The present invention relates to screens, and more particularly, to woven insect screens.
Insect screens have been in use on windows and doors for more than a century. Their intended purpose is to keep out common insects such as flies, moths, mosquitoes, and bees as well as other creatures such as birds and rodents. Insect screens are used for many applications such as windows, doors, patio enclosures, pool enclosures, garage doors, and more.
Insect screens are typically woven from various types of fibers, historically starting from materials such as horsehair and linen. For greater durability, screens evolved to woven wire made of low-carbon steel, however, the steel was known to rust. Bronze, stainless steel, and aluminum wire replaced steel. In the 1970's, screens woven from vinyl (PVC) coated fiberglass fibers were introduced. These screens offered benefits of durability, light weight, ease of weaving, and ease of installation. Vinyl coated fiberglass screens offered a significant improvement over metal screens for ease of installation since common tools can cut and trim the screen materials without leaving sharp wires that can create safety issues. Vinyl coated fiberglass screens have become the industry standard for common insect screens.
Insect screens are primarily designed to exclude insects from an enclosed area while still offering the sensation of the outdoors by transmitting light, sound, and airflow. However, the basic woven fiber construction of a screen will inherently compromise visibility and airflow due to blockage of open area by the fibers. Visual quality can be expressed in terms of both light transmission as well as clarity. Light transmission relates to the quantity of light that passes through the screen. Clarity is a measure of image distortion cause by the interference of the fibers with the visual image as viewed through the screen. Woven screens can also restrict airflow causing reduced ventilation and reduced sensation of “feeling the breeze.”
Insect screen constructions have been optimized over the years in order to reach a compromise between excluding most insects and enabling reasonable visibility and airflow. Typically, the most common insect screens used today include 16×16, 18×14, 18×16, and 18×18 meshes of plain weave construction. “Mesh” describes the number of openings and fractional parts of an opening per linear inch. With a plain weave, mesh count typically corresponds with the fiber count for number of fibers per inch in the warp and fill. With increased mesh or fiber count, the opening or hole size decreases with fiber diameter remaining constant. In certain geographical regions where small biting midges and sand flies, also known as no-see 'ums, are present, 20 ×20 mesh screening is recommended to offer exclusion of these insects. However, the tradeoff for excluding small insects, such as midges, is not only a reduction in visual quality but also a reduction in airflow due to the loss of open area from the increased number of fibers. For example, to compensate for the loss of airflow caused by a 20×20 mesh screen, it is recommended to double the amount of screen surface area used for ventilation in order to equal the amount of unscreened window normally used; i.e., two screened open windows are required to equal the airflow of one unscreened open window.
Although the term mesh is typically used to describe the relative hole size of woven screening, this term gives no recognition to the diameter of the fiber or wire, and thus the mesh number does not always have a relationship to the size of the hole in the screen. Hole size, aperture, or opening is defined as the dimension between adjacent parallel wires, usually expressed in decimal parts of an inch. It can be calculated using the equation below for each of the warp and fill directions of the screen. Fill is defined as fibers or wires running across the width or short way of the woven cloth during weaving, also referred to as shute and weft. Warp is defined as the fibers of wire running lengthwise during weaving.
Opening=(1/N)−D
This equation remains accurate for screens woven from wire and fibers where the diameter of the material is unchanging. In the case of PVC coated fiberglass, the coating can melt flow during processing thereby changing the original fiber dimensions. The above formula can be used for these materials as well providing that the fiber diameter is measured in the final state assuming uniform fiber size and parallel fibers.
When comparing screens of different materials and constructions, it is important to make these comparisons using similar opening or hole size dimensions since the opening dimension provides the critical dimension for insect exclusion. Typically, insect screens can be defined by the fiber material, fiber diameter, and weaving construction (mesh or fibers per inch).
In order to understand the opening size commonly used in insect screening, a sampling of various commercial insect screens was compared. The properties and calculated openings are shown in the table below. Calculations in the table assumed mesh and fiber count to be identical. In addition to commercial screens, also included are examples of insect wire screens specified as American National Standards approved by the Insect Screening Weavers Association in 1990 document ANSI/IWS 089-1990.
