home power article - how to power your home from solar generated hydrogen

8/14/2019 Home Power Article - How to Power Your Home From Solar Generated Hydrogen

1/1032Home Power #39 February / March 1994

Solar Hydrogen

Production byElectrolysisWalt Pyle, Jim Healy, Reynaldo Cortez

1994 Walt Pyle, Jim Healy, Reynaldo Cortez

Why would anyone want toproduce hydrogen at home?Hydrogen can be used as a

non-toxic energy storage and transportmedium. Hydrogen that is made fromwater using solar energy is asustainable and renewable homeenergy supply. Make hay (or hydrogen)while the sun shines. Then use thestored hydrogen to produce heat andelectricity on demand, day or night!

We got excited about solar hydrogen production duringthe seventies and the first oil shocks. What happenedbetween the seventies and nineties? For the most partwe worked with thermolysis (splitting water withconcentrated solar heat) and photoelectrolysis (splittingwater in a liquid solar cell). We also followed the workof other hydrogen pioneers, such as Roger Billings andhis associates, who produced and used hydrogen inhome appliances and vehicles.

The article by Richard Perez about the Schatz PVHydrogen Project (HP #22, pp. 2630) and asubsequent visit to Humboldt State Universitys TrinidadMarine Laboratory launched us into designing andmaking a home-sized system based on electrolysis of

water. Electrolysis is the competition for thermolysisand photoelectrolysis at this juncture.

Hydrogen and oxygen can be produced from waterusing electricity with an electrolyzer. This articledescribes the installation and operation of a 12 cellHydrogen Wind Inc. 1000 Watt electrolyzer. Thiselectrolyzer can produce 170 liters/hour (6 cubicfeet/hour) of hydrogen and 85 liters/hour (3 cubicfeet/hour) of oxygen (at standard temperature andpressure).

In addition, we describe a homebrew purification andstorage system for the hydrogen and oxygen producedby the electrolyzer. With proper after-treatment, thegases produced can be stored safely. The purifiedhydrogen and oxygen can be used in fuel cells (toproduce direct current electricity) and catalytic burners

(for heating and cooking) without poisoning ordamaging the noble metal catalyst materials. The gasescan also be used for welding and cutting, as well as formotor vehicle fuel.

!!!!Safety First!!!!Making and storing hydrogen and oxygen is not kidsstuff this is rocket fuel! Use flashback flamearrestors on the hydrogen and oxygen outlets from theelectrolyzer. Secure dangerous caustic from smallprying hands. Make sure your gases are pure beforestoring them. More on safety follows.

How Much Hydrogen Do I Need?This varies tremendously from household to household,depending on how well the Demand Side Management

job has been done. We can run our Platinum Cat spaceheater for about three hours on a cubic meter ofhydrogen. The amount of gas needed can be estimatedfrom the energy consumption of any appliance.Amanda Potter and Mark Newells article in HP#32 (pp.4245) describes the operation of an electrolyzer andshows how to calculate the amount of gas needed torun appliances. See articles on hydrogen space heatingin HP #34, hydrogen cooking in HP #33, and makingelectricity from hydrogen with a fuel cell in HP#35.

How Much Power Does It Take?A cubic meter (35.3 cubic feet) of hydrogen gas takesabout 5.9 hours to produce in this electrolyzer, whenoperated at its rated input power of 1000 Watts. Thismeans the energy required to produce a cubic meter ofhydrogen and 0.5 cubic meter of oxygen is about 5.9kW-hr. This translates to an efficiency of 51%, where 3kW-hr/m3 equals 100% efficiency at 20C. Typicalindustrial scale plants operate at about 4.5 kW-hr/m3 or67% efficiency at high current density. The efficiency isbetter at lower current density.

What Is Needed to Produce Hydrogen at Home?

Our system includes the following components andsub-systems (see the block diagram next page):

Solar electric power and/or utility grid power

Power Controller

Electrolyzer

Hydrogen Purifier

Oxygen Purifier

Hydrogen and Oxygen Storage Tanks

Electrolyte Storage Tank and Transfer Pump

Makeup-water Purifier

Hydrogen



Hydrogen

Where Can I Get AnElectrolyzer?The Hydrogen Wind electrolyzerwas introduced by its designerLawrence Spicer in HP #22 (pp.3234). Hydrogen Wind Inc.

electrolyzers are available insingle cell units for small demandor educational use, and in multiplecell configurations which providehigher gas production rates.

