Sciencemadness Discussion Board

Homemade carbon electrodes

Hexabromobenzene - 13-5-2023 at 16:50

The inert anode is a very important thing for electrochemistry. Both organic and not organic. Typically, such products are inaccessible and expensive. Here is a technology on which you can produce carbon anodes of any shape and size having a small stove or heating boiler.
The idea was taken from this video, but improved https://www.youtube.com/watch?v=N9B2OAiu95Y

This technology is similar to the industrial technology of the production of graphite electrodes, but from available raw materials and without graphitization, since this requires high temperatures

The main idea of this technology of baking of the conducting carbon with a binder at 1000 degrees and then impregnation with any varnish or glue.

As a conductive carbon, I used charcoal from the furnace. Charcoal was sprinkled from the stove into an iron jar and closed for colling and protection from air. Next, you will need a multimeter. You must choose the most conductive pieces of coal. I use pieces with a resistance of less than 10om. Small pieces are usually baked better and have less resistance up to 2 Ohms.

After you have chosen coal, which is well conducting the current, you must grind it. Be careful. Charcoal is very dusty. Next, I cook concentrated sugar syrup and mix it with carbon powder. So much sugar syrup is necessary that the mixture with coal becomes like a warm bitumen. Next, this mixture is pressed into the cardboard tube of the desired diameter, closed on one side with a paper. If you do not have a cardboard tube, you can make a paper pipe from a newspaper. To press the mixture conveniently steel reinforcement. After pressing the mixture, the tube is closed with paper. Then the finished baking dish is wrapped with aluminum foil for insulation from air when baking.

Next, you need to place your baking dish in a steel container. It is important! Without a steel container, the electrodes burns significal. I used metal from a tin can. The baking dish was wrapped in a thin iron sheet

A steel container with a baking dish is placed in the furnace and heats up to 800-1000 degrees for about an hour. An ordinary heating furnace is easily capable of giving a temperature of 1000 degrees if you place a lot of small firewood in it and surround them with a steel container.


After baking, the thin metal usually crumbles into the scale powder. The steel container is disposable. After extraction, we have a ready -made porous carbon electrode. As a rule, it is of poor quality,paper baking with paper and it must be separated.

Next, the electrode must be impregnated with any polymer resin. I used alkyd varnish for wood, but you can use a lot of different options. It is recommended to process electrodes with sandpaper before impregnation.

Also in industry repeat the baking cycles of the electrode several times. I saturated the electrodes with sugar and baked up to 3 times, but did not see a significant difference. Repeated baking makes sense if you have too many defects on your electrode.

After the varnish dries, we have a ready -made electrode. It has less strength than graphite electrodes. I do not recommend drilling it for the current supply. To create electrical contact, the electrode must be treated with sandpaper and covered with copper with electrolysis or wrapped with copper foil on one side.

In this way, I made electrodes with a diameter of up to 50 mm and up to 35 cm long. The maximum size depends only on your furnace. It makes no sense to make small electrodes. They are cheap and affordable. And large electrodes are expensive and rare.

As a replacement of charcoal, you can use activated charcoal, graphite powder from different sources, a powder of metallurgical coke is possible.

A coal tar is used as a binder in industry. But he is inaccessible. You can try to use wood tar. But sugar also does not work bad

As a resin, you can use a solution of any polymer convenient for you such as PVC, polystyrene. You can also use epoxy resin. You can even soak the electrode in molten polypropylene, but the process goes for a very long and technically not just to keep the molten polymer for many hours. You can also use home-made phenol -formaldehyde resin if you have components.

I checked made electrodes by a multimeter. They have a resistance less than 10 Ohms (3-8) with a point touch. When coating with copper and in liquid electrolyte, the resistance will be significantly lower

[Edited on 14-5-2023 by Hexabromobenzene]

mysteriusbhoice - 13-5-2023 at 17:08

graphite foil and carbon fiber sleaves actually lasts longer than dense graphite plates and is a good alternative.

This video below is an example of graphite foil being used for long periods.
https://www.youtube.com/watch?v=f5sY3rEAdes

Below is carbon fiber sleave electrode

carbon sleave.png - 376kB

[Edited on 14-5-2023 by mysteriusbhoice]

[Edited on 14-5-2023 by mysteriusbhoice]

Hexabromobenzene - 14-5-2023 at 14:17

Yes, but this need to buy it. My method allows you to make an electrode of any size and shape yourself. You only need charcoal, sugar, a simple furnace and a little garbage that can be found in a trash can

Jome - 15-5-2023 at 09:54

This sounds rather cool, I always expected the process to turn carbon decently conductive would require 2000+ K temperature.

mysteriusbhoice - 15-5-2023 at 17:50

Quote: Originally posted by Jome  
This sounds rather cool, I always expected the process to turn carbon decently conductive would require 2000+ K temperature.

