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The Nuclear Safeguards (Notification) Regulations 2004

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Statutory Instruments

2004 No. 1255

NUCLEAR SAFEGUARDS

The Nuclear Safeguards (Notification) Regulations 2004

Made

1st May 2004

Laid before Parliament

4th May 2004

Coming into force

5th May 2004

The Secretary of State, in exercise of the powers conferred on her by section 3(1) of the Nuclear Safeguards Act 2000 M1, hereby makes the following Regulations:

Marginal Citations

Citation and commencementU.K.

1.  These Regulations may be cited as the Nuclear Safeguards (Notification) Regulations 2004, and shall come into force on 5th May 2004.

InterpretationU.K.

2.  In these Regulations:

Annex II” means Annex II to the Additional Protocol M2;

electronic communications network” has the same meaning as in section 32 of the Communications Act 2003 M3;

the commencement date” means 30th April 2004, the entry into force date of the Additional Protocol;

high enriched uranium” means uranium containing 20 per cent or more of the isotope uranium-235;

non-nuclear-weapon State” means a State other than China, France, Russia, the United Kingdom and the United States of America;

nuclear fuel cycle-related research and development activities” means research and development activities which are specifically related to any process or system development aspect of—

(a)

the enrichment of nuclear material,

(b)

the reprocessing of nuclear fuel, or

(c)

the processing of intermediate or high level waste containing plutonium, high enriched uranium, or uranium-233

but does not include activities related to theoretical or basic scientific research or to research and development on industrial radioisotope applications, medical, hydrological or agricultural applications, health or environmental effects or improved maintenance;

nuclear material” means any source material (other than ore or ore residue) or any special fissionable material;

processing of intermediate or high level waste” does not include—

(a)

repackaging of the waste for storage or disposal,

(b)

conditioning of the waste not involving the separation of elements, for storage or disposal;

source material” means uranium containing the mixture of isotopes occurring in nature, uranium depleted in the isotope 235, thorium, and any of the foregoing in the form of metal, alloy, chemical compound or concentrate;

special fissionable material” means plutonium-239, uranium-233, uranium containing the isotopes 235 or 233 or both in an amount such that the abundance ratio of the sum of these isotopes to the isotope 238 is greater than the ratio of the isotope 235 to the isotope 238 occurring in nature, and any material containing one or more of the foregoing.

Marginal Citations

M2Cm 4282.

Persons required to notify the Secretary of StateU.K.

3.—(1) Subject to regulation 5, a person shall notify the Secretary of State not later than two months after the commencement date if at any time during the period of six months ending on the commencement date he has carried out in the United Kingdom any of the activities specified in paragraph 1 of the Schedule.

(2) Subject to regulation 5, a person shall notify the Secretary of State not later than two months after the commencement date if at any time during the period of six months ending on the commencement date he has carried out in the United Kingdom any nuclear fuel cycle-related research and development activities which were:

(a)carried out in co-operation with, or otherwise relevant to, a non-nuclear-weapon State; and

(b)not funded, specifically authorised or controlled by, or carried out on behalf of, Her Majesty's Government.

4.—(1) Subject to regulation 5, a person shall notify the Secretary of State on or before 15th January in each year if at any time during the previous calendar year he has carried out in the United Kingdom any of the activities specified in paragraph 1 of the Schedule.

(2) Subject to regulation 5, a person shall notify the Secretary of State on or before 15th January in each year if at any time during the previous calendar year he has carried out in the United Kingdom any nuclear fuel cycle-related research and development activities which were:

(a)carried out in co-operation with, or otherwise relevant to, a non-nuclear-weapon State; and

(b)not funded, specifically authorised or controlled by, or carried out on behalf of, Her Majesty's Government.

Persons not required to notify the Secretary of StateU.K.

5.—(1) The Secretary of State may serve on a person a written notice setting out particulars which the Secretary of State already has in relation to that person.

(2) A person on whom a notice has been served under paragraph (1) is not required to notify the Secretary of State under regulation 3 or 4 if the particulars set out in the notice are accurate at the time the notice is received by that person and are all the particulars which that person would be required to provide under these Regulations but for this paragraph.

(3) A person who by virtue of paragraph (2) is not required to notify the Secretary of State under regulation 3 or 4 shall, within 14 days of any change in any of the particulars which were set out in the notice served on him under paragraph (1), give to the Secretary of State notice of the new particulars.

