How are they made? The best engineered wood floors are built having 3-12 multiple ply layers that are cross layered, glued and pressed together.
Engineered wood floors - How are they made? The best engineered wood floors are built having 3-12 multiple ply layers (see picture below) that are cross layered, glued and pressed together. The inner core layers are are generally built up with either a hardwood and/or soft plywood type of material, which incorporates the tongue and groove system. The top thicker hardwood veneer wear layer is then glued and pressed on the top surface of the core. Engineered hardwood flooring is available in almost any wood species.The benefits of using engineered wood floors include more resistance to higher moisture levels than solid wood flooring, which adds to their appeal to use in damp basements or in regions of the country that have higher relative humidity levels. Also, engineered flooring (excluding the newer Click Lock flooring) can be direct glued-down over (dry) concrete slabs above or below grade or stapled down over a wood subfloor. Quality Engineered Hardwood flooring has the same resale value as 3/4 IN. solid wood flooring, if you ever decide to sell your home.Engineered Hardwood floors range in widths from 3-7 inches wide and in thicknesses from 3/8 - 3/4" they also come in a wide variety of domestic and exotic hardwood species and some are even available in the popular hand scraped styles. Some brands of engineered flooring have a thin .6 mm wear layer that can only be re-coated and cannot be sanded and refinished new again once they get worn. They have an average lifespan of between 20-30 years depending on traffic. Other brands or styles can have a thicker 2 - 6 mm thick wear layer that can be completely sanded and refinished 1- 5 times if they ever needed to be. These thicker wear layer engineered floors can last from 40 - 80 years before having to be replaced which add to their appeal.
Click Loc engineered flooring is becoming a more and more relevant trend in the engineered market. Click locking engineered boards have special tongue and groove systems that simply lock together, forming a tight seam and a seamlessly smooth appearance. Click locking floating engineered floors require absolutely no glue during installation and just float over a foam or cork underlayment. Click locking engineered floors can be installed on any grade level in the home and not only over traditional plywood or concrete subfloors, but also over old hardwood flooring, vinyl and tile as long as they are flat and well secured.
Engineered wood floors are manufactured two ways, one, where the top surface wear layer is Sliced/Sawn cut from the log like solid wood flooring is. Engineered hardwood flooring that has a Sliced/Sawn cut wear layer shows the truer natural look of the wood and finer graining. Sliced/Sawn cut engineered flooring also allows a thicker wear layer.
Engineered wood floors can also be Rotary cut, which the veneer hardwood wear layer is peeled off the log using big lathes. This peeling method can show dramatic wilder graining. engineered wood flooring cuts
Some homeowners think that engineered flooring is not as good as solid 3/4 IN. thick flooring because they are under the impression that it’s cheaply made. Well, as with all consumer products, manufacturers do make products at all levels of quality, each to fit a certain price point within the market. There are engineered floors on the cheaper end of the spectrum that are specifically manufactured to be affordable to a certain portion of the market. Sometimes, consumers are fooled into believing that these cheaper products are a bargain, but we would like to refute this belief.
There are a multitude of engineered floors on the market today that are made using the best raw materials available, for the prospective buyer who wants a top quality product for his or her home. You have probably heard of the popular adage “you get what you pay for.” This truism is most applicable towards the less costly engineered flooring that you will undoubtedly find at liquidators, home centers and discounter warehouses. These cheaper engineered floors are usually 3/8 IN. thick, have a paper thin wear layer and they are usually made overseas (China). At the other end of the price point spectrum, you will find very high end engineered floors that have an incredibly thick real wood wear layer that can, later on if ever needed, be sanded and refinished. The problem we have in the flooring industry is that the two different types of quality engineered flooring are often intermingled by retailers and the differences between them are either not known or is not often fully explained to the consumer. As a direct result of these missteps, in lots of cases the customer will purchase the cheaper floor that they see as a great bargain, only to have it fail once it’s installed in the home. At that point, an opinion is created and the consumer starts to think that all engineered flooring is of lesser quality than solid flooring. Even if your budget is tight, it is still possible to find a good quality engineered floor, if you know what to look for. The goal of this article is to help the consumer understand the differences between a low quality engineered floor and a high quality engineered floor and, ultimately, what to look for in the specifications of an engineered floor when shopping around.
