Presentation is loading. Please wait.

Presentation is loading. Please wait.

Using High Temperature Gas-cooled Reactors for low grade phosphate rock processing Nils Haneklaus1 , Ewald Schnug2, Harikrishnan Tulsidas3, Frederik Reitsma1.

Published byDulcie Brooks Modified over 9 years ago

Similar presentations

Presentation on theme: "Using High Temperature Gas-cooled Reactors for low grade phosphate rock processing Nils Haneklaus1 , Ewald Schnug2, Harikrishnan Tulsidas3, Frederik Reitsma1."— Presentation transcript:

1 Using High Temperature Gas-cooled Reactors for low grade phosphate rock processing
Nils Haneklaus1 , Ewald Schnug2, Harikrishnan Tulsidas3, Frederik Reitsma1 1 Section of Nuclear Power Technology Development, Division of Nuclear Power, IAEA, Vienna International Centre, PO Box 100, A-1400 Vienna, Austria 2 Technical University Braunschweig - Faculty 2 Life Sciences, Pockelsstraße 14, D Braunschweig, Germany 3 Section of Nuclear Fuel Cycle and Materials, Division of Nuclear Fuel Cycle and Waste Technology, IAEA, Vienna International Centre, PO Box 100, A-1400 Vienna, Austria

2 Introduction High Temperature Gas-cooled Reactors (HTGRs)
Phosphate rock – overview and uranium content HTGRs for energy neutral processing of low-grade phosphate rock Conclusions - outlook

3 High Temperature Gas-cooled Reactors (HTGRs) Overview
Structure: Thermal reactor Coolant: Helium Moderator: Graphite Characteristics: High efficiency Process heat Inherent safety characteristics Flexible fuel (Uranium/Thorium) Reactor core (pebble bed) Reactor core (block type) Side reflector Helium ≈ 250 ˚C Helium up to 1000 ˚C

4 (construction side Shandong Province)
High Temperature Gas-cooled Reactors (HTGRs) Past experience – current development DRAGON( ) PB-1 ( ) AVR ( ) FSR ( ) THTR ( ) PBMR ( ) HTTR (since 1998) HTR-10 (since 2000) HTR-PM (under construction) HTR-PM (construction side Shandong Province)

5 Phosphate rock – resource that feeds the world Overview
Finite resource – presently not recycled > 160 million metric tons/yr mined, 90% used for fertilizer production No substitute for phosphate rock in fertilizer production Lower grade deposits need to be developed Energy intensive thermal processes/beneficiation methods will have to be employed Source: accessed

6 Phosphate rock Uranium content
Phosphate rock contains considerable concentrations of ‘valuable’ impurities… Uranium (up to 400 ppm*) Thorium (up to 150 ppm*) …making it one of the largest unconventional uranium resource worldwide *ppm = parts per million Conventional uranium resources worldwide (14.413,7*10 t) 1 Estimated recoverable uranium resources from phosphate rock worldwide (5.665,97*10 t) 2 Source: 1IAEA Red Book 2011, 2Ulrich, A.E., Schnug E., Prasser H.-M., Frossard E., Uranium endowments in phosphate rock, Science of the Total Environment 478 (2014)

7 Limitations in Processing Low Grad Phosphate Rock
High temperature gas-cooled reactors for energy neutral processing of low grade phosphate rock Process Heat for Phosphate conversion and U/Th recovery (thermal process) Chemicals for Phosphate Rock conversion (wet process) Phosphate Rock Phosphate Fertilizer Relatively Large Amounts of Waste (≈ 2-3 t P-gypsum per t fertilizer) Limitations in Processing Low Grad Phosphate Rock Uranium/Thorium High Temperature Gas-cooled Reactor Reactor Fuel Manufacturing Source: Nils Haneklaus, Ewald Schnug, Harikrishnan Tulsidas, Bismark Tyobeka: Using high temperature gas-cooled reactors for greenhouse gas reduction and energy neutral production of phosphate fertilizers, Annals of Nuclear Energy, 2014

8 Conclusions - outlook Low grade phosphate rock may* be processed economically using high temperature gas-cooled reactors to power energy intensive thermal processing/beneficiation enabling… … recovery of presently lost uranium/thorium, (REE) resources … strongly reduced uranium/thorium contents in final products *The technological and economical feasibility of this idea will be elaborated within the next four years as part of a coordinated research project at IAEA “U/Th fuelled HTGR applications for energy neutral sustainable comprehensive extraction and mineral product developments” Phosphate Rock High Temperature Gas-cooled Reactor Reactor Fuel Manufacturing Uranium/Thorium Phosphate Fertilizer Process Heat for Phosphate conversion and U/Th recovery (thermal process)

Download ppt "Using High Temperature Gas-cooled Reactors for low grade phosphate rock processing Nils Haneklaus1 , Ewald Schnug2, Harikrishnan Tulsidas3, Frederik Reitsma1."

Similar presentations

-1- IAEA-ICTP Workshop on Nuclear Reaction Data for Advanced Reactor Technologies ICTP – Trieste, Italy, 18-30 May 2008 Gas-Cooled Reactors – International.