(4) Section 10 of the Nuclear Safeguards Act 2000 applies in relation to the service by the Secretary of State of notices under paragraph (1).

Form of notification to the Secretary of StateU.K.

6.—(1) A person who is required to notify the Secretary of State under regulation 3 or 4 shall do so by giving a notice to the Secretary of State containing particulars of his name, his proper address (within the meaning of section 10(3) of the Nuclear Safeguards Act 2000), each activity, referred to in the regulation in question, which he has carried out during the relevant period and the address of each place at or from which he has carried out each such activity.

(2) A person who has given particulars to the Secretary of State pursuant to paragraph (1) shall, within 14 days of any change in any of those particulars, give to the Secretary of State notice of the new particulars.

(3) Any notice to be given by a person under paragraph (1) or (2), or under regulation 5(3), shall be in writing and sent by post or delivered to [F1the UK Safeguards Office, HSE (UKSO), 7th Floor NW, Rose Court, 2 Southwark Bridge, London SE1 9HS], or sent by means of an electronic communications network to [F2UKSO@hse.gsi.gov.uk].

Nigel Griffiths,

Parliamentary Under Secretary of State for Small Business and Enterprise,

Department of Trade and Industry

Regulations 3(1) and 4(1)

SCHEDULEU.K.

PART I U.K.ACTIVITIES REFERRED TO IN REGULATIONS 3(1) AND 4(1)

1.  The activities referred to in regulations 3(1) and 4(1) are:U.K.

(i)the manufacture of centrifuge rotor tubes or the assembly of gas centrifuges;

(ii)the manufacture of diffusion barriers;

(iii)the manufacture or assembly of laser-based systems;

(iv)the manufacture or assembly of electromagnetic isotope separators;

(v)the manufacture or assembly of columns or extraction equipment;

(vi)the manufacture of aerodynamic separation nozzles or vortex tubes;

(vii)the manufacture or assembly of uranium plasma generation systems;

(viii)the manufacture of zirconium tubes;

(ix)the manufacture or upgrading of heavy water or deuterium;

(x)the manufacture of nuclear grade graphite;

(xi)the manufacture of flasks for irradiated fuel;

(xii)the manufacture of reactor control rods;

(xiii)the manufacture of criticality safe tanks and vessels;

(xiv)the manufacture of irradiated fuel element chopping machines;

(xv)the construction of hot cells.

2.  In paragraph 1:U.K.

centrifuge rotor tubes” means thin-walled cylinders as described in entry 5.1.1(b);

gas centrifuges” means centrifuges as described in the Introductory Note to entry 5.1;

diffusion barriers” means thin, porous filters as described in entry 5.3.1(a);

laser-based systems” means systems incorporating those items described in entry 5.7;

electromagnetic isotope separators” means those items referred to in entry 5.9.1 containing ion sources as described in entry 5.9.1(a);

columns or extraction equipment” means those items as described in entries 5.6.1, 5.6.2, 5.6.3, 5.6.5, 5.6.6, 5.6.7 and 5.6.8;

aerodynamic separation nozzles or vortex tubes” means separation nozzles and vortex tubes as described respectively in entries 5.5.1 and 5.5.2;

uranium plasma generation systems” means systems for the generation of uranium plasma as described in entry 5.8.3;

zirconium tubes” means tubes as described in entry 1.6;

heavy water or deuterium” means deuterium, heavy water (deuterium oxide) and any other deuterium compound in which the ratio of deuterium to hydrogen atoms exceeds 1:5000;

nuclear grade graphite” means graphite having a purity level better than 5 parts per million boron equivalent and with a density greater than 1.50g/cm3;

flask for irradiated fuel” means a vessel for the transportation and/or storage of irradiated fuel which provides chemical, thermal and radiological protection, and dissipates decay heat during handling, transportation and storage;

reactor control rods” means rods as described in entry 1.4;

criticality safe tanks and vessels” means those items as described in entries 3.2 and 3.4;

irradiated fuel element chopping machines” means equipment as described in entry 3.1;

hot cells” means a cell or interconnected cells totalling at least 6m3 in volume with shielding equal to or greater than the equivalent of 0.5m of concrete, with a density of 3.2g/cm3 or greater, outfitted with equipment for remote operations.

