High Thrust & High ISP Nuclear Thermal Rocket (NTR) Grooved Ring Fuel Element (GRFE)

Metadata Updated: February 28, 2019

Missions to Mars will benefit from propulsion systems with performance levels exceeding that of today[HTML_REMOVED]s best chemical engines. Nuclear Thermal Rocket (NTR) technology has the greatest potential for the near term success of increasing performance, reducing cost, and increasing safety margins by reducing total fuel required, thus reducing total launches for Mars missions. Solid core NTR engines during the Rover/NERVA program demonstrated specific impulses around 850 seconds. The objective of this innovation effort being proposed for MSFC is to mature an idea with great potential, to analytically verify that the Grooved Ring Fuel Element (GFRE) is thermal- hydraulically stable and confirm that it is able to support high heat transfer rates. These ideas and analyses will quantify the projected performance advantages of the GRFE over the Rover/NERVA and particle bed nuclear fuel elements. Missions to Mars will almost certainly require propulsion systems with performance levels exceeding that of today[HTML_REMOVED]s best chemical engines. A strong candidate for that propulsion system is the Nuclear Thermal Rocket (NTR). During the 1960[HTML_REMOVED]s and 1970[HTML_REMOVED]s the United States embarked on a nuclear rocket program called Rover/NERVA which was quite successful in developing high performance nuclear fuel forms. In spite of this success, however, there surfaced a number of materials and configuration issues which limited the ultimate performance of these engines. In particular, the relatively heavy and difficult to fabricate prismatic fuel block, with its small surface to volume ratio ([HTML_REMOVED] 5.6 cm-1), caused large core pressure drops which consequently limited the engine thrust to weight ratios to only 3 or 4. To address the problem of low thrust to weight in the Rover/NERVA engine design, a new configuration was proposed called the particle bed reactor where the fuel had a much higher surface to volume ratio ([HTML_REMOVED] 40 cm-1) and a small pressure drop. This engine was projected to have a thrust to weight ratio of 20 or greater, although the design ultimately proved unsatisfactory because of inherent problems with thermal instabilities resulting from unconstrained propellant flow through the fuel particles. The GFRE is a concept which attempts to combine the best features of the Rover/NERVA fuel element and the particle bed fuel element.

Access & Use Information

Public: This dataset is intended for public access and use. License: U.S. Government Work

Downloads & Resources


Metadata Created Date August 1, 2018
Metadata Updated Date February 28, 2019

Metadata Source

Harvested from NASA Data.json

Additional Metadata

Resource Type Dataset
Metadata Created Date August 1, 2018
Metadata Updated Date February 28, 2019
Publisher Space Technology Mission Directorate
Unique Identifier TECHPORT_10889
Maintainer Email
Public Access Level public
Bureau Code 026:00
Metadata Context https://project-open-data.cio.gov/v1.1/schema/catalog.jsonld
Metadata Catalog ID https://data.nasa.gov/data.json
Schema Version https://project-open-data.cio.gov/v1.1/schema
Catalog Describedby https://project-open-data.cio.gov/v1.1/schema/catalog.json
Harvest Object Id fa61a73f-5cbf-45b3-9f6e-1a01f77c6d2f
Harvest Source Id 39e4ad2a-47ca-4507-8258-852babd0fd99
Harvest Source Title NASA Data.json
Data First Published 2012-09-01
Homepage URL https://techport.nasa.gov/view/10889
License http://www.usa.gov/publicdomain/label/1.0/
Data Last Modified 2018-07-19
Program Code 026:027
Source Datajson Identifier True
Source Hash 6d0ee5f91d74948bf431eff8c0ca1e503474f890
Source Schema Version 1.1

Didn't find what you're looking for? Suggest a dataset here.