We purchased a 12 cell 1000 Wattsystem with the gas pressurecontrols and electrical metering.Larger systems with up to 24 cellsor smaller three cell and six cellsystems are available. Anotherarticle by Spicer, describing the

individual cells in more detail alongwith an introduction to cell arrays,appears in HP#26 (pp. 3435).

The cell electrodes are fabricatedfrom rectangular metal plates withtabs on one end. Both the anodeand the cathode metal plates aremade from porous, sintered nickel.Two clusters of nickel electrodeplates, 14 for the anode and 14 forthe cathode, are separated byporous plastic sheets folded

accordion style within a separatorcontainer.

The plastic separator container is open at the horizontal ends, and closed atthe top and bottom. This lets the larger hydrogen gas bubbles (which escapefrom the negative electrode or cathode) rise in the electrolyte, due to their

buoyancy, and exit the separator container on one side. The hydrogenremains separate from the smaller oxygen bubbleswhich evolve from the positive electrode (anode) andexit on the opposite side.

The micro-porous polypropylene separator containerand the electrode clusters are housed inside sectionsof steel pipe with flat steel plates welded on one endand bolted on the other end. The steel cell housingshold the water and potassium hydroxide electrolyte,and keep the hydrogen and oxygen gases apart afterthey rise from each end of the separator container.

We installed our electrolyzer inside a small weather-protected shelter made from box tubing and sheetmetal. We chose stainless steel sheet metal for itscorrosion resistance to caustic electrolyte and long-lasting perma-culture value. The photograph aboveshows an overview of the system.

Solar Power and Utility Grid Backup PowerOur solar electric power is produced by two 16-panelCarrizo Solar Mud photovoltaic arrays and a gaggleof other smaller panels. On a good summer day weget up to 75 Amperes at 14 Volts for charging the

Above: An overview of the electrolyzer system. The power supplies andelectrical controls are on the far left. Purification equipment is to the right ofthe power controls. The electrolyte reservoir and hydrogen and oxygen floatvalves with pressure gauges are to the right of the purification equipment.

Twelve electrolyzer cells are shown on the far right. A feedwater purificationsystem is just below the twelve electrolyzer cells. The caustic electrolyte

storage tank is on the ground below the float valves.Photo by Reynaldo Cortez

Solarelectric

modules

Makeup waterpurifier

Electrolyzer

Electricutility grid

Oxygenpurifier

Hydrogenpurifier

Electricpower

controller

Hydrogen gas

Hydrogen gas Oxygen gas

Electrolyte tank

SolarHydrogenProduction



Hydrogen

house batteries. When the two house battery banks arefully charged, our two 50 Amp SCI charge controllersdisconnect the PV power, and the PV voltage rises. AnEnermaxer controller senses the voltage rise andtransfers the PV power to the electrolyzers to makehydrogen and oxygen during theremainder of the day. A utility gridelectrolyzer power supply is used tomake hydrogen and oxygen whenthere is insuff icient solar poweravailable.

How Do We Purify the Gases?The gas purification system is shownin more detail in the diagram on right.The hydrogen gas and the oxygen gasare purified by two different systems.

BubblersFirst, each gas is scrubbed by passing

it through a water bubbler column.Each of the gas scrubbing bubblers ismade from two vertical plastic tubeswith end caps. A pair of fish-aquariumtype bubbler frits was glued into holesdrilled in the inside bottom caps ofeach acrylic plastic tube, usingmethylene chloride solvent. Flow ofgas into or out of a bubbler can thenbe seen by the operator. The bubblersare filled about one-third full with

distilled water using thedrain and fill valves on thebottoms.

We call these Bi-directional Bubblers. The

bubblers are tolerant off low in any direction,without letting the scrub-water into the productstorage system or theelectrolyzer. We got theidea for making thesebubblers from Dr. PeterLehman and hisassociates at HumboldtState University (SchatzSolar Hydrogen and FuelCell Laboratory.)

The gases entering thepurifier are saturated withwater vapor and maycontain minute amounts ofcaustic electrolyte aerosoland particulates like rust.

After passing through the bubblers the gases are stillsaturated with water vapor, but virtually caustic- andparticulate-free. Installing another coalescer before thebubbler would prevent particulates and some aerosolfrom entering the bubblers.