3.  The numbered entries referred to in paragraph 2 are the entries so numbered in Annex II, which entries are set out (with other entries referred to in them) in Part II of this Schedule.U.K.

PART II U.K.EXTRACTS FROM ANNEX II TO THE ADDITIONAL PROTOCOL

REACTORS AND EQUIPMENT THEREFORU.K.

1.   

Complete nuclear reactorsU.K.

1.1.  Nuclear reactors capable of operation so as to maintain a controlled self-sustaining fission chain reaction, excluding zero energy reactors, the latter being defined as reactors with a designed maximum rate of production of plutonium not exceeding 100 grams per year.

EXPLANATORY NOTEU.K.

A “nuclear reactor” basically includes the items within or attached directly to the reactor vessel, the equipment which controls the level of power in the core, and the components which normally contain or come in direct contact with or control the primary coolant of the reactor core.

It is not intended to exclude reactors which could reasonably be capable of modification to produce significantly more than 100 grams of plutonium per year. Reactors designed for sustained operation at significant power levels, regardless of their capacity for plutonium production, are not considered as “zero energy reactors”.

...

Reactor control rodsU.K.

1.4.  Rods especially designed or prepared for the control of the reaction rate in a nuclear reactor as defined in paragraph 1.1. above.

EXPLANATORY NOTEU.K.

This item includes, in addition to the neutron absorbing part, the support or suspension structures therefor if supplied separately.

...

Zirconium tubesU.K.

1.6.  Zirconium metal and alloys in the form of tubes or assemblies of tubes, and in quantities exceeding 500 kg in any period of 12 months, especially designed or prepared for use in a reactor as defined in paragraph 1.1. above, and in which the relation of hafnium to zirconium is less than 1:500 parts by weight.

...

PLANTS FOR THE REPROCESSING OF IRRADIATED FUEL ELEMENTS, AND EQUIPMENT ESPECIALLY DESIGNED OR PREPARED THEREFORU.K.

3.   

INTRODUCTORY NOTEU.K.

Reprocessing irradiated nuclear fuel separates plutonium and uranium from intensely radioactive fission products and other transuranic elements. Different technical processes can accomplish this separation. However, over the years Purex has become the most commonly used and accepted process. Purex involves the dissolution of irradiated nuclear fuel in nitric acid, followed by separation of the uranium, plutonium, and fission products by solvent extraction using a mixture of tributyl phosphate in an organic diluent.

Purex facilities have process functions similar to each other, including: irradiated fuel element chopping, fuel dissolution, solvent extraction, and process liquor storage. There may also be equipment for thermal denitration of uranium nitrate, conversion of plutonium nitrate to oxide or metal, and treatment of fission product waste liquor to a form suitable for long term storage or disposal. However, the specific type and configuration of the equipment performing these functions may differ between Purex facilities for several reasons, including the type and quantity of irradiated nuclear fuel to be reprocessed and the intended disposition of the recovered materials, and the safety and maintenance philosophy incorporated into the design of the facility.

A “plant for the reprocessing of irradiated fuel elements” includes the equipment and components which normally come in direct contact with and directly control the irradiated fuel and the major nuclear material and fission product processing streams.

These processes, including the complete systems for plutonium conversion and plutonium metal production, may be identified by the measures taken to avoid criticality (e.g. by geometry), radiation exposure (e.g. by shielding), and toxicity hazards (e.g. by containment).

Items of equipment that are considered to fall within the meaning of the phrase “and equipment especially designed or prepared” for the reprocessing of irradiated fuel elements include:

Irradiated fuel element chopping machinesU.K.

3.1.   

INTRODUCTORY NOTEU.K.

This equipment breaches the cladding of the fuel to expose the irradiated nuclear material to dissolution. Especially designed metal cutting shears are the most commonly employed, although advanced equipment, such as lasers, may be used.

Remotely operated equipment especially designed or prepared for use in a reprocessing plant as identified above and intended to cut, chop or shear irradiated nuclear fuel assemblies, bundles or rods.

DissolversU.K.

3.2.   

INTRODUCTORY NOTEU.K.

Dissolvers normally receive the chopped-up spent fuel. In these critically safe vessels, the irradiated nuclear material is dissolved in nitric acid and the remaining hulls removed from the process stream.

