Topics

Biochar in Cement - Open Access


Tom Miles
 

https://bit.ly/3aqWBnP

 

Singapore, Korea, Sri Lanka: Carbonaceous inserts from lignocellulosic and non-lignocellulosic sources in cement mortar: Preparation conditions and its effect on hydration kinetics and physical properties

 

Biochar from variety of feedstocks and preparation conditions are characterized.

Surface area and pore volume of biochar influence hydration kinetics of biochar-cement.

Carbon content and surface area of biochar contribute to compressive strength of mortar.

Addition of biochar, irrespective of feedstock type, reduce rate of water absorption.

 

Landfilling and open burning of biomass wastes lead to adverse environmental impacts. A potential means to valorize such wastes can be achieved through thermal conversion to biochar, and applying the produced biochar as admixture in cementitious construction materials. This article aims to investigate the influence of biochar from different lignocellulsic wastes, including sorghum, cotton stalk, wood and dairy manure, and non-lignocellulosic algae waste on hydration, mechanical and permeability properties of cement mortar. Performance of biochar-mortar composites were compared with mortar prepared with three different commercial biochar with relatively high carbon content and surface area. The findings suggest that biochar with higher surace area and pore volume, for instance, wood biochar, tend to increase hydration, while biochar with high ash content, for instance dairy manure biochar in this case, reduce peak hydration heat and negatively affect the overall hydration over 7-day monitoring period. Strength results suggest that depending on elemental carbon content and surface area, addition of biochar from different lignocellulosic biomass increases compressive strength, elastic modulus and fracture toughness by 10–12%, 16–20% and 30–40% respectively at 2 years compared to control. Among lignocellulosic biochars, only wood biochar prepared at 500C led to slight increase (7%) in 28-day strength compared to control, while non-lignocellulosic algae biochar reduced strength of mortar by 15%. Depending on feedstock and production condition, addition of lignocellulosic and non-lignocellulosic biochar led to 10–50% reduction in permeability at 28-day age, measured by water absorption through capillary action. The findings suggest that addition of biochar from horticultural, agricultural and forest waste may be a sustainable means to improve physical properties of construction materials while reducing the need for incineration and landfilling.

 

 


briancady413
 

Wouldn't it save the energy of  biochar combustion to just put the feedstock into the cement?

Brian
-

On Saturday, August 15, 2020, 12:20:42 PM EDT, Tom Miles <tmiles@trmiles.com> wrote:






https://bit.ly/3aqWBnP
 
Singapore, Korea, Sri Lanka: Carbonaceous inserts from lignocellulosic and non-lignocellulosic sources in cement mortar: Preparation conditions and its effect on hydration kinetics and physical properties
 
Biochar from variety of feedstocks and preparation conditions are characterized.
Surface area and pore volume of biochar influence hydration kinetics of biochar-cement.
Carbon content and surface area of biochar contribute to compressive strength of mortar.
Addition of biochar, irrespective of feedstock type, reduce rate of water absorption.
 
Landfilling and open burning of biomass wastes lead to adverse environmental impacts. A potential means to valorize such wastes can be achieved through thermal conversion to biochar, and applying the produced biochar as admixture in cementitious construction materials. This article aims to investigate the influence of biochar from different lignocellulsic wastes, including sorghum, cotton stalk, wood and dairy manure, and non-lignocellulosic algae waste on hydration, mechanical and permeability properties of cement mortar. Performance of biochar-mortar composites were compared with mortar prepared with three different commercial biochar with relatively high carbon content and surface area. The findings suggest that biochar with higher surace area and pore volume, for instance, wood biochar, tend to increase hydration, while biochar with high ash content, for instance dairy manure biochar in this case, reduce peak hydration heat and negatively affect the overall hydration over 7-day monitoring period. Strength results suggest that depending on elemental carbon content and surface area, addition of biochar from different lignocellulosic biomass increases compressive strength, elastic modulus and fracture toughness by 10–12%, 16–20% and 30–40% respectively at 2 years compared to control. Among lignocellulosic biochars, only wood biochar prepared at 500C led to slight increase (7%) in 28-day strength compared to control, while non-lignocellulosic algae biochar reduced strength of mortar by 15%. Depending on feedstock and production condition, addition of lignocellulosic and non-lignocellulosic biochar led to 10–50% reduction in permeability at 28-day age, measured by water absorption through capillary action. The findings suggest that addition of biochar from horticultural, agricultural and forest waste may be a sustainable means to improve physical properties of construction materials while reducing the need for incineration and landfilling.


Tom Miles
 

Co-locating the carbonizer at a cement kiln is clearly an option. Currently many kilns use waste materials as fuel in combination with fossil sources.

Tom

-----Original Message-----
From: main@Biochar.groups.io <main@Biochar.groups.io> On Behalf Of briancady413 via groups.io
Sent: Saturday, August 15, 2020 9:27 AM
To: biochar@groups.io; main@Biochar.groups.io
Subject: Re: [Biochar] Biochar in Cement - Open Access

Wouldn't it save the energy of biochar combustion to just put the feedstock into the cement?

Brian
-






On Saturday, August 15, 2020, 12:20:42 PM EDT, Tom Miles <tmiles@trmiles.com> wrote:






https://bit.ly/3aqWBnP

Singapore, Korea, Sri Lanka: Carbonaceous inserts from lignocellulosic and non-lignocellulosic sources in cement mortar: Preparation conditions and its effect on hydration kinetics and physical properties

Biochar from variety of feedstocks and preparation conditions are characterized.
Surface area and pore volume of biochar influence hydration kinetics of biochar-cement.
Carbon content and surface area of biochar contribute to compressive strength of mortar.
Addition of biochar, irrespective of feedstock type, reduce rate of water absorption.

Landfilling and open burning of biomass wastes lead to adverse environmental impacts. A potential means to valorize such wastes can be achieved through thermal conversion to biochar, and applying the produced biochar as admixture in cementitious construction materials. This article aims to investigate the influence of biochar from different lignocellulsic wastes, including sorghum, cotton stalk, wood and dairy manure, and non-lignocellulosic algae waste on hydration, mechanical and permeability properties of cement mortar. Performance of biochar-mortar composites were compared with mortar prepared with three different commercial biochar with relatively high carbon content and surface area. The findings suggest that biochar with higher surace area and pore volume, for instance, wood biochar, tend to increase hydration, while biochar with high ash content, for instance dairy manure biochar in this case, reduce peak hydration heat and negatively affect the overall hydration over 7-day monitoring period. Strength results suggest that depending on elemental carbon content and surface area, addition of biochar from different lignocellulosic biomass increases compressive strength, elastic modulus and fracture toughness by 10–12%, 16–20% and 30–40% respectively at 2 years compared to control. Among lignocellulosic biochars, only wood biochar prepared at 500C led to slight increase (7%) in 28-day strength compared to control, while non-lignocellulosic algae biochar reduced strength of mortar by 15%. Depending on feedstock and production condition, addition of lignocellulosic and non-lignocellulosic biochar led to 10–50% reduction in permeability at 28-day age, measured by water absorption through capillary action. The findings suggest that addition of biochar from horticultural, agricultural and forest waste may be a sustainable means to improve physical properties of construction materials while reducing the need for incineration and landfilling.