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6m /
50MHz J-Pole Antenna
( THE
EXTRA TERMS 6M / 6 METERS / SIX METERS / SIX METERS WERE ADDED TO HELP
GOOGLE... )
or
a 50 MHz / 6 metre Yagi
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Need a general
purpose antenna on ‘ 6 metres - the magic band ' ? The J-Pole is an
easy-to-build and inexpensive device that provides an omni-directional
vertically polarised antenna without the need for a ground plane. In
technical terms, it is an end fed vertical 1/2 wave which is fed via
a 1/4 wave matching stub.
I take no credit
for the design values for this project - only the easy construction
technique. If you need more info or dimensions for other frequencies,
check out the web pages for articles by Buck Rogers K4ABT at http://www.packetradio.com
and other authors. In particular for J Pole design info, look at http://www.packetradio.com/jpol.htm
and http://www.vk1.wia.ampr.org/bulletins/jpole.html
UPDATE
: 2nd January 2005 : Feedback from Doug Adair N8WWM [ 50MHz VUCC #1373
] with alternative spacer arrangements.
His email plus pictures are at the bottom of the original page - here.
Construction
time : About 1-2 hours
Costs : about
$AUD25 to $AUD50 – cost breakdown below is for the material actually
used – longer tubing lengths may be required that inflate the apparent
cost. Costs listed below relate to costs of the materials at the time
this antenna was constructed and do not necessarily reflect the current
price of materials.
Materials :
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1 x 6.1
metre length 19mmx1.5mm round aluminium tubing ($12.75)
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1 x 1000mm
length 16mmx1.2mm round aluminium tubing ($1.50)
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1 x 200mm
length 38x25mm rectangular aluminium tube (x 1.0mm wall) ($1.80)
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4 x 12-23mm
stainless steel worm-style hose clamps ($1.50 each)
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2 x 16mm
(tubing size) plastic chair tips ($0.70 each)
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16 x aluminium
pop rivets
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50 ohm
coax cable, eg RG58A/U, minimum length 3-4 metres
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| 200mm
x 32mm white outdoor conduit |
| Nylon
cable ties etc... |
Calculated
dimensions – 50.1 MHz
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Long section
:
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4290 mm
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Short section
:
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1423 mm
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Feed point
spacing :
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140mm (external
coax 'Y' style) **
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Element
spacing -metal tube outer to outer at closest dimension :
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135mm
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** This dimension
is based on the original 'Y' external feed. Using a modified feed system,
this distance is about 180 -210mm. Details of the modified feed are
listed near the end of this page.
Construction
:
Creating the
shorting stub – this is the hardest part of the entire construction
:
The critical
dimension is the 135mm spacing between the elements but this dimension
is not the centre-to-centre value – it is the spacing from tube outer
to tube outer. With 19mm diameter tube, adding 19mm gives the centre-to-centres
of the holes as 154mm. Therefore the outside to outside is 173mm so
it does not leave much from our 200mm material.
- Measure in
23mm from one end along the 25mm side section and then drill a pilot
hole as a guide for a larger drill.
- Making sure
it is square, mark the hole position on the 25mm section opposite
face and drill it.
- Enlarge the
hole to 19-20mm. I cheated here – I used a ¾" chassis punch from
each side to get a neat hole with about 0.5mm of play.
- From the inner
edge of the hole, measure and mark the position 145mm along the tube
on one face and then repeat the process for the opposite face.
- Drill these
pilot holes and enlarge them to 19-20mm.
- Not really
hard unless you don’t have a suitable drill press with a ¾" drill
or chassis punches to get the neat 19-20mm holes !
The separator
: To provide mechanical rigidity, an insulating separator must be fitted
near the top of the matching section joining both tubes. It is similar
in dimension and technique to the shorting stub but is made out of PVC
electrical conduit rather than aluminium.
Use the same
dimensions as in the construction of the shorting stub for the spacing
of the hole centres and drill 19-20mm holes through the conduit (the
chassis punch works well on the PVC tube too). Make sure that the alignment
of the holes is correct otherwise the aluminium tubes will not fit through.