As evidenced by the examples in the table, fiber or wire commonly used for window insect screening is known to have diameters ranging from 0.009 to 0.013 inches. It is important to note that the calculated hole width for the fiberglass screens used the indicated wire diameter as opposed to the actual wire diameter in the finished screen. Hole size and open area of PVC coated fiberglass screens typically have values less than the expected values due to flow of the PVC coating.
Various polymeric materials have been used for specialized greenhouse screening. This type of screening is used for the purposes of restricting very small insects and thereby negating the need to use pesticides. These screens are typically woven from small diameter polyethylene and nylon fibers into tight screen constructions to have very small hole sizes of less than 0.02 inches. These screens can be purchased from Green-tek under the names No-Thips and Virus Vector screens. These types of insect screens are not intended for residential insect screen applications because of poor visual clarity characteristics and limited airflow. Furthermore, fiber materials such as polyethylene and nylon are known to have poor UV radiation (sunlight) resistance, which can degrade the fiber strength over time. Thus, polyethylene and nylon screens are typically limited to a lifetime of three years or less. The lifetime of residential screens is expected to be many years, often five, ten, or more. For these reasons, polyethylene and nylon are not used as insect screens for windows, doors, patios, and other residential applications.
Typically, insect screens have either the warp or fill hole dimension to be less than about 0.05 inches in order to exclude most common flying insects, with the other hole dimension being larger than about 0.03 inches in order to offer acceptable airflow, visual clarity, and/or light transmission. In other words, the warp and fill dimension are not both below about 0.03 inches, nor are they both above about 0.05 inches. This hole size range for residential window screening is consistent with products offered and sold as window/insect screen. One example of screen sold for insect exclusion with a hole size larger than 0.05 inches in both the warp and fill dimensions is made of copper wire with a 16×16 mesh as described in the table above. This screen uniquely offers a historically accurate aesthetic appeal and does not fall into the hole size ranges depicted by the American National Standards of the Insect Screening Weavers Associations.
It has been recognized that optical attenuation and light distortion of window screens can be undesirable. U.S. Pat. No. 5,139,076 describes a distortion free window screen made from transparent fiber optic cables. It is the intention of this patent to increase the light transmission of the screen while minimizing distortion of the light passing through the fibers. They attempt to accomplish this by using clear, round cross-section, fibers. Although the total light transmission can be improved with clear fibers, distortion and glare will still exist due to reflection and refraction of the light rays through the clear fiber.
Another attempt to minimize the drawbacks of screen see-through visibility is described in U.S. Pat. No. 5,392,835. This patent describes a roll-type retractable insect screen that can be retracted when not in use. This type of technology enables the user to remove the screen from the field of view when not in use so as to provide a clear unobstructed view.
There are long-felt needs associated with current insect screen technology. These include the needs for improvement to optical transmission characteristics and airflow characteristics. In particular, there has been a long-felt need in the industry for an “invisible screen,” one that is less visible and hence less obstructive of the view through the screen. It is surprising that using smaller fibers for the screen construction would be effective because more fibers would be needed to provide the same hole sizes, thus not providing any real improvement in visibility.
The present invention is an improved insect screen designed to serve the primary purpose of keeping out insects and pests while maximizing visual clarity, light transmission, and airflow. The present invention employs the use of small diameter fibers woven into an insect screen with standard hole size construction. This construction is a warp and fill construction defining openings having a warp dimension and a fill dimension, at least one of the warp and fill dimensions being less than about 0.05 inches and the other of the warp and fill dimensions being larger than about 0.03 inches.
The present invention provides a non-metallic insect screen woven from fluoropolymer fibers, the fibers being from the fluoropolymer class including ETFE, ECTFE, PTFE, FEP, MFA, PFA, PEEK, and PVDF or hybrids thereof. PVDF fibers are particularly preferred. The invention also provides for metal fibers.
The present invention provides an insect screen woven from fibers with small diameters of about 0.007 inches or less, preferably diameters of about 0.006 inches or less, or more preferable of diameters of about 0.005 inches or less, or most preferably where the diameters are about 0.004 inches or less.
