PrecisionCAT Solidworks Assembly Files and Build of Materials

The attached zip files include SolidWorks pack-and-go assemblies of NREL's HERO WEC (hydraulic and electric reverse osmosis wave energy converter), the reverse osmosis (RO) assembly, and the submersible pump assembly that is used to provide flow to the RO assembly in the electric configuration. These 3 models were upgraded in 2023 from their baseline models. The HERO WEC model does not include all aspects of the design (i.e. RO system, electrical enclosure, hose, cable), it only includes the WEC and PTO (power take-off) design. This model supersedes the old MHKDR model submission, linked below. The RO model file includes a SolidWorks (version 2023) pack-and-go assembly of the RO assembly that was used for HERO WEC as it was upgraded in 2023. This model ONLY includes the RO assembly and not the WEC, hoses, etc. The submersible pump enclosure model includes a SolidWorks (version 2023) pack-and-go assembly of the submersible pump assembly that is used to provide flow to the RO assembly in the electric configuration HERO WECas it was upgraded in 2023. This model ONLY includes the submersible pump assembly and not the WEC, RO system, hoses, etc. This work has been developed by the National Renewable Energy Laboratory, operated by Alliance for Sustainable Energy, LLC, for the U.S. Department of Energy (DOE) under Contract No. DE-AC36-08GO28308. Funding provided U.S. Department of Energy Office of Energy Efficiency and Renewable Energy Water Power Technologies Office.

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PurposeOpen-wedge high tibial osteotomy (HTO) is a common surgical treatment for medial osteoarthritis in young and active patients. The accuracy of osteotomy is closely associated with postoperative efficacy. The accuracy of digital preoperative planning is higher than that of the preoperative manual measurement and several computer software with varying accuracy and convenience are used for digital preoperative planning. This study aimed to use the SolidWorks software for HTO preoperative planning and to determine its accuracy and reliability in HTO preoperative planning.MethodsWe reviewed the data of 28 patients with 54 with medial compartment knee arthritis who underwent open-wedge HTO preoperative planning using SolidWorks between June 2019 and March 2021. The standard anteroposterior standing whole-leg radiographs were assessed before and 6 weeks after the surgery. The correction angle, weight-bearing line (WBL) ratio, mechanical femorotibial angle (mFTA), and medial proximal tibial angle (MPTA) before and after the surgery were compared. The clinical results were evaluated using the Knee Society score.ResultsAt 6 weeks after the surgery, the WBL ratio was corrected from 16.8% to 50.5%, mFTA was corrected from 6.4° varus to 1.2° valgus, and MPTA was corrected from 83.4° to 89.3°. No significant difference was observed between the predicted correction angle before the surgery and the correction angle measured 6 weeks after the surgery (t = −1.745, p = 0.087). The knee score and function score of Knee Society increased from 76.4 and 80.7 before surgery to 95.0 and 95.7, respectively.ConclusionsThe SolidWorks software showed high accuracy and reliability in preoperative planning of open-wedge HTO in patients with medial compartment knee arthritis.

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Full SolidWorks 2016 CAD assembly for the UNH tow tank and turbine test bed.

The Computer-Aided Design (CAD) software market is experiencing robust growth, driven by increasing adoption across diverse industries like manufacturing, architecture, engineering, and construction (AEC). The market's expansion is fueled by several key factors: the rising need for efficient design processes, the proliferation of 3D printing technology, and the growing demand for sophisticated simulation and analysis tools integrated within CAD software. The shift towards cloud-based CAD solutions is also a significant trend, offering enhanced collaboration and accessibility. While the exact market size in 2025 is not specified, considering a reasonable CAGR of 10% (a conservative estimate based on industry reports showing growth between 8-12%) and assuming a 2024 market size of $50 billion USD (a reasonable estimation considering the prominence of the players listed and the broad industry application), the 2025 market size could be estimated at roughly $55 billion. This growth is expected to continue throughout the forecast period (2025-2033), although the pace might moderate slightly as the market matures. Key players like Autodesk, SolidWorks, and Bentley Systems maintain a strong market presence due to established brand reputation and comprehensive feature sets. However, emerging players offering specialized solutions or innovative cloud-based platforms are gaining traction, intensifying competition within the sector. The market faces certain restraints, including the high cost of advanced CAD software and the need for specialized training to effectively utilize these complex applications. Furthermore, data security concerns related to cloud-based solutions can pose challenges for some industries with stringent regulations. Market segmentation reveals significant demand across various industries, with AEC and manufacturing accounting for the largest shares. Geographic variations in adoption rates exist, with developed regions like North America and Europe currently leading the market, but significant growth potential lies in developing economies fueled by increasing industrialization and infrastructure development. The sustained adoption of generative design and AI-powered features further indicates a promising future for the CAD software market.