Critically safe tanks (e.g. small diameter, annular or slab tanks) especially designed or prepared for use in a reprocessing plant as identified above, intended for dissolution of irradiated nuclear fuel and which are capable of withstanding hot, highly corrosive liquid, and which can be remotely loaded and maintained.

...

Chemical holding or storage vesselsU.K.

3.4.   

INTRODUCTORY NOTEU.K.

Three main process liquor streams result from the solvent extraction step. Holding or storage vessels are used in the further processing of all three streams, as follows:

(a)The pure uranium nitrate solution is concentrated by evaporation and passed to a denitration process where it is converted to uranium oxide. This oxide is re-used in the nuclear fuel cycle.

(b)The intensely radioactive fission products solution is normally concentrated by evaporation and stored as a liquor concentrate. This concentrate may be subsequently evaporated and converted to a form suitable for storage or disposal.

(c)The pure plutonium nitrate solution is concentrated and stored pending its transfer to further process steps. In particular, holding or storage vessels for plutonium solutions are designed to avoid criticality problems resulting from changes in concentration and form of this stream.

Especially designed or prepared holding or storage vessels for use in a plant for the reprocessing of irradiated fuel. The holding or storage vessels must be resistant to the corrosive effect of nitric acid. The holding or storage vessels are normally fabricated of materials such as low carbon stainless steels, titanium or zirconium, or other high quality materials. Holding or storage vessels may be designed for remote operation and maintenance and may have the following features for control of nuclear criticality:

(1) walls or internal structures with a boron equivalent of at least two per cent, or

(2) a maximum diameter of 175 mm (7 in) for cylindrical vessels, or

(3) a maximum width of 75 mm (3 in) for either a slab or annular vessel.

...

PLANTS FOR THE SEPARATION OF ISOTOPES OF URANIUM AND EQUIPMENT, OTHER THAN ANALYTICAL INSTRUMENTS, ESPECIALLY DESIGNED OR PREPARED THEREFORU.K.

5.  ...

Gas centrifuges and assemblies and components especially designed or prepared for use in gas centrifugesU.K.

5.1.   

INTRODUCTORY NOTEU.K.

The gas centrifuge normally consists of a thin-walled cylinder(s) of between 75 mm (3 in) and 400 mm (16 in) diameter contained in a vacuum environment and spun at high peripheral speed of the order of 300 m/s or more with its central axis vertical. In order to achieve high speed the materials of construction for the rotating components have to be of a high strength to density ratio and the rotor assembly, and hence its individual components, have to be manufactured to very close tolerances in order to minimize the unbalance. In contrast to other centrifuges, the gas centrifuge for uranium enrichment is characterized by having within the rotor chamber a rotating disc-shaped baffle(s) and a stationary tube arrangement for feeding and extracting the UF6 gas and featuring at least 3 separate channels, of which 2 are connected to scoops extending from the rotor axis towards the periphery of the rotor chamber. Also contained within the vacuum environment are a number of critical items which do not rotate and which although they are especially designed are not difficult to fabricate nor are they fabricated out of unique materials. A centrifuge facility however requires a large number of these components, so that quantities can provide an important indication of end use.

Rotating componentsU.K.

5.1.1.   

...

(b)Rotor tubes:

Especially designed or prepared thin-walled cylinders with thickness of 12 mm (0.5 in) or less, a diameter of between 75 mm (3 in) and 400 mm (16 in), and manufactured from one or more of the high strength to density ratio materials described in the EXPLANATORY NOTE to this Section.

...

EXPLANATORY NOTEU.K.

The materials used for centrifuge rotating components are:

(a)Maraging steel capable of an ultimate tensile strength of 2.05 x 109 N/m2 (300,000 psi) or more;

(b)Aluminium alloys capable of an ultimate tensile strength of 0.46 x 109 N/m2 (67,000 psi) or more;

(c)Filamentary materials suitable for use in composite structures and having a specific modulus of 12.3 x 106m or greater and a specific ultimate tensile strength of 0.3 x 106m or greater (“Specific Modulus” is the Young's Modulus in N/m2 divided by the specific weight in N/m3; “Specific Ultimate Tensile Strength” is the ultimate tensile strength in N/m2 divided by the specific weight in N/m3).

