Calculating R Values for Insulation Assemblies

Calculating R Values for Insulation Assemblies

Understanding R-Value and Its Importance in Building Insulation

Understanding R-value and its importance in building insulation is crucial when it comes to calculating R-values for insulation assemblies. R-value, or thermal resistance, is a measure of an insulation materials ability to resist heat flow. The higher the R-value, the greater the insulating effectiveness of the material. This concept plays a pivotal role in ensuring energy efficiency and comfort within buildings.


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When calculating R-values for insulation assemblies, its essential to consider not only the individual components but also how they work together as a system. Each layer of insulation contributes to the overall thermal resistance of the assembly. For instance, combining different types of insulation materials, such as fiberglass batts and rigid foam boards, can enhance the total R-value of a wall or roof.


The process begins by identifying the R-value of each component in the assembly. Manufacturers usually provide this information on product labels or technical data sheets. Once you have these values, you can add them together to get the total R-value of the assembly. However, its important to account for any thermal bridging that might occur due to structural elements like studs or joists, which can reduce the effective R-value.


Understanding and accurately calculating R-values for insulation assemblies is vital for meeting building codes and standards, which often specify minimum R-value requirements for different parts of a structure. Moreover, achieving optimal R-values can lead to significant energy savings over time by reducing heating and cooling costs.


In practice, professionals use various tools and software to model and predict how different insulation assemblies will perform under real-world conditions. These simulations help in selecting the right combination of materials to achieve desired levels of thermal performance.


In conclusion, grasping the concept of R-value and its application in calculating insulation assemblies is fundamental for anyone involved in building design and construction. It ensures that buildings are not only compliant with regulations but also energy-efficient and comfortable for occupants.

Materials Used in Insulation and Their Individual R-Values —

Okay, so youre thinking about insulation, right? And you probably know that insulation helps keep your house warm in the winter and cool in the summer. But its not just some magical stuff you stuff in the walls. Its all about R-values. Basically, R-value is a measure of how well a material resists heat flow. The higher the R-value, the better it insulates.


Now, different materials have different R-values. Think about it: a thin sheet of paper isnt going to do much to keep you warm, but a thick down comforter will. Thats because the down comforter has a much higher R-value.


So, what are some common insulation materials and what kind of R-values are we talking about? Well, fiberglass batts are pretty common. Theyre relatively inexpensive and easy to install. Youre looking at something like R-3 to R-4 per inch of thickness, roughly. Then theres cellulose, which is made from recycled paper. Its a good option if youre looking for something eco-friendly, and it usually has an R-value around R-3.5 to R-3.7 per inch. Spray foam is another popular choice, and it can have a really high R-value, sometimes up to R-6 or even R-7 per inch, depending on the type. It also fills in cracks and crevices really well, which helps reduce air leaks. Rigid foam boards are often used for insulating foundations or exterior walls, and their R-value can vary quite a bit depending on the material, from R-4 to R-6.5 per inch for something like extruded polystyrene (XPS).


Keep in mind that these are just ballpark figures. The exact R-value of a specific material will depend on its density, thickness, and even the manufacturer. That's why it's always a good idea to check the product label.


Now, things get interesting when you start layering different types of insulation. To figure out the total R-value of a wall assembly, you basically just add up the R-values of all the individual layers. So, if you have a wall with fiberglass batts (R-13) and then a layer of rigid foam board (R-5), the total R-value of that wall would be R-18. Its pretty straightforward.


But here's the thing: its not just about the R-value of the insulation itself. Air leaks can really kill your insulations effectiveness. So, sealing up any cracks or gaps around windows, doors, and other openings is super important. It's often said that air sealing is as important, or even more important, than the R-value of the insulation itself. Think of it like wearing a really warm coat with a bunch of holes in it – youre still going to feel the cold.


In the end, understanding the R-values of different insulation materials and how they work together is key to creating a comfortable and energy-efficient home. And remember, its not just about the R-value; its about the whole system, including proper installation and air sealing.

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Calculating Total R-Value for Multi-Layer Insulation Assemblies

Okay, so youre staring at a wall assembly that looks like a lasagna of insulation materials. Youve got your fiberglass batt, maybe some rigid foam, and then that fancy radiant barrier stuff. You want to know how well this whole shebang is going to insulate, right? You need the Total R-value. Think of R-value as insulations superpower, its ability to resist heat flow. The higher the R-value, the better the insulation.


