What are the computer system requirements for Mastercam? Mastercam HLE Limitations. Possible Solutions: 1. Make sure your computer has the necessary requirments to run Mastercam. Make sure you are logged in as the administrator of your computer before installing Mastercam. Make sure any unauthorized copies of Mastercam are uninstalled. Make sure Windows Software is the latest release. If it is not, update the Windows Software.

Make sure the Graphics Driver on the computer is the most up to date. If you are running a laptop make sure the dedicated video card is being used, not the integraded.

Many laptops use power saving and disable the dedicated video card which leads to issues with Mastercam. Check video card instructions. If the problem still remains, some antivirus software can interfere with the install process.

Disabling the antivirus while Mastercam installs may solve this issue. If Mastercam is still not working perform the steps in the section below to diable the Hardware Acceleration.

To access the utility, choose Widows Start, browse to the folder based on the version you have installed, click on Advanced Configuration. Select Graphics Support and set the option to Disable. Click the Green Check and then restart Mastercam. For Licensed versions, the graphics setting is now found in the Mastercam Launcher. Right click on the Desktop shortcut and select Properties.

In the Target field copy and paste the following text C-Hooks do not work. For questions please email support caminstructor. Check video card instructions If the problem still remains, some antivirus software can interfere with the install process. Disable hardware acceleration For and prior versions , both HLE and Licensed copies, you’ll need to open the Advanced Configuration utility.

Uncheck the Hardware Acceleration box as shown. Click Ok, then restart Mastercam. If you are running multiple versions of Mastercam, these steps must be done for all.

 
 

 

HLE FAQ – CamInstructor.How to Force SOLIDWORKS to Use Your Graphics Card – MLC CAD Systems

 

Anybody else seeing anything like this with Mastercam? I have all the usual other apps on this workstation and none of them are perceptibly slower, just Mastercam.

Thanks, and regards. Joined Nov 14, Location canada. Click to expand Turns out there is more to it than just the last couple minor Windows Updates. While Mastercam did speed up after rolling back a couple updates, it soon got dog-slow again. I talked to Cimtech and they are aware of the problem, but no fix available :- : Probably can’t read the text The culprit is “Windows 10 Fall Creators Update, version “.

Since you only have 10 days after update installation to roll back, you probably cannot roll this back. Joined May 28, Location AZ. I’m no IT guru, or even a W10 user, so take this for what it’s worth: You might be able to do a System Restore to a time prior to the update, and return the OS to previous state.

Don’t know if that actually works on W10 if it’s still even something you CAN do , but I’ve had good result when I needed to revert to a previous setup in W7. From my understanding the build that causes the issue is Click the start button and then type ‘winver’ to check your build.

Build If your computer will not automatically update to that build, you can force the issue by downloading from the Windows Update Catalog. If your reseller Cimtech is telling you to hold tight then they may not help with issues resulting from forcing a windows update so proceed at your own risk.

I am still seeing this problem. Here are the manifestations: 1. Isn’t noticeable right after a computer restart, but gets progressively worse after the workstation has been running a day or two 2. Mastercam takes minutes like, literally, 5 minutes to start up 3. Printed metal parts can be post processed with conventional metal fabrication processes like tapping, polishing, or machining.

However, with the freedom to design intricate metal parts comes a problem—the more complex the part, the less likely standard workholding can hold it. Composite 3D printers enable fabricators to manufacture high-strength conformal workholding without consuming machine bandwidth. With them, you can produce low-cost tooling and fixturing capable of handling high loads and machining fluids.

For low-volume metal parts, printing both the metal part and the high-strength composite fixture will simplify your workholding design process while ensuring a perfect fit. Custom tools are often prohibitively expensive to create. Tools are often made of multiple materials to maximize performance: many hammers, for example, have hard, heavy metal heads and light, shock-absorbent fiberglass handles. Leveraging the secondary properties of each material yields strong tools that can be either hard and wear resistant or tough and non-marring.

These two fabrication methods are similar in execution, but produce parts with a wide variety of material properties. Having two different fabrication methods—one for PH stainless steel, and one for industrial composites—enables you to 3D print parts for a wide range of requirements and use cases, from tooling and fixtures to low-volume end-use parts and functional prototypes. Current and potential employees in Singapore will soon be able to add robotics literacy, an increasingly important skill, to their CVs as automation gains wide adoption in the country.

While manufacturers have been collecting information from across the manufacturing floor for decades, in recent years the cost of implementing smart sensors has gone down significantly, and conversely, analytics capabilities have grown extensively.

