Data Sheet
-53-
Sherline Machine Technical Specifications
LATHES 4000 (4100) 4400 (4410)
Swing over bed 3.50" (90 mm) 3.50" (90 mm)
Swing over carriage 1.75" (45 mm) 1.75" (45 mm)
Distance between centers 8.00" (200 mm) 17.00" (430 mm)
Hole through spindle .405" (10 mm) .405" (10 mm)
Spindle nose ext. thread 3/4-16 T.P.I. 3/4-16 T.P.I.
Spindle nose int. taper #1 Morse #1 Morse
Travel of crosslide 3.25" (83 mm) 3.25" (83 mm)
Tailstock spindle taper #0 Morse #0 Morse
Protractor graduations 0° to 45° by 5° 0° to 45° by 5°
Handwheel graduations .001" (.01 mm) .001" (.01 mm)
Leadscrew Pitch .050"/rev (1 mm/rev) .050"/rev (1 mm/rev)
Electronically controlled
spindle speed range 70 to 2800 RPM 70 to 2800 RPM
Length overall** 23" (584 mm) 32.5" (826 mm)
Width overall** 10.25" (260 mm) 10.55" (267 mm)
Height overall** 8" (203 mm) 8.5" (216 mm)
Shipping weight 24 lb. (10.9 kg) 30 lb. (13.6 kg)
VERTICAL MILLS 5000 (5100) 5400 (5410) 2000 (2010) 5800 (5810)
Max. clearance,
table to spindle 8.00" (203 mm) 8.00" (203 mm) 9.00" (229 mm) 14.00" (356 mm)
Throat (no spacer) 2.25" (50 mm) 2.25" (50 mm) (Adjustable) (Adjustable)
(w/ headstock spacer) (optional) 3.50" (90mm) (Adjustable) (Adjustable)
Travel, X-axis* 8.65" (220 mm) 8.65" (220 mm) 8.65" (220 mm) 13.65" (347 mm)
Travel, Y-axis 3.00" (76 mm) 5.00" (127 mm) 7.00" (178 mm) 11.00" (279 mm)
Travel, Z-axis* 6.25" (159 mm) 6.25" (159 mm) 5.38" (137 mm) 9.38" (238 mm)
Hole through spindle .405" (10 mm) .405" (10 mm) .405" (10 mm) .405" (10 mm)
Spindle nose ext. thread 3/4-16 T.P.I. 3/4-16 T.P.I. 3/4-16 T.P.I. 3/4-16 T.P.I.
Spindle nose int. taper #1 Morse #1 Morse #1 Morse #1 Morse
Handwheel graduations .001" (.01 mm) .001" (.01 mm) .001" (.01 mm) .001" (.01 mm)
Leadscrew Pitch .050"/rev (1 mm/rev) .050"/rev (1 mm/rev) .050"/rev (1 mm/rev) .050"/rev (1 mm/rev)
Electronically controlled
spindle speed range 70 to 2800 RPM 70 to 2800 RPM 70 to 2800 RPM 70 to 2800 RPM
Width overall** 14.75" (375 mm) 15.00" (381 mm) 15.00" (381 mm) 20.00 (508 mm)
Depth overall** 11.75" (298 mm) 14.00" (356 mm) 22.25" (565 mm) 23.13" (588 mm)
Height overall (Max.)** 20.75" (527 mm) 20.75" (527 mm) 23.38" (568 mm) 24.50" (622 mm)
Table size 2.75" x 13.00"
(70 mm x 330 mm)
2.75" x 13.00"
(70 mm x 330 mm)
2.75" x 13.00"
(70 mm x 330 mm)
2.75" x 18.00"
(70 x 457 mm)
Hold-down provision 2 T-slots 2 T-slots 2 T-slots 3 T-slots
Shipping weight 33 lb (15.0 kg) 36 lb (16.3 kg) 38 lb (17.2 kg) 50 lb. (22.7 kg)
Movements in addition to
X-, Y- and Z-axes
Headstock rotation
(90° L/R)
Headstock rotation
(90° L/R)
Headstock rotation
(90° L/R)
Headstock rotation
(90° L/R)
Column rotation (90° L/R) Column rotation (none)
Column pivot (90° Fwd/Bk) Column pivot (90° Fwd/Bk)
Column swing (90°L/R) Column swing (90°L/R)
Col. travel (In/Out) 5.5"
(140 mm)
Col. travel (In/Out) 5.5"
(140 mm)
Spindle Motor Specifications
Input voltage—100 to 240 VAC, 50 to 60 Hz
Output to motor—90 VDC
Current draw—.5 to 15 amps depending on load
No-load output shaft speed—6000 RPM (no pulley)
NOTE: Motor and speed control can be purchased separately.
Part numbers are as follows:
P/N 33050—DC Motor and Speed Control
P/N 33060— Headstock, DC Motor, Speed Control
Machining Basics—Using the Handwheels
P
recision leadscrews and the handwheels that drive
them make it possible to produce highly accurate parts on
a mill or lathe. Here are some tips that should help rst-time
machinists get o to a good start.
Handwheel Increments
The handwheels on Sherline machines are marked in increments
of one one-thousandth of an inch (.001") for inch models or
one one-hundredth of a millimeter (.01 mm) for metric models.
One turn of the handwheel causes the leadscrew to advance the
tool or part .050" (inch models) and 1 mm (metric models). The
leadscrews are precision rolled and are quite accurate. Therefore,
moving the handwheel three rotations, for example, moves that
axis exactly .150" (or .03 mm on metric machines). This precise
method of moving the tool or part is what makes it possible to
make accurate parts on a metalworking lathe or mill.
When advancing the crosslide handwheel to take a cut on the
lathe, keep in mind that the amount of metal removed is actually
twice the amount you dial in. You are removing a given amount
of material from the radius of the part, which means you are
actually removing twice that amount from the diameter of the
part. (Some lathes are set up with the crosslide feed reading the
amount the diameter is reduced, however, since it is possible
for Sherline lathes to also be used in a milling conguration
where the crosslide feed becomes the X-axis feed for milling,
this system was not used.)
Turning the Handwheels
Each handwheel has a small handle. This is mainly used to
advance the leadscrew quickly over long distances. When actually
making a cut, or at least when making the nal cut on a part, most
machinists will turn the handwheel itself, using the outer surface
and alternating back and forth between hands to keep a smooth,
continuous feed going. On small machines, the handwheel is
turned by its outer knurled surface using the thumb and a nger
of one hand. Then, as that hand is released, the thumb and nger
of the other hand pick up the rotation. Using the handle on the
handwheel can introduce pushing and pulling motions that can
adversely aect the nish. (See Figure 86.)
FIGURE 86—A two-
handed technique
for turning the
handwheels yields
a better nal nish
on your part. Shown
in use here is an
adjustable “zero”
handwheel.
Adjustable “Zero” Handwheels
Adjustable handwheels are optional on all Sherline machines and
are standard on the deluxe models. The increments are marked
on a collar which can be disengaged from the handwheel and
reset to “zero” or any other desired setting. To release the collar,
turn the black, knurled release knob on the outer face of the
handwheel counter-clockwise. The collar can then be adjusted
without moving the handwheel itself. When reset to zero, carefully
retighten the black locking knob to reengage the collar and then
advance the handwheel. The advantage of this system is that it
can eliminate errors when “dialing in” a dimension, as you are
starting from zero each time, rather than adding one number to
another to come up with the next stopping point.
* Standard dimensions listed. Optional longer tables and taller
columns with extra travel are available.
** All overall dimensions include motor and speed control.