After disposing of several other tasks I returned to the construction of the 40 meter reversible Moxon. The plan is for a more efficient and versatile replacement for the XM240. In an earlier article I described the computer model using EZNEC with the NEC5 engine. This is an antenna that requires NEC5 for acceptable accuracy.
After an unexpected spring snowstorm and other matters, spring is finally asserting itself and I can comfortably resume work on the antenna. There is an urgency since the hay will get tall in mid-May and more distractions are imminent. I hope to have it working and on the tower by then.
It's a large antenna but not so large as some others that I've built and raised onto the towers. The boom is reasonably short (typical of a Moxon) yet the elements are long and there are large capacitance hats. Due to the constraint of symmetry necessary to make it reversible, the elements are identical and that reduces the design challenge. My experience building most of my yagis allowed me to proceed with confidence with respect to material selection and the joining of tubes, plates and pipes.
This article is about how I mechanically designed and built the antennas. A future article will cover its electrical design, testing and performance. I prefer to split the discussion rather than wait to the end and write one very long article. Impatient readers can read previous articles about the electrical design and modelling with NEC5, and how I am approaching the feed system.
One note before I start is that this is not an XM240 conversion per the W6NL design. I am holding on to that antenna for another use. However, my mechanical design is similar to the conversion project with its relatively light duty elements. My XM240 was improved in line with the conversion specs by its previous owner.
I did not want to make it too heavy (over 100 lb) by specifying stronger elements such as those on my 3-element 40 meter yagi. The elements are therefore trussed, like the XM240 conversion, and other measures were taken to limit element flexing. The antenna will be low enough for service, if necessary, although I of course hope to avoid it. You can judge for yourself how well I've done from the description in this article.
Boom
The choice was easy. I had a 20' length of 2.375" OD schedule 80 6061-T6 aluminum pipe in my stock (0.218" wall thickness), which was perfect for this antenna. I bought it as used/surplus several years ago with the intent of using it as a mast, and then never did. With it, I can forgo a boom truss since boom droop is quite small. Its hefty 35 lb weight is an acceptable trade off.
This may not be a solution for most antenna builders since these pipes are expensive when new. A lighter duty boom with a truss may be more economical. Just don't get so economical that it is under-built for wind and ice loads. The load on the boom due to those long, end-loaded elements, is substantially more than for the XM240 or similar 40 meter yagis.
The distance between the element centres is about 225" (18.5' or 5.7 m). that leaves room outboard of the boom-to-element clamps for the clamps that support the 5' element truss posts.
Clamps
The boom-to-mast clamp is not easily seen in the picture above. A close up isn't necessary since it is nothing out of the ordinary. Again, I dug into my junk box and found a suitable plate clamp. Galvanized saddle clamps on a ¼" aluminum alloy plate fit the 2-⅜" boom and 1.9" pipe mast. It goes right at boom centre since, due to antenna symmetry, that coincides with the centre-of-gravity. The mast size is pre-determined by the Hy-Gain rotator used in the rotatable side mount where the XM240 currently resides.
The boom-to-element clamps are more elaborate. When I first designed the elements the halves were entirely supported by the clamp. The large bending moment puts a lot of stress on the polymer insulators (the element must be electrically isolated from the boom) and the clamp plate.
The polymer tubes were scavenged from an ancient 40 meter coil-loaded yagi that a friend gave me. The plates are 18" × 6" × ¼" aluminum alloy bars. Aluminum alloy strips protect the polymer from the stress points due to the saddles and u-bolts.
The galvanized angles take a lot of the stress but not enough of it. I built ¼" steel backing plates to make up the strength deficit. It worked but I was not satisfied by the complexity and weight of the completed clamps.
I purchased 2' lengths of 1" fibreglass rods from an antenna builder and fit them inside the inner pipes of the element halves. Aluminum flashing was used as a shim since the ID of the pipes is 1.049" -- I wanted a close fit so that more of the rod contacted the pipe to reduce point stresses. The rods are very strong and can support the element on their own. Fibreglass tube is lighter and cheaper and may have sufficed but this joint is critical. The steel backing plates were no longer needed.
The rods are held in place solely by the hose clamps at the slit ends of the pipes. If there is any "creep" I may need to drive screws through the pipe and into the rod. I prefer not to do that so we'll see how it fares. The inner hose clamps also hold the tabs from the switch boxes.
Elements
I made a deliberate decision to reduce the cost and weight of the elements by making them similar to what is found in XM240 conversions to W6NL Moxon antennas. It helped that I had almost all of the required aluminum on hand.
The capacitance hats, although not heavy, present cumbersome and complex loads since they are placed at the element tips. Heavier element construction might be sufficient to deal with those loads, but at a "heavy" cost. Thus, a truss is the preferred solution.
The details of element construction are as follows:
- 1.315" (0.133" wall) 6061-T6 pipe: 72". There is a 1" gap between the element halves, plus inductance due to the ~2" (5 cm) of conductors into the switch box and up to and through the relays.
