Primitive Technology: Geopolymer Cement (Ash and Clay)
Summary
TLDRThis video script details a unique and traditional process of creating cement using wood ash. It begins with making fire by friction at a brick hut, where wood is burned for ash, which also aids in drying bricks. The wood ash is then sifted to remove charcoal, mixed with water to form a paste, and shaped into pellets or clinkers. A single pellet is set aside to air dry, while the rest are calcined in a forge until they glow red hot. The calcined ash is then mixed with water and shaped into a cube without any aggregate. Subsequently, aggregate is created from crushed old bricks or pottery, and various ratios of ash to fired clay are tested to determine the optimal mixture for strength and cohesion. The video also explores the use of uncalcined and calcined ash, demonstrating that only ash subjected to high heat is suitable for cement. Experiments with different materials, such as sand, are conducted, and the process is refined to produce a fast-setting geopolymer cement using the leftover ash from previous firings. The video concludes with the successful water resistance test of the samples, showcasing the potential of this method for creating sustainable and efficient building materials.
Takeaways
- 🔥 The process begins with making fire by friction, which is used to burn wood for ash, also serving the dual purpose of drying bricks.
- 🏚 The wood ash is collected and sifted to remove charcoal, then mixed with water to form a paste, which is later formed into pellets or clinkers for firing.
- ⚗️ An uncalcined pellet is set aside to air dry, while the rest are calcined in a forge, requiring the pellets to glow red hot for proper calcination.
- 🧱 To create cement, the calcined pellets are mixed with water again and molded into shape, specifically a cube of calcined ash without aggregate.
- 👷♂️ Aggregate is made from crushed old bricks or pottery, with varying ratios of ash to fired clay tested for structural integrity.
- 🌟 A key observation is that only ash that has been very hot (calcined) is suitable for making cement, as demonstrated by a dissolving resistance test.
- 🔨 An experiment with a grate for a furnace is described, where the ash is used to make a cylindrical clinker, which is then fired using natural draft for efficiency.
- 📈 The experiment shows that using sand instead of fired clay in a 1:3 ratio with ash produces a slightly weaker but still viable cement.
- ⏱️ A fast-setting geopolymer cement is developed, with a sample surviving a 24-hour water test after only 6 hours of setting.
- 🔄 The potential for using the leftover ash from previous firings without further calcination is explored, suggesting a sustainable and efficient method.
- 🏗️ The script concludes by emphasizing the need for more experiments to scale up the process and determine the types of structures that can be created with this method.
Q & A
What is the primary purpose of burning wood in the brick making hut?
-The primary purpose of burning wood in the brick making hut is to create ash, which is used to make cement, and also to dry the bricks.
How is the wood ash processed before it can be used for making cement?
-The wood ash is sifted to remove most of the charcoal, then mixed with water to form a paste, which is subsequently formed into pellets or clinkers to be fired.
What is the significance of calcining the ash pellets in the forge?
-Calcining the ash pellets is crucial as it heats them to a high temperature, which is necessary for the ash to be suitable for making cement. Only ash that gets very hot is considered suitable.
How does the uncalcined pellet differ from the calcined block in terms of appearance?
-The uncalcined pellet has a dull surface, while the calcined block has a glossy surface, indicating the transformation that occurs during the calcination process.
What is the role of aggregate in the cement mixture?
-Aggregate, such as crushed old bricks or pottery, is mixed with the ash to improve the structural integrity of the cement. Different ratios of ash to fired clay are experimented with to find the optimal balance.
Why is the uncalcined ash pellet less suitable for cement compared to the calcined ash?
-The uncalcined ash pellet dissolves when put in water for a dissolving resistance test, indicating it is not suitable for cement. In contrast, all samples that used calcined ash survived the test, showing their suitability.
How does the process of making a grate for a furnace contribute to the efficiency of the firing process?
-The grate allows for better airflow and a more efficient, hotter burn compared to a fire on the ground. It also simplifies the process by using natural draft without the need for a blower.