Calculating the Total R-value for multi-layer insulation is actually pretty straightforward, in theory. The basic idea is that you simply add up the R-values of each layer. So, if your fiberglass batt has an R-value of 13, your rigid foam gives you R-5, and that radiant barrier adds, say, R-2 (well talk about radiant barriers in a bit, theyre a bit tricky), then your Total R-value is 13 + 5 + 2 = R-20. Easy peasy, lemon squeezy, right?


Well, hold on a minute. Its usually not quite THAT simple. First, make sure youre using the correct R-value for each material. Manufacturers should provide this information. Dont guess! Second, and this is important, the effectiveness of some insulation types, especially radiant barriers, depends heavily on HOW theyre installed. Radiant barriers work by reflecting radiant heat, and they need an air space to be effective. If you just slap a radiant barrier directly against another material, it wont perform nearly as well as if it has that critical air gap. So, the advertised R-value might be misleading if the installation doesnt create the necessary air space.


Also, remember that R-values are typically given at specific temperatures. The R-value of some materials can change slightly depending on the temperature difference across them. This is usually not a huge deal for most residential applications, but its something to keep in mind, especially in extreme climates.


Finally, be aware of thermal bridging. This happens when a more conductive material (like a wood stud) runs through the insulation. This creates a path for heat to easily bypass the insulation, reducing the overall effectiveness of the assembly. Calculating the effect of thermal bridging is a bit more complex and often requires specialized software or consulting with a building science professional.


So, in summary, adding up the R-values of each layer is the starting point. But to get a truly accurate picture of your insulations performance, consider the installation of radiant barriers, temperature effects (if relevant), and the potential for thermal bridging. Do that, and youll be well on your way to a comfortable and energy-efficient home.

Calculating Total R-Value for Multi-Layer Insulation Assemblies

Impact of Air Gaps and Thermal Bridging on Effective R-Value

Okay, so were talking about how well insulation actually works, not just what the label says the R-value should be. Thats where air gaps and thermal bridging come in, and theyre like the sneaky villains of insulation performance.


Think of it this way: R-value is a measure of resistance to heat flow. The higher the R-value, the better the insulation should be at keeping heat in (during winter) or out (during summer). But thats under ideal conditions, which rarely exist in the real world.


Air gaps? Imagine a perfectly fluffy blanket laid perfectly flat. Thats great insulation. Now, crumple it up and leave gaps between the blanket and your body. Suddenly, youre feeling the chill, right? Air gaps in insulation do the same thing. Even small gaps, like those behind poorly installed batts or around electrical boxes, allow air to circulate. This airflow carries heat across the insulated area, dramatically reducing the effective R-value. Its like creating little convection ovens within your walls.


Then theres thermal bridging. This is where materials that conduct heat well (like wood studs or metal fasteners) create a direct path for heat to flow through the insulation. Imagine those same fluffy blankets, but with metal rods running through them. Those rods would conduct heat right through the blanket, bypassing the insulation altogether. Wood studs in a wall, for example, have a much lower R-value than the insulation between them. So, heat flows directly through the studs, reducing the overall effective R-value of the wall assembly. Metal framing is even worse because metal is a much better conductor than wood.


Basically, air gaps let heat sneak around the insulation, and thermal bridges let heat zoom right through it. The result is a lower-than-expected effective R-value, meaning your heating and cooling systems have to work harder, and your energy bills are higher. Accurately calculating the effective R-value of an assembly requires considering these factors, often through complex calculations or software modeling. Its not enough to just add up the R-values of the individual insulation components; you have to account for these sneaky heat-transfer pathways. So, paying attention to proper installation techniques to minimize air gaps and using strategies to reduce thermal bridging (like using thermal breaks or continuous insulation) is crucial for achieving the energy savings youre hoping for.

R-Value Requirements Based on Climate Zone and Building Codes

When it comes to calculating R-values for insulation assemblies, understanding the R-value requirements based on climate zones and building codes is crucial. The R-value, or thermal resistance, measures how well a material can resist heat flow. This becomes particularly important in the context of energy efficiency and maintaining comfortable indoor temperatures.


Different regions have varying climate conditions, which directly influence the R-value requirements for buildings. For instance, colder climates necessitate higher R-values to prevent heat loss during winter months. Conversely, in warmer climates, the focus might be on preventing heat gain during summer. The U.S. Department of Energy provides a detailed map dividing the country into eight climate zones, each with specific recommendations for insulation levels.


