There are more than 85,000 DENSO robots installed across the globe. And we stand by our products, employing more than 17,000 DENSO robots in our own manufacturing plants.
DENSO Robotics is the clear first choice for high-performance, robust, and cost-effective robotic solutions.
DENSO robots are environmentally friendly and extremely efficient. Our robots have been designed to achieve low energy consumption. Furthermore, they come with standard electric plugs for use with 230V power outlets. Rely on our products and systems to help you realize the full potential of your business in an eco-friendly manner.Compact, light, and requiring only minimal periodic maintenance, our entire robot range is the first in the industry to come with a standard two-year guarantee. To maximize efficiency and ease-of-use, there is only one type of controller for all of our robots. DENSO robots have also been designed to operate in virtually any setting, including dusty, wet, or clinical environments.
*Expected release time: Spring 2017
The New VS 050S2 Series features a hygienic and easy-to-clean design, making it particularly suitable for cleanrooms.
Robot for use in sterile environments and clean environments that employ H2O2 gas 35% density (dry / wet) and UV exposure.
Smooth surface prevents adherence of dust and dirt.
Cables and other connector panels are positioned on the bottom for compatible installation in sealed and quarantine environments
Software for programming DENSO Robotics(PacScript,PAC) and creating simulations on the PC.
WINCAPS III is a software application that supports all processes from consideration of introduction to maintenance of DENSO robots. With its abundant functions, it helps users with operation of DENSO robots, such as robot programming, controller data backup and robot posture checking on a 3D screen.
ORiN2 SDK is a middleware application for developing application programs and providers based on ORiN2 specifications.
ORiN ® 2 SDK is a software tool kit used to develop an application program or provider based on ORiN2 specifi cation.
Robot Tools is a software application for helping streamline maintenance work and the operations of DENSO robots.
Robot Tools is a fully featured suite of utility tools created for optimum maintenance and operation of DENSO Robotics.
The software streamlines daily maintenance workflow and reduces the running costs of a robot after installation.
RC Vision is a robot vision application software package that utilizes DENSO Robotics and cameras to support equipment startup.
EVP Easy Vision Picking
EVP (Easy Vision Picking) is an image processing application that specializes in Pick & Place without using a program.
Image processing settings are configured using an application (EVP Guidance) on the PC. When executing (EVP Runtime) can be run by RC8 and the camera connected to RC8 only.EVP also includes a calibration wizard that can perform robot calibration and calibration between camera and robot.The picking device has built-in functionality to output the location of parts that are within the field of vision of the robot, allowing control of parts movement via a feeder or other device.
Software that enables simulation of multiple DENSO Robotics.
VRC is an emulator that provides a virtual environment for the RC8 on a PC by imaging the RC8 (robot controller) itself.
As an RC8 (robot controller) virtual robot module, VRC provides an RC8 virtual environment on the PC.
Allows operating, teaching and simple maintenance of the robot (not able to create & edit programs)
Modern control sensors are essential for today’s automobiles. Supporting safety control features in automobiles, these sensors have an important function. In many cases, their manufacturing has only been made possible with the introduction of automated production systems. Due to the required, highly precise installation of sensors in miniature spaces, a manual assembly is impossible. Their assembly is carried out in an (half) automated wave soldering process of fixating the sensor to a sensor carrier.
The challenge: Despite a pre-set solder wave height, deviations of this value are an unavoidable technical issue that has to be compensated for individually, depending on the varying degrees of deviation. Thus the sensor carrier has to be passed over the wave solder flexibly in order to adjust to the deviation.
The sensors are installed in sensor carriers by using a wave soldering process in an automated production system developed by Erwin Quarder Systemtechnik GmbH & Co. KG for an automotive industry supplier. Quarder is a specialist for automated solutions based on injection molding technology. Relying on innovative engineering know-how and computer science, the company is developing tailor-made production systems. In providing a high level of functionality, quality, safety and usability, these are meeting the requirements of today’s industry.