O2 bubblerH2 bubbler

Watercoalescer

Electrolyzer

FillDrain

H2 delivery O2 delivery

De-oxygenationcatalytic recombiner

Oxidation catalyticrecombiner

(future)

H2purifier

Gas Purification System

PowerController

Water coalescer

O2purifier

Watercoalescer

Water coalescer

P P

Sample Sample

Flashback arrestoracetylene check valve

Flashback arrestoracetylene check valve

Flashback arrestoroxygen check valve

Flashback arrestoroxygen check valve

FillDrain

Above: The bi-directional bubblers and purification systems. Photo by Reynaldo Cortez



Hydrogen

CoalescersNext, the gases are partially dried by passing themthrough coalescing filters. Special materials wererequired for the oxygen coalescer filter to preventspontaneous combustion, and no oil or hydrocarbonscan be present.

RecombinersThe hydrogen gas purifier treats the hydrogen gas in acatalytic recombiner. The purpose of the recombiner isto recombine any oxygen impurity in the hydrogenproduct, and make water. The noble metal catalyticrecombiner removes the oxygen impurity to make thehydrogen gas safe to store and handle. As a safetymeasure, we installed flashback arrestors between thefirst and second coalescers and the recombiners. Theflashback arrestors prevent flashback of poor puritygases (oxygen impurity in the hydrogen produced)when they reach the recombiner and ignition source.

The recombiners must be installed with their major axisvertical and the entry at the top.

Some data recently published by W. Hug et al from theGerman Aerospace Research Establishment(International Journal of Hydrogen Energy, Vol. 18 No.12, pp. 973977) shows that purity of the gasesproduced by an alkaline electrolyzer is affected by thecurrent density and temperature of the cells. From thegraphs we see that the purities of the hydrogen andoxygen gases are poorer at low current densities (suchas when a cloud covers the sun for example). This isbecause diffusion of the gases through the liquid

electrolyte is a more significant fraction of the totalproduction at low current densities.

The data also imply that there is more danger of havinghydrogen impurity in the oxygen than the reverse. Note

that the lower flammable limit, 4% for hydrogen impurityin bulk oxygen, is approached at low current densities.

How Does One Store the Gases?The hydrogen will be stored in two 0.47 cubic meter(125 gallon) propane tanks, and the oxygen will be

stored in one propane tank.REMEMBER: hydrogen gas is safe to store hydrogen/air or hydrogen/oxygen mixtures are NOTsafe to store! Put safety f irst! Safety is yourresponsibility. It is our intention to give you theinformation you need to follow safe practices.

Each of our used propane tanks was cleanedthoroughly and hydrostatically tested to 13.8 bar (200psig.). Pressure relief valves on each tank are set for10.3 bar (150 psig.). A pressure switch is installed onthe hydrogen tank feed line to shut off the electrolyzerpower supply when the pressure reaches 6.9 bar (100

psig.), the rated maximum output pressure of theelectrolyzer.

The produced hydrogen gas is pressurized by theelectrolyzer to its maximum rated pressure of 6.9 bar orless. Our two hydrogen tanks hold the equivalent of: 6.9bar x 2 tanks x 0.47 cubic meter = 6.5 cubic meters (atstandard temperature and 6.9 bar pressure).

Makeup-water Treatment SystemAs hydrogen and oxygen are produced in theelectrolyzer, water is consumed and it must bereplaced. We produce our makeup-water using thelocal Utility District water, which is piped into the home.

We want to prevent the formation of mineral scale onthe surface of the electrodes inside the electrolyzerbecause we want them to last a long time. First, the

Amount of Hydrogen in Oxygen

Current Densit mA/cm2)

Gas

Impuri

tyH2

inO2

(Vo

l%)

0

1

2

3

4

0 100 200 300 400 500 600

90C

60C

30C

Taken from measurements by Hug et al, IJH18:12, 1993

lower flammable limit

Current Density (mA/cm2)

Gas

Impuri

tyO2

inH2

(Vo

l%)

Taken from measurements by Hug et al, IJH18:12, 1993

90C30C

Amount of Oxygen in Hydrogen

0

1

2

3

4

0 100 200 300 400 500 600

lower flammable limit

60C



Hydrogen

water is passed through a 20 micron interference filterto remove particulates like rust and sand. Second, thewater passes through a charcoal drinking water filter toremove organics and chlorine. Third, the water passesthrough a de-ionizing column to remove metallic ions.The water before and after the purifier was analyzed.The results are shown in the table above.

