RU2115083C1 - Heat-transfer apparatus - Google Patents

Abstract

FIELD: thermal and nuclear power engineering; miscellaneous heat-generating plants. SUBSTANCE: apparatus has fuel elements 1,2 arranged concentrically to form circular slit to receive swirling devices 4 mounted so that they form gap along channel path separated by means of longitudinal ribs provided on convex surface of element 2 into several longitudinal slits. Spiral channels formed by concave surface of external fuel element 1 and changeable parts of swirling device 4 accommodate at least one guide member 7 in the form of annular fragment whose ends abut against turns of swirling device 4. Members 7 are relatively displaced both through width and length of channel confined within turns of device 4. Height of annular fragments at sections between longitudinal ribs does not exceed that of turns of device 4. Guide members 7 are beveled in transverse direction on inlet side of circular channel. EFFECT: improved design. 6 cl, 3 dwg

Description

 The invention relates to energy, can be used in installations for producing steam and is an improvement on the author. St. USSR N 1605671.

 The purpose of the invention is to increase operational reliability.

 For this, at least one guide element 7 in the form of an annular fragment is placed on the surface of the external fuel element between the turns of the twisting device 4. The ends of the annular fragment 7 are adjacent to the turns of the twisting device 4 (ribs). The guiding elements 7 are offset relative to each other both in width and along the length of the channel bounded by the screws of the twisting device 4. The height of the annular fragments 7 in the sections between the longitudinal ribs 6 exceeds the height of the turns of the twisting device 4. The guiding elements 7 in the transverse direction are made with a bevel with side of the entrance to the annular channel.

 The guiding elements 7, interacting with the coolant on a concave surface, partially discharge part of the liquid entering the concave surface due to centrifugal forces onto the convex surface, evenly distribute the liquid between the concave surface of the outer fuel element 1 and the convex surface of the internal fuel element 2, thereby increasing the critical thermal loads on both heat transfer surfaces and increasing the reliability of the heat transfer device.

 The invention relates to energy, can be used in installations for producing steam and is an improvement on the author. testimonial. USSR N 1605671.

 The purpose of the invention is to increase the operational reliability of the heat transfer device.

 In FIG. 1 shows the proposed heat transfer device; in FIG. 2 - scan concave surface; in FIG. 3 is a cross-sectional view of guide elements.

 The heat transfer device contains fuel elements 1 and 2 located concentrically with the formation of an annular gap 3.

 Torsion devices 4 are installed inside the annular gap 3. Special inserts, screw ribs, ribbons, etc. can be used as the latter. The twisting devices 4 are installed so that they form a gap 5 along the channel path. The gap 5, using longitudinal ribs 6 mounted on the convex surface of element 2, is divided into several longitudinal gaps. In FIG. 1 shows 4 slots (4 longitudinal ribs).

 At least one guide element 7 in the form of an annular fragment is placed in the spiral channels formed by the concave surface of the outer fuel element 1 and replaceable elements of the swirling device 4 (ribs). The ends of the annular fragment 7 are adjacent to the turns of the twisting device 4 (ribs). The guide elements 7 are offset relative to each other both in width and along the length of the channel bounded by turns of the twisting device 4.

 The height of the annular fragments 7 in the sections between the longitudinal ribs 6 exceeds the height of the turns of the twisting device 4. The guiding elements 7 in the transverse direction are beveled from the side of the entrance to the annular channel (Fig. 3).

 The heat transfer device operates as follows.

 The coolant enters the input of the device, part of the coolant enters the elements of the swirling device 4 (ribs), the rest is distributed along the longitudinal slots formed by the swirling device 4 and the concave surface of the outer fuel element 1 and the convex surface of the inner fuel element 2. The swirling device, interacting with the coolant, forms a system of three-dimensional vortices on the concave and convex surfaces of fuel rods 1 and 2, which contribute to a significant increase in critical heat fluxes. The guide elements 7, interacting with the coolant on a concave surface, partially dump it on the convex surface of the inner fuel element 2. As a result, the liquid is distributed between the convex surface of the inner fuel element 2 and the concave surface of the outer fuel element 1.

 By changing the size of the guide elements, it is possible to redistribute the liquid between the surfaces of the fuel rods 1 and 2 in accordance with the thermal load of the fuel rods and thereby increase the energy intensity of the device due to the almost simultaneous occurrence of a heat transfer crisis on both surfaces and, accordingly, increase its operational reliability.

Claims (6)

 1. A heat transfer device containing concentrically arranged fuel elements with ribs located in the annular space between them, made on the outer surface of the inner element, and on the inner surface of the outer element there is a twisting device in the form of turns of spiral ribs, characterized in that, in order to increase operational reliability, the ribs on the surface of the inner element are parallel to its longitudinal axis, and on the surface of the outer element between the turns at least one guide element in the form of an annular fragment is placed in a twisting device.  2. The device according to claim 1, characterized in that the ends of the annular fragment are adjacent to the turns of the twisting device and have a height not exceeding the height of the turns.  3. The device according to claim 1, characterized in that the ends of the annular fragment are installed with a gap relative to the turns of the twisting device.  4. The device according to claim 1, characterized in that the guide elements are installed with an offset relative to each other both in width and along the length of the channel limited by the turns of the twisting device.  5. The device according to claim 1, characterized in that the height of the annular fragments in the areas between the longitudinal ribs exceeds the height of the turns of the ribs of the twisting device.  6. The device according to claim 1, characterized in that the guide elements have a bevel in cross section from the side of the medium inlet into the annular channel.

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