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104 lines
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HTML
104 lines
8.6 KiB
HTML
<HTML>
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<title>Expo Solar Panel Documentation</title>
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<META HTTP-EQUIV="author" CONTENT="Martin Green">
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<META HTTP-EQUIV="keywords" CONTENT="Solar Panel, Battery">
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<META HTTP-EQUIV="description" CONTENT="Description of the solar panels and battery used at the stone bridge">
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<META HTTP-EQUIV="generator" CONTENT="a plain text editor, naturally...">
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<link rel="stylesheet" type="text/css" href=/css/main2.css />
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</head>
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<body id="top">
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<h2 id="tophead">CUCC Expedition Handbook</h2>
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<H1>Solar Power</H1>
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<H2>Summary</H2>
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<p>Since 2003 the bivy site at Steinbrückenhöhle (the stone bridge) has had a number of solar panels
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and a car battery, which are mainly used for <a href="charging.html">charging lamps and drill
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battery packs</a>, but also AA/AAA batteries and phones. Much bigger flexi solar panels arrived in 2007
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and a second, larger, battery around the same time.</p>
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<h3>UPDATE 2024</h3>
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Frank new PV documentation document:
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<a href="/expofiles/documents/TopCampSolarSystem2024_07_08.pdf">SOLAR POWER 2024</a>
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<h3>2018</h3>
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<p>In 2018 two new PV panels were bought.
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These <a href="/expofiles/documents/hardware/EN-Eagles-270PP-60_rev2014-1.pdf">Jinko JKM270PP-60</a> (<a href="https://www.jinkosolar.com/ftp/EN-Eagles-270PP-60_rev2014-1.pdf">original site</a>)
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beasts are 255W (peak), ~16% efficient and weigh 19kg each. They are glass-fronted, aluminium-framed, and measure 1650 x 992 x 40mm.
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These were installed at Steinbrückenhöhle top camp
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and the light-weight panels already there can be used at another camp. The rest of this text describes the situation
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in 2017 before these Jinkos were bought. Also new in 2018 is a new set of 12V sockets (car type). This page will be updated when they have been installed.
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<p>An MPPT controller charges the battery from the panels. It's a <a
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href="/expofiles/documents/hardware/V117_MPPT_Solar_Charge_Controller.pdf">MakeSkyBlue
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S3 series</a>. You can program the hours of operation (24hr), max
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charge voltage (14.2), float charge voltage (13.2), and battery load
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cutoff voltage (11.9V)</p>
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<p>The system (in 2017) was two independent systems running in parallel.
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<ul>
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<li>The Big system uses the three big solar cells on the big wooden frame the big battery and the cable with the (hopfully) obvious connectors on it</li>
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<li>The Little system uses the four small aluminium framed solar cells and the smaller battery and the cable with the banana plugs on one end</li>
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</ul>
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</p>
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<p>The system can be made moderately weather proof, but in very windy or wet weather, it should be bought into the relative safety of the stone bridge.</p>
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<H2>Equipment stored up the hill</H2>
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<ul>
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<LI>Four 12V solar panels in a aluminium frame</LI>
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<LI><b>Three big floppy solar panels</b></LI>
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<LI><b>A <u>massive-fuck-off</u> wooden frame, to mount the big floppy solar panels on</b></LI>
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<LI>2 x Charge-Discharge and Power Distribution boxes</LI>
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<LI>Lead-acid (Gel) 12V battery ~40Ah</LI>
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<LI><b><u>Another </u>Lead-acid (Gel) 12V battery</b></LI>
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<LI>Multimeter</LI>
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<li>Car cigarette lighter to USB distribution board</li>
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<li>Random other bits that may or may not be usefull</li>
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</ul>
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<H3>Setup of big solar panels</H3>
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<p>The three big solar panels are bolted to the big wooden frame using spare non structural bolts on the frame (ie not on a joint). The panels have to be overlaped to fit. This whole frame is then lashed to the stone bridge using the 4 spits just above the animal hole. The cable with the connectors that fit these panels is then run through the small gap in the animal hole end wall and up to the back of the bivi. The solar panel cable is then connected to the solar input on the "bent plastic" charge regulator. The big battery is connected to the battery connectors of the "bent plastic" charge regulator</p>
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<H3>Setup of smaller solar panels</H3>
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<p>In 2014 the smaller panels were perched on the stone bridge above the big panels as no frame emerged from Tramgold! The solar panels are connected together in parallel to give ~12V input (i.e. connect all the red and all the black solar panel banana plugs together, to make a long red stick and a separate long black stick). Then plug the two banna plugs on the end of the long cable into the end of the stick and insulate the two exposed ends of the sticks (we don't want them connecting!!). Now run the cable for this the same route as the big pannel cable. Connect the far end of this cable to the solar input on the project box charger and connect the small battery to the battery terminals of this box</p>
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<H2>Waterproofing</H2>
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All the circuits should be covered with plastic sheeting (There should be a cut open inglesport bag for that purpose). The sheeting is held down by medium sized rocks all around its perimeter and the liberal application of gaffer tape to hold it all togeather.