All about the wear layer
When working with a standard 3/4 IN. thick solid floor, the sandable (or renewable) wear layer is approximately 5/16 IN. If you sand down a solid floor below this depth, you will start to expose the nails that were used to install it. Therefore, the maximum wear thickness on a 3/4 IN. solid floor is going to be 5/16 IN. You can sand and refinish 3/4 IN. thick flooring approximately 5-7 times over the lifetime of the floor. The average lifespan of 3/4 IN. thick solid wood flooring is approx 100 years.
With engineered flooring, wear layer thicknesses can vary greatly. Wear layers on engineered flooring can range anywhere from .6mm to 6mm. As an example, an engineered wood floor with a wear layer of 4mm (5/32 IN.) usually can be sanded and refinished 4-5 times over the lifetime of the floor. The average lifespan of an engineered floor with this 4mm wear layer is approximately 60-80 years.
What should your concerns be?
Your concern should be what your demands are going to be for that flooring and match those demands to the flooring as best you can. If the area that the new flooring is going to be installed is it going to receive a lot of rough traffic with little or no care or maintenance then you will want a engineered floor that has a thick wear layer that can be sanded and refinished new again later if it ever needed to be. If the area is not going to be heavily trafficked and will be maintained properly then you may not need as thick a wear layer. Quality Engineered floors are very durable and are commonly used in shopping malls which receive a lot of foot traffic.
Engineered wood flooring is Green
Purchasing engineered wood flooring helps conserve expensive prized wood. For every 1 sq foot of 3/4 inch thick solid wood flooring manufactured you can manufacturer approx 4 times that amount into engineered wood flooring. Engineered wood flooring is the best flooring to provide people with to conserve our forests.
that is designed for use as flooring, either structural or aesthetic. Bamboo flooring is often considered a wood floor, although it is made from a grass (bamboo) rather than a timber.
Solid hardwood floors come in a wide range of dimensions and styles, with each plank made of solid wood and milled from a single piece of timber. Solid hardwood floors were originally used for structural purposes, being installed perpendicular to the wooden support beams of a building Known as bearers and joists. Modern construction techniques rarely use bearers and joists for the subfloor construction with most homes built in Australia being of a concrete slab basis with a wood building frame, solid Australian hardwood floors are used almost exclusively for their appearance.
For flooring, solid wood has natural characteristics. Australian hardwoods are hygroscopic that means they acquire and lose moisture due to the ambient conditions around them. Typically, 100mm thick boards are the largest that can be manufactured from solid wood without compromising the structure of the flooring (some manufacturers produce wider boards using proprietary milling techniques). There is, however, no standard size which will perform well in every environment. For contemporary construction techniques, the most significant characteristic of solid wood floors is that they are able to be installed over concrete slab - the battening system having the least maintenance.
Wood flooring is a popular feature in many houses.Engineered wood flooring is composed of two or more layers of wood in the form of a plank. The top layer (lamella) is the wood that is visible when the flooring is installed, and is adhered to the core (or substrate) which provides the stability.
vinyl and veneer floors are often confused with engineered wood floors - laminate uses an image of wood on its surface, vinyl is plastic formed to look like wood, and veneer uses a thin layer of wood with a core that could be one of a number of different composite wood products (most commonly, high density fibreboard).
Engineered wood is the most common type of wood flooring used globally. North America is the only continent that has a larger solid wood market than engineered, although engineered wood is quickly catching up in market share.
A subcategory of engineered wood flooring is acrylic impregnated wood flooring. This product utilizes a real wood veneer that is impregnated with liquid acrylic and then hardened using a special process. Non impregnated Northern Red Oak typically tests at 1,290 on the Janka hardness scale and acrylic impregnated Northern Red Oak typically tests at 2,286 and 4,786 on the Janka hardness scale (ASTM D-143). Acrylic impregnated engineered wood flooring is normally used in high traffic interior spaces that require a high level of dent and wear resistance.
It is difficult to compare in generalities solid wood floor to engineered wood floors, as there is a wide range of engineered wood floor qualities. Engineered floors typically are pre-finished more often than solid wood floors, and usually are supplied with beveled edges, affecting the appearance. There are several limitations on solid hardwood that give it a more limited scope of use: solid wood should not be installed directly over concrete, should not be installed below grade (basements) and it should not be used with radiant floor heating. Solid hardwood is also typically limited in plank width and is more prone to "gapping" (excessive space between planks), "crowning" (convex curving upwards when humidity increases) and "cupping" (a concave or "dished" appearance of the plank, with the height of the plank along its longer edges being higher than the centre) with increased plank size.
