G05B2219/39065

Isolating robotic actuators from food and beverage preparation

Provided is a device, comprising: a barrier configured to impeded or prevent particles shed by a robot in a first volume of space from entering a second volume of space in which the robot manipulates a workpiece; and a robot having three or more degrees of freedom, the robot comprising: a first portion disposed on a first side of the barrier in the first volume, the first portion comprising an actuator of the robot, the actuator being configured to drive movement of the robot to manipulate the workpiece; and a second portion disposed on a second side of the barrier in the second volume, the second portion comprising an end-effector of the robot by which the robot makes contact with the workpiece.

Reducing cost and size of food and beverage preparation robots

Provided is an alimentary-product assembling and dispensing device comprising: a plurality of alimentary-ingredient dispensers positioned to dispense respective ingredients in a plurality of different locations of a robotic work environment; a robot configured to receive an open-top vessel from an open-top-vessel dispenser and move the open-top vessel to the different locations to receive different ingredients from the plurality of alimentary-ingredient dispensers, wherein the robot comprises four or fewer degrees of freedom; and a vending aperture through which consumers retrieve vended alimentary products assembled by the robot from ingredients dispensed from the plurality of alimentary-ingredient dispensers.

ISOLATING ROBOTIC ACTUATORS FROM FOOD AND BEVERAGE PREPARATION

Provided is a device, comprising: a barrier configured to impeded or prevent particles shed by a robot in a first volume of space from entering a second volume of space in which the robot manipulates a workpiece; and a robot having three or more degrees of freedom, the robot comprising: a first portion disposed on a first side of the barrier in the first volume, the first portion comprising an actuator of the robot, the actuator being configured to drive movement of the robot to manipulate the workpiece; and a second portion disposed on a second side of the barrier in the second volume, the second portion comprising an end-effector of the robot by which the robot makes contact with the workpiece.

Increasing throughput of food and beverage preparation robots with concurrent transport of workpieces along multiple axes

Provided is a process, including: engaging, with a first subset of end effectors of a robot, a first open-top vessel; engaging, while the first subset of end effectors are engaged with the first open-top vessel, with a second subset of end effectors of the robot, a second open-top vessel; concurrently transporting the first open-top vessel and the second open-top vessel with two or more actuators; disengaging the first open-top vessel at a first workstation of the robot, the first workstation being configured to dispense a first alimentary product into the first open-top vessel; and disengaging the second open-top vessel at a second workstation of the robot, the second workstation being configured to dispense a second alimentary product into the second open-top vessel.

Isolating Robotic Actuators from Food and Beverage Preparation

Provided is a device, comprising: a barrier configured to impeded or prevent particles shed by a robot in a first volume of space from entering a second volume of space in which the robot manipulates a workpiece; and a robot having three or more degrees of freedom, the robot comprising: a first portion disposed on a first side of the barrier in the first volume, the first portion comprising an actuator of the robot, the actuator being configured to drive movement of the robot to manipulate the workpiece; and a second portion disposed on a second side of the barrier in the second volume, the second portion comprising an end-effector of the robot by which the robot makes contact with the workpiece.

Reducing Cost and Size of Food and Beverage Preparation Robots

Provided is an alimentary-product assembling and dispensing device comprising: a plurality of alimentary-ingredient dispensers positioned to dispense respective ingredients in a plurality of different locations of a robotic work environment; a robot configured to receive an open-top vessel from an open-top-vessel dispenser and move the open-top vessel to the different locations to receive different ingredients from the plurality of alimentary-ingredient dispensers, wherein the robot comprises four or fewer degrees of freedom; and a vending aperture through which consumers retrieve vended alimentary products assembled by the robot from ingredients dispensed from the plurality of alimentary-ingredient dispensers.

Increasing Throughput of Food and Beverage Preparation Robots with Concurrent Transport of Workpieces Along Multiple Axes

Provided is a process, including: engaging, with a first subset of end effectors of a robot, a first open-top vessel; engaging, while the first subset of end effectors are engaged with the first open-top vessel, with a second subset of end effectors of the robot, a second open-top vessel; concurrently transporting the first open-top vessel and the second open-top vessel with two or more actuators; disengaging the first open-top vessel at a first workstation of the robot, the first workstation being configured to dispense a first alimentary product into the first open-top vessel; and disengaging the second open-top vessel at a second workstation of the robot, the second workstation being configured to dispense a second alimentary product into the second open-top vessel.

Breakaway End-Effectors for Food and Beverage Preparation Robots

Provided is a robot, including: a controller; a plurality of actuators mechanically coupled to an end-effector mount; a first set of end-effectors magnetically coupled to the end-effector mount; and a sensor adjacent an interface between at least some of the first set of end effectors and the end-effector mount, wherein: the end effectors are magnetically coupled to the end-effector mount with magnetic couplings that decouple in response to less than 200 Newtons of force being applied to distal portions of respective end effectors in a direction opposing movement of respective end effectors driven by at least some of the actuators, and the sensor is configured to output a signal indicative of a given end effector decoupling and indicate which end effector in the first decoupled.

METHOD FOR CONTROLLING A ROBOTIC SYSTEM FOR MEDICAL OR SURGICAL TELEOPERATION, HAVING A MECHANICALLY UNCONSTRAINED MASTER DEVICE BEING MOVABLE BY AN OPERATOR, WITH CONTROL OF LOCAL REFERENCE COORDINATE FRAMES AND ROBOTIC SYSTEM USING THE METHOD

A method initiates and/or prepares and/or conducts teleoperation by a robotic system for medical or surgical teleoperation. The robotic system includes a master device, which is hand-held, mechanically unconstrained and moveable by an operator, and a slave device including a surgical instrument controlled by the master device. The master device is functionally symmetrical with respect to a predeterminable single, longitudinal axis of the master device. A local reference frame of the master device and the related longitudinal axis is detected, with respect to a main reference frame of the master device workspace; then, functionally equivalent local reference frames are detected. A corresponding target reference frame is mapped in a workspace of the slave device. An operating reference frame is detected according to criteria for optimization of the trajectory of the slave device. A robotic system for medical or surgical teleoperation is control led by the control method.

Method for determining a movement limit

In a movement system, the movement limit is determined by having a degree of freedom of the movement system defined and the respective current movement system state being available. Subsequently, an articulation trajectory is determined for each upper articulation point of the movement system, on which articulation trajectory the articulation point can move along the degree of freedom. The movement limit is then derived by calculating the point of intersection of the actuator movement in an extreme deflection with its respective articulation trajectory.