The automated production line features 12 modules – from the production of the plastic sensor carriers in an injection molding machine, their subsequent transfer onto the assembly line, to the removal and insertion of sensors, the preparation with a fluxing agent and the soldering of the sensors to the sensor carriers and finally to the quality check as well as their palletizing into trays.
For automotive suppliers, quality management is one of the key factors determining a company’s technical and economic success. In this industry, for both quality and safety reasons, the high-precision installation and fitting of a large number of very different, pre-fabricated components into a specific mechanical setting are particularly important.
In the past, manual quality checks have been too costly and time-consuming, as well as being relatively unsafe, given the likelihood of human error. In addition, today’s extensive variety of models and components would present a real challenge to any employee. And fitting delicate components into relatively inaccessible areas is almost impossible without the adequate tools.
Automotive suppliers are therefore relying increasingly on fully automated, robot-based test cells, where components are quality-checked and then correctly assembled using image processing and software to ensure precise integration and functionality.
Such a test cell has been developed by Handke Industrial Solution GmbH (HIS GmbH) for a client in the automotive supply industry. HIS GmbH, based in Garbsen near Hannover in Northern Germany, has been distributing und manufacturing products and software for the automation and electronics markets since 1979.
The test cell has been in operation since late 2016. It inspects the correct assembly of parking heaters (each component measuring up to 60x60x60 mm) for vehicles and trucks. While the actual base component is always quite similar, its mechanical fittings, i.e. the mounting, the waste gas extraction and the vacuum exhaust, vary widely, depending on the vehicle model. In total, the test call has to master 250 different versions. It currently manages a total of 1,500 components each day (in a three-shift cycle).
The assembled component carriers are transported automatically into the 3x3 m test cell where they are inspected by cameras mounted on two VS-087 DENSO robots. ...
To develop a very compact and flexible Workstation for In-line Automatic Measuring with the latest Manufacturing Equipment Capabilities. A new programmed Dimensional Measuring Machine capable to compare a large variety of components to be measured based on comparison between the item to be measured and its Master Sample that are normally used in the control of Headlamps for the Automotive Lighting Industry.
Against this background the DM Series emerged, based on the new revolutionary DENSO robot VS087 – that could be described as a type of Automated Lighting Inspection System Workstation, which is connected to the Manufacturer In-line Systems.
The Dimensional Measuring Machine robot receives its order data to carry out the measurements brilliantly assisted by DENSO robot VS087 according to its principle based on comparison through the Master Sample with the target measuring points located according to the Lamp’s CAD and the results obtained are then compared with the calibration values previously configured by the manufacturer ensuring all the times its precise performance and estimated manufacturer working cycles. DENSO robot VS087 gives to the DM401 a great speed and precision when calculates the points to be measured.
Great attention has been paid to the dimensions of the equipment to accomplish the World Class Manufacturing requirements where the DENSO Robot VS087 fits perfectly helping to minimize as much as possible the floor space usage when designing the DM401 Serie
Traditionally, the automotive supplier industry has been one of the most important branches for using compact robots, which are being employed in the manufacturing of various components. One of the companies in this area relying on DENSO robots is Renger Kunststoffspritzteile GmbH & CO. KG in Inzigkofen north of the Lake Constance in the Southwest of Germany. The company primarily manufactures plastic components in injection-moulding technology for the automotive industry. In this case study, we are looking at their production of cases for airbag control units, undoubtedly one of the most safety-related components in cars.
The challenge: In the past, the company had assembled the components by relying on traditional linear systems, quality control was carried out by employees. With the introduction of DENSO robots, however, the cycle time could be reduced significantly while also realising a zero defect figure. It is this 100-percent quality that really matters when it comes to delivering these crucial car components.
Thus the manufacturer had to develop a robot-based system, which would combine a fast pick-and-place performance with an outstanding quality control.
Renger has been working with DENSO robots since 2009 as the company appreciated the robots’ flexibility and the possibility of combining various tasks even later in the process. In light of growing quality and cost requirements of plastic components demanded by the car industry, these were two decisive advantages.
DENSO robots convinced the company also with their high speed, simple handling and the programming approach. Renger is using the VS-6577 and the VM-60B1G (among others), which were selected due to their arm length and payload capacity. Until then, Renger had only worked with linear robots, which offer only a fraction of operation capabilities a six-axis robot can cover.
