Polymer Structure Polymerization Polycondensation Polyaddition

Polymerization Polycondensation Polyaddition
Most of the advantages and disadvantages of polymers depend on the size of the structure of the individual polymer molecules, the shape and size of the polymers and how they are formed. The characteristics of a polymer molecule are determined by its size, a feature that distinguishes it from other organic chemical compositions. Polymers are long chains of molecules, also called micromolecules or giant molecules, which are formed by polymerization, in other words by the interlocking and crosslinking of different monomers. Monomers are the basic building blocks of a polymer. The word mer comes from the Greek meros meaning part, indicating the smallest unit.

Polymer means many mers or units, generally a repetition of hundreds or thousands of times a chain-like structure. Most monomers are organic materials in which the carbon atoms are joined in covalent bonds with other atoms, such as hydrogen, oxygen, nitrogen, fluorine, chlorine, silicon and sulfur.

To form macromolecular bonds from each thermoplastic material molecule is done in three ways, namely:

a. Polymerization:

Bringing together several similar molecules to form a large molecule Polymerisate. The monomers in polymers can be linked in repeating units that lengthen and enlarge the molecules by a chemical reaction known as a polymerization reaction. Despite the many variations, the two basic processes are Condentation polymer and Polyaddition.

b. Polycondensation;

The bonding of several molecules to form large macromolecules through the process of separating one of the atoms to bind small molecules from water. From this process, a material called Polycondensate is formed

c. Polyaddition;

Namely the union of several basic molecules through the placement of several molecules without separation of the non-fixed parts. The material formed is called "Polyadducf. In this reaction an initiator is added to break the two bonds between the carbon atoms and start the bonding process by adding more monomers to build the chain. For example the Ethylene monomer bonds to produce a polymer known as Polyethylene .

The sum of the molecular weights of the mer-mers in the polymer chain is the molecular weight of the polymer. The higher the molecular weight in a given polymer, the greater the chain length. Since polymerization is a random event, the resulting polymer chains are not all the same length, but the resulting chain lengths are formed in a traditional distribution curve. We determine and express the average molecular weight of a polymer on a statistical basis by averaging. The distribution of the molecular weight distribution is referred to as the molecular weight distribution (MWD). Molecular weight and MWD have a strong influence on polymer properties. For example, fracture and impact strength, resistance to cracking, and viscosity in the liquid state all increase with increasing molecular weight. Most of the polymers traded have molecular weights between 10,000 and 10,000,000.

In some cases, it is easier to describe the size of a polymer chain in Degrees of Polymerization (DP), defined as the ratio of the molecular weight of the polymer to the molecular weight of the repeating unit. For example, Polyvinyl chloride ( PVC) has a mer weight of 62.5, so the DP of PVC which has a molecular weight of 50,000 will be 50,000 / 62.5 = 800. In the polymerization process, the higher the DP, the greater the polymer viscosity, or flow resistance, thus making it easier to formation and overall costs.

During polymerization the monomers are bonded together in a covalent bond, forming a polymer chain. Because of their strength, covalent bonds are also called primary bonds. In addition, polymer chains hold on to secondary bonds such as van der Waals bonds, hydrogen bonds and ionic bonds. Secondary bonds are weaker than primary bonds. In a polymer, the increase in strength and viscosity with molecular weight is partly due to the fact that the longer the polymer chain, the greater the energy required for secondary bonding.

If the repeating units of the polymer chain are of the same type, we call the molecule a homopolymer. However, two or three types of heavy monomers can be combined to obtain special characteristic advantages, such as improved strength and durability. Copolymer consists of two types of polymers such as Styrene-butadine, widely used for car tires. Terpolymer consists of three types such as ABS used for helmets, telephones.