Yea and its possible to do this DIY using a 12V car battery or rewound MOT.
Basically after you put it into the furnace you will then use 2 electrodes to pass 800 amps through the carbon electrode and this allows you to convert it into both graphite and conductive vitreous carbon. Note that conductive vitreous carbon if doped with boron can make perchlorate so an addition of trimethyl borate can help improve the quality of these electrodes.

NickBlackDIN - 16-5-2023 at 00:20

Edit: I'm an idiot lol

[Edited on 16-5-2023 by NickBlackDIN]

Hexabromobenzene - 16-5-2023 at 05:50

Quote: Originally posted by mysteriusbhoice  
Quote: Originally posted by Jome  
This sounds rather cool, I always expected the process to turn carbon decently conductive would require 2000+ K temperature.

Yea and its possible to do this DIY using a 12V car battery or rewound MOT.
Basically after you put it into the furnace you will then use 2 electrodes to pass 800 amps through the carbon electrode and this allows you to convert it into both graphite and conductive vitreous carbon. Note that conductive vitreous carbon if doped with boron can make perchlorate so an addition of trimethyl borate can help improve the quality of these electrodes.

Charcoal, heated to 1000-1100 degrees already conductive. Charcoal heated to 1200 have compatible conductivity with graphite. But you need close porous and protect him from destruction during elecrolysis. I think impregnate with epoxy or molten polypropylene best.

Soon i try alternative technology. I will carbonizate patcricleboard or mdf then impregnate with sugar and heating again to close porous and threat with varnish or something polymer

[Edited on 16-5-2023 by Hexabromobenzene]

mysteriusbhoice - 16-5-2023 at 16:58

The graphitization temperature is between 1900 and 2000C and hence the need for high current because allows the carbon to reach those temperatures briefly which graphitizes it.

metalresearcher - 17-5-2023 at 08:05

Interesting. Never tried, but I might try.

You probably mean an Acheson furnace which graphitizes the baked electrodes described here to real graphite at extremely hot temperatures of 3000 C, using the resistance of the electrodes.
Amateurs can do it if you indeed have a current source of 800 amps and a low voltage. Probably by embedding the electrode in sawdust and / or sugar and then sand around it. But the duration of graphitizing in large scale commercial Acheson furnaces can take days. In China they make large electrodes for electric arc furnaces this way.

mysteriusbhoice - 17-5-2023 at 19:17

you infact dont want full graphitization because some amorphous carbon can have catalytic properties when doped with boron which also makes it conductive and even catalytic giving a very high O2 evolution potential but idk if this mixed with graphite will be good for use in such cells or if it will last long. It only takes 800C to boron dope amorphous carbon into a conductive version by trimethyl borate or boric acid.

Hexabromobenzene - 18-5-2023 at 07:42

As i know charcoal is hard carbon. Its not grapitizate. But strong heat may increase conductivity. Not so far. Mainly conductivity increase occurs up to 1000 degrees.
If you need graphitizing carbon you can try PVC coke PET plastic coke or polycarbonate coke. Also phenol formaldehyde resin produces interesting material like glass carbon
https://en.wikipedia.org/wiki/Hard_carbon
https://en.wikipedia.org/wiki/Graphitizing_and_non-graphitiz...

[Edited on 18-5-2023 by Hexabromobenzene]

[Edited on 18-5-2023 by Hexabromobenzene]

mysteriusbhoice - 18-5-2023 at 17:18

yea and boron doping may increase catalytic activity up to perchlorate forming potential like BDD electrodes.

Hexabromobenzene - 21-5-2023 at 19:03

For the preparation of electrodes, a denser coal was tested. It was made from laminated MDF fiberboard from the floor.
The board was broken and placed in a closed tin can, which was placed in a wood-fired furnace. After pyrolysis, coal takes up less volume than the original board, unlike pure wood. Next, the coal was ground in a coffee grinder and, according to proven technology, baked with sugar at 900. The electrode turned out to be noticeably denser than charcoal electrodes. However, it is still porous due to sugar, which, boils during pyrolysis. One of the electrodes had a high resistance on one side (up to 70 ohms), when an ideally baked electrode in a furnace has a resistance of about 3 ohms, regardless of the place where the multimeter probes are applied. He was badly calcined on one side.
Initially, poorly conducting coal was taken from fiberboard, which was pyrolysed at no more than 700 degrees, in contrast to the partial combustion of charcoal at 1000-1100. This created some problems.

The length of the electrode was 27 cm diameter 30mm. Large electrode diameter 40mm
To eliminate this defects, the electrode will be impregnated with sugar and calcined again. Repeated baking with sugar impregnation makes the electrode denser and reduces the number of defects.

