Everything You Need to Know About Robot-Flex® Robot Suit

Collaborative robots or cobots are shaping human and robot interactions in a better way. These collaborations have immensely benefitted industries and helped them increase their efficiency and productivity in applications that require precision, strength, or repetitive motions. The cobots are taking over monotonous and physically challenging works, and help free up human workers to focus on productive tasks. These robots can perform tasks accurately, safely, and quickly contributing to short lead times, increased output, and fast production cycles.

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Although designed to work in challenging environments, collaborative robots may not work as effectively as required. This may be due to damages caused to their arms or sensors in extreme work environments. This is where collaborative robot suits can help. This post explores how these   suits are helping manufacturing facilities optimize their robotic investments.

Why Your Cobot Needs a Robot Suit

There are several reasons why your cobot may need a robot suit. The following pointers will help you understand it better.

• A bare robot is often programmed and equipped with safety features and advanced sensors, which help avoid the chances of collision and allow build better working relationships with human beings. However, accidents may still occur when cobots and humans exist in the same bay. Robot full protective suits create an extra protective layer, preventing direct contact between the human operator and moving parts of the cobot. This further reduces the risk of injuries, such as bruises, pinches, and cuts.
• A bare cobot is used for production in many industries, such as food and beverage processing, pharmaceutical processing, etc. They are exposed to contamination like dust, debris, chemicals, and so on. Robot full protective suits help prevent the cobot from coming in contact with water, oil, debris, and other contaminants.
• A cobot makes a good investment for many businesses, including food serving organizations, where they are used for repetitive tasks such as serving customers; in car showrooms to welcome customers; in automotive manufacturing facilities near conveyor areas, and so on. Robot suits help prevent scratches, breakages, or spills that would otherwise damage their components in challenging environments.
• Although cobots are becoming popular in workplaces, many industries have already imposed strict regulations to avoid accidents or other unwanted events due to their collision with humans. The use of protective coverings is one such requirement, which is mandated by several regulations.

If you plan to invest in quality cobot suits, you can consider Robot-Flex® suits from Nabell. These protective cover suits are designed to protect your cobot against the environmental extremes and help avoid safety issues that may occur when the cobot and humans work closer. The next section offers insights on NRF Series Robot-Flex® suits developed by Nabell.

An Overview of Robot-Flex® Suits Developed by Nabell

Robot-Flex® suits are custom-fitted covers designed by Nabell to protect the cobot from challenging operating conditions. They are designed to fit over the robot’s servo motors and castings without hampering the robot’s working.

Types of Robot-Flex® Suits Developed by Nabell

Nabell offers the following types of Robot-Flex® Suits developed by combining traditional processing and 3D printing techniques.

• NRF-1: The NRF-1 suits offer excellent water and dust resistance, ensuring protection in various challenging work environments. They are designed for general-purpose use, with a thickness of 0.90 mm.
• NRF-2: The NRF-2 suits offer excellent impact resistance. Designed to safeguard the arms, these 0.70mm suits provide protection against abrasions, blasts, and chips.
• NRF-3: These NRF-3 suits possess a thickness of 0.59 mm and are generally recommended for use during chemical cleanings, misting, washdowns, and painting processes. They ensure excellent paint resistance.
• NRF-4: The NRF-4 suits ensure excellent oil and coolant resistance. These suits are made 1mm thick and can help protect the arms during machining operations.
• NRF-5: The NRF-5 suits are used to protect cobot arms during machining and welding processes. They protect the cobot from high heat and spatters.
• NRF-6: Primarily designed for food processing units and clean room applications, the NRF-6 suits have a thickness of 0.54 mm. They can resist contaminants and help maintain hygienic conditions in food and drug manufacturing facilities.

What types of chemicals can Robot-Flex® Suits withstand?

The Robot-Flex® Suits are designed to withstand the following types of chemicals.

