WE STAND WITH UKRAINE, WE STAND FOR FREEDOM!

The Ukraine flag wave in the wind

Like most of you, we are deeply saddened watching the atrocities Russia is committing on the Ukrainian people, at the behest of Mr. Putin, something I never thought would happen in today’s day and age.

As a show of solidarity to the Ukrainian people dying on the streets for their freedom FSD will NOT accept any Russian orders or be conducting business with any Russian affiliates.

I want to clarify that this is not a move to hurt the fun-loving Russian people who want to live and prosper like the rest of the free world, but strictly a move to show our solidarity with #ukraine and the rest of the free world. We want to use our platform to support in any way we can because we are all stronger united. So, I ask that you consider joining me in helping our friends in Ukraine by donating to these trustworthy organizations that are in urgent need of funds:

– Red Cross Ukraine
– Ukraine Armed Forces
– The Come Back Alive Fund
– Nova Ukraine

Here at #FSD, we pray for a quick and peaceful end to this conflict. May peace be restored in Ukraine, and no more innocent lives lost.

Sincerly,
Dave Burgess
President & CEO

LANBI – STABILIZER LINK ASSEMBLY LINE

FSD STABILIZER LINK ASSEMBLY LINE

STABILIZER LINK ASSEMBLY LINE

LANBI has delivered a multireference axial-radial stabilizer link assembly line for a German multinational, including a full range of controls. One only operator is responsible for managing a completely automatic and robotized cell based on 22 stations divided into two rotary tables.

LANBI can provide this kind of assembly totally automatic or in a semiautomatic mode, adapting the solution always to customer needs.

🔽Customized Machines for Ball Joint Assembly 🔽

Our team is available 24/7/365 to support your operations!
Lanbi North America
📞1-800-825-3049 Ext. 108
📧maria.gutierrez@lanbi.com
🌎www.lanbi.com

Unlocking robotics’ potential – Design strategies to boost machine-tending productivity

Fanuc Machine Tending

From turning machines to machining centres to presses and press brakes, the evolution of robotic automation continues to address stringent demands, driving industries forward.

Once used in very controlled environments where low-mix/high-volume production was the only viable and cost-effective option for reasonable ROI, more affordable and extremely capable robots have opened the door to highly flexible production environments, fostering greater yields.

To better fill the uptick in consumer product variety, create agile supply chains, and adapt to labour shortages, manufacturers are complementing current operations with versatile robots and their peripheral technologies to create intelligent factories capable of repetitive high-mix production. Because of their perceived ROI over a given payback period, the use of industrial and collaborative robots alike for machine tending continues to be a front-runner for company leaders looking to quickly address dull, dirty, dangerous, and difficult jobs, freeing workers for higher-value-added tasks.

Whether loading/unloading a CNC machine or tending another piece of equipment for grinding, stamping, or trimming, highly repeatable robots are helping to orient and transport parts, minimizing human error, improving worker safety, optimizing system utilization, and facilitating greater efficiency.

Strategic Robotic System Design

Despite the growing use of robotics, each application requires careful consideration where workcell design is concerned. To unlock the full potential value of these automated systems, manufacturers should evaluate the various automation components.

Robot Type

Choosing the proper robot model to complement the existing workspace, along with the weight, size, and manipulation requirements of the part, is key.

First, it is helpful to have a clear grasp of where the robot will be placed. Compact industrial robots that are easily redeployed can be integrated into a machine tool itself, while larger streamlined arms can be positioned outside of a CNC machine’s sliding door or on a mobile platform, tending operations on an as-needed basis.

With robot placement in mind, it is also important to note the existing environment requirements. For example, will human workers be present in or near the robot work envelope? If so, a collaborative-style robot (cobot) could be used. This could entail the use of a cobot that is inherently safe by design and capable of working safely with (or in close proximity to) human workers, or it could mean the implementation of an industrial robot equipped to work collaboratively via one of the four modes of collaboration: safety-monitored stop, speed and separation monitoring, power and force limiting, and hand guiding.

A hybrid option serves to close the gap between operator safety and speed, increasing cycle time with the addition of a safety device such as a scanner, light barrier, or safety mat. These devices can help the robot detect human presence in the work envelope, slowing the robot when necessary. Either way, the determination to use a cobot or an industrial robot with collaborative features should always be based on the completion of a thorough risk assessment.

The condition of the workspace also should be noted because many machine-tending environments tend to be harsh. In facilities where humidity, dust, and water are present, it is beneficial for manufacturers to implement an IP67-rated robot. To facilitate greater layout flexibility without losing capability, manufacturers in these settings are turning to higher-payload, IP67-rated collaborative robots that offer robust programming options.

