Reliable Vacuum for Plasma Nitriding Ensures Batch Quality and Saves Material

The core area of expertise of HWL Löttechnik GmbH in Berlin is heat treatment of steel and other metals, mainly for the aerospace and automotive industries and for power plant technology. They offer nearly all types of heat treatment, from induction hardening and annealing, to vacuum hardening, annealing and brazing, and all types of case-hardening. For the plasma nitriding process, HWL relies on the vacuum technology from Busch that is used in the nitriding furnace.

Kai Lembke has worked in the HWL family-run business since 2004 and has been a shareholder and member of the management board since 2011. He sees his company as a development partner for many of his customers, who often come to him with only an idea. These ideas become the basis for prototypes, small-scale production, and often result in large-scale production. In most cases, the process includes extremely complex tasks in which HWL works together with the customer to find a solution. HWL's activities as official Rolls Royce Aerospace research association partner are a sign of respect for the family business as a competent supplier.

Plasma nitriding is becoming more and more important for heat treatment at HWL. They have more than 30 years of experience with this process. Today, state-of-the-art system technology and control ensure that the structure and composition of the compound and diffusion layers can be continually controlled and monitored. Pulsed direct current plasma is used to achieve uniform heat treatment results. The advantage of this thermochemical process is that heat treatment can be performed at comparatively low temperatures between 520° and 580° Celsius. Free charge carriers for electricity transmission must be available to make the plasma electrically conductive. At atmospheric pressure, economically unrealistic temperatures would be required to produce electrical conductivity of the plasma. HWL works with pressures of 2.5 millibar, which, in practice, enables heat treatment below 600° Celsius. The temperatures are low when compared to other heat treatment methods and this has an extremely positive effect on the warping behaviour of the components. Another advantage to this method is that individual sections of components that should not be nitrided can be mechanically masked and thus selectively excluded from the nitriding process. This does not change the properties of outer layers underneath the masked sections.


Fig. 1: Vacuum system consisting of an R 5 rotary vane vacuum pump and a Puma vacuum booster from Busch

Before the actual plasma nitriding process, the components to be treated are precisely placed on the mounting device. HWL's many years of experience pay off here as the parts must be optimally positioned in the furnace to achieve the desired surface properties. After the charging procedure and after the furnace is closed, it is evacuated to the required process pressure and heated using the wall heater. After this heating process, the components are exposed to glow discharge in a nitrogen atmosphere. A plasma is created in this glow discharge. The nitrogen dissociates in the process, ionises, and is fired at the surface of the components. The exact handling temperature and nitriding duration depend on the material, size and composition of the components, and the nitriding depths to be achieved. After the nitriding procedure, the furnace with the components is cooled down. The entire process lasts between 17 and 30 hours. The vacuum system is in operation during this period (fig. 1).

After HWL already had positive experience with other heat treatment systems with vacuum pumps from Dr.-Ing. K. Busch GmbH, a new nitriding furnace was acquired in 2013, and it also had a Busch vacuum system. It consists of R 5 rotary vane vacuum pump as a backing pump and a Puma vacuum booster. This vacuum system achieves an ultimate pressure of <1 x 10-2 mbar while the actual operating pressure during the process is 2.5 millibars. This utilizes the optimal pumping speed of the vacuum system, which is highest in this operating range (fig. 2).


Fig. 2: Vacuum system pumping speed

At the beginning of the process, the R 5 rotary vane vacuum pump evacuates the furnace from atmospheric pressure to a rough vacuum of 100 millibars. The Puma vacuum booster is turned on only now. As a booster, it considerably increases the pumping speed of the vacuum system to quickly achieve and reliably maintain the process pressure. By combining the vacuum system with a rotary vane vacuum pump and its controls, which are specifically coordinated for the process, it is possible to achieve maximum pumping speed with the lowest possible energy expenditure.

Precise maintenance of the operating pressure and pumping speed guarantees the ability to run and document replicable processes. This makes it possible to precisely achieve the desired product properties. Most of the time, high-alloy stainless steels are plasma nitrided at HWL but construction steels or sintered metals are also heat treated using this process.
Since starting up the nitriding furnace in 2013, there has never been a vacuum system malfunction or failure even though it is in operation around the clock. Continuous operation is only interrupted by set-up or placement times.

For Kai Lembke, absolute reliability of the vacuum technology has the highest priority. This is because failure of the vacuum system during the process can make the entire batch of top-quality and costly precision components unusable. During this time there has never been a vacuum supply malfunction. This is why it is clear to Kai Lembke that the only nitriding systems worth considering for the planned expansion of the company and the Plasma Nitriding division must be equipped with Busch vacuum technology. Maintenance of the vacuum system is limited to a minimum. In addition to daily visual inspection of the oil level, the oil in the R 5 rotary vane vacuum pump and in the gear of the Puma vacuum booster is changed every two years. Kai Lembke also knows that the Busch Service Center is nearby and can be on site immediately if anything ever happens.

About HWL Löttechnik

HWL Löttechnik was founded in 1981 in a courtyard in Berlin-Wedding, Germany, with just one employee. In 1983, Berlin's first-ever vacuum furnace began operation at HWL. Since then, they have dealt with the heat treatment of steel and other metals including titanium. In 1996, the company moved to a new building in Berlin-Reinickendorf. In 2006, they moved into a second site. Today HWL has 30 employees and is already planning further expansion to a third site. The equipment is in operation 365 days a year.


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