As you can see, we removed some scale-formingmaterial. Other elements were below the lowerdetectable level of the instrument (approximately oneppb). Our water before the deionizer and charcoal filteris not very hard at this location; it does not containvery many dissolved minerals. After the de-ionizer thereis a marked reduction in elemental concentrations ofeverything except silicon.

Why Conduct a Hydrostatic Test on the Electrolyzer?Prior to filling the electrolyzer with caustic electrolyte,we conducted a hydrostatic leak test by filling the cells

with purified water and pressurizing the cells andelectrolyte reservoir to 6.9 bar (100 psig) using utilityline pressure. Several tubing fittings leaked untilt ightened. Fixing water leaks during the init ialhydrostatic test is much better than fixing leaks whenthey involve caustic electrolyte! Getting caustic on yourtools, gloves, safety glasses, and clothes is a real drag.Plan ahead!

When installing the tubing clamps, position them so youcan tighten them later when the cells are tied together.An improvement would be to mount the cells higher toallow for access to the clamps from below.

Why Do You Need the Caustic Electrolyte?Potassium hydroxide (KOH) in the water makes itelectrically conductive, so that ions can be transportedthrough the electrolyte during electrolysis. See graphshowing the conductivity of the KOH electrolyte as afunction of weight percent KOH in water on right.

We have chosen KOH as the caustic. The twelveelectrolysis cells and the electrolyte reservoir holdabout 61 liters (16 gallons) of water plus 15 kilograms(33 pounds) of KOH. This solution is about 23% KOH

Water Purification Results

Before After

Element Purifier, ppm Purifier, ppm

barium 0.009 nil

calcium 7.3 0.006

potassium 0.37 nil

magnesium 0.7 nil

sodium 1.8 nil

silicon 3.8 3.8

Concentration % Weight

Con

duc

tiv

ity

(Siemens

/cm

@2

0C)

0

0.01

0.02

0.03

0.04

0.05

0.06

0 10 20 30 40 50

Conductivity vs. KOH ConcentrationOmega Conductivity and pH Measurement Catalog

by weight. The strength of the electrolyte solution canbe tested with a battery hydrometer. The specificgravity should be about 1.1.

Safety is a Must When Handling Caustic Electrolyte!DANGER!! Potassium hydroxide is very corrosive and

hazardous to handle. KOH deserves great respect.Goggles or safety glasses with side protectors, andplastic or rubber gloves are absolutely necessary whenhandling KOH. When caustic comes into contact withthe skin, the natural oils of the skin are chemicallyconverted to a soap, which initially gives a slipperyfeeling. Prolonged contact will dissolve the skin andgive a chemical burn similar but more severe than thatgiven by handling lime or fresh wet concrete with barehands. The best treatment for any accidental spill isf lushing with copious amounts of water, orneutralization with a weak acid such as vinegar. Alwayshave a water hose hooked up and operational before

handling KOH caustic. Keep the electrolyzer outdoorsand locked so only qualified people can service it. Acyclone fence with top and sides might be the solution.

DANGER!! The mucous membranes of the eye areespecially susceptible to caustic damage. It has beenestimated that 15 seconds of contact to the eye withconcentrated KOH caustic is enough to producepermanent blindness. If any KOH comes into contactwith the eyes, the best treatment is to flush the eyesimmediately with pure water for at least 15 minutes andseek medical attention.



Hydrogen

What Provisions Need to be Considered WhenHandling Caustic?To service any of the cells, we need a way to drain theelectrolyte and store it for re-use. We have a drain valveand line on the bottom of the electrolyte reservoir thatallows the KOH solution to gravity drop into a stainless

steel tank at a lower level on the ground. A tubing rollerpump is used to refill the electrolyzer cells with KOHafter the maintenance is completed. Our KOH tank waspreviously used as a swimming pool filter case.

We mixed the water and KOH in the ground levelcaustic storage tank. Water and KOH mixing produceschemical heat, the heat of solution, which issurprisingly high. After we mixed in all of the KOHflakes, the water temperature rose from 20C (68F) toabout 82C (180F).

At this point we made our first big mistake. After theKOH and water electrolyte solution was mixed (andhot), we immediately started pumping it into theelectrolyzer reservoir and cells, using the tubing pump.Within minutes, the tubing pump began leaking. Westopped the pump and drained the KOH back to theground level tank. After cleaning up the mess, we foundthat the silicone tubing had split open. We let the KOHsolution cool overnight. The next day we replaced thetubing in the pump, and tried again. This time thetransfer proceeded without pump tubing problems.

