阅读说明：本技术 移动水喷射轨道维修系统 (Mobile water jet track maintenance system ) 是由 J·雅各布斯 于 2019-09-17 设计创作，主要内容包括：可平移超高压液体喷射系统(100),所述系统包括被配置成维持与轨道(124)的机械接触的可平移框架(200)。所述液体喷射系统包括液体喷射处理头(408),所述液体喷射处理头被加接到所述框架并且被配置成距所述轨道维持一距离并且提供接触所述轨道的液体喷射。所述液体喷射系统还包括与所述液体喷射处理头流体连通的超高压液体泵(116)。所述超高压液体泵被配置成将加压液体供应到所述液体喷射处理头。(A translatable ultra-high pressure liquid injection system (100) comprising a translatable frame (200) configured to maintain mechanical contact with a rail (124). The liquid ejection system includes a liquid ejection processing head (408) affixed to the frame and configured to maintain a distance from the rail and provide a liquid ejection that contacts the rail. The liquid injection system also includes an ultra-high pressure liquid pump (116) in fluid communication with the liquid injection processing head. The ultra-high pressure liquid pump is configured to supply pressurized liquid to the liquid jet processing head.)

1. A translatable ultra-high pressure liquid injection system, comprising:

a translatable frame configured to maintain mechanical contact with the track;

a liquid-ejection-processing head affixed to the frame and configured to maintain a distance from the rail and provide a liquid ejection that contacts the rail; and

an ultra-high pressure liquid pump in fluid communication with the liquid jet processing head, the ultra-high pressure liquid pump configured to supply pressurized liquid to the liquid jet processing head.

2. The ultra-high pressure liquid injection system of claim 1, wherein the frame is attached to one or more wheels configured to contact the rail.

3. The ultra-high pressure liquid injection system of claim 2, wherein the system is configured to translate along the track via the one or more wheels during a track processing operation.

4. The ultra-high pressure liquid injection system of claim 1, wherein the ultra-high pressure liquid pump is disposed on the frame.

5. The ultra-high pressure liquid injection system of claim 1, wherein the ultra-high pressure liquid pump is disposed on a unit separate from the frame and is movable independently of the frame and at a different speed than the frame.

6. The ultra-high pressure liquid injection system of claim 1, wherein the system is configured to remove an outer portion of the rail having a linear dimension between 0.01 mm and 0.1 mm.

7. The ultra-high pressure liquid injection system of claim 1, wherein the system is configured to remove an outer portion of the rail having a linear dimension between 0.1 mm and 1.0 mm.

8. The ultra-high pressure liquid injection system of claim 1, wherein the system is configured to remove an outer portion of the rail having a linear dimension between 1.0 mm and 5.0 mm.

9. The ultra-high pressure liquid injection system of claim 1, wherein the liquid injection handling head is configured to provide the liquid injection to the track at an angle relative to a ground plane.

10. The ultra-high pressure liquid injection system of claim 9, further comprising second and third liquid injection treatment heads in fluid communication with the ultra-high pressure liquid pump and configured to provide second and third liquid injections to the rail at second and third angles, respectively, relative to a ground plane.

11. The ultra-high pressure liquid spray system of claim 10, further comprising fourth, fifth and sixth liquid spray process heads in fluid communication with the ultra-high pressure liquid pump and configured to provide fourth, fifth and sixth liquid sprays, respectively, at fourth, fifth and sixth angles, respectively, relative to the ground plane to a second rail opposite the first rail.

12. The ultra-high pressure liquid spray system of claim 1, wherein the liquid spray treatment head is affixed to a positioning system attached to the frame, the positioning system configured to adjustably position the liquid spray treatment head relative to the track.

13. The ultra-high pressure liquid injection system of claim 12, wherein the positioning system comprises at least one of a robotic arm or a gantry attached to the frame and movable independently of the frame.

14. The ultra-high pressure liquid injection system of claim 12, further comprising a second frame configured to engage the rail, the second frame being movable relative to the frame during operation of the ultra-high pressure liquid injection system.

15. The ultra-high pressure liquid injection system of claim 14, wherein the second frame comprises a liquid reservoir fluidly connected to the ultra-high pressure liquid pump.

16. The ultra-high pressure liquid injection system of claim 15, wherein the liquid reservoir has a capacity of at least 1000 liters.