Fiberboard coal was denser than charcoal. I think the ideal coal for baking is phenol-formaldehyde resin char(for example bakelite products) or calcined anthracite
Charcoal electrodes are very porous. They can probably be used for catalytic electrosynthesis, but they are not very good for high current density electrolysis. Also, all carbon electrodes need to be impregnated with a polymer.

[Edited on 22-5-2023 by Hexabromobenzene]

[Edited on 22-5-2023 by Hexabromobenzene]

metalresearcher - 24-5-2023 at 00:40

@C6Br6: Good idea.
I want to try it out baking with sugar, I don't need them for KClO3 / KClO4 electrolysis as I already have both MMO and platinized Ti anodes which work well.
But I use carbon electrodes for arc melting or making CaC2 and other extremely high temperature applications using a DC welder. Yes I can purchase these carbon rods online, but would like to make them myself on own size and shape.
So I can use crushed particle board waste and bake it with sugar to 1100 C ?


Ubya - 24-5-2023 at 03:37

If coal tar is unavailable, what about bitumen/asphalt? Vacuum impregnation of hot thin bitumen could solve for the added porosity caused by the sugar?

Hexabromobenzene - 24-5-2023 at 14:26

The electrodes were saturated with sugar syrup and again in the furnace. They became better. Now the electrodes are close to the reference resistance from 3 Ohms to 10 Ohms. Satisfactorily
Porous electrode made of charcoal can be used for electrocatalytic hydration covering it with nickel galvanically


metalresearcher, Ubya

Grinding the fiberboard is difficult. I first made char from mdf and then char grinded and baked with sugar
This is probably the denser available coal. Only anthracite is even denser. It must also be pre -calcined for electrical conductivity. But I do not have anthracite at the moment. Previously, anthracite uses as fuel for heating and it was lying a lot on the ground near the roads and on the landfills of old cities.
Electrodes made of charcoal and sugar burn in the furnace when air access to electrode if you poorly isolated a steel container. They burn much more slowly than charcoal, but faster than graphite. You also probably will have to cover them with galvanically copper for electrical conductivity

Bitumen will also work, but I don’t have bitumen at the moment with it is more difficult to work with it than sugar. It must be heated or diluted with a solvent. I poured the roof with bitumen for a long time in my house
Probably, instead of bitumen, you can use heavy fractions of oil from pyrolysis of wood and various plastics

The baking form is also important. I usually use a cardboard pipe into which a baking mixture is pressed. The cardboard form is wrapped with a sheet of iron from a canning can and placed in furnace. But you can press a mixture without paper or cardboard in a steel container. I recommend using aerosol cylinders. Metal from cans and aerosol cylinders after baking oxidizes and crumble. But he performs his protective function at least 1 time. And you can find a lot of aerosol cylinders

Hexabromobenzene - 24-5-2023 at 15:35

Here is a graph of the conductivity of carbon from fiberboard as a function of temperature. For charcoal and other coals, it is similar

See more here:
https://www.academia.edu/48186506/Evaluation_of_carbonized_m...

carbnz.jpg - 25kB

Hexabromobenzene - 16-6-2023 at 07:57

I also conducted experiments on the manufacture of carbon electrodes. This time I tried catalytic graphics. Hard carbon is catalytically graphitized in the presence of iron compounds.
I mixed coal from MDF with a solution of iron chloride (from rust from the old pipe) 1 to 10 by weight and dried it . Further, the carbon electrode was made using ordinary technology with sugar
The results are as follows. Not noticeable changes in mechanical strength were not noticed. Electrical conductivity increased slightly but weakly. However, the appearance has become different. The electrode has become black, matte and a little brilliant. He stopped dusting and getting his hands dirty with black mud and also significantly became more resistant to burning probably due to the loss of the microporous structure. The electrode also has noticeably more defects due to the decomposition of iron chloride. One electrode even broke in half. It is probably better to add another catalyst, which, when decomposed, does not emit gases or graphite the coal mass before sintering with sugar. You can also remove iron oxide particles with hydrochloric acid
I do not know how this electrode will show itself in electrolysis, but in my opinion, catalytic graphitization makes sense for electrodes for electric arc furnaces due to more better burning resistance.

In the manufacture of carbon electrode there are several important rules:
You must use the MINIMUM amount of sugar syrup, sugar syrup should be as MAXIMUM CONCENTRATION as possible. You must CORRECTLY PRESS the coal mass with sugar. It is necessary to press the piston with the diameter of the paper sleeve with significant force. You can’t press everything at once. Add the coal mass in small portions. The carbon electrode after calcining has poor mechanical strength. However, after IMPREGNATION with polymer, it becomes a STRONG COMPOSITE MATERIAL

In the following posts I will publish testing these electrodes in an electrolyzer

You can read an article about catalytic graphitization here
https://pubs.rsc.org/en/content/articlelanding/2022/ta/d1ta0...

mysteriusbhoice - 16-6-2023 at 18:26

add maybe SnO2 but it may reduce to tin in that environment sadly. Pb salts are another option as it forms PbO2 when anodized. Antimony and bismuth may help also.

