This logo can be used by brands / business with letter GT / TG company name. • 100% vector • AI / EPS files • CMYK / RGB • Unique and Original • Transparent Image • High Resolution! • 100% Satisfaction guaranteed • Print ready any size/vector files • Fully editable – all colors and text can be modified • Source Files
Need an initials logo? Shop our monogram collection to get instant access to a premade logo from your business name initials. *Every two-letter monogram combination is available, but not all are listed in this shop. Please contact us if you cannot find yours.* // DETAILS You will receive your monogram in black & gold as a • JPG file • PNG file with a transparent background • Vector PDF file which can be re-sized to as large or small as needed without the monogram losing quality // EDITING A written and video tutorial (video at bit.ly/2FfP7VP) is provided with instructions on how to change the color of your monogram. // FREE VENDOR RESOURCE GUIDE Using this as your wedding logo? Grab our FREE Vendor Resource Guide which will give you the best vendors for monogramming your napkins, cocktail cups, guest book + more with your digital monogram! www.elegantquill.com/guide // WEDDING MONOGRAM IDEAS Are you a wedding client? We've created Pinterest boards to help you get ideas on how to use your monogram at your wedding! Check them out at www.pinterest.com/elegantquill/boards // REFUND POLICY Your happiness is our top priority. Your monogram comes with a 30-day satisfaction guarantee. // TERMS OF USE • Unlimited use in personal projects and events. • You may modify the monogram to suit your or your client's needs. • Unlimited use with a single client. Please purchase again if a new client needs the same monogram. • Monogram must be purchased first even if you plan to create a hand-painted rendition of it. • If you want to use this monogram as your business logo you may. However, keep in mind that this monogram is sold more than once. • You may not trademark this monogram logo. • You may not use the monogram as part of a product that is for sale or distribution without my permission (please contact me). • You may not share, distribute, sub-license, resell, or rent the monogram. // COPYRIGHT INFRINGEMENT Always purchase a monogram first before using the design in your work. This includes hand-painted renditions of the monogram. Without purchasing first, reproduction of my monograms in any way is an act of copyright infringement which may result in me taking legal action.
Get this well crafted monogram GT logo design With a minimalist, clean and modern design, very suitable for the logo gt, monogram gt, gt logo
TG GT Monogram logo design designed by xcoolee. Connect with them on Dribbble; the global community for designers and creative professionals.
This Rhetorical Appeals Chart and Rhetorical Analysis Graphic Organizer Pack helps students more easily understand the rhetorical appeals: logos, pathos, and ethos! Make teaching rhetorical analysis an easier process! WHAT IS INCLUDED? Rhetorical Appeals Chart The chart with 2 options breaks down the meaning, so students can better comprehend the purpose of each appeal! Rhetorical Analysis Organizers Students can examine any piece of rhetoric and analyze logos, pathos, or ethos individually or ALL 3! Varied options are included to help with differentiation! JUST PRINT & TEACH! Want an easy way to teach 8 rhetorical texts? Click here >>>Rhetorical Analysis Writing Bundle
GT 2 designed by logofamous. Connect with them on Dribbble; the global community for designers and creative professionals.
TG GT Letter logo design designed by xcoolee. Connect with them on Dribbble; the global community for designers and creative professionals.
La marque Mini GT a annoncé cette nuit un partenariat avec Jun Imai, ancien designer de chez Mattel, pour une nouvelle gamme de miniatures
< HIPHOP > © 2017 by TIVSOY Hiphop Turns Me On. #tivography #minimalist #design #tivsoy @ello @ellodesign @ellominimal
A fun, fantastic and creative take on the word 'elevate' that has a clean, lofty and evocative sound> Possible uses: A salary comparison site. A construction company. A crowdfunding site. A consultant. A parenting brand.
