The present invention is a continuation of PCT Application No. PCT/GB2014/050472 filed Feb. 18, 2014, that claims priority to GB Application No. 1302909.5, filed on Feb. 19, 2013, both of which are incorporated herein by reference in their entireties.
The present invention relates to the discharging of bulk commodities from a hopper. The present invention is particularly concerned, although not exclusively, with the discharging of bulk commodities from a hopper wagon.
A hopper is a chamber for storing bulk commodities such as grain, rock, coal, biomass etc. The bulk commodities are typically loaded into a hopper through an inlet aperture at the top of the chamber and discharged through an outlet aperture in the bottom of the chamber. Due to the arrangement of the outlet, bulk commodities discharge through the outlet under the force of gravity. The discharging process is controlled by using a discharge system to open and close the outlet aperture when required.
A hopper may be a free-standing container or it may be combined with other apparatus. For example, a hopper may be incorporated in a vehicle.
A hopper wagon is a type of freight railway vehicle for transporting bulk commodities. The hopper wagon comprises a hopper wagon body with a hopper chamber for storing bulk commodities. The hopper wagon body is supported by an underframe. Bogies may be coupled to the underside of the underframe to allow the hopper wagon to move along the railway track. The bulk commodities are loaded into the chamber through an inlet aperture and discharged through at least one outlet aperture. The inlet aperture is conventionally formed in the top of the hopper wagon body whilst the at least one outlet aperture is conventionally formed in the bottom of the hopper wagon body. It is customary for bulk commodities to be discharged from the chamber into an unloading bay formed in the floor between the rails and beneath the railway track. The discharging process is controlled by using a discharge system to regulate the opening and closing of the outlet aperture(s).
Conventional discharge systems typically comprise one or more closable doors that are arranged on the underside of an outlet and are movable between an open position and a closed position. For example, a prior art discharge system may comprise a pair of doors that are arranged on opposing sides of an outlet and extend the length of the outlet. Each door is pivotally mounted to allow for the rotation between a closed position and an open position. When rotated to the closed position, the doors extend across the outlet and form a sealing engagement, thereby covering the outlet such that the discharging of bulk commodities is prevented. When the doors are rotated to the open position, the outlet is uncovered such that unrestricted discharging can occur.
During the discharging process, it has been found that bulk commodities may spill or spread undesirably. For example, when discharging a hopper wagon, bulk commodities may spill laterally and/or longitudinally along the railway track and the surrounding area rather than into the unloading bay. The spillage of bulk commodities is wasteful. The spillage of bulk commodities may impede the operation of the hopper. For example, the spillage on the railway tracks may reduce the engagement between the bogie wheels and railway track and may ultimately lead to the derailment of the hopper wagon. The spillage may obstruct the motion of the doors such that they are unable to open and close properly. The spillage may interfere with other component parts of the hopper or associated apparatus. The spillage of bulk commodities may release unwanted dust or particulates into the atmosphere. Accordingly, railway personnel must regularly inspect the railway track to remove any spillage from a hopper wagon, which is both an expensive and time consuming procedure. Given that hopper wagons may have approximately 20,000 to 30,000 loading/unloading cycles over a lifetime, the spillage of bulk commodities for hopper wagons is a significant problem.
Embodiments of the invention seek to address or counteract the problems associated with conventional hopper discharge systems as described above. The present invention seeks to provide a solution to the problem of spillage as bulk commodities are discharged through an outlet of a hopper.
The present invention is defined in the attached independent claims, to which reference should now be made. Further preferred features may be found in the sub claims appended thereto.
A first aspect of the invention relates to a baffle that can be arranged to extend from an edge of an outlet of a hopper so that it impedes the spread of bulk commodities in a direction beyond the baffle as they discharge through the outlet, and thereby control the flow of bulk commodities.
The baffle comprises a panel body that can be mounted on a wall of a hopper adjacent an edge of an outlet of a hopper and, whereby in use, the panel body can be arranged in a projecting position, to project in a generally downwardly direction beyond the edge of the outlet so as to restrict the spread of bulk commodities past the panel body as the bulk commodities discharge through the outlet.
By restricting the spread of commodities beyond (behind, to the rear of) the panel body the baffle advantageously reduces the loss of bulk commodities.
