The present disclosure relates generally to continuous mining and, more particularly, to a wethead seal design for a continuous mining machine.
In underground mining operations using drum-type continuous miners, water spray nozzles may be located on the cutting drum near each cutter bit to suppress the generation of airborne dust and frictional ignition as the cutter bits engage the mine face. Airborne dust and wet dislodged material may also be suppressed by mounting spray nozzles on a bar located behind the cutter drum. The bar mounted spray nozzles wet the mine material above and below the cutter drum and also wet the bits as the cutter drum completes each rotation.
The effectiveness of a spray bar is limited and may not control dust before it becomes airborne. However, the incorporation of spray nozzles located immediately adjacent the cutter bits on the surface of the cutter drum has been found to be effective in suppressing dust before it becomes airborne. The water is continuously sprayed from the cutter bits directly at the point where the material is dislodged from the mine face. Generating a water spray at the cutter bits suppresses the dust at its source and effectively eliminates any risk of frictional ignition as the cutter bits strike the solid material. Generating a water spray from the nozzles also serves to extend the life of cutter bits for continuous miners. Water is supplied to the nozzles on the surface of a continuous miner drum from a water supply on a non-rotating portion of the mining machine. For example, water is supplied from the cooling circuits of the drive motors and conveyed through conduits in stationary struts and housings to a rotary seal mounted concentrically on the axis of the drum. Conventional rotary seals are positive pressure seals designed to prevent any leakage of the water past the seals. A rotary seal has a stationary part with ports for receiving the water and a rotational part mounted on or connected to the drive shaft. In order to maintain a positive pressure seal between the stationary and rotating parts, the rotary seal typically employs an elastomeric material such as rubber, or surfaces of other materials such as carbon that are machined to extremely tight tolerances. Surfaces of the positive pressure rotary seal are in constant contact in order to form the seal. Relative rubbing motion between the parts may cause wear and eventual failure of the seal. A typical positive pressure rotary seal in a mining machine must also keep the water from leaking into contact with the gears and bearings as the water passes through the rotary seal on its way to fittings on spray nozzles associated with the cutter bits.
A critical aspect in supplying water through a cutter drum to the external surface behind the cutter bits is the effectiveness of the rotary seal in preventing leakage of water into the gearcase and bearings. With a positive pressure seal for a continuous mining machine, this problem is aggravated because a relatively large rotating seal must be used around the drive shaft of the continuous miner. The larger diameter rotary seal has more contact surface area where breakdown of the seal or other failures can occur. This problem is further complicated with continuous miners having multiple sections. A typical continuous miner includes a pair of end drum sections and a center drum section. Each section has a separate drive shaft requiring separate large diameter rotary seals. In addition to preventing contamination of the gearcase and bearings, the rotary seal must withstand periods of time in which it runs dry where water is not circulated to the seal.
A continuous mining machine is disclosed in U.S. Pat. No. 5,507,565 that issued to LeBegue et al. on Apr. 16, 1996 (“the '565 patent”). The continuous mining machine in the '565 patent provides a cutter drum assembly rotatably mounted on a boom member. Cutter bits are secured to the cutter drum assembly and extend therefrom. A gearcase is positioned in the cutter drum. A plurality of sprayers are associated with the cutting elements for spraying water onto the material being mined. Positive pressure liquid seals are positioned in the gearcase for directing liquid through the gearcase to the spray devices and preventing liquid from coming into contact with the bearing means. A lubricant seal is required surrounding the positive pressure liquid seals in the gearcase to keep the liquid seals lubricated and to act as a redundant seal to prevent liquid leakage from the liquid seals contaminating the bearings.
Although the apparatus of the '565 patent may have improved the ability to spray liquid onto the mine face as material is dislodged, while avoiding contamination of the gearcase with the liquid, the apparatus may still be problematic. In particular, the apparatus disclosed in the '565 patent requires positive pressure water seals that are subject to constant wear, and that must be relied upon to keep water from getting into the bearings and gear assemblies. Failure of one of these seals can allow water to get into the bearings or gearcase, causing catastrophic failure. The seals are also buried deep inside the assembly, making replacement or maintenance of the seals difficult. Additionally, the seals require lubrication with oil-based lubricants, and additional lubricant seals must be provided to contain the lubricants in contact with the liquid seals.