“100 #AI companies in different stages of R&D, from emerging #startups to established #unicorns >>> @CBinsights via @MikeQuindazzi >>> #IoT #MachineLearning #DeepLearning #DataScience #DataAnalytics #VentureCapital >>> https://t.co/ChsABARTiY”
The Obsession
Preamble This is the eighteenth post in the "Art Resource" series, specifically aimed to construct an appropriate knowledge base in order to develop an artistic voice in ArtCloth. Other posts in this series are: Glossary of Cultural and Architectural Terms Units Used in Dyeing and Printing of Fabrics Occupational, Health & Safety A Brief History of Color The Nature of Color Psychology of Color Color Schemes The Naming of Colors The Munsell Color Classification System Methuen Color Index and Classification System The CIE System Pantone - A Modern Color Classification System Optical Properties of Fiber Materials General Properties of Fiber Polymers and Fibers - Part I General Properties of Fiber Polymers and Fibers - Part II General Properties of Fiber Polymers and Fibers - Part III General Properties of Fiber Polymers and Fibers - Part IV General Properties of Fiber Polymers and Fibers - Part V Protein Fibers - Wool Protein Fibers - Speciality Hair Fibers Protein Fibers - Silk Protein Fibers - Wool versus Silk Timelines of Fabrics, Dyes and Other Stuff Cellulosic Fibers (Natural) - Cotton Cellulosic Fibers (Natural) - Linen Other Natural Cellulosic Fibers General Overview of Man-Made Fibers Man-Made Cellulosic Fibers - Viscose Man-Made Cellulosic Fibers - Esters Man-Made Synthetic Fibers - Nylon Man-Made Synthetic Fibers - Polyester Man-Made Synthetic Fibers - Acrylic and Modacrylic Man-Made Synthetic Fibers - Olefins Man-Made Synthetic Fibers - Elastomers Man-Made Synthetic Fibers - Mineral Fibers Man Made Fibers - Other Textile Fibers Fiber Blends From Fiber to Yarn: Overview - Part I From Fiber to Yarn: Overview - Part II Melt-Spun Fibers Characteristics of Filament Yarn Yarn Classification Direct Spun Yarns Textured Filament Yarns Fabric Construction - Felt Fabric Construction - Nonwoven fabrics A Fashion Data Base Fabric Construction - Leather Fabric Construction - Films Glossary of Colors, Dyes, Inks, Pigments and Resins Fabric Construction – Foams and Poromeric Material Knitting Hosiery Glossary of Fabrics, Fibers, Finishes, Garments and Yarns Weaving and the Loom Similarities and Differences in Woven Fabrics The Three Basic Weaves - Plain Weave (Part I) The Three Basic Weaves - Plain Weave (Part II) The Three Basic Weaves - Twill Weave The Three Basic Weaves - Satin Weave Figured Weaves - Leno Weave Figured Weaves – Piqué Weave Figured Fabrics Glossary of Art, Artists, Art Motifs and Art Movements Crêpe Fabrics Crêpe Effect Fabrics Pile Fabrics - General Woven Pile Fabrics Chenille Yarn and Tufted Pile Fabrics Knit-Pile Fabrics Flocked Pile Fabrics and Other Pile Construction Processes Glossary of Paper, Photography, Printing, Prints and Publication Terms Napped Fabrics – Part I Napped Fabrics – Part II Double Cloth Multicomponent Fabrics Knit-Sew or Stitch Through Fabrics Finishes - Overview Finishes - Initial Fabric Cleaning Mechanical Finishes - Part I Mechanical Finishes - Part II Additive Finishes Chemical Finishes - Bleaching Glossary of Scientific Terms Chemical Finishes - Acid Finishes Finishes: Mercerization Finishes: Waterproof and Water-Repellent Fabrics Finishes: Flame-Proofed Fabrics Finishes to Prevent Attack by Insects and Micro-Organisms Other Finishes Shrinkage - Part I Shrinkage - Part II Progressive Shrinkage and Methods of Control Durable Press and Wash-and-Wear Finishes - Part I Durable Press and Wash-and-Wear Finishes - Part II Durable Press and Wash-and-Wear Finishes - Part III Durable Press and Wash-and-Wear Finishes - Part IV Durable Press and Wash-and-Wear Finishes - Part V The General Theory of Dyeing – Part I The General Theory Of Dyeing - Part II Natural Dyes Natural Dyes - Indigo Mordant Dyes Premetallized Dyes Azoic Dyes Basic Dyes Acid Dyes Disperse Dyes Direct Dyes Reactive Dyes Sulfur Dyes Blends – Fibers and Direct Dyeing The General Theory of Printing There are currently eight data bases on this blogspot, namely, the Glossary of Cultural and Architectural Terms, Timelines of Fabrics, Dyes and Other Stuff, A