Do It Yourself

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Homemade Jiffy Pots

This photo shows a paper towel cylinder, divided into three pieces on the band saw.... could possibly make four.
I then scissored up into the cylinder, in four equal places, (EG on a clock face 1/4 past. 1/2 past, 1/4 to and o'clock.)
I bent the cardboard back...as in photo, then folded the flaps back into the cylinder as they do with cardboard boxes. I should add ...for my example I have made the flaps a bit long, purely so it is easier to photograph.
The second little fellow is the end result. I am chuffed at our little experiment....as to the end result ...shall wait and see. I imagine no worries if the seeds germinate,........as this will result in very little disturbance of their roots.

 

homemade jiffy pots

How to build a cheap electrically heated propagation unit

This is a DIY Article on how to build a ‘cheap as possible’ propagation unit for raising seedlings, cuttings and young plants.

The unit is ‘self regulated’ i.e. it does not use a thermostat as these devices are hard to get secondhand and usually come attached to a big things like fridges or ovens. The most important thing with getting stuff done on the cheap is patience. Eventually, everything you need will turn up at the dump or the op-shop.

The important components:

The most critical (and hardest to get) thing you need to keep an eye out for is the heating element. What you need to look for is a heating device that outputs low amounts of heat over a large area. These are commonly found in electric blankets (I found the one I used in my propagator in a “dinner plate warmer”). This heating wire is usually insulated which is better for obvious reasons. You can also buy new uninsulated nichrome wire from Dick Smith or Jaycar (only 4m lengths) or any size/type from E-bay or a wire merchant (just search on ‘Nichrome heating wire’). Its actually pretty cheap from a supplier, which is why I cringe when I see how much they sell “heating units” for in the hydroponic shops.

 

The second critical thing is the lighting ballast. These can be bought for about $5-10 from scrap yards or the dump always has a ready supply. They just need to be wired up to a switch/plug.

The fluoros you cant really skimp on, but day-light (more blue) or cool-white (more even blue/red mix) work great for seedling/cutting/germination work. ‘Plant lights’ are specially doped and give you more bang for your energy consumption but they also cost about three times as much. Flouros dim eventually and need to be replaced. Swap them for fluoros in less light intensity critical areas like the shed.

 

The third critical element is the power supply, if you choose to operate at mains power you don’t need an additional power supply. However….Should you choose to build this unit using mains power then it has the potential to kill you. Ensure that all conductive (i.e. metal) components are fully grounded and protective fuses are in place to ensure continued safety. Additionally, ensure a qualified electrician checks the safety of the device prior to operation. Having said this, the cheapest way to run the unit is at mains power as any transformer will loose you energy when dropping the voltage.

You can more safely build the unit using a safer voltage (say 12 or 24V).

 

The small commercial unit I bought works on a watt density of about 0.01 W/sq.cm (100 W/sq.m). This amount of wattage gives about a 10-15 deg.C rise above ambient temperature for flats placed on the unit (this obviously varies in a ‘self regulated system’ as the more pots are placed on the unit the more insulated it becomes and therefore less heat escapes so the hotter it gets). If I use a sheet to cover germination flats I can get up to a 20-25deg.C rise in ambient temperature. This is a very important consideration, as I just accidently cooked a batch of seeds by covering them with a blanket!

The watt density is what I used as the basis for calculating the wattage of the heating element I needed to build.

Calc 1: I want to heat an area equivalent to about 6 seedling flats (70*95cm) or 6860 sq.cm. So if the watt density needs to be 0.01 W/sq.cm I need an element that generates 6860 sq.cm * 0.01 W/sq.cm = 68.6 watts. Lets say 70 W to round it up.

Calc 2 (calculating the watts an element will generate, this calc is not really needed but it gives you an idea of the resistance you need when buying nichrome or maybe you’ve got an electric blanket in the house and might mention to the wife that its looking a bit shabby!): If I required an element of 70 Watts and ran this from a power supply of 240V the resistance of the element would need to be (240V*240V)/70W= 822 ohms.

If you have the wire already you can measure the resistance/meter (ohm/m) and determine how long the wire needs to be. As a rule of thumb the shorter the element wire the hotter it has to get to produce the same amount of heat (watts). This must be a compromise. You need a wire long enough to evenly distribute the heat over the area but not so long it is unmanageable or so short it melts anything. Length is not really a limiting factor as if the element is too long you just have to wind the wire more around your element frame, this gives more even heat distribution and reduces thermal strain on the wire as it operates at a lower overall temperature.

A note of caution: Nichrome does not take solder, it needs to be crimped or clamped for a secure electrical contact, so get good joiners from Dick Smith or a suitable nut and bolt would suffice.

To build my element I used ‘Corflute’. This material is a 5mm corrugated PVC plastic used universally in house ‘For Sale’ signs. It also retails for ~$20 a sheet (1.8*2.4m). If you found an electric blanket suited to your needs then you could just use that no modifications necessary.