The present invention provides an insect screen with a total light transmission equal to about 75% or greater, preferably about 80% or greater, and more preferably about 85% or greater. Additionally, this present invention provides a non-metallic insect screen with a total light transmission greater than or equal to about 60%, preferably about 65% or greater, more preferably about 70% or greater, even more preferably about 75% or greater, then even more preferably of about 80% or greater and most preferably of about 85% or greater.
The present invention provides an insect screen with a specular light transmission of about 75% or greater, preferably about 80% or greater. Additionally, this present invention provides a non-metallic insect screen with a specular light transmission greater than or equal to about 60%, preferably about 65% or greater, and even more preferably about 70% or greater, then even more preferable of about 75% or greater, and most preferable of about 80% or greater.
The present invention provides an insect screen where the visual clarity factor is equal to or greater than about 55%, preferably greater than about 60%, still more preferably greater than or equal to about 65%, even more preferable greater than or equal to about 70%, and most preferable greater than or equal to about 75%. Additionally, the present invention provides a non-metallic insect screen where the visual clarity factor is equal to or greater than about 55% preferably about 60% or greater, and even more preferably about 65% or greater, then even more preferably about 70% or greater, and most preferably about 75% or greater.
The present invention provides an insect screen with the above elements wherein the fibers are clear, or in the preferred embodiment, where the fibers are dark or opaque to minimize the glare factors caused by refraction and reflectance.
The present invention provides an insect screen made from non-metallic fibers wherein a substantial number of fibers are bonded at the fiber intersections to form bonded intersections, and the fibers are bonded so as to maintain the original fiber cross section (preferably substantially round) in non-bonded regions between said bonded intersections. Preferably, such bonded intersections are thermally bonded, and more preferably thermally bonded via ultrasonic energy.
The present invention provides insect screen fabric which can be easily mounted and framed using conventional techniques such as spline and groove attachment.
In another aspect, this invention provides a method of making a woven fiber screen by providing non-metallic fibers having a cross-section; weaving the non-metallic fibers into a warp and fill construction defining openings having a warp dimension and a fill dimension, the fibers in the warp dimension and the fibers in the fill dimension intersecting at intersections; and ultrasonically bonding the fibers at at least some of the intersections to form bonded intersections without substantially disturbing the cross-section of the fibers between the bonded intersections.
The present invention is an improved insect screen material with remarkable light transmission and airflow properties. An embodiment of the present invention is illustrated in
In a preferred embodiment, this invention involves the use of fibers with diameters of about 0.007 inches or less woven into an insect screen having a particular hole size and construction. In other preferred embodiments, the fibers have diameters of less than about 0.006 inches, less than about 0.005 inches, and less than about 0.004 inches. By using fibers that are significantly smaller than current insect screen fibers, the light transmission and airflow increases substantially. Furthermore, by decreasing the fiber diameter, the fibers tend to become less visually apparent, thus creating an insect screen that is much more visually appealing.
The screens of the present invention can be of a variety of fiber materials. These materials can include, but are not limited to, standard metal materials such as aluminum, steel, bronze, copper, and stainless steel. These materials can also include non-metallic materials such as polyester, nylon, PVC coated fiberglass and others.
A factor that can affect screen durability is ultraviolet (UV) degradation, typically caused by sunlight exposure. It is known that most non-metallic fibers will degrade and lose strength after a few years of sunlight exposure due to UV degradation. PVC coated fiberglass screens exhibit this degradation with the PVC coating turning white and flaking off. It can be desirable to use non-metallic fibers as a screen material, but it becomes challenging to meet durability expectations if small fibers are used. Small diameter fibers already can be weaker in breakstrength than larger diameter fibers and with further UV degradation the fiber can fail prematurely. With these limitations, it is challenging for small diameter non-metallic insect screens to meet the typical industry expectations for lifetimes of five to ten years or more.