Fashion Data Base, the Glossary of Colors, Dyes, Inks, Pigments and Resins, the Glossary of Fabrics, Fibers, Finishes, Garments and Yarns, Glossary of Art, Artists, Art Motifs and Art Movements, Glossary of Paper, Photography, Printing, Prints and Publication Terms and the Glossary of Scientific Terms, which has been updated to Version 3.5. All data bases will be updated from time-to-time in the future. If you find any post on this blog site useful, you can save it or copy and paste it into your own "Word" document etc. for your future reference. For example, Safari allows you to save a post (e.g. click on "File", click on "Print" and release, click on "PDF" and then click on "Save As" and release - and a PDF should appear where you have stored it). Safari also allows you to mail a post to a friend (click on "File", and then point cursor to "Mail Contents On This Page" and release). Either way, this or other posts on this site may be a useful Art Resource for you. The Art Resource series will be the first post in each calendar month. Remember - these Art Resource posts span information that will be useful for a home hobbyist to that required by a final year University Fine-Art student and so undoubtedly, some parts of any Art Resource post may appear far too technical for your needs (skip over those mind boggling parts) and in other parts, it may be too simplistic with respect to your level of knowledge (ditto the skip). The trade-off between these two extremes will mean that Art Resource posts will hopefully be useful in parts to most, but unfortunately may not be satisfying to all! External Structure Of Fibers The external structure of s fiber consists of length, diameter, cross-sectional shape, surface contour, crimps or twists and distinctive parts etc. Whilst we have dealt with some of these characteristics previously, for completeness we shall give a quick overview of these external properties. Length Fibers are produced in basically two types: filaments and staple form. Filaments are long continuous strands; they can be natural such as in the case of silk or not natural such as man-made. The man-made filaments are either a mono-filament yarn (i.e. a single fiber type) or multifilament yarn (i.e. made from a number of tiny filaments with or without twists). In the latter form, the size and the number of filaments may vary, depending on the end-use of the fabric. Types Of Filament Fiber Yarns. A: Multifilament Yarn; B: Monofilament Yarn. Courtesy reference [1]. Staple fibers are either natural or man-made and are short in length (from 1 to 60 cm). All the natural fibers, except silk, are staple. Staple From Man-Made Fibers. Note: Fibers are uniformly cut lengths that have been fluffed. Courtesy reference [1]. Filament tow is a collection of many parallel filaments with crimp, but without twist and grouped together in rope form. Section of Filament Tow or Rope. Note: Thousands of filaments from which it is made. Courtesy reference[1]. Filament Tow Cut in Uniform Lengths. Note: This is required for ultimate use in fabrics and garments. Courtesy reference[1]. Diameter, Size or Denier Man-made fibers can be made uniform in diameter, can be varied in diameter shape, and can be made thick and thin at regular intervals throughout their length. Natural fibers are subject to growth irregularities and therefore are not uniform in size or in development along their length. The finer the diameter of the fiber, the more pliable it is and therefore the softer it feels. The thicker the fiber, the more body and stiffness it has and the more resistant it is to crushing. In natural fibers a major determinant of quality is the thickness of the fiber. Fiber thickness is measured in microns (10-6 meter). Hence cotton, wool and silk have thickness of 16-20, 10-70 and 11-12 microns. respectively. The fineness of man-made fibers is measured in deniers, which is the weight of 9,000 meters of yarn or fiber. It is the weight in grams of this unit length. Stable fiber is sold by denier and length, whereas filaments are sold by denier of the yarn or tow and the number of filaments in the yarn or tow. To determine the filament size, the yarn denier is divided by the number of filaments (i.e. 2 denier per filament is 40 denier