• Top of Form
• Bottom of Form
• Nitric Acid (31%), Hydrochloric Acid (23%), Ammonia, Skydrol, Methyl Ethyl Carbonate
• Hydrogen Peroxide Water (Oxydol), Hypochlorous Acid Water, (Conc. 200ppm), Sodium Hypochlorite (Conc. 0.02%), Hypochlorous Acid Water (Conc. 400ppm), Sodium Hypochlorite (Conc. 0.1%)
• Half-life Period: 9.7 seconds (Warp: 670V, Weft: 740V)
• Hydrogen Peroxide(Oxydol): Positive
• Lacquer Thinner 100%:ISO Passed
• Hypochlorous Acid, (Conc. 200ppm), Sodium Hypochlorite (Conc. 0.02%): Slightly changed color on the material (White ⇒ Light yellow), No tearing
• Hypochlorous Acid (Conc. 400Ppm), Sodium Hypochlorite (Conc. 0.1%): Spray Test: Positive
• Hypochlorous Acid (Conc. 400Ppm), Sodium Hypochlorite (Conc. 0.1%): Immersion Test: Slightly changed color on the material (White ⇒ Light yellow), No tearing

How to Install Robot-Flex® Suits on Cobot?

Robot-Flex® Suits can be easily installed on Cobot. The pointers below will guide you on the right steps of installation.

• Choose custom protective cover suits for your application.
• Carefully remove any peripheral device before installing the cover to avoid the risks of damage.
• Ensure the robot is at rest and switch it off before installing the cover.
• Do not haste the installation and removal process of the cover. It must be performed carefully and slowly to avoid damaging robot parts or personal injuries.
• Ensure the Robot-Flex is not upside down. After the installation, inspect the gaps in the joined areas. Adjust the cover at joint attachments as necessary before starting the robot.
• Move the robot manually and operate it across all axis of rotation to ensure smooth movement.

How Robot-Flex® Suits Differ from Other Robot Suits in the Market?

The Robot-Flex® Suits differ from other robot suits in the market in many ways. The following pointers will help you understand it better.

• The suits are made of specialized materials, such as polyester+ rayon, polyester fiber, polyester, aramid, carbon-aramid fiber, and polyester. These materials have different characteristics and assure durability and reduced maintenance costs, which make them ideal for different challenging environments.
• These suits create excellent condensation barriers in challenging environments.
• The suits are designed for manufacturers, such as ANUC, MITSUBISHI, TECHMAN, DENSO, YASKAWA and UNIVERSAL ROBOT brand collaborative robots.
• The suits ensure improved hand mechanics sensor and gripper.
• They protect against water, shocks, heat, dust, oil, chemicals, etc.
• All Robot-Flex® Suits conform to REACH and RoHS.

If you wish to invest in Robot-Flex® Suits for your applications, you can contact the experts at Nabell USA Corporation. The experts at the company will work closely with you to understand your requirements and offer you the right solution. They can provide custom suits to meet your application requirements.

The ability of collaborative robots to share tasks with humans and flexibly adapt to new requirements can provide high returns on investment in a wide variety of industrial applications. Manufacturers employ these robots to reap the benefits of integrated safety features that allow them to work with or close by humans and boost productivity for a wide variety of repetitive tasks.

Despite the numerous safety features that include lightweight frames, collision detection technology, and minimized pinch points, appropriate safety measures must still be considered for the overall application — including the gripper, end effector, and other equipment located near the collaborative workspace. Safe implementation based on comprehensive risk assessments is crucial for ensuring the success of a collaborative robotic application.

This article discusses industry standards, project stages, and solutions for getting the greatest value from collaborative robots (commonly shortened to “cobots”). It also defines and discusses safety requirements for the robots themselves as well as the collaborative workspace and typical collaborative operations.

What are Cobots, and What Safety Standards Apply?

Collaborative robots are designed to work with human operators thanks to technologies like force feedback, low-inertia servomotors, elastic actuators, and collision detection technology that limit their power and force capabilities to levels suitable for contact. More compact than conventional robots, cobots generally have lightweight frames with soft, rounded edges and minimized pinch points (Figure 1).

Force and speed monitoring are the defining abilities of collaborative robots. When they are equipped with safety devices that detect when a person has entered the collaborative workspace, they are often allowed to operate at higher speeds. This helps them maximize throughput when people are not present within the hazard zone.