...

Gaseous diffusion barriersU.K.

5.3.1.   

(a)Especially designed or prepared thin, porous filters, with a pore size of 100-1,000 Å (angstroms), a thickness of 5 mm (0.2 in) or less, and for tubular forms, a diameter of 25 mm (1 in) or less, made of metallic, polymer or ceramic materials resistant to corrosion by UF6 ...

...

Separation nozzlesU.K.

5.5.1.  Especially designed or prepared separation nozzles and assemblies thereof. The separation nozzles consist of slit-shaped, curved channels having a radius of curvature less than 1 mm (typically 0.1 to 0.05 mm), resistant to corrosion by UF6 and having a knife-edge within the nozzle that separates the gas flowing through the nozzle into two fractions.

Vortex tubesU.K.

5.5.2.  Especially designed or prepared vortex tubes and assemblies thereof. The vortex tubes are cylindrical or tapered, made of or protected by materials resistant to corrosion by UF6, having a diameter of between 0.5 cm and 4 cm, a length to diameter ratio of 20:1 or less and with one or more tangential inlets. The tubes may be equipped with nozzle-type appendages at either or both ends.

EXPLANATORY NOTEU.K.

The feed gas enters the vortex tube tangentially at one end or through swirl vanes or at numerous tangential positions along the periphery of the tube.

...

Liquid-liquid exchange columns (Chemical exchange)U.K.

5.6.1.  Countercurrent liquid-liquid exchange columns having mechanical power input (i.e., pulsed columns with sieve plates, reciprocating plate columns, and columns with internal turbine mixers), especially designed or prepared for uranium enrichment using the chemical exchange process. For corrosion resistance to concentrated hydrochloric acid solutions, these columns and their internals are made of or protected by suitable plastic materials (such as fluorocarbon polymers) or glass. The stage residence time of the columns is designed to be short (30 seconds or less).

Liquid-liquid centrifugal contactors (Chemical exchange)U.K.

5.6.2.  Liquid-liquid centrifugal contactors especially designed or prepared for uranium enrichment using the chemical exchange process. Such contactors use rotation to achieve dispersion of the organic and aqueous streams and then centrifugal force to separate the phases. For corrosion resistance to concentrated hydrochloric acid solutions, the contactors are made of or are lined with suitable plastic materials (such as fluorocarbon polymers) or are lined with glass. The stage residence time of the centrifugal contactors is designed to be short (30 seconds or less).

Uranium reduction systems and equipment (Chemical exchange)U.K.

5.6.3.   

(a)Especially designed or prepared electrochemical reduction cells to reduce uranium from one valence state to another for uranium enrichment using the chemical exchange process. The cell materials in contact with process solutions must be corrosion resistant to concentrated hydrochloric acid solutions.

EXPLANATORY NOTEU.K.

The cell cathodic compartment must be designed to prevent re-oxidation of uranium to its higher valence state. To keep the uranium in the cathodic compartment, the cell may have an impervious diaphragm membrane constructed of special cation exchange material. The cathode consists of a suitable solid conductor such as graphite.

(b)Especially designed or prepared systems at the product end of the cascade for taking the U4+ out of the organic stream, adjusting the acid concentration and feeding to the electrochemical reduction cells.

EXPLANATORY NOTEU.K.

These systems consist of solvent extraction equipment for stripping the U4+ from the organic stream into an aqueous solution, evaporation and/or other equipment to accomplish solution pH adjustment and control, and pumps or other transfer devices for feeding to the electrochemical reduction cells. A major design concern is to avoid contamination of the aqueous stream with certain metal ions. Consequently, for those parts in contact with the process stream, the system is constructed of equipment made of or protected by suitable materials (such as glass, fluorocarbon polymers, polyphenyl sulfate, polyether sulfone, and resin-impregnated graphite).

...

Uranium oxidation systems (Chemical exchange)U.K.

5.6.5.  Especially designed or prepared systems for oxidation of U3+ to U4+ for return to the uranium isotope separation cascade in the chemical exchange enrichment process.

EXPLANATORY NOTEU.K.

