Methods and apparatuses for manufacturing products having custom graphic designed are disclosed. A method may comprise printing a first order identifier graphic on a substrate material, the first order identifier graphic associated with a first order for a first set of products, printing a first set of one or more graphic designs on the material, the graphic designs associated with the first order, combining the material with one or more product components to form the first set of products, each of the products of the first set of products being associated with the first customer order and at least one of the products of the first set of products comprising the first order identifier graphic, performing a print quality inspection on the print test graphic, and after determining the print test graphic failed the print quality inspection, culling each of products associated with the first order.

A sheet conveying device includes: a holding mechanism configured to hold suction members; and a driving device including a rotary shaft which is rotatable about a second axis parallel to the first axis and a connecting mechanism configured to connect the rotary shaft and suction members to each other; and a support mechanism configured to support the holding mechanism and the drive device. The connecting mechanism is connected to the suction members in a state where the suction members are movable in a radial direction of the circle about the first axis. The support mechanism supports the holding mechanism and the drive device such that the holding mechanism and the drive device are relatively movable from each other in a direction orthogonal to the first axis.

A method for in-line analysis of a composite product, wherein a hyperspectral sensor is used to acquire images of samples of target materials that are part of the composite product, in order to perform an in-line optical inspection at process speed.

Methods and apparatuses for manufacturing products having custom graphic designed are disclosed. A method may comprise printing a first order identifier graphic on a substrate material, the first order identifier graphic associated with a first order for a first set of products, printing a first set of one or more graphic designs on the material, the graphic designs associated with the first order, combining the material with one or more product components to form the first set of products, each of the products of the first set of products being associated with the first customer order and at least one of the products of the first set of products comprising the first order identifier graphic, performing a print quality inspection on the print test graphic, and after determining the print test graphic failed the print quality inspection, culling each of products associated with the first order.

The present disclosure relates to systems and processes for controlling the relative positions or phasing of advancing substrates and/or components in absorbent article converting lines. The systems and methods may utilize feedback from technologies, such as vision systems, sensors, remote input and output stations, and controllers with synchronized embedded clocks to accurately correlate component placement detections and placement control on an absorbent article converting process. The systems and methods may accurately apply the use of precision clock synchronization for both instrumentation and control system devices on a non-deterministic communications network. In turn, the clock synchronized control and instrumentation network may be used to control the substrate position. As such, the controller may be programmed to the relative positions of substrates and components along the converting line without having to account for undeterminable delays.

Disclosed herein are apparatus, systems and methods of measuring the weight and distribution of the fluff pulp and super absorbent polymer (SAP) or absorbent gelling material (AGM) of absorbent articles. The apparatus may be located at a position after the absorbent cores are formed. Each absorbent article is passed between the light emitter and the camera as well as between the radio transmitter and the radio detector. The camera and radio detector receive the signal transmitted by the light emitter and the radio transmitter respectively through the absorbent articles. The encoder synchronizes the transmission of data by the camera and the radio receiver to the movement of the web. The computer receives the signal data from radio detector and the image data from the camera from each absorbent article and uses the data to determine at least the weight of the fluff pulp and SAP/AGM in the absorbent core.

A method for inspecting absorbent articles is provided. The inspection is performed using an inspection algorithm generated with a convolutional neural network having convolutional neural network parameters. The convolutional neural network parameters are generated by a training algorithm. Based on the inspection, characteristics of the absorbent articles, such as defects, can be identified. Absorbent articles having identified characteristics can be rejected, or other actions can be taken.

A method for inspecting absorbent articles is provided. The inspection is performed using an inspection algorithm generated with a convolutional neural network having convolutional neural network parameters. The convolutional neural network parameters are generated by a training algorithm. Based on the inspection, characteristics of the absorbent articles, such as defects, can be identified. Absorbent articles having identified characteristics can be rejected, or other actions can be taken.

A machine for making absorbent sanitary articles including an absorbent pad with at least one discrete layer of superabsorbent polymer material includes a unit for forming and applying a succession of absorbent pads, which includes a drum for forming the pad, a duct for feeding a charge of superabsorbent polymer material to the drum and intermittent valve mounted along a stretch of the duct and driven by an actuator. A device detects the superabsorbent polymer material and sends a signal to a control and drive unit connected to the device indicating that the superabsorbent polymer material has been detected. The control and drive unit is configured to drive the actuator to bring the valve into phase with the rotation of the drum when the deviation of the signal from a reference signal exceeds a defined threshold value.

A method for inspecting absorbent articles is provided. The inspection is performed using an inspection algorithm generated with a convolutional neural network having convolutional neural network parameters. The convolutional neural network parameters are generated by a training algorithm. Based on the inspection, characteristics of the absorbent articles, such as defects, can be identified. Absorbent articles having identified characteristics can be rejected, or other actions can be taken.