Building codes also play a significant role in determining R-value requirements. These codes are often set at the state or local level and can vary widely. For example, the International Energy Conservation Code (IECC) sets minimum standards that many states adopt and sometimes modify to suit local conditions. Adhering to these codes is not only a legal requirement but also ensures that buildings are constructed with optimal energy efficiency in mind.


Calculating the appropriate R-value for an insulation assembly involves considering both the climate zone and applicable building codes. For walls, floors, and ceilings, different materials contribute to the overall R-value of the assembly. Insulation materials like fiberglass, cellulose, or spray foam each have their own R-values per inch of thickness. By summing up these values and comparing them against local requirements, builders can ensure compliance and maximize energy savings.


In practice, this means that someone constructing a home in a cold climate zone like Zone 6 might need to install wall insulation with an R-value of at least R-20 to meet minimum IECC standards. However, if local building codes are more stringent or if aiming for higher energy efficiency, they might opt for an even higher value like R-25 or more.


Ultimately, understanding and applying R-value requirements based on climate zones and building codes is essential for anyone involved in construction or renovation projects. It ensures not only compliance with regulations but also contributes significantly to creating sustainable and comfortable living spaces.

Tools and Resources for Accurate R-Value Calculation

When it comes to calculating R-values for insulation assemblies, having the right tools and resources at your disposal is crucial. R-value, which measures the thermal resistance of a material or assembly, is a key factor in determining the energy efficiency of buildings. Accurate calculations ensure that insulation performs as expected, helping to maintain comfortable indoor temperatures while reducing energy costs.


One of the most essential tools for R-value calculation is a reliable calculator specifically designed for this purpose. Many online platforms offer free R-value calculators that allow users to input the type and thickness of various insulation materials within an assembly. These calculators then provide an estimated total R-value based on the inputs. Its important to choose a calculator from a reputable source, such as those provided by government agencies or well-established industry organizations.


In addition to online calculators, there are several software programs available that offer more advanced features for calculating R-values. These programs often include databases of common insulation materials and their corresponding R-values per inch. They may also account for factors such as air gaps, framing members, and other components that can affect the overall thermal performance of an assembly. Some software even allows users to model complex building envelopes and generate detailed reports.


For those who prefer traditional methods, printed reference guides and manuals can be valuable resources. Many insulation manufacturers publish technical data sheets that list the R-values of their products under various conditions. Building codes and standards organizations also produce guides that outline accepted methods for calculating R-values in different types of assemblies.


Its worth noting that while these tools and resources can provide accurate estimates, actual R-values may vary depending on real-world conditions such as installation quality and environmental factors. Therefore, its always a good idea to consult with experienced professionals who can offer practical advice based on their knowledge and experience in the field.


In conclusion, accurately calculating R-values for insulation assemblies requires access to reliable tools and resources. Whether you prefer online calculators, specialized software, or printed reference materials, there are plenty of options available to help you determine the thermal performance of your building envelope. By using these resources effectively and seeking expert guidance when needed, you can ensure that your insulation choices contribute to a more energy-efficient and comfortable living or working space.

Optimizing Insulation Assemblies for Cost-Effectiveness and Energy Efficiency

In the quest for cost-effective and energy-efficient buildings, optimizing insulation assemblies plays a pivotal role. A crucial aspect of this optimization process is calculating the R-values for these assemblies, which directly influences both the financial and environmental performance of a structure.


R-value, or thermal resistance, measures an insulation materials ability to resist heat flow. The higher the R-value, the greater the insulating effectiveness. When calculating R-values for insulation assemblies, its essential to consider not just individual components but how they interact within the whole system. This holistic approach ensures that we accurately predict the assemblys overall thermal performance.


To begin calculating R-values, one must first identify all materials in the assembly-from exterior cladding to interior finishes-and their respective thicknesses and R-values per inch. For instance, common insulation materials like fiberglass batts or spray foam have known R-values per inch that can be multiplied by their thickness to determine their contribution to the total assembly.


However, simply summing up these values isnt always sufficient due to factors such as thermal bridging-where structural elements like studs create paths of least resistance for heat transfer-or air gaps that can either enhance or diminish insulation effectiveness depending on their location and size. Advanced calculation methods often involve using computer simulations or adhering to standards like those set by ASHRAE (American Society of Heating, Refrigerating and Air-Conditioning Engineers) to account for these complexities.


