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To ensure companies are able to recognise their own energy saving potentials and to implement projects that exploit these potentials, the TU Darmstadt initiated the research project Energy Efficient Factory (ETA-Factory) together with 39 industrial partners

Image: MAFAC

Industrial Parts Cleaning Energy efficiency for aqueous parts cleaning

May 15, 2017

Reducing the amount of energy required by a machine for aqueous parts cleaning is one of the best ways to cut costs and lower the environmental impact of production. This was the key finding of a recent study of an aqueous parts cleaning machine within the framework of the interdisciplinary research project ‘ETA-Factory’ led by TU Darmstadt as part of its drive to enhance energy-efficient production processes. A read on…

In view of rising energy prices and constantly increasing international competition, energy-efficient production is one of the key issues for the German industry. As a result, domestic companies are called upon to reduce the energy consumption of their production, as well as their carbon footprint. To ensure companies are able to recognise their own energy saving potentials and to implement projects that exploit these potentials, the TU Darmstadt initiated the research project ‘Energy Efficient Factory’ (ETA-Factory) together with 39 industrial partners. The aim of the research project is to develop approaches for reducing energy consumption of industrial production processes. The project forecasts that the thermal interconnectedness of industrial factories, technical infrastructure, and machinery will result in potential energy savings of up to 40%.

Parts cleaning as a field of study

Due to its increasing significance in the industry and its partly energy-intensive processes, parts cleaning is a key element of the ETA investigations. Optimisation solutions and energy saving potentials for cleaning and drying processes were examined using a spray-flood parts washer with dual-wash technology. Generally speaking, three optimisation steps are feasible for energy efficient parts cleaning:

  1. Reducing system and internal losses of the actual machine through effective thermal insulation and shielding

  2. Minimising internal losses through efficient energy storage, recovery, and utilization (integrated energy recuperation)

  3. Enabling and utilising intelligent power generation beyond machine limits (interconnectedness)

Within this context, four main approaches were identified in which the most energy saving potentials in terms of power costs can be exploited. These included heating of process water through external interconnectedness; heat storage and recuperation of machine specific heat and efficient utilisation for preheating the drying air; heat recuperation of waste air and sensor-based process control.

Based on the total amount of energy required by the cleaning machine, potential financial savings of up to 35% can be achieved by the company at the current level of development and when utilising appropriate machine equipment, process models and intelligent interconnectedness. In line with the assembly and process analysis hierarchy, the investigation initially focused on heating process water with the aim of developing an exchange technology for reproducible heat transfer. Further, to provide the right conditions in terms of thermal interconnectedness, it must be possible to feed existing, technical heat from the production environment into the exchange process.

Parameters of heat exchange for heating process water

Parts cleaning represent a heat sink within a manufacturing chain. In other words, energy has to be supplied to the process to achieve the required level of parts cleanliness using heated cleaning baths. In order to be able to determine the energy consumption of the investigated parts cleaning machine, a standard process was defined and the influence of media temperature, batch sizes, process model (cleaning, rinsing, drying), and operating time on overall energy consumption was systematically analysed. The focus then turned to the energy behaviour of the companies— in other words, which type of energy and state-of-the-art techniques are applied for heating process baths – either conventional electricity for heating or alternative energy sources such as available water heated from solar power, co-generation or technical heat from
a district heating network.

The investigation resulted in the following definition of requirements—the envisaged exchange technology must provide a constant temperature of up to 75°C without the need of electricity for heating while guaranteeing reliable operation without any negative implications for the cleaning capacity and quality of the process water. It should also be able to respond flexibly to various heat sources and additionally transmit heat faster and more efficiently than conventional power sources. This would ensure shorter lead times and compensate any temperature losses in a faster and more efficient way, for instance when cleaning larger components. Moreover, there should be virtually no losses during heat transfer in order to provide a maximum energy saving potential of up to 35%.

The heat exchange module

The knowledge gained was used to develop a heat exchange module that uses heat from external sources to heat up cleaning media. In counterflow principle, a highly-efficient heat exchange technology utilises coaxial tubes to ensure the waste heat of the heating agent is transferred to the cleaning agent virtually without losses before being returned to the cleaning process. To enhance flexibility, it was made sure that electricity for heating can be replaced efficiently with hot water from alternative energy sources and that heat (hot water) can be supplied from three energy sources— heat treatment processes, existing co-generation processes or regenerative water heating applications (solar heat).

The results show that an efficient heat exchange module can help to reduce power consumption for media heating by more than 90% and cut the relevant CO2 emissions proportionally.

Exploiting energy saving potentials

The newly developed heat exchange technology enables a direct supply of waste heat from production environment to the sub-process parts cleaning, thus optimising a company’s energy balance in line with EMAS pursuant to DIN EN ISO 50001.

Consequently, it is possible to guarantee the said energy saving potentials through efficient thermal machine shielding and the intelligent provision of internal machine heat for drying processes in combination with interconnected process water heating. These energy savings additionally enhance heat emission from machinery and help to improve working conditions in the machine environment. It additionally reduces concentrations of air pollutants inside the factory. As a result, the typical costs for factory air disposal and conditioning can be saved.

The holistic approach of the ETA project makes it clear that machine optimisation is not the only way to cut energy costs and that there are greater savings to be achieved by thermally interconnecting machine, factory, and production environment.

EMAS of the European Union

The Eco-Management and Audit Scheme (EMAS) is a voluntary EU initiative designed to improve a company’s environmental performance pursuant to EMAS DIN EN ISO 50001. EMAS acknowledges organisations that improve their environmental performance on a continuous basis. Since July 2015, large companies that employ at least 250 staff and have an annual turnover of more than €50 million must be EMAS certified. The EMAS certificate is also a requirement for partial exemption from certain renewable energy surcharges and future relief of the electricity and energy tax for energy-intensive companies in the manufacturing sector.

Image Gallery

  • Assembly and process analysis

    Image: MAFAC

  • Process water coupling (prototype)

    Image: MAFAC


    Image: MAFAC

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