FI126298B - Systems for transferring energy from a uranium compound - Google Patents

Description

TECHNICAL FIELD FOR Uranium Compound Energy Transfer

The application relates generally to a system for the energy transfer of a uranium compound. Background

Generally speaking, the nuclear fuel chain used in nuclear power plants deals with uranium in various physical and chemical forms. A commonly used uranium compound is uranium hexafluoride (UF6). UF6 is typically stored in storage cylinders suitable for uranium storage. At normal room temperature and normal atmospheric pressure, UF6 is in a solid state, making it difficult to get it out of the storage cylinder. In this case, depending on the intended use, it is desired to convert UF6 to either a liquid or gaseous state where it is possible to remove UF6 from the storage cylinder. According to the UF6 phase diagram, the conversion to a solid gas phase can be accomplished by either raising the temperature or lowering the pressure, or a combination thereof. Converting from solid to liquid phase requires raising the temperature when the starting point is room temperature. Typically, in order to raise the temperature, the uranium storage cylinder is heated, for example in an autoclave suitable for uranium sampling, by various methods. Air and water vapor storage cylinder heating is commonly used in the nuclear fuel industry. In air and water vapor heating, the heat energy is mainly transferred by convection, i.e. the flowing air or water vapor conducts heat to the surface of the storage cylinder. It is further known that a small part of the heat transfer power can also be produced in the storage cylinder by radiation. It is also desired to cool the storage cylinder for certain applications to solidify uranium in the gas and liquid phases. In known convection-based solutions, cold air is circulated along the outer surface of the storage cylinder, whereby the flowing air transports the heat energy away from the surface of the storage cylinder.

US 2005/0103049 discloses convection cooling of nuclear fuel.

The problem with known air and water vapor heating solutions is the slowness and difficult adjustment of the heating and cooling process.

A further problem is the steam treatment autoclave water treatment apparatus used for heating and cooling the storage cylinder, which complicates the autoclave structure and increases manufacturing and maintenance costs.

Summary

It is an object of the invention to eliminate the problems of the prior art and to implement a simple system for the energy transfer of a uranium compound.

An object of the invention is achieved by the system of claim 1, the method of claim 8 and the energy transfer means of claim 9.

In one embodiment, the system for transferring uranium compound energy comprises a storage cylinder for storing the uranium compound and energy transfer means for heating and / or cooling the uranium compound in the storage cylinder. The energy transfer means are adapted to transfer energy to and / or remove energy from the uranium compound.

According to one embodiment, the method for transferring energy of a uranium compound in a system comprising a storage cylinder for storing the uranium compound and energy transfer means for heating and / or cooling the uranium compound in the storage cylinder comprises transferring energy from the uranium compound to the uranium compound.

Energy transfer means for the uranium compound energy transfer according to one embodiment, adapted to transfer energy to the uranium compound and / or remove energy from the uranium compound. The energy transfer means comprise contact means adapted to conduct thermal energy and adapted to be mounted against the outer surface of the uranium compound storage cylinder, and temperature separation means adapted to provide thermal energy applied to the uranium compound through contact means and / or to remove the contact medium.

Other embodiments are set forth in the dependent claims.

Brief description of the pictures

In the detailed description of the drawings, embodiments of the invention will be explained in more detail with reference to the accompanying drawings, in which Figure 1a illustrates a uranium compound energy transfer system and Figures 1b-1d show details of energy transfer means.

DETAILED DESCRIPTION OF THE DRAWINGS System 100 comprises a storage cylinder 110 for storing uranium compound 101 and energy transfer means 130 for heating and / or cooling the uranium compound 101 by conduction.

Heating and cooling of the uranium compound 101 is necessary, for example, during transfer from storage cylinder 110 to another storage cylinder, pre-heating in separate pre-heating cabinets prior to the actual process and sampling, for example in an autoclave.

1a, the storage cylinder 110 is disposed for sampling in the autoclave 120 through its terminal hood 122 and connected to the autoclave 120 sampling apparatus 124. a quarter of the total time since the heat transfer by system 100 can be up to 50 times faster than a flowing air heating and cooling solution where the convective heat transfer coefficient is typically 10-100 W / m2K.

In addition, system 100 also makes it possible to reduce the number of processing equipment, such as autoclaves 120, since the processing equipment is used for a shorter period of time in a single heating and cooling process.

In addition, system 100 can eliminate the need for preheating cabinets, since preheating can be accomplished by energy transfer means 100 of system 100.

Figures 1b-1d show in more detail the energy transfer means 130 which are arranged to transfer energy to and / or remove uranium from the uranium compound 101. The energy transfer means 130 may comprise, for example, one or more energy transfer covers. The energy transfer means 130 mounted on the outer surface 112 of the storage cylinder 110 comprises contact means 132 arranged to be mounted against the outer surface 112 of the storage cylinder 110 and to conduct thermal energy so that thermal energy is transmitted through the contact means 132 and the storage cylinder 110. The direction of transfer depends on whether it is heating or cooling.

For example, the contact means 132 comprise at least one metal profile comprising a channel 133. The metal profiles 132 may be, for example, aluminum or copper profiles formed in a mold.

For example, the metal profiles 132 in the energy transfer cover 130 of Figures 1b-1d are 40, 50 or 60 mm wide and can be 25, 30 or 35. The length of the metal profiles 132 depends on the length of the energy transfer cover 130.

In addition, the energy transfer means 130 comprise a temperature difference forming means 134 adapted to produce thermal energy supplied to the uranium compound 101 via the contact means 132 and / or to remove the thermal energy from the uranium compound 101 via the contact means 132. The temperature difference forming means 134 comprises at least one channel 136a, 136b, 136c, 136d through which the energy transfer fluid (not shown) can flow. The energy transfer fluid, which can be used for both heating and cooling, may be any suitable liquid or gas that does not react with uranium compound 101.

