Main heat and waste heat integrated thermal exchanger for small nuclear reactor

Abstract

A main heat and waste heat integrated thermal exchanger for a small nuclear reactor has a first coolant zone for a first main heat loop, a second coolant zone for a second main heat loop and a third coolant zone for a waste heat removal loop. The first coolant for the first main heat loop passes through the first coolant inlet, and then reaches the orifice plate, and finally flows out from the first coolant outlet. The second coolant for the second main heat loop passes through the second coolant inlet, and then reaches the lower tube sheet, and finally flows out from the second coolant outlet. The third coolant for the waste heat removal loop enters the entrance sleeve through the third coolant inlet, and then enters multiple tubes of the tube bundle, and then enters the exit sleeve, and finally flows out from the third coolant outlet.

Description

CROSS REFERENCE OF RELATED APPLICATION

The present invention claims priority under 35 U.S.C. 119(a-d) to CN 202111007621.9, filed Aug. 30, 2021.

BACKGROUND OF THE PRESENT INVENTION

Field of Invention

The present invention relates to the field of advanced nuclear energy development technology, and more particularly to a main heat and waste heat integrated thermal exchanger for a small nuclear reactor.

Description of Related Arts

In order to match the advantages of the small nuclear reactors with small size, light weight and low cost, it is urgent to develop a corresponding main thermal exchanger and a corresponding waste thermal exchanger for the small nuclear reactors, so as to ensure that the reactors are able to effectively export decay heat under normal shutdown and accident conditions, and at the same time, the main thermal exchanger and the waste thermal exchanger have a small enough volume to fit in the confined space inside the reactors. However, the two types of thermal exchangers usually work independently of each other, which poses a great challenge to volume reduction. To sum up, it is necessary to for the main heat and waste thermal exchangers of the small nuclear reactors to be compact and integrated in structure, which should not occupy too much volume, and at the same time, should ensure the heat transfer intensity and minimize thermal stress. Therefore, it is necessary for reactor engineering to develop a main heat and waste heat integrated thermal exchanger for small nuclear reactors, which is helpful to advance the process of autonomous mastery of small nuclear reactor technology in China.

SUMMARY OF THE PRESENT INVENTION

In order to overcome problems in prior arts, the present invention provides a main heat and waste heat integrated thermal exchanger for a small nuclear reactor, which provides the equipment basis for the design of the reactor and residual heat removal system.

To achieve the above object, the present invention provides technical solutions as follows.

A main heat and waste heat integrated thermal exchanger for a small nuclear reactor comprises:

a housing;

a lower cap and an upper cap both of which are fixed at a bottom and a top of the housing respectively, wherein the lower cap has an annular entrance chamber for a second main heat loop, and the upper cap has an annular exit chamber for the second main heat loop;

an entrance sleeve for a waste heat removal loop, wherein the entrance sleeve is sleeved within the housing and the lower cap, and is provided at a center of the bottom of the housing and a center of the lower cap;

an exit sleeve for the waste heat removal loop, wherein the exit sleeve is sleeved within the upper cap, and is provided at a center of the upper cap; and

a tube bundle, which is provided within the housing, comprising multiple tubes, wherein a portion of the multiple tubes, which are provided between the housing and the entrance sleeve, are fixed by an upper tube sheet and a lower tube sheet, and another portion of the multiple tubes, which are provided at a middle portion of the housing, are fixed by the upper tube sheet and the entrance sleeve, wherein:

the thermal exchanger has a first coolant zone for a first main heat loop, a second coolant zone for the second main heat loop and a third coolant zone for the waste heat removal loop;

the first coolant zone has a first coolant flow space which is defined by an inner wall of the housing, an outer wall of the entrance sleeve and an outer wall of each of the portion of the multiple tubes of the tube bundle which are provided between the housing and the entrance sleeve;

the second coolant zone has a second coolant flow space which is defined by an interior of each of the portion of the multiple tubes of the tube bundle which are provided between the housing and the entrance sleeve, the annular entrance chamber and the annular exit chamber;

the third coolant zone has a third coolant flow space which is defined by an interior of the entrance sleeve, an interior of the exit sleeve and an interior of each of the another portion of the multiple tubes of the tube bundle which connect the entrance sleeve with the exit sleeve;

the housing has a first coolant inlet for the first main heat loop and a first coolant outlet for the first main heat loop at one side wall thereof, and at an upper portion and a lower portion thereof within the first coolant zone;

the lower cap has a second coolant inlet for the second main heat loop, the upper cap has a second coolant outlet for the second main heat loop, and the second coolant inlet and the second coolant outlet are diagonally opposite to each other;

