Remanufacturing


Remanufacturing is "the rebuilding of a product to specifications of the original manufactured product using a combination of reused, repaired and new parts". It requires the repair or replacement of worn out or obsolete components and modules. Parts subject to degradation affecting the performance or the expected life of the whole are replaced. Remanufacturing is a form of a product recovery process that differs from other recovery processes in its completeness: a remanufactured machine should match the same customer expectation as new machines.
In 1995, the United States Environmental Protection Agency implemented the Comprehensive Procurement Guideline program to promote waste reduction and resource conservation through the use of materials recovered from solid waste, and to ensure that the materials collected in recycling programs will be used again in the manufacture of new products. The EPA is required to designate products that are or can be made with recovered materials, and to recommend practices for buying these products. Once a product is designated, state and federal procuring agencies are required to purchase it with the highest recovered material content level practicable.
In 2004, the EPA published its third CPG update which designated seven additional products and revised three existing product designations. One of the new product categories to be added was Rebuilt Vehicular Parts. The EPA defines rebuilt vehicular parts as "vehicle parts that have been re-manufactured, reusing parts in their original form. Rebuilt parts undergo an extensive re-manufacturing and testing process and must meet the same industry specifications for performance as new parts."
In the UK, a market potential of up to 5.6 billion GBP has been identified in remanufacturing, with the benefits said to be improvement to business margins, revenues and security of supply.

Other forms of product recovery

  1. Reuse implies that items are used by a second customer without prior repair operations or as originally designed.
  2. Repair: the process of bringing damaged components back to a functional condition.
  3. Refurbishing/Reconditioning is the process of restoring components to a functional and/or satisfactory state to the original specification, using methods such as resurfacing, repainting, etc.
  4. Recycling is the process of taking a component material and processing it to make the same material or useful degraded material.
  5. Cannibalization
Many formal definitions of remanufacturing exist in the literature, but the first published report on remanufacturing, by R. Lund, describes remanufacturing as "... an industrial process in which worn-out products are restored to like-new condition. Through a series of industrial processes in a factory environment, a discarded product is completely disassembled. Useable parts are cleaned, refurbished, and put into inventory. Then the product is reassembled from the old parts to produce a unit fully equivalent and sometimes superior in performance and expected lifetime to the original new product".
Furthermore, the Automotive Parts Remanufacturers Association realized that communication problems can arise when people from different countries with different language skills talk about remanufacturing. Certain terms can have different meanings as definitions between countries and individuals vary. In 2013, APRA was able to solve these communication problems by publishing a common in many different languages in order to unite all those who deal with the automotive industry.

Range of products being remanufactured

There are three main types of remanufacturing activities, each with different operational challenges.
  1. Remanufacturing without identity loss With this method, a current machine is built on yesterday's base, receiving all of the enhancements, expected life and warranty of a new machine. The physical structure is inspected for soundness. The whole product is refurbished and critical modules are overhauled, upgraded or replaced. If there are defects in the original design, they are eliminated. This is the case for customized remanufacturing of machine tools, airplanes, computer mainframes, large medical equipment and other capital goods. Because of its uniqueness, this product recovery is characterized as a project.
  2. Remanufacturing with loss of original product identity With this method, used goods are disassembled into pre-determined components and repaired to stock, ready to be reassembled into a remanufactured product. This is the case when remanufacturing automobile components, photocopiers, toner cartridges, furniture, ready-to-use cameras and personal computers. Once the product is disassembled and the parts are recovered, the process concludes with an operation not too different from original manufacturing. Disassembled parts are inventoried, just like purchased parts and made available for final assembly. Remanufacturing with loss of original product identity encompasses some unique challenges in inventory management and disassembly sequence development. Some of the open questions relate to the commonality of parts in products of different generations, the uncertainty in the supply of used products, and their relationship with production planning. The National Center for Remanufacturing and Resource Recovery at Rochester Institute of Technology is researching remanufacturing processes including testing standards for remanufactured products.
  3. Repetitive remanufacturing without identity loss In this method, there is the additional challenge of scheduling the sequence of dependent processes and identifying the location of inventory buffers. There is a fine line between repetitive remanufacturing without loss of identity and product overhaul. Again, the critical difference is that remanufacturing is a complete process. The final output has a like-new appearance and is covered by a warranty comparable to that of a new product.
Remanufacturing by Recoating of Worn Engine Parts
In addition to these is a less significant type of remanufacturing, remanufacturing by recoating of worn engine parts. This type of remanufacturing serves many engine parts and other large and expensive components that become worn after a period of use. An example of such a part is the engine block, in particular the cylinder engine bores, which must withstand explosions during piston firing. Instead of disposing of large engine blocks, remanufacturing has resulted in re-use of the parts by coating them with plasma transferred wire arc spraying. Remanufacturing by recoating of parts is also very popular in the aircraft field, the geothermal pipe field and the automotive engine field.

Rebuilding

Rebuilding is an old name for remanufacturing. It is still widely used by automotive industry. For example, the Automotive Parts Remanufacturers Association, have the new term in their name, but to be safe on their own website use the combined term 'rebuild/remanufacture'.
The term 'rebuilding' is also often used by railway companies; a steam locomotive may be rebuilt with a new boiler or a diesel locomotive may be rebuilt with a new engine. This saves money and allows the incorporation of improved technology. For example, a new diesel engine may have lower fuel consumption, reduced exhaust emissions and better reliability. Recent examples include British Rail Class 57 and British Rail Class 43.

Benefits of Engine Remanufacturing

  1. Lower Cost - One of the biggest factors in choosing a remanufactured engine is cost. Remanufactured engines cost up to 50 percent less than a new Tier 4 Final engine, not including associated engineering costs, and offers even greater savings over the purchase of a new piece of equipment. Maintenance on some new Tier 4 Final engines can be costly as well. In addition to being more complex to service, additional costs for after treatment cleaning and DEF fluid can add up quickly.
  2. Less Downtime - Opting to replace your existing engine with a new one typically requires significant engineering time that can render rental equipment out of service for months. The integration and testing process also takes significantly longer with a new Tier 4 Final engine than with remanufactured engines.
  3. Increased Equipment Resale Value - There are two main factors currently making it difficult to sell Tier 4 Final-powered equipment in lesser regulated countries: serviceability and fuel availability. The lack of established service programs for the new technology makes supporting the product difficult. This coupled with high product costs, have companies shying away from Tier 4 Final powered equipment. In addition, many lesser regulated countries don't have high availability for ultra-low sulphur diesel fuel, which is required by Tier 4 Final engines to operate effectively. Without it, the diesel particulate filter can clog rapidly and cause significant operation issues.
  4. More Sustainable Option - Purchasing a remanufactured engine keeps an old engine core and many usable components out of a landfill, which can greatly reduce the impact on the environment. According to Perkins Pacific's Andy Machin, approximately 73 percent of the old engine can be salvaged during the remanufacturing process saving millions of pounds of waste out of landfills. New engine production requires all new materials, substantial amounts of energy for the production process and additional transportation costs. By utilizing recycled components, a remanufactured engine typically uses about 80 percent less energy than new engine production, making it a much greener option. For rental fleet owners, reman offers the opportunity to expand their sustainability practices while saving money.