Determination of the thermal characteristic of the ground in Cyprus and their effect on ground heat exchangers

Pouloupatis, Panayiotis

January 2014

Since the ancient years, human beings were using holes and caves to protect themselves from weather conditions making it the first known form of exploiting ground’s heat, known as Geothermal Energy. Nowadays, geothermal energy is mainly used for electricity production, space heating and cooling, Ground Coupled Heat Pump (GCHP) applications, and many other purposes depending on the morphology of the ground and its temperature. This study presents results of investigations into the evaluation of the thermal properties of the ground in Cyprus. The main objectives were i) to determine the thermal characteristics of the ground in Cyprus, ii) investigate how they affect the sizing and positioning of Ground Heat Exchangers (GHE) and iii) present the results for various ground depths, including a temperature map of the island, as a guide for engineers and specifiers of GCHPs. It was concluded that there is a potential for the efficient exploitation of the thermal properties of the ground in Cyprus for geothermal applications leading to significant savings in power and money as well. Six new boreholes were drilled and two existing ones were used for the investigation and determination of i) the temperature of the ground at various depths, ii) its thermal conductivity, iii) its specific heat and iv) its density. The thermal conductivity was determined by carrying out experiments using the line source method and was found to vary in the range between 1.35 and 2.1 W/mK. It was also observed that the thermal conductivity is strongly affected by the degree of saturation of the ground. The temperature of the undisturbed ground in the 8 borehole locations was recorded monthly for a period of 1 year. The investigations showed that the surface zone reaches a depth of 0.25 m and the shallow zone 7 to 8 m. The undisturbed ground temperature in the deep zone was measured to be in the range of 18.3 °C to 23.6 °C and is strongly dependent on the soil type. Since the ground temperature is a vital parameter in ground thermal applications, the temperature of the ground in locations that no information is available was predicted using Artificial Neural Networks and the temperature map of the island at depths of 20 m, 50 m and 100 m was generated. Data obtained at the location of each borehole were used for the training of the network. Data for the sizing of GHEs based on the ground properties of Cyprus were presented in an easily accessible form so that they can be used as a guide for preliminary system sizing calculations. With the aid of Computational Fluid Dynamics (CFD) software the capacity of the GHEs in each location and the optimum distance between them was estimated. Additionally, the long term temperature variation of the ground was investigated. For the first time since a limited study in the 1970’s, a research focusing on the determination and presentation of the thermal properties of the ground in Cyprus has been carried out. Additionally, the use of Artificial Neural Networks (ANNs) is an innovative approach for the prediction of data at locations where no information is available. The publication of this information not only contributes to knowledge locally but also internationally as it enables comparison with other countries with similar climatic conditions to be carried out.

621.402

Ground-coupled heat pump systems: a pumping analysis

Mays, Cristin Jean

January 1900

Master of Science / Department of Architectural Engineering / Fred Hasler / Ground-coupled heat pump (GCHP) systems use the ground as a heat source or sink that absorbs heat from or rejects heat to the soil, respectively; this is referred to as the geothermal heat exchanger. Apart from the geothermal heat exchanger, there are two other main system components that make up a GCHP system: heat pumps and circulation pumps. This report studies four GCHP pumping systems and makes comparisons between the four using life-cycle cost analyses for six building models. The goal for this analysis was to discover commonalities between the models in order to provide designers insight into which pumping system is the most cost effective. The analysis was performed by first creating energy models to obtain system and zone load information, as well as system part-load data and geothermal heat exchanger performance. From the zone load information, heat pump selections were then performed to indicate the worst case piping path that is required for pump head calculations. Piping layouts were created to establish pipe lengths for the pump head calculations as well. Other piping components such as valves and fittings and the air separator pressure drops were also calculated. Once the pump head calculations were complete for each system, pump schedules were created. From there initial unit and installation costs were determined for each pump, as well as their replacement costs. The part-load data from the energy models were then used to obtain annual pump energy consumption and pump utility cost. Finally, assumptions were made to establish regular and preventative maintenance requirements for each pumping system. Initial and replacement unit costs, annual utility cost and regular and preventative maintenance costs were the components used in the life-cycle cost analysis. Each of these components was converted to 30-year projected costs and added to create a total life-cycle cost for each pumping system. Comparisons were then made and the results showed that a primary pumping system with VFD control and 100% redundancy was the most cost effective system. However, there are other considerations such as controllability, flexibility and availability that might persuade designers to choose one of the other alternate solutions.