Channels 136a, 136b, 136c, 136d are connected to both ends of the metal profiles 132 so that the energy transfer fluid can flow from the distribution channel 136a to the contact channels 136b from where it passes through the channel 133 of the metal profile 132, uniformly transferring energy in the area covered by energy transfer means 130. The energy transfer fluid exits from channel 133 to contact channels 136c, from where it flows to collecting channel 136d.

In Figure 1c, where dielectric 138 comprises only contours, well-visible ducts 136a, 136b, 136c, 136d may be, for example, a flexible silicone tube or other tube that does not react with uranium compound 101.

Further, the temperature forming means 134 comprise energy transfer fluid heating means (not shown) and / or energy transfer fluid cooling means (not shown).

The heating of the energy transfer fluid is accomplished by heating means comprising at least one of an electrical resistor, means for generating electromagnetic radiation, and means for producing heat radiation. Cooling, in turn, is accomplished by cooling means comprising at least one channel for a flowable cooling fluid which may be any suitable liquid or gas that does not react with the uranium compound 101.

The energy transfer means 130 comprise an insulator 138 adapted to insulate at least partially the contact means 132 and at least partly the temperature difference forming means 134 so that some of the contact means 132 can still be mounted against the outer surface 112 of the storage cylinder 110.

The insulator 138 may be, for example, a mattress filled with dry air or other gas that does not react with the uranium compound 101, which acts as an insulator and at the same time presses the contact means 132 at its base as closely as possible against the outer surface 112 of storage cylinder 110.

The material of the insulation 138 may be, for example, air or gas tight nonwoven, aluminum foil or aluminum reinforced plastic or fabric.

The energy transfer means 130 are mounted on the storage cylinder 110 through an opening 139 in the energy transfer means 130.

For example, the energy transfer means 130, by one or more energy transfer overlays 130, depending on their size, are capable of transferring thermal energy over the entire outer surface 112 or zone of the storage cylinder 110 such that only a portion of the outer surface 112 is heated by applying heat therewith or only a portion of the outer surface 112.

If the energy transfer means 130 comprises a plurality of energy transfer blankets 130, the heat energy introduction and removal may also occur simultaneously at different locations on the outer surface 112 of the same storage cylinder 110, thereby optimizing the overall cooling process if part of the outer surface 112 is heated during cooling. System 100 makes it easy and simple to implement a zone energy transfer, unlike known solutions, where zone and simultaneous heating and cooling operation is nearly impossible.

In addition, system 100 may comprise control means (not shown) adapted to control the heating and / or cooling process, and temperature monitoring means (not shown) adapted to monitor the temperature of the energy transfer fluid since the chemical composition of the uranium compounds 101 is temperature sensitive. Temperature monitoring means ensure that the temperature of the energy transfer fluid to be supplied is not too high, thereby preventing hot spots on the surface 112 of the storage cylinder 110. An overheated inner surface of the storage cylinder causes the uranium compound to decompose.

Only some embodiments of the invention are described above. The principle of the invention can, of course, be modified within the scope of the claims, for example with respect to details of implementation and areas of use.

Claims (9)

A system (100) for energy transfer of a uranium compound (101), comprising: a storage cylinder (110) for storing the uranium compound and energy transfer means (130) for heating and cooling the uranium compound in the storage cylinder; energy to the uranium compound and remove energy from the uranium compound by leading to the uranium compound being uranium hexafluoride. The system of claim 1, wherein the energy transfer means comprises contact means (132) adapted to conduct thermal energy and adapted to be mounted against the outer surface (112) of the storage cylinder. A system according to any one of the preceding claims, wherein the energy transfer means comprises temperature differential means (134) adapted to provide thermal energy to the uranium compound through the contact means and / or to remove the thermal energy from the uranium compound through the contact means. The system of claim 3, wherein the temperature difference generating means comprises at least one channel (136) for a flowing energy transfer fluid and at least one of the energy transfer fluid heating means and the energy transfer fluid cooling means. The system of claim 4, wherein the energy transfer fluid heating means comprises at least one electrical resistor, electromagnetic radiation generating means, or heat radiation generating means, and the energy transfer fluid cooling means comprises at least one channel for flowing cooling fluid. A system according to any one of the preceding claims, wherein the energy transfer means are arranged to transfer energy by zones so that at least a portion of the outer surface of the storage cylinder is heated by applying thermal energy and / or cooling at least a portion of the outer surface of the storage cylinder. A system according to any one of the preceding claims, wherein the energy transfer means comprises an insulator (138) adapted to insulate the contact means and at least partially the temperature difference forming means so that a portion of the contact means can be mounted against the outer surface of the storage cylinder. A method of energy transfer of a uranium compound (101) in a system (100) according to any one of claims 1-7, comprising a storage cylinder (110) for storing the uranium compound and energy transfer means (130) for heating and cooling the uranium compound in the storage cylinder. characterized in that, in the method, energy is transferred to and / or removed from the uranium compound by the energy transfer means (130) of the system, the uranium compound being uranium hexafluoride. Energy transfer means (130) for transferring energy to the uranium compound (101), characterized in that the energy transfer means are adapted to transfer energy to and from the uranium compound and to remove energy from the uranium compound, and the energy transfer means (110) an outer surface (112), and temperature differential forming means (134) adapted to provide thermal energy to the uranium compound through the contact means and to remove thermal energy from the uranium compound through the contact means, the uranium compound being uranium hexafluoride and the thermal energy to Krav