- 1" (0.120" or 0.130" wall) 6061-T6 tube: 115".
- ¾" (0.058" wall) 6061-T6 tube: 48.5", with a ⅝" (0.058" wall) 6063-T832 tube inside
- The same ⅝" tube projects 19" beyond the ¾" tube to form the element tip.
- 4" × 3" × ¼" 6061-T6511 plate with stainless u-bolt to attach the capacitance hats to the end of the ¾" tube.
- ⅞" (0.058" wall) 6061-T6 tube: 7" (half of capacitance hat centre tube).
- ¾" (0.058" wall) 6061-T6 tube: 20.5". A single length runs through the centre tube and also forms the second tube section for the other half of the capacitance hat.
- ⅝" (0.058" wall) 6063-T832 tube: 33" (capacitance hat).
- ½" (0.065" wall) 6061-T6 tube: 46.25" (capacitance hat tip)
Most of the joints are fixed with screw fasteners in a manner I've used for other yagis. That leaves few places to adjust the yagi should it not exactly match the NEC5 model. The only adjustable tubes are the tips of the capacitance hats and the element tip. The latter can only be lengthened. Since the distance between capacitance hat tips should not vary far from its design value, one option is to only adjust the outside arms of the hats. This must be done on all 4 to preserve symmetry. For small adjustments the mechanical imbalance won't be an issue.
The element tips can be lengthened by insertion of a ½" tube fastened with a hose clamp. Since I don't expect to use this method (it is more likely the elements will need to shortened slightly) I have not cut slits in the tips. That can be done in the field if necessary. I'll know more after the antenna is in the air and its electrical behaviour is measured.
The capacitance hats could have been made by stepping down the tubing schedule by ⅛", similar to that for the typical 40 meter Moxon. I opted for a stronger design because of the antenna's symmetry and for stable element coupling, the latter of which has a strong impact on antenna performance.
In the W6NL Moxon, which is unidirectional, the capacitance hats are laterally offset. The coupling between driven element and reflector is therefore less than in a Moxon rectangle, and the tips are less likely to touch. This appears to be a reasonable trade off between off performance and reliability. However, I have never seen this stated so it may not have been one of his design criteria.
The capacitance hat tips in my antenna are aligned and 30 cm (12") apart. It is far easier for the tips to touch. That could cause havoc in the shack when amplifiers fault and go offline or (worst case) cause a hardware failure. There are two approaches to prevent this from happening: insulation barriers to reduce or eliminate metal-on-metal contact, or fix the relative positions of the capacitance hat tips. I chose the latter option, which is described below.
Element truss
My first design didn't work. I used a long ⅜" threaded rod to "reach" over element centre to adjust for the post's boom clamp that positions it about 5" to 6" towards the end of the boom. I went further and removed the saddles from the clamps so that the post would lean inward. The reason this failed to work as intended was that the tension on the truss rope was greater than I expected.
Although the element halves are not heavy, the geometry is not in my favour. The truss attachment to the post is ~4' above the element and it attaches to the element at the end of the 1" tube, which is 18' from the boom. The angle between the truss rope and the element is therefore only 13°. It doesn't look that acute when I stand next to it but it is.
The tension to lift the element is on the order of several tens of pounds. There was too much inward bending stress on the post. I had intended to use a non-tempered aluminum tube for the post. Instead I went with a 1.315" pipe. I'm glad I did. I am surprised that the W6NL XM240 conversion specifies a 3' tall PVC pipe, yet I know that many of those antennas are working perfectly well.
I replaced the saddles and attached the truss ropes closer to the post. That worked. Only a small adjustment was required to keep the element straight when the truss rope tension is high enough to level the element. Shorter ⅜" bolts serve to properly align the post and element. Each bolt is covered with a ½" scrap aluminum tube to protect the rope from the sharp threads.
Rather than turnbuckles, the tension is manually adjusted and the rope secured by a simple cleat made from long #10 screws. The rope can be taped to the post to prevent unravelling. The nylon rope used during setup (seen in the photo) was replaced by low stretch, UV-resistant Dacron. The improvised cleat is on both sides of the post to allow each rope to be independently adjusted.
I tested the truss as well as I could by simulating wind and ice load by bending them in various direction by hand and to simulate oscillation in the wind. The antenna performed well with no sign that the element was prone to buckling or other weakness. However I can't be certain without a full mechanical analysis which will not be done. That's beyond my expertise.
An alternative truss whereby lateral flexing of the elements can be largely eliminated is with
a cross bar on the post and attaching ropes to each end of the cross
bar. The weight and wind load penalty is small. Although that will not
reduce flexing of the element tips and capacitance hats, their flexing will
be less prone to amplification by in phase element oscillations.