What is the significance of the 1:3 ratio of ash to sand or fired clay in the cement mixture?
-The 1:3 ratio is found to be effective in creating a cement mixture that can survive a water test after 24 hours. It represents a balance between the binding properties of the ash and the structural integrity provided by the sand or fired clay.
What is the advantage of using ash left over from the previous firing in the next batch?
-The leftover ash is assumed to have been sufficiently heated during the previous firing, eliminating the need for further calcination. This could simplify the process and save time and energy.
How does the experiment with different shapes of the same material affect the outcome?
-Different shapes of the same material (ash and fired clay mixture) are tested to see if the shape has any impact on the performance of the cement. The results indicate that the material composition is more critical than the shape for the cement's effectiveness.
What is the key takeaway from the experiment with the fast-setting geopolymer cement?
-The key takeaway is the discovery of a simple method for producing a fast-setting geopolymer cement using a 1:1 ratio of ash to fired clay, which can survive in water after only 6 hours of setting, suggesting potential for rapid construction applications.
What is the next step proposed after these experiments?
-The next step proposed is to conduct more experiments to scale up the process and explore what structures can be made using this method of producing cement.
Outlines
🔥 Brick Making and Ash Processing
The video begins with the process of making bricks, starting with creating fire by friction at the brick making hut. Wood is burned to produce ash, which is then used for both drying bricks and as a primary material. The ash is sifted to remove charcoal, mixed with water to form a paste, and then shaped into pellets or clinkers for firing. One pellet is set aside to air dry, while the rest are calcined in a forge. The calcination process requires the pellets to glow red hot. Subsequently, the calcined pellets are mixed with water and shaped into a cube without aggregate. Old bricks or pottery are crushed to create an aggregate, mixed with ash in various ratios (1:1, 1:2, 1:3), with a 1:4 ratio proving insufficient for cohesion. The difference in surface texture between uncalcined and calcined pellets is highlighted, with the uncalcined pellet having a dull surface.
🧪 Cement Testing and Furnace Construction
The video continues with a series of tests to determine the dissolving resistance of the ash-based cement. A week of curing is followed by a water test, where it's observed that only the calcined ash samples survive, indicating that high heat is necessary for a suitable cement. The presenter then proceeds to make a grate for a furnace, which is used to sift ash of charcoal and form a cylindrical clinker. The clinker is placed on the grate within the furnace, which is then stacked with wood and lit from the top for a more efficient burn. The process is designed to use natural draft rather than a blower, to simplify and reduce labor. The furnace is sealed with mud, and the clinker is calcined. After calcination, the clinker is crushed and mixed with sand and fired clay in a 1:3 ratio, and the different samples are tested for water resistance after 2 days.
🏗️ Fast Setting Geopolymer Cement Experiment
The final part of the video focuses on further experimentation with the geopolymer cement. Using the ash leftover from the previous firing without additional calcination, a 1:3 ratio of ash to fired clay is tested. When it doesn't stick well, more ash is added to reach a 1:1 ratio. This new mixture is subjected to a water test after only 6 hours and surprisingly survives for 24 hours. This discovery leads to the conclusion of a simple method for producing a fast-setting geopolymer cement. The video ends with a note on the need for more experiments to scale up the process and explore the potential for constructing various structures with this innovative material.
Mindmap
Keywords
💡Friction
💡Wood Ash
💡Calcination
💡Aggregate
💡Curing
💡Dissolution Resistance
💡Geopolymer Cement
💡Natural Draft
💡Furnace
💡Sintering
💡Ratio
Highlights
Making fire by friction at the brick making hut is the initial step in the process.
Wood is burned for ash, which serves a dual purpose of drying bricks and providing ash for cement.
Wood ash is sifted to remove most of the charcoal before use.
Ash is mixed with water to form a paste, which is then shaped into pellets or clinkers for firing.
One ash pellet is set aside to air dry, while the rest are calcined in a forge.
Calcination of pellets requires them to glow red hot for proper processing.
