A conveyor component incorporating at least one sensor, a component identifier, and a transmitter, as well as a system/method for monitoring conveyor components. Each sensor is integrally formed in said conveyor component and is adapted to sense at least one characteristic of said conveyor component to produce sensor data representative of said sensed characteristic. An identification device is adapted to provide unique identification data for the respective conveyor component. The transmitter is adapted to transmit said sensor and identification data to a central server wherein said data is processed to generate status data in relation to the conveyor component indicative of any maintenance required to be performed on said conveyor component. The system/method for monitoring includes at least one sensor, a central server, and a user interface. Each sensor is adapted to sense at least one characteristic of a respective conveyor component and produce sensor data representative of said sensed characteristic. The central server is adapted to receive said sensor data from each sensor, process said sensed data to generate status data in relation to each conveyor component. The user interface is adapted to receive said status data from said central server and provide maintenance information to a user indicative of any maintenance required to be performed on said conveyor component.

A protection system includes a mount for attachment to a wear panel of equipment. The mount includes a first portion which engages the wear panel to be protected and a second portion extending from the first portion which engages an adjacent face to be protected. The second portion has a passage which allows sliding movement of a bolt along the passage. A wear part is releasably mounted to the mount and has a first portion that slidingly engages the first portion of the mount and a second portion that engages the second portion of the mount. The second portion of the wear part has a passage arranged to align with the passage through the second portion of the mount when the wear part and the mount are engaged. A bolt extends through the aligned passages to secure the wear part to the mount via a locking member.

Systems and method for retaining a downspout onto a spout are disclosed. The downspout may be retained on the spout using hook and loop fasteners. In some implementations, a portion of a spout may include a first portion of a hook and loop fastener and the downspout may include a second portion of the first hook and loop faster. The first and second portions of the hook and loop faster are complimentary such that the first and second portions of the hook and loop fastener combine to interlocking secure the downspout and the spout together.

A conveyance apparatus (1) according to an embodiment includes: a trough (11) that receives an article from an outside and conveys the article in a conveyance direction from upstream to downstream; and a drive unit (20) that drives the trough. The trough includes a plurality of protrusions (92) on a front surface (91) on which the article is conveyed, and an opening (91A) passing from the front surface to a back surface (93) is formed at an end (92E) on a downstream side of the plurality of protrusions.

A wear panel for mining and materials handling applications is provided. The wear panel includes a housing matrix (1) with a top surface (2), a bottom surface (3) opposite the top surface (2) and at least one cavity (4) with cavity walls (5). The cavity (4) extends through the top surface (2) and the bottom surface (3). The wear panel also includes at least one wear-resistant member (6) with a preformed shape. The at least one wear-resistant member (6) has a top surface (7) and a bottom surface (8) opposite the top surface (7). The wear-resistant members (6) are disposed in the cavity (4) and are locked into place by their preformed shape and the cavity walls (5).

A wear panel for mining and materials handling applications is provided. The wear panel includes a housing matrix (1) with a top surface (2), a bottom surface (3) opposite the top surface (2) and at least one cavity (4) with cavity walls (5). The cavity (4) extends through the top surface (2) and the bottom surface (3). The wear panel also includes at least one wear-resistant member (6) with a preformed shape. The at least one wear-resistant member (6) has a top surface (7) and a bottom surface (8) opposite the top surface (7). The wear-resistant members (6) are disposed in the cavity (4) and are locked into place by their preformed shape and the cavity walls (5).

The present invention relates broadly to a wear liner module (10) for equipment in a high wear environment, said module (10) comprising a back plate (12) and a wear liner (11) including one or more tiles (14a) to (14f) formed of wear resistant material, and one or more sensors such as (16a) mounted to the wear resistant tile such as (14a). The wear sensor (16a) is mounted to a perimeter face of the corresponding wear resistant tile (14a). The wear sensor (16a) is electrically coupled to a microprocessor mounted to a rear face of the tile (14a). The microprocessor is configured to process data received from the wear sensor (16a) to provide a wear signal represented of wear in the wear sensor (16a). The microprocessor (24a) transmits the wear signal to a wireless receiver (34a) mounted to the backing plate (12).

The present invention relates broadly to a wear liner module (10) for equipment in a high wear environment, said module (10) comprising a back plate (12) and a wear liner (11) including one or more tiles (14a) to (14f) formed of wear resistant material, and one or more sensors such as (16a) mounted to the wear resistant tile such as (14a). The wear sensor (16a) is mounted to a perimeter face of the corresponding wear resistant tile (14a). The wear sensor (16a) is electrically coupled to a microprocessor mounted to a rear face of the tile (14a). The microprocessor is configured to process data received from the wear sensor (16a) to provide a wear signal represented of wear in the wear sensor (16a). The microprocessor (24a) transmits the wear signal to a wireless receiver (34a) mounted to the backing plate (12).

A liner protects an interior surface of a chute that transfers workable foundry molding mix from a mixer to a machine for molding and hardening. The liner has an upper border portion and body portion. The upper border portion secures the liner to an upper portion of the chute. The body portion has at least one panel of a flexible material and is sized and adapted to line the interior surface of the chute. The liner also has a plurality of apertures through the upper border portion for attaching the upper border portion to the upper portion of the chute. The flexible material of the body portion is a woven fabric with polymeric fibers and, optionally, a polymeric coating.

A liner protects an interior surface of a chute that transfers workable foundry molding mix from a mixer to a machine for molding and hardening. The liner has an upper border portion and body portion. The upper border portion secures the liner to an upper portion of the chute. The body portion has at least one panel of a flexible material and is sized and adapted to line the interior surface of the chute. The liner also has a plurality of apertures through the upper border portion for attaching the upper border portion to the upper portion of the chute. The flexible material of the body portion is a woven fabric with polymeric fibers and, optionally, a polymeric coating.