Flat EH antennas from UA1ACO
Flat EH antennas from UA1ACO
Sait about flat EH antennas. Articles. Descriptions. Design. Experiments. Results of tests.
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On this page I describe and detail the construction of a flat EH antenna for the 1.8 MHz band (160 metres). I also compare Сon-airТ, the flat EH antenna for 160m against the cylindrical EH antenna for this band. A couple of major advantages of constructing a flat EH for the 160m band is its relatively small physical size with no loss of performance relative to a dipole. The construction of the flat EH antenna for Сtop bandТ is exactly the same as for the 2m flat EH antenna apart from the obvious change in physical dimensions.

FLAT EH ANTENNA 1,8 MHz (160 meters)

Kononov Vladimir (Vlad UA1ACO )
St-Petersburg

This antenna fully repeats the philosophy of construction for the flat EH antenna cut for 80m . From a practical point of view, what materials are needed? You will need copper foil approximately 0,5 mm thick by 1500x600 mm in size. Good sources for this material include good hardware shops or shops specialising in roofing materials. From this sheet it is possible to construct the rectangular plates of the flat EH antenna by cutting this sheet into two parts. Thus, we have two pieces of copper plate with a size of 750x600 mm. The next step is to input these dimensions into the eh6.exe program, kindly coded byVK4ANW. Therefore, we need to calculate the surface area of the copper rectangular plates where the cylinder diameter of 750 mm = (750/3,14=240 mm) 240 mm (diameter virtual). This is the required basic information to transpose physical dimensions from a cylindrical EH antenna to a flat EH antenna: Screenshot of the program calculation is presented in Pic.1 (below)



Pic.1 Flat EH antenna on 1,8 MHz band (scrinshot of calculation).

The physical dimensions for the flat EH antenna for 160m are presented below (Pic.2):



Pic.2 Flat EH antenna cut for 1,8 MHz band.



Pic.3 Photo of construction.
(Distance between copper plates is decreased, because transmitter output power will be no more than 100 watts)

Now we will talk about making of spool of tuning.
The next step is to discuss how to construct the tuning coil. You will need a polypropylene waste pipe with a diameter of 75 mm by 150 mm long to act as a former for the tuning coil wiring. . Approximately 70 turns of twisted wire around the coil is needed. This equates to between 2-3 coils per centimetre, (but this is not critical). With reference to Pic.2, tuning is easier if you loosely coil the first 3 Ц 4 turns at the top and bottom of the tuning coil. At the tuning stage you will be compressing or lengthening the coil turns at the top and bottom of the tuning coil for resonance, VSWR and maximum field strength. At a later stage of construction you will need to СtapТ the centre wire from your SO239 connector onto the tuning coil approximately 8 turns from the bottom of the tuning coil.



Pic.4 Tuning coil

The constructed tuning coil is then placed in a sanitary engineering muff with a diameter of 110 mm, preferably using a muff that is closed at both ends.



Pic.5 Sanitary engineering muff.

Drill two holes at the top end of the tuning coil muff end so that you can connect the top of the tuning coil wire to one side of the copper plates and another wire goes through the other hole (this wire is from the base of the tuning coil). Drill another hole in the bottom muff cover so that the centre wire from an HF connector (i.e. SO-239) can connect approximately 8 turns from the bottom of the tuning coil (see Pic.2). Please note that a ground wire is connected at the base of the tuning coil to the СgroundТ side of the SO239 connector.
Original appearance of spool of tuning on the choke, on the picture of Pic.6



Pic.6 Spool of tuning.

Following the physical attachment of wires between the tuning coil, copper plates and SO239 and noting that the initial tuning СtapТ from the SO239 central wire is 8 turns from the bottom of the tuning coil, the next stage is to tune the antenna. Tuning is discussed in more detail on my TUNING page but for now, by compressing and moving apart the coils (either at the bottom or top of the tuning coil) we are looking for the point of maximum field strength and minimum VSWR at mid-band. The screenshot below gives you a visual idea of antenna parameters following tuning using a MiniVNA (Pic.7).



Pic.7 Description of the adjusted flat EH antenna on 1,8 MHz band.

Real bandwidth on the level of 3 dB of the field, on the picture of Pic.8



Pic.8 Real bandwidth on the level of 3 dB of the field

As visible from the pictures of Pic.7 and Pic.8, the SWR bandwidths are very good i.e. 197 KHz SWR < 2:1 and 508,905 KHz plus or minus 3dB.



Pic.9 Flat EH antenna on 1,8 MHz (left) and cylindrical EH antenna 1,8 MHz (right) on the roof. (8 metres above the ground).

I carried out a number of on-air comparisons between the flat and cylindrical EH antennas, mostly CW with an output power of approximately 85 watts. I found very little difference in signal strengths between the two.
73! UA1ACO

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