We'll see how the built truss fares after it is installed. I was also pleased to observe that the capacitance hats resisted moving inward under simulated lateral (wind) load. That won't prevent the tips from touching but it reduces the difficulty to mitigate that problem, as described in the next section.
Capacitance hat tip management
The capacitance hats are collinear, unlike in the W6NL Moxon. That makes them far more prone to touching as they bounce in the wind. Even if they don't touch, the tip spacing has a significant impact on performance since the "critical coupling" that makes a Moxon work depends on that spacing. I considered and rejected a few alternatives:
- Double truss the elements to reduce lateral motion
- Several narrow ring insulators on each inside tip so that when they try to occupy the same space the insulators strike the aluminum and prevent metal-on-metal contact
- Side trusses on the elements using boom extensions as truss posts and a rope between the capacitance hat tips -- the tensioned structure is rigid in the horizontal plane
My preferred solution is simple and should be effective. It works well when the antenna is agitated during testing at ground level. A fibreglass rod connects the capacitance hat tips.
The ½" aluminum tube tips of the hats are slotted for compression with hose clamps. The fibreglass rods are 4' long driveway marker posts that are common in snowy climates and can be found for a few dollars at any hardware store. I pulled off the top caps and inserted them into the tubes.
Since the rods are about 5/16" (8 mm) diameter, a little smaller than the ID of the tubes I wrapped the rod with a few turns of electrical tape at each end for a tighter fit. The distance between tips is 12" (30 cm) per the EZNEC (NEC5) model. I used the full length of the rods so there are 18" (45 cm) inside each tube, adding to the strength of the tubes.
The distance between the elements is ~18.5' (5.6 m) so there is droop in the capacitance hats and the fibreglass rod bends to fit the curves. Although they may appear flimsy they withstood a lot of abuse when the elements were strongly agitated by hand. The elements moved as a rigid structure.
We'll see how the hat tips fare once the antenna is installed on the tower. If there is a failure I can always fall back to one of the alternatives listed earlier. But for now I like it: cheap, simple and effective.
Weight and wind load
The antenna is almost ready for its first live test. It'll be trammed to a low height on the 15/20 meter tower where antenna interactions will be minimal. It was assembled at the approximate launch point in the hay field between the big towers since it is an awkward antenna to move once assembled.
Although most hams would classify it as a large antenna, it is a middling large antenna for my station. When assembled it is quite heavy, approximately 105 lb (50 kg). That's at least 15 lb more than I estimated before construction. The element clamps and truss posts are two of the culprits. The weight was measured with a method I've used before: weigh myself and then again holding the antenna. I had to hold the antenna steady for the 10 seconds until it stopped wobbling and the scale reading was stable.
I'll probably use a vehicle to tram the antenna onto the tower. There will be less grumbling from my friends! We're all getting older and it takes a lot of muscle to pull an antenna this size up the tram line.
One detail I'll have to deal with is that the antenna can't get past the tower because the capacitance hat tips are connected. The forward fibreglass spacer will have to be removed and reinstalled after the hats advance to the far side of the tower. Good communication with the ground crew is critical.
The wind load is less that what you might expect for an antenna of this size. The reason is that there are only two elements and the boom is not very long.
The wind surface area (cylindrical) is simple to calculate from the tube and pipe dimensions:
- Boom: 4.0 ft²
- Each element (not including the capacitance hat): 3.4 ft²
- Each capacitance hat: 0.7 ft²
- Element truss: 0.5 ft²
The total is 4 + 6.8 + 2.8 + 1 = 14.6 ft². The wind load experienced is never that high because all components of the antenna are not parallel. The expected wind load would exceed 7.8 ft² by a small amount, which is that of the two elements or, coincidentally, the boom and capacitance hats. Due to droop, there is some wind load due to their vertically projected area. The element trusses always face the wind and their area is included for all wind directions.
Since the elements are long and will oscillate in high winds, the spikes in the dynamic load suggest that the load is greatest when the antenna is pointed toward or away from the wind direction. You don't want so much tension on the truss that the element is at risk of buckling when it bends due to wind and/or ice load.
To reduce the risk, the post height can be increased and the element attachment point moved inward. I anchored the rope at the end of the 1" (~0.125" wall), not at the capacitance hat clamp as in the W6NL XM240 conversion design. The element is still strong at that point and the truss rope angle is higher than it would be when anchored at the capacitance hat
The wind load is not really within the capacity of the Ham-M rotator that is used on the tower side mount where the XM240 is currently mounted. I don't anticipate serious problems unless we get a severe wind storm. I'd likely have the same risk with the XM240 since its wind loading is only a little less, the main differences being the capacitance hats and element trusses on the Moxon.
There it is, ready for liftoff. First I need to complete the feed system so that it can be tested. I'll discuss that after the antenna is raised and tested since that's more associated with tuning, not the mechanical construction.
My hope is to complete this project by mid-May before the hay gets too high for comfortable ground work.