17. The ultra-high pressure liquid injection system of claim 14, further comprising an electrical generator disposed on the second frame and operatively connected to the ultra-high pressure liquid pump.

18. The ultra-high pressure liquid injection system of claim 14, wherein the liquid injection handling head is configured to handle the track as the second frame translates along the track.

19. The ultra-high pressure liquid injection system of claim 1, further comprising a nozzle fluidly connected to the liquid injection treatment head.

20. The ultra-high pressure liquid injection system of claim 1, further comprising an abrasive feed system fluidly connected to the liquid injection treatment head and configured to introduce a stream of abrasive into the liquid injection.

21. The ultra-high pressure liquid injection system of claim 1, wherein the ultra-high pressure liquid pump is configured to generate at least 20000 PSI of liquid injection for a rail cutting operation or a retrofit operation.

22. The ultra-high pressure liquid spray system of claim 1, wherein the ultra-high pressure liquid pump is configured to generate liquid spray between 200 to 2000 PSI for track cleaning operations or surface treatment operations.

23. A method of operating an ultra-high pressure liquid ejection system, the method comprising:

positioning a translatable frame relative to a track, the translatable frame having a liquid-ejection processing head fluidly connected to an ultra-high pressure liquid pump;

providing pressurized fluid forming a liquid jet contacting the rail to the liquid jet processing head via the ultra-high pressure liquid pump; and

translating the liquid-jet processing head relative to the track, thereby performing a processing operation along the direction of translation of the track over a linear length of the track.

24. The method of claim 23, wherein the frame comprises one or more wheels configured to engage the track.

25. The method of claim 23, wherein movement of the ultra-high pressure liquid pump corresponds to translation of the frame.

26. The method of claim 23, wherein the ultra-high pressure liquid pump is fixedly connected to the frame.

27. The method of claim 23, wherein the ultra-high pressure liquid pump is disposed on a unit separate from the frame and is movable at a different speed than the frame.

28. The method of claim 23, wherein the liquid jet processing head is configured to provide the liquid jet to the track at an angle relative to a ground plane.

29. The method of claim 23, wherein the pressurized fluid is at least 20000 PSI during a rail cutting operation or a retreading operation.

30. The method of claim 23, wherein the pressurized fluid is between 200 to 2000 PSI during a track cleaning operation or a surface treatment operation.

31. The method of claim 23, wherein the ultra-high pressure liquid pump is included within a second frame that is movable independently of the first frame during operation of the liquid injection system, and the method further comprises translating the second frame at a different speed than the frame during operation of the liquid injection system.

32. The method of claim 23, wherein the liquid jet processing head is configured to provide the liquid jet to the track at an angle relative to a ground plane.

33. The method of claim 23, wherein the frame further comprises a second and third liquid-jet-processing head fluidly connected to the ultra-high pressure liquid pump, and the method further comprises providing pressurized fluid forming second and third liquid jets to the second and third liquid-jet-processing heads, respectively, via the ultra-high pressure liquid pump, the second and third liquid jets contacting the track at second and third angles, respectively, relative to a ground plane.

34. The method of claim 23, further comprising fourth, fifth, and sixth liquid-jet-treatment heads in fluid communication with the ultra-high pressure liquid pump, and further comprising providing pressurized fluid forming fourth, fifth, and sixth liquid jets to the fourth, fifth, and sixth liquid-jet-treatment heads, respectively, via the ultra-high pressure liquid pump, the fourth, fifth, and sixth liquid jets contacting the rail at fourth, fifth, and sixth angles, respectively, relative to the ground plane.

35. The method of claim 23, further comprising adjusting at least one of an abrasive or a speed setting to adjust a polishing surface of the track.

36. A curved spray nozzle for an ultra-high pressure liquid spray system, the nozzle comprising:

a frame configured to engage a rail;

at least two liquid jet treatment heads attached to the frame at different angles relative to a ground plane; and

an ultra-high pressure liquid pump fluidly connected to the at least two liquid-jet processing heads and configured to provide pressurized fluid to each of the at least two liquid-jet processing heads to form a first liquid jet and a second liquid jet that intersects the first liquid jet to form a composite liquid jet that contacts the rail.

37. The nozzle of claim 36 wherein at least one of said at least two liquid-ejection processing heads includes a radial deformation that causes a fan shape in at least one of said first liquid ejection or said second liquid ejection.