Sulaiman - 16-6-2023 at 20:09

I love experimentation, it's why I'm on SM,
presently there is massive investment in carbon materials,
relative to this discussion are electrodes for
arc furnaces, EDM, batteries and electrolysis.
So, great as an experiment,
but probably no so useful or cheap as using or modifying commercial electrodes.

For no particular reason other than curiosity stimulated by this thread
I bought a couple of sheets (100x100x2 mm) of graphite
manufactured for use as Edm electrodes.
I believe isotropic, sawn from a large block. they are:
. Cheap (usd 4.27 for two w/p&p)
. Hard (the sheets 'ring' at c600 Hz when flicked with a fingernail)
. Highly conductive (I had to check my meter because I didn't believe the measurement)
. High current capacity (designed for EDM 'roughing' at 5 to 25 A/cm2)

For (my) amateur purposes
where high temperatures and pressures are inconvenient
it may be best to design around existing shapes,
or carve a block to the required shapes.

I now want to look at boron (or similar) surface treatment.

Hexabromobenzene - 17-6-2023 at 08:32

Lead salts under these conditions form lead. During electrolysis, it forms lead dioxide. But I do not think that such an electrode will be reliable. Iron salts are needed for catalytic graphitization. However, I do not see the obvious advantages of these graphitized electrodes over hard carbon electrodes for electrolysis. For an electric arc furnace, they have the advantage of burning much more slowly.

To make carbon electrodes, I use a wood-burning furnace for heating. Furnace gives temperatures up to 1000 degrees. It takes me 5 kg of firewood to prepare the electrodes

[Edited on 17-6-2023 by Hexabromobenzene]

Hexabromobenzene - 20-10-2023 at 10:28

Experiments with homemade carbon electrodes have been completed. Here is the information that was obtained during the experiments

The manufacture of a carbon electrode consists of 3 stages
1. Obtaining conductive carbon
2. Sintering of carbon powder with a binder containing carbon
3. Impregnation of the electrode with various substances



To obtain conductive carbon, we need carbon raw materials. As experiments have shown, the best raw materials are hardboard or laminate flooring. The ideal raw material is phenol-formaldehyde resin. Carbon from it is the densest. However, it is difficult to find sufficient quantities of phenol formaldehyde resin and it is usually contaminated with fillers. Charcoal has high porosity and is not very dense and is also difficult to heat in a furnace to a conductive state due to the thickness of the pieces.
First we must carboniazte our feedstock. Usually this is hardboard. It must be calcined in a closed container in an oven until complete carbonization and removal of volatile substances.

Once we have carbon, there are 2 ways to make it conductive. They are all associated with high fever
The first method is partial combustion in an air stream in any furnace. During the combustion process, carbon heats up to 1200-1300 degrees, which is enough to make it conductive after holding it for about a minute. The carbon must then be quickly extinguished. I don't recommend using water. It is extremely difficult to remove from carbon without repeated calcination. Carbon can be easily extinguished by placing it in a steel container and covering it with a lid. Carbon from hardboard is especially convenient for this method since it has the shape of thin plates and is heated completely, unlike charcoal.
This method allows you to obtain pure conductive carbon without impurities and without the use of additional reagents. However, the partial combustion process can burn up to half its weight in carbon.

The second method is catalytic graphitization. Heating to high temperatures promotes the growth of graphite nanostructures in carbon and increases its conductivity. It grows quickly up to 1000 degrees and then increases about 3 times from 1000 to 1400 degrees. During catalytic graphitization, carbon is impregnated with a soluble iron compound of 1 to 10 to 1 to 30 by weight. Iron also promotes the growth of graphite nanostructures, but at 900 degrees its conductivity is the same as at 1400 degrees for ordinary carbon. With a further increase in temperature, the conductivity does not increase. Typically, carbon is ground and mixed with an iron salt such as chloride and the powder is calcined in a closed container in an oven at 900 degrees.
This method has a significant drawback. Carbon is contaminated with iron. For some syntheses this is unacceptable. Acid leaching does not completely remove iron and requires careful drying before sintering.

Carbon pieces can be tested for conductivity with a multimeter. Ideal carbon shows a resistance of about 3 ohms. To make electrodes, it is permissible to use carbon with a resistance of up to 10-20 ohms.
Ideally calcined carbon up to 1400 degrees has 3 times greater resistance than pure graphite.

