A cutting bit assembly includes a block, a bit sleeve, and a seal. The block includes a first bore and a fluid passage. The fluid passage includes a first portion and a second portion in fluid communication with the first portion. The first portion is oriented obliquely with respect to the first bore, and the second portion extends at least partially around the perimeter of the first bore. The bit sleeve includes a shank, a flange, and a second bore extending through the shank and the flange. The shank is positioned within the first bore of the block such that a surface of the flange engages a first end surface of the block. The seal is positioned between the second portion of the fluid passage and the shank to prevent contact between a fluid in the fluid passage and the outer surface of the shank.

A mining machine includes a chassis, a boom, a cutting head, and a shield supported for movement relative to the chassis. The chassis includes a first end and a second end, and defines a longitudinal axis extending between the first end and the second end. The boom includes a first end and a second end, and the boom is supported for movement relative to the chassis. The boom translates in a first direction and is pivotable relative to the chassis between first and second positions. The cutting head is coupled to the second end of the boom and is supported for rotation relative to the boom. The cutting head is rotatable about a cutting head axis. The shield is supported for movement relative to the chassis and positioned proximate the cutting head. In some embodiments, the shield is coupled to a sumping frame supported for movement relative to the chassis.

A mining machine includes a chassis, a boom, a cutting head, and a shield supported for movement relative to the chassis. The chassis includes a first end and a second end, and defines a longitudinal axis extending between the first end and the second end. The boom includes a first end and a second end, and the boom is supported for movement relative to the chassis. The boom translates in a first direction and is pivotable relative to the chassis between first and second positions. The cutting head is coupled to the second end of the boom and is supported for rotation relative to the boom. The cutting head is rotatable about a cutting head axis. The shield is supported for movement relative to the chassis and positioned proximate the cutting head. In some embodiments, the shield is coupled to a sumping frame supported for movement relative to the chassis.

A support includes a support element for supporting a drilling tool used in rock drilling. The support element is inside a suction housing of a rock drilling unit at least during drilling. The support is located at a front end portion of a feed beam and is used to support the tool especially during the collaring phase of the drilling. A method of collaring is disclosed wherein the drilling tool is supported by the support.

Cold planer exhaust systems and methods of clearing the same are disclosed. The exhaust systems and methods may include an inlet manifold located proximate a milling drum housing and above a material conveyor. The inlet manifold may further include at least one inlet passage and at least one access door configured to open and allow access to an interior of the exhaust system. The systems and methods may further include a ventilator configured to draw dust and fumes into and through the exhaust system.

A dust mitigation system removes dust from the lens of a laser or a camera on a mining equipment rig or in other industrial applications. The dust mitigation system is operable to deliver high pressure air in short bursts to remove dirt from the lens in a manner that does not damage the laser or the camera.

A dust mitigation system removes dust from the lens of a laser or a camera on a mining equipment rig or in other industrial applications. The dust mitigation system is operable to deliver high pressure air in short bursts to remove dirt from the lens in a manner that does not damage the laser or the camera.

A spray system for dust control on a shearer machine that operates laterally with respect to a mining floor surface is provided where the spray system is provided with a set of first ranging arm sprays mounted on a first ranging arm and wherein said first ranging arm is located on a first end of a shearer machine chassis. A set of second ranging arm sprays is optionally provided and is mounted on the upper side of the first ranging arm and resides approximate to and in operational relationship to the set of first ranging arm sprays. Furthermore, a plurality of chassis spray sets may also be optionally provided and are located on a mining side of said shearer machine chassis and reside in a non-linear format. Moreover, a set of shearer-clearer venturi arm sprays may also optionally be provided and is mounted on a shearer-clearer venturi arm that resides as an angular extension of the set of first shearer-clearer arm sprays.

A block for use in a cutting assembly wherein the block includes a block body that contains a reservoir with coolant therein. The block body contains a top passage operative communication with the reservoir so as to receive coolant. The top passage has an axial forward top passage section terminating in an axial forward top passage end. The axial forward top passage section has an axial forward top passage section central longitudinal axis. The top passage further has an axial rearward top passage section terminating in an axial rearward top passage end. The axial rearward top passage section has axial rearward top passage section central longitudinal axis. The axial forward top passage section central longitudinal axis is disposed at an angle with respect to the axial rearward top passage section central longitudinal axis.

A block for use in a cutting assembly wherein the block includes a block body that contains a reservoir with coolant therein. The block body contains a top passage operative communication with the reservoir so as to receive coolant. The top passage has an axial forward top passage section terminating in an axial forward top passage end. The axial forward top passage section has an axial forward top passage section central longitudinal axis. The top passage further has an axial rearward top passage section terminating in an axial rearward top passage end. The axial rearward top passage section has axial rearward top passage section central longitudinal axis. The axial forward top passage section central longitudinal axis is disposed at an angle with respect to the axial rearward top passage section central longitudinal axis.