The separator is held in place by nylon ties fed around the vertical
aluminium tubes but placed within the end of the conduit and later tightened
so as to not allow any slippage down the aluminium tubing - and without
requiring additional holes.
The round tubing
now needs to be cut to length and prepared for fixing :
- From the 6.1
metre tube length, cut off 1300mm - leaving a 4.8 metre section for
the main vertical radiator and mounting.
- Cut a contraction
slot in one end of each tube (4.8m & 1.3m) section for about 50mm.
- Mark 4000mm
from the slotted end of the main radiator. This is the position for
the main shorting stub.
Assembly into
the finished product :
 
- Slide the
shorting stub along the main radiator tube until the upper edge lines
up with the 4000mm mark (the stub will be on the shorter length side
of the mark).
- Making sure
that the tubing is square to the cross stub, drill clearance holes
in the 38mm section sides for the pop rivets you are using and set
the rivets. I recommend drilling one hole and installing the rivet
before drilling the next hole etc.. Rivet both sides of the bottom
stub tube to the main radiator tubing. This will pull in the 25mm
dimension of the tube a little but that is the reason why it is so
close to the end of the rectangular tube !
- Install the
unslotted end of the matching tube – the shorter length of 19mm section
into the shorting stub with about 3-5mm protruding through the bottom.
- Making sure
that this tubing is also square to the cross stub, drill clearance
holes for the pop rivets you are using and set the rivets. As before,
I recommend drilling one hole and installing the rivet before drilling
the next hole etc.. Rivet both sides of the bottom stub tube to the
matching section tubing.
- Slide a worm
clamp down each 19mm tube down to the matching stub.
- Form a loop
from a single nylon tie making sure it will fit over the 19mm tube
(make 2 of these.)
- Fit a looped
tie into one end of the separator and carefully feed onto the main
radiator tube
- Slide the
separator down over the long tube first then over the matching tube
so that it is just above the slotted top of the matching tube. Install
the second looped nylon tie into the other end of the separator tube
and feed it down over the aluminium matching tube until it is just
below the slotted section. Pull each tie tight so that it will not
slip on the aluminium tubing. Multiple ties can be fitted if desired.
- Slide a second
worm clamp over the slotted section on each 19mm tube and insert the
16mm tube and adjust the worm to just hold the clamp in position.
- Measure the
main radiator tube from the top of the shorting stub and set the adjuster
to 4290mm before tightening the worm again to just hold the tube in
position. Do not overtighten at this stage.
- Measure the
matching stub tube from the top of the shorting stub and set the adjuster
to 1423mm before tightening the worm again to just hold this tube
in position. Do not overtighten at this stage.
- From the shorting
stub, mark a position 140mm up each 19mm tube. This is the position
to attach the coax cable. Note that the coax inner goes to the main
radiator while the outer goes to the matching stub tube.
- Slide the
worm clamps up to these marks and lightly tighten in position.
Final steps :
Cable connection and adjustment - standard 'Y' cable feed.
- Create an
RF choke by winding 5 turns of the RG58 cable around a 125mm former
and nylon tie it into a stable structure. Leave at least 400mm of
cable free from the feed end. The other end (the tail) can either
be terminated in a BNC or other coax connector to suit the cable type
or can simply be the start of the feeder that takes it to the radio.
- Strip back
100 - 125mm of the outer on the feed end.
- Push the braid
back a bit to loosen it up, then poke a ‘hole’ in the braid and ‘fish
out’ the coax inner.
- Strip the
inner back to about 75mm of exposed poly and the rest the inner conductor.
- Tin the inner
conductor and then screw it under the worm clamp on the main radiator.
- Feed the braid
under the worm clamp on the matching section and pull it until there
is just a little slack in the cable. Cut it off, remove it and tin
the braid before placing it back under the worm clamp.
- Mount the
antenna vertically in a clear space in such a manner that it can easily
be brought down to adjust at each of the following stages :
- Connect a
suitable transmitter via a SWR bridge to the coax ‘tail’ and check
the VSWR at say 50.160 Mhz. Do not use 50.110
MHz as a test frequency !