2 Sintering
After we have received the conductive carbon powder for making an electrode, it must be mixed with any chemical compound capable of significant carbonization and calcined in a furnace, protected from exposure to air.
I used sugar as the most accessible substance. But it should probably be replaced with something

Sugar has disadvantages. It requires water to dissolve. Water during carbon sintering can lead to cracks and even breakage of the electrode. Therefore, sugar syrup should be as concentrated as possible. 1 to 4 water sugar by weight approximately. Sugar dissolves completely when heated, but you must have time to press the carbon mass with sugar syrup before cooling. The amount of sugar syrup should be MINIMUM to prevent cracking. The ratio of dry sugar to carbon powder is usually approximately 1 to 1 for optimal wetting. You also have to press the carbon powder into the mold with SIGNIFICANT FORCE. I pressed my hands with a wooden piston with a force of about 30-50 kg with impacts on an electrode with a diameter of about 2.5 cm, which corresponds to a range of about 1 megapascal. According to studies, electrical conductivity increases during pressing to 2 megapascals. Pressing also increases the mechanical strength of the finished electrode. I used cardboard tubes as a mold for pressing. After sintering, they become carbonized and are easily separated from the electrode. The cardboard tube must be covered on one side with paper.
After the carbon powder is pressed into the mold, it must be calcined. The mold with the mixture must be placed in a steel container to protect it from combustion. I recommend thin metal from aerosol cans and cans. It is enough for 1-2 firings. The container with the mold must be placed in an already preheated oven to quickly carbonate the sugar.

After cleaning from paper residues, a properly prepared electrode should not have cracks, be straight and have a smooth surface. This result is not easy to achieve.

3 Electrode impregnation and current supply

If you want to use an electrode for the electrolysis of aqueous solutions, it must be impregnated with some kind of organic substance. The simplest option is paraffin or linseed oil. But it is better to impregnate with resin. Epoxy resin would probably be the best option. I used alkyd resin from old paint whose filler had precipitated. The electrode must be soaked until it stops absorbing liquid. You'll be surprised how much they can absorb. After the resin hardens, the electrode turns into a durable composite material similar to industrial carbon electrodes.

In order to ensure contact with the electrode, it may be coated with copper, wrapped with copper wire and the contact coated again with copper. A more affordable option is to wrap it with copper foil, but such contact will have greater resistance. The current lead can also be placed inside the electrode during sintering.

Hexabromobenzene - 4-1-2024 at 18:00

I also conducted experiments with the production of carbon electrodes.
The main problem from the electrodes of sugar and charcoal is that they are similar to foam in structure. Repeated sugar impregnation and heating does not solve this problem. This operation increases the strength of the electrode, reduces porosity, corrects defects

To obtain monolithic carbon, you need thermosetting polymer. It's IMPORTANT.
I saturated the electrodes with an old alkyd paint, which had a filler out to the bottom. Once I decided to burn him for an experiment in the furnace. Oh miracle! I received a monolithic hard piece of carbon, which does not scratch with a fingernail. You can use epoxy resin. I used the old alkyd paint since it was free. To save resin, you can make an electrode of char from laminate or phenol -formaldehyde resin. It is less porous and you need less resin to impregnate your product. You can also impregnate your electrode several times with sugar and burn it. This will increase the strength of the carbon frame and reduce porosity
Thus, you can make the glass -hot electrode itself.

You can also make graphite from the glass carbon electrode. I wrote about catalytic graphitization. However, during the experiments it was found that an iron catalyst can only be used once. Therefore, you need to soak the finished glass -carbon electrode with iron salt and burn it

Catalytic graphite of more resistant to combustion and probably to electrolysis, but graphite is difficult to eliminate iron residues after heating

Thus, having a simple wood furnace, you can make glass carbon and graphite electrodes of any shape and large sizes.

RU_KLO - 23-1-2024 at 09:09

Can Li-ion battery graphite be used, instead of "conductive carbon"? (I have a lot -like a kg - from disasemblng Li ion batteries
Of course it will be very contaminated.
I can boil it 1hr with water, then HCl boiling / washes to try to remove as most contamination as possible.

how do you meassure "first" resistance (before making the electrode).
I have a powder.
You add it to a cardboard or plastic tube, compress it and then meassure resistance?

Hexabromobenzene - 24-1-2024 at 05:33

If you have a lot of graphite, you can use it. The task of the first baking to form an electrical conductive carbon matrix. It can be used as an electrode after impregnation. But for better stability, the electrode must be impregnated with thermosetting resin(epoxy, polyurethane and other) and baked again

I usually measure the resistance of pieces of wood coal from the furnace before grinding into dust. You can also measure the resistance of the electrode after baking

A cardboard pipe is a form for the electrode. You press carbon powder with sugar into it. I did it with the help of a large wooden piston. If you use the jack, you can achieve better results

P.S I did not use a plastic tube and I do not know if it is suitable for baking. If you do not have a cardboard tube, you can turn any newspaper or better the magazine into the tube and use tape to fix the form. Use pressed paper like a plug