By the time the caustic was about half pumped into thecells, we found that six of the tubing fittings on the firsttwo cells were dripping KOH onto the floor of the

shelter. The hot KOH the night before had damagedsome of the pipe thread seals which were made withfive minute epoxy. The threads in cells further awayfrom the caustic KOH entry point were not damaged,presumably because the caustic KOH solution hadcooled by the time it reached those points. We drainedthe caustic KOH back to the ground storage tank,removed the affected fittings and replaced the epoxythread sealant. The next day we filled the cells back upwith KOH solution for the third try.

More caustic KOH leaks! This time we had leaks on thetubing fittings on the gas-trap tubing loops where the

hydrogen and oxygen come out of the cells at the top.Additional tightening of the tubing clamps with a 12 pointbox wrench stopped some leaks. Other fittings had to beremoved and thread epoxy had to be reapplied. Whenwill solid polymer electrolyte electrolyzer cells beavailable at a reasonable price so we wont have tohassle with KOH???

What Were the Cell Operating Conditions?The cells require about 1.7 volts each to beginoperating; at higher currents there is a greater voltage

requirement. The direct current requirement is about 40Amperes for each cell at rated gas output. In a twelve-cell system the cells are wired in series, so that all ofthe cells get the same current and the voltages add upto 12 x 1.7 V or 20.4 Volts total at 20 Amperes ofcurrent. The cells can also be wired in series-parallel for

10.2 Volts total.

Our solar photovoltaic system and grid back-up powersupplies can only produce about 25 Amperes at themoment, so we cannot yet achieve full gas output. The20.4 Volt operating voltage was not a problem with ourCarrizo solar electric arrays, however, since they havean open circuit voltage of about 25 Volts.

Strange and Unusual Behavior?When operating the electrolyzer the first day on directcurrent power, the power controller behavedpredictably. We measured about 22 Volts and 25Amperes flowing into the electrolyzer cells. We had gasflow only through the oxygen bubbler however!! Andoccasionally, the oxygen float valve burped someKOH solution upward with a release of gas. The fix forthis problem was to raise the electrolyte level fromabout 5 cm (2 inch) on the reservoir level gauge to 20cm (8 inch).

At first startup the gas comes out after a delay of aboutan hour while the cells are charging and the gasbubbles on the electrodes get large enough to breakaway. Voltage across the cell array gradually risesduring charging from 18 to 19 to 20 Volts before gascomes out.

On restart, hydrogen comes out later than oxygen sinceit must first fill the top of the electrolyte reservoir tank topressure-pump the system. When both gases werecoming out of the electrolyzer pressure control floatvalves, the pressure on the reservoir was 2.5 bar (36psig) when discharging to atmospheric pressure.

The next day we may have had our first personaldemonstration of Will iam Groves astonishingobservation that an electrolyzer can run backwards andbecome a power source. Grove discovered in the early19th century that the reverse reaction supplyingoxygen and hydrogen to electrodes causes anelectrolyzer to produce direct current electricity and actas a fuel cell.

Before we turned on our power supply the next day, thevoltmeter showed about 16 Volts DC on the electrolyzerterminals indicating it was acting as a source. Afterthat we put a resistive load on the electrolyzer leadsand generated about 16 Volts and 10 Amps for severalhours (160 Watts) before it ran out of gas. Was thecell acting as a fuel cell, as an alkaline nickel-ironbattery, or a combination of both?



Hydrogen

Grunting and Wheezing Sounds are Normal!Inside the Hydrogen Wind gas pressure control systemthere are three float control valves. Two float valves areused for the oxygen and one is used for the hydrogen.When the float valves are filled with gas (vertical acrylictubes with top caps), they float on the electrolyte in the

chambers. As each chamber f i l ls with gas theelectrolyte is gradually displaced and the the buoyancyof the float decreases. When the buoyancy is lowenough, the float falls which releases the elastomerplug from the exit passage and allows the gas to leavethe system.

The float valves cycle over and over again to releasebursts of gas to the purifiers. You can hear gruntingand wheezing sounds when standing alongside theunit. A little back pressure on the discharge lines makesthe release less violent and quieter. With 1 bar (14.5psig) back pressure we had good results.

Budget & Economics for Gas Production & StorageThe approximate cost for the solar hydrogen systemequipment is listed below, broken down by sub-system.