As a result, today we have the technology to go beyond data capture to extrapolate near real-time insights to inform and optimise processes for better outcomes. This is the nirvana of the Smart Factory. In its landmark study, The Internet of Things: Mapping the Value Beyond the Hype, the McKinsey Global Institute proclaimed the greatest potential for creating value from the IoT for manufacturers will be in operations optimisation—making the various processes within the factory more efficient.

This includes using sensors, rather than human judgment and human error , to adjust the performance of machinery. It also involves use of data from production machinery to adjust workflows to eliminate unproductive practices, capacity erosions, inefficiencies and line performance bottlenecks.

This is done by remotely tracking, monitoring, and adjusting machinery, based on sensor data from different parts of the plant and even across plants. Monitoring machines to harness and understand data can help manufacturers optimise machine performance by enabling more proactive, predictive maintenance. Using sensors to determine when machines need service can prevent breakdowns and save on routine maintenance costs.

Connecting equipment with sensors through a common platform can provide invaluable data about the ongoing condition of equipment that can be analysed to predict potential points of failure for equipment breakdown and production shutdown. In the event a breakdown does occur, organisations can analyse this data to determine root cause and take corrective actions to prevent future occurrences.

Monitoring can also deliver improved quality and production throughput, through greater uptime and overall equipment effectiveness, less scrap and rework, and lower operating costs.

Additionally, these efforts can support continuous improvement initiatives and contribute to heightened workforce engagement, by keeping front-line workers and management informed for improved responsiveness, ownership and accountability.

Remote monitoring, tracking, and control of equipment and workflow also can support additional efficiencies in optimised energy usage. This cost savings in this regard can be considerable, especially in instances when energy prices rise precipitously.

Using sensor technology, manufacturers can then track serialised and non-serialised components as they are received, warehoused and used to construct sub-assemblies and finished goods. Prior to the start of processing, traceability and production control can ensure the correct part is being run, the correct machine program type is being used, that the part was not previously rejected as bad, that the part is at the correct operation no process was skipped , and that parts are not run a second time at the same operation, and that part orientation is correct for processing.

However, the velocity and volume of data on the manufacturing floor can be a hardship to manufacturing organisations that do not have the right technology infrastructure in place. Having the right software foundation to capture, analyse and act is critical.

A unified reporting framework to simultaneously view and easily discern information from multiple, disparate data sources is just the beginning. Manufacturers need to have the operational agility to act on this data and apply these insights across the entire product lifecycle—from design, through engineering, manufacturing, delivery, and service—to deliver immediate and actionable information to the necessary departments and functions with greater speed, accuracy, and efficiency than ever before.

Seco Tools has expanded its popular family of T helical milling cutters to include five new cutters for economical and versatile roughing and semi-finishing operations. Designed specifically with aerospace manufacturers in mind, the new long reach cutters with HSKA back ends optimize side-milling operations. With replaceable ends, the cutters allow for custom solutions if needed and the capability to replace the first row of pocket seats without replacing the entire system.

The cutters excel in applications with sticky materials such as stainless steels and high temperature alloys. The high-positive, free-cutting insert geometries and grades boost tool life, while the tangentially mounted multi-edged inserts enable efficient chip flow and provide stability.

In addition to that, the bending systems save up to 60 percent of the production time for tubes with a diameter up to mm. The fast setting-up of the machine, at times in less than 10 minutes, also plays a crucial role. These tight bending radii are achieved with minimal thinning of the tube walls. This leads to benefits also in terms of space on board ships. We have found that one of the best computer upgrades is to invest in a NVMe drive.

These drives are now priced at a point which makes them a good investment. Many of our test systems employ a smaller primary NVMe drive for the OS and installed applications with a second large capacity conventional drive for data. A 3D mouse improves the way you interact with your 3D application. It is designed to be used by your non-dominant hand in tandem with a standard mouse for a balanced and cooperative work style.

Additional technical and purchase information can be found on the 3Dconnexion website. Most computers today have some kind of anti-virus software to protect from unwanted malware. In some cases, these have been found to interfere with applications such as Mastercam which are running on the computer.

CNC Software does not recommend specific anti-virus products, but if you see unexpected issues, it may be a conflict with anti-virus software. Try temporarily disabling the anti-virus software or setting an exception for Mastercam. Our global community of Mastercam users, experts, educators, and enthusiasts helps you get the most from your investment. Skip to content. Stay up to date with the latest version of Mastercam.

Full 3D CAD modeling. Context-sensitive help available from all dialog boxes. Robust 2D through Multiaxis cutting strategies. Explore Mastercam products including Mill , Lathe , and Router.

Intelligent, stock-aware toolpaths. Complete tool library and custom tool support. Get your free copy of Mastercam Learning Edition today! Request a Free Mastercam Download.