Orion SKYVIEW PRO 120 EQ User Manual

2. Loosen the Dec. lock lever and rotate the optical tube on

the declination axis so that the tube is at a 90° to the right
ascension axis (Figure 10). This is so you can view through
the mount with the polar axis finder. Tighten the Dec. lock
lever.

3. Remove the cap on the front of the equatorial mount

(Figure 6). Focus the polar finder by rotating the eyepiece.
Now, sight Polaris in the polar axis finder scope. If you
have followed the approximate polar alignment procedure
accurately, Polaris will probably be within the field of view.
If not, move the tripod left-to-right, and adjust the latitude
up-and down until Polaris is somewhere within the field of
view of the polar axis finder scope.

4. Shine a red flashlight down the front end of the polar finder

to illuminate the reticle within the field of view. Make sure
the flashlight shines in at an angle, so as not to block the
polar finder’s field of view. It may be helpful to have a friend
hold the flashlight while you look through the polar finder.
Note the constellation Cassiopeia and the Big Dipper in
the reticle. They do not appear in scale, but they indicate
the general positions of Cassiopeia and the Big Dipper
relative to the north celestial pole (which is indicated by
the cross at the center of the reticle). Rotate the reticle so
the constellations depicted match their current orientation
in they sky when viewed with the naked eye. To do this,
release the R.A. lock lever and rotate the main telescope
around the R.A. axis until the reticle is oriented with sky.
For larger optical tubes, you may need to remove the tube
from the mount to prevent it from bumping into the mount.
Once the reticle is correctly oriented, use the right ascen-
sion lock lever to secure the mount’s position.

Now use the azimuth adjustment knobs (Figure 8) and the
latitude adjustment L-bolts (Figure 6) on the mount to position
the star Polaris inside the tiny circle marked “Polaris” on the
finder’s reticle. You must first loosen the knob underneath the
equatorial mount on the center support shaft to use the azi-
muth adjustment knobs. Once Polaris is properly positioned
within the reticle, you are precisely polar aligned. Retighten
the knob underneath the equatorial mount
Note: From this point on in your observing session, you
should not make any further adjustments in the azimuth
or the latitude of the mount, nor should you move the
tripod. Doing so will undo the polar alignment. The tele-
scope should be moved only about its right ascension
and declination axes.

additional note regarding Focusing the Polar

axis Finder scope
The polar axis finder scope is normally focused by simply
rotating the eyepiece focus ring. However, if after adjusting the
focus ring you find that the image of the reticle is sharp, but
the stars are out of focus, then you must adjust the focus of
the polar axis finder’s objective lens. To do this, first remove
the polar axis finder from the mount. Look through the polar
axis finder at a star (at night) or distant object at least 1/4 mile
away (during daylight). Use the eyepiece focus ring to bring
the reticle into sharp focus. Now, loosen the focus lock ring

(Figure 9a) and thread the entire objective end of the finder
inwards or outwards until images appear sharp. Re-tighten the
focus lock ring. Once the polar axis finder’s objective lens is
focused, it should not need to be adjusted again.

use of the right ascension and Declination slow‑

Motion control Knobs
The right ascension (R.A.) and declination (Dec.) slow-motion
control knobs allow fine adjustment of the telescope’s position
to center objects within the field of view. Before you can use
the knobs, you must manually “slew” the mount to point the
telescope in the vicinity of the desired target. Do this by loos-
ening the R.A. and Dec. lock levers and moving the telescope
about the mount’s right ascension and declination axes. Once
the telescope is pointed close to the object to be viewed,
retighten both lock levers.
Note: If you have an optional motor drive attached, you
will need to loosen the manual clutch on the R.A. (and
Dec. for dual-axis drives) worm gear shaft before using
the slow-motion control knob.

The object should now be visible somewhere in the telescope’s
finder scope. If it isn’t, use the slow-motion knobs to scan the
surrounding area of sky. When the object is visible in the finder
scope, use the slow-motion knobs to center it. Now, look in the
telescope’s eyepiece. If the finder scope is properly aligned,
the object should be visible somewhere in the field of view.
Once the object is visible in the eyepiece, use the slow-motion
knobs to center it in the field of view.

tracking celestial objects
When you observe a celestial object through the telescope,
you’ll see it drift slowly across the field of view. To keep it in
the field, if your equatorial mount is polar aligned, just turn
the R.A. slow-motion control knob clockwise. The Dec. slow-
motion control knob is not needed for tracking. Objects will
appear to move faster at higher magnifications, because the
field of view is narrower.

optional Motor Drives for automatic tracking
An optional DC motor drive can be mounted on the R.A.
axis of the equatorial mount to provide hands-free tracking.
Objects will then remain stationary in the field of view with-
out any manual adjustment of the right ascension slow-motion
control knob.

understanding the setting circles
The setting circles on an equatorial mount enable you to
locate celestial objects by their “celestial coordinates”. Every
object resides in a specific location on the “celestial sphere”.
That location is denoted by two numbers: its right ascension
(R.A.) and declination (Dec.). In the same way, every loca-
tion on Earth can be described by its longitude and latitude.
Right ascension is similar to longitude on Earth, and declina-
tion is similar to latitude. The R.A. and Dec. values for celestial
objects can be found in any star atlas or star catalog.
The R.A. setting circle is scaled in hours, from 1 through 24,
with small marks in between representing 10-minute incre-

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