At Renger, DENSO robots are primarily used in the manufacturing and quality control of cases for airbag control units; these manufacturing system are quite complex, as they are fully integrated with an injection moulding machine and a PLC system.
The future of an optimized industrial automation lies in efficient, safe and reliable Industry 4.0/IoT applications. The key to any successful Industry 4.0/IoT solution in so-called smart factories is a simple, fast and highly user-friendly interaction between all parts of the system: Users have to be able to monitor and control processes at any time, from anywhere and with as many different devices as they wish. Central tools for facilitating these applications are cloud services functioning as a platform for the actual automation application and the user control. But how can robot-assisted industrial automation, cloud services and user friendliness be integrated into one system today – relying on already existing software and technologies, thus making automation even more efficient?.
A solution was presented at Microsoft’s.Net conference in Madrid (Spain) in 2016 through a cutting-edge project called "DENIoT". The project aimed at showing how Industrial IoT applications can be made more efficient and safer by using already existing software and technologies. “DENIoT” was coordinated by DeROBÓTICA, the Iberian sales organization for DENSO Robotics, and supported by ENTRESISTEMAS, an industrial automation and system integrator specialist, as well as ENCAMINA, a Spanish consultancy company specialized in Microsoft products.
The central elements of the solution were the software development interface ORiN (Open Resource interface for the Network), which is part of DENSO’s robot controller RC8, a DENSO VS-060 6-axis robot and the cloud platform Azure by Microsoft. Azure is a collection of integrated cloud services, such as analytics, computing, database, mobile, networking, storage and Website. ORiN is a powerful tool that enables the interaction with DENSO robots using high-level programming languages such as C#, C++, VB, etc. This unique capability of programming permits a very easy integration of the software platforms with the DENSO robot and with Microsoft’s Azure.
The cloud platform was connected to the DENSO robot controller in order to collect and interpret data using big data analytics and other techniques. These data were turned into actionable information. In the actual demonstration, the VS-060 had been programmed to perform up to 9 different movements, mostly pick-and-place. By monitoring and analyzing the robot data, it is not only possible to interact with and control the robot from virtually anywhere, but it also facilitates machine learning, which further enhances efficiency and performance. The data monitored included parameters such as the robot arm's speed, acceleration, positions and (joint) angles.
During the “DENIoT” demonstration, the robot was also controlled via Microsoft's intelligent voice command system Cortana: Basically, it translates verbal commands into robot movements (through the cloud). In the demonstration, each of the nine movement commands was assigned a number. The command "move", for example was assigned the figure "10", which was sent to the robot in order to perform this specific movement. Voice command interaction will become more important as the human-robot-collaboration will be increasing in the future.
For the release of its highly successful blockbuster string of “Avengers” movies, the production company Marvel Studios needed futuristic-looking robots for one of the movie’s key scene showing a dramatic turn of events in the movie plot. “Avengers: Age of Ultron” is the epic follow-up to the biggest super hero movie of all time. When Tony Stark tries to jumpstart a dormant peacekeeping program, things go awry and the “Avengers” are put to the ultimate test as the fate of the planet hangs in the balance. As the villainous Ultron, an artificial intelligence, emerges, it is up to the “Avengers” to stop him from enacting his terrible plans. .
DENSO Robotics provided three robots, two VS 050 and one VS 087, for the dramatic, turning-point scene set in a futuristic medical lab meant to be in Seoul of movie character Dr. Helen Cho (played by Claudia Kim), a geneticist helping the Avengers. “For this scene, we were not looking for industrial robots that would have fitted Stark’s lab, but rather for medical ones”, explains movie set designer Richard Roberts, one of the world’s leading sci-fi and fantasy set designers. “After some research we found images of DENSO robots, which had the right, white color and the high-tech design we were looking for. We wanted to show the cutting-edge technology in Dr. Cho’s lab – and the robots reflect that image. The DENSO robots definitely had the best look suiting the existing set design.”
