Presentation is loading. Please wait.

Presentation is loading. Please wait.

Geothermal Energy: Geophysical Concepts, Applications and Limitations Prof. Dr. Manfred Koch Department of Geohydraulics and Engineering Hydraulics University.

Published by Modified over 9 years ago

Similar presentations

Presentation on theme: "Geothermal Energy: Geophysical Concepts, Applications and Limitations Prof. Dr. Manfred Koch Department of Geohydraulics and Engineering Hydraulics University."— Presentation transcript:

1 Geothermal Energy: Geophysical Concepts, Applications and Limitations Prof. Dr. Manfred Koch Department of Geohydraulics and Engineering Hydraulics University of Kassel Kassel Winter University, January 6, 2012

2 Overview 0 Energy statistics 1 Origins of geothermal energy 1.1 Leftover heat from the accretion of the earth 1.2 Radioactive decay 1.3 Heat flow from the earth’s interior 2 Classification of geothermal systems 2.1 Deep geothermal reservoirs 2.1.1 High-enthalpy reservoirs 2.1.2 Low-enthalpy reservoirs 2.1.2.1 Hydrothermal systems 2.1.2.2 Petrothermal systems 2.1.2.3 Deep earth tubes 2.2 Surficial geothermal energy use with heat pumps 2.3 Geothermal energy from tunnels 2.3 Geothermal energy from tunnels 2.4 Geothermal energy from mining shafts 2.5 Geothermal energy from seasonal storage systems

3 Overview 3. Use of geothermal energy 3.1 Direct use 3.1 Direct use 3.2 Heating and cooling with geothermal energy 3.2 Heating and cooling with geothermal energy 3.3 Electric power generation 3.3 Electric power generation 4. Economic and regulatory aspects for the use of geothermal energy in Germany 5. Ecological aspects 6.1 Energy potential 6.2 Regeneration of the geothermal reservoir 6. Risks 7.1 Risks of seismic events 7.1 Risks of seismic events 7.2 Risks for building due to vertical deformation of the ground surface and 7.2 Risks for building due to vertical deformation of the ground surface and due to drilling due to drilling 7.3 Economic risk of a geothermal project 7.3 Economic risk of a geothermal project 7. Potential of geothermal energy for Germany 8. References

4 0 Energy statistics/Germany Primary energy mix for Germany Primary energy mix for Germany Renewable energy production in Germany Users of energy in Germany Users of energy in Germany

5 0 Energy statistics/geothermal power capacity in the world http://www.bp.com/liveassets/bp_internet/globalbp/globalbp_uk_english/ reports_and_publications/statistical_energy_review_2008/ STAGING/local_assets/2010_downloads/renewables_section_2010.pdf

6 Geothermal Energy and Geothermics Geothermal Energy and Geothermics Geothermal energy is that part of the total heat energy stored within the Earth’s interior that is available for human use. That means practically that it is related to the heat energy stored in the upper layers (crust) of the earth. Geothermal energy is that part of the total heat energy stored within the Earth’s interior that is available for human use. That means practically that it is related to the heat energy stored in the upper layers (crust) of the earth. Although the earth’s stored heat is theoretically finite, its large amount ( 12.6 x 10 MJ) makes geothermal energy practically a renewable energy that can theoretically sustain the energy needs of mankind many times. Although the earth’s stored heat is theoretically finite, its large amount ( 12.6 x 10 24 MJ) makes geothermal energy practically a renewable energy that can theoretically sustain the energy needs of mankind many times. Geothermics is the science that deals with the theoretical studdy of the thermal regime of the earth as well as the engineering aspects to use the earth’s heat for heating / cooling and electric power generations. Geothermics is the science that deals with the theoretical studdy of the thermal regime of the earth as well as the engineering aspects to use the earth’s heat for heating / cooling and electric power generations.