Rotary screen printing an effective way of printing

screen galus linearis
Screen printing is a printing technique that uses a woven mesh to support an ink-blocking stencil to receive a desired image. The attached stencil forms open areas of mesh that transfer ink or other printable materials which can be pressed through the mesh as a sharp-edged image onto a substrate. A fill blade or squeegee is moved across the screen stencil, forcing or pumping ink into the mesh openings for transfer by capillary action during the squeegee stroke. Basically, it is the process of using a stencil to apply ink onto another material whether it be t-shirts, posters, stickers, vinyl, wood, or any material that can keep the image onto its surface. Screen printing is also a stencil method of print making in which a design is imposed on a screen of polyester or other fine mesh, with blank areas coated with an impermeable substance. Ink is forced into the mesh openings by the fill blade or squeegee and onto the printing surface during the squeegee stroke. It is also known as silkscreen, serigraphy, and serigraph printing. A number of screens can be used to produce a multicolored image or design.
Rotary screen printing - an effective way of printing
Screen printing is ideally suited wherever a high degree of coverage, precise detail and colour intensity are required to obtain a brilliant, high-quality image. Applying a coating allows special relief and other effects to be created. Scented coatings, thermochromatic inks and glitters are just a few examples of screen printing applications.
One particular feature of screen printing is its ability to produce what is known as the no-label look with transparent labels being applied to the packaging. Screen printing also enables Braille to be applied to any label. 
Gallus Rotascreen - performance package
Gallus Rotascreen is a performance package and our contribution to success for labelprinters:
Gallus Screeny conventional screen printing plates 
Gallus Screeny digital screen printing plates 
Know-how transfer, training
Application know how and combination printing (screen, flexo, offset, hotfoil etc.)
Technology centre, product development
Prepress devices
Test equipment on Gallus site
Production expertise plating and coating
Attractive illustrations using rotary screen printing in combination with other printing processes.
The Gallus Rotascreen performance package - complete support for the screen printer.

Desain Tempat Usaha Cuci Mobil dan Toko Asesoris

jasa gambar usaha cuci mobil
Mencari Pakar Desain untuk usaha cuci mobil hidrolik maupun manual dengan segala konsep? Hubungi Kami untuk memulainya, cukup kirim chat ke WA 081916200296, Kami Siap Membantu Anda dengan Beragam Ide Desain Fantastis. Terlampir contoh Design Bangunan tempat cuci steam mobil dan toko asesoris mobil yang pernah kita buat sesuai keinginan klien. Jasa penyedia gambar tempat cuci mobil dengan berbagai model. Menerima pembuatan desain baik dari lahan kosong maupun renovasi. Arsitek Profesional berkomitmen untuk memberikan hasil yang terbaik untuk Anda. Telah berpengalaman lebih dari 10 tahun, dan telah mengerjakan banyak bangunan cuci steam. Mulai dari desain cuci mobil manual, desain cuci mobil minimalis, desain tempat cuci mobil hidrolik, desain cucian mobil plus cafe, desain cuci motor mobil, desain ruang tunggu cuci mobil, desain toko cuci mobil, dan lain lain. Jika Anda tertarik, langsung kirim saja datanya. Prosedur pemesanan sangat aman, desain kita buatkan dulu dalam resolusi rendah sebagai bukti bahwa kita telah mengerjakan sesuai data2 yang telah dikirimkan oleh klien setelah transfer segera kita buatkan resolusi tingginya untuk direview lebih detai. Revisi bisa 2x free. Arusha Desain penyedia Jasa Gambar Tempat usaha cuci mobil Online dengan banyak pelanggan dan telah berpengalaman.

Two-Cavity Unscrewing Mold for a Glass Fiber Reinforced Polyamide Threaded Plug

Two-Cavity Unscrewing Mold for a Glass-Fiber-Reinforced Polyamide Threaded Plug The threaded plug consists of a top flange with a hexagonal recess in its upper surface. The underside of the flange has a pot-shaped section that encloses the hexagonal recess and to the bottom of which a stop pin is attached. This section is enclosed by an outer ring that carries the threads. In addition, the underside exhibits an annular groove ‘‘O’’ around the outer ring and intended to hold a seal. The annular space between the pot-shaped section and outer ring contains radial ribs. Mold Release of the annular groove and threads is accomplished most easily by unscrewing the molded part from a threaded sleeve. The mold is designed with two cavities. Release of the threads is accomplished on the stationary mold half. The threaded sleeves are located in guide bushings and are driven by the gear and spindle of the unscrewing mechanism. The annular core forms the stop pin and, by means of a tubular extension, the annular space in the plug. A central core pin provides for venting of the stop pin cavity. The hexagonal recess is formed by the core insert , which also encloses an ejector pin . The other ejector pins are used to knock out the sprue and runner. Gating The location of the ejectors and unscrewing mechanism requires that injection takes place into the mold parting line . Each plug has a single submarine gate located at the flange. Mold Temperature Control The mold plates on either side of the parting line have cooling lines encircling the mold inserts. The annular core contains a double-threaded cooling pin. Part Release=Ejection The latch causes the mold to first open at parting line ‘I’. This withdraws the annular core from the underside of the plug and releases the stop pin. This motion is limited by the stop bolt . The opening motion is now interrupted and the unscrewing begins. The threaded sleeve is unscrewed while the hexagonal core insert prevents the molded part from turning. Upon completion of unscrewing, the main parting line ‘II’ opens, shearing off the submarine gates. The molded part is still retained on the core insert; the sprue and runner are held by the undercut in the sprue puller. As the ejector plate moves forward, the ejector pins eject the molded part and the sprue.

