Difference between revisions of "Baking with Improved Ovens"

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= Fuels<br/> =
 
= Fuels<br/> =
  
Theoretically, anything that burns can be used to heat a baking oven, but in practice, fuel needs careful selection. It is not always best to choose the cheapest energy source in order to be economical. Other factors to that should be considered are the type and amount of ash that is formed, the energy value of the fuel and the location of the bakery to prevent smoke disturbances.  
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Theoretically, anything that burns can be used to heat a baking oven, but in practice, fuel needs careful selection. It is not always best to choose the cheapest energy source in order to be economical. Other factors to that should be considered are the type and amount of ash that is formed, the energy value of the fuel and the location of the bakery to prevent smoke disturbances.
  
 
For more detailed information on cooking processes of different fuels, please refer to the [[#Cooking_Energy_Technologies_and_Practices|Cooking Energy Technologies and Practices]] Chapter. Baking requires a larger amount of thermal energy input, e.g. wood, than cooking. Availability and price of fuel are therefore crucial for bakeries as it constitutes their largest operating cost: up to 30 per cent of the bread loaf cost&nbsp;&nbsp; is constituted by fuel costs. (Fellows 2012; Lawson, Joseph 1989) Bakers must therefore conduct a careful analysis of their energy needs.
 
For more detailed information on cooking processes of different fuels, please refer to the [[#Cooking_Energy_Technologies_and_Practices|Cooking Energy Technologies and Practices]] Chapter. Baking requires a larger amount of thermal energy input, e.g. wood, than cooking. Availability and price of fuel are therefore crucial for bakeries as it constitutes their largest operating cost: up to 30 per cent of the bread loaf cost&nbsp;&nbsp; is constituted by fuel costs. (Fellows 2012; Lawson, Joseph 1989) Bakers must therefore conduct a careful analysis of their energy needs.
  
The following fuels may be available <ref name=" Fellows, Peter 2012: Baking. Technical Brief of Practical Action. This is a technical brief about the baking process. March 2012, available at: http://practicalaction.org/baking"> Fellows, Peter 2012: Baking. Technical Brief of Practical Action. This is a technical brief about the baking process. March 2012, available at: http://practicalaction.org/baking</ref><ref name="Fellows, P.J. and Axtell, B. (2004): Setting up and running a small flour mill or bakery. Opportunities in food processing series. Wageningen: ACP-EU Technical Centre for Agricultural and Rural Cooperation (CTA), 2004. fckLRhttp://www.anancy.net/documents/file_en/Milling-baking%20BROCH%20juin05.pdf ">Fellows, P.J. and Axtell, B. (2004): Setting up and running a small flour mill or bakery. Opportunities in food processing series. Wageningen: ACP-EU Technical Centre for Agricultural and Rural Cooperation (CTA), 2004. fckLRhttp://www.anancy.net/documents/file_en/Milling-baking%20BROCH%20juin05.pdf </ref>:
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The following fuels may be available <ref name="Fellows, P.J. and Axtell, B. (2004): Setting up and running a small flour mill or bakery. Opportunities in food processing series. Wageningen: ACP-EU Technical Centre for Agricultural and Rural Cooperation (CTA), 2004. fckLRhttp://www.anancy.net/documents/file_en/Milling-baking%20BROCH%20juin05.pdf ">Fellows, P.J. and Axtell, B. (2004): Setting up and running a small flour mill or bakery. Opportunities in food processing series. Wageningen: ACP-EU Technical Centre for Agricultural and Rural Cooperation (CTA), 2004. fckLRhttp://www.anancy.net/documents/file_en/Milling-baking%20BROCH%20juin05.pdf </ref><ref name="Fellows, P.J. and Axtell, B. (2004): Setting up and running a small flour mill or bakery. Opportunities in food processing series. Wageningen: ACP-EU Technical Centre for Agricultural and Rural Cooperation (CTA), 2004. fckLRhttp://www.anancy.net/documents/file_en/Milling-baking%20BROCH%20juin05.pdf ">Fellows, P.J. and Axtell, B. (2004): Setting up and running a small flour mill or bakery. Opportunities in food processing series. Wageningen: ACP-EU Technical Centre for Agricultural and Rural Cooperation (CTA), 2004. fckLRhttp://www.anancy.net/documents/file_en/Milling-baking%20BROCH%20juin05.pdf </ref>:
  