All you need to then do is thread the wire up and down the corflute to form the element. You can seal/waterproof the element with silicon, but as this part should never be wet you can leave it be.

 

If you choose to run at 240V you don’t need an additional power supply. But this is potentially dangerous and needs a qualified electrician to certify the job. Not building the unit out of anything conductive and ensuring your wiring is enclosed within the system means your pretty safe if anything goes wrong.

 

My standard source for a switch mode PS is old computers, but wall warts, battery chargers and light dimmers can also be used. The list is endless and you only need to check the unit is capable of pumping the Amps required (see below). You then can build the rest of the unit around the Volts the supply runs at (standards are 5, 12 or 24V, the higher the volts the better). Any old electrical equipment generally has good transformers, but these obviously need more work to make them work.

 

A note of caution about solid state power supplies, if your running a small heating unit it may not draw enough power to operate the power supply properly. Checking the minimum amperage these devices need is not usually possible as they don’t write this info on the units. This is especially pertinent with light dimmers and computer power supplies but you can get around this problem by adding additional loading to circuit (say a small light bulb to let you know the powers on).

To check that your power supply will handle the Amps drawn by the element, you need to factor in a safety margin of 2. This is an arbitrary safety measure for determining power supply suitability.

Calc 2: I calculated above (calc 1) that the element generates 70 watts of heat; therefore I need a power supply that is rated to at least 140 Watts. However, more commonly, power supplies are rated in Amps, so a conversion is needed.

I have calculated I need a 70 Watt element (see calc 1), and I have a power supply equivalent to mains voltage (240V rated at 10A). Is my power supply big enough? Well a 70Watt element will draw 70W/240V = 0.29Amps. As my power supply is rated at 10 Amps this gives me a safety factor of 10A/0.29A= 34. So yes the power supply will not overheat when running the element.

As a rule of thumb the smaller the voltage used the higher the Amps needed to produce the same amount of power from an element. The power supply you find will be the primary determinate on how big a unit you can build. If you start getting low on the safety margin or element wire length play around with the element wattage and reduce the overall area of the propagator. It’s a matter of crunching the numbers to see what fits best. The best way to do this is to make a spreadsheet.

 

This is all standard wiring to a three pin plug.

 

I built the element first (cut to fit ~six seed flats) and then built a tray from framing pine and masonite (any scrap will do). I first lined the tray with polystyrene cut from broccoli boxes and then with some old foam yoga mats (you want the heat to go up, not down). To waterproof the element I used pond liner plastic as a solid barrier between the pot area and the tray/element components. This was followed by a 20kg bag of washed sand. The sand helps the liner plastic keep close contact with the element and builds up the thermal mass of the unit.

 

The whole thing is on an old desk and the light is suspended from the roof with a couple of pulleys and a rope.

 

As mentioned earlier the more insulation you have over the heating pad the hotter it will make the soil due to reduced heat loss to the environment. The converse happens also, so it is important if you want to get the heat built up to use wet sand in the unit to increase the heat retention. If you don’t use sand an alternative could be to use foam covers over the sections you are not using to trap the generated heat.

Equations for converting stuff
V=Voltage A=Amps R=Resistance (ohms) W=Watts

W= (V*V)/R
A= W/V
V=IR
R=(V*V)/W

 

Disclaimer: The author nor the administrators of this site accept any liability arising from any loss or harm resulting from the use of this information and data or reliance placed on it not only of this article but any content on this website. But in relation to this particular article don't play with electricity and water unless you know what ya doing or you could fry :)


Pruning Time - Secateur Maintenance

Various Types

With rose pruning getting close, it's probably a great idea to pull out the secateurs and sharpen and lubricate them in readiness. To do the job, it's best to dismantle the secateurs and thoroughly clean the gum from both the blade and anvil.

A small wire brush is ideal although some wet'n'dry works well also. This build up on the blade can be kept at bay by washing after each use in warm soapy water then rubbing a bit of vegetable/cooking oil on the blades.

The blade can quickly be sharpened using an oilstone with a couple of drops of light oil to assist the cutting action of the stone. (Remember to dress the anvil). Most secateurs eg Felco come with detachable blades, which makes this task easier.

Hygiene should be practiced in the garden when pruning and a wipe with an alcohol swab or a dip in a bleach solution should be done between plants.

Hand sharpening blade
Once you've used them for a while, a touch up sharpen with a small hand stone is all that's needed. A small stone soaking in a little linseed oil & turps is handy for these touch ups.

Don't forget your pruning saw and if it needs sharpening, think about either sending it to the saw doctor or replacing it.

Now for a good comfortable pair of gloves, remember that thick gloves will restrict your movement with the secateurs. Riggers gloves make good gloves for pruning roses.

 **Felco actually make a secateur with a holding clamp, which holds the pruning in the jaws which allow you to place pruning in barrow without being spiked by thorns. See Felco Classic - 100 model.