After baking with sugar, conductivity may fall due to sugar coal isolates the conductive carbon. You probably need to bake the final electrode up to 1000 degrees

[Edited on 24-1-2024 by Hexabromobenzene]

Hexabromobenzene - 18-2-2024 at 21:35

I conducted several more experiments with electrodes with saturated polyurethane varnishes and alkyd. After pyrolysis, all of them become and sound like ceramic with a weak blow. The impregnation of thermoreactive resin turns them into a semblance of glassy carbon. Theoretically, you can bake a mixture of coal with thermorectative resin without sugar. However, thermoreactive resins are prone to cracking when heated. It is probably better to bake carbon foam from coal powder and sugar, but only then soak it with thermoreactive resin. This resembles a reinforcement of epoxy fiberglass

The more affordable composition of sugar and phosphate ammonium was founded. This glue forms a crosslinked polymer and gives 2 times more carbon than with sugar pyrolysis


[Edited on 19-2-2024 by Hexabromobenzene]

Hexabromobenzene - 8-4-2024 at 13:26

I found a cheaper and effective replacement of binder sugar for the production of carbon electrodes!
Sugar forms only 20% carbon for pyrolysis, which is very small. Also, carbon foam from sugar has small strength
I recently found information on sugar-amino adhesives. The simplest diammonium sugar phosphate 80 20. This glue, unlike sugar, forms a crosslinked polymer and gives up to 60% carbon for pyrolysis. However, a large amount of phosphorus will be a problem when baking the carbon electrode
https://www.ncbi.nlm.nih.gov/pmc/articles/PMC6960737/

More recently, I invented my binder for electrodes based on wheat flour:

150 grams of wheat flour, 200 ml of water and 30ml 15% hydrochloric acid is mixed and heats up in a boiling water bath 10 hours .Gluten reacts with sugar in an acidic medium with the formation of soluble amino products.
During pyrolysis, this glue behaves differently than sugar or molasses made of starch. First, the excess of glucose decomposes. Then there is a reaction between sugar and dissolved protein with the formation of a crosslinked polymer, which is charred (the smell differs from the smell of burnt sugar). The result is much more carbon than from the clean sugars and it has greater mechanical strength.

For the manufacture of carbon electrodes, I recommend using this glue. However, with it will not be possible to make a whole piece of carbon without pores. To do this, you need a polymer that is become solid at a ROOM TEMPERATURE to avoid the formation of gas bubbles.


[Edited on 8-4-2024 by Hexabromobenzene]

Hexabromobenzene - 19-4-2024 at 20:07

I experienced another binder for carbon electrodes. This time from oatmeal.
900 grams of oatmeal 1.5 liters of water and 120 ml of 15% hydrochloric acid were mixed and heat about 1 day at 90-100 degrees. The resulting liquid smells like apples and cinnamon
During filtering, it was lost up to half the solution. This is probably due to cellulose . When using wheat flour, filtration is not required

The carbonization of this solution showed that it forms significant amounts of carbon (possibly more than from wheat flour) more strong than from sugar. Unlike the binder from wheat flour during carbonization, there was no smell of burnt sugar.
This means that all glucose reacted with proteins. Wheat flour contains 80% starch and 10% protein. Oatmeal contain 70% starch and 13% protein
Probably in oatmeal, the ratio of carbohydrates and proteins closer to the stichiometric

Definitely sugar-amine binder is better than sugar for the manufacture of carbon electrodes

[Edited on 20-4-2024 by Hexabromobenzene]

[Edited on 20-4-2024 by Hexabromobenzene]

Hexabromobenzene - 21-4-2024 at 15:13

Another binder for carbon electrodes was prepared. Gluten was extracted from 1200 grams of wheat flour using water and added to 700 grams of flour. 1000 ml of water and 100 ml of 15% hydrochloric acid were added to the gluten and flour mixture
The mixture was also heated to 90-100 degrees for 1 day. When carbonation, there was no burnt sugar smell like a binder without gluten addition flour.
The carbon produced from this binder is different from the previous one. It is less foam-like and harder than the previous 2

Conclusion: for a more complete reaction with sugars in flour, 2-3 times more protein is required than what was initially in the flour.
Bran contains a suitable ratio of proteins and sugars. There are also a lot of pentoses, which quickly form addition products with amino acids
However, lignin and cellulose residues create problems during filtration

Many strong odors are observed during the preparation of binders. Sometimes it looks like cinnamon, sometimes like parquet varnish or chipboard glue.
These are probably reaction products of Maillard reaction and similar

[Edited on 21-4-2024 by Hexabromobenzene]

Hexabromobenzene - 1-5-2024 at 09:29

After a few more experiments, I finally understood how the binder from flour works.

After filtering of flour glue, the quality of carbon after carbonization drops sharply. The amount of carbon remains higher than after a carbonization of sugar and it is stronger. However, carbon precipitation obtained from non filtered binding from flour is very homogeneous.

