Difference between revisions of "Concrete"

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'''Concrete''' is a well known material for building [[house]]s and [[infrastructure]] elements. It has excellent characteristics for protection against [[radiation]] and small [[meteorites]]. Possibly, concrete can be made in situ on [[Mars]], using [[local resources]].  Concrete is a mixture of cement, sand and stone in various proportions.
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'''Concrete''' is a well known material on Earth, and would be useful for building [[settlement facilities]] such as [[house]]s and [[infrastructure]] elements. It has excellent characteristics for protection against [[radiation]] and small [[meteorites]]. Possibly, concrete can be made in situ on [[Mars]], using [[local resources]].  Concrete is usually a mixture of water, Portland cement, sand and stone in various proportions. Portland Cement ingredients may not exist on Mars, hence other types of binders have been explored over time.  The density of concrete depends on the mix and the density of the aggregate, but is usually about 2400 kg/m3.  Concrete has an [[embodied energy]] of about 1,1 to 2 MJ/kg.  Steel Rebar is usually required and increases the embodied energy of the material. 
  
 +
Concrete has the great advantage that it can be cast in place into practically any shape.  It is much cheaper than steel, although is is also much less tough.  It provides much better radiation protection than steel. 
  
Hydraulic cement
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==Mix==
 +
Concrete preparation follows certain ratios for the main ingredients.: Cement, Sand and Aggregate.  (M) stands for mix and the number is the compressive strength in MPa (N/m2) after 28 days of curing.  Water is usually mixed in at about 0,45 per volume of the cement.  There proportions are for volumes, nor for masses.
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{| class="wikitable"
 +
|'''Grades of Concrete'''
 +
|'''Ratios of Concrete mix design(Cement:Sand:Aggregate)'''
 +
|-
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|M5
 +
|1:5:10
 +
|-
 +
|M7.5
 +
|1:4:8
 +
|-
 +
|M10
 +
|1:3:6
 +
|-
 +
|M15
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|1:2:4 (most common mix)
 +
|-
 +
|M20
 +
|1:1.5:3
 +
|-
 +
|M25
 +
|1:1:2
 +
|-
 +
|M30
 +
|1:0.75:1.5
 +
|-
 +
|M35
 +
|1:0.5:1
 +
|-
 +
|M40
 +
|1:0.25:0.5
 +
|}
  
There seems to be plenty of water on Mars, but hydraulic cement also requires [[calcium]], [[silicon]] oxide (sand) and [[aluminum]] oxide. It is unclear whether these substances can be found on Mars in a form that allows a simple processing.
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==Cement==
 +
Cement is the binder in concrete.  There are many possible materials for this function.  On Earth the most common binders are lime and calcium silicate, than produce hydrate when mixed with water, hence the name hydraulic cements.
  
==Waterless concrete==
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===Hydraulic (Portland) cement===
There are ideas of making waterless concrete from [[sulfur]] and [[regolith]]<ref>https://arxiv.org/pdf/1512.05461.pdf "A Novel Material for In Situ Construction on Mars:
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There seems to be plenty of water on Mars, but hydraulic cement also requires [[calcium]], [[silicon]] oxide (sand) and [[aluminum]] oxide. It is unclear whether these substances can be found on Mars in a form that allows a simple production process.
Experiments and Numerical Simulations." Lin Wan et al. 2016</ref>.
+
 
 +
===[[Sorel Cement]]===
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[[Sorel Cement|Sorel cement]] is magnesium based cement, a non hydraulic cement made from a mixture of magnesium oxide and magnesium brine.  It has poor water resistance but excellent sheer strength.
 +
 
 +
===Sulfur cement===
 +
Waterless concrete can be produced from [[sulfur]] and [[regolith]]<ref>https://arxiv.org/pdf/1512.05461.pdf "A Novel Material for In Situ Construction on Mars:
 +
Experiments and Numerical Simulations." Lin Wan et al. 2016</ref>.  Some applications have been found on Earth, in particular for conditions requiring acid protection.
  
 
The ultimate strength and tensile strength was found to be best at a mixing ratio of 50% sulfur and 50% JSC Mars-1A regolith simulant sieved to a maximum particle size of 1 mm. The concrete was found to have a compression strength of > 50 MPa, a flexural strength of 1.75 MPa, and a splitting tensile strength of 3.9 MPa.
 
The ultimate strength and tensile strength was found to be best at a mixing ratio of 50% sulfur and 50% JSC Mars-1A regolith simulant sieved to a maximum particle size of 1 mm. The concrete was found to have a compression strength of > 50 MPa, a flexural strength of 1.75 MPa, and a splitting tensile strength of 3.9 MPa.
  
Utilizing sulfur-regolith concrete is possible on Mars, but not the Moon. On the moon, the concrete mass would be gradually lost due to sublimation of sulfur in vacuum, and the large temperature swings between lunar day and night which compromise the structure. Sulfur-regolith concrete is stable under martian conditions and would not experience a loss in mass due to sublimation.
+
Utilizing sulfur-regolith concrete is possible on Mars, but not the Moon. On the moon, the concrete mass would be gradually lost due to sublimation of sulfur in vacuum, and the large temperature swings between lunar day and night which compromise the structure. Sulfur-regolith concrete is stable under Martian conditions and would not experience a loss in mass due to sublimation.
  