 
*<u>Mains gas or bottled gas (LPG)</u> are the preferred options in countries that have an established gas distribution system because they burn cleanly and produce no contamination of products. I<ins cite="mailto:Johanna%20Hartmann" datetime="2012-11-28T21:10">n some regions gas</ins> may be too expensive, and <ins cite="mailto:Johanna%20Hartmann" datetime="2012-11-28T21:10">it </ins><ins cite="mailto:Johanna%20Hartmann" datetime="2012-11-28T21:11">may be</ins> available only in some urban centres. See also: Cooking with [https://energypedia.info/index.php/Cooking_with_fossil_fuels#Cooking_with_Liquefied_Petroleum_Gas_.28LPG.29 Liquefied Petroleum Gas]
 
*<u>Mains gas or bottled gas (LPG)</u> are the preferred options in countries that have an established gas distribution system because they burn cleanly and produce no contamination of products. I<ins cite="mailto:Johanna%20Hartmann" datetime="2012-11-28T21:10">n some regions gas</ins> may be too expensive, and <ins cite="mailto:Johanna%20Hartmann" datetime="2012-11-28T21:10">it </ins><ins cite="mailto:Johanna%20Hartmann" datetime="2012-11-28T21:11">may be</ins> available only in some urban centres. See also: Cooking with [https://energypedia.info/index.php/Cooking_with_fossil_fuels#Cooking_with_Liquefied_Petroleum_Gas_.28LPG.29 Liquefied Petroleum Gas]
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*<u>Liquid fuels</u> such as kerosene or diesel are not widely used in baking ovens because they risk contaminating products with off-odours or even fires and explosions (petrol).
 
*<u>Liquid fuels</u> such as kerosene or diesel are not widely used in baking ovens because they risk contaminating products with off-odours or even fires and explosions (petrol).
 
*<u>Solar energy </u>can also be an energy source for baking purposes. For solar restaurants and bakeries, see: [http://solarcooking.wikia.com/wiki/Solar_restaurants_and_bakeries http://solarcooking.wikia.com/wiki/Solar_restaurants_and_bakeries] or relate to the [https://energypedia.info/index.php/Cooking_with_Sun#Parabolic_Solar_Cookers Solar cooking chapter].
 
*<u>Solar energy </u>can also be an energy source for baking purposes. For solar restaurants and bakeries, see: [http://solarcooking.wikia.com/wiki/Solar_restaurants_and_bakeries http://solarcooking.wikia.com/wiki/Solar_restaurants_and_bakeries] or relate to the [https://energypedia.info/index.php/Cooking_with_Sun#Parabolic_Solar_Cookers Solar cooking chapter].
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= References<br/> =
 
= References<br/> =
  
 
&nbsp;<references />
 
&nbsp;<references />

Revision as of 13:09, 11 December 2012

Overview / Background

Baking refers to a process “to cook by dry heat“ and is therefore next to cooking another essential way of preparing food from raw staple crops. Usually, it takes place in an oven or on a hotplate, but also in hot ashes or on hot stones. Baking is primarily applied to the process of preparing bread, and is also applied for firing and hardening pottery, earthenware or bricks by heat.

During baking, the heating process is done by a combination of three forms of heat: by infra-red energy that is radiated from oven walls, by circulating hot air; and by conduction through the baking pan or tray.[1] That means the efficiency of the baking process depends on the optimal use of three different parts of the device: the walls, the tray and the ventilation system.

Burning biomass within the device produces the desired heat. Subsequently, the goods are placed inside and are baked for a certain amount of time. In the simplest way, a fire is lighted in a pit on the ground and after being burned down, the covered food is started to be baked (earth oven).


The chemical changes during the baking process allow for two improvements:

  1. The dough is transformed into an eatable food (nutritional improvement).
  2.  At the same time, microorganisms causing spoilage are destroyed prolonging keeping time of the product (food preservation).

Unlike other cooking methods, baking does not alter the nutritional value of the food item, e.g. the fat and calorie content of the food.


Baked Staple Food

Many different varieties of bread and pastry have emerged from regional traditions around the world: like various sorts of bread, rolls, biscuits, pastries, cakes, buns and rusks, crêpes, injera, pancakes, etc. Corn tortillas form the staple food in most of Mexico, while in Peru the diversion of bread includes ingredients like potatoes or pumpkin. In Ethiopia and in east North Africa, the wide, flat, circular bread, which is called injera, is made from a grain called teff. Divers types of unleavened flat breads, which are usually made from whole-wheat flour and baked on a hot iron griddle called tava are the staple bread in South Asia and the Middle East.