- Check the
VSWR at various spot frequencies in that segment. If the VSWR goes
up as the frequency rises, the tube lengths are too long and need
to be shortened. If the VSWR goes down as the frequency rises, the
tube lengths are too short and need to be lengthened. Lengthen both
together but make sure that the main radiator adjustments are about
triple the matching section’s length changes.
- Once the
VSWR is minimum at the centre of the desired section of the band,
it is time to adjust the feed point positions on both tubes to bring
the VSWR down to the absolute minimum. Slide the clamps up or down
the tubes TOGETHER and see where the trend goes.
- If the VSWR
rises, move in the opposite direction. It should be possible to get
the SWR down to 1.05 or better without any problem.
Final steps :
Cable connection and adjustment - modified cable feed.
- Drill a 5/16"
hole about 200mm from the top of the shorting stub along the inner
side of the matching tube(facing the main radiator tube) and remove
any burrs.
- Feed the RG58
up the short tube and pull it out of the hole.
- Strip back
the cable outer sheath for about 200mm.
- Push the braid
back a bit to loosen it up, then poke a ‘hole’ in the braid and ‘fish
out’ the coax inner right at the start of the exposed braid.
- Cut the braid
off with about 25-30mm left and tin it with a soldering iron making
sure you do not overheat the poly inner of the RG58.
- Slide the
cable back through the hole and set the worm clamp to hold the braid
on the tube adjacent to the feed hole.
- Feed the coax
inner across towards the main radiator element making sure you have
about 20mm of slack on the poly and enough inner to tin about 30mm
before cutting it off.
- Feed a length
of the black plastic coax sheath back over the inner to provide some
protection against UV.
- Clamp the
inner to the main feed directly opposite the feed hole as an initial
location.
- Create an
RF choke in the coax by winding 5 turns of the RG58 cable after it
exits the tube around a 125mm former and nylon tie it into a stable
structure and nylon tie it to the base of the matching section. The
tail can either be terminated in a BNC or other coax connector to
suit the cable type or can simply be the start of the feeder that
takes it to the radio.
- Mount the
antenna vertically in a clear space in such a manner that it can easily
be brought down to adjust at each of the following stages :
- Connect a
suitable transmitter via a SWR bridge to the coax ‘tail’ and check
the VSWR at say 50.160 Mhz. Do not use 50.110
MHz as a test frequency !
- Check the
VSWR at various spot frequencies in that segment. If the VSWR goes
up as the frequency rises, the tube lengths are too long and need
to be shortened. If the VSWR goes down as the frequency rises, the
tube lengths are too short and need to be lengthened. Lengthen both
together but make sure that the main radiator adjustments are about
triple the matching section’s length changes.
- Once the
VSWR is minimum at the centre of the desired section of the band,
it is time to adjust the feed point positions on the radiator tube
to bring the VSWR down to the absolute minimum. Slide the clamp up
or down the tube and see where the trend goes.
- If the VSWR
rises, move in the opposite direction. It should be possible to get
the SWR down to 1.05 or better without any problem.
When all is done,
the centre frequency is as desired and VSWR is negligible, it is time
to put the plastic chair tips on the tops of the tubes, tighten the
worm clamps and weatherproof as desired. Don't forget to weatherproof
the slotted adjustments and their worm clamps with a marine varnish
to prevent excessive oxidisation. If using the modified feed, remember
to seal up the hole where the coax feed exits across to the main radiator
with a good silicone sealant.
 
Final dimensions
– 50.1 MHz
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Long section
:
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4425 mm
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Short section
:
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1513 mm
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Feed point
spacing :
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160mm
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Element
spacing :
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135mm
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How
it went together here at VK4ADC ?
I can only say
‘like a dream’. I built it without needing a 'you-beaut' workshop. The
tubes were cut and slotted out in the back yard just using a portable
workbench. The matching section was drilled with a cordless drill and
then punched out to size – again in the back yard. The assembly – yes,
the back yard - again !
The 'Y' feed
results : -
The initial VSWR
at 50.100 (the design frequency) was 1.2:1 and reduced as frequency
was increased. Fine, the elements obviously needed to be lengthened.
