Rubber-basedmousepad Model No..CTO21742Description. SIZE.225*185*2.5MM PRICE. CARTONSIZE.400*250*300mm QUANTITY/CARTON.200pcs NETWEIGHT.20kg GROSSWEIGHT.21.5kg PRODUCTDESCRIPTION.Surfaceofthemousepadelasticjerseyclothorlycraclothis.

Rubber-basedmousepad Model No..CTO21741Description. SIZE.230*203*3mm PRICE. CARTONSIZE.430*250*200mm QUANTITY/CARTON.120pcs NETWEIGHT.11.5kg GROSSWEIGHT.13kg PRODUCTDESCRIPTION.Thesurfaceisusedelasticjerseyclothorlycracloth, whilet.

Rubber-basedmousepad Model No..CTO21740Description. SIZE.250*210*1.5mm PRICE. CARTONSIZE.260*220*170mm QUANTITY/CARTON.120pcs NETWEIGHT.9kg GROSSWEIGHT.10kg PRODUCTDESCRIPTION.Thesurfaceisusedcolorpaperfilm, whilethebottomisslide-pr.

Rubber-basedmousepad Model No..CTO21739Description. SIZE.230*205*2mm PRICE. CARTONSIZE.440*250*260mm QUANTITY/CARTON.240pcs NETWEIGHT.20.5kg GROSSWEIGHT.21.5kg PRODUCTDESCRIPTION.Thesurfaceisusedcolorpaperfilm, whilethebottomissli.

Rubber-basedmousepad Model No..CTO21738Description. CARTONSIZE.400*250*220mm QUANTITY/CARTON.120pcs NETWEIGHT.10.5kg GROSSWEIGHT.11.5kg PRODUCTDESCRIPTION.Surfaceofthemousepadelasticjerseyclothorlycraclothisused, andthebottomslid.

Rubber-basedmousepad Model No..CTO21738Description. CARTONSIZE.400*250*220mm QUANTITY/CARTON.120pcs NETWEIGHT.10.5kg GROSSWEIGHT.11.5kg PRODUCTDESCRIPTION.Surfaceofthemousepadelasticjerseyclothorlycraclothisused, andthebottomslid.

Rubber-basedmousepad Model No..CTO21741Description. SIZE.230*203*3mm PRICE. CARTONSIZE.430*250*200mm QUANTITY/CARTON.120pcs NETWEIGHT.11.5kg GROSSWEIGHT.13kg PRODUCTDESCRIPTION.Thesurfaceisusedelasticjerseyclothorlycracloth, whilet.

Rubber-basedmousepad Model No..CTO21740Description. SIZE.250*210*1.5mm PRICE. CARTONSIZE.260*220*170mm QUANTITY/CARTON.120pcs NETWEIGHT.9kg GROSSWEIGHT.10kg PRODUCTDESCRIPTION.Thesurfaceisusedcolorpaperfilm, whilethebottomisslide-pr.

Rubber-basedmousepad Model No..CTO21739Description. SIZE.230*205*2mm PRICE. CARTONSIZE.440*250*260mm QUANTITY/CARTON.240pcs NETWEIGHT.20.5kg GROSSWEIGHT.21.5kg PRODUCTDESCRIPTION.Thesurfaceisusedcolorpaperfilm, whilethebottomissli.

Rubber-basedmousepad Model No..CTO21742Description. SIZE.225*185*2.5MM PRICE. CARTONSIZE.400*250*300mm QUANTITY/CARTON.200pcs NETWEIGHT.20kg GROSSWEIGHT.21.5kg PRODUCTDESCRIPTION.Surfaceofthemousepadelasticjerseyclothorlycraclothis.

