My amateur telescope making page

The 20 inch  "Deep Space Scope" Design

Overview

DS-3 and DS-4 have ended up being such a successful telescope design that I have been thinking of creating even a bigger ultralight telescope.  This web page currently holds some of my design requirements, brainstorming ideas and engineering solutions.  I am putting it on the net in order to share my ideas, as well as get some feedback.  My e-mail address can be found in Astronomy, which can be found through the link above.

DS-5 requirements are as follows:

• The heaviest single part of the telescope must weigh under 50 pounds, and be easily moved.
• The scope will be stored in a garage, so it can split into as many parts as needed.
• Small size when stowed is imperitive. The telescope must fit in the trunk of a mid size hatchback.  My target car is a Subaru Impresa, Toyota Prius, Honda Fit, or VW Golf.  I also want space left over for carrying a step stool, my eyepiece box and an observing chair.
  
• I want the largest diameter mirror possible while fulfilling the other requirements.  This is believed to be a 20" f4.0.
• Height at the eyepiece. I want the eyepiece to be viewable by a 6' 0" man standing on a folding two step stool.
  
• Setup time should be under 15 minutes.  Setup of this truss dob should require no tools and include a minimum amount of setup or tear down.  
• Easy to build.  
• As a secondary design goal, this scope should be cool looking!

• Peak Oil.  See my Peak Oil Links page for a description of why gasoline prices are so high, and why they will continue to get higher.
  
• Cost.  Cars are cheaper than trucks and mileage is better.  Just because I can afford a gas guzzler doesn't mean that I should buy a gas guzzler.
  
• Stuff.  If the telescope fits in a car, it forces designs that are simpler.  No big ladder and no big ramps.  By design.
  

• Primary mirror: 20" f4.0, 1.5" thick, enhanced coatings
• Secondary mirror: 3.5", enhanced coatings.
• Secondary diameter percent of primary diameter: 20%
• Weight of heaviest piece (Mirror box with mirror):  unknown.
• Secondary cage weight: unknown
  
• Truss length: unknown
  
• Height of eyepiece: unknown
  
• Finder: Unknown.  Possibly a Telrad or a Rigel Quick Finder
• Focuser: Feather touch 2"
• Packed size: tbd

• Primary diameter: 20", 1.625" thick
• Biggest mirror that doesn't require a big ladder and that I can lift.
  
• Focal ratio: 4.0 
• This is as fast as I think I can go.  Coma will be an issue, so a paracor may need to be used.  Any slower, and my eyepiece requirement is not net.
• Diagonal minor axis: 4.0"  
• Tube inside diameter: 22"
• Tube thickness 0.5"
• This is for half inch plywood.  We may use a plate of aluminum.  Basically, as thin as possible.
• Focuser to front of tube: 3.0"
• Irrelevant.  Used by NEWT.
• Mirror face to back of tube: 3.5"
• Irrelevant.  Used by NEWT.
  
• Focuser height: 2"
• Thickness of the focuser from the base plate to the top of the tube.  This is from a feathertouch focuser.
• Spare focuser in travel: 0.25"
• I think that this is irrelevant.
  
• Focuser inside diameter: 2.0"
• Designed for a 2" eyepiece.  Allows use of better eyepieces with a wider field of view.  Requires better baffling.  Heavier.
  

• Diagonal too small to admit 100% ray?  No.
• Vignetting of 75% ray at front of aperture? Yes. (But not by much).
• Vignetting of focuser at 100% ray?  No.
  
• Vignetting of focuser at 75% ray?  Yes.  (I believe that it says that I need a bigger focuser.  2" is probably big enough.)
  
• Theoretical limiting magnitude: 15.3
• Obstruction of the primary by the secondary by area: 3%
• Obstruction of the primary by the secondary by diameter: 18%
• Theoretical resolution: 0.23 arc seconds.

