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fuel cell, borit, bipolar plates, flow plates, fuel cell, electrolyzer, heat exchanger, sheet metal, hydroforming, design, prototype, production, quality, flexibility, structural panels, light weight structures, sandwich, crash elements, durable packaging, facade, transport, automotive, metal structure, design plate

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<meta name="Description" content="Borit is a world-class manufacturer of sheet metal products and assemblies.  Borit is a full service partner supporting our customers through the full cycle, from conceptual product design, over prototyping to large production series. The innovative Borit Hydrogate technology guarantees optimal product design possibilities, the best product quality, combined with a very high productivity. Products: Flow plates: high precision embossed plates for clean energy applications such as fuel cells, electrolyzers, heat exchangers and solar collectors. Structural panels: full-metal solutions combining light weight with high strength and stiffness, with proven benefits for end-use in transportation, construction, furniture and packaging, amongst others. Borit NV is a spin off company of OCAS NV and borit Leichtbau-Technik GmbH. OCAS is a world leading innovation center for steel solutions, established in 1991 and today a joint venture between ArcelorMittal and the Flemish Region. borit Leichtbau-Technik is a German technology development company, active since 2004.

Borit&#8217;s production centre is based in Zelzate, Belgium, with a technology and product development center in Herzogenrath, Germany. A fuel cell is an electrochemical conversion device. It produces electricity from fuel (on the anode side) and an oxidant (on the cathode side), which react in the presence of an electrolyte. The reactants flow into the cell, and the reaction products flow out of it, while the electrolyte remains within it. Fuel cells can operate virtually continuously as long as the necessary flows are maintained. Fuel cells are different from electrochemical cell batteries in that they consume reactant from an external source, which must be replenished &#8211; a thermodynamically open system. By contrast, batteries store electrical energy chemically and hence represent a thermodynamically closed system. Many combinations of fuels and oxidants are possible. A hydrogen fuel cell uses hydrogen as its fuel and oxygen (usually from air) as its oxidant. Other fuels include hydrocarbons and alcohols. Other oxidants include chlorine and chlorine dioxide. A fuel cell works by catalysis, separating the component electrons and protons of the reactant fuel, and forcing the electrons to travel through a circuit, hence converting them to electrical power. The catalyst typically comprises a platinum group metal or alloy. Another catalytic process puts the electrons back in, combining them with the protons and oxidant to form waste products (typically simple compounds like water and carbon dioxide). A typical fuel cell produces a voltage from 0.6 V to 0.7 V at full rated load. Voltage decreases as current increases, due to several factors: Activation loss Ohmic loss (voltage drop due to resistance of the cell components and interconnects) Mass transport loss (depletion of reactants at catalyst sites under high loads, causing rapid loss of voltage) To deliver the desired amount of energy, the fuel cells can be combined in series and parallel circuits, where series yields higher voltage, and parallel allows a stronger current to be drawn. Such a design is called a fuel cell stack. Further, the cell surface area can be increased, to allow stronger current from each cell. Proton exchange fuel cells In the archetypal hydrogen&#8211;oxygen proton exchange membrane fuel cell (PEMFC) design, a proton-conducting polymer membrane, (the electrolyte), separates the anode and cathode sides. This was called a "solid polymer electrolyte fuel cell" (SPEFC) in the early 1970s, before the proton exchange mechanism was well-understood. (Notice that "polymer electrolyte membrane" and "proton exchange mechanism" result in the same acronym.) On the anode side, hydrogen diffuses to the anode catalyst where it later dissociates into protons and electrons. These protons often react with oxidants causing them to become what is commonly referred to as multi-facilitated proton membranes (MFPM). The protons are conducted through the membrane to the cathode, but the electrons are forced to travel in an external circuit (supplying power) because the membrane is electrically insulating. On the cathode catalyst, oxygen molecules react with the electrons (which have traveled through the external circuit) and protons to form water &#8212; in this example, the only waste product, either liquid or vapor.

In addition to this pure hydrogen type, there are hydrocarbon fuels for fuel cells, including diesel, methanol (see: direct-methanol fuel cells and indirect methanol fuel cells) and chemical hydrides. The waste products with these types of fuel are carbon dioxide and water. Construction of a high temperature PEMFC: Bipolar plate as electrode with in-milled gas channel structure, fabricated from conductive plastics (enhanced with carbon nanotubes for more conductivity); Porous carbon papers; reactive layer, usually on the polymer membrane applied; polymer membrane. Condensation of water produced by a PEMFC on the air channel wall. The gold wire around the cell ensures the collection of electric current. The materials used in fuel cells differ by type. In a typical membrane electrode assembly (MEA), the electrode&#8211;bipolar plates are usually made of metal, nickel or carbon nanotubes, and are coated with a catalyst (like platinum, nano iron powders or palladium) for higher efficiency. Carbon paper separates them from the electrolyte. The electrolyte could be ceramic or a membrane. Oxygen ion exchange fuel cells In a solid oxide fuel cell (SOFC) design, the anode and cathode are separated by an electrolyte that is conductive to oxygen ions but non-conductive to electrons. The electrolyte is typically made from zirconia doped with yttria.