These systems may incorporate equipment such as:

(a)Equipment for contacting chlorine and oxygen with the aqueous effluent from the isotope separation equipment and extracting the resultant U4+ into the stripped organic stream returning from the product end of the cascade,

(b)Equipment that separates water from hydrochloric acid so that the water and the concentrated hydrochloric acid may be reintroduced to the process at the proper locations.

Fast-reacting ion exchange resins/adsorbents (Ion exchange)U.K.

5.6.6.  Fast-reacting ion-exchange resins or adsorbents especially designed or prepared for uranium enrichment using the ion exchange process, including porous macroreticular resins, and/or pellicular structures in which the active chemical exchange groups are limited to a coating on the surface of an inactive porous support structure, and other composite structures in any suitable form including particles or fibers. These ion exchange resins/adsorbents have diameters of 0.2 mm or less and must be chemically resistant to concentrated hydrochloric acid solutions as well as physically strong enough so as not to degrade in the exchange columns. The resins/adsorbents are especially designed to achieve very fast uranium isotope exchange kinetics (exchange rate half-time of less than 10 seconds) and are capable of operating at a temperature in the range of 100°C to 200°C.

Ion exchange columns (Ion exchange)U.K.

5.6.7.  Cylindrical columns greater than 1,000 mm in diameter for containing and supporting packed beds of ion exchange resin/adsorbent, especially designed or prepared for uranium enrichment using the ion exchange process. These columns are made of or protected by materials (such as titanium or fluorocarbon plastics) resistant to corrosion by concentrated hydrochloric acid solutions and are capable of operating at a temperature in the range of 100°C to 200°C and pressures above 0.7 MPa (102 psia).

Ion exchange reflux systems (Ion exchange)U.K.

5.6.8.   

(a)Especially designed or prepared chemical or electrochemical reduction systems for regeneration of the chemical reducing agent(s) used in ion exchange uranium enrichment cascades.

(b)Especially designed or prepared chemical or electrochemical oxidation systems for regeneration of the chemical oxidizing agent(s) used in ion exchange uranium enrichment cascades.

EXPLANATORY NOTEU.K.

The ion exchange enrichment process may use, for example, trivalent titanium (Ti3+) as a reducing cation in which case the reduction system would regenerate Ti3+ by reducing Ti4+.

The process may use, for example, trivalent iron (Fe3+) as an oxidant in which case the oxidation system would regenerate Fe3+ by oxidizing Fe2+.

Especially designed or prepared systems, equipment and components for use in laser-based enrichment plantsU.K.

5.7.   

INTRODUCTORY NOTEU.K.

Present systems for enrichment processes using lasers fall into two categories: those in which the process medium is atomic uranium vapor and those in which the process medium is the vapor of a uranium compound. Common nomenclature for such processes include: first category—atomic vapor laser isotope separation (AVLIS or SILVA); second category—molecular laser isotope separation (MLIS or MOLIS) and chemical reaction by isotope selective laser activation (CRISLA). The systems, equipment and components for laser enrichment plants embrace: (a) devices to feed uranium-metal vapor (for selective photo-ionization) or devices to feed the vapor of a uranium compound (for photo-dissociation or chemical activation); (b) devices to collect enriched and depleted uranium metal as “product” and “tails” in the first category, and devices to collect dissociated or reacted compounds as “product” and unaffected material as “tails” in the second category; (c) process laser systems to selectively excite the uranium-235 species; and (d) feed preparation and product conversion equipment. The complexity of the spectroscopy of uranium atoms and compounds may require incorporation of any of a number of available laser technologies.

EXPLANATORY NOTEU.K.

Many of the items listed in this section come into direct contact with uranium metal vapor or liquid or with process gas consisting of UF6 or a mixture of UF6 and other gases. All surfaces that come into contact with the uranium or UF6 are wholly made of or protected by corrosion-resistant materials. For the purposes of the section relating to laser-based enrichment items, the materials resistant to corrosion by the vapor or liquid of uranium metal or uranium alloys include yttria-coated graphite and tantalum; and the materials resistant to corrosion by UF6 include copper, stainless steel, aluminium, aluminium alloys, nickel or alloys containing 60% or more nickel and UF6-resistant fully fluorinated hydrocarbon polymers.

Uranium vaporization systems (AVLIS)U.K.

5.7.1.  Especially designed or prepared uranium vaporization systems which contain high-power strip or scanning electron beam guns with a delivered power on the target of more than 2.5 kW/cm.