-1- IAEA-ICTP Workshop on Nuclear Reaction Data for Advanced Reactor Technologies ICTP – Trieste, Italy, May 2008 Gas-Cooled Reactors – International.
IAEA Sources of Radiation Fuel Cycle - Overview Day 4 – Lecture 5 (1) 1.

IAEA Sources of Radiation Fuel Cycle - Overview Day 4 – Lecture 5 (1) 1.
Nuclear Power. Source: Uranium-235 Process: – An unstable uranium nucleus is bombarded with a neutron and splits into two smaller nuclei and some neutrons.

Nuclear Power. Source: Uranium-235 Process: – An unstable uranium nucleus is bombarded with a neutron and splits into two smaller nuclei and some neutrons.
钍基熔盐核能系统 Safety analysis of graphite core in molten salt test reactor Derek Tsang SINAP 16.09.2013.

钍基熔盐核能系统 Safety analysis of graphite core in molten salt test reactor Derek Tsang SINAP
GENERATION III AND III+ NUCLEAR POWER PLANT DESIGNS ACR-1000 (Advanced CANDU Reactor) Dr. Şule Ergün Hacettepe University Department of Nuclear Engineering.

GENERATION III AND III+ NUCLEAR POWER PLANT DESIGNS ACR-1000 (Advanced CANDU Reactor) Dr. Şule Ergün Hacettepe University Department of Nuclear Engineering.
Nuclear Power – Need and Future. Outline Economics of Nuclear Energy Basics of a Power Plant Heat From Fission History of Nuclear Power Current Commercial.

Nuclear Power – Need and Future. Outline Economics of Nuclear Energy Basics of a Power Plant Heat From Fission History of Nuclear Power Current Commercial.
Some nuc. reactors. Nuclear reaction by Fission Nuclear fission: All commercial power reactors are based on nuclear fission. generally use uranium and.

Some nuc. reactors. Nuclear reaction by Fission Nuclear fission: All commercial power reactors are based on nuclear fission. generally use uranium and.
Miss Nelson SCIENCE ~ CHAPTER 12 ENERGY AND MATERIAL RESOURCES.

Miss Nelson SCIENCE ~ CHAPTER 12 ENERGY AND MATERIAL RESOURCES.
Nuclear Fuel, Uranium Enrichment, Fuel Fabrication, MOX Seminar on Nuclear Science and Technology for Diplomats P. Adelfang (+)Division of Nuclear Fuel.

Nuclear Fuel, Uranium Enrichment, Fuel Fabrication, MOX Seminar on Nuclear Science and Technology for Diplomats P. Adelfang (+)Division of Nuclear Fuel.
Supplying Electricity & Hydrogen from the nuclear Pebble Bed Modular Reactor Andrew Kenny Energy Research Centre University of Cape Town South Africa Electricity.

Supplying Electricity & Hydrogen from the nuclear Pebble Bed Modular Reactor Andrew Kenny Energy Research Centre University of Cape Town South Africa Electricity.
Power Stations Nuclear power stations. Introduction  A nuclear power plant is a thermal power station in which the heat source is a nuclear reactor.thermal.

Power Stations Nuclear power stations. Introduction  A nuclear power plant is a thermal power station in which the heat source is a nuclear reactor.thermal.
Nuclear Reactors. Fission has been developed as an energy source to produce electricity in reactors – Within the reactors, controlled fission occurs –

Nuclear Reactors. Fission has been developed as an energy source to produce electricity in reactors – Within the reactors, controlled fission occurs –
By Amy Crouch and Zofia Soch

By Amy Crouch and Zofia Soch
What is Nuclear Energy? Nuclear energy or atomic energy is the energy that is released spontaneously or artificially in nuclear reactions. The main feature.

What is Nuclear Energy? Nuclear energy or atomic energy is the energy that is released spontaneously or artificially in nuclear reactions. The main feature.
Natural Resources. 1. What are the Earth’s Natural Resources? Mineral Resources Energy Resources Living Resources Air Water Sunlight Soil.

Natural Resources. 1. What are the Earth’s Natural Resources? Mineral Resources Energy Resources Living Resources Air Water Sunlight Soil.
Alternative Energy Sources

Alternative Energy Sources
Nuclear Power Station Lecture No 5. A generating station in which nuclear energy is converted into electrical energy is known as a Nuclear power station.

Nuclear Power Station Lecture No 5. A generating station in which nuclear energy is converted into electrical energy is known as a Nuclear power station.
Generation IV Reactor International Efforts American Nuclear Society Washington D.C. Section John E. Kelly Deputy Assistant Secretary for Nuclear Reactor.

Generation IV Reactor International Efforts American Nuclear Society Washington D.C. Section John E. Kelly Deputy Assistant Secretary for Nuclear Reactor.
BNFL/Westinghouse’s Perspective on the Nuclear Hydrogen Economy Dr PJA Howarth Head of Group Science Strategy.

BNFL/Westinghouse’s Perspective on the Nuclear Hydrogen Economy Dr PJA Howarth Head of Group Science Strategy.
2002IAEA1 Department of Nuclear Energy International Atomic Energy Agency Status of Nuclear Desalination Technology Lecture presented at the Workshop.

2002IAEA1 Department of Nuclear Energy International Atomic Energy Agency Status of Nuclear Desalination Technology Lecture presented at the Workshop.

Similar presentations

Ads by Google