Ground-coupled

Heat pump

Pumping system

HVAC

Ground-source

Distributive

Architectural engineering (0462)

Investigation of Heat Dissipation Enhancement due to Backfill Modification in Ground Coupled Heat Pump Systems

January 2012

abstract: Due to the lack of understanding of soil thermal behavior, rules-of-thumb and generalized procedures are typically used to guide building professionals in the design of ground coupled heat pump systems. This is especially true when sizing the ground heat exchanger (GHE) loop. Unfortunately, these generalized procedures often encourage building engineers to adopt a conservative design approach resulting in the gross over-sizing of the GHE, thus drastically increasing their installation cost. This conservative design approach is particularly prevalent for buildings located in hot and arid climates, where the soils are often granular and where the water table tends to exist deep below the soil surface. These adverse soil conditions reduce the heat dissipation efficiency of the GHE and have hindered the adoption of ground coupled heat pump systems in such climates. During cooling mode operation, heat is extracted from the building and rejected into the ground via the GHE. Prolonged heat dissipation into the ground can result in a coupled flow of both heat and moisture, causing the moisture to migrate away from the GHE piping. This coupled flow phenomenon causes the soil near the GHE to dry out and results in the degradation of the GHE heat dissipation capacity. Although relatively simple techniques of backfilling the GHE have been used in practice to mitigate such coupled effects, methods of improving the thermal behavior of the backfill region around the GHE, especially in horizontal systems, have not been extensively studied. This thesis presents an experimental study of heat dissipation from a horizontal GHE, buried in two backfill materials: (1) dry sand, and (2) wax-sand composite mixture. The HYDRUS software was then used to numerically model the temperature profiles associated with the aforementioned backfill conditions, and the influence of the contact resistance at the GHE-backfill interface was studied. The modeling strategy developed in HYDRUS was proven to be adequate in predicting the thermal performance of GHE buried in dry sand. However, when predicting the GHE heat dissipation in the wax-sand backfill, significant discrepancies between model prediction and experimental results still exist even after calibrating the model by including a term for the contact resistance. Overall, the thermal properties of the backfill were determined to be a key determinant of the GHE heat dissipation capacity. In particular, the wax-sand backfill was estimated to dissipate 50-60% more heat than dry sand backfill. / Dissertation/Thesis / M.S. Design 2012

Design

Civil engineering

Architectural engineering

Backfill Improvement

Ground Coupled Heat Pump

Ground Heat Exchanger

Heat Dissipation

Modelling the performance of horizontal heat exchanger of ground-coupled heat pump system with Egyptian conditions

Ali, Mohamed

January 2013

The aim of this work was to investigate the effect on horizontal ground heat exchanger performance of changing soil and load parameters, and pipe horizontal separation distance for ground-coupled heat pumps under Egyptian conditions.Egypt possesses a variety of energy resources; namely fossil and renewable. The amount of renewable energy available is significant and must be utilized perfectly for the sake of achieving sustainable use of energy resources. Soils in Egypt vary widely from being clay with its thermal conductivity of 1.11 (for clay particles) to sand with its thermal conductivity of 5.77 (for sand particles). Two soil samples were chosen from the literature to be used in the investigation held in this work with boundary conditions that match the weather and ground temperature distribution conditions in Egypt.Conduction heat transfer in soils is a very complicated process especially when it is combined with time dependant boundary conditions and temperature dependent thermophysical properties of the medium. A MATLAB code was used to estimate thermophysical properties of the soil samples with three different moisture contents (0, 0.2, and saturation %) and the upper boundary condition bases on two surface dryness conditions (dry and wet). The results of the code were fed to Abqaus/CAE to analysis and predict the temperature distribution in these soils with implementing the time dependant boundary conditions to investigate the ground thermal behaviour of these soils. Also the temperature distribution around two pipes per trench of horizontal ground heat exchanger with applying synthetic load based on estimated cooling and heating degree days for one set of weather conditions. The horizontal separation distance between pipes was investigated by changing it to be 0.2, 0.3, 0.4, and 0.5 metres.Both the MATLAB code and Abaqus environment were validated against measured data published in the literature and their results agreed well with this data.The results of the simulation showed that the ground thermal behaviour depends mainly on the boundary conditions applied on the model. Dry soils are the worst being affected by the variation of the boundaries, because of its low volumetric heat capacities. The moisture content in the soil should be kept around 0.2 or above to get the most benefits from the presence of moisture in the vicinity of ground heat exchangers. The effect of the soil surface dryness is less significant than that of the moisture content of the entire system but it is more controllable than the moisture content. Also it was found that the horizontal separation distance (HSD) between pipes must be selected on the bases of prior knowledge of the site parameters soil type and moisture level. The results showed that the 0.4m HSD is the optimum HSD for the conditions and load profile included in this study.