Po raz szósty publikujemy na naszych łamach - przygotowany przez Centrum Analiz Rynkowych - ranking największych przedsiębiorstw Polskiego Przemysłu Gumy i Kauczuków. Kolejne informacje o tym sektorze narodowej gospodarki będą mogli Państwo znaleźć na łamach kwartalnika Rubber Review, którego pierwszy numer, po długiej nieobecności na rynku, ukaże się we wrześniu tego roku. Ale zanim to nastąpi, zapraszamy do lektury sekcji kauczukowej Plastics Review. Polska jest już w UE. Koniunktura na globalnym rynku przetwórstwa kauczuków rośnie. Czy te korzystne fakty i tendencje zdołają wykorzystać polskie firmy? Wydaje się, że tak.

Turtle Wax Professional SYSTEM SILICONE FREE TRIM AND RUBBER CLEANER Czyści i regeneruje wszelkie wykończenia wewnętrzne i zewnętrzne wykonane z plastiku, gumy i…

A yellowish, amorphous, elastic material obtained from the milky sap or latex of various tropical plants, especially the rubber tree, and vulcanized, pigmented, finished, and modified into products such as electric insulation, elastic bands and belts, tires, and containers. Also called

units. With the development of synthetic rubbers having some rubbery characteristics but differing in chemical structure as well as properties, a more general designation was needed to cover both natural and synthetic rubbers. The term

Three requirements must be met for rubbery properties to be present in both natural and synthetic rubbers: long thread like molecules, flexibility in the molecular chain to allow

In the crude state, natural and synthetic rubbers possess certain physical properties which must be modified to obtain useful end products. The raw or unmodified forms are weak and

in varying ratios. However, in the most commonly used type, the ratio of butadiene to styrene is approximately 78:22. Unlike natural rubber, SBR does not crystallize on stretching and thus has low

and a diene, usually butadiene. The nitrile rubbers can be blended with natural rubber, polysulfide rubbers, and various resins to provide characteristics such as increased

Polysulfide rubbers have a large amount of surlfur in the main polymer chain and are therefore very chemically resistant, particularly to oils and solvents. They are used in such applications as putties, caulks, and hose for paint

gasoline, and fuel. Polyacrylate rubbers are useful because of their resistance to oils at high temperatures, including sulfur-bearing extreme-pressure lubricants.

or another agent that establishes chemical cross-links between the polymers. Fillers and other additives allow tailoring of properties to the desired use (e.g., by foaming, shaping, and curing). More than half of all rubber goes into making tires; the rest is used principally in belts, hoses, gaskets, shoes, clothing, furniture, and toys.

A highly resilient material, capable of recovering from large deformations quickly; manufactured from the juice of rubber trees as well as of other trees and plants.

Although rubber-yielding plants are native to Africa and Asia as well as to the Americas, the first mention of rubber in the West was made by Pietro Martire d'Anghiera, the Italian representative to the court of Spain (

waterproof bottles, and garments. Although a little rubber was used in Europe in the eighteenth century to make erasers—it derived its name "rubber" for its property of

and mixing machine granted to John J. Howe in 1820. Prompting these first steps was the profitable trade in crude rubber shoes imported into Boston and New York City from Brazil. By 1833, America's pioneering rubber factory was established at Roxbury, Massachusetts. Other rubber shoe and clothing factories soon appeared elsewhere in Massachusetts, as well as in New Jersey, Rhode Island, Connecticut, New York, and Pennsylvania. By 1840, the infant industry had experienced a speculative boom (about $2 million in stock was issued) and a disastrous collapse. The primary cause for the loss of confidence was that rubber products had not proven reliable—they softened in the heat and stiffened in the cold—but the

in general business conditions that began in the fall of 1837 only added to the industry's distress. So great were the industry's troubles that in 1843 the Roxbury Rubber Company sold the "monster" spreading machine (built by Edwin Marcus Chaffee in 1837) for $525; it had been purchased for $30,000.