Bread doughs produced from wheat flour have a unique viscoelasticity due to the wheat protein gluten, and therefore provide a better nutrition for humans. The world production of wheat in 2010 was 651 million tons, toped only by the cereals maize and rice. At the beginning of this century, more than 45 per cent of the world’s wheat was produced in developing countries[2].

Bread is a convenience food in Africa for both urban and rural communities. The major challenge with bread consumption in Africa is that most countries can't produce sufficient quantities of wheat to supply the bread market. Therefore, other starchy materials such as corn, potato, banana, yam, rice, sorghum, or cassava substitute wheat[3].


Bakeries Worldwide

Baking is also a lucrative business. In many regions the industry as well as small and micro enterprises, are often facing unfavourable conditions.

It is therefore important to guarantee and improve:[4]

  • abundant supply of wheat flour
  • efficient baking technologies
  • capital at low interest rate
  • quality control of the products
  • continuous demand for bakery products
  • access to good transportation and communication
  • effective promotion

 

In order to be successful, bakeries regularly require:[5]

  • Ingredient inspection
  • Quality assurance of bakery products
  • Process control in a bakery involves accurate weighting of ingredients, control over baking temperatures and times and correct handling procedures for products. This includes also an optimal usage and handling of the chosen technology and energy fuel.
  • Cleaning routine to ensure hygienic standards.

Bakeries exist worldwide in all sizes in both the formal and the informal sector: Small bakers operating from home, retail bakers who operate in-store bakeries, independent bakers who operate stand-alone bakeries, and large wholesale bakers who operate industrial (plant) bakeries.

In India, there are around 60,000 bakeries, mostly concentrated in the informal sector. The bakery industry is among the few processed food segments whose production has been increasing consistently in the country over the last few years.  Baking constitute the largest segment of consumer foods with an annual production of around 4 million tonnes.[6]

In South Africa, approximately 3000 bakeries were registered in 1990 and approximately 80% of the bread production was in the hands of 6 large baking groups. After abolishment of the controlled bread prices in the early 1990's, the number of bakeries increased considerably. In 2005, out of the total of 7900 bakeries, 85 were wholesale bakeries, 600 were in-store corporate bakeries, 3700  were independent bakers, and 3500 were franchise bakers. It is estimated that 53,200 informal bakers operate in non-licensed premises.[7]

They offer their baking products to different markets such as domestic, food service establishments, institutions, and wholesale.

In small-scale bakeries, dough is rolled by hand in order to form the required shape, thickness and size, which is time-consuming and can also produce variable thickness in pieces if staff is not properly trained. At a larger scale of operation, machines are used to process the dough before baking.[5]

Baking requires very high temperature (around 250°C) and thus needs a larger amount of thermal energy input, e.g. wood, than cooking. Efficient baking technology reduces the firewood consumption, guaranteeing not only an efficient and shorter baking process, but also reduced operating costs.


Ovens

The most important fixture in a bakery is the oven. Before obtaining an oven, a baker should consider oven prices, fuel costs, possible assistance, supply and quality of the materials, etc.
Since many projects of GIZ focus on biomass for cooking and baking, the presented ovens are fuelled with biomass. If you have information on ovens with other fuels, please feel free to contribute.


Traditional Ovens

The simplest way is to bake within a so-called earth oven: after a lighted fire in a pit on the ground is burned down, the food is put inside the pit and covered: the baking process starts.
Other traditional baking ovens consist of a baking chamber made of fireproof brick, concrete, stone, clay, or cob. Traditionally they are wood-fired, but coal-fired ovens are also common. It is known as a “black oven” because the smoke from the burned wood sometimes collects soot on the roof of the oven. They often lack insulation and proper ventilation.
Traditional ovens tend to consume more than 0.5-1 kg of wood per kg of baked wheat flour.[8]


Improved Ovens

Two types of improved ovens are in common use worldwide: direct heating ovens heated by fuels in the baking chamber and indirect heating ovens that have a separate heater or firebox. Both types are constructed from materials such as steel, which withstands high temperatures. Insulation of the chamber is very important.

Directly Heated Ovens

Directly heated solid fuel ovens are typically used by artisans, small-scale bakeries and restaurants. This type of oven costs relatively little but involves the risk of product contamination by smoke and ash. Fuel is burnt on the stone hearth for 6 to 12 hours, often overnight. The heat, which is retained inside the oven and in the oven walls, is then used for baking, while the oven temperature gradually drops during the day.