Mounting Flexibility

To allow for maximum robot reach, it is best to keep the base as close as possible to the equipment being tended or the part being processed. Bases can be fixed or mobile for easy redeployment.

Most robots are lagged to the floor, but sometimes it’s necessary to accommodate unique floor space layouts. For example, top loading, where a robot “sits” on top of a machine, is quite popular for machine- tending applications. In situations like this, shelf-mounted robots with extended- reach capability far below the robot base are ideal. Likewise, a robot installed in the overhead position is well-suited for servicing two machines, often reducing cycle time and costs.

When greater flexibility is needed for high-throughput operations, a linear-motion robot track can be advantageous, adding a seventh axis of motion to the robot’s operating range. Often used for machine tending in the overhead position to improve machine access, optimize floor space, and extend the work envelope (sometimes doubling, tripling, and even quadrupling the space), robot tracks and rails provide exceptional speed, repeatability, and rigidity.

Robots in this configuration can be installed in various positions (floor-, wall-, and ceiling-mounted), maximizing the robot reach while offering optimum load distribution.

For tasks where having a dedicated robot does not make sense, a greater number of highly flexible autonomous mobile robots (AMRs) are now being used. Replacing less sophisticated fixed-routed automated guided vehicles (AGVs), AMRs combine innovative technologies (LiDAR sensors, vision systems, custom tooling) to equip robots with a high degree of skill and autonomy. These robotic platforms, which can move on their own through a facility to the task they are assigned, make it easy for manufacturers to redeploy industrial and collaborative robots around factories for machine tending where needed.

While the initial setup for AMRs may be more difficult and costly than installing a robot on a stationary riser, for example, the use of AMRs can assist with rapid-scale production during periods of demand volatility. Conversely, stationary robots equipped to work collaboratively can facilitate the loading/unloading of items on and off AMRs for enhanced flexibility in high-mix/low-volume production. Using robots in this way is another option to quickly, accurately, and ergonomically handle parts for organized material transfer and consistent throughput.

End-of-Arm Tooling

One of the most complicated aspects of machine tending is how a robot grasps a part.

Whether it’s a pneumatic, magnetic, electric, or hydraulic gripper, the design of the end-of-arm tool (EOAT) is of the utmost importance, and special consideration should be given to the grasping point.

At this point, these questions need answered:

  • How fragile is the part?
  • Can the part surface be marred?
  • Is there an interference that the EOAT might impose when handling or loading the part?

To empower shops with the peripheral tools needed to adapt to changing production requirements quickly, robot suppliers and gripper manufacturers are partnering to provide off-the-shelf ecosystems for ISO-compliant gripper packages that often are easy to install and program. Typically used for collaborative applications, most of these plug-and-play options come standard with plastic fingers that are well-suited for low-weight, easy-to-pick parts.

While there are a lot of standard EOAT options, unique grippers with custom-machined aluminum or steel fingers that accommodate the weight and shape of the part to be tended may be required.

To save time and reduce costs, savvy manufacturers may benefit from 3D-printing gripper fingers in-house. For high-mix production environments, where one robot will be tending to multiple part sizes, it is often wise to invest in a tool changer, because it saves valuable time and resources.

Part Buffering Stations

Determining how a part will be presented to and disposed of by the robot (pre- and post-machining) is vital to the success of any machine-tending task. Depending on part size and dimensions, configurable trays, drawer systems, conveyors, and bins frequently are used.

If a robot needs to grab a raw part, localization is needed so that the part can be retrieved correctly. The trick here is to find balance between convenience and flexibility.

A dedicated drawer or racking system is a relatively simple option and is well-suited for use on the same type of part over long periods.

Regardless of the option chosen, to achieve the fastest ROI, it is important to position the robot at the optimal distance for part loading and unloading, as well as test how the part presenter works in conjunction with the gripper.

Vision Capability

To overcome costly bottlenecks for tasks such as loading/unloading, as well as for handling randomly presented parts, manufacturers have many pre-engineered 2D and 3D vision options for robot guidance. While one could assume that a more structured environment is better-suited for a 2D vision system and that a more chaotic, random environment is more ideal for a 3D vision system, determining the proper option for use really depends on product specifications and standards and environment, as well as the end result trying to be achieved.

Along with this, decision-makers may want to consider whether a camera should be mounted on the robot or off of the robot. While this usually is determined by the application, it is sometimes forced by the camera technology because some 3D vision systems require an off-the-robot camera and some 2D options can use either. It is important to note that off-the-robot cameras typically make cable management easier, provide a larger field of view, and facilitate parallel operations.