The continuous mining machine of the present disclosure solves one or more of the problems set forth above and/or other problems in the art.
In one aspect, the present disclosure is directed to a continuous mining machine that includes a cutter drum assembly rotatably mounted on a stationary gear and bearing housing attached to a boom assembly of the mining machine. Cutting elements may be mounted on the rotatable cutter drum assembly, with spray nozzles located in close proximity to the cutting elements to direct liquid spray at a mine face as mine material is dislodged by rotation of the cutter drum assembly and contact of the cutting elements with the mine face. Stationary liquid passageways may be provided through the gear and bearing housing, and rotatable liquid passageways may be provided through the rotatable cutter drum assembly and configured to convey liquid to the spray nozzles. A liquid distribution cavity may be defined within the cutter drum assembly between two labyrinth-type, non-contacting seal assemblies. The liquid distribution cavity may be configured to convey liquid from the stationary liquid passageways to the rotatable liquid passageways and to the spray nozzles for the cutting elements. The two labyrinth-type, non-contacting seal assemblies may be configured to control at least one of liquid quantity and liquid pressure in the stationary and rotatable liquid passageways by providing a controlled leakage pathway directing a portion of the liquid away from the stationary gear and bearing housing to outside of the continuous mining machine.
In another aspect, the present disclosure is directed to a method of controlling at least one of the quantity and the pressure of liquid supplied from a stationary source on a body portion of a continuous mining machine to rotatable cutting elements mounted on a rotatable cutter drum assembly of the machine. The method may include directing the liquid through a manifold extending along a stationary boom member of the machine, into a liquid reservoir formed in a stationary gear and bearing housing mounted on the boom member of the machine, along stationary liquid passageways formed in the gear and bearing housing, and into a liquid distribution cavity defined between two labyrinth-type, non-contacting seal assemblies. The method may further include providing a controlled amount of liquid leakage through each of the labyrinth-type, non-contacting seal assemblies away from the gear and bearing housing and to the outside of the continuous mining machine.
As shown in
One of ordinary skill in the art will recognize that the mining machine may include any number of cutter drum assemblies rotatably supported on gear and bearing housings connected to boom members 134 extending from body portion 120 of mining machine 100. The gear assemblies transferring rotational power from one or more input drive shafts 22 to one or more drive shafts connected to rotating cutter drum assemblies 142, 146 may also include additional gears arranged to produce desired output torques and rotational speeds. These additional gears may include planetary gear assemblies including a sun gear, planet gears engaged with the sun gear and rotatably supported on a planet carrier, and a ring gear engaged with the planet gears. The one or more drive shafts 30, 32 connected to rotating cutter drum assemblies 142, 146 may be rotatably supported by bearing assemblies mounted in the gear and bearing housings.
In accordance with various implementations of this disclosure, manifolds 132 may also be provided extending along boom members 134 and configured for conveying liquid from body portion 120 of mining machine 100 to cutter drum assemblies 142, 146 and cutting elements (not shown) secured to the rotating cutter drum assemblies 142, 146. Certain retrofit implementations may include providing these manifolds on an existing mining machine without liquid spraying capabilities by attaching the manifolds along the body and boom members through welding or other joining processes. The arrangement of the manifolds along the exterior of boom members 134 also facilitates access to the manifolds for any necessary repairs or maintenance. Spray devices carried by the cutting elements may direct a liquid spray from the cutting elements during rotation of the cutter drum assemblies. The manifolds may be positioned on the body portion of the mining machine, and extending along the boom members for supplying liquid to the cutting elements of the cutter drum assemblies. Liquid conveyed to the cutter drum assemblies through the manifolds extending along the boom members may be directed into stationary liquid passageways 138, 152 that extend through various portions 52, 122, 124 of the gear and bearing housing (see
Stationary liquid passageways 138, 152 extending through the gear and bearing housing may be formed as bores or tubes extending through portions of the gear and bearing housing. Liquid provided from the manifolds 132 along boom members 134 may first enter one or more water dams 136 formed in the gear and bearing housing. The one or more water dams 136 may be configured as an annular reservoir or one or more separate reservoirs machined into an outer periphery of the stationary gear and bearing housing. One or more water dam covers 125 may be provided to seal off the water dam and contain water or other liquid received from manifolds 132. Liquid may then pass from the one or more water dams 136 into multiple stationary liquid passageways 138, 152 through portions of the gear and bearing housing.