Although experiments to cure rubber have been attributed to the eighteenth-century Swedish physician and pharmacist Petter-Jonas Bergius, it remained for

and white lead at a high temperature. His samples of "cured" rubber, with which he tried to raise funds in England, prompted the English inventor Thomas Hancock to make his own "discovery" of vulcanization. The "elastic metal" provided by these two inventors would soon prove

Yet long before the automobile appeared at the end of the nineteenth century, America's consumption of raw rubber had grown twenty fold—from 1,120 short tons in 1850 to 23,000 tons in 1900 (two-fifths of the world total of 59,000 short tons). Wherever elastic, shock-absorbing, water-resistant, insulating, and air-and steam-tight properties were required, vulcanized rubber was used. Most of the raw rubber came from Brazil, with Africa the second-most important source. The problem was not to find rubber but to find the labor to collect it in the almost

forests and ship it to the factories of the Northern Hemisphere. Until the systematic development of plantation rubber in Southeast Asia in the twentieth century made collection and transportation a comparatively easy task, the growing demand for crude rubber could only be met at increased cost. In 1830, Para rubber was 20 cents a pound; in 1900 the annual average

grew from 2,500 to 22,000. Because of the economies of scale and the absence of product differentiation, the market for rubber products was fiercely competitive—hence the tendency for the early rubber manufacturers to band together. Before the

marketing arrangements were already in existence to control the sale of footwear and other products. By the eve of World War I, production had come to be dominated by the "Big Four": Goodyear Tire and Rubber Company, United States Rubber Company, B. F. Goodrich Company, and Firestone Tire and Rubber Company. Partly to be close to the carriage-making industry—at the time the rubber industry's major consumer—the center of rubber manufacture had shifted from the towns of New England to Akron, Ohio. The industry's first branch factories were established in Western Europe in the 1850s.

tire in the early 1900s. Between 1900 and 1920, consumption of raw rubber increased tenfold—to 231,000 short tons. Even the world depression of the early 1930s only temporarily halted the industry's rapid expansion. By 1940, the United States was consuming 726,000 tons of a world total of 1,243,000 tons of crude rubber. Between 1900 (when the first four tons of Southeast Asia plantation rubber had reached the market) and 1910, the annual average wholesale price per pound of crude rubber doubled from $1 to $2. By 1915, more than twice as much rubber was coming from the plantations of Southeast Asia than from America and Africa combined, and prices had fallen to a quarter of their 1910 level; on 2 June 1932, the price was just three cents a pound.

Partly because of the great fluctuations in the price of crude rubber, and partly because the plantation industry of the Far East was largely in British hands, the industry began a search for rubber substitutes in the 1920s. In the next decade, manufacturers produced a few hundred tons a year of a special type of synthetic rubber. As Japan seized the rubber lands of Southeast Asia during World War II, U.S. production of synthetic rubber increased a hundredfold—from 9,000 short tons in 1941 to 919,000 tons in 1945, at which point synthetic rubber met four-fifths of America's needs. By 1973, of a world output of 6.3 million metric tons, the United States produced about 40 percent, almost three times more than the next greatest producer, Japan. That year, the United States had consumed only 696,000 metric tons of a world output of approximately 3.5 million tons of natural rubber.

rubber by making a wide range of elastomers and plastomers available, they changed the character of the industry until it was no longer possible to distinguish between rubber and rubber substitutes. The price of the synthetic compared favorably with that of the natural product, and for some uses synthetic rubber was preferable.

and the industry employed more than half a million workers. In 1987, the American rubber industry shipped $24.9 billion in goods, of which automobile tires accounted for $10.5 billion of that amount. According to the Environmental Protection Agency, more than 230,000 people were employed in the rubber industry in the United States in 1987. Although rubber was used in thousands of ways, automobile tires—with which the major technical developments in manufacture have been associated—continued to account for more than one-half of the industry's consumption of raw materials. The overwhelming size of the major rubber corporations (a fifth giant was added to the Big Four in 1915 when the General Tire and Rubber Corporation was formed at Akron) did not

the industry's competitive nature. After World War II, the tendency toward global expansion increased, and, in the late twentieth century, the major rubber manufacturers were worldwide in scope and operation.

