.0254.v1 ◽

2019 ◽

Author(s):

Tomislav Kurevija ◽

Adib Kalantar ◽

Marija Macenić ◽

Josipa Hranić

Keyword(s):

Heat Transfer ◽

Steady State ◽

Heat Exchanger ◽

Thermal Response ◽

Heat Extraction ◽

Double Loop ◽

Borehole Heat Exchanger ◽

Pipe System ◽

State Heat ◽

Steady State Heat

When considering implementation of shallow geothermal energy as a renewable source for heating and cooling of the building, special care should be taken in hydraulic design of borehole heat exchanger system. Laminar flow can occur in pipes due to usage of glycol mixture at low temperature or inadequate flow rate. This can lead to lower heat extraction and rejection rates of the exchanger because of higher thermal resistances. Furthermore, by increasing flow rate to achieve turbulent flow and satisfactory heat transfer rate can lead to increase the pressure drop of the system and oversizing of circulation pump which leads to impairment of seasonal coefficient of performance at the heat pump. Most frequently used borehole heat exchanger system in Europe is double-loop pipe system with smooth inner wall. Lately, development is focused on implementation of different configuration as well as with ribbed inner wall which ensures turbulent flow in the system, even at lower flow rates. At a location in Zagreb, classical and extended thermal response test was conducted on three different heat exchanger configurations in the same geological environment. With classic TRT test, thermogeological properties of the ground and thermal resistance of the borehole were determined for each smooth or turbulator pipe configuration. Extended Steady-State Thermal Response Step Test (TRST) was implemented, which incorporate series of power steps to determine borehole extraction rate at the define steady-state heat transfer conditions of 0/-3°C. Results show that heat exchangers with ribbed inner pipe wall have advantages over classic double-loop smooth pipe design, in terms of greater steady state heat extraction rate and more favorable hydraulic conditions.

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STEADY-STATE HEAT REJECTION RATES FOR A COAXIAL BOREHOLE HEAT EXCHANGER DURING PASSIVE AND ACTIVE COOLING DETERMINED WITH THE NOVEL STEP THERMAL RESPONSE TEST METHOD

Rudarsko-geološko-naftni zbornik ◽

10.17794/rgn.2018.2.6 ◽

2018 ◽

Vol 33 (2) ◽

pp. 61-71 ◽

Cited By ~ 2

Author(s):

Tomislav Kurevija ◽

◽

Marija Macenić ◽

Kristina Strpić ◽

◽

...

Keyword(s):

Steady State ◽

Heat Exchanger ◽

Thermal Response ◽

Test Method ◽

The Novel ◽

Thermal Response Test ◽

Borehole Heat Exchanger ◽

Response Test ◽

Steady State Heat ◽

Rejection Rates

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Numerical Investigation of Steady-State Heat Conduction in Arbitrary Shaped Heat Exchanger Tubes with Mutliply Connected Cross Sections

International Journal of Applied and Computational Mathematics ◽

10.1007/s40819-017-0456-8 ◽

2017 ◽

Vol 4 (1) ◽

Author(s):

Santosh Kumar Rana ◽

Biswajit Mishra ◽

Amit Jena

Keyword(s):

Heat Conduction ◽

Steady State ◽

Heat Exchanger ◽

Numerical Investigation ◽

Cross Sections ◽

State Heat ◽

Steady State Heat

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Building Performance Simulations coupled to Borehole Heat Exchanger Simulations: a tool for realistic monitoring and forecast

10.5194/egusphere-egu21-14502 ◽

2021 ◽

Author(s):

Jan Niederau ◽

Johanna Fink ◽

Moritz Lauster

Keyword(s):

Heat Exchanger ◽

Thermal Power ◽

Thermal Response ◽

Heat Extraction ◽

Building Performance ◽

Power Demand ◽

Outdoor Temperature ◽

Borehole Heat Exchanger ◽

Heat Demand ◽

Demand Models

The actual heat demand of a building depends on various building-specific parameters, such as building age, insulation type, housing volume, but also external parameters, e.g. outdoor temperature. Being able to dynamically model the thermal power demand of a specific building can increase the robustness of coupled borehole heat exchanger simulations (BHE-simulations), as the transient heat demand models of a building / consumer can be used to simulate the thermal response of the subsurface to the prescribed consumer demand.We present results of coupling results of Building Performance Simulation (BPS) with simulations of Borehole Heat Exchangers. BPS are carried out using TEASER (Tool for Energy Analysis and Simulation for Efficient Retrofit) which models the thermal power demand of a building based on parameters, such as year of construction, net-lease area, and outdoor-temperature.Using annual temperature curves, we model the thermal power demand of buildings from the 1950s, once in original state and in retrofitted state. The thermal response of a connected BHE-field is simulated using SHEMAT-Suite, an open-source simulator for heat- and mass-transfer in porous media. In our BHE simulations, thermal plumes develop as a result of heat-extraction and regional groundwater flow.To improve the forecast of, e.g. the magnitude of these plumes, realistic knowledge of the heat demand is important, which can be achieved by the presented coupling of BPS- and BHE-modelling.&#160;

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