Moreover, optimizing for cost-effectiveness requires balancing initial investment against long-term savings. Higher R-value materials might be more expensive upfront but could lead to significant reductions in heating and cooling costs over time. Conversely, less costly options might not provide adequate energy efficiency, leading to higher utility bills that offset any initial savings.


In practice, this means conducting a life-cycle cost analysis alongside R-value calculations. Such analyses consider factors like local climate conditions, expected lifespan of materials, maintenance costs, and potential rebates or incentives for energy-efficient upgrades. By integrating these considerations into our calculations, we can make informed decisions about which insulation assemblies offer the best balance between upfront costs and long-term benefits.


Ultimately, calculating R-values for insulation assemblies is more than just a technical exercise; its a strategic approach toward building sustainable structures that are both economically viable and environmentally responsible. Through diligent analysis and thoughtful design choices based on accurate R-value calculations, architects and builders can significantly enhance a buildings performance while keeping an eye on budgetary constraints-a true win-win in todays world where efficiency matters more than ever before.

"Carpenters" and "Carpenter" redirect here. For the American pop duo, see The Carpenters. For other uses, see Carpenter (disambiguation).
Carpentry
Occupation
Occupation type
 Professional
Activity sectors
 Construction
Description
Education required
 No
Carpentry includes such specialties as barrelmaker, cabinetmaker, framer, luthier, and ship's carpenter
Exhibit of traditional European carpenter's tools in Italy
Carpenters in an Indian village working with hand tools

Carpentry is a skilled trade and a craft in which the primary work performed is the cutting, shaping and installation of building materials during the construction of buildings, ships, timber bridges, concrete formwork, etc. Carpenters traditionally worked with natural wood and did rougher work such as framing, but today many other materials are also used[1] and sometimes the finer trades of cabinetmaking and furniture building are considered carpentry. In the United States, 98.5% of carpenters are male, and it was the fourth most male-dominated occupation in the country in 1999. In 2006 in the United States, there were about 1.5 million carpentry positions. Carpenters are usually the first tradesmen on a job and the last to leave.[2] Carpenters normally framed post-and-beam buildings until the end of the 19th century; now this old-fashioned carpentry is called timber framing. Carpenters learn this trade by being employed through an apprenticeship training—normally four years—and qualify by successfully completing that country's competence test in places such as the United Kingdom, the United States, Canada, Switzerland, Australia and South Africa.[3] It is also common that the skill can be learned by gaining work experience other than a formal training program, which may be the case in many places.

Carpentry covers various services, such as furniture design and construction, door and window installation or repair, flooring installation, trim and molding installation, custom woodworking, stair construction, structural framing, wood structure and furniture repair, and restoration.

Etymology

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The word "carpenter" is the English rendering of the Old French word carpentier (later, charpentier) which is derived from the Latin carpentarius [artifex], "(maker) of a carriage."[4] The Middle English and Scots word (in the sense of "builder") was wright (from the Old English wryhta, cognate with work), which could be used in compound forms such as wheelwright or boatwright.[5]

In the United Kingdom

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In the UK, carpentry is used to describe the skill involved in first fixing of timber items such as construction of roofs, floors and timber framed buildings, i.e. those areas of construction that are normally hidden in a finished building. An easy way to envisage this is that first fix work is all that is done before plastering takes place. The second fix is done after plastering takes place. Second fix work, the installation of items such as skirting boards, architraves, doors, and windows are generally regarded as carpentry, however, the off-site manufacture and pre-finishing of the items is regarded as joinery.[6][7] Carpentry is also used to construct the formwork into which concrete is poured during the building of structures such as roads and highway overpasses. In the UK, the skill of making timber formwork for poured or in situ concrete is referred to as shuttering.

In the United States

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Carpentry in the United States is historically defined similarly to the United Kingdom as the "heavier and stronger"[8] work distinguished from a joiner "...who does lighter and more ornamental work than that of a carpenter..." although the "...work of a carpenter and joiner are often combined."[9] Joiner is less common than the terms finish carpenter or cabinetmaker. The terms housewright and barnwright were used historically and are now occasionally used by carpenters who work using traditional methods and materials. Someone who builds custom concrete formwork is a form carpenter.

