Month: September 2018

Morel Speakers is a brand that is respected worldwide by audiophiles and sound aficionados alike. Founded in 1975, Morel is an esteemed manufacturer of high-quality sound equipment, but the jewel in their crown is undoubtedly their range of speakers. Crafted with scientific precision, Morel Speakers offer unparalleled sound quality that impresses even the most discerning audiophiles. In this article, we delve deeper into the science behind the unparalleled excellence of Morel Speakers.

At the heart of the technology driving Morel forward is their commitment to acoustic research and innovation. It may surprise some to know that speaker technology is not as straightforward as it appears. Basic speaker designs have been around for a century, and while these designs have been refined, the science behind them remains the same. This is where Morel has led the charge by revolutionizing speaker technology.

The core science behind Morel Speakers is their approach to transducer design. Morel’s unique ‘Unified Field’ magnet system morel speakers involves a hybrid magnetic motor system. This system combines two types of magnets, Neodymium and Ferrite, demonstrating a unique understanding of magnetic field geometry. The combination of high-energy Neodymium and high-inductance Ferrite magnets allows Morel’s speakers not only to deliver a higher magnetic field in a compact design, but also aids in the control of the speakers in a more precise manner than traditional systems.

Another aspect of the science behind Morel’s success is their cone technology. Morel invests heavily in materials research to produce the best cones for their speakers, providing excellent rigidity and damping characteristics while avoiding unwanted resonance. Their unique C.A.R filter – Controlled Acoustic Resistance – optimizes the airflow within the speaker, resulting in greater control and improved efficiency. This material science and careful design lead to a more direct and accurate sound reproduction.

Morel has also revolutionized the way speakers handle temperature. Heat generation is a natural byproduct of the electrical energy applied to any speaker, and too much heat can distort sound. Morel’s External Voice Coil (EVC) technology is central to dealing with this problem. EVC allows more of the voice coil to be exposed to the air, leading to better heat dissipation and higher power handling.

Furthermore, understanding the way sound travels and how listeners perceive audio is another component of Morel’s strategy. By using inventive, off-axis tweeter designs and a ground-breaking sound radiation pattern, Morel Speakers deliver a more accurate and consistent sound to listeners.

In essence, Morel has elevated speaker designing to a form of science in itself. Combining physics of sound, material science, and clever mechanical design, they deliver products that are well ahead of their competition. It’s the relentless pursuit of perfection, rigorous testing, and innovation that keeps them at the forefront of speaker technology.

In conclusion, Morel is not just another speaker brand. It is the result of years of intense dedication to studying and understanding the science of sound, resulting in crisp, clean, and quality audio. Through their clever use of magnet systems and cone technology, their focus on temperature control and sound perception – it’s clear why Morel Speakers are hailed as the epitome of audio excellence. Understanding the science behind Morel Speakers truly underscores the remarkable craftsmanship and engineering prowess that goes into every unit, emphasizing why they are a beloved choice for sound enthusiasts worldwide.

In today’s competitive manufacturing industry, cell manufacturing and lean principles are playing a prominent role in improving the quality and efficiency of manufacturing systems. Lean principles involve a systematic approach to identify and eliminate waste while focusing on continuous improvement. In cell manufacturing, workstations are arranged in a way that they can handle a specific set of tasks with a lesser need for handling and transportation activities. The implementation of lean principles in cell manufacturing quality systems has been shown to produce significant results in terms of waste reduction, increased productivity, and better quality control.

Cell manufacturing aims at reducing product lead time, eliminating cell manufacturing quality system transportation, and improving productivity and quality. It involves grouping machines and workstations according to product flow rather than the type of machine or equipment. Lean principles involve a systematic approach to identify and eliminate waste while focusing on continuous improvement.

The first step to implement lean principles involves creating a vision for the quality management system. The vision should be clear, specific, and measurable. It should identify the objectives of implementing lean principles in cell manufacturing quality systems. The objectives should be geared towards reducing waste, increasing productivity, improving quality control, and enhancing overall performance.

The second step involves conducting a thorough analysis of the current manufacturing process to identify areas of waste in cell manufacturing. A value stream map can be used to identify the different steps involved in the process and the various wastes generated. The wastes generated include overproduction, stock, transportation, waiting, over-processing, defects, and underutilization of talent. After identifying the wastes, the next step is to categorize them into three broad categories; value-adding activities, necessary non-value-adding activities, and non-value-adding activities.

After identifying the wastes, the next step is to eliminate them. The non-value-adding activities should be eliminated or minimized as much as possible. The value-adding activities should be improved to increase productivity and reduce lead times. The necessary non-value-adding activities should be maintained at the optimal level to ensure they do not cause any delays or quality issues.

Another aspect of implementing lean principles in cell manufacturing quality systems is to standardize the work processes. This involves creating well-defined and documented processes for all the activities in the manufacturing process. Work instructions should be created for all the standard work processes, and all employees should be trained on the new procedures. This ensures that all employees understand the new processes, and they can follow the correct procedures consistently.

The next step involves continuous improvement. The implementation of lean principles does not end with the elimination of wastes and standardizing work processes. The lean principles approach requires continuous improvement to ensure that the process remains efficient and effective. Continuous improvement involves reviewing the processes periodically, identifying bottlenecks or additional wastes and implementing changes or improvements.

The implementation of lean principles in cell manufacturing quality systems has resulted in significant improvements in the manufacturing process. Some of the benefits of implementing lean principles include; reduced waste, reduced lead time, increased productivity, better quality control, higher customer satisfaction, and increased employee morale. By implementing lean principles, cell manufacturing plants can improve their competitiveness while reducing costs and improving profitability.

In conclusion, the implementation of lean principles in cell manufacturing quality systems requires a systematic approach to identify and eliminate wastes while focusing on continuous improvement. The approach involves creating a vision and clear objectives, analyzing the manufacturing process to identify wastes, eliminating non-value-adding activities, standardizing work processes, and continuous improvement. The successful implementation of lean principles in cell manufacturing quality systems can result in significant improvements in manufacturing processes that lead to increased productivity, better quality, and customer satisfaction, and higher employee morale.