Indirect Heating Ovens

Indirect heating ovens can be operated continuously at constant temperatures because the fire can be maintained without interrupting production. The simplest oven designs have a separate firebox with brick or tile-lined flues surrounding the baking chamber. Both types of oven can be found in various sizes and with varying capacities.
The heat should be evenly distributed throughout the baking chamber and all parts of the chamber should be easily reached through the oven door so that products can be loaded/unloaded without the risk of burns.
Experience shows that improved ovens reduce firewood consumption significantly – up to 50-80 per cent compared to a traditional oven.

Example - Ethiopia: Mirt Stove

The Mirt stove is primarily designed for baking injera. The stove is produced from locally available raw materials, mainly red ash (or in its absence, pumice or river sand) mixed with cement. The stove comprises six parts. Four of these make a cylindrically shaped enclosure about 66cm in diameter and 24cm high, where the firewood is burned under a baking plate. The remaining two parts sit behind the cylindrical enclosure and facilitate smoke removal and cooking on a pot.
Small holding injera bakers use a single stove for their daily baking. Others, such as cooperative micro-enterprises use different versions of modified Mirt stoves, which cluster two or four individual stoves so that they use a single chimney, with additional tailored parts for collecting the smoke from the individual stoves.
The stove reduces fuel consumption by 50 per cent compared to the traditional three stone open fire and is optimised to burn a range of biomass fuels including firewood, agro-residues and dung.
Current average market price for a single stove is USD 11 and USD 126 for the modified stove with four individual stoves. Thanks to the resultant reduced fuel costs, the oven purchase cost amortises within approximately two months. Most component parts can be replaced if damaged. One of the Mirt parts is only USD 2, but a new chimney costs around USD 63; owing to the high costs users are unfortunately reluctant to repair them immediately. Energy experts at GIZ ECO are currently working to improve the chimney design as the bakers are affected by heat radiation created by the absence of an insulator on the chimney of the stove.

Find more information on GIZ’s approach, a case study and further literature here.

Example - Uganda: Rocket baking ovens

The firewood rocket baking oven promoted by GIZ in Uganda comes in three different sizes: the single deck rocket oven, the double deck rocket oven, and the large-scale commercial rocket oven which is the equivalent of four double deck ovens constructed in modular format. Baking capacity per oven varies between 32 and 256 kg of bread in one cycle, or 100 to 800 buns. A baker can save time and money compared to using a traditional baking oven. Preheating time is reduced by at least two-thirds. Firewood consumption is reduced to one-tenth of previous consumption. The rocket oven increases efficiency by 70 per cent because of improved heat transfer. It evenly distributes heat around the baking chamber, thereby producing better quality products. Proper sealing of the baking chamber ensures that the bread is not contaminated by smoke or ash.
Entrepreneurs invest between UGX and 18.5 million (USD 1,616 and USD 7,474) depending on the size of the ovens. Big ovens bake 760 loaves of bread at once, small ovens 12-24 loaves. These investments can be financed by future savings because of considerably reduced firewood consumption - up to 80 per cent. One cubic metre of fuel wood costs UGX 20,000 (USD 234).

Find more information on GIZ’s approach, a case study and further literature here.


Further Information

Baking Manual: how to construct a baking oven
Rocket Bread Oven Construction Manual, developed by Peter Scott
The manual is a flexible tool that describes how to build efficient bakery scale wood burning rocket bread ovens. It guides the builder through the construction process. Available at:
https://energypedia.info/index.php/File:GIZ-2012_bread_baking_oven_burn_lab_design_en.pdf.

Technical Brief: Baking. Fellows, Peter 2012. Technical Brief of Practical Action, available at: http://practicalaction.org/baking.


Fuels

Theoretically, anything that burns can be used to heat a baking oven, but in practice, fuel needs careful selection. It is not always best to choose the cheapest energy source in order to be economical. Other factors to that should be considered are the type and amount of ash that is formed, the energy value of the fuel and the location of the bakery to prevent smoke disturbances.

For more detailed information on cooking processes of different fuels, please refer to the Cooking Energy Technologies and Practices Chapter. Baking requires a larger amount of thermal energy input, e.g. wood, than cooking. Availability and price of fuel are therefore crucial for bakeries as it constitutes their largest operating cost: up to 30 per cent of the bread loaf cost   is constituted by fuel costs. (Fellows 2012; Lawson, Joseph 1989) Bakers must therefore conduct a careful analysis of their energy needs.