The panel body may be mountable on a sidewall of the hopper adjacent to a side edge of the outlet and, in use, may be arrangeable in the projected position to project downwardly beyond the side edge of the outlet so as to restrict lateral spread of bulk commodities past the panel body as the bulk commodities discharge from the outlet.
The panel body may be mountable on an end wall of the hopper adjacent to an end edge of the outlet and, in use, may be arrangeable in the projected position to project in a generally downwardly direction beyond the end edge of the outlet so as to restrict longitudinal spread of bulk commodities past the panel body as the bulk commodities discharge from the outlet. If the baffle is mounted in a movable hopper or hopper vehicle, the end edge may be a leading end edge or a trailing end edge.
Since the bulk commodities will only discharge when the outlet is open, the panel body is preferably arrangeable in the projected position to project in a generally downwardly direction beyond the edge of the outlet and between a gap space defined by the edge of the outlet and an outlet cover arranged in an open position.
The panel body may be arrangeable in the projected position to project at a first incline angle α. Optionally, the first inclined angle α may be selected in accordance with the position of a discharge region or receptacle so that the panel body advantageously guides the discharging bulk commodities towards the discharge region or receptacle.
The baffle may comprise means for mounting the panel body on the wall of the hopper such that the panel body is movable between the projected position and a retracted position, where the panel body is arranged in a stowed configuration and provides no barrier effect. Preferably, in the retracted position, the panel body is arrangeable to extend from the hopper wall at a second incline angle β, where angle β<angle α.
The baffle may comprise hinge means to rotatably mount the panel body on the hopper wall such that the panel body is rotatable between the projected position and the retracted position.
The baffle may comprise drive means to drive the panel body between the projected position and the retracted position. Preferably, the drive means are self-actuating means. The self-actuating means may be configured to incite the rotation of the panel body between the projected position and the retracted position as the outlet cover moves between an open position and a closed position. Hence, the panel body will be arranged for use in a projected position when the outlet door is open and the panel body will be arranged in a retracted position when the outlet door is closed. The self-actuating means may comprise slidable coupling means for slidably coupling the panel body to the outlet cover. The slidable coupling means may comprise one or more low friction contact members mounted on a lower edge and/or side edge of the panel body and arranged in mating contact with the outlet cover.
The baffle may comprise a stiffening tip arranged along a lower edge of the panel body.
A second aspect of the invention comprises a discharge system for controlling the discharge of bulk commodities through an outlet of a hopper comprising:
A third aspect of the invention relates to a hopper comprising:
A fourth aspect of the invention relates to a hopper wagon comprising:
The or each outlet cover may comprise an opposing pair of doors for the outlet, whereby the opposing pair of doors are mountable on opposing walls and are rotatable between an open position where the doors are rotated to extend from the opposing walls in a generally downwardly direction and a closed position, where the doors are rotated such the distal edges of the doors engage and the outlet is thereby closed.
The actuating means may comprise a cylinder and piston and an equaliser linkage to drive the opposing pair of doors between the closed position and the open position.
The control means may be automatic control means configured to sequentially open and close the outlet covers as the respective outlets of the hopper wagon pass over an unloading bay.
For a better understanding of the present invention and to show how it may be carried into effect, reference shall now be made by way of example to the accompanying drawings in which:
The present invention relates to a baffle and its applications thereof.
The baffle is a flap-like mechanism for controlling the spread or deployment of bulk commodities as they discharge through an outlet of a hopper.
The baffle is suitable for use in any type of hopper. For example, the baffle is suitable for use in a free-standing hopper for storing bulk commodities at a particular location or a hopper combined with other apparatus. For example, the hopper may be a hopper incorporated in a vehicle for transporting bulk commodities. The vehicle may be a hopper railway wagon.
With reference to
When mounted on the hopper wall, the panel can be arranged to project from the hopper wall in a generally downwardly direction beyond the edge of the outlet. In this projected position, the panel body forms a barrier (blockade, boundary wall) that extends downwardly from the edge of the outlet and across a region below the edge of the outlet. Therefore, as bulk commodities discharge from the outlet, the spread of bulk commodities in a direction beyond the panel is impeded. By restricting the spread of bulk commodities, the baffle reduces undesirable spillage. The baffle improves the volume of bulk commodities reaching a discharge region or receptacle. The baffle reduces the risk of operational problems caused by the spillage. The baffles limits the transfer of dust and particulates to the environment. The baffle reduces or eliminates the need for personnel to be present in the unloading location to clear spillage from the tracks.