which are high molecular weight compounds consisting of long chains of one or more types of molecules, such as monomers. Vulcanization (or curing) produces chemical links between the loosely coiled polymeric chains; elasticity occurs because the chains can be stretched and the crosslinks cause them to spring back when the stress is released. Natural rubber is a polyterpene, i.e., it consists of isoprene molecules linked into loosely twisted chains. The monomer units along the backbone of the carbon chains are in a

configuration leading to a crystalline solid at room temperature. Unvulcanized rubber is soluble in a number of hydrocarbons, including benzene, toluene, gasoline, and lubricating oils.

Rubber is water repellent and resistant to alkalies and weak acids. Rubber's elasticity, toughness, impermeability, adhesiveness, and electrical resistance make it useful as an adhesive, a coating composition, a fiber, a molding compound, and an electrical insulator. In general, synthetic rubber has the following advantages over natural rubber: better aging and weathering, more resistance to oil, solvents, oxygen, ozone, and certain chemicals, and resilience over a wider temperature range. The advantages of natural rubber are less buildup of heat from flexing and greater resistance to tearing when hot.

Natural rubber is obtained from the milky secretion (latex) of various plants, but the only important commercial source of natural rubber (sometimes called Pará rubber) is the tree

), a shrub native to the arid regions of Mexico and the SW United States. To soften the rubber so that compounding ingredients can be added, the long polymer chains must be partially broken by

mechanical shearing forces applied by passing the rubber between rollers or rotating blades. Thus, for most purposes, the rubber is ground, dissolved in a suitable solvent, and compounded with other ingredients, e.g., fillers and pigments such as carbon black for strength and whiting for stiffening;

; plasticizers, usually in the form of oils, waxes, or tars; accelerators; and vulcanizing agents. The compounded rubber is sheeted, extruded in special shapes, applied as coating or molded, then vulcanized. Most Pará rubber is exported as crude rubber and prepared for market by rolling slabs of latex coagulated with acid into thin sheets of crepe rubber or into heavier, firmly pressed sheets that are usually ribbed and smoked.

An increasing quantity of latex, treated with alkali to prevent coagulation, is shipped for processing in manufacturing centers. Much of it is used to make foam rubber by beating air into it before pouring it into a vulcanizing mold. Other products are made by dipping a mold into latex (e.g., rubber gloves) or by casting latex. Sponge rubber is prepared by adding to ordinary rubber a powder that forms a gas during vulcanization. Most of the rubber imported into the United States is used in tires and tire products; other items that account for large quantities are belting, hose, tubing, insulators, valves, gaskets, and footwear. Uncoagulated latex, compounded with colloidal emulsions and dispersions, is extruded as thread, coated on other materials, or beaten to a foam and used as sponge rubber. Used and waste rubber may be reclaimed by grinding followed by devulcanization with steam and chemicals, refining, and remanufacture.

The more than one dozen major classes of synthetic rubber are made of raw material derived from petroleum, coal, oil, natural gas, and acetylene. Many of them are copolymers, i.e., polymers consisting of more than one monomer. By changing the composition it is possible to achieve specific properties desired for special applications. The earliest synthetic rubbers were the styrene-butadiene copolymers, Buna S and SBR, whose properties are closest to those of natural rubber. SBR is the most commonly used elastomer because of its low cost and good properties; it is used mainly for tires. Other general purpose elastomers are