yarn divided by 20 filaments). Carpets range from 15-24 deniers, whereas clothing from 1-7 deniers. Cross-Sectional Shape Fiber shape of man-made fibers is controlled by the spinneret. Shapes vary from round to flat and straw-like and are important because they help determine the texture of fabrics. For a silk like texture, trilobal fibers, which resemble silk in size and cross-section, are man-made. Shape is also important in luster, bulk and body, and helps to determine the hand or feel of the fabric. Natural fibers derive their shape from : (i) the way the cellulose is built up during the plant growth; (ii) the way the shape of the orifice through which the silk fiber is extruded; (iii) the way the shape of the hair follicle and the formation of protein substances in animals. The figure below shows typical cross-section shapes and fiber contours. Typical Cross-Section Shapes and Fiber Contours. Note: Surface smoothness or roughness is also exposed. Courtesy reference[1]. Surface Contour Surface contour may be smooth serrated, lobular or rough. The surface contour is defined as the surface of the fiber along its shaft. Some of the differences in the surface contour of the different fibers are shown in the figure above. Surface contour is important in the hand and texture of the fabric. Crimp Crimp refers to the waves, bends or twists that occur along the length of the fiber. Fiber crimp should not be confused with the weave crimp, which results from the interlacing of yarns in the fabric, nor with molecular crimp, which results from the way molecular chains are built up. Fiber crimp increases cohesiveness, resiliency, resistance to abrasion, and gives increased bulk and warmth to fabrics. It assist fabrics to maintain their loft or thickness, increases absorbency and skin-contact comfort, but reduces luster. A fiber may have three kinds of crimp, namely: mechanical crimp, natural or inherent crimp, or latent (chemical) crimp. Mechanical crimp is imparted to fibers by passing them through fluted rollers to produce a two-dimensional, saw-tooth crimp. The bends are angular in contrast to the rounded waves of a natural crimp. If the fluted rolls are heated, the crimp will be permanent in the thermoplastic or synthetic fibers. The figure below shows mechanical crimping gears. Texturizing processes to give loft, bulk or stretch are done on filament (sometimes staple fiber) yarns by dropping the yarns into a stuffing box, or running them through a false twister or subjecting them to a curling process. Natural or inherent crimp occurs in cotton and wool. Cotton has a two-dimensional twist called convolutions. Wool has three-dimensional crimp. The third type of crimp, latent or chemical, exists in the fiber in an undeveloped state until the finished garment is either: (i) immersed in a suitable solvent or; (ii) given a heat treatment to develop the crimp. This kind of crimp occurs in fibers that have been modified in the spinning solution or in the extrusion process. The modification produces a fiber that will shrink more on one side than it does on the other. High shrinkage of one side forces the fiber to curl. Mechanical Crimping Of Man-Made Fibers. Courtesy reference[1]. Distinctive Parts Natural fibers, except for silk, usually have three distinctive parts: (i) an outer covering called a skin or cuticle; (ii) an inner area; (iii) a central core that may or may not be hollow. On the other hand, man-made fibers are not so complex and usually have a skin and a solid core. Internal Structure Of Fibers We shall not labor on the internal structures of fibers, although their chemical structure, chemical composition, molecular structure and the regions of the fiber polymer system are all critical areas in understanding the properties of specific fibers. Rather we shall only give a brief overview of the latter. The fiber polymer system of a fabric can be explained in terms of the way in which polymer chains are orientated with respect to each other. The amorphous regions of a fiber polymer system have random orientations with respect to each other leaving large voids or spaces between them. These are also called the non-crystalline regions of the fiber polymer system. Hence in the figure (a) below there are two