Stepped the inner adjuster tubes out a bit and measured again – yes,
the frequency was coming down as the VSWR had reduced to 1.15 at 50.1
and was even lower at 50.2 MHz. Extended the tubes a couple more times
at about 8mm a time and the VSWR was then about 1.1:1 at 50.1 and flat
across 50.0 to 50.2 – now it was time to adjust the feed connection
positions. Adjusted it up about 10mm along each vertical element and
the VSWR dropped to 1.02:1 – close enough !
The modified
feed results :-
Again, the initial
VSWR was about 1.2:1 and the array was obviously high in frequency.
Extending the adjuster tubes brought the SWR down and the final SWR
was achieved by moving the worm clamp on the coax inner up and down
slightly to provide the best overall match. Again the SWR of 1.02 to
1.05 over the 50.0 to 50.2 was achieved. The lengths were different
to the 'Y' feed but the feeder was a far better version mechanically.
Certainly it is the style I recommend for general construction.
Mounting
As per the suggestion
by Buck Rogers, I just purchased a 1.2m TV-style galvanised steel fascia
mount and a couple of 50mm coach bolts plus 3 x 50mm stainless steel
worm clamps to mount it. JUST MAKE SURE THAT THE "J" SECTION
IS CLEAR ABOVE ANY SUPPORTING PIPE SEGMENT FOR BEST OPERATION.
I wasn't looking
for great height so it was simply a matter of attaching the fascia mount
to the exposed fascia under the guttering with the coach bolts and aligning
it so it was vertical.
I do recommend
using a suitable size hex socket on the end of a cordless drill to tighten
up the worm clamps rather than a screwdriver. Make sure you have the
drill set to ratchet otherwise you will strip the worm. Nominally tighten
them, check the antenna alignment is vertical and then tighten completely.
A couple of nylon
ties hold the coax back to the vertical pipe before it feeds away to
the shack.
Overall
How well it
works in practice will need to be seen over a period of time. It’s main
use here at VK4ADC is to feed to a modified 27MHz CB as a monitoring
receiver for the 50.110 calling frequency. If I need to hit the CB’s
transmit button, I will know that it will be a perfect match to the
transmitter right across that (VK4) segment from 50.0 to 50.3 MHz !
Doug Hunter
VK4ADC
18/19 August
2001
Date: Sun, 2 Jan 2005 00:33:00
GMT
To: vk4adc@ozhelpservices.com
Hello Doug,
I was looking
at your great ideas for yagis and jpoles on 6 meters and thought I would
pass my own idea along. I have built 14 6 meter jpoles using this variation
of your idea for the feed system plastic spacers.
I used the plastic
tubing for spacers, as you did, but with one hole in the middle of the
spacer, used two plastic ties to anchor the spacer in a sandwich between
the feeder sections. Using a product we have in the states called plumber's
goop to literally meld with the plastic and make a wrap around fit.
2 benefits I
have discovered in this method: Extremely strong bond at the spacers,
and the fact that one does not have to line up 2 holes accurately when
cutting and fitting them to the antenna. I am always looking for methods
that make it easier for laymen to make antennas. Curse those expensive
commercial antennas!
Along with the antenna picture there are a few more that are more personal.
Myself, XYL, and simple but effective shack included.
73 and good DX
on 6!
Doug Adair N8WWM
50MHz VUCC #1373
{
Editing note : I have found that even the black nylon ties weaken after
a few years in severe UV environments (like here in VK). The glue here
is what is used here to bond the spacer to the tubing and the ties just
hold it in position until the glue has set. Do NOT just use nylon ties
- a longlife glue is an absolute necessity. The original conduit tube
with parallel holes method obviates this but is just a little harder
to achieve those parallel holes - but then again the electrical conduit
is cheap, lasts a lot longer and with greater strength. If you are going
to build a number of these, build a simple jig or use a drill press
with a sliding bed. }
Click
on the spacer image
or the the station
image for larger views.
Close-up of
the alternative spacer |
Overview
of the alternative spacer arrangement from N8WWM
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Station de N8WWM |
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Doug N8WWM
Obviously
a keen 6 metre operator and homebrewer of these antennas...
(and
obviously staring at a webcam !)
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Thanks
for the feedback Doug. Anyone else have alternative construction methods
or suggestions ???
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