A binder of whole grain flour was made. It was very viscous because of a large amount unhydrolyzed flour

So after the flour hydrolysis in the solution, the gluten suspension remains, which crosslinks sugar at a pyrolysis temperature. Therefore, it is necessary

If, during pyrolysis, the binder is pressed with a sheet of metal, then a dense carbon precipitate is obtained. I expect that electrodes of excellent quality will be made of wheat flour binder. Much better than sugar. The solution after filtering is suitable for use for impregnation of the electrode

Hexabromobenzene - 29-6-2024 at 19:21

I made a new binder. This time I used bones extract or gelatin . 1 to 4 to sugar in weight and a little acid. This composition forms a compact layer of carbon with good shrinkage. I think this is the best option.
You can use any water -soluble organic amino acid

Is the this theme interesting to anyone?

Sulaiman - 29-6-2024 at 21:23

Quote: Originally posted by Hexabromobenzene  
Is the this theme interesting to anyone?
I'm interested enough to follow your progress,
but not enough to try myself.

As you are investigating primarily the fabrication of electrodes,
I think that you need to have a measure of electrode durability in electrolysis duty.
eg amp.hours per square centimeter.

Hardness and conductivity are good,
and probably good indicators of potential performance as an anode,
but how long will each composition survive use as an electrode?

Alkoholvergiftung - 30-6-2024 at 00:09

Interesting Artikel how the old Bunsen elements made there Carbon Anode.
https://dingler.bbaw.de/articles/ar156073.html#:~:text=Bunse...

Hexabromobenzene - 30-6-2024 at 01:03

When I will have time, I will check the electrodes. In any case, they will work at least a day

I wrote about sugar many times. This is a bad binder. Electrodes crumble from it. This can be corrected by impregnating the workpiece of epoxy or other resin and then burn it, but it is expensive

Sugar forms 20% carbon during carbonization. Sugar-amino binders up to 50-60 and this carbon is solid and durable. This is more affordable and safer than phenol-formaldehyde resin

[Edited on 30-6-2024 by Hexabromobenzene]

Alkoholvergiftung - 30-6-2024 at 01:56

Thats why later down they used Tar as binder because lot of more carbon

EF2000 - 30-6-2024 at 12:25

Quote: Originally posted by Hexabromobenzene  

Is the this theme interesting to anyone?

I find your work very interesting. It's an easy and affordable method to produce decent pyrolytical carbon from something as mundane as oatmeal or gelatine. It can find other applications than electrodes. For example, nozzle inserts in rocket motors.

Have you measured the density of produced carbon? How hard it to scratch?

Hexabromobenzene - 30-6-2024 at 15:06

The workpiece obtained by baking charcoal with sugar is scratched with a fingernail. When impregnating with alkyd resin and carbonization, electrode can no longer be scratched with a fingernail. It also becomes ringing as ceramics with a slight blow

I have not made electrodes from the new binder yet. However, the remains after carbonization on the electric stove are very strong. Especially a strong last composition. Its adhesion is very strong both to metal and glass. It forms a very dense layer. The remains after heating of last composition on the glass surface I could not separate without damaging the glass. It can only be separated by a metal tool from the metal. Carbonization sugar forms a very soft foam

The density of the coal obtained is comparable with water. However, it depends on the size of the coal powder, binder and the number of impregnations


[Edited on 30-6-2024 by Hexabromobenzene]

Hexabromobenzene - 30-6-2024 at 15:29

Here is the full preparation of the last binder.
Starch was extracted from 2.5 kilograms of flour using water. After the starch at the bottom formed layer, the water was separated and 50 ml of 18% hydrochloric acid was added to the resulting starch suspension. The suspension was heated for 8 hours at 100 degrees to the full hydrolysis of starch.
Then about 300 grams of bone glue were added to the suspension and heating lasted another 5 hours

The quality char from the composition was not exellent. Then another 600 grams of bone glue and 70 grams of old amino acid creatine were added to the mixture. Another 20 ml of hydrochloric acid and hydrozysate prepared from 1.5 kg of starch were added. The mixture was heated at 90 degrees 4 hours. After the synthesis, the binder smells like soy sauce

Hexabromobenzene - 30-6-2024 at 16:29

Also, do not forget that adding only 1-2% iron by weight to fixed carbon leads to the formation of graphite, which is more resistant to combustion, for example. However, it will be difficult for you to remove the iron later
You can add any soluble iron salt to the binder
https://www.researchgate.net/publication/272274928_Study_on_...

Hexabromobenzene - 13-9-2024 at 12:37

The sugar-amine binder should form strong, compact, shiny carbon deposits when calcinated. If there is too much amine or sugar, the deposit will be foamy. You have to find the right ratio. For molasses and bone glue, it is 1 to 3 by weight, respectively. Molasses produces carbon deposits worse than sugar, probably because of the oligomers, but it is cheaper.