Liquid uranium metal handling systems (AVLIS)U.K.

5.7.2.  Especially designed or prepared liquid metal handling systems for molten uranium or uranium alloys, consisting of crucibles and cooling equipment for the crucibles.

EXPLANATORY NOTEU.K.

The crucibles and other parts of this system that come into contact with molten uranium or uranium alloys are made of or protected by materials of suitable corrosion and heat resistance. Suitable materials include tantalum, yttria-coated graphite, graphite coated with other rare earth oxides or mixtures thereof.

Uranium metal “product” and “tails” collector assemblies (AVLIS)U.K.

5.7.3.  Especially designed or prepared “product” and “tails” collector assemblies for uranium metal in liquid or solid form.

EXPLANATORY NOTEU.K.

Components for these assemblies are made of or protected by materials resistant to the heat and corrosion of uranium metal vapor or liquid (such as yttria-coated graphite or tantalum) and may include pipes, valves, fittings, “gutters”, feed-throughs, heat exchangers and collector plates for magnetic, electrostatic or other separation methods.

Separator module housings (AVLIS)U.K.

5.7.4.  Especially designed or prepared cylindrical or rectangular vessels for containing the uranium metal vapor source, the electron beam gun, and the “product” and “tails” collectors.

EXPLANATORY NOTEU.K.

These housings have multiplicity of ports for electrical and water feed-throughs, laser beam windows, vacuum pump connections and instrumentation diagnostics and monitoring. They have provisions for opening and closure to allow refurbishment of internal components.

Supersonic expansion nozzles (MLIS)U.K.

5.7.5.  Especially designed or prepared supersonic expansion nozzles for cooling mixtures of UF6 and carrier gas to 150 K or less and which are corrosion resistant to UF6.

Uranium pentafluoride product collectors (MLIS)U.K.

5.7.6.  Especially designed or prepared uranium pentafluoride (UF5) solid product collectors consisting of filter, impact, or cyclone-type collectors, or combinations thereof, and which are corrosion resistant to the UF5/UF6 environment.

UF6/carrier gas compressors (MLIS)U.K.

5.7.7.  Especially designed or prepared compressors for UF6/carrier gas mixtures, designed for long term operation in a UF6 environment. The components of these compressors that come into contact with process gas are made of or protected by materials resistant to corrosion by UF6.

Rotary shaft seals (MLIS)U.K.

5.7.8.  Especially designed or prepared rotary shaft seals, with seal feed and seal exhaust connections, for sealing the shaft connecting the compressor rotor with the driver motor so as to ensure a reliable seal against out-leakage of process gas or in-leakage of air or seal gas into the inner chamber of the compressor which is filled with a UF6/carrier gas mixture.

Fluorination systems (MLIS)U.K.

5.7.9.  Especially designed or prepared systems for fluorinating UF5 (solid) to UF6 (gas).

EXPLANATORY NOTEU.K.

These systems are designed to fluorinate the collected UF5 powder to UF6 for subsequent collection in product containers or for transfer as feed to MLIS units for additional enrichment. In one approach, the fluorination reaction may be accomplished within the isotope separation system to react and recover directly off the “product” collectors. In another approach, the UF5 powder may be removed/transferred from the “product” collectors into a suitable reaction vessel (eg, fluidized-bed reactor, screw reactor or flame tower) for fluorination. In both approaches, equipment for storage and transfer of fluorine (or other suitable fluorinating agents) and for collection and transfer of UF6 are used.

UF6 mass spectrometers/ion sources (MLIS)U.K.

5.7.10.  Especially designed or prepared magnetic or quadrupole mass spectrometers capable of taking “on-line” samples of feed, “product” or “tails”, from UF6 gas streams and having all of the following characteristics:

(1.)Unit resolution for mass greater than 320;

(2.)Ion sources constructed of or lined with nichrome or monel or nickel plated;

(3.)Electron bombardment ionization sources;

(4.)Collector system suitable for isotopic analysis.

Feed systems/product and tails withdrawal systems (MLIS)U.K.