• Primary diameter diameter: 508 mm
• Primary mirror thickness: 41.3 mm 
• Primary mirror focal length: 2032 mm 
• Secondary mirror diameter:   88.9 mm
• Number of point suspension: 18

• Support ring diameters:
• Inside ring 39.78%
• Outside ring: 80.09%
• Six triangles of 1/2" plywood
• Triangle dimensions: Point one: 0.0", 0.0", Point two: 4.2886", 0.0", Point three 2.3", 3.62" , CG 2.196", 1.206", Radius of CG 6.452" from center of mirror at 0, 60, 120, 180, 240, and 300 degrees.   Triangles oversized by 1/2".
• Three bars of 1/2" plywood
• Bar dimensions: Point one: 0.0", 0.0", Point two: 6.452", 0.0".  CG 3.226", 0.0", Radius of CG 5.587" from center of mirror at 0, 120, and 240 degrees.   Bars oversized by 1/2".
• See details below.

• 1/2" plywood weights about 47 lbs/4X8 apple ply sheet.  Thus, 1.5 lb/sq foot is used for calculations.  Apple ply basically means thin layered plywood, with no voids.
  
• 1/4" plywood weights about 0.75 lb/sq foot.
  

Design methodology

1. Select the mirror.  I am going to go with a 20" f4.0.  This is the largest mirror that I can use, be able to lift and only need a step stool.  It also will fit in a car.  So, DS-5 will be a 20" f4.0 truss based dob telescope.
   

2. Select the building materials. Initial design will use 1/2" and 1/4" apple ply.  This wood was chosen due to weight and ease of use.  
3. Design the mirror cell. The mirror cell will be a modified version of DS-4.  Be sure to read all of my detail on running Graphical Plop here. The mirror cell is currently planned to be the following  
   
1. Mirror.  1.5" thick.
2. Plop inputs: See above.
   
3. Modified 18 point suspension.  
4. The 18 point suspension will be 18 round masonite disks 3" in diameter, with a center hole the size of the bolt head.  There will have another piece of masonite (1") glued on the back, with a hole the diameter of the bolt shaft.  There will be a metal washer below both masonite disks..
5. There will be 6 1/2" plywood triangles.  See attached diagram for sizes.  Note that the actual triangles will be oversized by 3/4" on all three sides.  Pt1:0.0,0.0 Pt2: 5.88,  0.0: Pt3: 2.93, 5.09.  Masonite disks will be attached using a small nut and bolt.
6. There will be 3 bars, one each passing between two  triangles.  Ends of the bar are attached to the plywood trianges with a small nut and bolt.  Middle of the bars have a threaded shaft extending from them. They may also have a 2" 1/2"thick disk glued to them, with a 1" hole drilled 1/2" deep.  This is for 3 springs (we are hiding the springs in these holes);  Center hole to outter holes are 3.25".


Count	Name	Dimensions	Material	Weight ply	Distance from bottom of OTA
18	Mirror cell contacts	3" diameter	1/8" masonite	0.5 lbs
6	Mirror cell triangles		1/2" ply	1.0 lbs
3	Mirror cell bars	2.5"X8.5"	1/2" ply	0.7 lbs
?	Misc hardware		Metal	1.0 lbs
	Total weight			3.2 lbs	1.5




4. Design the mirror box. The mirror box will use 8 trusses.  It will measure 22" X 22" X 5"  I want it to not have any open holes, not including the mirror box bottom.  (The hole in the mirror box top is covered with a piece of Masonite.)  Also, a second mirror bottom will be glued to the bottom, which will have numerous lightening holes drilled in it.  This stiffening plate will be inside the box.
   

Count	Name	Dimensions	Material	Weight ply	Distance from bottom of   and notes	Notes
1	Mirror box bottom	22"x22"	1/2" ply	5.1 lbs		Composite with 1/4" stiffener listed below.  Should this also be composite?
1	Mirror box bottom stiffening	21"X21"	1/4" ply	1.2 lbs		Composite with 1/2" stiffener.  This stiffener has 50% of it's material removed.
2	Mirror box long side	22"x4"	1/2" ply	1.8 lbs		Composite of two pieces of 1/4" ply.  Inside piece 3/4 removed.  Front and back piece.
2	Mirror box short side	21"x4"	1/2" ply	1.8 lbs		Solid.  Side pieces
1	Mirror box top	22"x22"	1/2" ply	1.8 lbs		Composite of two 1/4" ply.  Inside piece 3/4 removed.
4	Corner triangles	3"x3"	1/2" ply	0.4 lbs
	Total weight			12.1 lbs	2.5



5. Total weight of the mirror box
  Pyrex has a density of about 0.081 lbs/cubic inch.  Mass of a disk 1 5/8" thick is 41.35 lbs.  But, we remove about 5 pounds of glass.  Thus,  about 36 pounds.


