A processing and buffering device compatible with various conveying lines is disclosed and includes a fixing and installation mechanism, a jacking component and a clamping component. The fixing and installation mechanism is used for fixing the processing and buffering device on a lateral side of a conveying line. The jacking component is disposed on the fixing and installation mechanism, and includes a jacking cylinder and a connection element, wherein the jacking component is allowed moving up and down in a vertical direction under the action of the jacking cylinder. The clamping component is disposed on the fixing and installation mechanism, connected to the jacking component through the connection element, and includes a horizontal displacement cylinder and two clamping elements. The clamping component is driven by the jacking component to move. The clamping elements are driven by a horizontal displacement cylinder to perform a clamping operation or a releasing operation.

Various embodiments disclosed herein provide for an improved accumulation conveyor and systems and methods for controlling a high rate, high density tunable accumulation conveyor. In one embodiment, an accumulation conveyor system determines whether an item detection variable associated with a second zone of a plurality of zones is satisfied, wherein the second zone is downstream of a first zone. The accumulation conveyor system determines whether at least one of two operational characteristic variables is satisfied. In an instance where both the item detection variable and at least one operational characteristic variable are satisfied, the accumulation conveyor system is configured to set a zone operating state associated with the first zone to inactive and send a command signal comprising the zone operating state associated with the first zone to a control module associated with the first zone. In another embodiment, an improved method for adjusting aggressiveness is disclosed. In another embodiment, a tunable release rate accumulation conveyor is disclosed. In still another embodiment, a tunable crowding accumulation conveyor is disclosed.

A method for managing an automation system involving a plurality of synchronous elements, the method including: designating a master signal for controlling the plurality of synchronous elements; determining a communication protocol for communicating the master signal to the plurality of synchronous elements; determining a compensation profile for each of the plurality of synchronous elements based on the communication protocol and characteristics of each of the plurality of synchronous elements; and utilizing the compensation profile in the control of the automation system. A system for managing an automation system involving at least two synchronous elements, the system including: a first controller for controlling a first synchronous element; a second controller for controlling at least a second synchronous element; a configuration module for configuring at least the second synchronous element; a memory storing instructions that, when executed by the second controller, cause the second controller to perform the method above.

System and method are provided where parcels or packages are associated or grouped, into logical group or logical containerization of parcels or packages, without need for physical container, such that parcels or packages can be tracked as a group, for example with a unique group ID. Logical group may be tracked within specified logical zone on conveyor, transported, sorted and/or otherwise processed as unique logical group without need to be contained in physical container. System and method for automated sortation can accumulate set number or set volume of packages, and then process the accumulated set number or volume of packages, including automatically closing a container filled with the packages.

A waste stream is analyzed and sorted to segregate different items for recycling. Certain features of the technology improve the accuracy with which waste stream items are diverted to collection repositories. Other features concern adaptation of neural networks in accordance with context information sensed from the waste. Still other features serve to automate and simplify maintenance of machine vision systems used in waste sorting. Yet other aspects of the technology concern marking 2D machine readable code data on items having complex surfaces (e.g., food containers with integral ribbing for structural strength or juice pooling), to mitigate issues that such surfaces can introduce in code reading. Still other aspects of the technology concern prioritizing certain blocks of conveyor belt imagery for analysis. Yet other aspects of the technology concern joint use of near infrared spectroscopy, artificial intelligence, digital watermarking, and/or other techniques, for waste sorting. A variety of further features and arrangements are also detailed.

A waste stream is analyzed and sorted to segregate different items for recycling. Certain features of the technology improve the accuracy with which waste stream items are diverted to collection repositories. Other features concern adaptation of neural networks in accordance with context information sensed from the waste. Still other features serve to automate and simplify maintenance of machine vision systems used in waste sorting. Yet other aspects of the technology concern marking 2D machine readable code data on items having complex surfaces (e.g., food containers with integral ribbing for structural strength or juice pooling), to mitigate issues that such surfaces can introduce in code reading. Still other aspects of the technology concern prioritizing certain blocks of conveyor belt imagery for analysis. Yet other aspects of the technology concern joint use of near infrared spectroscopy, artificial intelligence, digital watermarking, and/or other techniques, for waste sorting. A variety of further features and arrangements are also detailed.