effects, not ordered and not orientated. The second type is when there are highly ordered or crystalline regions embedded amongst unordered or amorphous regions as in figure (b) below. Note: none of the ordered or crystalline regions are orientated with respect to each other. Also the crystalline regions always have much smaller voids or spaces then the amorphous regions. The third extreme is when the fiber polymer system is highly ordered or crystalline as well as highly orientated in a particular direction. Figure (c) show both properties, namely highly ordered and highly orientated. Orientation and Order of Fiber Polymer System. (a) Non Orientated Non-crystalline Fiber Polymer System; (b) Non-Orientated but Sections Ordered Fibre Polymer System; (c) Orientated and Crystalline Fiber Polymer System. It is clear that the amount of crystallinity (ordered regions) and the amount of orientation of the ordered regions will affect a myriad of properties such as dye-ability, tensile strength, hand of the fabric, stretching and drawing properties etc. Note: stretching or drawing of a fiber increases the orientation of the fiber, reduces its diameter and packs the polymer chains closer together. (a) Non-Stretched or Undrawn Fiber; (b) Stretched or Drawn Fiber. Fiber Properties and How They Affect Fabrics To make matters simple, we will do the translation under three headings: Fiber Property Reason For Fiber Property Translation Into Fabric Property Fiber Property: Abrasion resistance is the ability of the fiber to resist damage due to rubbing or abrasion during every day use. Reason For Fiber Property: This is due to: (i) the tough outer layer, scales or skin of fiber; (ii) the flexible and strong bonds within the fiber polymer system. Translation Into Fabric Property: Affects the following properties of fabrics: (i) its durability; (ii) its abrasion resistance; (iii) its rubbing resistance; (iv) its resistance to splitting. Fiber Property: Absorbency is the ability of a fiber to take up moisture and is expressed in terms of moisture regain (which is the percentage of moisture that a bone-dry fiber will absorb from air under standard conditions of temperature and moisture). Reason For Fiber Property: This is due to: (i) the fiber polymer system contains hydroxyl groups (-OH); (ii) the fiber polymer system have large amorphous regions and low regions of crystallinity. Translation Into Fabric Property: It affects the following properties of a fabric: (i) comfort; (ii) warmth; (iii) water repellency; (iv) absorbency; (v) static electricity build up; (vi) shrinkage; (vii) dyeability; (viii) wrinkle resistance and crease recovery; (ix) tear strength; (x) spotting. Fiber Property: Ageing resistance. Reason For Fiber Property: This is due to the chemical structure of the fiber polymer system. Translation Into Fabric Property: This affects the durability and long lived storage of the fabric. Fiber Property: Chemical reactivity is the effect of acids, alkali, oxidizing agents and solvents on the fiber. Reason For Fiber Property: The fiber polymer system contains polar groups and so its chemical structure is the cause for this fiber property. Translation Into Fabric Property: Helps to determine care required during cleaning of the fabric - such as its ability to withstand bleaching, and to take acid or alkali finishes. Fiber Property: Cover is the ability of the fiber to occupy space for the purpose of concealment or protection. Reason For Fiber Property: This results from the crimp, curl or twist of the fiber and its cross-sectional shape. Translation Into Fabric Property: It affects the warmth of the fabric and its cost, since less fiber is required. Fiber Property: Cohesiveness is the ability of fibers to cling together during spinning. This is an important property in staple but not in filament. Reason For Fiber Property: This is caused by the crimp or twist property of the fiber. Translation Into Fabric Property: This affects the fabrics resistance to ravelling. Fiber Property: Creep is delayed elasticity; that is, the fiber does not recover immediately from the strain but will recover gradually. Reason For Fiber Property: This is due to the lack of side chains, cross links and strong bonds within the fiber polymer