The labor used for this installation was our own andwas not tallied. Normally, for a first time system suchas this, a rule of thumb is that the labor costs will aboutequal the capital equipment costs. Labor on any futureclone would be significantly less. Capital equipmentcosts could have been reduced by using fewer stainlesssteel and more plastic components.

We didnt work out the payout or ROCE for this

system before going for it. We made it because wethought it was nifty stuff!

It would probably take quite a while to pay for thissystem. However, dont forget, its a prototype. Massproduction has a way of cutting costs by factors of ten.How does a cloned system capital cost of $678 sound?

Status and Future DirectionStartup of this system occurred during the first week ofDecember 1993. Our next task is to measure the purity

Hydrogen System Cost

Equipment Cost % 12 cell electrolyzer system (incl S&H) $2,300 34%

Photovoltaic modules (used) $1,500 22%

Gas storage tanks, relief valves, tubing $1,100 16%

Hydrogen purification system $950 14%

Oxygen purification system $350 5%

Caustic storage and transfer $300 4%

Feedwater purification system $275 4%

Total $6,775

of the hydrogen and oxygen product gas streamsbefore we attempt storage.

Eventually, when we have a use for the oxygen gasproduct in a large fuel cell, we plan to add an oxidationrecombiner to the oxygen side. This will remove any

hydrogen impurity from the oxygen side and make itsafe to store and handle. For now, we are not storingthe oxygen. Instead, we will supply the oxygen to theroot system of vegetables in some experiments with ahorticultural friend of ours, but thats another story......

A future article will focus on safe storage of hydrogenand oxygen. We plan to cover compressed hydrogenand oxygen gas storage and hydrogen storage in metalhydride.

AcknowledgementsAlternative Energy Engineering, David Booth and DavidKatz, for the upgrade to our Enermaxer power

controller.

Jim Robbers and Mike Robbers for the used stainlesssteel swimming pool filter cases which we use forelectrolyte storage.

AccessWalt Pyle, WA6DUR, Richmond, CA 510-237-7877

Jim Healy, WH6LZ, Richmond, CA 510-236-6745

Reynaldo Cortez, Richmond, CA 510-237-9748

Electrolyzer

Hydrogen Wind Inc. RR 2 Box 262, Lineville, IA 50147 515-876-5665

Purifier and Storage Components

Hydrogen Coalescer (Coilhose 27C3-S): Weill IndustrialSupply Inc. FAX 510-235-2405

Bi-directional Bubbler: H-Ion Solar Co. FAX 510-232-5251

Flame Arrestors: Check valve flashback arrestor, flasharrestor body with female inlet check valve. Part # FA-3CV. Western Enterprises FAX 216-835-8283

Oxygen Coalescer Finite Housing S2M-2C10-025: A FEquipment Co. 408-734-2525

Hydrogen Recombiner Deoxo Purifier D50-1000: GPT

Inc. FAX 908-446-2402Pressure Relief Valves (Nupro 177-R3A-K1-A):Oakland Valve & Fitting Co. FAX 510-798-9833

Power Sources

Solar arrays: Carrizo Solar Corp. 800-776-6718

Enermaxer controller: Alternative Energy Engineering(see ad index) 800-777-6609


8/10

32 Home Power #22 April / May 1991

ydrogen is an abundant fuel and it is simple to make. Above the initial cost of thegenerating equipment, the hydrogen produced can be free. The only substances

used up in making hydrogen are water and electricity. My electricity comes froma wind generator and the water I use is rainwater. By using solar cells, the entireprocess can be done without one moving part.

H

Hydrogen FuelL.E. Spicer

1991 L.E. Spicer

Hydrogen's TraitsI consider hydrogen to be a much safer fuel than gasoline

or propane. Hydrogen has a builtin safety factor

because it is the lightest element. Upon release it

disperses very rapidly, rising straight up, and is lost assoon as it is released. Hydrogen disperses so quickly that

a gas welding torch will not light unless the spark is next

to the gas outlet. An ordinary acetylene welding torch can

be used with hydrogen. The hydrogen flame is clear and

to adjust the acetylene flame you will need to look at the

glow coming from the metal. In bright daylight the

hydrogen oxygen flame of an acetylene torch cannot be

seen.

AdjustmentsA few simple adjustments can be made to your propane

cooking stove to make it operate on hydrogen. Fill any

large venturi cavity with steel wool to prevent a poppingnoise. Next adjust the jet size, regulate the pressure, and

close off all air at the jet.

