Design and Performance of the Hotrod Melt-Tip Ice-Drilling System

We introduce the design and performance of a melt-tip ice-drilling system designed to insert a temperature sensor cable into ice. The melt tip is relatively simple and low cost, designed for a one-way trip to the ice-bed interface. The drilling system consists of a melt tip, umbilical cable, winch,...

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Main Authors: Colgan, William, Shields, Christopher, Talalay, Paval, Fan, Xiaopeng, Lines, Austin P., Elliott, Joshua, Rajaram, Harihar, Mankoff, Kenneth, Jensen, Morten, Backes, Mira, Liu, Yunchen, Wei, Xianzhe, Karlsson, Nanna B., Spanggård, Henrik, Pedersen, Allan Ø.
Format: Text
Language:English
Published: 2022
Subjects:
Ice Sheet
Online Access:https://doi.org/10.5194/gi-2022-18
https://gi.copernicus.org/preprints/gi-2022-18/
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spelling ftcopernicus:oai:publications.copernicus.org:gid106652 2023-05-15T16:41:07+02:00 Design and Performance of the Hotrod Melt-Tip Ice-Drilling System Colgan, William Shields, Christopher Talalay, Paval Fan, Xiaopeng Lines, Austin P. Elliott, Joshua Rajaram, Harihar Mankoff, Kenneth Jensen, Morten Backes, Mira Liu, Yunchen Wei, Xianzhe Karlsson, Nanna B. Spanggård, Henrik Pedersen, Allan Ø. 2022-10-06 application/pdf https://doi.org/10.5194/gi-2022-18 https://gi.copernicus.org/preprints/gi-2022-18/ eng eng doi:10.5194/gi-2022-18 https://gi.copernicus.org/preprints/gi-2022-18/ eISSN: 2193-0864 Text 2022 ftcopernicus https://doi.org/10.5194/gi-2022-18 2022-10-10T16:22:41Z We introduce the design and performance of a melt-tip ice-drilling system designed to insert a temperature sensor cable into ice. The melt tip is relatively simple and low cost, designed for a one-way trip to the ice-bed interface. The drilling system consists of a melt tip, umbilical cable, winch, interface, power supply, and support items. The melt tip and the winch are the most novel elements of the drilling system, and we make the hardware and electrical designs of these components available open access. Tests conducted in a laboratory ice well indicate that the melt tip has an electrical energy to forward melting heat transfer efficiency of ~35 % with a theoretical maximum penetration rate of ~12 m/hr at maximum 6.0 kW power. In contrast, ice-sheet testing suggests the melt tip has an analogous heat transfer efficiency of ~15 % with a theoretical maximum penetration rate of ~6 m/hr. We expect the efficiency gap between laboratory and field performance to decrease with increasing operator experience. Umbilical freeze-in due to borehole refreezing is the primary depth-limiting factor of the drilling system. Enthalpy-based borehole refreezing assessments predict refreezing below critical umbilical diameter in ~4 hours at -20 ˚C ice temperatures and ~20 hours at -2 ˚C. This corresponds to a theoretical depth limit of up to ~200 m, depending on firn thickness, ice temperature and operator experience. Text Ice Sheet Copernicus Publications: E-Journals
institution Open Polar
collection Copernicus Publications: E-Journals
op_collection_id ftcopernicus
language English
description We introduce the design and performance of a melt-tip ice-drilling system designed to insert a temperature sensor cable into ice. The melt tip is relatively simple and low cost, designed for a one-way trip to the ice-bed interface. The drilling system consists of a melt tip, umbilical cable, winch, interface, power supply, and support items. The melt tip and the winch are the most novel elements of the drilling system, and we make the hardware and electrical designs of these components available open access. Tests conducted in a laboratory ice well indicate that the melt tip has an electrical energy to forward melting heat transfer efficiency of ~35 % with a theoretical maximum penetration rate of ~12 m/hr at maximum 6.0 kW power. In contrast, ice-sheet testing suggests the melt tip has an analogous heat transfer efficiency of ~15 % with a theoretical maximum penetration rate of ~6 m/hr. We expect the efficiency gap between laboratory and field performance to decrease with increasing operator experience. Umbilical freeze-in due to borehole refreezing is the primary depth-limiting factor of the drilling system. Enthalpy-based borehole refreezing assessments predict refreezing below critical umbilical diameter in ~4 hours at -20 ˚C ice temperatures and ~20 hours at -2 ˚C. This corresponds to a theoretical depth limit of up to ~200 m, depending on firn thickness, ice temperature and operator experience.
format Text
author Colgan, William
Shields, Christopher
Talalay, Paval
Fan, Xiaopeng
Lines, Austin P.
Elliott, Joshua
Rajaram, Harihar
Mankoff, Kenneth
Jensen, Morten
Backes, Mira
Liu, Yunchen
Wei, Xianzhe
Karlsson, Nanna B.
Spanggård, Henrik
Pedersen, Allan Ø.
spellingShingle Colgan, William
Shields, Christopher
Talalay, Paval
Fan, Xiaopeng
Lines, Austin P.
Elliott, Joshua
Rajaram, Harihar
Mankoff, Kenneth
Jensen, Morten
Backes, Mira
Liu, Yunchen
Wei, Xianzhe
Karlsson, Nanna B.
Spanggård, Henrik
Pedersen, Allan Ø.
Design and Performance of the Hotrod Melt-Tip Ice-Drilling System
author_facet Colgan, William
Shields, Christopher
Talalay, Paval
Fan, Xiaopeng
Lines, Austin P.
Elliott, Joshua
Rajaram, Harihar
Mankoff, Kenneth
Jensen, Morten
Backes, Mira
Liu, Yunchen
Wei, Xianzhe
Karlsson, Nanna B.
Spanggård, Henrik
Pedersen, Allan Ø.
author_sort Colgan, William
title Design and Performance of the Hotrod Melt-Tip Ice-Drilling System
title_short Design and Performance of the Hotrod Melt-Tip Ice-Drilling System
title_full Design and Performance of the Hotrod Melt-Tip Ice-Drilling System
title_fullStr Design and Performance of the Hotrod Melt-Tip Ice-Drilling System
title_full_unstemmed Design and Performance of the Hotrod Melt-Tip Ice-Drilling System
title_sort design and performance of the hotrod melt-tip ice-drilling system
publishDate 2022
url https://doi.org/10.5194/gi-2022-18
https://gi.copernicus.org/preprints/gi-2022-18/
genre Ice Sheet
genre_facet Ice Sheet
op_source eISSN: 2193-0864
op_relation doi:10.5194/gi-2022-18
https://gi.copernicus.org/preprints/gi-2022-18/
op_doi https://doi.org/10.5194/gi-2022-18
_version_ 1766031551097733120

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