Cement is formed by mixing calcined pellets with water and shaping them into cubes without aggregate.
Aggregate for cement is made from crushed old, broken bricks or pottery.
Different ratios of ash to fired clay are experimented with, from 1:1 to 1:4.
Uncalcined pellets have a dull surface, while calcined blocks have a glossy surface.
A week-long curing process is implemented before a dissolving resistance test in water.
Only calcined ash that gets very hot is suitable for making cement.
A grate is made for the furnace to simplify the process and save labor.
Firing the clinker in the furnace uses natural draft, eliminating the need for a blower.
The furnace is modified for better natural draft by raising its height and sealing joints with mud.
Burning wood on a grate is more efficient and reaches higher temperatures than a ground fire.
Experiments with different materials show that a 1:3 ratio of ash to sand or fired clay works well.
A sand sample is slightly weaker and more easily scratched compared to others.
Using ash from the previous firing, which requires no further heat treatment, results in a fast-setting geopolymer cement.
A simple method for producing a fast-setting geopolymer cement with a 1:1 ratio of ash to fired clay is discovered.
Further experiments are needed to scale up the process and determine what structures can be created.
Transcripts
At the brick making hut
Making fire by friction
Wood is burnt for ash (also drying bricks)
The wood ash
To the brick hut
The ash is sifted to get most of the charcoal out
Water is mixed with the ash to form a paste
The ash is formed into pellets or clinkers to be fired
one pellet is set aside to air dry only
The rest of the pellets are calcined in the forge
One by one the pellets are burnt with wood in the forge
The pellets must glow red hot for them to be properly calcined
To form the cement, the pellets are mixed with water again and formed into shape
This is a cube of calcined ash only, no aggregate added
Old, broken bricks/pottery made previously will be crushed to form aggregate
The brick is crushed to a fine aggregate
1:1 ash to fired clay
1:2 ash to fired clay
1:3 ash to fired clay
I tried 1:4 but it wouldn't hold together so I just made a big block about 1:2 ratio ash to fired clay
Uncalcined pellet has a dull surface
Calcined block has a glossy surface
A week of curing, the samples are put in water to for a dissolving resistance test
Time lapsing about 30 minutes. Watch the uncalcined pellet (far right)
The uncalcined ash pellet dissolved. All samples that used calcined ash survived,
The lesson here is that only ash that gets very hot is suitable for cement
A tame lizard
Making a grate for a furnace
Making ash for the next batch
The ash is sifted of charcoal
water added to form paste
A single cylindrical clinker is formed that is less than 1/2 the width of the grate
Ash clinker on grate
Adding clay to hold up grate in furnace
Grate into position in furnace
Clinker in furnace on grate
This time the firing will work by natural draft (no blower) to save labor and simplify the process
Raising the height of the furnace for better natural draft
Sealing joints with mud
The furnace is stacked with wood
The fire is lit from the top (less smoke this way)
wood is periodically added so it's nearly full
Burning wood on a grate is more efficient and hotter than a fire on the ground
After an hour the clinker is well and truly calcined
Calcined clinker
Half the clinker is taken and crushed
Using sand instead of fired clay for this one as an experiment
1:3 ash to sand
Ash sand sample
1:3 ash to fired clay
Same material but different shapes
2 days later a water test is done
After 24 hours all samples have survived. The sand sample works like the others but is more easily scratched, being slightly weaker
The next experiment will only use the ash left over from the previous firing as it is (no more calcining)
In theory, the ash from wood burnt on the grate should have gotten so hot it needs no further heat treatment
A 1:3 ratio ash to fired clay is tried
It's not sticking so more ash is needed. The ash is less dense than the clinker so more needs to be added
This is more like 1:1 ratio now
6 hours later the sample is water tested
Astoundingly, after setting for only 6 hours, the sample survived 24 hours in water.
We now have a simple method for producing a fast setting geopolymer cement.
More experiments need to be done to scale up the process and see what structures can be made.
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