Provided is a logistics palletizing system. The logistics palletizing system includes a palletizer including a walking device, a telescopic platform device, a feeding device, a multi-stage lifting device and a feed diverting device, where the telescopic platform device is mounted above the walking device, the multi-stage lifting device and the feed diverting device are each mounted on the telescopic platform device, and the telescopic platform device is configured to drive the multi-stage lifting device and the feed diverting device to move in a preset direction relative to the walking device; and the feeding device is mounted on the multi-stage lifting device, the multi-stage lifting device is configured to drive the feeding device up and down, the feed diverting device is configured to convey materials to the feeding device, and the feeding device is configured to palletize the materials

Provided is a logistics palletizing system. The logistics palletizing system includes a palletizer including a walking device, a telescopic platform device, a feeding device, a multi-stage lifting device and a feed diverting device, where the telescopic platform device is mounted above the walking device, the multi-stage lifting device and the feed diverting device are each mounted on the telescopic platform device, and the telescopic platform device is configured to drive the multi-stage lifting device and the feed diverting device to move in a preset direction relative to the walking device; and the feeding device is mounted on the multi-stage lifting device, the multi-stage lifting device is configured to drive the feeding device up and down, the feed diverting device is configured to convey materials to the feeding device, and the feeding device is configured to palletize the materials

Embodiments of a system and a method for determining an edge hardness value for a cementitious board can be used to effectively determine the hardness of the board after it has been made and dried at a predetermined location, such as, at a stacking station, for example. An actuator assembly can manipulate a punch such that the punch is inserted into one of the edges of one of the cementitious boards in the stacker in a controlled manner. A force gauge can be associated with the punch to measure the resistance force exerted by the cementitious board in response to the punch being inserted into its edge. The measured resistance force can be used to determine the edge hardness value.

Embodiments of a system and a method for determining an edge hardness value for a cementitious board can be used to effectively determine the hardness of the board after it has been made and dried at a predetermined location, such as, at a stacking station, for example. An actuator assembly can manipulate a punch such that the punch is inserted into one of the edges of one of the cementitious boards in the stacker in a controlled manner. A force gauge can be associated with the punch to measure the resistance force exerted by the cementitious board in response to the punch being inserted into its edge. The measured resistance force can be used to determine the edge hardness value.

A reception system for receiving objects comprises at least one reception device for receiving objects, a conveyor device, which has at least one conveyor belt section for conveying objects in a conveyance direction in the at least one reception device, and a sensor device, which is arranged on the at least one reception device, for detecting objects in the at least one reception device. It is provided in this case that the sensor device is designed to emit sensor signals along different signal paths over the reception device, to conclude a fill level of the reception device on the basis of an interaction of at least one of the sensor signals with objects conveyed into the reception device. In this manner, a reception system for receiving objects is provided, which enables further automation, in particular in the conveyance of objects into a reception device.

A reception system for receiving objects comprises at least one reception device for receiving objects, a conveyor device, which has at least one conveyor belt section for conveying objects in a conveyance direction in the at least one reception device, and a sensor device, which is arranged on the at least one reception device, for detecting objects in the at least one reception device. It is provided in this case that the sensor device is designed to emit sensor signals along different signal paths over the reception device, to conclude a fill level of the reception device on the basis of an interaction of at least one of the sensor signals with objects conveyed into the reception device. In this manner, a reception system for receiving objects is provided, which enables further automation, in particular in the conveyance of objects into a reception device.

A load former includes a frame, a loading zone bounded on a first end by a stop wall having a stop surface lying in a plane and a rear wall at a rear side of the frame, and a cookie sheet slidably supported by the frame for travel along a path perpendicular to the plane. The path includes portions on first and second sides of the plane, and a portion of the cookie sheet in the second portion of the path defines a bottom of the loading zone. A platform extends over the first portion of the path, and a top wall is vertically spaced from the platform to define a storage space between the top wall and the platform. The storage space has a front opening so that it is accessible from the front of the load former.

A load former includes a frame, a loading zone bounded on a first end by a stop wall having a stop surface lying in a plane and a rear wall at a rear side of the frame, and a cookie sheet slidably supported by the frame for travel along a path perpendicular to the plane. The path includes portions on first and second sides of the plane, and a portion of the cookie sheet in the second portion of the path defines a bottom of the loading zone. A platform extends over the first portion of the path, and a top wall is vertically spaced from the platform to define a storage space between the top wall and the platform. The storage space has a front opening so that it is accessible from the front of the load former.

A box moving device is disclosed. The box moving device changes the position of a box having four side surfaces. The box moving device is equipped with a conveyor and a movement control unit. The movement control unit drives the conveyor to cause the box to move from a first position to a second position. The conveyor can alternately switch between a first state, in which it is contracted along a moving direction of the box, and a second state, in which it is extended along the moving direction of the box. The movement control unit causes the box to move from the first position to the second position by driving the conveyor that is in a holding mode in which it holds at least one of the side surfaces of the box and simultaneously switching the conveyor from the first state to the second state.

A combined weighing system 1 includes a first X-ray inspection device 20, a combined weighing device 40, a bag making and packaging device 50, a weight inspection device 60, a second X-ray inspection device 70, and a management device 90 that manages each device. The management device 90 revises a weight conversion table of the first X-ray inspection device 20 and a correction value of the combined weighing device 40 based on an average value of weights of products B, which is calculated from a result of inspection over a certain time period in the weight inspection device 60.