The robots were lent to the production by DENSO Robotics, a DENSO service representative was on site programming the robots in PacScript to perform regular pick-and-place functions with several position variables, which were easily obtained by using the functions within the controller.
The actual filming of the scene took place over three days last year at the Shepperton studios near London.
Airbus studies and tests the flow behaviour and the flight capability of diverse airplane types- especially wings and engines- that are essential components for the development and manufacturing of new aircraft types. The Airbus Low Speed Wind Tunnel (LSWT Bremen) has been designed to analyse the performance of aircrafts during take-off and landing. It also studies factors such as pressure, stress and temperature at speeds of up to 85 m/s. Multi-hole pressure probes play a decisive role in this process because they are efficient and reliable tools to precisely measure flow conditions. As expected, all probes used for this purpose have to be calibrated accurately.
Probes are checked with the support of a DENSO VM-60B1G-V robot either before or after every test or during a flight simulation.
“Contrary to most robotic applications, in this case, the most important is not speed but absolute accuracy”, explains Airbus’ project manager. “In this way, it is easy to decide whether or not a new calibration is necessary or whether additional tests can be performed.” In order to decide this, the probes are exposed to a flow field with known speed and direction. The robots carry out the movements of the probes within the measuring grid and the results obtained are then compared with the calibration values.
“The simplicity to operate the robots and the free choice to communicate with them using our own software is a great advantage.” says the responsible engineer at Aerodynamics Testing at Airbus. “Additionally, with its six axes, the robot is extremely flexible when operating in a three-dimensional grid with 1,000 measuring points. You have the opportunity to control the robot in such way that it is possible to check the same measuring point for one minute.” Previously, inflexible rotating discs inconveniently carried out these tasks.
In one of the few industries where automation seems to have leveled out, a breakthrough application has now successfully demonstrated how robots can perform even the most challenging food handling usually done manually by human operators.
At SINTEF, Scandinavia’s biggest independent research center, engineers developed the “Gribbot”, a specially designed system using a DENSO VS 087 robot for processing chicken breasts.
“This part of the chicken is the most costly one, so meat producers are naturally concerned about the yield", explains SINTEF’s research leader for the Gribbot, Dr. Ekrem Misimi. "However, automating this process, as any procedure that relies on human hand-based operations, is very challenging. With the Gribbot, we wanted to show to manufacturers and food retailers that this kind of automation is possible today.”
The Gribbot is based on the center’s experiences with several robot-based projects such as RoboTrim project, also using a DENSO VS 087, which was used to trim objects in a salmon fillet. This experience with the DENSO V087, primarily because of its flexibility and the ease of use, has opened up a sea of opportunities in robot-based automation in the food industry for handling and processing operations.
The main goal but biggest challenge was to generate a satisfactory yield comparable to that of human operators - not an easy task, given the slippery surface, soft texture and the high variation of the chicken breasts as such. “We had to implement the scraping of the fillet from the carcass along the rib cage so that a minimal amount of rest meat was left on the carcass. This was an even bigger challenge for the entire system - from the detection of the gripping point with machine vision as well as creating an optimal path movement for the robot arm”, says Dr. Misimi. The biggest challenge, however, consisted in the development of the gripper. The chicken fillet had to be handled with care so that it would not be teared off or squeezed too hard.
The processing of fish and meat is subject to strict regulations: The production process has to be completely hygienic. It must be possible to track the origin of every product. Fish and meat have to have a consistent quality.
The research company SINTEF from the Norwegian city of Trondheim is currently working to automate and optimize the way these foods are processed. For the processing, SINTEF uses the highly efficient six-axis robot of the model VS-087 produced by DENSO Robotics. With over 2200 employees SINTEF is one of Norway’s biggest research facilities.
"Our robot fillets the fish and operates the cutting blades”, Lars Wirenfeldt, Sales Manager of DENSO Robotics in Scandinavia, explains. The fish is measured with the help of sensors, so it can then be analyzed at which exact points the blade has to cut around the skin and the bones. Another advantage for the consumer is that unwanted bloody spots can be identified by the sensors and can be removed by the robot. The use of robots ensures that the weight and shape of the filets is close to identical when they go into sale. The process is also intended for portioning chicken breasts.