Among the specialty elastomers are copolymers of acrylonitrile and butadiene that were originally called Buna N and are now known as nitrile elastomers or NBR rubbers. They have excellent oil resistance and are widely used for flexible couplings, hoses, and washing machine parts. Butyl rubbers are copolymers of isobutylene and 1.3% isoprene; they are valuable because of their good resistance to abrasion, low gas permeability, and high dielectric strength. Neoprene (polychloroprene) is particularly useful at elevated temperatures and is used for heavy-duty applications. Ethylene-propylene rubbers (RPDM) with their high resistance to weathering and sunlight are used for automobile parts, hose, electrical insulation, and footwear. Urethane elastomers are called spandex and they consist of urethane blocks and polyether or polyester blocks; the urethane blocks provide strength and heat resistance, the polyester and polyether blocks provide elasticity; they are the most versatile elastomer family because of their hardness, strength, oil resistance, and aging characteristics. They have replaced rubber in elasticized materials. Other uses range from airplane wheels to seat cushions. Other synthetics are highly oil-resistant, but their high cost limits their use. Silicone rubbers are organic derivatives of inorganic polymers, e.g., the polymer of dimethysilanediol. Very stable and flexible over a wide temperature range, they are used in wire and cable insulation.

Pre-Columbian peoples of South and Central America used rubber for balls, containers, and shoes and for waterproofing fabrics. Mentioned by Spanish and Portuguese writers in the 16th cent., rubber did not attract the interest of Europeans until reports about it were made (1736–51) to the French Academy of Sciences by Charles de la Condamine and François Fresneau. Pioneer research in finding rubber solvents and in waterproofing fabrics was done before 1800, but rubber was used only for elastic bands and erasers, and these were made by cutting up pieces imported from Brazil. Joseph Priestley is credited with the discovery c.1770 of its use as an eraser, thus the name

The first rubber factory in the world was established near Paris in 1803, the first in England by Thomas Hancock in 1820. Hancock devised the forerunner of the masticator (the rollers through which the rubber is passed to partially break the polymer chains), and in 1835 Edwin Chaffee, an American, patented a mixing mill and a calender (a press for rolling the rubber into sheets).

In 1823, Charles Macintosh found a practical process for waterproofing fabrics, and in 1839 Charles Goodyear discovered vulcanization, which revolutionized the rubber industry. In the latter half of the 19th cent. the demand for rubber insulation by the electrical industry and the invention of the pneumatic tire extended the demand for rubber. In the 19th cent. wild rubber was harvested in South and Central America and in Africa; most of it came from the Pará rubber tree of the Amazon basin.

Despite Brazil's legal restrictions, seeds of the tree were smuggled to England in 1876. The resultant seedlings were sent to Ceylon (Sri Lanka) and later to many tropical regions, especially the Malay area and Java and Sumatra, beginning the enormous East Asian rubber industry. Here the plantations were so carefully cultivated and managed that the relative importance of Amazon rubber diminished. American rubber companies, as a step toward diminishing foreign control of the supply, enlarged their plantation holdings in Liberia and in South and Central America.

During World War I, Germany made a synthetic rubber, but it was too expensive for peacetime use. In 1927 a less costly variety was invented, and in 1931 neoprene was made, both in the United States. German scientists developed Buna rubber just prior to World War II. When importation of natural rubber from the East Indies was cut off during World War II, the United States began large-scale manufacture of synthetic rubber, concentrating on Buna S. Today synthetic rubber accounts for about 60% of the world's rubber production.

Are any of these polymers solvent resistant or age resistant natural rubber styrene butadiene nitrile rubber butyl rubber neoprene polysulfide rubber silicone rubber polyurethane?

Kliknij na „Pobierz instrukcję” na końcu tej umowy, jeśli akceptujesz jej warunki, wtedy rozpocznie się pobieranie instrukcji produktu firmy 3M BOND NEOPRENE RUBBER INSULATION TO CHILLER TANK OF COMMERCIAL AC.

Diplodocs kategorycznie zabrania korzystania z serwisu wszystkim, którzy nie zgadzają się z powyższymi warunkami. Akceptując lub pobierając instrukcję firmy 3M BOND NEOPRENE RUBBER INSULATION TO CHILLER TANK OF COMMERCIAL AC , potwierdzasz przeczytanie umowy, całkowite jej zrozumienie oraz zastosowanie się do jej warunków.

