RU1656974C - Heat-emissive assembly - Google Patents

Abstract

The invention relates to energy and can be used to produce dry saturated or superheated steam. The goal is to increase energy intensity. For this purpose, tubular fuel rods are located in the housing with the formation of a tube bundle, and the inlet chamber and outlet chamber are separated from each other by the fuel rod tube. In this case, any change in the temperature regime along the length or radius of the assembly automatically changes the enthalpy of the coolant and redistribution of heat fluxes on the surfaces of the fuel rods and improving the temperature regime of the latter. This makes it possible to increase the energy intensity of the heat-generating assembly. 2 ill.

Description

The invention relates to energy and can be used to produce dry saturated or superheated steam.

The purpose of the invention is to increase the energy intensity of a fuel assembly.

In FIG. 1 schematically depicts a fuel assembly, general view, variant with connection of teel tube spaces to the inlet chamber; in FIG. 2 - fuel assembly, general view, variant with connecting the annular space of the fuel elements to the input chamber.

The fuel assembly includes a housing 1 with an inlet chamber 2, an outlet chamber 3, an intermediate collector 4 and longitudinally mounted tubular fuel rods 5. The fuel rods 5 are fixed at one end to the tube plate 6, and the other are inserted into the intermediate manifold 4. The chambers 2 and 3 are located on the tube side boards b and are separated by the last one from another. The fuel rods 5 are installed in the housing 1 with the formation of a bundle of pipes spaced by the locking elements 7.

Input 2 and output 3 cameras are connected to the source and consumer of the coolant, respectively. The required parameters of the coolant sent to the consumer, the set pressure drop across the assembly and the temperature conditions of the fuel rods 5 are ensured by appropriate selection of the sizes of the latter, the steps of the arrangement of the fuel rods 5 and fuel loading (the amount of heat generated in the fuel rods 5).

The fuel assembly operates as follows.

In the embodiment of the fuel assembly shown in FIG. 1, the coolant after the claims

FUEL ASSEMBLY, comprising a housing with an inlet and outlet chambers, as well as an intermediate manifold and longitudinally mounted tubular fuel rods, the latter of which are fixed at one end with a tube board and with the other at the aforementioned

the pipe space passes exactly; the exact collector 4, the fuel elements 5 and the output i

The heat-generating variant shown in Fig. 2, the heat supply pipe, passes through the inlet annulus, and the inlet manifold 4 is tubular.

to the fuel rods 5 and the output cam (, the walls of the fuel rods 5 from both sides are heated and then pi saturated or overheated - the pi coolant changes

due to a change in the temperature of the fuel rods 5. When the PM - mode changes on the fuel element surface during a crisis, the flow redistributes over the cross section 5 and part of the heat passes t the false side of the TR wall, the temperature change at ,,, not or the assembly radius

changes in the coolant, redistributed flows to the surface, and an improvement in their temperature. This makes it possible to increase the heat release

(56) Terentyev V.D., Fundamentals and. individual calculations of ship and steam generators. L. .. Seizure with. 51.

Kramerov A.Ya. The Question of Nuclear Reactors, f.-i 1971, p. 199-200, Fig. 7, 6.

intermediate manifold, run- separated from one another and from the side of the tube plate TBJ i ЩА so that, in order to

At the same time, fuel rods in the housing with the formation of a navel are separated from one another by i-fuel rods.

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