This invention is related to a double grab, its rinsing cup and milking machine provided therewith, and the method for automatically applying teat cups to the teats of an udder of an animal to be milked. The double grab, according to the invention, includes: a first housing part provided with a first magnet designed to hold a first teat cup; a second housing part, installed substantially in a horizontal plane next to the first housing part, provided with a second magnet designed to hold a second teat cup whereby each housing part is provided with separate pivoting means that can be activated and is designed to make the related housing part pivot around a pivoting axis which in use, extends substantially in a horizontal direction, substantially in a widthwise direction of the arm.

A system comprises a memory operable to store first light intensity information for a first pixel of an image that includes a dairy livestock, and second light intensity information for a second pixel of the image, wherein the second pixel is adjacent to the first pixel. The system further comprises a processor communicatively coupled to the memory and operable to determine that a difference between the first light intensity information and the second light intensity information exceeds a threshold, and discard one of the first pixel or the second pixel from the image.

Disclosed is a system for treating dairy livestock having fore legs and hind legs, wherein the system comprises a parallel milking parlor ramp, livestock stalls positioned along at least part of the parallel milking parlor ramp, wherein each stall is configured to contain one dairy livestock, at least one vertical upright teat cup holder comprising teat cups and a mobile unit. The mobile unit comprises equipment for treating livestock and a processor, where the mobile unit is configured to travel between the fore legs and hind legs of the dairy livestock on the parallel milking parlor ramp and use the equipment to perform at least one action related to a treatment of the dairy livestock. Also disclosed is that the equipment includes an arm configured to withdraw the teat cups from the vertical upright teat cup holder and connect them to the dairy livestock.

An implement for automatically milking a dairy animal, such as a cow, comprises a milking parlour, a sensor for observing a teat, and a milking robot for automatically attaching a teat cup to the teat. The milking robot comprises a robot control that is connected to the sensor. The sensor comprises a radiation source for emitting light, a receiver for receiving electromagnetic radiation reflected from the dairy animal, a lens, and sensor control unit. The sensor comprises a matrix with a plurality of rows and a plurality of columns of receivers. The sensor control unit is designed to determine for each of the receivers a phase difference between the emitted and the reflected electromagnetic radiation in order to calculate the distance from the sensor to a plurality of points on the part to be observed of the dairy animal.

An implement for automatically milking a dairy animal, such as a cow, comprises a milking parlour, a sensor for observing a teat, and a milking robot for automatically attaching a teat cup to the teat. The milking robot comprises a robot control that is connected to the sensor. The sensor comprises a radiation source for emitting light, a receiver for receiving electromagnetic radiation reflected from the dairy animal, a lens, and sensor control unit. The sensor comprises a matrix with a plurality of rows and a plurality of columns of receivers. The sensor control unit is designed to determine for each of the receivers a phase difference between the emitted and the reflected electromagnetic radiation in order to calculate the distance from the sensor to a plurality of points on the part to be observed of the dairy animal.

In certain embodiments, a system includes a three-dimensional camera and a processor communicatively coupled to the three-dimensional camera. The processor is operable to determine a first hind location of a first hind leg of a dairy livestock based at least in part on visual data captured by the three-dimensional camera and determine a second hind location of a second hind leg of the dairy livestock based at least in part on the visual data. The processor is further operable to determine a measurement, wherein the measurement is the distance between the first hind location and the second hind location. Additionally, the processor is operable to determine whether the measurement exceeds a minimum threshold.

An implement for automatically milking a dairy animal, such as a cow, comprises a milking parlour, a sensor for observing a teat, and a milking robot for automatically attaching a teat cup to the teat. The milking robot comprises a robot control that is connected to the sensor. The sensor comprises a radiation source for emitting light, a receiver for receiving electromagnetic radiation reflected from the dairy animal, a lens, and sensor control unit. The sensor comprises a matrix with a plurality of rows and a plurality of columns of receivers. The sensor control unit is designed to determine for each of the receivers a phase difference between the emitted and the reflected electromagnetic radiation in order to calculate the distance from the sensor to a plurality of points on the part to be observed of the dairy animal.

An apparatus includes a carriage, camera, spray tool, and controller. The carriage is movably coupled to a track. The camera and spray tool are coupled to the carriage. The controller moves the carriage along the track away from a starting position based on a first signal from the camera, and as the carriage moves away from the starting position, discharges, through the spray tool, a solution for a first time. The controller moves the carriage towards the starting position after the solution has been discharged for the first time, and based on a second signal from the camera as the carriage moves towards the starting position and before the carriage reaches the starting position, moves the carriage away from the starting position. As the carriage moves away from the starting position, the controller discharges, through the spray tool, the solution for a second time.

A time-of-flight (TOF) camera system for a robot milking system includes a housing accommodating a light source, imaging optics, an image sensor, and electronics; a front part including a light transparent window disposed in front of the light source and the imaging optics; and fasteners. The housing has a front side and a back side, and the front part has a front side and a backside, the surface of the front side being flat and including a front surface of the light transparent window. The fasteners releasably mechanically fasten the front part to the housing with the back side of the front part and the front side of the housing facing each other. The fasteners are maneuverable from the back side of the housing to fasten the front part to, and release the front part from, the housing, thereby enabling the front part to be replaceable.

A milking device and method for milking an animal includes a frame; a teat cup carrier connected pivotally to the frame; a number of receiving elements arranged in or on the teat cup carrier and configured to receive teat cups to which milk hoses are connectable for the purpose of discharging milk, a guide for moving the teat cups and/or milk hoses substantially vertically downward and pivoting the teat cup carriers relative to the frame; and a cylinder comprising a teat cup end and a guide end. The teat cup end is connected operatively to the teat cup carrier, and wherein the guide end of the cylinder is arranged in, on or at the guide, wherein the milking device comprises a rest state and a milking state and is displaceable from the rest state to the milking state by the cylinder.