7 1 Origins of geothermal energy 1. Left-over heat from the time of the accretion of the earth (4.6 By BC) (30%) 1. Left-over heat from the time of the accretion of the earth (4.6 By BC) (30%) 2. heat generated by the decay of the long-lived radioactive isotopes of uranium (U238, U235), thorium (Th232) and potassium (K40) (70%). 2. heat generated by the decay of the long-lived radioactive isotopes of uranium (U238, U235), thorium (Th232) and potassium (K40) (70%).

8 1 Origins of geothermal energy Temperature distribution in the earth Temperatures in the earth Geothermal gradient in the upper 150km dT/dz ~ 30 o C/km

9 1 Origins of geothermal energy Mechanisms of heat transport in the earth 1) Heat transport by conduction Fourier’s law Fourier’s law Thermal conductivity of rocks

10 1 Origins of geothermal energy Mechanisms of heat transport in the earth (2) Heat transport by convection convection Mantle convection driving the plates Numerical simulation of Mantle convection

11 1 Origins of geothermal energy Heat flow at the earth’s surface Average heat flow Average heat flow = 60mW/m 2 = 60mW/m 2 Compare with Compare with Solar Constant Solar Constant S= 1360 W/m 2 S= 1360 W/m 2 Note the large lateral variations across the surface of the earth Note the large lateral variations across the surface of the earth Explanation by Explanation by Theory of Theory of Plate Tectonics Plate Tectonics

12 1 Origins of geothermal energy The earth’s thermal regime and relation with plate tectonics

13 Plates, plate boundaries and distribution of volcanoes across the earth

14 1 Origins of geothermal energy Plate tectonics and geothermal fields World pattern of plates, oceanic ridges, oceanic trenches, subduction zones, and geothermal fields. http://www.geothermal-energy.org/105,interactive_map.html

15 2. Classification of geothermal systems/reservoirs The “ideal geothermal reservoir” = high temperatures + water = steam!!!

16 2. Classification of geothermal systems/reservoirs Thermal processes in an “ideal geothermal reservoir” resulting in the formation of hot steam

17 2 Classification of geothermal systems Temperature distribution with depth at different locations and classification of geothermal systems in relation of their depths

18 2. Classification of geothermal systems Use of geothermal energy from surficial, hydrothermal and deep petrothermal reservoirs

19 2. Classification of geothermal systems 2.1 Deep geothermal energy reservoirs 2.1 Deep geothermal energy reservoirs Classification of geothermal reservoirs in relation to the temperature o C

20 2. Classification of geothermal systems 2.1 Deep geothermal energy reservoirs 2.1 Deep geothermal energy reservoirs 2.1.1 High enthalpy reservoirs 2.1.1 High enthalpy reservoirs Characterization of high enthalpy-systems Characterization of high enthalpy-systems Mostly in regions with vulkanic activity Mostly in regions with vulkanic activity Use for generation of electricity (flash-method) Use for generation of electricity (flash-method) and of process heat and of process heat Temperature range: 90 – 300°C Temperature range: 90 – 300°C Depending on pressure reservoirs have more Depending on pressure reservoirs have more steam or water steam or water Steam is reinjected Steam is reinjected  no negativ environmental impact  higher productivity

21 2. Classification of geothermal systems 2.1 Deep geothermal energy reservoirs 2.1 Deep geothermal energy reservoirs 2.1.1 High enthalpy reservoirs 2.1.1 High enthalpy reservoirs

22 2. Classification of geothermal systems 2.1 Deep geothermal energy reservoirs 2.1 Deep geothermal energy reservoirs 2.1.1 High enthalpy reservoirs / World map 2.1.1 High enthalpy reservoirs / World map http://www.geothermal-energy.org/105,interactive_map.html http://www.geothermie.de/aktuelles/geothermie-in-zahlen/weltweit.html

23 2. Classification of geothermal systems 2.1 Deep geothermal energy reservoirs 2.1 Deep geothermal energy reservoirs 2.1.1 High enthalpy reservoirs/ Examples 2.1.1 High enthalpy reservoirs/ Examples Laradello geothermal power plant The Geysers geothermal field, California http://geothermal.marin.org/GEOpresentation/sld036.htm