The Laboratory Upgrade Point Absorber (LUPA) is an open-source wave energy converter designed and tested by Oregon State University. The computer-aided design (CAD) files are provided here in two forms: the original SOLIDWORKS (2021) model as "LUPA SOLIDWORKS.zip" and as a STEP file "LUPA-A1000.step". The bill of materials is provided as an Excel file with assemblies (LUPA-Axxx), part numbers (LUPA-Axxx-Pyyy), part descriptions, manufacturers, and manufacturer part numbers. This comprehensive CAD model represents LUPA as it was deployed in Fall 2022 testing at the O.H. Hinsdale Wave Research Laboratory. The mass properties including mass, center of gravity, and moments of inertia have been overridden for some parts and assemblies to match the physical device properties as determined from experiments. This appears as "overridden by user" when viewing mass properties in SOLIDWORKS. The LUPA-A1000.SLDASM file from the LUPA SOLIDWORKS.zip folder is the topmost assembly, open this file to see the entire model as one assembly. See "PMEC Page", "OpenEI Wiki Page", and the "Signature Project Page" resources below for more information on LUPA.

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CAD model of the Dynamic Robotic Actuator (Dyrac). The Dyrac actuator was developed in the frame to reproduce human hammering motions in a teleoperation scenario. The design requirements were were a stiffness changing time of 50 ms, a peak output velocity of 20 rad/s, and variable damping.Performance measurements on the prototype showed an effective stiffness changing time of 50-120 ms for small to large stiffness steps, nominal output velocity of 16 rad/s, and a variable damper with a damping torque of 0-3 Nm. Its effective stiffness range is 0.2-313 Nm/rad.

qyhhhhh/solidwork dataset hosted on Hugging Face and contributed by the HF Datasets community

Structural specification of samples designed by Solidworks.

Este Trabalho de Conclusão de Curso apresenta a utilização de um software CAD – Computer Aided Design, traduzido por desenho assistido por computador, em uma disciplina de Projeto de Produto dos cursos de Engenharia de Produção e Engenharia de Produção Mecânica. Para proporcionar um ambiente prático de concepção de produto foram realizadas aulas básicas de modelagem no software SolidWorks, utilizando ferramentas e recursos para modelar e montar um produto. Para montagem das aulas será apresentado como se deu a escolha do produto e do software, além da construção das aulas e as etapas da construção do produto utilizando a modelagem digital. Foi realizado um estudo breve das tecnologias de impressão 3D contendo a forma na qual realiza o procedimento de impressão e também foram descritas algumas vantagens e desvantagens de cada tipo de máquina. Este trabalho de conclusão se dispõe a apresentar linhas e métodos que são utilizados para a geração de conhecimento. Como o professor pode criar um clima organizacional que realmente agrega valor aos discentes tanto acadêmico como profissional. Por fim este trabalho dedicou-se a analisar os impactos relacionados a construção da aula ministrada de SolidWorks pelos monitores. Foi montado um questionário para a geração de dados suficientes com a finalidade de estudar a percepção dos alunos perante software utilizado.

The Computer-Aided Design (CAD) software market, currently valued at $19,930 million (2025), is projected for robust growth, exhibiting a Compound Annual Growth Rate (CAGR) of 6.5% from 2025 to 2033. This expansion is driven by several key factors. The increasing adoption of CAD software across diverse sectors like architecture, engineering, and manufacturing reflects a broader trend towards digitalization and automation in design processes. The rising complexity of projects and the demand for higher precision and efficiency further fuel the market's growth. Furthermore, advancements in 3D modeling capabilities, the integration of artificial intelligence (AI) for enhanced design automation, and the proliferation of cloud-based CAD solutions are contributing to this upward trajectory. The market is segmented by application (Education, Architecture, Art & Design, Mechanical Design, and Others) and type (2D, 3D, and Others), allowing for specialized software catering to specific industry needs. Competition is fierce, with established players like Autodesk, SolidWorks, and Bentley Systems vying for market share alongside emerging providers offering innovative solutions. While potential restraints could include the high initial investment costs for software licenses and training, the long-term benefits in terms of productivity and accuracy outweigh these hurdles, driving continued adoption. The geographical distribution of the CAD software market is widespread, with North America, Europe, and Asia Pacific representing major revenue streams. However, the burgeoning economies in Asia Pacific, particularly in countries like India and China, are poised for significant growth due to their expanding manufacturing and construction sectors. This regional diversification presents ample opportunities for CAD software vendors to tap into new markets and expand their reach. The continuous innovation in CAD technology, coupled with growing demand across various industries and regions, positions the market for sustained, substantial growth throughout the forecast period. The competitive landscape necessitates continuous product development and strategic partnerships to maintain a competitive edge. The focus on user-friendly interfaces and cloud-based accessibility is further streamlining adoption and enhancing market penetration.