The safety standard ISO and technical specification RIA TS define the safety functions and performance of the collaborative robot. Under TS , the force and speed monitoring of the cobot is set based on application data, human contact area, and workspace hazards. Human contact is defined in two types: transient and quasi-static. The former refers to contact that is non-clamping, whereas the latter involves situations that can cause a body part to be clamped.

Application data, possible human contact, and workspace hazards all factor into the calculated safety settings based on TS . This may be a challenging task for manufacturers who are not familiar with safety standards, in which case they can hire a safety assessment provider to make the calculations and offer suggestions for improving the safety of the overall collaborative application.

Hand-Guided Teaching Safety Standards

ISO and ISO/TS provide standards and guidance for collaborative robot teaching functionality. Many cobots, such as Omron’s TM Series robot, employ intuitive hand-guiding mechanisms for teaching new tasks without the need to explicitly program the movements of the robotic arm. Hand-guiding mode monitors force and speed to ensure that the teaching process complies with safety standards.

Enabling hand guiding. Before an operator enters the robot’s workspace for teaching, the robot must be stopped even if its force and speed-limiting functionality is activated. Otherwise, a protective stop must be executed upon detection of the operator by a safety device like an area scanner.

Unlike with high-speed robots, the operator can activate the teaching mode using a simple trigger, button, or mode selection as long as safety force and speed monitoring are active. Otherwise, a three-position safety enable is required. Safety standards require the teaching mode transition to be deliberate, not lead to unexpected motion, and avoid creating additional hazards.

Ensuring safe teaching. Since the operator is responsible for the robot’s motion, he or she must be aware of surrounding equipment and safety concerns at all times (Figure 2). It is possible to enforce limits in motion, such as space and soft axis limits, to help keep the operator safe.

Enabling safe operation. The operator must first vacate the safeguarded space. This can be detected by safety sensors or additional operator verification. To re-enable the robot for operation, intentional mode selection must be provided.

What is a Collaborative Workspace?

Cobots perform automated tasks around other equipment that could potentially cause harm. The area in which a collaborative robot operates, including any tooling or additional equipment, is known as the collaborative workspace. As defined by ISO /ANSI RIA 15.06, this is the space within the safeguarded area where the robot and human can perform tasks simultaneously during production operations. Similarly, TS defines it as the area within the operating space where the robot system can perform tasks concurrently with a human operator during production.

It is important to list and map out all additional equipment in the complete collaborative automation project. Manufacturers should be sure to evaluate each device for potential hazards and safety sensors to use to prevent human and equipment damage. In addition, the collaborative workspace must be clearly marked.

The following are examples of noncollaborative safety-rated equipment that can be part of the workspace requiring safety devices:

• Material handling

• Tooling

• Grippers/actuators

• Machines

Safety devices are generally quite easy to integrate into a collaborative robotic application. Following are a few solutions for safeguarding the collaborative workspace.

Open area safety guarding solutions. Safety area scanners and mats are the most popular safeguarding for cobots. They are also some of the simplest items to integrate into applications with low hazards and few additional pieces of equipment.

Gated/limited area safety guarding solutions. Safety light curtains and safety switches are used for applications with hazards or high-speed operation enablement for increased productivity.

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Active hazards safety guarding solutions. When a hazard is present or operation could cause a hazard, operators can enable the “deadman” switch — a switch that automatically goes back to the “off” position if the user fails to exert pressure.

Maximizing safety in collaborative operations. It is essential for manufacturers to validate their cobot applications for safety across all operations. Every application is unique, but there are some guidelines manufacturers can follow when evaluating the safety of a robot while performing a given task in collaboration with a human operator. Drive and power hazards may still exist even if the robot is not moving.

Safe robot enable. Whether starting up the robot or recovering from an emergency stop, there must be an intentional act to enable the robot that ensures operators are safe and no hazards are present; for example, when an e-stop is activated by an operator, the robot should not perform an automatic re-enable. Instead, it should require input from a second operator verification action.

Safe hand guiding. During design and safety setup, manufacturers must ensure that hand-guiding can only occur after (1) the robot has stopped, (2) intentional mode selection has occurred, and (3) speed and force monitoring are active. If hand-guiding activation occurs without a stop command or safety input, this should initiate a safety stop and fault.