system as well as because of its poor orientation. Translation Into Fabric Property: It affects the levelness of the fabric when dyed. A high creep fiber may cause the fabric to dye streakily. Fiber Property: Density of the fiber is a measure of its mass relative to its volume and so has units of gm per millimeter (g ml-1). Specific gravity is the ratio of the mass of the fiber to an equal volume of water at 4oC. Both measure the weight of a fiber. Reason For Fiber Property: This is due to the chemical composition of the fiber polymer system. Translation Into Fabric Property: It affects the fabric's: (i) warmth without weight; (ii) loftiness - full and light; (iii) buoyancy. Fiber Property: Dye-ability is the ability of fibers to be dyed. Reason For Fiber Property: There are numerous fiber properties that contribute to its dye-ability and for that matter, some of these properties preclude the use of particular dye types in preference for other dye types etc. The major fiber properties with respect to dye-ability depend on: (i) Chemical structure of the fiber (e.g. reactive groups and dye sites in the fiber polymer system); (ii) molecular structure such as its orientation, crystallinity, cross linkages, hydrogen bonding etc. within the fiber polymer system; (iii) fiber diameter. Translation Into Fabric Property: Affects the ability of a fabric to be dyed or printed with a particular dye type. Fiber Property: Elastic recovery is the ability of fibers to recover from strain. Elasticity is the ability of a stretched material to return immediately to its original size. Fibers usually have high elasticity for low stretches and high elasticity for high stretches. Reason For Fiber Property: This is due to the molecular structure - such as side chains, cross-linkages and strong bonds - within the fiber polymer system. Translation Into Fabric Property: This affects the fabric's process-ability, resiliency and delayed elasticity or creep. Fiber Property: Electrical conductivity is the ability of a fiber to transfer electrical charges (such as electrons) along its length and breadth. Reason For Fiber Property: This is due to the chemical structure (i.e. existence of polar groups) within the fiber polymer system. Translation Into Fabric Property: Poor conductivity causes: (i) fabric to cling to a person in cold dry atmospheres; (ii) promotes the build up of static charge causing electrical shocks; (iii) causes fabrics to cling to machinery during fabric and garment production. Fiber Property: Elongation is the ability for a fiber to be stretched, extended or lengthened. For production of yarns and fabrics a minimum of 10 per cent elongation is desirable. Elongations vary at different temperatures, or when the fiber is wet or dry. Reason For Fiber Property: This is due to the fiber crimp and/or to the molecular structure of its fiber polymer system (e.g. molecular crimp orientation). Translation Into Fabric Property: It affects: (i) working of textiles; (ii) fabrics tear strength; (iii) fabrics brittleness; (iv) provides "give" and stretchiness of fabrics. Fiber Property: Feltability is the ability of fibers to mat together. Reason For Fiber Property: This is associated with the scale structure of wool. Translation Into Fabric Property: Enhances the ability to make fabrics directly from fibers; special care required during washing in order to avoid unintended felting. Fiber Property: Flammability is the ability of a fiber to ignite and burn. Reason For Fiber Property: This is due to the chemical composition of the fiber polymer system. Translation Into Fabric Property: The flammability of the fabric is controlled by the flammability of the fiber. Fiber Property: Hand is the way a fiber and fabrics feels when handled - silky, harsh, soft, crisp, dry and tactile are just some descriptors of the handle or hand of a fabric. Reason For Fiber Property: This is due to the outside or external structure of the fiber; that is, is due to the fiber's diameter, cross-sectional shape, its crimp and length etc. Translation Into Fabric Property: It affects the handle or hand of the fabric. Fiber Property: Heat conductivity is the ability of the fiber to conduct heat away from the body. Reason For Fiber Property: This is due to the