Omegon 2" Crayford: this eyepiece holder is pure sharpness Is the focuser not working correctly to take astrophotos or observe at high magnifications? The Omegon Crayford eyepiece ensures you have the precision you need to adjust sharpness. With its smooth adjustment, ball bearing and reducer you will find the right focus effortlessly.
And all so that in the future you can concentrate on what really matters: viewing pleasure.
Summary of advantages:
Crayford eyepiece holder with guide rail for maximum stability
Smooth, accurate movement for precision focusing during observing or astrophotography sessions
1:10 reducer to find focus with tenths of accuracy
2.5 kg load capacity for cameras with accessories or heavy 2" eyepieces
High quality thanks to thick anodized aluminum housing
Crayford and guide rail combination: double mechanics The Crayford bearing combines two techniques for the holder to operate with maximum accuracy: a large ball bearing and a stainless steel guide rail. The eyepiece holder adjusts very flexibly and smoothly and retains its position even under heavy load. This is a very robust astrophotography accessory.
1:10 mechanism for 10 times more precise focusing Adjust the sharpness to observe stars, planets, and diffuse nebulae. What is simple in visual observation is a complicated task in astrophotography. But with this holder you can solve it without complications. Use the 1:10 reducer along with the normal focusing wheel to adapt the tube with 10 times greater precision than with a conventional holder.
2 or 1.25" accessories - everything you need The 2" Crayford holder features a compression ring to attach eyepieces or adapters. It ensures a strong grip without damaging accessories. A 2" to 1.25" reducer allows you to install any 1.25" eyepiece to which you can also screw 2" filters
Load capacity up to 2.5 kg Mount your photography equipment with complete confidence, even if it's large full-frame cameras, because it supports up to 2.5kg without bending. This way you will be assured of exact focus centered on the optical axis.