SolidWorks System Requirements - MVP Blog

SolidWorks System Requirements

The majority of software programs have a set of minimum system requirements, including those for video cards, to ensure compatibility with a user’s computer hardware. Nevertheless, these requirements often only provide the bare minimum necessary to run the software and do not take into account the hardware that would offer optimal performance. In some instances, the lists can also be outdated, specify outdated hardware versions, or simply suggest inferior hardware options.

In an effort to provide a more reliable and accurate recommendation, we have conducted thorough testing to determine the hardware that performs best with SOLIDWORKS. As a result, we have created our own list of recommended hardware based on our findings.

CPU for SolidWorks

For SOLIDWORKS modelling, the ideal CPU choice is the Intel Core i7 13700K. This CPU is favoured due to its high operating frequency, which is crucial for fast performance in general modelling tasks in SOLIDWORKS such as opening and saving files, rebuilding assemblies, and rotating models. The Core i7 13700K boasts high clock speeds and improved per-core performance, as well as additional efficient cores for handling background tasks and multithreading, allowing the main cores to focus on active workloads. If even more power is desired, the Core i9 13900K offers higher clock speeds and additional efficiency cores for improved multi-tasking.

SolidWorks 2020 SP5 | Benchmarks Simulation 2000K

For simulation in SOLIDWORKS, the Intel Xeon W-3365 32 Core is a top choice. Simulation workloads are sensitive to both clock speed and the number of CPU cores. They also require substantial memory bandwidth and a larger overall system RAM. For this reason, Intel’s high core count Xeon W processors are ideal for simulation, particularly for FEA and Flow simulations, while still delivering excellent performance for general SOLIDWORKS modelling tasks. The additional cores in the Xeon W-3365 32 Core also enhance rendering performance with PhotoView 360. If rendering is the primary focus, even higher core count CPUs like AMD’s Thread Ripper PRO line will deliver faster results.

Will having more CPU cores enhance SOLIDWORKS performance?

When it comes to modelling and working with assemblies in SOLIDWORKS, the number of cores is not a major factor in determining performance. Our testing has revealed that the operating frequency of the processor plays a more significant role in overall performance for general modelling tasks. On the other hand, simulation and rendering can experience moderate to significant performance gains with an increased number of cores, which is why we utilise Intel Xeon W CPUs with up to 32 cores for our simulation workstations.

Is it necessary to have a Xeon CPU for SOLIDWORKS?

Some Intel Xeon processors offer higher core counts and larger memory capacities compared to the Core models, as well as support for additional instruction sets, which can enhance performance in rendering and certain types of simulation. However, Xeon CPUs generally have a lower operating frequency than Core i7 and i9 CPUs, meaning that some performance may be sacrificed for general modelling tasks. We offer workstations based on both platforms to accommodate the different needs and budget considerations of SOLIDWORKS users.

Is overclocking a suitable option for SOLIDWORKS?

As a general rule, we do not recommend overclocking for professional workstations. The modest performance increases achieved through overclocking are often outweighed by the potential downsides, such as instability, shortened hardware lifespan, and the risk of producing inaccurate data.

When it comes to video cards for SOLIDWORKS, Dassault Systemes suggests using a workstation GPU. This type of card has been found to offer significant performance benefits over other options, such as a low-end Quadro that outperforms other, faster GeForce cards. Additionally, using a certified GPU is necessary to receive official support for features like Realview and Ambient Occlusion.

Before SOLIDWORKS 2019, there was little variation in performance between different Quadro video cards, except for complex assemblies on high resolution monitors. However, with the introduction of the “Enhanced Graphics Performance” mode in SOLIDWORKS 2019, the video card plays a larger role in displaying parts and assemblies, resulting in a noticeable difference in frame rates depending on the Quadro card used.

SolidWorks 2019 SP1 | 1080P Viewport Frame Rate with Quadro GPUs

Graphics card for SolidWorks

For SOLIDWORKS, it is recommended to use a workstation card from companies like Nvidia or AMD. Our research has shown that in certain cases, a lower end Quadro card can perform better than a high-end GeForce card. To have access to features like Realview and Ambient Occlusion, it is important to use a certified card.

Before SOLIDWORKS 2019, there wasn’t a noticeable difference in performance between different Quadro video cards, except for very complex assemblies on high-resolution monitors. With the introduction of “Enhanced graphics performance” mode in SOLIDWORKS 2019, the video card plays a larger role in displaying parts and assemblies. This means that there is now a significant difference in frame rates between different Quadro cards. Based on our findings, we suggest selecting a video card that provides smooth frame rates, exceeding 30fps, for most situations, depending on model size and resolution. These are the best Graphic Card for Solidworks

SolidWorks 2019 SP1 | 4K Viewport Frame Rate with Quadro GPUs

Solidworks RAM Requirements

The amount of RAM needed for SOLIDWORKS can vary based on the complexity of the models being worked on. However, as a general guideline, SOLIDWORKS requires between 4-8GB of RAM for tasks such as rotating models, simulations, and rendering. To ensure optimal performance, it is recommended to have 16GB of RAM in your system.

