Casting Technique

Casting Technique

Metal casting strategy means the casting processes, which make the metal supplies into designed metal goods. Casting is the most simple and the most frequently utilized metal manufacturing technologies.

According to the distinct casting materials, casting strategies can be divided into black metal casting (like cast iron, cast steel) and nonferrous metal casting (including aluminum, copper alloy, zinc alloy, magnesium alloy, etc.).

According to the different mold components, casting approaches can be divided into sand mold casting and metal mold casting.

Casting methods can also be divided into gravity casting and stress casting according to the various approach theories.

Gravity casting is the casting approach that pours the molten metal into the mold by the Earth’s gravity, also identified as pouring casting. Gravity casting strategy includes sand casting, metal mold casting, investment casting, lost foam casting and die casting.

Sand casting is a sort of metal casting method, whose major material is quartz sand. Sand casting is a conventional casting procedure. Sand casting is typically gravity casting, but if there are specific requirements, it also might be low stress casting or centrifugal casting process.

Sand casting has a wide adaptability, such as creating small castings, large castings, simple parts, complicated parts, single casting, large quantities of castings. The casting patterns of sand casting can be divided into wood pattern, resin pattern and metal pattern.

Metal mold casting strategy makes use of the heat-resistant alloy steel patterns as the casting molds, and the melted metal will be poured into the steel patterns straight. Metal mold casting methods can also be divided into gravity metal mold casting and pressure metal mold casting. The steel patterns of metal mold casting can be utilized repeatedly, each and every time pouring can get a casting, the steel patterns have a quite long lifetime, and the production efficiency is higher.

Metal mold casting method is not only a very good dimensional accuracy, surface finish, and the casting strength is larger than the sand castings, but also not effortless to damage. As a result, metal mold casting strategy is typically utilized for making non-ferrous metal castings.

Even so, the metal mold casting technique also has some disadvantages: The heat-resistant alloy steel patterns are quite costly, so for tiny batch production, the share to the expense of every single product is too higher on the mold, usually difficult to be accepted. Moreover, simply because the steel patterns have size limitation, so it also limit the size of castings. For that reason, for small quantities or huge size castings, normally do not use metal mold casting.

Die casting approach is a type of metal mold casting approach, but the melted metal is injected by pressure from die casting machines. Die casting machines are divided into hot chamber die casting machines and cold chamber die casting machines. Die casting machine has a high degree of automation, significantly less waste of materials, and larger efficiency than the cold chamber die casting machine, but due to the fact of the mechanical heat capacities, the hot chamber die casting machines are only for creating zinc alloy, magnesium alloy and other low melting point materials casting. Today’s widespread use of aluminum die casting, due to high melting point, only created in the cold chamber die casting machines.

In brief, all metal casting approaches have their own positive aspects and disadvantages. According to the difference of the solution components, applications and needs, buyers need to decide on the appropriate casting strategy.

This write-up was from Dandong Foundry Weblog.

http://www.iron-foundry.com/casting-approach.html

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The cogen pellet boiler designed a lot interest at the The Globe Sustainable Energy Days in Wels, Austria, a stage to most of the major wood pellet boiler companies. ÖkoFEN’s and Qnergy’s most recent technologies is not only economical and automated but it also delivers heat and power embodied in a single platform.

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“5 kw of electricity and larger permits us to tap into new markets for cogeneration that so far have been out of our scope” stated ÖkoFEN founder and CEO Herbert Ortner. “We are hoping to commercialize the item as quick as feasible the 1st pilot buyers are expecting to take deliveries in the close to future”.

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How It Performs &#13

As the wood pellets are burned, heat from the burner flue gas is transferred to the head of the QB7500 external combustion Stirling engine, initiating a cyclic heating and cooling method of inert gas inside the engine. In the course of this thermodynamic procedure, electrical energy is generated by means of the QB7500’s linear alternator.

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The heat then travels through the boiler to supply hot water for space heating, domestic use or for industrial and industrial process requirements. This cutting edge cogeneration program generates economical grid-high quality electricity as a by-product of low-price, environmentally friendly hot water production.

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About ÖkoFEN &#13

ÖkoFEN is the European specialist in pellet heating. Ecological research and improvement of little-scale ecological biomass heating systems was their main objective and this mission is reflected in their company name ÖkoFEN. Ecology is the middle point of all their activities and is their philosophy throughout the complete organization. When wood pellets had been launched on the Austrian marketplace in 1996, ÖkoFEN was the 1st Austrian manufacturer to supply an officially-certified pellet heating program to the public, in 1997. This pioneering activity has had wide-ranging effects throughout the market and represents the starting of a period of extraordinary market improvement. For a lot more info, please check out http://www.oekofen.com

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About Qnergy &#13

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“The HAPLS timing program should be in a position to operate independent of the ELI timing method,” Drouin mentioned. “But, it also needs to be capable of becoming completely synchronized to ELI. That bridge in between timing systems is what we have been functioning on – making sure HAPLS runs extremely nicely independently as properly as integrating with ELI.”

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Haefner pointed out that whilst HAPLS is a key component, it becomes a subsystem when it moves to the ELI facility. When at ELI, HAPLS will integrate with the wider user facility, consisting of target systems, experimental systems, diagnostic systems – all of which have to be timed and fed from a master clock.

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Kasl likened the master clock to a universal clock used by an workplace. “We brought the clock right here, and now absolutely everyone in the workplace is making use of the clock to synchronize their function,” he said.

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The master clock, constructed by ELI, was programmed as a bridge among the ELI and HAPLS timing systems. During their time at LLNL, Drouin and Kasl worked on configuring that hardware and writing the computer software that talks to the clock and to the subcomponents that control a quite precise sequence of events.

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“This unit is going to get integrated with our other systems, so there demands to be an overlap amongst the two teams,” Kasl said.

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