Demanding work environment
“The biggest challenge when processing fish and meat is that all pieces are different but are still supposed to look identical when they go into sale”, Harry Westavik, Research Manager for automation and product efficiency at SINTEF, says. But the processing of fish and meat is a difficult field to operate in. Westavik: “The work environment is cold and yet very wet, which is corrosive to all objects made of metal. DENSO robots are very robust and operate extremely fast. This is why we have chosen one.”
Folding napkins is one of the most labor consuming processes in the gastronomy and hotel industries. Each year, around 400,000 napkins are folded in larger hotels. It was witnessed that it takes about 30 seconds to fold a napkin but the 3,333 hours of folding can quickly become monotonous and demotivating for the worker. In addition to this, in food courts, napkins fall under special hygienic requirements as they come into contact with the mouth.
Designing and developing a cost-effective, efficient and hygienic automatized system could replace this monotonous manual task.
The company ROFOBOX (RobotFoldingBox) together with partners developed a fully automatized machine that uses, combined with other devices, DENSO robots for the handling, folding and palletizing of napkins.
The DENSO technology that is being utilised by the ROFOBOX is the best robotics technology available on the market. “The robots are compact, fast, relatively light and have a long arm reach. In addition, the small floor area required for the robot allows for easy installation- whether it is on the ground, or mounted on the ceiling. The VS087 DENSO robots that we use have an attractive design and their white color portrays the purity of their design. These are precisely the skills we need for our innovative napkin machine,” says Kartal Can. CEO of Rofobox.
Stem cell research is one of the most innovative areas in current medical research and plays a decisive part in developing new agents and drugs. Research is thereby based on cultivated stem cells, in particular mesenchymal stem cells, or MSCs. These are mature stem cells extracted from adult human tissue, which means that isolation (unlike embryonic stem cells) can be done in an ethically acceptable way. Due to their capability to differentiate into new cell types, stimulate cell growth and influence the human immune system, they hold much promise for regenerative cell therapy.
The expansion of these cells, however, is a long and labor-intensive process. What is more, researchers have to deal with variations in the biological material that originates from many different donors. This variability is further increased by deviations in the cell treatment in manually produced cultures. At the same time, human interaction raises the risk of error and limits reproducibility. Additionally, as cell cultures are living organisms, a cleanroom environment is essential, which requires special standards for instruments and devices.
The solution is the development of a fully automated, self-contained yet flexible system for cultivating stem cells. StemCellDiscovery is a globally leading pilot project launched by the Fraunhofer Institute for Production Technology (IPT) in Aachen, Germany. The Aachen facility aims at growing and researching MSCs, and implementing various lab processes – from cultivating cells to generating experimental data. The facility features the easy integration of devices; consistent and accurate reproducibility; an individual, modular-based control of processes; high-quality cell products; and the use of advanced measuring technology for quality assurance and analysis.
A DENSO robot plays a central role in the facility. The robot, a VS-087 model, serves as a flexible handling unit for all transportation steps in the platform: transporting cell cultures in multititer plates, moving falcon tubes between different processing and measuring devices, and ensuring highly accurate positioning. Precision is particularly important at the microscope, where the robot first grips the cell culture container and then positions it in the designated holder. The robot’s flexibility also is useful for pre-positioning resources, such as transporting pipette tips from the storage to the liquid handling unit.
In addition, the robot provides the service for shaking the cell cultures with the same speed and movement in order to distribute the cells equally. This is key, as an inconsistent movement could result in cells accumulating at the edge of the container, leading to suboptimal conditions for cell growth. To achieve a consistent distribution of cells in the container, it is important that the robot applies constant acceleration to the cultures...
To develop a very compact and flexible system able to manipulate a large variety of objects (i.e.: drug vials, syringes, and IV bags of different shapes and dimensions) that are normally used in the manual process of drugs compounding.