fiber's external structure; that is, it is due to its crimp, cross-sectional shape and the uniformity of its cross-section shape. Translation Into Fabric Property: It affects the warmth of a fabric. Fiber Property: Heat sensitivity is the ability of the fiber to soften, melt or shrink when subjected to heat. Reason For Fiber Property: This is due to the inner structure of the fiber; that is, there are fewer inter-molecular attractive forces, and no cross links within the fiber polymer system. Heat causes the molecular structure and/or molecular groups within the fiber polymer system to vibrate more vigorously. Translation Into Fabric Property: This property determines safe washing and ironing temperatures of the fabric; makes heat setting the fabric possible; makes certain heat sensitive fabric finishes possible. Fiber Property: Luster is the light reflected from the surface of the fiber. It differs from shine in that it is more subdued; that is, in the case of luster the reflected light is more scattered, whereas for shine the reflected light is better bundled in a given direction. Reason For Fiber Property: This is due to the external structure of the fiber; that is its length, crimp and cross-sectional shape. Translation Into Fabric Property: It affects the luster or shine of the fabric. Fiber Property: Loft or compressional resiliency refers to the ability of the fiber, yarn or fabric to spring back to its original thickness after being compressed. Reason For Fiber Property: This is due to the fiber crimp. Translation Into Fabric Property: It affects fabric's springiness, cover and resistance to flattening. Fiber Property: Moth resistance. Reason For Fiber Property: This is due to chemical composition of the fiber (e.g. no sulfur being present in the fiber polymer system). Translation Into Fabric Property: It affects level of care during storage of the fabric. Fiber Property: Mildew Resistance. Reason For Fiber Property: This is due to the chemical composition of the fiber polymer system. Translation Into Fabric Property: It affects level of care during storage and moreover, the selection of fabrics for damp, humid conditions. Fiber Property: Pilling is the balling up of fiber ends on the surface of fabrics. Reason For Fiber Property: This is associated with fiber strength. Translation Into Fabric Property: It affects extent of pilling of fabric. Fiber Property: Stability is the retention of size, shape or form of the fiber. Reason For Fiber Property: This is due to the chemical composition of the fiber polymer system (e.g. strong molecular bonds). Translation Into Fabric Property: It affects the fabrics resistance to shrinkage. Fiber Property: Stiffness or rigidity is the opposite to flexibility. It is the resistance to bending or creasing of the fiber. Reason For Fiber Property: This is due to the amount of crystallinity of the fiber polymer system. Translation Into Fabric Property: It affects the handle and body of the fabric. Fiber Property: The strength of the fiber is defined as the ability to resist stress and is expressed as tensile strength (pounds per square inch) or tenacity (grams per denier). Reason For Fiber Property: This is due to molecular structure of the fiber polymer system (e.g. degree of polymerization, orientation, crystallinity etc.). Translation Into Fabric Property: It affects the fabric's: (i) durability; (ii) tear strength); (iii) sagging characteristics; (iii) extent of pilling; (iv) fabric weight. Fiber Property: Sunlight resistance is the ability of a fiber to withstand degradation from direct sunlight (usually the UV component). Reason For Fiber Property: This is due to the chemical composition of the fiber polymer system. Translation Into Fabric Property: It affects the durability of outdoor cloths, swim wear, curtains and draperies etc. Reference: [1] N. Hollen and J. Saddler, Textiles, 3rd Edition, The Macmillan Company, London (1971).
In today’s crowded business landscape, having a strong brand identity and memorable corporate logo design is crucial for companies to stand out. Your brand logo acts as the visual ambassador and…
AirtelTigo Recruitment 2023/2024 Application Form Portal. Are you interested in AirtelTigo Recruitment 2023? Then you are on the right post.