Again, to ensure they are choosing the proper robot and peripherals, manufacturers should have a thorough risk assessment performed by an experienced robot supplier or integrator. This will go a long way in answering system configuration questions, as well as adhering to ISO standards for the utmost safety.

Unlocking Greater Potential

Implementing robotic automation for machine tending can enable multi-shift operation, minimize manual product transfer damage, free human workers for higher-value-added tasks, and optimize product work flow in manufacturing facilities.

From greater precision and consistency to increased efficiency and quality, robots provide considerable benefits to labour-intensive tasks. Moreover, robust yet easy-to-program robots equipped with multi-function EOAT and other innovative peripherals are readily deployed and redeployed on demand, adding greater flexibility on the shop floor to meet increased customer demands for various materials in nearly every shape and size.

By: Dean Elkins

Via: https://www.canadianmetalworking.com/canadianmetalworking/article/automationsoftware/unlocking-robotics-potential

 

 

 

 

The Importance of Preventive Maintenance for Industrial Robots

Preventive-Maintenance-Robot

When an industrial robot is integrated into the production line, it is done to reduce unintended downtime in production and the probability of component failure or deterioration.

 Industrial Robots Maintenance has undergone a great evolution in recent times, appearing the concepts of Preventive and Predictive Maintenance. Let’s clarify these concepts!

Preventive Maintenance – Helps prevent equipment failure by systematically replacing deteriorating components and/or identifying and correcting problems before they lead to failure.

This process is carried out with the following steps:

  • Carry out a routine check of the electrical and mechanical condition.
  • System tests.
  • Shaft and ball joint lubrication.
  • Gearbox oil replacement.
  • Measurements and adjustments.
  • Replacement of arts.
  • Equipment deterioration record, backup

Predictive Maintenance: it is the condition monitoring solution (Condition Monitoring) that indicates the different levels of pressure, temperature, and humidity in the system. The process would include:

  • The proportion of real-time and historical data on asset and process trends.
  • It allows operators to detect and diagnose any problems that may turn into problems.
  • Provides analytics and alerts to operators when needed.

But applying this type of predictive maintenance solution to every asset in a facility is simply not profitable.

Being clear about these concepts can help us save time and money in maintenance.

If properly maintained, industrial robots can last for many years, even decades, before needing to be replaced. By maintaining a regular preventive maintenance schedule, you are extending the life of your robot exponentially.

The different leading brands in robotics recommend scheduling preventive maintenance every 12 months, others are based on their working hours. It is considered convenient to do it after 10,000 hours. It is important to check the manual of your robot to know when it is advisable to do it.

Planning this maintenance is the most appropriate since, having this programmed, the stop of its production will be minimal compared to the time we would lose in the event of an unexpected stop in production.

The FSD Robotics Maintenance Team provides maintenance programs that guarantee the best results and performance of your robots.

For more information about Robot Preventive & Predictive Maintenance, contact the FSD Robotics Service Team for all your robot services & repairs today!

Cobots: What are they and what are they for?

Cobots, What are they and what are they for?

There are still many people who wonder what a cobot is . Well, cobots are collaborative robots that serve to automate industrial processes , whether they are repetitive, manual processes or that endanger people.

Many companies are already betting on the use of collaborative robots in industrial processes. They provide precision and optimization to the processes, resulting in higher quality and productivity production chains.

They are the new generation of robots, which were born to work together with the operators, with the idea of ​​being able to adapt them to different work processes with great ease.

Hanwha HCR Cobot

These are completely safe robots for humans, since they are designed for this purpose, working side by side together with human personnel , they are even capable of interacting with them. However, the label of collaborative is not only given by security. It is also about ease of use, adaptability and accessibility. They can be programmed for different functions very easily, there is no need for special training or high qualification to be able to take charge of programming a cobot. They are provided with a very intuitive interface, with which any operator can move without any problem.

Cobots can carry out almost any type of work , thanks to the full range of collaborative accessories that can be provided. Normally they will be used to perform those tasks that are more repetitive and therefore heavier and monotonous to be performed by the operators. In addition, they can perform tasks that can pose a health risk, or those that require extreme temperatures or with sharp or toxic parts for humans.

Hanwha Robotics HCR Cobot

Their design is light and compact, so they can be easily adapted to any production center, working even in tight spaces.

Five immediate advantages of Hanwha HCR Cobots for your business

Hanwha HCR Cobot Advantages

Flexibility

The low weight of the cobots, will allow you to move them very easily to be able to integrate them into new processes. So you can automate any task within your company. Even if a quick change is required or when we talk about small batches.