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<H2>24V drill battery charging</H2>
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To charge the (now rarely-used) Bosch 24V drill batteries, the four solar panels should be connected together with two pairs of serially connected solar panels connected together in parallel. Crocodile clips can then be used to connect to the battery terminals. Note that the battery will not stop charging, and may damage the battery if left to over charge.
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<H2>Putting the (Lead-acid) batteries away</H2>
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<p>Store the batteries full, this means that you should stop discharging the batteries a few days before they are to be put away to allow them to charge. Grease the battery terminals, and place the batteries where they will stay dry, do not cover with anything that may get soggy and short the battery (e.g. cardboard box).
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<p>In 2019, as we had long feared, inexperienced and under-supervised cavers in a hurry dropped a lead-acid battery
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several metres while putting it away. Fortunately no one was hurt. We now plan to try to run
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power cabling in a much longer run to the PV panels and the bivvy so that the batteries need to bemoved as little as possible.
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<H2>Thanks</H2>
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On behalf on anyone using the system, thanks go to Earl Merson who provided most of the equipment, and more importantly carried a car battery up the hill. More thanks go to whoever carries it down again should it ever become knackered.
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<hr />
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<h2>This is mostly historic</h2><p>
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Four 12V solar panels were are mounted on an aluminium frame, which has been put on some flat limestone, slightly downhill and to the right from the stone bridge. The solar panels are waterproof, but are liable to be being blown over and damaged, hence large rocks must be used to keep it in place. The panels should be orientated pointing into the sun, without any shadows on them. Looking at the panels you can see the individual ~0.6V photo-arrays, each one not getting sunlight reduces the voltage output of the panel. There is also a fifth panel that can be propped against a rock in good weather.</p>
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<H3>Setup of charge-discharge circuit</H3>
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The next part is to connect the lead-acid charge-discharge circuit, which is found mounted in a Tupperware box with wires coming out. The solar panels are then connected to the circuit to it in parallel to give ~12V input (i.e. connect all the red and all the black solar panel banana plugs together, to make a long red stick and a separate long black stick). The car battery should also be connected to the circuit, and so should the power distribution box (The one that looks like it has been properly made and designed).
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<p>The charge discharge circuit contains a fuse some LEDs and a toggle switch. It has three modes:
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<LI>Battery charged: The battery no longer receives current from the solar panels</LI>
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<LI>Battery partial charged: The battery will receive and supply current</LI>
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<LI>Battery discharged: The battery no longer supplies current</LI>
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<p>It is left to the user to work out the interface, to work out the mode from the LEDs etc. The circuit will automatically enter the charged and discharged state at set voltages, which are adjustable by two potentiometers. Do not adjust these unless you know what you are doing, they should remain at sensible values. To get back into the partially charged state from the discharged, it is necessary to push the toggle switch.
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<H3>Setup of the power distribution circuit</H3>
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The input power from the charge-discharge circuit, goes into the connectors marked solar panels, the battery connectors are now redundant. This box is also fused, and has a number of cigarette socket outputs, a four way cigarette socket adaptor, will increase this number. Note that battery power is not unlimited, so any chargers at the stone bridge do not mean that you should not carry your batteries down the hill to be charged when you are able.
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<hr /></body>
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</HTML>
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