Une identité visuelle réussie. Helmo, c'est Thomas Couderc et Clément Vauchez. Ils sont graphistes. Ils conçoivent des affiches, des livres, des
This science art print dedicated to the botanist and zoologist Carl Linnaeus! It features a taxonomy tree illustration and makes gift for a botanist or science lover! • Printed on high quality digital paper with a semi-gloss finish • Print only - does not come matted or framed Carl Linnaeus, born in 1707, was a Swedish botanist and zoologist. This rock star scientist is most known for devising the formal two-part naming system called 'binomial nomenclature' that we use it to classify all lifeforms. The first part of the name identifies the genus to which the species belongs and the second part identifies the species within the genus. >> Biology mosaic: https://www.etsy.com/listing/129043497/biology-gift-science-art-biology-poster >> Linnaeus t-shirt: https://www.etsy.com/listing/105986066/science-shirt-teacher-shirt-gift-for-men - - - - - - - - - - - - - - - - Images ©Megan Lee Studio, LLC No images may be reproduced, resold or used in any way without written consent. By purchasing this item you agree to my shop policies: https://www.etsy.com/shop/meganlee#policies
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Here are the Back to School Top Deals we are seeing at Staples this week Jul 20 - Jul 26. Be sure to watch for these posts every week this summer as the
Color is a complicated creature that can make us feel hot and bothered one minute, and warm and gooey the next! For a designer creating business cards, flyers, logos, websites, etc, color is everything. It is the fundamental driving force of a design and can be the difference between design failure or success. Here's an infographic guide to color and its meaning.
Channel 7 Turkey Geometric Sans-Serif Number, Number 7, Broadcast, TV. Oval shape with Seal technique and Flat effect in Red.
Een IPE balk wordt meestal toegepast als ligger in constructie doeleinden en kan afhankelijk van de maat een flinke belasting verdragen. Het draagvermogen ligt wel lager dan bij die van een H balk, zoals HEM balk, HEB balk of HEA balk. Een stalen IPE200 constructiebalk is 200 mm (hoogte), 100 mm (breedte) en bevat een wanddikte van 5,6 mm (flens tw) tot 8,5 mm (flens tf) De IPE 200 kan eventueel op aanvraag worden ingekort met een snijbrander. LET OP! Het zijn gebruikte balken dus er kunnen zogenoemde lippen, flenzen & boorgaten inzitten. De constructiebalken zijn hierbij niet altijd standaard voorzien van kop- & voetplaten. De staat van de balk wordt uitgedrukt in letters. G : GemeniedR : OnbehandeldB : BehandeldV : VerfAangegeven prijs is per hele balk en verzending is mogelijk op aanvraag.
A smart, masterful and confident name that evokes the words 'certain', 'certainty', 'certify' and 'certificate'> Possible uses: An appraisal service. A security firm. An insurance company. A research company. An analytics platform.
9" x 9" laminated adhesive topper. Super easy to apply! Just peel and stick! ****this is a rush service! I send will send your design and instructions to your local Fedex for them to make What you need to know: - Fedex charges around 10 dollars -does not include center hole cut - I need your name and number and your local FedEx number - your local FedEx may not offer this but most do -timing depends on number of customizations needed Graduate in style and walk with pride while inspiring others to be great! Customization is available!
Adam Opel AG - Founded: 1862. Headquarters: Rüsselsheim, Hesse, Germany. Parent: General Motors.
There’s an enduring nature to vintage logos crafted with simplicity and a focus on one idea. From the book World of Logotypes.
Cy répond à des questions d'éducation sexuelle dans des planches publiées sous le nom de Point Cul... Et ça fait du bien !
Hulpfiches: verdubbelen en verenkelen, vervoeging van werkwoorden (t, d of dt), cht of gt.
GT Sectra is a serif typeface combining the calligraphic influence of the broad nib pen with the sharpness of the scalpel. This sharpness defines its contemporary look. The GT Sectra subfamily was originally designed for the long-form magazine Reportagen, a publication with interesting stories from all around the world. The Zürich-based studio Moiré designed the […]
The 2022 Kia Stinger was built to thrill. Ferguson Kia has the 2022 Kia Stinger available, for sale, near Tulsa, Oklahoma.