Name	Weight
Mirror	36 lbs
Mirror cell	3.2 lbs
Mirror box	12.1 lbs
Total weight of heaviest telescope part	49.8 lbs



6. Design the Bearings - rough, for CG calculations. The bearings will consist of a 1/2" arc on the outside, with a 1/4" arc on the inside.The inside arch will be 1/2" larger than the outside arc.  The bearings will taper towards the top.
   

Count	Name	Dimensions	Material	Weight ply	Distance from bottom of OTA
2	Bearings composite 3/4" thick (here for weight)  (Use DS-4 design)	36"x3"	1/2" ply	3.5 lbs
	Total weight			3.5 lbs	8



7. Design the secondary "cage".  The secondary cage will consist of two plywood rings.  They will have an inside diameter of 22", and an outside diameter of 25".  At present, a 4 wire spider will be used.  See DS-3 and DS-4 for details.  Secondary will be an astrosystems design (purchased or made)



Count	Name	Dimensions	Material	Weight ply	Dimensions from bottom of OTA
1	Secondary mirror	3.5"	glass	2.0 lbs
1	Spider stuff	??	aluminum/wood	1.0 lbs
2	Secondary rings	25" od, 22" id ring	1/2" ply	2.4 lbs
1	Secondary focuser board	6" X 6"	1/2" ply	0.4 lbs
	Additional structure - 3	6" X 2"	1/2" ply	0.4 lbs
1	Focuser (Starlight Featherweight)			1.3 lbs
1	Telrad			0.7 lbs
	Total secondary cage - figured, bare			8.2 lbs
	ParaCor			1.0 lbs
	Heaviest eyepiece that I own			1.0 lbs
	Baffle, large			1.0 lbs
	Normal secondary cage weight with eyepiece			11.2 lbs	66+4+3=73



8. Trusses. Trusses for this truss telescope will be eight aluminum poles 1.5" in diameter.  They will be set into holes drilled into the mirror box.  They are then flexed into place. The top end of these trusses will have a hole drilled in them, which will be placed over the exterior portion of the brass threaded rods from section 5 above. Truss lengths should be APPROXIMATELY 80(focal length)-10(mirror radius)-1(height above mirror)-3(focal length into focuser)=66" in length.  



Count	Name	Dimensions	Material	Weight	Dimensions from bottom of OTA
8	Truss poles	1.5" X 66" long	Aluminum	11 lbs	37



9. Bearings.  Bearings will use close to the same design as DS-4. First off, we have to calculate the center of gravity of the system.
   
The formula for center of gravity is as follows: totalWeight * centerOfGravity = weightPartA * distancePartA + weightPartB * distancePartB + ... + weightPartZ * distancePartZ where distancePart* represents the distance in inches from the bottom of the optical tube assembly.



Item	Weight lbs	Distance from bottom of OTA	Moment arm Weight * distance
Mirror	36.0	3	108
Mirror cell	3.2	1.5	4.8
Mirror box	10.6	1.5	15.9
Bearings (guess, used for calculations)	3.5	18	63
Secondary ring, focuser, eyepieces, baffling, etc	10	73	730
Truss tubes	11	37	407
Total	74.3		1329


Center of gravity = totalMomentArm/totalWeight, or 1329/74.3 = 18".  This will be the distance from the bottom of the mirror box to the center of gravity, and the center of the bearings. These bearings will ride up on the box about 4", and will have a radius of 16".


10. Rocker box and ground board.  DS-5 will use the same rocker box design as was used by DS-4.  Additional stiffening will be added to the rocker box along the back edge.  Bottom of OTA will be 2.6"+1"+pad=4" above rocker base plate.
    



Count	Name	Dimensions	Material	Weight
1	Base plate	26" circular	1/2" ply
1	Rocker base plate	23.5"X23.5"	1/2" ply
2	Rocker base stiffener	23.5"X	1/2" ply? composite?
2	Rocker side plate	23.4"X6"	1/2" ply
6	Magic sliders - above and below base plate,, Teflon, bolts
	Total weight