the entrance sleeve has a third coolant inlet for the waste heat removal loop at a bottom thereof, the exit sleeve has a third coolant outlet for the waste heat removal loop at a top thereof;

an orifice plate for distributing a flow of a first coolant in the first main heat loop is transversely set below the first coolant inlet and within the first coolant zone;

the first coolant for the first main heat loop enters the first main heat loop through the first coolant inlet, and then reaches the orifice plate for heat emission, and finally converges and flows out from the first coolant outlet;

a second coolant for the second main heat loop enters the second main heat loop through the second coolant inlet, and then reaches the lower tube sheet for distributing a flow of the second coolant for the second main heat loop and absorbing heat, and finally converges and flows out from the second coolant outlet;

a third coolant for the waste heat removal loop enters the entrance sleeve through the third coolant inlet, and then enters the another portion of the multiple tubes of the tube bundle for heat absorption, and then enters the exit sleeve, and finally converges and flows out from the third coolant outlet.

Compared with prior arts, the present invention has some beneficial effects as follows.

(1) The second main heat loop and the waste heat removal loop simultaneously exchange heat with the first main heat loop in compact spaces, which improves the heat transfer efficiency.

(2) Countercurrent heat exchange occurs between the first coolant for the first main heat loop and one of the second coolant for the second main heat loop and the third coolant for the waste heat removal loop, which is beneficial to reduce pressure drop and local thermal stress.

(3) The second coolant for the second main heat loop and the third coolant for the waste heat removal loop flow in the same direction, which is beneficial to suppress flow-induced vibration.

(4) The design of integrated main heat transfer and waste heat transfer is conducive to the miniaturization of nuclear reactors.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a structural schematic diagram of a main heat and waste heat integrated thermal exchanger for a small nuclear reactor provided by the present invention.

FIG. 2 is a cross-sectional view along a II-II direction of FIG. 1.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT

The present invention is further described in detail by taking a small fluoride salt-cooled high temperature reactor as an example in combination with accompanying drawings.

Referring to FIGS. 1 and 2, a main heat and waste heat integrated thermal exchanger for a small nuclear reactor according to a preferred embodiment of the present invention is illustrated. The thermal exchanger has a first coolant inlet 1 for a first main heat loop, a first coolant outlet 2 for the first main heat loop, a second coolant inlet 3 for a second main heat loop, a second coolant outlet 4 for the second main heat loop, a third coolant inlet 5 for a waste heat removal loop, and a third coolant outlet 6 for the waste heat removal loop. Moreover, the thermal exchanger comprises an orifice plate 7 for distributing a flow of a first coolant in the first main heat loop, a tube bundle 8, a housing 9, an upper tube sheet 10, a lower tube sheet 11, a lower cap 12, an entrance sleeve 13 for the waste heat removal loop, an upper cap 14, and an exit sleeve 15 for the waste heat removal loop, wherein the lower cap 12 has an annular entrance chamber for the second main heat loop, and the upper cap 14 has an annular exit chamber for the second main heat loop.

According to the preferred embodiment of the present invention, the tube bundle 8, having a triangular structure, comprises multiple tubes, wherein a portion of the multiple tubes are fixed by the upper tube sheet 10 and the lower tube sheet 11, and another portion of the multiple tubes are fixed by the upper tube sheet 10 and the entrance sleeve 13.

The thermal exchanger has three fluid zones, that is, a first coolant zone A for the first main heat loop, a second coolant zone B for the second main heat loop and a third coolant zone C for the waste heat removal loop. The first coolant zone A has a first coolant flow space which is defined by an inner wall of the housing 9, an outer wall of the entrance sleeve 13 and an outer wall of each of the portion of the multiple tubes of the tube bundle 8 which are provided between the housing 9 and the entrance sleeve 13. The second coolant zone B has a second coolant flow space which is defined by an interior of each of the portion of the multiple tubes of the tube bundle 8 which are provided between the housing 9 and the entrance sleeve 13, the annular entrance chamber and the annular exit chamber. The third coolant zone C has a third coolant flow space which is defined by an interior of the entrance sleeve 13, an interior of the exit sleeve 15 and an interior of each of the another portion of the multiple tubes of the tube bundle 8 which connect the entrance sleeve 13 with the exit sleeve 15.

The first coolant inlet 1 for the first main heat loop and the first coolant outlet 2 for the first main heat loop are provided at one side wall of the housing 9, and provided at an upper portion and a lower portion of the housing 9 within the first coolant zone A. The orifice plate 7 for distributing the flow of a first coolant in the first main heat loop is transversely set below the first coolant inlet 1 and within the first coolant zone A. The second coolant inlet 3 and the second coolant outlet 4 for the second main heat loop are provided at the lower cap 12 and the upper cap 14 respectively and are diagonally opposite to each other. The third coolant inlet 5 and the third coolant outlet 6 for the waste heat removal loop are provided at a bottom of the entrance sleeve 13 and a top of the exit sleeve 15 respectively.

