Introduction
It’s almost unreasonable to write about “setting up and aligning” an Alt-Az Mount. The whole point of the Alt-Az mount is simplicity, and their popularity is largely due to the fact that they don’t require any “setting up”. You just put the scope on the mount and look at things.
Nevertheless, there may be some initial problems to solve as you first work out how to mount your particular scope on your particular mount, and it’s also worth understanding how to balance your scope on the mount — and why you should.
Note: this little article is about traditional, completely manual alt-az mounts like the Televue Gibraltar mount shown here. Motorized fork mounts are also alt-az mounts, but they actually do require alignment, and I’m treating them in a separate article.
Mounting the Telescope
Your first challenge is to mount your optical tube securely on the alt-az mount. On mounts designed for, or sold with, specific telescopes, this will usually be easy. If you acquired mount and scope separately, you may have to solve some minor adaptation problems.
Balancing the Mount
Once your telescope is attached to the mount, you should balance it for movement in the up/down direction. This will make it easier to move the telescope to track and find things, and have the scope stay where you put it.
Balancing in a Single Dimension
Why Single-Axis Balancing Can Never be Perfect
The explanation and photos above use an alt-az mount that is typical of most — the tube can be moved forward or backward to achieve balance when the tube is horizontal. However, if you have a large OTA (such as the 105mm refractor in these photos), then with practically every alt-az mount, you will discover that the tube does not act balanced once it is tilted upward to observe objects in the sky. The higher the tube is tilted, the more it will appear imbalanced. Here’s why.
The problem is that most mounts are not built that way. On most mounts, such as the one shown above, the centre of gravity of the OTA is held somewhat above the axis of altitude rotation, as shown in this diagram. (Getting the weight centred is why the U-shaped mount saddle in the photos above hangs below the axis. But it makes assumptions about the size and weight balance of the OTA.)
Even when the tube is perfectly matched to the mount and centred, the accessories you add to the OTA (finder and eyepieces) will usually put the centre of gravity above the axis of rotation.
The tube in this diagram is balanced when horizontal, but as the tube is tilted to point upward, there will be more weight above the axis of altitude rotation than below it, and an imbalance will result.
So what do we do about this?
On most mounts, there are limits to what you can do, but there are some things:
- Find a way to mount your OTA as low as possible in the mount, to minimize the distance between the altitude rotation axis and the centre of gravity of the tube.
- When balancing your OTA in the mount, bias the weight slightly forward — i.e. so that the tube has a very slight tendency to tip forward when horizontal. This will counter the tendency for it to want to tip backward when pointed upward.
- Unfortunately the amount of forward bias you need depends on the altitude at which you will be viewing, so no single adjustment can compensate for all possible viewing targets. However, if you are doing most of your viewing within a small range of altitudes, which is often the case, you can compensate this way.
Use the mount’s friction controls to reduce the tube’s ability to tip when tilted.
Setting the Mount Friction
Now you should tighten the friction clutches that hold the mount in the up/down and left/right directions just enough so you can still move the mount but so that it stays where you put it.
Different mounts do this differently. The up/down and left/right friction controls on this Televue Gibraltar mount are shown here as an example.
Finding Objects
When you are ready to point your telescope at an object, you will appreciate the simplicity of the alt-az mount. You just point it. Grab the telescope itself, or the handle on the mount (if it has one), and gently move the scope left or right, and up or down, until you are pointed at your target. There is nothing to it, and this is the main reason alt-az mounts are popular. Some alt-az mounts have “slow motion” controls to make the last part of the trip more precise (the mount I’ve been using in the photos in this article does not).
The ability to quickly assemble an alt-az mount, quickly put the telescope on it, and quickly point it at something to observe, is why they are so popular as “grab and go” mounts, for having a quick look at the sky with a small, portable telescope.
Tracking Objects
Once you are observing an object, you will notice it gradually drifting out of your field of view. This is apparent motion caused by the rotation of the earth. The higher the magnification you use, the faster your target will drift.
You keep the object in view by gently “nudging” your scope in the necessary directions, either by hand or using the slow motion controls if you have them. Because an alt-az mount does not mimic the way the sky moves you will have to adjust in both directions. For example, if an object in the south is still rising, you will have to adjust slightly right and slightly up to keep it in view, and repeat this adjustment every minute or two.
This constant nudging is why manual Alt-Az mounts are not useable for astrophotography.
I’m new to astronomy and just purchased my first scope, a reflector. I believe the one pictured is a refractor, right? So mine is on a different type mount but nevertheless, when I target an object and let go of the scope to view it, (say the planet Saturn which I viewed last night)the scope gradually moves and I lose the object, even though I’ve hand tightened it about all I can. This makes for a frustrating night of trying to maintain a comfortable view of Saturn.Any idea what may be the problem.
Hi James. Well, something is moving. It could be the scope – if you tightened everything (and you shouldn’t have to “really crank” on stuff), it is possible that it’s a balance issue. Maybe the scope is front-end heavy, or rear-end heavy. Check if it’s possible to slide it forward or backward in the mount, and get it balanced with a typical eyepiece.
However, more likely is that it’s you that’s moving. The earth, that is. You mentioned viewing Saturn, so you were probably using pretty high magnification. At high magnification, with a non-motorized mount, the rotation of the earth will drift your target out of your field of view in about 2 minutes. If that’s what’s happening, you either just need to learn to slowly turn the slow-motion controls to keep the object in the view, or look into getting a motorized mount.
Dear Richard
Can I get your permission to use one of your images in a instructive talk at our local amateur astronomy club in Oslo?
My own mouth are all German equatorial and I just need a picture of a simple mount.
How would a short OTA (like a 4″ Maksutov) affect the altitude balance on the Gibralta mount in your example?
Would the different weights of eyepieces make the off-balance be increased or decreased from a longer OTA?