The panel may be mounted on an external surface or on an internal surface of a hopper wall. In the embodiment depicted in
The panel may be configured to be mounted on a sidewall of the hopper, adjacent to a side edge of the outlet and to be arranged to project downwardly beyond the side edge of the outlet so as to form a barrier in a region below the side edge of the outlet that limits lateral spread of bulk commodities. Alternatively, the panel may be configured to be mounted on an end wall of the hopper, adjacent to an end edge of the outlet and arranged to extend downwardly beyond the end edge of the outlet so as to form a barrier in a region below the end edge of the outlet that limits longitudinal spread of bulk commodities. If the hopper is movable, the panel may be mounted on a trailing end edge of the outlet so as to form a barrier that limits trailing longitudinal spread. The panel may be mounted on a leading end edge of the outlet so as to form a barrier that limits leading longitudinal spread.
In the embodiment depicted in
Given that bulk commodities can only be discharged from a hopper when the outlet is open, the baffle is preferably arranged and used in association with an outlet cover that opens and closes the outlet. The baffle may be used with any suitable type of outlet cover that does not conflict with the projecting profile of the baffle. The outlet cover may comprise one or more doors, where the or each door is moveable between an open position and a closed position.
When the outlet cover is arranged in the open position, the one or more doors are configured to extend in a direction away from the outlet such that the outlet is at least substantially open (unrestricted, exposed). As a result, the outlet is sufficiently uncovered to allow for the discharging of bulk commodities into a discharging region or receptacle. When the outlet cover is arranged in a closed position, the one or more doors are configured to extend across the length and width of the outlet so that the outlet is at least substantially covered (shut, obstructed). As a result, discharging from the outlet is at least substantially restricted. Any bulk commodities stored within the hopper are at least substantially concealed (enclosed) within the hopper.
The or each door may be driven to move between the open position and closed position using manual, automatic and/or semi-automatic actuating means.
The panel may be configured to project downwardly beyond an edge of the outlet and at least substantially across a gap space defined by the edge of the outlet and the open outlet cover. For example, in the embodiment depicted in
In the projected position, the panel may extend downwardly from the hopper wall at a first incline angle α relative to a vertical plane (ZZ). The panel may be configured to extend at an incline angle α towards the open door(s), and optionally form a mating contact with the door(s). The panel may be configured to extend at incline angle α towards a discharge region or receptacle located below the outlet and thereby advantageously guide the bulk commodities towards the discharge region or receptacle. Moreover, the panel may be inclined at an angle α to aid the flow of bulk commodities towards the discharge region or receptacle.
The panel may be permanently arranged (fixed) in the projected position. Preferably, the panel would be sited so as not to compromise the opening and closing action of the outlet cover. Alternatively, the panel may be movable between the projected position and a retracted position. The panel may be movable to the projection position when the outlet cover is in the open position and the panel may be movable to the retracted position when the outlet cover is in the closed position. In the retracted position, the panel is preferably arranged such that it is not usable and provides little or no barrier effect. When retracted, the panel may be arranged at least substantially above the edge of the outlet. In the retracted position, the panel may be inclined at a second incline angle β relative to the vertical plane (ZZ), whereby angle β<angle α (not shown). As shown in
The panel may be rotatably mounted on the wall of the hopper so as to allow the panel to rotate between the projected (usable) position and the retracted (unusable) position. The baffle may comprise any suitable hinge means for rotatably mounting the panel on the hopper wall. In the embodiment depicted in
The baffle may be driven to move between the projected position and the retracted position using actuating means. The actuating means may be self-actuating means for inciting the movement of the panel. As shown in the embodiment depicted in
The self-actuating means may comprise slidable coupling means for slidably coupling the panel to one or both of the opposing side doors. The slidable coupling means is configured to drive the panel in a sliding action across one or both opposing outlet doors such that the panel rotates between the projected position and the retracted position as the opposing outlet doors rotate between an open position and a closed position respectively. The panel may be driven to slide along an arcuate path between a distal edge (D1d, D2d) and proximal edge (D1p, D2p) of the opposing outlet doors as the opposing outlet doors rotate between an open position and a closed position.