Examples of good deposits

[Edited on 13-9-2024 by Hexabromobenzene]

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Hexabromobenzene - 30-9-2024 at 15:32

Results of preliminary electrochemical tests of carbon electrodes. Current in a strong salt solution is 10 mA versus 300 mA with 2 metal electrodes and 2 AA batteries as a current source
I recommend treating the results with caution. Electrical contact was made by touching a copper wire. At a voltage of 1.5 (1 battery), the current drops to 1 mA. Perhaps the electrodes need to be galvanically coated with copper. Electrodes made of catalytic graphite (iron salts) may be better


Photo of electrodes made of carbon from HDF floor laminate board. Lithium batteries 18650 for comparison. As you can see, one electrode partially burned during baking due to the lack of protection(iron sheet) in this place. The catalytic graphite electrode is significantly more resistant to combustion

Sugar was used as a binding agent (with sugar-amine binder will be much better) and impregnation of alkyd varnish.

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Of course it's interesting !

jam_kemist - 26-10-2024 at 02:47

Quote: Originally posted by Hexabromobenzene  
I made a new binder. This time I used bones extract or gelatin . 1 to 4 to sugar in weight and a little acid. This composition forms a compact layer of carbon with good shrinkage. I think this is the best option.
You can use any water -soluble organic amino acid

Is the this theme interesting to anyone?


Just wanna say that I'm very interested but I don't really have much time to experiment myself,
I made a video on this subject but before you posted about this new binder, so I used sugar and of course, the results were poor.

metalresearcher - 26-10-2024 at 09:46

Does such baking of electrodes not require an Acheson furnace ?
Such a furnace heats baked carbon rods (like TO makes using HDF powder bound with sugar) to 3000 C under a bed of sand using the resistance of the electrode ?
Maybe with a low voltage, high current transformer (a 300A welder, or better a transformer delivering 2-3V and hunderds of A) it can be done by amateurs.

Hexabromobenzene - 27-10-2024 at 10:34

So, after many experiments with the ratio of sugar and amine, I understood how it works
When pure sugar decomposes, you have a soft carbon foam. If you add a little amine, the foam will become stronger. With an optimal ratio, you get compact residue. If there is too much amine, you get foam, but hard.

Sugar with any amine forms a complex polymer - melanoidin. Excess sugar is important. It forms carbon foam, on which solid carbon from melanoidin grows and is also a solvent for the reaction. If your binder consists of pure melanoidin, then due to the large amount of sediment, the mass foams significantly.

Quote: Originally posted by metalresearcher  
Does such baking of electrodes not require an Acheson furnace ?
Such a furnace heats baked carbon rods (like TO makes using HDF powder bound with sugar) to 3000 C under a bed of sand using the resistance of the electrode ?
Maybe with a low voltage, high current transformer (a 300A welder, or better a transformer delivering 2-3V and hunderds of A) it can be done by amateurs.


I use a wood stove for heating. Fiberboard is used to make charcoal because charcoal from HDF is several times denser and requires less binder.
A transformer would be useful for the final baking of the electrode AFTER carbonization. For example, you can make a furnace from a steel pipe wrapped in fiberglass
You don't need temperatures of 3000 degrees. You will never be able to graphitize hard carbon. And catalytic graphitization occurs at 900 degrees. 1100 degrees is enough

[Edited on 27-10-2024 by Hexabromobenzene]

Hexabromobenzene - 27-10-2024 at 11:21

I also recommend adding a larger coal fraction to the baking mixture. This prevents cracks

It probably works as adding stones to concrete

Hexabromobenzene - 28-10-2024 at 04:59

A broken piece of carbon electrode from fiberboard charcoal and sugar as a binder. After baking, the electrode was impregnated with alkyd resin, dried and baked again. It became hard and sounds like ceramics when struck. Before re-baking with alkyd resin, it was scratched with a fingernail

As you can see, even an electrode made of a binder such as sugar can be corrected by impregnation with thermosetting resin. A similar process occurs when baking a sugar-amine binder. Carbon from furan polymers and melanoidins stabilizes the carbon foam from sugar

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[Edited on 28-10-2024 by Hexabromobenzene]

Hexabromobenzene - 27-11-2024 at 07:51

Electrode test in a 10-15% salt solution. Voltage 12V current to 1.5A. The electrode is impregnated with alkyd resin. The place of contact heated significantly, but in any case, such electrodes have conductivity less than graphite and require copper coating. Maybe electrodes made of catalytic graphite (with iron salts) will show better results

I also probably found replacement varnishes for impregnation. Polyethylene and polypropylene soluble in a paraffin overheated higher melting point than plastic. This solution probably will be an excellent varnish for electrodes

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