Simple to configure

It is so easy to use, that even mounting an entire arm for the first time can be done without difficulty. Assembling the entire arm and programming it for a simple task will take less than an hour.

Programming

The cobot is provided with a 3d interface, with which any operator without any programming experience can quickly program the robotic arm. It is as simple as moving the arm to the desired points or touching the arrows on the touch screen tablet. The whole process is intuitive, fast and simple.

Security

You can incorporate cobots in your company without creating fenced spaces or security protections, after a risk assessment. They are equipped with a series of devices that make them safe for operators.

Amortization

If you think that automation is an expensive process and that it is not within the reach of anyone, perhaps it is time to rethink it. Cobots are amortized in a short period of time. It is because, thanks to its design, it is possible to do without other costs associated with automation, such as the large infrastructure of traditional robots, security fences, etc.

Cobots can automate virtually everything

Thanks to the flexibility of cobots and the wide range of accessories they have, we can say that cobots can automate almost any industrial process. They are economical even in the assembly of small batches, since it is a highly adaptable robotic arm. It can do: painting, labeling, screwing, packaging, molding, injection, polishing …

Hanwha HCR Applications

Packaging and palletizing

Let the cobot do the work and all shipments will always be properly packaged and taped.

Laboratory analysis

You can increase the degree of objectivity in tests and analyzes with the help of a cobot.

Injection molding

Cobots can be used in all polymer production tasks, with great precision.

Screwing

You will improve the quality and precision of the products, if the cobot is in charge of always making the same movement with the same degree of force and speed.

Gluing and welding

The cobot will bring high quality to the gluing and welding processes by injecting material, as well as perform welds with great precision.

Polishing

The cobots polish and sand even curved and irregular surfaces, with a constant and adjustable force to obtain a perfect result.

Mounting

Cobots can effortlessly assemble a wide variety of materials, such as wood, plastics and metals. Resulting in a perfect precision assembly. Improving the result of the entire process, increasing quality and speed.

Machinery supervision

Cobots can carry out machinery monitoring functions, easily adapting within the production line.

QA

Cobots are provided with a camera that can be used to review and identify faulty parts within a production chain. Increasing the quality of the product, and avoiding shipping and packaging.

Pick and Place

Cobots can take care of all the applications that are required in the pick and place. In this way, the cycles will be faster, increasing the quality and productivity in the process.

 

The Advantages of CNC Machine Tending with Hanwha HCR Collaborative Robots

CNC with Hanwha cobot

Machine tending is the procedure of loading and unloading components into a computer numerical control (CNC) machine. Usually, this process has been done manually by a human worker. Over time, machine tending has demonstrated to be tedious and potentially unsafe for workers. Therefore, manufacturers are having an increasingly challenging time finding employees willing to tend machines.

Manual machine tending procedures are slower, less precise and less consistent. Collaborative robots offer an encouraging solution for more efficient machine tending.

Why Utilize Hanwha HCR Collaborative Robots for CNC Machine Tending?

There are several reasons why a collaborative robot is exceptionally effective for CNC machine tending applications. Firstly, Hanwha HCR collaborative robots highlight fast deployment that diminishes integration expenses and allows for simple changeovers when a different job needs to be automated. Easy programming further improves the speed of implementation and reallocation.

Collaborative robots come at a much lower price point than industrial robots. This lower initial price allows companies to quickly accumulate return on investment to start noticing productivity advantages straight away.

The Advantages of Hanwha HCR Collaborative Robots in CNC Machine Tending Applications

The most direct and impressive advantage of using Hanwha HCR Cobots in CNC machine tending applications is their capability to build up productivity. For cutting, routing, grinding, or milling, Cobots function with considerably superior levels of uptime than human labourers, resulting in substantially greater output. When this element is considered alongside the vast cost savings created by collaborative robots, the result is superior productivity and efficiency.

In addition to greater efficiency, Cobots tend to generate greater levels of safety in operations. They permit human employees to concentrate on other more cognitive-oriented jobs that are safer and usually have strong characteristics to prevent damaging accidents. When contrasted to industrial robots that require security barriers and larger safety equipment, collaborative robots are small and take up very little room on the factory floor.

Collaborative robots are ideal for CNC machine tending applications. They’re safe, productive, and they allow human workers to focus on more value-added tasks in production. CNC machine tending, when done physically, can be inconsistent and a blockage in production. Collaborative robots help companies ramp up production for more competitiveness on a global level.