The slidable coupling means may comprise male or female slidable coupling means configured to slidably engage a corresponding female or male slidable coupling means of the outlet cover.
The slidable coupling means may comprise one or more low friction contact members mounted on the panel so as to form a slidable mating contact with the outlet cover.
The low friction contact members may comprise any suitable low friction material. The low friction contact members may comprise a hard wearing material. The low friction contact members may comprise a plastics, polymer or resin material. For example, the low friction contact member may comprise polytetrafluoroethylene (PTFE) or Devlon.
To help maintain the slidable mating contact between the panel and outlet cover, the outlet cover may comprise one or more elongate slot, groove, channel, ridge or aperture to receive the corresponding low friction contact member.
In the embodiment of the baffle depicted in
The baffle and/or the outlet cover may comprise a stop to prevent the panel from rotating beyond a predetermined projected position. The baffle and/or the outlet cover may comprise a stop to prevent the panel from rotating beyond a predetermined retracted position.
The baffle may comprise a tip (2e) arranged to extend along at least a part of the lower edge of the panel. The tip may be provided so as to stiffen or reinforce the lower edge of the panel. The tip may be integrally formed or welded to the panel.
It will be understood that the dimensions of the baffle will depend upon the type of hopper, the size of the outlet, the outlet doors, distance from the outlet to the predetermined discharge location or receptacle, the discharge region or receptacle and/or the type of bulk commodity.
The length of the baffle (L) may fall within the range of approximately 200 mm to 500 mm. The width (W) of the baffle may fall within the range of approximately 750 mm to 1200 mm.
The inclined angle α may be selected from a range of approximately 120° to 140° with respect to the vertical axis ZZ, depending on the arrangement of the discharge region or receptacle, the type of bulk commodities, the flow characteristics of the bulk commodities, volume of bulk commodities being discharged and the load of bulk commodities acting on the panel. In the embodiment depicted in
The incline angle β may be selected from a range of approximately 98° to 110° with respect to the vertical axis ZZ, depending on the mounting arrangement of the panel and the type of actuating means. In the embodiment depicted in
The panel of the baffle may be formed from a metal material or any other material that has sufficient structural integrity. For example, the panel may be formed from sheet stainless steel.
The baffle may be fitted when manufacturing a hopper. Alternatively, the baffle may be retro-fitted to an existing hopper so as to improve the discharging process of bulk commodities.
The hopper wagon may form part of a freight train comprising several such wagons, typically twenty five in number arranged to be moved by a locomotive in a leading direction (LEADING).
In this embodiment, the hopper wagon (10) comprises a hopper wagon body (11) with a hopper storage chamber for storing bulk commodities (not shown), an inlet (12) formed in the top of the hopper wagon panel through which the bulk commodities can be loaded into the chamber, four outlets (13a,13b,13c,13d) formed in the base of the hopper wagon panel through which the bulk commodities can be discharged from the chamber, an underframe (14) for supporting the hopper wagon body, a first bogie (15a) and a second bogie (15b) coupled to the underside of the underframe.
The hopper wagon further comprises a discharge system for controlling the discharging of the bulk commodities through the outlet. The discharge system comprises four outlet covers (16a, 16b,16c,16d) arranged in association with a respective outlet, actuating means for driving each outlet cover between an open position and a closed position, control means for controlling the actuating means, four trailing edge baffles (17a,17b,17c,17d) arranged in association with the trailing end edge of each respective outlet, four leading edge discharge barriers (18a,18b,18c, 18d) arranged in association with the leading end edge of each respective outlet. The trailing edge baffles and leading edge baffles are provided so as to limit the longitudinal spread of bulk commodities as the bulk commodities discharge through the outlets. The leading and trailing baffles have the same configuration as the baffle depicted in
In the embodiment depicted in
The discharge system comprises control means for controlling the actuating means for each outlet cover. The discharge system may comprise automatic control means. Hence, the discharge system has an automatic mode of operation. The automatic control means may comprise sensors mounted on the hopper wagon that are activated by one or more a line side discharge activation devices (DADI) mounted on infrastructure at the discharging site. For example, automatic control means may open an outlet cover for an outlet when the sensor is activated by a first line side discharge activation device at the entry of the discharging bay and control the closing of the outlet cover when the sensor is activated by a second line side discharge activation device at the exit of the discharging bay. The automatic control means preferably opens the outlet covers of the hopper wagon in a sequential fashion as the hopper wagon passes over the unloading bay located between the rails and beneath the rail tracks.