Against this background the i.v. Station emerged, based on a DENSO robot – that could be described as a type of automated medicine distribution system, which is connected to the hospital prescription system. The appliance receives its order data from the prescriptions for the treatment specific to the patient. This information includes the medicine preparations that have to be made available in a selected time period and in a special form. At the point in time that a new bottle, a new syringe or a new bag is introduced almost nothing on the machine's hardware has to be changed. It is enough to readjust the software or the modalities to handle and administer the object. Among others the i.v. Station allows the preparation of medicines such as antibiotics, painkillers and anti-inflammatories for inpatient treatments.
A DENSO 6-axis robot of the VP-G2 series takes the syringe and positions it on a mechanical dosing feeder.
Then it takes the top off the syringe and takes the bottle that has to be filled with the medicine out of the repository, which had previously checked by an image processing system.
After the needle has drawn off the desired quantity the robot lifts the syringe into the weighing system.
A gravimetric check is carried out there that makes it possible to make an independent check of the dosage. During these procedures the machine is continually provided with a constant air flow that guarantees sterility in the interior. This system guarantees that the air is completely exchanged practically every two seconds.
Before discharging, the syringe is provided with a protective cap so that the contents do not come into contact with the outside air. Then it is labelled by the labelling machine, which provides information about the medicine preparation and a barcode for identification purposes.
To avoid errors when filling materials the i.v. Station has two image processing systems with medium resolution cameras (three megapixels). These check if the bags and syringes have been correctly positioned and they also scan the bottle labels that appear to prevent the operator from accidentally confusing the medicines during the filling phase. This is supplemented by a control phase – which takes place during filling - that is done by a barcode reader placed on the front panel of the machine. The final check is done by the computer monitoring system, but through the barcode reader the machine already knows what to expect.
Great attention has been paid to the dimensions of the equipment, because there is normally little space in hospitals. “Large equipment,” emphasises Giribona, “means nothing less than sacrificing part of the market, because many hospital do not have enough space to install it. It is for precisely this reason that we drafted the i.v. Station to be the size of a large fridge, a cuboid one metre by two metres high that can be easily set up." The compact design of the DENSO robot met this aim.
To be able to guarantee an appropriate safety level in terms of functionality and operator access the i.v. Station is equipped with certain capabilities. For example, it guarantees that access by unauthorised people is prevented during working procedures. These measures extend from profiling the user using user names and passwords, reader modules to identify RFID badges, up to biometric recognition.
The manual retrieval of medications is a time-consuming task, requiring millions of man hours in hospitals and pharmacies each year. In Germany alone, pharmacies sell some 1.3 billion medication packages annually, or roughly 68,000 packages per pharmacy.* Yet medication retrieval is also an error-prone process, for error rates as high as 15% have been reported by some studies. This is a pressing problem, because errors in filling prescriptions can endanger patient health.
To address these issues, the Finnish company NewIcon has developed automated, robot-assisted systems that make medication storage and retrieval safer, faster, and more efficient. DENSO robots lie at the heart of the solution.
Previously, NewIcon employed linear robots in its medication retrieval systems. Since 2010, however, the company has been using DENSO robots, which offer more axes for faster storage and retrieval as well as light-weight components in a compact housing. NewIcon also opted for DENSO because DENSO´s open architecture could be flexibly integrated with its existing software and machine vision system.
NewIcon offers two interlocking systems: a storage system for sorting and registering medications, and an input system for retrieving and delivering medications that have been stored. The DENSO VP-6242G is used in most applications, although the VS-068A2 is also employed when there is a need for faster speed and longer reach. The robots are controlled through an Ethercat bus connection. Robot programming is carried out in Visual Basic and C# using WINCAPS, DENSO´s offline programming, monitoring, and simulation software.
The information for picking and delivering a package can be manually entered by staff on a PC or communicated by scanning a barcode. In both cases, the control system directs the robot to grab the appropriate package and drop it into a container, which is then forwarded to a collection tray. When sorting packages, the robot performs scanning autonomously, without human interaction.
The robot arm is equipped with vacuum pumps and special suction cups to ensure reliable grip. The PC software knows the dimensions of all packages, enabling it to specify exact coordinates for robot pick-up.