24 2. Classification of geothermal systems 2.1 Deep geothermal energy reservoirs 2.1 Deep geothermal energy reservoirs 2.1.2 Low enthalpy reservoirs 2.1.2 Low enthalpy reservoirs 2.1.2.1 Hydrothermal systems 2.1.2.1 Hydrothermal systems http://www.unendlich-viel- energie.de/uploads/media/ Hydrothermale_Geothermi e.pdf Thermal power extraction P therm = ρ c p Q flow ΔT ρ = density of water c p = specific heat Q flow = flow rate ΔT = T hot -T cold

25 2. Classification of geothermal systems 2.1 Deep geothermal energy reservoirs 2.1 Deep geothermal energy reservoirs 2.1.2 Low enthalpy reservoirs 2.1.2 Low enthalpy reservoirs 2.1.2.1 Hydrothermal systems/Germany 2.1.2.1 Hydrothermal systems/Germany

26 2. Classification of geothermal systems 2.1 Deep geothermal energy reservoirs 2.1 Deep geothermal energy reservoirs 2.1.2 Low enthalpy reservoirs 2.1.2 Low enthalpy reservoirs 2.1.2.2 Petrothermal systems /HDR/EGS 2.1.2.2 Petrothermal systems /HDR/EGS http://www.uni- kassel.de/fb14/geohydraulik/ Lehre/Geophysik_Geothermi e/Vortraege_2008/Kobs_Hali m_Hot_Dry_Rock.ppt http://www.soultz.net/version -en.htm Soulz sous la Foret HDR= Hot Dry Rock Technology EGS = Enhanced Geothermal System

27 2. Classification of geothermal systems 2.1 Deep geothermal energy reservoirs 2.1 Deep geothermal energy reservoirs 2.1.2 Low enthalpy reservoirs 2.1.2 Low enthalpy reservoirs 2.1.2.3 Deep earth tubes/Super C Aachen 2.1.2.3 Deep earth tubes/Super C Aachen Drilling for the Super C Aachen project. Stopped for economic reasons after a depth of 2500 m was reached.

28 2. Classification of geothermal systems 2.2 Surficial geothermal energy use with heat pumps 2.2 Surficial geothermal energy use with heat pumps Open dublett system horizontal ground loops vertical U-tube loop (most common) In 2009 in Germany 330.000 ground source heat pumps (GSHP) installed with 51.000 new installations in 2010

29 2. Classification of geothermal systems 2.2 Surficial geothermal energy use with heat pumps/Principle 2.2 Surficial geothermal energy use with heat pumps/Principle Heat Pump: Coefficient of Performance COP= Q th / W el ~ 4-5 with Q th = output heat rate =Q in + W el W el = electric power input

30 2. Classification of geothermal systems 2.3 Geothermal energy use from tunnels/Switzerland 2.3 Geothermal energy use from tunnels/Switzerland http://www.uni-kassel.de/fb14/geohydraulik/Lehre/Geophysik_Geothermie/Vortraege_2010/Pfaffel.ppt http://www.geothermie.ch/index.php?p=examp_tunnels

31 2. Classification of geothermal systems 2.4 Geothermal energy use from old mining shafts 2.4 Geothermal energy use from old mining shafts http://www.uni-kassel.de/fb14/geohydraulik/Lehre/Geophysik_Geothermie/Vortraege_2010/Gemmeke.ppt Doublett-system of pumping and injection wells for water from a mining shaft Extraction of warm water from mining shaft

32 2. Classification of geothermal systems 2.4 Geothermal energy use from old mining shafts/Project Heerlen 2.4 Geothermal energy use from old mining shafts/Project Heerlen http://www.uni- kassel.de/fb14/geohydraulik/Lehre/Geophysik_Geothermie/Vortraege_2008/Kallert_Remining_Low_Ex.ppt