Labels

2d (1) 3D (1) ABG (1) agen JNE (1) almari (1) Alufoil (1) Aluminum Foil (1) anilox roll (1) apartemen (1) Atom (1) autocad (1) backdrop logo (1) bagian dalam (1) bangunan (1) batu alam (1) berkualitas (1) bermutu (1) berpengalaman (1) bertingkat (1) birdview (1) black and white (1) botol plastik (1) cafe (1) classic (1) coklat (1) cold rolled sheet (1) Computer To Plate (1) Consumer Understanding (1) control movement (1) counter (1) CTP (1) denah berwarna (1) denah kantor (1) desain (1) desain cuci mobil (1) desain kamar (1) desain produk (1) design (1) Design and Function (1) design meja (1) Design restaurant (1) design rumah (1) di daerah (1) dinding bata (1) dining (1) Duromer (1) Electrons (1) etnik (1) factors (1) flexo packaging (1) flexo printing (1) food (1) furniture (1) gallus (1) gambar (1) gaya modern (1) gloss (1) grc kotak (1) Halftone (1) hanya 550 ribu (1) harga murah (1) hasil cepat (1) hotel (1) industrial (1) injection (1) Injection Mold (1) ink (1) inovatif (1) install (1) interior (1) interior rumah (1) jasa gambar rumah (1) jasa 3d (1) jasa arsitek (1) jasa desain (1) jasa desain 3d (1) jasa design (1) jasa designer (1) jasa gambar (1) kamar tidur (1) kamar tidur anak (1) kampus (1) karaoke (1) kawasan (1) kawasan industri (1) kemasan (1) kerja di rumah (1) kitchen set (1) kontemporer (1) kosan (1) kost (1) krem (1) laci (1) lamination (1) lithography (1) living room (1) livingroom (1) lounge (1) Luscher MultiDX (1) masterplan (1) matt (1) meja kerja (1) metalworking (1) mewah (1) minimalis (1) minimalist (1) modern (1) mold (1) molding (1) Monomer (1) murah (1) murah. (1) Neutron (1) nuansa remaja (1) offset (1) online design (1) open ceiling (1) outdoor (1) overprint (1) pabrik (1) pantai (1) pencahayaan (1) perumahan (1) pesan desain (1) pesan desain toko (1) plug (1) Polimer (1) Polyaddition (1) Polycondensation (1) Polymerization (1) Polystyrene (1) printing ink (1) Product Creation (1) product function (1) produk katalog (1) Protons (1) Raster Image Processor (1) register (1) rendering (1) resepsionis (1) responsibility (1) resto industrial (1) RIP (1) Rotary (1) ruang kantor (1) ruang keluarga (1) ruang kerja (1) ruang tamu (1) ruang tunggu (1) ruko (1) rumah (1) rumah hook (1) rumah susun (1) rumah tropis (1) scandinavian (1) screen printing (1) sederhana (1) sempoa (1) setup (1) simple sederhana (1) specifications (1) spring (1) steel (1) Struktur Plastik (1) suspension (1) sweet home (1) taman (1) tampak (1) tampak rumah (1) Technological Change (1) terbaru (1) termurah (1) toko aksesoris (1) toko asesoris (1) trapping (1) two cavity (1) unscrewing (1) use (1) uv varnish (1) via online (1) website (1)