Referring to FIG. 1, the first coolant for the first main heat loop enters the first main heat loop through the first coolant inlet 1, and then reaches the orifice plate 7 for heat emission, and finally converges and flows out from the first coolant outlet 2. A second coolant for the second main heat loop enters the second main heat loop through the second coolant inlet 3, and then reaches the lower tube sheet 11 for distributing a flow of the second coolant for the second main heat loop and absorbing heat, and finally converges and flows out from the second coolant outlet 4. A third coolant for the waste heat removal loop enters the entrance sleeve 13 through the third coolant inlet 5, and then enters the another portion of the multiple tubes of the tube bundle 8 for heat absorption, and then enters the exit sleeve 15, and finally converges and flows out from the third coolant outlet 6.

The number and size of the tube bundle 8 are dependent on specific working conditions, and here the number and size of the tube bundles 8 are not determined.

The above content is a further detailed description of the present invention in combination with the specific preferred embodiment, and it is unable to be considered that the specific embodiment of the present invention is limited to this. For those skilled in the art, without departing from the concept of the present invention, any simple deduction or replacement should fall within the protection scope determined by the claims of the present invention.

Claims

1. A main heat and waste heat integrated thermal exchanger for a small nuclear reactor, the thermal exchanger comprising: a housing;a lower cap and an upper cap both of which are fixed at a bottom and a top of the housing respectively, wherein the lower cap has an annular entrance chamber for a second main heat loop, and the upper cap has an annular exit chamber for the second main heat loop;an entrance sleeve for a waste heat removal loop, wherein the entrance sleeve is sleeved within the housing and the lower cap, and is provided at a center of the bottom of the housing and a center of the lower cap;an exit sleeve for the waste heat removal loop, wherein the exit sleeve is sleeved within the upper cap, and is provided at a center of the upper cap; anda tube bundle, which is provided within the housing, comprising multiple tubes, wherein a portion of the multiple tubes, which are provided between the housing and the entrance sleeve, are fixed by an upper tube sheet and a lower tube sheet, and another portion of the multiple tubes, which are provided at a middle portion of the housing, are fixed by the upper tube sheet and the entrance sleeve, wherein:the thermal exchanger has a first coolant zone for a first main heat loop, a second coolant zone for the second main heat loop and a third coolant zone for the waste heat removal loop;the first coolant zone has a first coolant flow space which is defined by an inner wall of the housing, an outer wall of the entrance sleeve and an outer wall of each of the portion of the multiple tubes of the tube bundle which are provided between the housing and the entrance sleeve;the second coolant zone has a second coolant flow space which is defined by an interior of each of the portion of the multiple tubes of the tube bundle which are provided between the housing and the entrance sleeve, the annular entrance chamber and the annular exit chamber;the third coolant zone has a third coolant flow space which is defined by an interior of the entrance sleeve, an interior of the exit sleeve and an interior of each of the another portion of the multiple tubes of the tube bundle which connect the entrance sleeve with the exit sleeve;the housing has a first coolant inlet for the first main heat loop and a first coolant outlet for the first main heat loop at one side wall thereof, and at an upper portion and a lower portion thereof within the first coolant zone;the lower cap has a second coolant inlet for the second main heat loop, the upper cap has a second coolant outlet for the second main heat loop, and the second coolant inlet and the second coolant outlet are diagonally opposite to each other;the entrance sleeve has a third coolant inlet for the waste heat removal loop at a bottom thereof, the exit sleeve has a third coolant outlet for the waste heat removal loop at a top thereof;an orifice plate for distributing a flow of a first coolant in the first main heat loop is transversely set below the first coolant inlet and within the first coolant zone;the first coolant for the first main heat loop enters the first main heat loop through the first coolant inlet, and then reaches the orifice plate for heat emission, and finally converges and flows out from the first coolant outlet;a second coolant for the second main heat loop enters the second main heat loop through the second coolant inlet, and then reaches the lower tube sheet for distributing a flow of the second coolant for the second main heat loop and absorbing heat, and finally converges and flows out from the second coolant outlet;a third coolant for the waste heat removal loop enters the entrance sleeve through the third coolant inlet, and then enters the another portion of the multiple tubes of the tube bundle for heat absorption, and then enters the exit sleeve, and finally converges and flows out from the third coolant outlet.

2. The main heat and waste heat integrated thermal exchanger according to claim 1, wherein the tube bundle has a triangular structure.