Automatic device for the automated conduct of analyses, notably medical analyses, including: 43. a storage zone for bottles, 44. an automated sampling system for selectively sampling the content of a bottle among those present in the storage zone, 45. a loading zone for introducing a new bottle into the automatic device, 46. an unloading zone for collecting a bottle previously present in the storage zone, 47. a bottle conveyor and storage system, configured selectively and individually to transport a bottle from a location in the storage zone to the unloading zone or from the loading zone to a location in the storage zone.

An accumulator has a control system for controlling motion of a plurality of buckets on a continuous loop and logs traversing on a log transfer device. The log transfer device delivers a log from an entrance of the log transfer device to a bucket infeed on the accumulator. The bucket infeed receives a log from the log transfer device and allows a bucket to receive the log from the log transfer device. A time for the log to move from the entrance of the log transfer device to the bucket infeed is determined. Based on the time for the log to move from the entrance of the log transfer device to the bucket infeed, the control system controls the accumulator drive to move the continuous loop such that a bucket in the plurality of buckets is positioned at the bucket infeed with sufficient time to allow the bucket to receive the log from the log transfer device.

Conveyor assembly for in a lying position, in X-direction from an inlet to an outlet, conveying products serially supplied in transverse series comprising: —an inlet conveyor situated on the inlet side; —a drive for driving the inlet conveyor for in X-direction conveying the transverse series of products lying thereon; —a first recording device for recording the position of the products within a transverse series, in a Y-direction that is horizontally transverse to the X-direction; —a first correction device for influencing the positions in Y-direction of the products within a transverse series; —a programmable control unit which is configured for receiving and processing the recording data from the first recording device and for controlling the first correction device, if the products within the recorded transverse series are not in the wanted position in Y-direction, —wherein the first correction device comprises a first conveyor and a first drive for it for conveying the products in X-direction, —wherein the first conveyor comprises a number of first sub-conveyors positioned next to each other for respective conveyance in X-direction of the products situated in a transverse series, according to paths that are situated next to each other, —wherein the first correction device further comprises first sub-drives for individually from each other setting the upstream ends of the first sub-conveyors in position in Y-direction, which first sub-drives can be controlled for that purpose by the control unit in response to the recording data received from the first recording device relating to the positions of the products in a transverse series in Y-direction, —wherein the first conveyor is situated downstream of the inlet conveyor.

Conveyor assembly for in a lying position, in X-direction from an inlet to an outlet, conveying products serially supplied in transverse series comprising: —an inlet conveyor situated on the inlet side; —a drive for driving the inlet conveyor for in X-direction conveying the transverse series of products lying thereon; —a first recording device for recording the position of the products within a transverse series, in a Y-direction that is horizontally transverse to the X-direction; —a first correction device for influencing the positions in Y-direction of the products within a transverse series; —a programmable control unit which is configured for receiving and processing the recording data from the first recording device and for controlling the first correction device, if the products within the recorded transverse series are not in the wanted position in Y-direction, —wherein the first correction device comprises a first conveyor and a first drive for it for conveying the products in X-direction, —wherein the first conveyor comprises a number of first sub-conveyors positioned next to each other for respective conveyance in X-direction of the products situated in a transverse series, according to paths that are situated next to each other, —wherein the first correction device further comprises first sub-drives for individually from each other setting the upstream ends of the first sub-conveyors in position in Y-direction, which first sub-drives can be controlled for that purpose by the control unit in response to the recording data received from the first recording device relating to the positions of the products in a transverse series in Y-direction, —wherein the first conveyor is situated downstream of the inlet conveyor.