History

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Log church building in Russia reached considerable heights such as this 17th century example

Along with stone, wood is among the oldest building materials. The ability to shape it into tools, shelter, and weapons improved with technological advances from the Stone Age to the Bronze Age to the Iron Age. Some of the oldest archaeological evidence of carpentry are water well casings. These include an oak and hazel structure dating from 5256 BC, found in Ostrov, Czech Republic,[10] and one built using split oak timbers with mortise and tenon and notched corners excavated in eastern Germany, dating from about 7,000 years ago in the early Neolithic period.[11]

Relatively little history of carpentry was preserved before written language. Knowledge and skills were simply passed down over the generations. Even the advent of cave painting and writing recorded little. The oldest surviving complete architectural text is Vitruvius' ten books collectively titled De architectura, which discuss some carpentry.[citation needed] It was only with the invention of the printing press in the 15th century that this began to change, albeit slowly, with builders finally beginning to regularly publish guides and pattern books in the 18th and 19th centuries.

Some of the oldest surviving wooden buildings in the world are temples in China such as the Nanchan Temple built in 782, Greensted Church in England, parts of which are from the 11th century, and the stave churches in Norway from the 12th and 13th centuries.

Europe

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By the 16th century, sawmills were coming into use in Europe. The founding of America was partly based on a desire to extract resources from the new continent including wood for use in ships and buildings in Europe. In the 18th century part of the Industrial Revolution was the invention of the steam engine and cut nails.[12] These technologies combined with the invention of the circular saw led to the development of balloon framing which was the beginning of the decline of traditional timber framing.

Axonometric diagram of balloon framing

The 19th century saw the development of electrical engineering and distribution which allowed the development of hand-held power tools, wire nails, and machines to mass-produce screws. In the 20th century, portland cement came into common use and concrete foundations allowed carpenters to do away with heavy timber sills. Also, drywall (plasterboard) came into common use replacing lime plaster on wooden lath. Plywood, engineered lumber, and chemically treated lumber also came into use.[13]

For types of carpentry used in America see American historic carpentry.

Training

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Carpentry requires training which involves both acquiring knowledge and physical practice. In formal training a carpenter begins as an apprentice, then becomes a journeyman, and with enough experience and competency can eventually attain the status of a master carpenter. Today pre-apprenticeship training may be gained through non-union vocational programs such as high school shop classes and community colleges.

Informally a laborer may simply work alongside carpenters for years learning skills by observation and peripheral assistance. While such an individual may obtain journeyperson status by paying the union entry fee and obtaining a journeyperson's card (which provides the right to work on a union carpentry crew) the carpenter foreperson will, by necessity, dismiss any worker who presents the card but does not demonstrate the expected skill level.

Carpenters may work for an employer or be self-employed. No matter what kind of training a carpenter has had, some U.S. states require contractors to be licensed which requires passing a written test and having minimum levels of insurance.

Schools and programs

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Formal training in the carpentry trade is available in seminars, certificate programs, high-school programs, online classes, in the new construction, restoration, and preservation carpentry fields.[14] Sometimes these programs are called pre-apprenticeship training.

In the modern British construction industry, carpenters are trained through apprenticeship schemes where general certificates of secondary education (GCSE) in Mathematics, English, and Technology help but are not essential. However, this is deemed the preferred route, as young people can earn and gain field experience whilst training towards a nationally recognized qualification.

There are two main divisions of training: construction-carpentry and cabinetmaking. During pre-apprenticeship, trainees in each of these divisions spend 30 hours a week for 12 weeks in classrooms and indoor workshops learning mathematics, trade terminology, and skill in the use of hand and power tools. Construction-carpentry trainees also participate in calisthenics to prepare for the physical aspect of the work.

Upon completion of pre-apprenticeship, trainees who have passed the graded curriculum (taught by highly experienced journeyperson carpenters) are assigned to a local union and to union carpentry crews at work on construction sites or in cabinet shops as First Year Apprentices. Over the next four years, as they progress in status to Second Year, Third Year, and Fourth Year Apprentice, apprentices periodically return to the training facility every three months for a week of more detailed training in specific aspects of the trade.

In the United States, fewer than 5% of carpenters identify as female. A number of schools in the U.S. appeal to non-traditional tradespeople by offering carpentry classes for and taught by women, including Hammerstone: Carpentry for Women in Ithaca, NY, Yestermorrow in Waitsfield, VT and Oregon Tradeswomen in Portland, OR.