Gasoline engines can also be adjusted to run on

hydrogen. I have adapted a propane/air mixer to a

gasoline carburetor with success using hydrogen as a

fuel. A standby gas generator set adapted to hydrogen

would be a good arrangement.

A better use of hydrogen that I would like to see, rather

than wasting it on a low efficiency gas motor, would be the

use of a hydrogen-oxygen fuel cell. A fuel cell can be

used for electricity or to run a vehicle with good efficiency.StorageI store my hydrogen in a 500 gallon propane tank.

Propane and hydrogen are compatible in the same tank.

In fact, propane can be conserved by bubbling hydrogen

into it. Another advantage to putting hydrogen in propane

tanks is to add smell to it, and to avoid mixing your

hydrogen with oxygen from the air. Propane tanks also

Hydrogen

have a pressure release valve set at 250 PSI. I have had

no problems with storing hydrogen below this pressure.

Hydrogen and oxygen must be stored in separate tanks.

The only time to combine oxygen or air to hydrogen is at

the burn site. Hydrogen and oxygen mixed and ignited isexplosive, same as any hydrocarbon fuel.

ElectrolysisIn my electrolyzer cell, the hydrogen evolves off the

negative potential; the positive potential releases the

oxygen. It is important to maintain the same polarity on

an electrolyzer cell. If the polarity is switched your gases

will be mixed. I use Nickel on the positive side along with

potassium hydroxide as an electrolyte. Nickel electrodes

in potassium hydroxide do not electroplate away. Pure

water is a non-conductor of electricity. Therefore, a

potassium hydroxide electrolyte is necessary. The

potassium hydroxide is not used up is the process of

electrolysis. I purchase my potassium hydroxide from a

chemical warehouse.

I use the hydrogen gas for combustion. I use the oxygen

gas produced for welding, especially for cutting which

uses lots of oxygen. I haven't bought oxygen for my

cutting torch since I installed the hydrogen setup.

Homemade ElectrolytesIf you want to make your own electrolyte, it can be made

from wood ashes. First, soak your wood ashes for a

period of time, depending on how concentrated you want

your solution. Remove the clear solution off the top of thewood ashes, then evaporate down to the specific gravity

you want your electrolyte to be at. A weak solution works

fine, and is not as caustic as a stronger solution.

Gas PressureHydrogen and oxygen gas will evolve from the

electrolyzer under pressure. This can be taken

advantage of by using a hydrostatic column to obtain


9/10

33Home Power #22 April / May 1991

Hydrogen

pressure. See the illustration. This one cell electrolyzer

along with this simple three foot hydrostatic control will

give pressurized storage of both hydrogen and oxygen

with no moving parts. The pressure is obtained from theweight of the three foot water column. This is sufficient

pressure to displace the water from the bottom 55 gallon

barrel to the top barrel. The water in the top barrel in turn

puts pressure on the gas. A series of 55 gal. drums can

be lined up in this fashion to store larger quantities of gas.

There is no need for gauges as the liquid level can readily

be seen through the clear tubing. There are no pop-off

valves to be concerned with. After adding the electrolyte

to the system only water and electricity are needed for

continued operation. A fail-safe feature of this control is

that the hydrogen and oxygen go into storage or arevented into the air.

Controls & Power SourcesI also build a 50 PSI control that operates three

electrolysis cells in series which operate at 12 Volts DC

and 40 Amperes.

My larger control is a 100 PSI control which can handle

six or more electrolyzer cells in series. I presently have a

HYDROGEN

HydrogenOutlet

Valve

Vent

OXYGEN

WATER

OxygenOutlet

Valve

Vent

WATER

WATER

WATER

Water

Input

Hydrogen Out Oxygen Out

gas

checkloops

3

feet

ELECTROLYZER

CELL


10/10

34 Home Power #22 April / May 1991

six cell unit with a 100 PSI

control in my shop. It is

powered by a Jacobs wind

generator. Each cell requires

4 Volts DC. These are wired

in series and operate at 24

Volts DC and will load to 40

amps with each cell delivering

1/2 cubic foot of hydrogen per

hour on a windy day.

A good power source to drive

a one cell electrolyzer is a high

amperage six Volt wind

generator. Another good

source would be a permanent

magnet motor driven by water.

Access

L.E. Spicer, Hydrogen Wind,Inc. RR#2 Box 262, Lineville,

Iowa 50147 515-876-5665.

Hydrogen

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