Solid wood products, on average, have a substantially, or slightly, thicker 'sandable surface' (the wood that is above the tongue), and can be installed using nails. Lastly, solid wood tends to be less expensive than engineered wood, but this, as with the thickness of the 'sandable surface,' depends on the quality of the engineered wood (most inexpensive engineered wood products are 'veneer' wood floors, and not 'engineered'). In many installations, however, engineered flooring can only withstand a limited number of sandings, versus solid wood, which can be sanded many times.
Engineered wood flooring has several benefits over solid wood, beyond dimensional stability and universal use. Patented installation systems (such as "unilin" or "fiboloc") allow for faster installation and easy replacement of boards. Engineered wood also allows a 'floating' installation (where the planks are not fastened to the floor below or to each other), further increasing ease of repair and reducing installation time.
In general engineered wood panels are longer and wider than solid planks. The top surface of solid and engineered flooring have the same properties of hardness and durability.The development of "structural" engineered flooring now means engineered floors (often with 1/4 inch lamellas and birch ply backing) can be nailed directly over joists without the need for plywood sub-flooring.
Solid wood can be cut in three styles: flat-sawn, quarter-sawn, and rift-sawn. However, because only one side of the wood is visible on flooring, "quarter-sawn" and "rift-sawn" will have the same appearance. Many solid woods come with "absorption strips" - grooves cut into the back of the wood that run the length of each plank. They are used to reduce cupping. Solid wood floors are mostly manufactured at 3/4" thick with a tongue-and-groove for installation.
‹ The template below (Cleanup) is being considered for deletion. See templates for discussion to help reach a consensus.›
This article may require cleanup to meet Wikipedia's quality standards. (Consider using more specific cleanup instructions.) Please help improve this article if you can. The talk page may contain suggestions. (October 2011)
The lamella is the face layer of the wood that is visible when installed. Typically it is a sawn piece of timber.
The timber can be cut in three different styles: flat-sawn, quarter-sawn, and rift-sawn. However, because only one side of the wood is visible on flooring, "quarter-sawn" and "rift-sawn" will have the same appearance.
1) Wood ply construction ("sandwich core"): Uses multiple thin plies of wood adhered together. The wood grain of each ply runs perpendicular to the ply below it. Stability is attained from using thin layers of wood that have little to no reaction to climatic change. The wood is further stabilized due to equal pressure being exerted lengthwise and widthwise from the plies running perpendicular to each other.
2) Finger core construction: Finger core engineered wood floors are made of small pieces of milled timber that run perpendicular to the top layer (lamella) of wood. They can be 2-ply or 3-ply, depending on their intended use. If it is three ply, the third ply is often plywood that runs parallel to the lamella. Stability is gained through the grains running perpendicular to each other, and the expansion and contraction of wood is reduced and relegated to the middle ply, stopping the floor from gapping or cupping.
3) Fibreboard: The core is made up of medium or high density fibreboard. Floors with a fibreboard core are hygroscpoic and must never be exposed to large amounts of water or very high humidity - the expansion caused from absorbing water combined with the density of the fibreboard, will cause it to lose its form. Fibreboard is less expensive than timber but is not VOC (volatile organic compound) free and is not environmentally friendly.
4)An engineered flooring construction which is popular in parts of Europe is the hardwood lamella, softwood core laid perpendicular to the lamella, and a final backing layer of the same noble wood used for the lamella. Other noble hardwoods are sometimes used for the back layer but must be compatible. This is thought by many to be the most stable of engineered floors.
Wood can be manufactured with a variety of different installation systems:
1) Tongue-and-groove: One side and one end of the plank have a groove, the other side and end have a tongue (protruding wood along an edge's center). The tongue and groove fit snugly together, thus joining or aligning the planks, and are not visible once joined. Tongue-and-groove flooring can be installed by glue-down (both engineered and solid), floating (mostly engineered only), or nail-down (not recommended for most engineered).
2) "Click" systems: there are a number of patented "click" systems that now exist. These click systems are either "unilin" or "fiboloc" A "click" floor is similar to tongue-and-groove, but instead of fitting directly into the groove, the board must be angled or "tapped" in to make the curved or barbed tongue fit into the modified groove. No adhesive is used when installing a "click" floor, making board replacement easier. This system not only exists for engineered wood floors but also bamboo and a small number of solid floors (such as "parador solido click") and is designed to be used for floating installations. It is beneficial for the Do-It-Yourself market.