Apprenticeships and journeyperson

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Tradesmen in countries such as Germany and Australia are required to fulfill formal apprenticeships (usually three to four years) to work as professional carpenters. Upon graduation from the apprenticeship, they are known as journeyperson carpenters.

Up through the 19th and even the early 20th century, the journeyperson traveled to another region of the country to learn the building styles and techniques of that area before (usually) returning home. In modern times, journeypeople are not required to travel, and the term now refers to a level of proficiency and skill. Union carpenters in the United States, that is, members of the United Brotherhood of Carpenters and Joiners of America, are required to pass a skills test to be granted official journeyperson status, but uncertified professional carpenters may also be known as journeypersons based on their skill level, years of experience, or simply because they support themselves in the trade and not due to any certification or formal woodworking education.

Professional status as a journeyperson carpenter in the United States may be obtained in a number of ways. Formal training is acquired in a four-year apprenticeship program administered by the United Brotherhood of Carpenters and Joiners of America, in which journeyperson status is obtained after successful completion of twelve weeks of pre-apprenticeship training, followed by four years of on-the-job field training working alongside journeyperson carpenters. The Timber Framers Guild also has a formal apprenticeship program for traditional timber framing. Training is also available in groups like the Kim Bồng woodworking village in Vietnam where apprentices live and work to learn woodworking and carpentry skills.

In Canada, each province sets its own standards for apprenticeship. The average length of time is four years and includes a minimum number of hours of both on-the-job training and technical instruction at a college or other institution. Depending on the number of hours of instruction an apprentice receives, they can earn a Certificate of Proficiency, making them a journeyperson, or a Certificate of Qualification, which allows them to practice a more limited amount of carpentry. Canadian carpenters also have the option of acquiring an additional Interprovincial Red Seal that allows them to practice anywhere in Canada. The Red Seal requires the completion of an apprenticeship and an additional examination.

Master carpenter

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After working as a journeyperson for a while, a carpenter may go on to study or test as a master carpenter. In some countries, such as Germany, Iceland and Japan, this is an arduous and expensive process, requiring extensive knowledge (including economic and legal knowledge) and skill to achieve master certification; these countries generally require master status for anyone employing and teaching apprentices in the craft. In others, like the United States, 'master carpenter' can be a loosely used term to describe any skilled carpenter.

Fully trained carpenters and joiners will often move into related trades such as shop fitting, scaffolding, bench joinery, maintenance and system installation.

Materials

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The Centre Pompidou-Metz museum under construction in Metz, France. The building possesses one of the most complex examples of carpentry built to date and is composed of 16 kilometers of glued laminated timber for a surface area of 8,000 m2.

Carpenters traditionally worked with natural wood which has been prepared by splitting (riving), hewing, or sawing with a pit saw or sawmill called lumber (American English) or timber (British English). Today natural and engineered lumber and many other building materials carpenters may use are typically prepared by others and delivered to the job site. In 2013 the carpenters union in America used the term carpenter for a catch-all position. Tasks performed by union carpenters include installing "...flooring, windows, doors, interior trim, cabinetry, solid surface, roofing, framing, siding, flooring, insulation, ...acoustical ceilings, computer-access flooring, metal framing, wall partitions, office furniture systems, and both custom or factory-produced materials, ...trim and molding,... ceiling treatments, ... exposed columns and beams, displays, mantels, staircases...metal studs, metal lath, and drywall..."[15]

Health and safety

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United States

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Carpentry is often hazardous work. Types of woodworking and carpentry hazards include: machine hazards, flying materials, tool projection, fire and explosion, electrocution, noise, vibration, dust, and chemicals. In the United States the Occupational Safety and Health Administration (OSHA) tries to prevent illness, injury, and fire through regulations. However, self-employed workers are not covered by the OSHA act.[16] OSHA claims that "Since 1970, workplace fatalities have been reduced by more than 65 percent and occupational injury and illness rates have declined by 67 percent. At the same time, U.S. employment has almost doubled."[17] The leading cause of overall fatalities, called the "fatal four," are falls, followed by struck by object, electrocution, and caught-in/between. In general construction "employers must provide working conditions that are free of known dangers. Keep floors in work areas in a clean and, so far as possible, dry condition. Select and provide required personal protective equipment at no cost to workers. Train workers about job hazards in a language that they can understand."[18] Examples of how to prevent falls includes placing railings and toe-boards at any floor opening which cannot be well covered and elevated platforms and safety harness and lines, safety nets, stair railings, and handrails.