As shown in
Labyrinth seal assemblies 300, shown in detail in
The outer diffuser ring openings 166 may be aligned with cutter element port group 180 in the outer shell of rotating center cutter drum assembly 146 (see
As shown in
Liquid that does not exit through the spray nozzles for cutter elements at each of cutter element port groups 180, 182, 184 may then enter center ring liquid passageways 186, 188 defined in a center portion of the gear and bearing housing rotatably supporting center cutter drum assembly 146. The center ring liquid passageways may be defined to include an upper extent 188 and a lower extent 186, where the upper and lower extents may each define arcuate cavities extending over an arc that is less than or equal to 180 degrees. As seen in the axial and radial cross sectional views of
Annular cavity 165 may be defined between labyrinth seal assemblies 300, and may be configured to control a pressure drop and resulting liquid back pressure in the flow path of the liquid by providing a controlled leakage path to the outside of the cutter drum assemblies. As illustrated in
As shown in the detailed view of
As shown in
The labyrinth-type, non-contacting seal assemblies contained within the cutter drum assemblies direct liquid from stationary liquid passageways 138, 152 to rotatable primary and secondary liquid passageways 170, 172, and passageways leading to cutter element port group 182, while preventing leakage of liquid into contact with the gear or bearing assemblies. The seal assemblies are designed to provide controlled liquid leakage flow paths that divert some liquid leakage away from the bearing and gearing assemblies and externally out of the cutter drum assembly. Because the various components of the seal assemblies are configured to allow a controlled amount of leakage through the seal assemblies, while being axially and radially spaced from each other to avoid rubbing contact between components, the seal assemblies are not subject to failure resulting from wear over extended periods of use. The controlled leakage in combination with periodic fluctuations in pressure drop through the seal assemblies as inner diffuser ring openings 162 move into and out of radial alignment with outer diffuser ring openings 166 may be configured to achieve the desired amount of liquid flow and liquid pressure to all the ports and cutting elements included in cutter element port groups 180, 182, 184.
Methods of applying various exemplary implementations of a continuous mining machine designed in accordance with the parameters discussed above will be discussed in more detail in the following section in order to further illustrate the disclosed concepts.
The disclosed continuous mining machine may provide an apparatus and method for spraying a mine face with liquid during a mining operation that includes supplying liquid from a stationary source on continuous mining machine 100 to rotatable cutting elements mounted on one or more rotatable cutter drum assemblies 142, 146 of the machine. The method may include directing the liquid through manifold 132 extending along stationary boom members 134 of the machine, into water dam 136 formed in a stationary gear and bearing housing connected to the boom assembly of the machine, along stationary liquid passageways 138, 152 formed in the gear and bearing housing, and into annular liquid cavity 165 defined between two labyrinth-type, non-contacting seal assemblies 300. The method may further include providing a controlled amount of liquid leakage through each of the labyrinth-type, non-contacting seal assemblies away from the gear and bearing housing and to the outside of continuous mining machine 100. The labyrinth-type, non-contacting seal assemblies may provide a means for controlling the amount of liquid and the liquid pressure in passageways leading to cutter drum port groups interspersed along the outer periphery of the rotating cutter drum assemblies. Flow paths through the labyrinth seal assemblies may be designed to provide controlled leakage pathways to rotatable liquid passageways formed in the cutter drum assemblies that lead to cutter drum port groups. The labyrinth seal assemblies may also define leakage pathways leading away from the gear and bearing assemblies to the outside of the continuous mining machine.
The provision of external manifolds along the stationary boom assembly of the mining machine may also provide a way to retrofit an existing continuous mining machine to include liquid flow paths for directing liquid to the cutting elements provided around the outer periphery of the cutter drum assemblies. The externally mounted manifolds are accessible for any necessary maintenance or repair. Liquid passing through the manifolds along the boom assemblies may then enter one or more liquid reservoirs such as water dam 136 formed in the gear and bearing housing connected to ends of the boom assemblies and configured to rotatably support the cutter drum assemblies. The one or more liquid reservoirs formed in the gear and bearing housing may provide a well from which the liquid may be supplied through stationary liquid passageways through the gear and bearing housing. The presence of this well of liquid in the gear and bearing housing may help to ensure that sufficient liquid is available for supply to the cutting elements during use of the mining machine, even when fluctuations in the quantity or pressure of the liquid being supplied from the body portion of the continuous mining machine are experienced.