3) Floor connection system: There are a wide range of connection systems, as most of them are mill-specific manufacturing techniques. The general principle is to have grooves on all four sides of the plank with a separate, unconnected, piece that is inserted into the grooves of two planks to join them. The piece used for the connection can be made from wood, rubber, or plastic. This installation system allows for different materials (i.e. wood and metal) to be installed together if they have the same connection system.
4) Wood flooring can also be installed utilizing the glue-down method. This is an especially popular method for solid parquet flooring installations on concrete sub-floors. Additionally, engineered wood flooring may use the glue-down method as well. A layer of mastic is placed onto the sub-floor using a trowel similar to those used in laying ceramic tile. The wood pieces are then laid on top of the glue and hammered into place using a rubber mallet and a protected 2x4 to create a level floor. Often the parquet floor will require sanding and re-finishing after the glue-down installation method due to the small size pieces.
This process involves treating the wood by boiling the log in water at a certain temperature for a certain amount of time. After preparation, the wood is peeled by a blade starting from the outside of the log and working toward the center, thus creating a wood veneer. The veneer is then pressed flat with high pressure. This style of manufacturing tends to have problems with the wood cupping or curling back to its original shape. This problem is commonly known as "face checking" and is a manufacturing defect. Rotary-peeled engineered hardwoods tend to have a plywood appearance in the grain.
This process begins with the same treatment process that the rotary peel method uses. However, instead of being sliced in a rotary fashion, with this technique the wood is sliced from the end of a log, resulting in disc shaped veneers. The veneers then go through the same manufacturing process as rotary peeled veneers. Engineered hardwood produced this way tends to have fewer problems with "face checking", and also does not have the same plywood appearance in the grain. However, the planks can tend to have edge splintering and cracking due to the fact the veneers have been submersed in water and then pressed flat.
Instead of boiling the hardwood logs, in this process they are kept at a low humidity level and dried slowly to draw moisture from the inside of the wood cells. The logs are then sawed in the same manner as for solid hardwood planks. This style of engineered hardwood has the same look as solid hardwood, and does not have any of the potential problems of "face checking" that rotary-peel and slice-peel products have, because the product is not exposed to added moisture.
Finishing, refinishing, and sanding
The two most popular modern finishes for wood flooring are oil and polyurethane. Within both categories there are many variations and other names used to describe the finish. Oil and polyurethane also have very different refinishing and maintenance regimes.
1) Natural shellacs, lacquers, and varnishes were used in the past, as were waxes, often blended with oils.
2) Oil - Oiled floors have existed for several thousand years and is the most common floor finish used globally. Oil finished floors are made from naturally derived drying oils, and are not to be confused with petroleum based oils. Pre-finished oil floors can be UV cured. Most vegetable based oils are 100% natural and contain no VOCs.
2.1) Brushed and Oiled - Steel brushes are used in the direction of the grain which opens up the surface of the wood and removes splinters. The wood is then oiled.
3) Polyurethane - Polyurethane floor finishes were first introduced around 1940. There are several types of polyurethane finishes that exist, but the two most common are straight polyurethane and oil-modified polyurethane. Both products are sold under various names including: urethane, lacquer, and varnish. Many finish manufacturers and wood flooring manufacturers create brand names for their finish.
Sanding provides a method for smoothing an installed floor, compensating for unevenness of the subfloor. Additionally, sanding is used to renew the appearance of older floors. Sanding using successively finer grades of sandpaper is required to ensure even stain penetration when stains are used, as well as to eliminate visible scratches from coarser sandpaper grades used initially. Prior to modern polyurethanes, oils and waxes were used in addition to stains to provide finishes. Beeswax and linseed oil, for example, are both natural crosslinking polymers are hardened over time.
Care of wood floors
Proper use of vacuuming, sweeping, and damp mopping is usually all that is required to maintain the cleanliness and appearance of a wood floor. Oil soaps should not be used to clean the floors. The best suggestion is to use the manufacturers recommended cleaning products. Like tile floors, excessive grit and foot traffic will affect appearance. Unlike carpet or rugs, a properly finished wood floor, like tile, does not accumulate hidden soil or odorous compounds.