STOBER Drives – Motion Control – Page 1 Take your manufacturing process to the next level with STOBER Drives ServoFit motion control applications. We offer a wide array of motion control solutions to meet your servo needs, including inline and offset, hollow and right angle, food and beverage and integrated brake and cooling systems. Innovation and use of high-quality components allows us to manufacture highly efficient and high performance motion control devices that produce low noise, which helps improve productivity while reducing operating costs. Our gearboxes offer up to 97 percent efficiency, which can curb energy costs and surpass our nearest competitors’ best efforts of between 70 and 85 percent efficiency. ServoFit Precision Planetary …show more content…
Our orthocyclically-wound motor coil makes it possible to manufacture the stator windings with the highest possible copper fill factor, allowing for a shortened motor length while increasing power output by up to 80 …show more content…
STOBER Drives’ family of servo motors mount directly to gearboxes, eliminating a motor coupling, adapter, coupling housing or additional input seals and bearings. Direct mounting also reduces inertia by up to 75 percent. We offer both high and low servo motors to fit unique applications. For applications in need of more power, water or forced air-cooling will offer up to a 35 percent torque increase through heat dissipation. Keep cords and cables in one place with our Hollow Servo Motor, which is designed with a flange-mount hollow bore. It allows for media – power cables, pipes and hoses – to pass through the motor. The motor produces powerful torque and high stiffness with a low total weight, making it well suited for applications where the motor is also moving. It is ideal for industrial robots, machinery, machine tools, automatic assembly machines, converting and printing, handling equipment, and laser machine
The new era of virtual to real manufacturing is under way which will increase productivity, efficiency and innovation, speed-to-market, and flexibility, resulting in a powerful new cycle of growth and value creation. The advanced manufacturing facilities of today and tomorrow are clean and replete with robots, computers, lasers, and other ultramodern machine technologies for example the most common tools carried on the new auto plants are not wrench or screwdriver instead it’s IPad (Ludwig & Spiegel,
Detroit asserts that the Cadillac engine system is responsible for cost reduction especially with regard to the Cadillac maintenance (73). This owes to the fact that the flexible logistics of installation and low consumption of fuel guarantee savings. This vehicle’s engine is efficient due to the fact that it is safe to drive at high and low speeds. The brake system of this vehicle does not require electromagnetic fields in order to function. The model in question is also fitted with emergency tools, which help in case of skidding. These tools include the braking cruise control. Cadillac’s brake system is light unlike other vehicles’ brake systems, and this enhances swiftness in driving the Cadillac. Additionally, this model does not have the shortcoming of fuel loss especially through drags. The Cadillac has Eigen solver system, which is responsible for squeal analysis. In this regard, the need for programming is eliminated. The thermoregulation ensures that the braking system’s heat is controlled. Furthermore, the thermoregulation amplifies the computation performance of squeal. The engine...
Investigating the Efficiency of Different Pulley Setups. Aim In this experiment I will be investigating the efficiency of five different pulley setups. These are the results shown below. Background on pulleys A pulley is one of the simplest mechanical powers or machines consisting of a grooved wheel/roller(s) for a cord or string to pass over a mounted block this is used for lifting a mass or changing direction of power.
“How about we use a pulley system with a weight at the end to push the car forward?” my team member suggested. “Or we could use a hammer launcher,” I proposed. We went back and forth, contemplating different methods. We faced trials, tribulations, and troubles in the design process. Building and perfecting our designs took weeks, but our coach guided us throughout the process and encouraged us to “Never give up!” We researched the effects of different factors that could potentially come in the way of our success and analyzed all of the device possibilities. Even when research got arduous and we couldn’t agree on something, we never gave up on our dream of placing in the regional competition. This was one of the hardest challenges I’ve ever faced in my Science Olympiad career, but our unfaltering dedication and our belief in success helped us persist in the face of setbacks. Once we finished our plan, we began to build the device. It was exhilarating to see our plan come to
Scherbius’s first model was big, bulky, and had a keyboard from a typewriter to input code. Four geared wheels drove four rotors. The four wheels drove one rotor ea...
In a DC motor, the armature consists of any number of windings, each one an electromagnet. The armature is immersed in a directional external magnetic field. This external field does not move, and can come from permanent magnets or electromagnets.
In order to highlight Segway's situation, we have broken down their value chain into two simple classes. Firstly we will focus on "what is working" and secondly on "what is not working" for Segway.
Energy efficient motors use more copper and iron than regular motors. They also consume less energy than regular motors.
Even Steve Jobs predicted that cities would be built around it. So, what went wrong with that? In this essay, the reasons why Segway didn’t do a better job in anticipating the issues that will face the project will be explored. Being a technological piece of art and mechanically robust, sales expectations were high. Segway was predicted to be the fastest company in the open era to hit $ 1 billion dollars in sales and they were so optimistic they erected a 77,000 square feet factory that can produce around 48,000 units per annum with an average price of $ 5000.
Each of the six basic styles of robot used in industry today were designed with different applications in mind. Some of the robots were designed for assembly, others are more suited for simple pick and place applications, while a select few are capable of carrying heavy loads over a large area.
Electric motors are the most common device for converting electrical energy into mechanical power. According to the laws of physics "whenever a current carrying conductor is placed in a magnetic field, it experiences a mechanical force"[1]. The Armature which is simply a coil of wires is places between two magnets. When the current is supplied through the armature an electromagnetic force is induced on it according to the Lorentz law so the coil will start to rotate. As the armature is connected to the commutator rings which is connected to power supply of opposite polarity. This guarantees that the rotation action is always in the same direction throughout the motion of the armature, so the coil will continue on rotating. This rotation is
delivering power instantly to the wheels. By providing high torque at low speeds, they give a feel
Actuators used in robotics is almost always a combination of different electro-mechanical devices. Sometimes robots use hydraulics, particularly in the car building industry. The electro-mechanical devices range from `muscle-wires' to inexpensive RC-servo and motors. There are several types of motors available including:
This is a unique function which automatically adjusts the power required by the motors during the action of the robot.