NOMAGE4 activities 2011, Part II, Supercritical water loop

Publication: ResearchReport – Annual report year: 2012

Standard

NOMAGE4 activities 2011, Part II, Supercritical water loop. / Vierstraete, Pierre; Van Nieuwenhove, Rudi; Lauritzen, Bent.

Roskilde : NKS, 2012. 66 p. (NKS-255).

Publication: ResearchReport – Annual report year: 2012

Harvard

Vierstraete, P, Van Nieuwenhove, R & Lauritzen, B 2012, NOMAGE4 activities 2011, Part II, Supercritical water loop. NKS, Roskilde. NKS-255

APA

Vierstraete, P., Van Nieuwenhove, R., & Lauritzen, B. (2012). NOMAGE4 activities 2011, Part II, Supercritical water loop. Roskilde: NKS. (NKS-255).

CBE

Vierstraete P, Van Nieuwenhove R, Lauritzen B 2012. NOMAGE4 activities 2011, Part II, Supercritical water loop. Roskilde: NKS. 66 p. (NKS-255).

MLA

Vierstraete, Pierre, Rudi Van Nieuwenhove, and Bent Lauritzen NOMAGE4 activities 2011, Part II, Supercritical water loop Roskilde: NKS. 2012. (NKS-255).

Vancouver

Vierstraete P, Van Nieuwenhove R, Lauritzen B. NOMAGE4 activities 2011, Part II, Supercritical water loop. Roskilde: NKS, 2012. 66 p. (NKS-255).

Author

Vierstraete, Pierre; Van Nieuwenhove, Rudi; Lauritzen, Bent / NOMAGE4 activities 2011, Part II, Supercritical water loop.

Roskilde : NKS, 2012. 66 p. (NKS-255).

Publication: ResearchReport – Annual report year: 2012

Bibtex

@book{1fe176e0c6ca4c0aaa5c1bc951e15e17,
title = "NOMAGE4 activities 2011, Part II, Supercritical water loop",
publisher = "NKS",
author = "Pierre Vierstraete and {Van Nieuwenhove}, Rudi and Bent Lauritzen",
year = "2012",
isbn = "978-87-7893-327-0",
series = "NKS-255",

}

RIS

TY - RPRT

T1 - NOMAGE4 activities 2011, Part II, Supercritical water loop

A1 - Vierstraete,Pierre

A1 - Van Nieuwenhove,Rudi

A1 - Lauritzen,Bent

AU - Vierstraete,Pierre

AU - Van Nieuwenhove,Rudi

AU - Lauritzen,Bent

PB - NKS

PY - 2012

Y1 - 2012

N2 - The supercritical water reactor (SCWR) is one of the six different reactor technologies selected for research and development under the Generation IV program. Several countries have shown interest to this concept but up to now, there exist no in-pile facilities to perform the required material and fuel tests. Working on this direction, the Halden Reactor Project has started an activity in collaboration with Risoe-DTU (with Mr. Rudi Van Nieuwenhove as the project leader) to study the feasibility of a SCW loop in the Halden Reactor, which is a Heavy Boiling Water Reactor (HBWR). The ultimate goal of the project is to design a loop allowing material and fuel test studies at significant mass flow with in-core instrumentation and chemistry control possibilities. The present report focusses on the main heat exchanger required for such a loop in the Halden Reactor. The goal of this heat exchanger is to assure a supercritical flow state inside the test section (the core side) and a subcritical flow state inside the pump section . The objective is to design the heat exchanger in order to optimize the efficiency of the heat transfer and to respect several requirements as the room available inside the reactor hall, the maximal total pressure drop allowed and so on.

AB - The supercritical water reactor (SCWR) is one of the six different reactor technologies selected for research and development under the Generation IV program. Several countries have shown interest to this concept but up to now, there exist no in-pile facilities to perform the required material and fuel tests. Working on this direction, the Halden Reactor Project has started an activity in collaboration with Risoe-DTU (with Mr. Rudi Van Nieuwenhove as the project leader) to study the feasibility of a SCW loop in the Halden Reactor, which is a Heavy Boiling Water Reactor (HBWR). The ultimate goal of the project is to design a loop allowing material and fuel test studies at significant mass flow with in-core instrumentation and chemistry control possibilities. The present report focusses on the main heat exchanger required for such a loop in the Halden Reactor. The goal of this heat exchanger is to assure a supercritical flow state inside the test section (the core side) and a subcritical flow state inside the pump section . The objective is to design the heat exchanger in order to optimize the efficiency of the heat transfer and to respect several requirements as the room available inside the reactor hall, the maximal total pressure drop allowed and so on.

BT - NOMAGE4 activities 2011, Part II, Supercritical water loop

SN - 978-87-7893-327-0

T3 - NKS-255

T3 - en_GB

ER -