5.7.11.  Especially designed or prepared process systems or equipment for enrichment plants made of or protected by materials resistant to corrosion by UF6, including:

(a)Feed autoclaves, ovens, or systems used for passing UF6 to the enrichment process;

(b)Desublimers (or cold traps) used to remove UF6 from the enrichment process for subsequent transfer upon heating;

(c)Solidification or liquefaction stations used to remove UF6 from the enrichment process by compressing and converting UF6 to a liquid or solid form;

(d)“Product” or “tails” stations used for transferring UF6 into containers.

UF6/carrier gas separation systems (MLIS)U.K.

5.7.12.  Especially designed or prepared process systems for separating UF6 from carrier gas. The carrier gas may be nitrogen, argon, or other gas.

EXPLANATORY NOTEU.K.

These systems may incorporate equipment such as:

(a)Cryogenic heat exchangers or cryoseparators capable of temperatures of −120°C or less, or

(b)Cryogenic refrigeration units capable of temperatures of −120°C or less, or

(c)UF6 cold traps capable of temperatures of −20°C or less.

Laser systems (AVLIS, MLIS and CRISLA)U.K.

5.7.13.  Lasers or laser systems especially designed or prepared for the separation of uranium isotopes.

EXPLANATORY NOTEU.K.

The laser system for the AVLIS process usually consists of two lasers: a copper vapor laser and a dye laser. The laser system for MLIS usually consists of a CO2 or excimer laser and a multi-pass optical cell with revolving mirrors at both ends. Lasers or laser systems for both processes require a spectrum frequency stabilizer for operation over extended periods of time.

...

Uranium plasma generation systemsU.K.

5.8.3.  Especially designed or prepared systems for the generation of uranium plasma, which may contain high-power strip or scanning electron beam guns with a delivered power on the target of more than 2.5 kW/cm.

...

Electromagnetic isotope separatorsU.K.

5.9.1.  Electromagnetic isotope separators especially designed or prepared for the separation of uranium isotopes, and equipment and components therefor, including:

(a)Ion sources

Especially designed or prepared single or multiple uranium ion sources consisting of a vapor source, ionizer, and beam accelerator, constructed of suitable materials such as graphite, stainless steel, or copper, and capable of providing a total ion beam current of 50 mA or greater.

(b)Ion collectors

Collector plates consisting of two or more slits and pockets especially designed or prepared for collection of enriched and depleted uranium ion beams and constructed of suitable materials such as graphite or stainless steel.

(c)Vacuum housings

Especially designed or prepared vacuum housings for uranium electromagnetic separators, constructed of suitable non-magnetic materials such as stainless steel and designed for operation at pressures of 0.1 Pa or lower.

EXPLANATORY NOTEU.K.

The housings are specially designed to contain the ion sources, collector plates and water-cooled liners and have provision for diffusion pump connections and opening and closure for removal and reinstallation of these components.

(d)Magnet pole pieces

Especially designed or prepared magnet pole pieces having a diameter greater than 2 m used to maintain a constant magnetic field within an electromagnetic isotope separator and to transfer the magnetic field between adjoining separators.

Explanatory Note

(This note is not part of the Regulations)

These Regulations require persons engaged in specific nuclear and nuclear-related activities to give certain details about themselves and those activities to the Secretary of State. The United Kingdom is required to provide certain information in relation to nuclear and nuclear-related activities to the International Atomic Energy Agency (“IAEA”) pursuant to the Additional Protocol referred to in section 1(1) of the Nuclear Safeguards Act 2000. These Regulations enable the Secretary of State to know who may have such information.

Regulations 3 and 4 provide that a person who has carried out any of the activities referred to in the respective paragraphs of those regulations, supplemented by the Schedule, must notify the Secretary of State. The activities referred to are those specified in the Additional Protocol about which information is required to be given by the Secretary of State to the IAEA, but which may be carried on without the Secretary of State knowing other than as a result of compliance with these Regulations. The relevant provisions from the Additional Protocol are reproduced in Part II of the Schedule.

Regulation 5 negates the obligation to notify the Secretary of State where the Secretary of State already has the details which that person would otherwise have to give under the Regulations, and serves on that person a written notice setting out those details. Such a person must still notify the Secretary of State if the details set out in the notice are incomplete or wrong, or if they change.

Regulation 6 describes what details a person has to give when notifying the Secretary of State under regulation 3 or 4.

A full regulatory impact assessment has not been produced for this instrument as it has no impact on the costs of business.

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