On the cathode side, oxygen catalytically reacts with a supply of electrons to become oxygen ions, which diffuse through the electrolyte to the anode side. On the anode side, the oxygen ions react with hydrogen to form water and free electrons. A load connected externally between the anode and cathode completes the electrical circuit. Molten carbonate fuel cells (MCFCs) operate in a similar manner, except the electrolyte consists of liquid (molten) carbonate, which is a negative ion and an oxidizing agent. Because the electrolyte loses carbonate in the oxidation reaction, the carbonate must be replenished through some means. This is often performed by recirculating the carbon dioxide from the oxidation products into the cathode where it reacts with the incoming air and reforms carbonate. Unlike proton exchange fuel cells, the catalysts in SOFCs and MCFCs are not poisoned by carbon monoxide, due to much higher operating temperatures. Because the oxidation reaction occurs in the anode, direct utilization of the carbon monoxide is possible. Also, steam produced by the oxidation reaction can shift carbon monoxide and steam reform hydrocarbon fuels inside the anode. These reactions can use the same catalysts used for the electrochemical reaction, eliminating the need for an external fuel reformer. Proton exchange membrane fuel cell design issues Costs. In 2002, typical fuel cell systems cost US$1000 per kilowatt of electric power output. In 2008, the Department of Energy reported that fuel cell system costs in volume production are $73 per kilowatt.[citation needed] The goal is $35 per kilowatt. In 2008 UTC Power has 400 kW stationary fuel cells for $1,000,000 per 400 kW installed costs. The goal is to reduce the cost in order to compete with current market technologies including gasoline internal combustion engines. Many companies are working on techniques to reduce cost in a variety of ways including reducing the amount of platinum needed in each individual cell. Ballard Power Systems have experiments with a catalyst enhanced with carbon silk which allows a 30% reduction (1 mg/cm² to 0.7 mg/cm²) in platinum usage without reduction in performance.[5]. Monash University, Melbourne uses PEDOT instead of platinum. The production costs of the PEM (proton exchange membrane). The Nafion membrane currently costs $565.92/m². In 2005 Ballard Power Systems announced that its fuel cells will use Solupor, a porous polyethylene film patented by DSM. Water and air management (in PEMFCs). In this type of fuel cell, the membrane must be hydrated, requiring water to be evaporated at precisely the same rate that it is produced. If water is evaporated too quickly, the membrane dries, resistance across it increases, and eventually it will crack, creating a gas "short circuit" where hydrogen and oxygen combine directly, generating heat that will damage the fuel cell. If the water is evaporated too slowly, the electrodes will flood, preventing the reactants from reaching the catalyst and stopping the reaction. Methods to manage water in cells are being developed like electroosmotic pumps focusing on flow control. Just as in a combustion engine, a steady ratio between the reactant and oxygen is necessary to keep the fuel cell operating efficiently. Temperature management. The same temperature must be maintained throughout the cell in order to prevent destruction of the cell through thermal loading. This is particularly challenging as the 2H2 + O2 2H2O reaction is highly exothermic, so a large quantity of heat is generated within the fuel cell. 

Durability, service life, and special requirements for some type of cells. Stationary fuel cell applications typically require more than 40,000 hours of reliable operation at a temperature of -35 °C to 40 °C (-31 °F to 104 °F), while automotive fuel cells require a 5,000 hour lifespan (the equivalent of 150,000 miles) under extreme temperatures. Current service life is 7,300 hours under cycling conditions[10]. Automotive engines must also be able to start reliably at -30 °C (-22 °F) and have a high power to volume ratio (typically 2.5 kW per liter). Limited carbon monoxide tolerance of the cathode." />



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		<h1>Industrial Design Parts</h1>

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    <tr><td colspan="2"> Borit can offer a wide range of Hydro Formed sheet metal parts used as mechanical components in:<br />

<ul>

<li>Consumer electronic devices like smart phones, notebooks, digital cameras etc</li>

<li>Half shells for electronic equipment as back shells for phones including Logo and specific cosmetic look per customer demand.</li>

<li>Half shells as front panel for digital cameras, medical equipment and implants for the medical world</li>

<li>Formed reflectors for the lighting industry</li>

<li>Cooling elements for high power Led s</li>

</ul></td></tr>

    <tr><td><a href="images/ip1.jpg" rel="lightbox"> <img src="images/ip1.jpg" alt="industrial parts" /></a><br /><br /><a href="images/ip2.jpg" rel="lightbox[Flow-Plates]"> <img src="images/ip2.jpg" alt="industrial parts" /></a><br /><br /><a href= "images/ip3.jpg" rel="lightbox[Flow-Plates]"> <img src="images/ip3.jpg" alt="industrial parts"/></a><br /><br /> </td>

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                    Industrial parts manufactured with the innovative Borit Hydrogate technology offer distinctive advantages compared to plates produced with more conventional manufacturing processes: </p>

                     <p>Design & operational flexibility</p>

               	 <ul>

                	<li>Fast prototyping for an optimal design process</li>

                    <li>Esthetical design parts: capability for 3D shapes including a surface texture</li>

                    <li>Forming of all relevant metal-alloys for fuel cells possible: stainless steel, aluminium, titanium, Ni-based alloys, etc. </li>

                    <li>Wide range of sheet thicknesses, typically 0.1 to 0.5 mm </li>

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<p>Excellent quality</p>

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                 <li>Controlled flow of material with uniform sheet thickness and strength</li>

                 <li>Superb dimensional accuracy & repeatability</li>

                 <li>No pin holes or material cracks</li>

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<p>Economic</p>

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                 <li>Limited die cost</li>

                 <li>Efficient production process, due to continuous production method from coil and short cycle times. </li>

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<p>Additional advantages</p>

<ul><li>Finishing (cutting, coating, welding) done in-house or at trusted partners.</li>

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