The CNC software market for CNC machines is experiencing robust growth, driven by increasing automation across manufacturing sectors and the rising adoption of Industry 4.0 technologies. The market, estimated at $2.5 billion in 2025, is projected to expand significantly over the forecast period (2025-2033), fueled by a Compound Annual Growth Rate (CAGR) of approximately 12%. This growth is propelled by several key factors. Firstly, the demand for precision and efficiency in manufacturing processes is pushing businesses towards CNC machining, creating a corresponding need for sophisticated software solutions. Secondly, the proliferation of small and medium-sized enterprises (SMEs) adopting CNC technology, alongside the continued expansion of large enterprises already utilizing CNC, widens the user base for CNC software. Furthermore, advancements in software capabilities, including improved CAM (Computer-Aided Manufacturing) functionalities, simulation tools, and integration with other manufacturing software, are enhancing productivity and reducing errors. The diverse range of operating systems supported (Windows, macOS, Linux, Raspberry Pi) further broadens the accessibility and applicability of this software. However, market growth is not without its restraints. The high initial investment cost of CNC software, particularly advanced packages, can be a barrier to entry for smaller businesses. Additionally, the complexity of some software can require significant training and expertise, leading to potential adoption hurdles. Competition within the market is also fierce, with established players like Autodesk (AutoCAD, Fusion 360), SolidWorks, and Mastercam vying for market share alongside emerging providers of open-source and specialized software. Despite these challenges, the long-term outlook for the CNC software market remains positive, driven by ongoing technological innovation and the consistent demand for improved manufacturing efficiency. The market segmentation, across various applications (large enterprises, SMEs) and operating systems, indicates significant opportunity for specialized software tailored to particular needs and user preferences. Regional variations in adoption rates are expected, with North America and Europe likely maintaining leading positions due to established manufacturing industries and higher technological adoption rates.

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Contains the Reference Model 3 (RM3) full scale geometry files of the Wave Point Absorber, developed by the Reference Model Project (RMP). These full scale geometry files are saved as SolidWorks assembly, IGS, and STEP files, and require a CAD program to view. This data was generated upon completion of the project on September 30, 2014.

The Reference Model Project (RMP), sponsored by the U.S. Department of Energy (DOE), was a partnered effort to develop open-source MHK point designs as reference models (RMs) to benchmark MHK technology performance and costs, and an open-source methodology for design and analysis of MHK technologies, including models for estimating their capital costs, operational costs, and levelized costs of energy. The point designs also served as open-source test articles for university researchers and commercial technology developers. The RMP project team, led by Sandia National Laboratories (SNL), included a partnership between DOE, three national laboratories, including the National Renewable Energy Laboratory (NREL), Pacific Northwest National Laboratory (PNNL), and Oak Ridge National Laboratory (ORNL), the Applied Research Laboratory of Penn State University, and Re Vision Consulting.

Reference Model 3 (RM3) is a wave point absorber, also referred to as a wave power buoy, that was designed for a reference site located off the shore of Eureka in Humboldt County, California. The design of the device consists of a surface float that translates (oscillates) with wave motion relative to a vertical column spar buoy, which connects to a subsurface reaction plate. This two-body point absorber converts wave energy into electrical power predominately from the device's heave oscillation induced by incident waves; the float is designed to oscillate up and down the vertical shaft up to 4 m. The bottom of the reaction plate is about 35 m below the water surface. The device is targeted for deployment in water depths of 40 m to 100 m. The point absorber is also connected to a mooring system to keep the floating device in position.