Safety is not just about the workers on the job site. Carpenters' work needs to meet the requirements in the Life Safety Code such as in stair building and building codes to promote long-term quality and safety for the building occupants.

Types of carpentry

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A team of carpenters assembling a Tarrant hut during World War I
  • Conservation carpenter works in architectural conservation, known in the U.S. as a "preservation" or "restoration"; a carpenter who works in historic preservation, maintaining structures as they were built or restoring them to that condition.
  • Cooper, a barrel maker.
  • Formwork carpenter creates the shuttering and falsework used in concrete construction, and reshores as necessary.
  • Framer is a carpenter who builds the skeletal structure or wooden framework of buildings, most often in the platform framing method. A framer who specializes in building with timbers and traditional joints rather than studs is known as a timber framer.
  • Log builder builds structures of stacked horizontal logs with limited joints.
  • Joiner (a traditional name now rare in North America), is one who does cabinetry, furniture making, fine woodworking, model building, instrument making, parquetry, joinery, or other carpentry where exact joints and minimal margins of error are important. Various types of joinery include:
    • Cabinetmaker is a carpenter who does fine and detailed work specializing in the making of cabinets made from wood, wardrobes, dressers, storage chests, and other furniture designed for storage.
    • Finish carpenter (North America), also trim carpenter, specializes in installing millwork ie; molding and trim, (such as door and window casings, mantels, crown mouldings, baseboards), engineered wood panels, wood flooring and other types of ornamental work such as turned or Carved objects. Finish carpenters pick up where framing ends off, including hanging doors and installing cabinets. Finish Carpenters are often referred to colloquially as "millworkers", but this title actually pertains to the creation of moldings on a mill.
    • Furniture maker is a carpenter who makes standalone furniture such as tables, and chairs.
    • Luthier is someone who makes or repairs stringed instruments. The word luthier comes from the French word for lute, "luth".
  • Set carpenter builds and dismantles temporary scenery and sets in film-making, television, and the theater.
  • Shipwright specializes in fabrication maintenance, repair techniques, and carpentry specific to vessels afloat. When assigned to a ship's crew would they would be known as a "Ship's Carpenter". Such a carpenter patrols the vessel's carpenter's walk to examine the hull for leaks.

Other

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  • Japanese carpentry, daiku is the simple term for carpenter, a Miya-daiku (temple carpenter) performs the work of both architect and builder of shrines and temples, and a sukiya-daiku works on teahouse construction and houses. Sashimono-shi build furniture and tateguya do interior finishing work.[19]
  • Green carpentry specializes in the use of environmentally friendly,[20] energy-efficient[21] and sustainable[22] sources of building materials for use in construction projects. They also practice building methods that require using less material and material that has the same structural soundness.[23]
  • Recycled (reclaimed, repurposed) carpentry is carpentry that uses scrap wood and parts of discarded or broken furniture to build new wood products.

See also

[edit]
  • Japanese carpentry – Distinctive woodworking style
  • Ship's carpenter – Ship crewman responsible for maintaining wooden structures
  • Traditional trades – Category of building trades
  • Woodworking – Process of making objects from wood
  • Worshipful Company of Carpenters – Livery company of the City of London