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Diplodocs pozwala na pobranie podręczników firmy 3M BOND NEOPRENE RUBBER INSULATION TO CHILLER TANK OF COMMERCIAL AC, poradników firmy 3M BOND NEOPRENE RUBBER INSULATION TO CHILLER TANK OF COMMERCIAL AC, instrukcji firmy 3M BOND NEOPRENE RUBBER INSULATION TO CHILLER TANK OF COMMERCIAL AC.

Malaysian Rubber Board (MRB) organised a one-day seminar on Design of Engineering Rubber Components on 3 November, 2008 at Akademi Hevea Malaysia, Sg Buloh, Selangor.

The Malaysian Rubber Exchange (MRE) hosted the 9th ASEAN Rubber Business Council Assembly meeting held on 25 October 2008 in Kuala Lumpur in conjunction with its Annual Dinner.

In conjunction with its 46th anniversary, the Malaysian Rubber Exchange (MRE) held its Annual Dinner on 24 October 2008 at Hilton Kuala Lumpur. More than 800 members and associates of the rubber industry, as well as their guests, attended the dinner, during which they interacted and renewed ties with one another.

Renowned invited speakers, experts, scientists and researchers from around the globe gathered in Kuala Lumpur for three days from 21 - 23 October, 2008 to share their knowledge and latest research findings on the development and opportunities available in the rubber industry.

The 13th International Tripartite Rubber Council (ITRC) meeting was held in Kuala Lumpur from 28-29 August 2008. The meeting was chaired by Y Bhg Dato' Dr Kamarul Baharain bin Basir, Director General of the Malaysian Rubber Board.

The Government and Malaysian Rubber Board shall not be liable for any loss or damage caused by the usage of any information obtained from this site.

Remember that all prices on this blog are not exact. Gatsby Moving Rubber is sold in a wide range of Prices. The prices given are just an idea of what you are expecting to pay. If you know of exact prices for each of the

With over 120 years experience, Avon Rubber p.l.c., is an innovative engineering group specialising in respiratory protection, defence and dairy markets. With a strong emphasis on research and development we design, test and manufacture specialist products from a number of sites in the USA and UK, serving markets around the world.

The Ergo Diver MousePad was one of the better products we received from Scythe Co.. If you have used a RatPadz or Everglide mousepad, then you will be familiar with this style of plastic mousepad. These pads differ from the more traditional rubber mousepads, in that they are made with a very hard, stiff plastic. They generally have the advantage of a lower coefficient of friction on the surface, so that the mouse moves easier. Here are the features of this mousepad, taken from Scythe Co.'s site. Features.

