In one aspect, a computing system may be configured to perform operations including obtaining image data that depicts a portion of a field positioned aft of a ground-engaging tool of an agricultural implement relative to a direction of travel of the agricultural implement. The operations may also include inputting the image data into a machine-learned classification configured to receive imagery and process the imagery to output one or more visual appearance classifications for the imagery. Furthermore, the operations may include receiving a visual appearance classification of the image data as an output of the machine-learned classification model. Additionally, the operations may include determining when the ground-engaging tool is plugged based on the visual appearance classification of the image data.

A plugging control system for an agricultural implement includes a sensor configured to output a sensor signal indicative of plugging of a ground engaging component and a controller having a processor and a memory. The processor is configured to receive the sensor signal indicative of plugging of the ground engaging component from the sensor, determine whether the plugging exceeds a threshold value, and in response to the plugging exceeding the threshold value, output a monitoring signal to perform a monitoring operation, output a control signal to perform a control operation, or both.

A plugging control system for an agricultural implement includes a sensor configured to output a sensor signal indicative of plugging of a ground engaging component and a controller having a processor and a memory. The processor is configured to receive the sensor signal indicative of plugging of the ground engaging component from the sensor, determine whether the plugging exceeds a threshold value, and in response to the plugging exceeding the threshold value, output a monitoring signal to perform a monitoring operation, output a control signal to perform a control operation, or both.

Harvesting device of an agricultural harvesting machine, comprising a housing (17), comprising at least one rotatably driven apparatus (15) which has a shaft (18) and is rotatably mounted by the shaft (18) relative to the housing (17) about the longitudinal axis (19) thereof, comprising a sealing disk (21) which acts on the housing (17) and which is fixed relative to the shaft (18) for sealing the housing (17) relative to the shaft (18) in the region of a feed-through of the shaft (18) through the housing (17), wherein the sealing disk (21) has a through-passage (22) for the feed-through of the shaft (18), wherein when viewed in the radial direction of the shaft (18) a slide bearing joint bush (25) is arranged between the shaft (18) and the sealing disk (21).

Harvesting device of an agricultural harvesting machine, comprising a housing (17), comprising at least one rotatably driven apparatus (15) which has a shaft (18) and is rotatably mounted by the shaft (18) relative to the housing (17) about the longitudinal axis (19) thereof, comprising a sealing disk (21) which acts on the housing (17) and which is fixed relative to the shaft (18) for sealing the housing (17) relative to the shaft (18) in the region of a feed-through of the shaft (18) through the housing (17), wherein the sealing disk (21) has a through-passage (22) for the feed-through of the shaft (18), wherein when viewed in the radial direction of the shaft (18) a slide bearing joint bush (25) is arranged between the shaft (18) and the sealing disk (21).

A system for de-plugging ground engaging tools of an agricultural implement includes a ground engaging tool. A fluid nozzle is in fluid communication with a pressurized fluid source such that pressurized fluid from the pressurized fluid source is flowable to the fluid nozzle. The fluid nozzle is oriented towards the ground engaging tool. Thus, pressurized fluid from the fluid nozzle is flowable towards, next to and/or against the ground engaging tool.

A system for de-plugging ground engaging tools of an agricultural implement includes a ground engaging tool. A fluid nozzle is in fluid communication with a pressurized fluid source such that pressurized fluid from the pressurized fluid source is flowable to the fluid nozzle. The fluid nozzle is oriented towards the ground engaging tool. Thus, pressurized fluid from the fluid nozzle is flowable towards, next to and/or against the ground engaging tool.

A system for managing material accumulation relative to an agricultural implement may include a ground engaging tool supported on an agricultural implement and an infrared sensor having a field of view directed towards the ground engaging tool. The infrared sensor may be configured to generate data indicative of a temperature gradient of field materials at the ground engaging tool. A controller of the system may be communicatively coupled to the infrared sensor. The controller may monitor the data received from the infrared sensor and determine a presence of material accumulation relative to the ground engaging tool based at least in part on the temperature gradient of the field materials at the ground engaging tool.

A scraper blade for a row unit of a planter. The scraper blade has a connecting portion that connects to the pivot hub of a depth-gauge assembly. The connecting portion connects to a blade portion. The blade portion is positioned in a gap formed between the pivot hub and the contact surface of the depth-gauge wheel. The scraper blade is connected to the depth-gauge assembly in a static and stationary position at a pivot point. As a pivot arm and the depth-gauge wheel move about in relation to the pivot point, the scraper blade maintains a fixed position at close tolerances with the depth-gauge wheel to remove soil and debris from the depth-gauge wheel.

A scraper blade for a row unit of a planter. The scraper blade has a connecting portion that connects to the pivot hub of a depth-gauge assembly. The connecting portion connects to a blade portion. The blade portion is positioned in a gap formed between the pivot hub and the contact surface of the depth-gauge wheel. The scraper blade is connected to the depth-gauge assembly in a static and stationary position at a pivot point. As a pivot arm and the depth-gauge wheel move about in relation to the pivot point, the scraper blade maintains a fixed position at close tolerances with the depth-gauge wheel to remove soil and debris from the depth-gauge wheel.