33 2. Classification of geothermal systems 2.5 Geothermal energy use for seasonal storage 2.5 Geothermal energy use for seasonal storage

34 3. Use of geothermal energy Lindal-Diagram Geothermal use depend on the temperature of the geothermal reservoir

35 3. Use of geothermal energy 3.1 Direct use 3.1 Direct use http://geothermal.marin.org/ GEOpresentation/sld072.htm

36 3. Use of geothermal energy 3.2 Heating and cooling 3.2 Heating and cooling http://geothermal.marin.org/ GEOpresentation/sld089.htm

37 3. Use of geothermal energy 3.3 Electric power generation 3.3 Electric power generation http://geothermal.marin.org/GEOpresentation/sld036.htm Carnot thermodynamic efficiency η = W/Q therm = 1 - T cold /T hot

38 4. Economic and regulatory aspects for the use of geothermal energy in Germany geothermal energy in Germany http://www.uni- kassel.de/fb14/geohydraulik/Lehre/Geophysik_Geothermie/Vortraege_2007/ Angebotspotential_Schmidmeier.ppt

39 5 Ecological aspects of geothermal energy 5.1 Energy potential of a geothermal reservoir (meaning it is basically a regenerative energy source) (meaning it is basically a regenerative energy source) 5.2 Regeneration of a geothermal reservoir (sustainability) 5.2.1 Regeneration in a fissured rock system with convective heat transport transport 5.2.2 Pure heat conduction in a solid rock system (requires complicated numerical modeling of the flow and heat (requires complicated numerical modeling of the flow and heat transport in a reservoir) transport in a reservoir)

40 6 Risks of the use of geothermal energy 6.1 Risks of seismic events http://www.uni-kassel.de/fb14/geohydraulik/Lehre/ Geophysik_Geothermie/Vortraege_2009/ Boos_Basel_Projekt.ppt 6.2 Risks at buildings due to vertical deformations of the earth’s surface or from drilling of the earth’s surface or from drilling http://www.uni-kassel.de/fb14/geohydraulik/Lehre/ Geophysik_Geothermie/Vortraege_2009/ Seeliger_Staufen_Projekt.ppt 6.3 Economic risks http://www.uni- kassel.de/fb14/geohydraulik/Lehre/Geophysik_Geothermie/ http://www.uni- kassel.de/fb14/geohydraulik/Lehre/Geophysik_Geothermie/ Vortraege_2007/Angebotspotential_Schmidmeier.ppt Basel Staufen Aachen

41 7. Potential of geothermal energy for Germany Geothermal temperatures underneath Germany at depths of 1000m and 2000m

42 7. Potential of geothermal energy for Germany Regions with highest geothermal potential with values of hydraulic conductivity for the Molasse region in the south Present-day geothermal locations in Germany with different uses

43 7. Potential of geothermal energy for Germany /Projection Geothermal heat production Geothermal electrical power production

44 8. References http://www.ceramin.eu/IE/Veranstaltungen/Geothermie/Schellschmidt.pdf http://geothermal.marin.org/GEOpresentation/index.htm http://www.geothermal-energy.org/314,what_is_geothermal_energy.html http://www.economist.com/node/16909897?story_id=16909897&fsrc=rss http://en.wikipedia.org/wiki/Geothermal_energy http://www.geotis.de/vgs/templates/listing.php

Download ppt "Geothermal Energy: Geophysical Concepts, Applications and Limitations Prof. Dr. Manfred Koch Department of Geohydraulics and Engineering Hydraulics University."

Similar presentations

Warm Up 11/26 The Hawaiian Islands were formed when the Pacific Plate moved over ____. a. a hot spot c. the Aleutian Plate b. a subduction zone d.

Warm Up 11/26 The Hawaiian Islands were formed when the Pacific Plate moved over ____. a. a hot spot c. the Aleutian Plate b. a subduction zone d.
Geology of the Lithosphere 1. Earth’s Heat Flow What is the Earth’s heat flow? What is the origin of this heat flow? How does heat flow vary with depth?