Safe operation. Enabling the automatic or run operation of the cobot must be an international mode selection by the operator that requires all safety devices and conditions to be validated for operation. Operators must be protected from hazards on the end-of-arm tooling before enabling operation.

Safety validation. It is important for manufacturers to have a safety assessment service group review all the surrounding areas and equipment and to have a safety remediation service performed if necessary. Safety service groups will perform an on-site inspection to assess the safety of equipment, confirm certifications, verify safety parameter settings, and document that safety validation has been completed.

Safety Considerations for Collaborative Machine Tending

Machine tending is the most common application for cobots due to the ease of installation, the high return on investment, and the benefits from the robots’ flexible manufacturing capabilities. Machine tending applications can be misleading in their appearance of safety; in fact, they are one of the industry’s top safety concerns for experts who have completed many inspections and safety assessments.

To maximize safety in automated machine tending applications, manufacturers must use a safety-rated gripper to safeguard against operator injury, and they should also investigate whether the product itself presents any dangers (such as extreme heat or sharp edges).

Other things to consider include:

• Do other machines need to be safety control-linked to prevent either from operating when the other is in a safety stop condition?

• Is material handling equipment being used? If so, what are the necessary safety considerations?

• Since cobots used in machine tending can be moved from machine to machine, how are the safety setting and program validated?

• Are there warning zones for the operator that will indicate hazards or operation interference?

It is also extremely important to review the entire area for any circumstances where an operator could be trapped or clamped by the robot and surrounding pieces of equipment.

Safety Considerations for Collaborative Material Handling

Material handling applications that benefit from the incorporation of cobots encompass picking, packing, palletizing, sorting, and more (Figure 3). The wide-ranging use of these applications makes them a more site-specific solution for safety implementation. Operators and other workers are often moving or transporting other materials around the cobot, requiring additional planning to avoid hazardous contact.

Safety-rated grippers are rare in the market at the present time. Currently, manufacturers typically use pneumatic grippers, which require safety considerations for impacts and the loss of power or suction.

Application designers must also investigate whether the product itself presents any damagers like being heavy or containing hazardous material — characteristics that could be especially problematic if the product were to be dropped.

Other things to consider include:

• Do other machines need to be safety control-linked to prevent either from operating when the other is in a safety stop condition?

• Since cobots can be moved from application to application, how could this affect validation of the safety settings and program?

• Are there warning zones for operator that will indicate hazards or operation interference?

As with automated machine tending applications, manufacturers must review the entire area for any circumstances where an operator can be trapped or clamped.

Safety Considerations for Collaborative Assembly

Assembly applications employing cobots often involve special tooling and close collaboration with operators while also requiring high-speed operation zones to be present. The extensive variety of custom end-of-arm tooling makes these applications especially complex (Figure 4). If multiple robots are involved, application designers must coordinate the safety solutions for each one.

As with material handling applications, it is important to consider safety requirements for pneumatic grippers, places were an operator could be trapped or clamped, and any products that are heavy or that contain hazardous substances.

Other things to consider include:

• Do other machines need to be safety control-linked to prevent either from operating when the other is in a safety stop condition?

• Since cobots can be moved from application to application, how could this affect validation of the safety settings and program?

• Are there warning zones for operator that will indicate hazards or operation interference?

Summary

Designed with a human collaborator in mind, cobots are generally considered to be safe; however, they still require risk assessments to guarantee safety of human operators throughout their use. It is crucial for manufacturers to consider all the possible hazards associated with hand-guided teaching, including transient and quasi-static contact, as well as what may happen when the robot is involved in an emergency stop.

Designers of automated machine tooling, material handling, and assembly applications must consider all the ways in which the robot would interact with an operator, what aspects of the surroundings might cause clamping or entrapment, and what characteristics of the end-of-arm tooling might pose a risk due to high heat, sharp edges, or other hazards.

If a risk assessment is performed thoroughly and requisite safety measures are implemented, it will ensure the successful efficiency gains of an application and boost performance.

This article was written by Tina Hull, TUV Functional Safety Expert and Product Engineer, and Darrell Paul, Market Manager of Robotics and Motion, at Omron Automation Americas, Hoffman Estates, IL. For more information, visit here  .

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