621.402

Design Tool for a Ground-Coupled Ventilation System

Alfadil, Mohammad Omar

26 April 2019

Ground-coupled ventilation (GCV) is a system that exchanges heat with the soil. Because ground temperatures are relatively higher during the cold season and lower during the hot season, the system takes advantage of this natural phenomenon. This research focused on designing a ground-coupled ventilation system evaluation tool of many factors that affect system performance. The tool predicts the performance of GCV system design based on the GCV system design parameters including the location of the system, pipe length, pipe depth, pipe diameter, soil type, number of pipes, volume flow rate, and bypass system. The tool uses regression equations created from many GCV system design simulation data using Autodesk Computational Fluid Dynamics software. As a result, this tool helps users choose the most suitable GCV system design by comparing multiple GCV systems' design performances and allows them to save time, money, and effort. / Doctor of Philosophy / Ground-coupled ventilation (GCV) is a system that exchanges heat with the soil. Because ground temperatures are relatively higher during the cold season and lower during the hot season, the system takes advantage of this natural phenomenon. This research focused on designing a ground-coupled ventilation system evaluation tool of many factors that affect system performance. The tool predicts the performance of GCV system design based on the GCV system design parameters including the location of the system, pipe length, pipe depth, pipe diameter, soil type, number of pipes, volume flow rate, and bypass system. The tool uses equations created from many GCV system designs’ simulation data using simulation software. As a result, this tool helps users choose the most suitable GCV system design by comparing multiple GCV system designs’ performance and allows them to save time, money, and effort.

Ground-coupled ventilation system

earth to air tunnel heat exchanger

geo-exchange system

geothermal energy

CFD Simulation Methodology for Ground-Coupled Ventilation System

Alghamdi, Jamal Khaled

08 February 2009

In the past two decades, a growing interest in alternative energy resources as a replacement to the non-renewable resources used now days. These alternatives include geothermal energy which can be used to generate power and reduce the demands on energy used to heat and cool buildings. Ground-coupled ventilation system is one of the many applications of the geothermal energy that have a lot of attention in the early 80's and 90's but all designs of the system where based on single case situations. On the other hand, computational fluid dynamics tools are used to simulate heat and fluid flow in any real life situation. They start to develop rapidly with the fast development of computers and processors. These tools provide a great opportunity to simulate and predict the outcome of most problems with minimum loss and better way to develop new designs. By using these CFD tools in GCV systems designing procedure, energy can be conserved and designs going to be improved. The main objective of this study is to find and develop a CFD modeling strategy for GCV systems. To accomplish this objective, a case study must be selected, a proper CFD tool chosen, modeling and meshing method determined, and finally running simulations and analyzing results. All factors that affect the performance of GCV should be taken under consideration in that process such as soil, backfill, and pipes thermal properties. Multiple methods of simulation were proposed and compared to determine the best modeling approach. / Master of Science

Computational Fluid

Ground-Coupled Ventilation

Computational fluid dynamics

GCV

geothermal energy

soil temperature

heat exchange

Dynamics

Dimensioning and control for heat pump systems using a combination of vertical and horizontal ground-coupled heat exchangers / Dimensionering och styrning för värmepumpssystem som använder en kombination av vertikala och horisontella markvärmekollektorer

Denker, Richard

January 2015

A model has been developed which simulates a system consisting of a horizontal and vertical ground-coupled heat exchanger connected in parallel to the same heat pump. The model was used in computer simulations to investigate how the annual minimum and mean fluid temperatures at the heat pump varied as several parameters of the combined system were changed. A comparison was also made between different control settings for fluid flow rate distribution between the two exchangers. For the case when the flow rate distribution was not controlled, the effect of viscosity differences between a colder and warmer exchanger was investigated. The short term effects of letting the vertical heat source rest during the warm summer months was then tested. Lastly, the results of the model was compared to a simple 'rule of thumb' that have been used in the industry for this kind of combined system. The results show that using a combined system might not always result in increased performance, if the previously existing exchanger is a vertical ground-coupled heat exchanger. The effects of viscosity differences on the flow distribution seems to be negligible, especially for high net flows. Controlling the fluid flow rates seems to only be worth the effort if the the pipe lengths of the two combined exchangers differ heavily. Letting the vertical ground-coupled heat exchanger rest during summer was shown to in some cases yield an increased short-term performance in addition to the already known positive long term effects. The rule of thumb was shown to recommend smaller dimensions for combination systems than the more realistic analytical model.

heat pump system

ground-coupled

ground source

combination

dual

horizontal

vertical

borehole heat exchanger

BHE

complementary source

flow control