Household appliances

Household appliances

Innovation and reliability in household appliances | ANSYS in practice

Users demand high-performance, durable and reliable products every day, making reliability and energy efficiency key selling points. Testing all failure scenarios before marketing is essential, and equipment manufacturers see CAD as a must-have solution.

In addition to reliability, consumers are looking for products that are easy to use, more compact yet offer maximum capacity, while consuming less energy and making less noise. The design of these sophisticated devices meets complex

mechanical and electrical requirement requiring advanced expertise in dynamics, structures, fluids, thermodynamics and controls. This requires a thorough understanding of market expectations and engineering system dynamics.

Using ANSYS simulation and modelling tools, designers can explore alternatives and refine designs at an early stage when changes are least costly. This also reduces the need for physical prototypes, speeding development and time to market.

Innovation and reliability in household appliances| ANSYS in practice

Users demand high-performance, durable and reliable products every day, making reliability and energy efficiency key selling points. Testing all failure scenarios before marketing is essential, and equipment manufacturers see CAD as a must-have solution.

In addition to reliability, consumers are looking for products that are easy to use, more compact yet offer maximum capacity, while consuming less energy and making less noise. The design of these sophisticated devices meets complex

mechanical and electrical requirement requiring advanced expertise in dynamics, structures, fluids, thermodynamics and controls. This requires a thorough understanding of market expectations and engineering system dynamics.

Using ANSYS simulation and modelling tools, designers can explore alternatives and refine designs at an early stage when changes are least costly. This also reduces the need for physical prototypes, speeding development and time to market.

Customer references

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Antenna Design Using ANSYS Electronics Solutions

The WLAN Dual-band antennas are integrated onto the printed circuit board (PCB). The impedance matching bandwidth must be wide enough for the antenna to perform well in various locations.
By using ANSYS HFSS and ANSYS optiSLang, the influence of various geometric parameters on antenna performance can be evaluated. This helps optimize resonance frequencies, bandwidths, antenna gain, and understand the impact of manufacturing tolerances and different mounting locations. New layout concepts are studied with ANSYS SIwave, particularly optimizing the layout of power and ground planes and the positioning of decoupling capacitors.

In this way, capacitors are saved, and new design rules are established. Signal integrity analysis using ANSYS SIwave shows the potential savings for termination resistances and helps optimize high-speed critical signal lines.
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Simulation of Elastoplastic Materials with Creep Behavior

Under load, plastic components in washing machines exhibit time-dependent effects such as creep and stress relaxation, in addition to plasticity.
In collaboration with CADFEM, Miele conducted a study to determine the material behavior and subsequently adjust its parameters.
ANSYS Workbench and ANSYS DesignExplorer were used to solve this problem, with which a general workflow was developed. Minimizing the force difference between test and simulation values was the methodological basis.
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Simulation of Refrigerator Trim Thermoforming

Thermoforming is widely used for mass production of refrigerator liners. The variation in the thickness distribution of the liner is an important quality parameter that has traditionally been controlled by trial and error. This typically involves choosing different sheet thicknesses and process parameters (temperature, pressure, etc.), resulting in material waste and production time loss.
A thermoforming simulation could quickly and efficiently predict the thickness and distribution of the liner, eliminating material waste and production time.

Engineering Solution:
– ANSYS Polyflow provides different equations to model deformation velocity and viscosity temperature dependence.
– ANSYS Polyflow offers various material models and contact algorithms to effectively reproduce the thermoforming process and predict accurate results.
– Polyflow’s adaptive meshing helps refine the mesh of the sheet as it comes into contact with the mold to closely follow the mold’s geometry.

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Development of Ovens, Washing Machines, and Other Innovative Appliances Using Engineering Simulation

After thorough research on simulation software to better meet evolving needs, V-ZuG found that ANSYS structural mechanics software, supported by CADFEM, its local ANSYS partner, best met its requirements.

Problem 1:
V-ZuG was using ANSYS software to simulate an oven door made of steel, incorporating a glass window glued to the frame. Originally, when the oven operated at high temperatures, the glass would break under thermal loads. To simulate the problem, the engineer imported the door geometry from CATIA into the ANSYS Workbench platform and simulated the thermal load using the ANSYS DesignSpace tool. The simulation results matched those of the prototype, with the highest stresses occurring at the corner where cracking began. The V-ZuG engineer then simulated the performance of various glass materials in ANSYS DesignSpace to identify a material capable of withstanding thermal loads.

Problem 2:
Washing machine developers increased the capacity of the machine from 5 to 8 kg of dry laundry. This change necessitated the development of a vibration absorption system; otherwise, the 8 kg spin cycle would take up too much space in the casing. The engineer simulated the new design using ANSYS Mechanical software.

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