References

[edit]
  1. ^ Roza, Greg. A career as a . New York: Rosen Pub., 2011. 6. Print.
  2. ^ Vogt, Floyd, and Gaspar J. Lewis. Carpentry. 4th ed. Clifton Park, NY: Thomson Delmar Learning, 2006.xvi Print.
  3. ^ "Carpenter | Careers in Construction". www.careersinconstruction.ca.
  4. ^ The American heritage dictionary of the English language Archived June 7, 2007, at the Wayback Machine - Etymology of the word "carpenter"
  5. ^ The American Heritage Dictionary of the English Language: Fourth Edition. 2000.
  6. ^ "What's the Difference Between a Carpenter and a Joiner?" (30 April 2015). InternationalTimber.com. Retrieved 2 January 2020.
  7. ^ "Joiner vs Carpenter - What's the Difference?".
  8. ^ "Carpenter." Def. 1. Oxford English Dictionary Second Edition on CD-ROM (v. 4.0) © Oxford University Press 2009
  9. ^ Whitney, William D., ed. "Carpenter." Def, 1. The Century Dictionary: An Encyclopedic Lexicon of the English Language vol. 1. New York. The Century Co. 1895. 830. Print.
  10. ^ Rybníček, Michal; Kočár, Petr; Muigg, Bernhard; Peška, Jaroslav; Sedláček, Radko; Tegel, Willy; KoláÅ™, Tomáš (2020). "World's oldest dendrochronologically dated archaeological wood construction". Journal of Archaeological Science. 115: 105082. Bibcode:2020JArSc.115j5082R. doi:10.1016/j.jas.2020.105082. S2CID 213707193.
  11. ^ Prostak, Sergio (24 December 2012). "German Archaeologists Discover World's Oldest Wooden Wells". sci-news.com.
  12. ^ Loveday, Amos John. The cut nail industry, 1776–1890: technology, cost accounting, and the upper Ohio Valley. Ann Arbor, Mich.: University Microfilms International, 1979. Print.
  13. ^ Jester, Thomas C.. Twentieth-century building materials: history and conservation. New York: McGraw-Hill, 1995. Print.
  14. ^ [1] Archived April 28, 2009, at the Wayback Machine
  15. ^ "United Brotherhood Of Carpenters". carpenters.org. Retrieved 10 April 2015.
  16. ^ "Workers' Rights". osha.gov. Retrieved 10 April 2015.
  17. ^ "Commonly Used Statistics". osha.gov. Retrieved 10 April 2015.
  18. ^ "Safety and Health Topics - Fall Protection". osha.gov. Retrieved 10 April 2015.
  19. ^ Lee Butler, "Patronage and the Building Arts in Tokugawa Japan", Early Modern Japan. Fall-Winter 2004 [2]
  20. ^ "Environmentally Friendly Building Materials". McMullen Carpenters And Joiners. 2009-04-10. Archived from the original on 2013-06-28. Retrieved 2012-07-08.
  21. ^ "A Green Home Begins with ENERGY STAR Blue" (PDF). Energystar. Retrieved 8 September 2012.
  22. ^ "Green Building Basics". Ciwmb.ca.gov. Archived from the original on 2009-12-10. Retrieved 2012-05-21.
  23. ^ "Defining Green-Collar Jobs" (PDF). Archived from the original (PDF) on 2011-09-27. Retrieved 2009-07-07. There is no consensus on how to define green-collar jobs. A very broad interpretation of green jobs would include all existing and new jobs that contribute to environmental quality through improved efficiencies, better resource management, and other technologies that successfully address the environmental challenges facing society. Probably the most concise, general definition is "well-paid, career-track jobs that contribute directly to preserving or enhancing environmental quality" (Apollo Alliance 2008, 3). This definition suggests that green-collar jobs directly contribute to improving environmental quality, but would not include low-wage jobs that provide little mobility. Most discussion of green-collar jobs does not refer to positions that require a college degree, but they typically do involve training beyond high school. Many of the positions are similar to skilled, blue-collar jobs, such as electricians, welders, carpenters, etc.

[1]

[edit]
Look up carpentry in Wiktionary, the free dictionary.
 
Wikiquote has quotations related to Carpentry.
  • Media related to Carpentry at Wikimedia Commons
  • Carpentry at Wikibooks
  • "Carpentry" . Encyclopædia Britannica. Vol. 5 (11th ed.). 1911.
  • The Institute of Carpenters (England)
  • Carpenters entry in the Occupational Outlook Handbook of the Bureau of Labor Statistics of the United States Department of Labor
  • Carpentry for Boys (1914). James Slough Zerbe, The New York Book Company
 
 
 
  1. ^ What Is Carpentry

 

A structure or edifice is an encased structure with a roof covering, wall surfaces and home windows, typically standing completely in one area, such as a home or manufacturing facility. Structures are available in a selection of sizes, forms, and functions, and have been adjusted throughout history for various factors, from constructing materials readily available, to climate condition, land costs, ground problems, specific uses, stature, and aesthetic reasons. To much better recognize the concept, see Nonbuilding structure for comparison. Buildings serve several social needs –-- occupancy, largely as sanctuary from climate, safety, living area, personal privacy, to keep possessions, and to easily live and function. A building as a sanctuary represents a physical splitting up of the human environment (an area of comfort and safety) from the outside (an area that might be extreme and damaging sometimes). buildings have actually been items or canvasses of much artistic expression. In recent years, rate of interest in lasting planning and building practices has become a willful part of the design procedure of numerous new buildings and various other frameworks, usually green structures.

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