One way to determine the necessary amount of RAM is to calculate 5GB of RAM for SOLIDWORKS and an additional 20 times the largest assembly size you work with. For example, if your assemblies are around 200MB in size, you would need a minimum of 5GB + 20 x .2 = 9GB of RAM. This formula provides the following minimum recommended RAM amounts for various assembly sizes.

Check out our catalogue of optimised Solidworks builds here.

We build and ship Custom PCs across India with upto 3 years of Doorstep Warranty & Lifetime Technical Support. We have 3 stores in Hyderabad, Gurgaon & Bangalore. Feel free to visit them or get in touch with us through a call for consultation.

SHARE THIS POST

1 Comments Text
  • Mancubus0Brish says:
    Your comment is awaiting moderation. This is a preview; your comment will be visible after it has been approved.
    vibration monitoring equipment Vibration Monitoring Equipment: The Balanset-1A Solution In industries reliant on machinery with rotating components, the significance of vibration monitoring equipment cannot be overstated. Among such equipment, the Balanset-1A serves as a versatile portable balancer and vibration analyzer. This dual-channel device is meticulously engineered to facilitate dynamic balancing in multiple applications, enhancing operational efficiency while minimizing downtime. Comprehensive Overview of the Balanset-1A The Balanset-1A is a cutting-edge vibration monitoring equipment specifically designed for balancing various rotor types, including crushers, fans, mulchers, augers on combines, shafts, centrifuges, and turbines. Its robust functionality enables users to achieve high precision in balancing operations across a wide variety of industrial applications. This device stands out due to its simplicity of use and powerful analytical capabilities. It encompasses advanced technologies that allow for effective vibration analysis and balancing, essential for preventing equipment deterioration and ensuring smoother operational processes. Key Features of the Balanset-1A The Balanset-1A is equipped with numerous features that enhance its performance as a vibration monitoring equipment. Notable functionalities include: Vibrometer Mode: This function accurately measures the rotational speed (RPM) of machinery, providing insights into the performance of rotating components. Phase Measurement: The phase angle of the vibration signal can be determined, allowing for precise vibration analysis. Frequency Spectrum Analysis: The FFT (Fast Fourier Transform) Spectrum feature offers detailed frequency spectrum analysis, serving as an essential tool for diagnosing vibration issues. Overall Vibration Monitoring: It continuously monitors overall vibration levels, helping maintain operational stability. In addition to the analytical capabilities, the Balanset-1A is proficient in providing balancing solutions: Single Plane Balancing: Effectively reduces vibration by achieving balance in a single plane. Two Plane Balancing: Facilitates dynamic balancing by employing a two-plane approach for enhanced accuracy. Visual Tools: The polar graph feature visualizes imbalance, thereby aiding users in accurately positioning corrective weights. Tolerance Calculation: The device computes acceptable balancing tolerances in compliance with ISO 1940 standards, ensuring industry compliance. Enhanced Functionality for Practical Applications The practicality of the Balanset-1A extends beyond basic analysis and balancing functions. It includes capabilities for grinding wheel balancing, where the device utilizes three counterweights for optimal results. Moreover, the Balanset-1A supports the storage of historical data, which can be pivotal during subsequent analysis or re-balancing activities. Users can easily retrieve past measurements and generate detailed reports of the balancing outcomes, streamlining procedures and enhancing operational efficiency. This vibration monitoring equipment is adaptable and user-friendly, accommodating both Imperial and Metric measurement systems, thus ensuring applicability in diverse geographical regions and industry standards. Specifications and Components of the Balanset-1A For those considering the Balanset-1A as their vibration monitoring equipment, understanding its specifications is crucial. This device features: Two vibration sensors (Vibro Accelerometers) with a standard cable length of 4 meters, offering an optional extension up to 10 meters. An optical sensor (Laser Tachometer) that operates effectively at distances between 50 to 500 millimeters. A comprehensive software interface that includes capabilities for measuring vibration, torque phase angles, and correction mass calculations. In terms of performance metrics, the Balanset-1A supports a range of functions and can accurately measure: RMS Vibration Velocity from 0 to 80 mm/s. A frequency range of RMS vibration velocity measurements from 5 to 550 Hz. Measurement accuracy rates, ensuring reliable operational data. Conclusion: The Importance of Vibration Monitoring Equipment Investing in vibration monitoring equipment, such as the Balanset-1A, is essential for industries aiming to enhance the longevity and efficiency of their machinery. The importance of dynamic balancing cannot be sidelined, as unbalanced rotors can lead to excessive wear, potential failures, and increased operational costs. The Balanset-1A offers a compelling solution through its advanced features, ease of use, and adaptability across various industrial applications. In summary, the Balanset-1A revolutionizes vibration analysis and balancing processes, making it an indispensable tool for professionals dedicated to maintaining operational excellence in their equipment. As industries continue to strive for efficiency, the role of reliable vibration monitoring equipment will remain increasingly vital.
  • Leave a Reply

    Your email address will not be published. Required fields are marked *

    themvp.in | All rights reserved