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Title: Prints for precision engineering research lathe (Engineering Materials)

Abstract

The precision engineering research lathe (PERL) is a small two-axis, ultra-high-precision turning machine used for turning very small contoured parts. Housed in a laminar-flow enclosure for temperature control, called a clean air envelope, PERL is maintained at a constant 68 degrees F (plus or minus 1 degree). The size of the lathe is minimized to reduce sensitivity to temperature variations. This, combined with internal water cooling of the spindle motor, the only major heat source on the machine, permits the use of air-shower temperature control. (This approach is a departure from previous designs for larger machines where liquid shower systems are used.) Major design features include the use of a T-configuration, hydrostatic oil slides, capstan slide drives, air-bearing spindles, and laser interferometer position feedback. The following features are particularly noteworthy: (1) to obtain the required accuracy and friction characteristics, the two linear slides are supported by 10-cm-travel hydrostatic bearings developed at LLNL; (2) to minimize backlash and friction, capstan drives are used to provide the slide motions; and (3) to obtain the best surface finish possible, asynchronous (nonrepeatable) spindle motion is minimized by driving the spindle directly with a brushless dc torque motor. PERL operates in single-axis mode. Using facingmore » cuts on copper with a diamond tool, surface finishes of 7.5 nm peak-to-valley (1.5 nm rms) have been achieved.« less

Publication Date:
Research Org.:
Lawrence Livermore National Lab., CA (USA)
OSTI Identifier:
5574339
Report Number(s):
CAPE-2944
ON: TI85011046
DOE Contract Number:  
W-7405-ENG-48
Resource Type:
Miscellaneous
Resource Relation:
Other Information: 146 35-mm aperture cards
Country of Publication:
United States
Language:
English
Subject:
42 ENGINEERING; LABORATORY EQUIPMENT; LATHES; DESIGN; HYDROSTATIC BEARINGS; MECHANICAL ENGINEERING; SURFACE FINISHING; BEARINGS; ENGINEERING; EQUIPMENT; MACHINE TOOLS; TOOLS; 420200* - Engineering- Facilities, Equipment, & Techniques

Citation Formats

. Prints for precision engineering research lathe (Engineering Materials). United States: N. p., 1982. Web.
. Prints for precision engineering research lathe (Engineering Materials). United States.
. 1982. "Prints for precision engineering research lathe (Engineering Materials)". United States.
@article{osti_5574339,
title = {Prints for precision engineering research lathe (Engineering Materials)},
author = {},
abstractNote = {The precision engineering research lathe (PERL) is a small two-axis, ultra-high-precision turning machine used for turning very small contoured parts. Housed in a laminar-flow enclosure for temperature control, called a clean air envelope, PERL is maintained at a constant 68 degrees F (plus or minus 1 degree). The size of the lathe is minimized to reduce sensitivity to temperature variations. This, combined with internal water cooling of the spindle motor, the only major heat source on the machine, permits the use of air-shower temperature control. (This approach is a departure from previous designs for larger machines where liquid shower systems are used.) Major design features include the use of a T-configuration, hydrostatic oil slides, capstan slide drives, air-bearing spindles, and laser interferometer position feedback. The following features are particularly noteworthy: (1) to obtain the required accuracy and friction characteristics, the two linear slides are supported by 10-cm-travel hydrostatic bearings developed at LLNL; (2) to minimize backlash and friction, capstan drives are used to provide the slide motions; and (3) to obtain the best surface finish possible, asynchronous (nonrepeatable) spindle motion is minimized by driving the spindle directly with a brushless dc torque motor. PERL operates in single-axis mode. Using facing cuts on copper with a diamond tool, surface finishes of 7.5 nm peak-to-valley (1.5 nm rms) have been achieved.},
doi = {},
url = {https://www.osti.gov/biblio/5574339}, journal = {},
number = ,
volume = ,
place = {United States},
year = {Wed Dec 01 00:00:00 EST 1982},
month = {Wed Dec 01 00:00:00 EST 1982}
}

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