A novel aspect of the present invention is that in a preferred embodiment it incorporates the use of fluoropolymer fibers as the primary fiber for woven insect screen. Fluoropolymers offer a unique advantage for this application since they typically have extremely low UV light absorption, which enables the material to remain virtually unaffected when exposed to these often harmful wavelengths. Fluoropolymers that may be suitable for this application include, but are not limited to, fluoropolymers in the classes of ethylene tetrafluoroethylene (ETFE), ethylene chlorotrifluoroethylene (ECTFE), polytetrafluoroethylene (PTFE), fluorinated ethylene propylene (FEP), perfluoroalkoxy (PFA), tetrafluoroethylene perfluoromethylvinylether (MFA), tetrafluoroethylene hexafluoropropylene vinylidene fluoride (THV), polyetheretherketone (PEEK), and polyvinylidene fluoride (PVDF). Attributes that should be considered in material selection include strength, elongation, modulus, and processibility.
One of the preferred fluoropolymer fiber materials of this invention is PVDF. This material is readily melt processible thereby enabling fibers of uniform small diameters to be cost effectively fabricated. This material is also one of the stronger fluoropolymer materials thus offering enhanced durability. Also, this material can be bonded to itself through various bonding techniques thus being able to produce a preferable insect screen fabric where a substantial number of the fibers are bonded at their intersection points for improved stability.
Insect screens are typically manufactured by weaving monofilament or multifilament fibers using standard weaving processes. Weaving constructions can include plain, twill, satin, and others such as the leno weave. The most popular weave for metal and PVC coated fiberglass screens is the plain weave. This construction offers a simple cost effective process for fabricating an insect screen. One disadvantage of the plain weave is that the fiber construction can be loose and unstable depending on the openness of the fabric and rigidity of the fiber. PVC coated fiberglass screens overcome this issue by melt flowing the PVC coating to adhere the fibers at the intersections.
Another aspect of this invention is an insect screen of a non-metallic material that is bonded at the fiber intersections. Durably bonding polymer fibers can be particularly challenging. Adhesives can be used, however, excess adhesive may be inadvertently applied beyond the fiber intersections regions. Furthermore, adhesives tend not to be UV resistant. Another bonding approach is to use heat for melt bonding fiber at the intersections. This technique can be accomplished through various processing options, one of which uses heated calendering rolls. With this approach, special care needs to be taken to avoid melting the entire fiber outside of the intersection points regions. This melting can cause the fiber cross-section to flow and flatten resulting in a screen that has less light transmission and airflow. This problem is evident with PVC coated fiberglass insect screens in that the PVC coating flows during the thermal bonding process, which decreases the dimensions of the warp and fill openings. The result is a significant loss of 10% or more in light transmission yielding a screen of only about 55% light transmission. This bonding issue is typically limited to non-metallic insect screens since the fibers of metal screens tend to offer a more rigid and stable weave thereby negating the need for bonding of the fibers.
An inventive preferable method of bonding non-metallic fibers is through the use of ultrasonic energy. Heat can be generated locally at the fiber intersections by applying ultrasonic energy through an ultrasonic horn and anvil system. This process can be accomplished when the fabric is stationary using a plunge and activate method. Preferably, it may be accomplished in a continuous process using a horn and rotary anvil. Use of ultrasonics for bonding fibers in insect screens has unique inventive advantages. Since the process can generate heat for bonding isolated only to the fiber intersections, bonding can occur without heating the entire fiber. By controlling the applied heat, the fiber shape is less likely to distort. The result is a screen of fibers that substantially maintain their original cross section of the fibers in the non-bonded, non-intersecting regions. The end result is an insect screen that is substantially stable due to the bonds at fiber intersection, with very little flow of the fibers elsewhere. This non-metallic screen construction can offer higher light transmission and visual clarity properties than previously achieved.
Insect screens are available in a variety of colors ranging from black to green to white. Metal screens are typically painted or coated for color and corrosion resistance. It has been found that a darker color such as black is preferable in order to reduce reflective glare. Furthermore, a fiber that is opaque can reduce the transmitted refractive glare. Clear fibers can increase the total light transmission of a screen fabric but can suffer from reflective and refractive glare in certain applications.
Another aspect of this invention is an insect screen material that is suitable for mounting in a screen frame using a conventional spline and groove attachment. The majority of insect screens used in combination with window frames utilize this method for mounting and attachment. It is preferable that the screen construction enables this means for mounting and attachment.
Without intending to limit the scope of the present invention, the following examples illustrate how the present invention may be made and used.