Geology of the Lithosphere 1. Earth’s Heat Flow What is the Earth’s heat flow? What is the origin of this heat flow? How does heat flow vary with depth?
Fourier law Conservation of energy The geotherm

Fourier law Conservation of energy The geotherm
Geothermal energy in private homes Presentation for “Energy and the Environment“ Nov. 29th 2011 by Kira Quint and Oliver Ricken Source: erdwaerme-info.de.

Geothermal energy in private homes Presentation for “Energy and the Environment“ Nov. 29th 2011 by Kira Quint and Oliver Ricken Source: erdwaerme-info.de.
Geothermal Energy: Natural heat energy produced by the Earth Geo (Earth) Thermal (Heat)

Geothermal Energy: Natural heat energy produced by the Earth Geo (Earth) Thermal (Heat)
Chapter 13 Section 3.

Chapter 13 Section 3.
ENERGY RENEWABLE ENERGY- Inexhaustible source of energy. Ex-solar, Hydro, Wind, Tidal& Geothermal NON-RENEWABLE ENERGY-Exhaustible with time. Ex- Fossil.

ENERGY RENEWABLE ENERGY- Inexhaustible source of energy. Ex-solar, Hydro, Wind, Tidal& Geothermal NON-RENEWABLE ENERGY-Exhaustible with time. Ex- Fossil.
Low-CO 2 Energy.

Low-CO 2 Energy.
Focus the Nation, Prof. Stryker Energy Consciousness and Conservation Focus the Nation, 2009 Professor Stryker, Department of Mechanical Engineering.

Focus the Nation, Prof. Stryker Energy Consciousness and Conservation Focus the Nation, 2009 Professor Stryker, Department of Mechanical Engineering.
Class 1. Earth Structure and Plate Tectonics William Wilcock OCEAN/ESS 410.

Class 1. Earth Structure and Plate Tectonics William Wilcock OCEAN/ESS 410.
Chapter 12 Earth’s Interior

Chapter 12 Earth’s Interior
Geothermal Energy. Introduction The center of the Earth is very hot, approximately 5000 K. [1] More than 95 % of the Earth’s volume is warmer than 1000.

Geothermal Energy. Introduction The center of the Earth is very hot, approximately 5000 K. [1] More than 95 % of the Earth’s volume is warmer than 1000.
An Introduction to Heat Flow

An Introduction to Heat Flow
- What is Geothermal Energy? - Where can we find Geothermal Energy? - How do we get the Geothermal Energy? - How does Geothermal Energy work? - Advantages.

- What is Geothermal Energy? - Where can we find Geothermal Energy? - How do we get the Geothermal Energy? - How does Geothermal Energy work? - Advantages.
BY: ANA BRAR Residential Geothermal Energy Use. What Is Geothermal Energy? Heat from the earth Can be found almost anywhere Affordable and sustainable.

BY: ANA BRAR Residential Geothermal Energy Use. What Is Geothermal Energy? Heat from the earth Can be found almost anywhere Affordable and sustainable.
Trapping the Earth’s Internal Heat

Trapping the Earth’s Internal Heat
Geothermal Energy Presented by: William Murray March 28, 2007.

Geothermal Energy Presented by: William Murray March 28, 2007.
Geothermal Energy “Digging Deep to Discover the Power” Michelle Kennedy & Caitlin Sloan.

Geothermal Energy “Digging Deep to Discover the Power” Michelle Kennedy & Caitlin Sloan.
The Power from the earth -Mr. Wright-.  The energy from the heat from the earth’s crust  In some areas there are deposits of water in the earth’s Crust.

The Power from the earth -Mr. Wright-.  The energy from the heat from the earth’s crust  In some areas there are deposits of water in the earth’s Crust.
Geothermal Energy By Brooke Miller. Geothermal energy is formed and generated in the Earth.

Geothermal Energy By Brooke Miller. Geothermal energy is formed and generated in the Earth.

Similar presentations

Ads by Google