 
Mars is considered a sulfur-rich planet, but it in unclear where sulfur may be and if it is present in a form suitable for the production of sulfur concrete.
 
Mars is considered a sulfur-rich planet, but it in unclear where sulfur may be and if it is present in a form suitable for the production of sulfur concrete.
 +
 +
An important disadvantage of sulfur cement is that is is not fireproof.  The sulfur used as binder can melt at higher temperatures, and may emit  large amounts of smoke.
 +
 +
==Sand and stone==
 +
Sand and stone are common on Mars. Most types of volcanic rock are compatible with concrete.
  
 
==Reinforcement==
 
==Reinforcement==
The stability of concrete can be increased significantly by [[tension glass fibers]] or reinforcing [[steel]].
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The stability of concrete structures can be increased significantly by [[tension glass fibers|glass fibers]] or reinforcing [[steel]]. Concrete is almost always reinforced with rebar, steel bars that give it strength in tension.  Composite basalt fiber rebar is available on Earth, but problems with installation may reduce its adoption.  The binder required for the composite rebar may be expensive, in [[Embodied energy|embodied energy]] terms. 
  
 
==See also==
 
==See also==
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*[[Sintered regolith]]
 
*[[Sintered regolith]]
 
*[[Brick]]
 
*[[Brick]]
 +
*[[Compressed regolith]]
  
 
==External links==
 
==External links==

Revision as of 12:14, 14 December 2020

Concrete is a well known material on Earth, and would be useful for building settlement facilities such as houses and infrastructure elements. It has excellent characteristics for protection against radiation and small meteorites. Possibly, concrete can be made in situ on Mars, using local resources. Concrete is usually a mixture of water, Portland cement, sand and stone in various proportions. Portland Cement ingredients may not exist on Mars, hence other types of binders have been explored over time. The density of concrete depends on the mix and the density of the aggregate, but is usually about 2400 kg/m3. Concrete has an embodied energy of about 1,1 to 2 MJ/kg. Steel Rebar is usually required and increases the embodied energy of the material.

Concrete has the great advantage that it can be cast in place into practically any shape. It is much cheaper than steel, although is is also much less tough. It provides much better radiation protection than steel.

Mix

Concrete preparation follows certain ratios for the main ingredients.: Cement, Sand and Aggregate. (M) stands for mix and the number is the compressive strength in MPa (N/m2) after 28 days of curing. Water is usually mixed in at about 0,45 per volume of the cement. There proportions are for volumes, nor for masses.

Grades of Concrete Ratios of Concrete mix design(Cement:Sand:Aggregate)
M5 1:5:10
M7.5 1:4:8
M10 1:3:6
M15 1:2:4 (most common mix)
M20 1:1.5:3
M25 1:1:2
M30 1:0.75:1.5
M35 1:0.5:1
M40 1:0.25:0.5

Cement

Cement is the binder in concrete. There are many possible materials for this function. On Earth the most common binders are lime and calcium silicate, than produce hydrate when mixed with water, hence the name hydraulic cements.

Hydraulic (Portland) cement

There seems to be plenty of water on Mars, but hydraulic cement also requires calcium, silicon oxide (sand) and aluminum oxide. It is unclear whether these substances can be found on Mars in a form that allows a simple production process.

Sorel Cement

Sorel cement is magnesium based cement, a non hydraulic cement made from a mixture of magnesium oxide and magnesium brine. It has poor water resistance but excellent sheer strength.

Sulfur cement

Waterless concrete can be produced from sulfur and regolith[1]. Some applications have been found on Earth, in particular for conditions requiring acid protection.

The ultimate strength and tensile strength was found to be best at a mixing ratio of 50% sulfur and 50% JSC Mars-1A regolith simulant sieved to a maximum particle size of 1 mm. The concrete was found to have a compression strength of > 50 MPa, a flexural strength of 1.75 MPa, and a splitting tensile strength of 3.9 MPa.

Utilizing sulfur-regolith concrete is possible on Mars, but not the Moon. On the moon, the concrete mass would be gradually lost due to sublimation of sulfur in vacuum, and the large temperature swings between lunar day and night which compromise the structure. Sulfur-regolith concrete is stable under Martian conditions and would not experience a loss in mass due to sublimation.

Mars is considered a sulfur-rich planet, but it in unclear where sulfur may be and if it is present in a form suitable for the production of sulfur concrete.

An important disadvantage of sulfur cement is that is is not fireproof. The sulfur used as binder can melt at higher temperatures, and may emit large amounts of smoke.

Sand and stone

Sand and stone are common on Mars. Most types of volcanic rock are compatible with concrete.

Reinforcement

The stability of concrete structures can be increased significantly by glass fibers or reinforcing steel. Concrete is almost always reinforced with rebar, steel bars that give it strength in tension. Composite basalt fiber rebar is available on Earth, but problems with installation may reduce its adoption. The binder required for the composite rebar may be expensive, in embodied energy terms.

See also

External links

  1. https://arxiv.org/pdf/1512.05461.pdf "A Novel Material for In Situ Construction on Mars: Experiments and Numerical Simulations." Lin Wan et al. 2016