An insect screen was fabricated in the following manner:
PVDF fiber was extruded using standard methodologies known in the industry. For this example, Albany International, of Albany, N.Y., extruded fiber at a diameter of 0.005 inches. This fiber had an average denier of 242 and average tenacity of 3.22 grams per denier. Clear fiber was extruded.
The fiber was then woven into a plain weave construction using standard weaving techniques. For this example, Prodesco of Perkasie, Pa. provided the weaving. The fiber was woven into a 52 inches wide construction screen having 20 picks per inch (ppi) by 17 picks per inch (ppi). The warp and fill openings (hole sizes) were measured to be 0.046″ and 0.053″ respectively.
This woven screen was then tested for light transmission properties. The results are listed in the table below.
Insect screen from Example 1 was then lightly painted with black semigloss spray paint. The paint used was Painter's Touch #1974 by Rust-oleum Corporation. The purpose of this paint was to simulate a black opaque fiber in order to conduct light transmission testing. This painted woven screen was then tested for light transmission properties. The results are listed in the table below.
The following method was used to evaluate light transmission properties for inventive and comparative insect screen materials. The comparative insect screen materials of PVC fiberglass (11 mil−18×14) and stainless steel (9 mil−18×14) were from New York Wire Co., Mt. Wolf, Pa. and TWP Inc., Berkeley, Calif. respectively.
Light Transmission Testing
The procedure to measure the optical properties of a screen material makes use of a spectrometer, specifically a Perkin Elmer Lambda 18 model suitable for measurements in the visible range of wavelengths. The spectrometer must have the capability to measure integrated reflectivity and transmission via an integrating sphere attachment like, for example, model RSA-PE-18 from Labsphere. The values obtained here require four different configurations: Specular+diffuse transmission (total transmission), Specular+diffuse reflectance (total reflectance), diffuse-only transmission and diffuse-only reflectance. The results are recorded in each instance in absolute percentages. With reference to
In Specular+Diffuse transmission mode, the sample is placed in port 1 and transmission of the beam in the forward direction (specular) as well as all hemispherically scattered transmission is recorded simultaneously. A 100% standard must be placed in port 2. For the diffuse-only transmission, the specular component of the transmitted light needs to be trapped by a light trap placed in port 2 with the sample in port 1.
Diffuse+Specular reflectance is measured by placing the sample into port 2. Care must be taken (since reflectance can be quite low) that a light trap is placed behind the sample so that any light, transmitted through the sample, cannot return back into the sphere via port 2. Appropriate background subtraction procedures should be applied. A measurement of diffuse reflectance eliminates specularly reflected light by placing another light trap into port 3 while having the sample, backed by a light trap, in port 2. This will measure only that light which is diffusely reflected into the intergrating sphere. Specular-only reflectance is calculated by subtracting diffuse-only reflectance from total reflectance.
Specular transmission is meant to depict the direct light that passes through the screen openings excluding diffuse transmission and the reflective components. This direct light represents the undistorted light emitted by the image to be viewed. This value was calculated by the following equation:
Specular transmission=total transmission−(diffuse transmission only)
Visual clarity factor is meant to describe the specular transmission of the image to be viewed through the screen while taking into account the negative effects of glare associated with the diffuse transmission as well as both the diffuse and specular reflective light components. This value was calculated by the following equation:
Visual clarity factor=Specular transmission−(diffuse transmission only+total reflectance)
The results of the testing are shown in the table below:
As can be seen from the table, the visual clarity of the working examples, demonstrated by the visual clarity factor, is considerably better than the comparative examples. This is quite a surprising result, because the hole sizes are similar in all the examples (working and comparative), and the pick count is higher with the working examples. Because the inventive screens have such better visual clarity, they are much more desirable for the industry, fulfilling the long-felt need for screens with better visual characteristics.
While particular embodiments of the present invention have been described herein, the present invention should not be limited to such descriptions. It should be apparent that changes and modifications may be incorporated and embodied as part of the present invention within the scope of the following claims.
This application is a continuation of U. S. patent application Ser. No. 10/405,104 filed Mar. 31, 2003.
Number | Date | Country | |
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Parent | 10405104 | Mar 2003 | US |
Child | 11369687 | Mar 2006 | US |