The following fuels may be available [9][9]:

  • Mains gas or bottled gas (LPG) are the preferred options in countries that have an established gas distribution system because they burn cleanly and produce no contamination of products. In some regions gas may be too expensive, and it may be available only in some urban centres. See also: Cooking with Liquefied Petroleum Gas
  • Electricity is mostly a question of availability.
  • Solid fuels may be the lowest-cost option in many countries. Traditionally, wood has been cheap or free and hence widely used in bakery ovens, but deforestation in many countries has resulted in legal restrictions on its use and/or increased costs. It also produces a light fluffy ash that can easily contaminate products. But wherever biomass is the economically best option, efficient technology may help to overcome the environmental problems and health issues. See also: Cooking with Firewood
  • Where available, coal is the preferred solid fuel for bakery ovens because it is dense and compact, it has a high calorific (heating) value, it is handled relatively easily and it produces a compact ash that is more easily disposed of than wood ash. See also: Cooking with coal
  • Charcoal is often more expensive than wood and coal, but it produces an intense heat with little smoke. Having skills and experience to control the fire is more crucial for solid fuels. Variable temperatures causing quality disturbances and wasteful consumption of fuel may lead to increased expenses. See also: Cooking with charcoal
  • Liquid fuels such as kerosene or diesel are not widely used in baking ovens because they risk contaminating products with off-odours or even fires and explosions (petrol).
  • Solar energy can also be an energy source for baking purposes. For solar restaurants and bakeries, see: http://solarcooking.wikia.com/wiki/Solar_restaurants_and_bakeries or relate to the Solar cooking chapter.


References

 

  1. Fellows, P.J. and Axtell, B. (2004): Setting up and running a small flour mill or bakery. Opportunities in food processing series. Wageningen: ACP-EU Technical Centre for Agricultural and Rural Cooperation (CTA), 2004. fckLRhttp://www.anancy.net/documents/file_en/Milling-baking%20BROCH%20juin05.pdf
  2. Curtis, B.C. (2002): Bread Wheat. Food and Agriculture Organization of the United Nations, available at http://www.fao.org/docrep/006/y4011e/y4011e04.htm#bm04.
  3. Bokanga, M./ Tewe, O. (1998): Cassava: A Premium Raw Material for the Food, Feed, and Industrial Sectors in Africa. In: Ferris, R.: Postharvest Technology and Commodity Marketing in West Africa: Proceedings of a Postharvest Conference 2 Nov. to 1 Dec. 1995, International Institute of Tropical Agriculture, Accra, Ghana.
  4. Dagoon, J. (2005): Home Economics Technology IV, RBS Technology, Livelihood Education, and Life Skills Series, Rex Bookstore, Philippines.
  5. 5.0 5.1 Fellows, Peter 2012: Baking. Technical Brief of Practical Action. This is a technical brief about the baking process. March 2012, available at: http://practicalaction.org/baking.
  6. GIZ India (2011): Identification of Industrial Sectors Promising for Commercialisation of Solar Energy, Commercialisation of Solar Energy in Urban and Industrial Areas – ComSolar, New Dehli, India. Available at: http://www.giz.de/themen/en/33542.htm.
  7. Hobson, Stephen (2006): A Trade and Poverty Case Study:
The Effects of Trade Liberalization on the Wheat-Flour-Bread Value Chain in South Africa. Available at: http://www.saldru.uct.ac.za/home/index.php?/component/option,com_docman/Itemid,32/gid,267/task,doc_view/
  8. Armando Manhiça, Fabião/ Lucas, Carlos/ Richards, Tobias (2012): Wood consumption and analysis of the bread baking process in wood-fired bakery ovens, Applied Thermal Engineering, Volume 47, 5 December 2012, Pages 63-72, available at: http://www.sciencedirect.com/science/article/pii/S1359431112001627.
  9. 9.0 9.1 ↑ Fellows, P.J. and Axtell, B. (2004): Setting up and running a small flour mill or bakery. Opportunities in food processing series. Wageningen: ACP-EU Technical Centre for Agricultural and Rural Cooperation (CTA), 2004. fckLRhttp://www.anancy.net/documents/file_en/Milling-baking%20BROCH%20juin05.pdf