The discharge system may comprise manual control means. Hence, the discharge system has a manual mode of operation. The manual control means may comprise user operated handles for the door. The manual control means may be configured to override the automatic control means, for example, during an emergency.
The discharge system may comprise locking means. The locking means may comprise means to lock the door in the open position. For example, the locking means may comprise means to continually provide air pressure in the cylinders so as to keep the cylinders and therefore the door in the open position. The locking means may comprise means to lock the door in the closed position. For example, the locking means may comprise a primary mechanical lock (25) connected to each cylinder that engages mechanically by the closing of the cylinder and is released mechanically by the opening of the cylinder. A secondary mechanical lock may be provided. The locking means may be configured to lock and unlock one or more doors of the hopper wagon.
The trailing edge baffle (17a,17b,17c,17d) for each respective outlet is rotatably mounted on a trailing wall of the hopper (TW) adjacent to the trailing edges of the outlet and slidably coupled to the inside surfaces (19ia, 19bi) of the first side door and second, opposing side door of the outlet cover for the outlet.
Likewise, the leading edge baffle (18a,18b,18c,18d) for each respective outlet is rotatably mounted on a leading wall (LW) adjacent to the leading edges of the outlet and slidably coupled to the inside surfaces (19ai, 19bi) of first side door and second, opposing side door of the outlet cover for the outlet.
The trailing edge baffle and leading edge baffle are slidably coupled to the first side door and second side door (D1, D2) using low friction contact means (4a,4b). As the first side door and second side door rotate, the contact means slide along the first side door and second side door. The sliding action causes the trailing edge baffle and leading edge baffle to rotate. Hence, the contact means remain in contact with the first side door and second side door as the first side door and second side door rotate between an open position and a closed position and the trailing edge baffle and the leading edge baffle rotate between a projected position and retracted position.
When arranged in the open position/projected position, the opposing side doors, the trailing edge baffle and the leading edge baffle extend downwardly and form a chute extending towards a region between the rails of a railway track. As bulk commodities discharge through the outlet, the opposing side doors limit the lateral spread of bulk commodities outside the unloading bay. The trailing edge baffle and the leading edge baffle minimise the longitudinal spread of bulk commodities outside the unloading bay.
Indeed, when the hopper wagon is moved across an unloading bay arranged between the railway tracks, the opposing side doors, trailing edge baffle and leading edge baffle are preferably configured to form a chute that guides discharging bulk commodities towards the unloading bay.
If spillage has occurred or the unloading bay has been overfilled, the trailing baffle and optionally the leading baffle help to plough the bulk commodities so as to move or diminish the amount of bulk commodities from key regions of the railway track.
Whilst endeavouring in the foregoing specification to draw attention to those features of the invention believed to be of particular importance, it should be understood that the applicant claims protection in respect of any patentable feature or combination of features referred to herein, and/or shown in the drawings, whether or not particular emphasis has been placed thereon.
Throughout the description and claims of this specification, the words “comprise” and “contain”, and any variations of the words, means “including but not limited to” and is not intended to (and does not) exclude other features, elements, components, integers or steps.
Throughout the description and claims of this specification, the singular encompasses the plural unless the context requires otherwise. In particular, where the indefinite article is used, the specification is to be understood as contemplating plurality as well as singularity, unless the context requires otherwise.
Features, integers or characteristics described in conjunction with a particular aspect, embodiment or example of the invention are to be understood to be applicable to any other aspect, embodiment or example described herein unless incompatible therewith.
Number | Date | Country | Kind |
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1302909.5 | Feb 2013 | GB | national |
Filing Document | Filing Date | Country | Kind |
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PCT/GB2014/050472 | 2/18/2014 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
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WO2014/128450 | 8/28/2014 | WO | A |
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20160001788 | Gibney | Jan 2016 | A1 |
20160001792 | Gibney | Jan 2016 | A1 |
20160311445 | Galvan | Oct 2016 | A1 |
Number | Date | Country |
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519637 | Mar 1931 | DE |
519637 | Mar 1931 | DE |
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Number | Date | Country | |
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20160001788 A1 | Jan 2016 | US |