Description. The pad is square, with a curve cut out of the bottom for your wrist. It isn't as large as a RatPadz or Everglide pad, measuring 20cm x 20cm, or about 8 x 8. The top surface of the pad is rough to the touch, with many small bumps in the texture of the pad, which are supposed to help the precision of the mouse. The pad is farly lightweight, yet stiff enough that it doesn't bend at all. It also has nine rubber pads on the underside, which prevents it from sliding around quite well. We received three colors - black, blue, and green - all of which look good on your desk alongside your other peripherals. Results. I used the mousepad over a period of a few weeks in order to get a good sense of what it felt like, and to get adjusted to it. Because Scythe Co. included Teflon tape pieces with the mousepad, I decided to put them on my mouse over the existing pads on the bottom. However, because my Logitech optical mouse has 5 pads on the bottom, I took a fifth tape piece from a second mousepad package. So be warned, if your mouse has more than four pads on the bottom, you can't really put Scythe Co.'s on without making the mouse unbalanced. I don't really think these Teflon tape pieces are any better than the stock ones on most mice, so it's not a problem they didn't include enough. I only tested this pad with optical mice, as I don't own any ball mice anymore - although I'm sure the results would be similar on a ball mouse. When I first started using the pad, I felt like I was consistently losing control of my mouse. The mousepad was so slick that I had to hold the mouse back when moving it, so that I wouldn't lose control of it completely. However, this was a good problem, because it meant that once I got used to the pad, I could move the mouse much quicker than with my old rubber pad. I found that I could push the mouse on the pad and let go, and it would slide all over it. I could also spin it in circles, and it would keep spinning around when I released it. However, after using the mousepad for a few weeks, I found that the mouse no longer glided as well as it did initially. I inspected the surface of the pad, and found that a good amount of dust and dirt had built up in the rough surface. I followed Scythe Co.'s suggestions for cleaning, and sprayed some Windex cleaner on it, and wiped it off with tissue paper. This cleared the surface up completely, and returned it to a like-new state. I started by testing the pad with Quake III, which seemed like a good game to use a product like this, because it is very fast paced and requires twitchy aiming. Initially, I couldn't play at my usual skill because I was having trouble keeping the mouse from flying off the edge of the pad. Nevertheless, in ten minutes I was used to the pad, and I was playing better than I ever had. I'm not usually one to advise buying new hardware to increase your skill in games, because I think skill comes through practice instead of the computer one is playing on. Yet, I felt like I could move the mouse much faster in Quake, and this seemed to be helping me out quite a bit, as I could simply aim at people and move around quicker. Since then, I have been using the Ergo Diver MousePad exclusively, both in various applications in Windows, and in RTS and FPS games. The pad has worked well, giving me increased pointer speed, as well as increased precision. Conclusion. The only complaint I have with the Ergo Diver MousePad is that it is smaller than competitors' pads. While I don't find myself running out of area on it, I think that this is because I use a high mouse sensitivity in Windows and in games. If you are a person who is most comfortable with low sensitivity (pointer speed) in either Windows or in games, then this mousepad may not be the right one for you. However, if you prefer a higher mouse sensitivity, or if you don't mind occasionally picking up your mouse when you run out of real estate on the pad, then this would be a good pad for you. I wouldn't recommend it if you're not a gamer, because this pad only really starts to shine when you are doing something that requires quick mouse movement, such as an RTS or FPS. Matt's Moment. I also have been using this mousepad for a good month and I absolutely love it! I don't mind the small size at all. Pros. - Mouse moves very smoothly on it. - Many rubber pads on bottom keep pad from moving. Cons. - Smaller than other plastic mousepads. - Requires cleaning every few weeks (although this is also true of other plastic pads). - Only included four Teflon tape pieces, when my mouse originally had five.

Provide the Ultimate Mousing Surface for smoother tracking. Super sensative, not scratchy, and with an eggshell hardness, the Ultra Thin mousing surface responds to the very slightest movements of your hand and mouse for unsurpassed mousing precision. The UltraThin practically clings to your desktop, a fast track to smoother mousing. Easy, low-cost distribution is one of the biggest bonuses of the better mousetrap. Thinner than a business card, the UltraThin slips into a regular envelope like an ordinary business letter. UltraThins also insert seamlessly between the pages of a magazine like the subscription reply-cards that fall into your lap. It is very simply the most functional, useful, and therefore most valuable device ever to fit between two sheets of paper. UltraThin mousing surfaces utilize the amazing Friction Coat non-skid backing that eliminates the need for rubber or foam backs. Eliminating rubber and foam from a mouse pad greatly reduces the cost, weight and overall thickness of the product. It would take sixteen (16) UltraThins to equal one of the competitor's 1/4" foam mousepads. And if you've used a foam or rubber mousepad you know it is only a short mattter of time before it starts to wear down. Not UltraThins. There is no laminate to chip or peel. No rubber or foam to attract dust and other atmospheric particles. Should you be placing your expensive computer equipment and your computer mouse next to, or on top of, a dust magnet?