Labyrinth-type, non-contacting seal assemblies 300 also provide a way to control leakage of liquid from the flow path for the liquid between stationary liquid passageways in the gear and bearing housing and rotatable liquid passageways through the rotating cutter drum assemblies. Rather than providing a positive pressure liquid seal as is traditionally used between the stationary and rotating portions of the continuous mining machine, the labyrinth-type seal assemblies may be designed purposefully to provide a controlled leakage pathway for a portion of the liquid being supplied to the cutting elements. As a result of the stationary and rotating components of the seal assemblies not actually being in contact with each other, the labyrinth seal assemblies are not subject to the wear and potential wear-induced failures of traditional positive pressure seals. The spacing between the components of the seal assemblies, and their resulting ability to “float” relative to each other, also allows the seal assemblies to self-adjust their relative positions when exposed to liquid pressure, and to compensate for variations in machining tolerances of components in the cutter drum assemblies.
The desired pressure drop through the annular cavity defined between two labyrinth seal assemblies may be predetermined and pre-set as a function of a desired amount and pressure of liquid being supplied to the various cutter drum port groups along the outer periphery of the rotating cutter drum assemblies. The provision of a stationary diffuser ring at the entrance to the annular cavity, with circumferentially-spaced openings through which the liquid enters the annular cavity, and a corresponding rotating outer diffuser ring with circumferentially-spaced openings through which the liquid exits the annular cavity, may also result in desired fluctuations in the liquid pressure. The flow path for liquid through the seal assemblies may be a relatively unobstructed, substantially straight flow path when the inner diffuser ring openings are radially aligned with the outer diffuser ring openings. As the cutter drum assembly rotates, the circumferentially-spaced openings through the outer diffuser ring move out of radial alignment with the openings through the inner diffuser ring, thereby increasing the resistance to flow of liquid through the annular cavity. The resulting fluctuations in liquid pressure during rotation of the cutter drum assemblies may help to ensure a desired distribution of liquid to the various cutter drum port groups. As discussed above, the shapes, sizes, and spacings between the various components of the seal assemblies may also be chosen to provide a pre-set amount of pressure drop for the liquid passing through the seal assemblies. As one non-limiting example, greater axial and/or radial spacings between the seal rings of the seal assemblies may allow more liquid leakage from the annular cavity to the outside of the mining machine. This exemplary implementation may be desirable when the quantity or pressure of liquid being supplied through the manifolds to the rotating cutter drum assemblies must be reduced before being supplied to the cutter drum port groups and cutting elements. In an alternative exemplary implementation where the axial and/or radial spacings between various components of the seal assemblies are made smaller, the leakage of liquid through the seal assemblies may be reduced and a greater amount or pressure of liquid may be supplied to the cutter drum port groups.
It will be apparent to those skilled in the art that various modifications and variations can be made to the disclosed continuous mining machine. As one non-limiting example, the stationary liquid passageways through the gear and bearing housing, and the rotatable liquid passageways through the rotating cutter drum assemblies, may be defined as different shaped bores, annular passageways, or other configurations that provide liquid from stationary portions of the machine to rotating portions and the rotating cutting elements. The number and configuration of the labyrinth-type, non-contacting seal assemblies may also be varied in accordance with different performance parameters. The seal assemblies may be pre-assembled and then installed onto the cutter drum assemblies, or may be installed onto the cutter drum assemblies piece by piece. Other implementation will be apparent to those skilled in the art from consideration of the specification and practice of the disclosed methods. It is intended that the specification and examples be considered as exemplary only, with a true scope being indicated by the following claims and their equivalents.
Number | Name | Date | Kind |
---|---|---|---|
3698769 | Amoroso | Oct 1972 | A |
4289357 | Hintermann et al. | Sep 1981 | A |
5507565 | LeBegue et al. | Apr 1996 | A |
6070944 | LeBegue | Jun 2000 | A |
6139112 | Parrott | Oct 2000 | A |
8235470 | Zimmerman et al. | Aug 2012 | B2 |
Number | Date | Country | |
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20150001912 A1 | Jan 2015 | US |