38. The nozzle of claim 36, wherein the first and second sprays of liquid are positioned to intersect each other at an acute angle such that the third spray of liquid forms a spray having a different trajectory that creates a smooth polished surface on the track during processing operations without nodules remaining after the initial cutting operation.

39. A method of operating an ultra-high pressure liquid ejection system, the method comprising:

positioning a translatable frame on two rails spaced a distance from each other, the translatable frame having (i) a set of wheels for contacting the two rails, and (ii) two sets of three liquid-jet treatment heads fluidly connected to an ultra-high pressure liquid pump, each set of three liquid-jet treatment heads being directed at one of the two rails;

providing pressurized fluid from the ultra-high pressure liquid pump to two groups of the three liquid-ejection processing heads that form two groups of three liquid ejections that contact the two tracks; and

translating the frame relative to the track, thereby performing a processing operation along a direction of translation over a linear length of the track.

40. A translatable ultra-high pressure liquid injection system, the system comprising:

a first means for maintaining mechanical contact with the rail;

a second device for providing a liquid jet contacting the track, the second device being attached to the first device and configured to maintain a distance from the track; and

third means for supplying pressurized liquid to the second means, the third means being in fluid communication with the second means.

Technical Field

The present invention relates generally to the field of liquid pressurization (compression) systems and processes. More particularly, the present invention relates to a method and apparatus for restoring and cleaning a rail using pressurized liquid jets.

Background

Liquid pressurization systems generate high pressure (e.g., 20000 to 90000 pounds Per Square Inch (PSI)) jets (streams) of liquid for various applications. For example, the high pressure liquid may be dispensed to a liquid jet cutting head, a cleaning tool, a pressure vessel, or an isostatic press. In the case of a liquid jet cutting system, liquid is forced at high velocity through a small orifice plate to gather a large amount of energy over a small area. For cutting hard materials, the liquid jet can be "abrasive" or include abrasive particles to increase cutting ability. As used herein, the term "liquid spray" includes any substantially pure water spray, liquid spray, and/or slurry spray. However, those skilled in the art will readily appreciate that the present invention can be applied to other systems using liquid pumps or similar technology.

Railroads are an important mode of transportation throughout the world. However, prolonged use and heavy loading can cause the track to deform and wear over time. Damaged track creates bumpy ride, stress on train car wheels that contact the track, and other damage, and replacing damaged railroad rails can be very expensive. One known method for repairing railroad rails is to use large grinding trains to machine the rails, but this method is loud, unpleasant and expensive, especially when applied to damaged areas. This sound and resulting sparks are so annoying that these trains are often referred to as "jail trains". Furthermore, this grinding technique is not effective near corners or at intersections. What is needed is an improved method for handling (e.g., repairing, rebuilding, and restoring) existing railroad rails.

Disclosure of Invention

The present invention includes a new mobile liquid spray system that uses one or more pressurized liquid jets to treat damaged, worn, or dirty railroad track. The system can include a mobile platform (e.g., a truck, train, rail car or automobile or other rail transit system) supporting a water jet system that can be operated while moving (e.g., while it travels along the rail it is handling) while processing the rail via one or more pressurized liquid jets. The system can include a robot or other motion system that can be placed on or adjacent to the track being serviced, but does not necessarily have to be attached to the track being serviced. In some embodiments, the invention may include a mobile truck-mounted unit (see, e.g., fig. 1A) that may have one set of tires for driving along a roadway and another set of deployable railroad wheels so that a vehicle may travel along and/or on a railroad rail.

In one aspect, the invention features a translatable ultra-high pressure liquid injection system. The liquid ejection system includes a translatable frame configured to maintain mechanical contact with the rail. The liquid ejection system also includes a liquid ejection processing head affixed to the frame and configured to maintain a distance from the rail and/or provide a liquid ejection that contacts the rail. The liquid injection system further includes an ultra-high pressure liquid pump in fluid communication with the liquid injection treatment head. The ultra-high pressure liquid pump is configured to supply pressurized liquid to the liquid jet processing head.

In some embodiments, the frame is attached to one or more wheels configured to contact the track. In some embodiments, the system is configured to translate along the track via one or more wheels during track processing operations. In some embodiments, the ultra-high pressure liquid pump is disposed on the frame. In some embodiments, the ultra-high pressure liquid pump is provided on a unit separate from the frame and is capable of moving independently of and at a different speed than the frame. In some embodiments, the system is configured to remove an outer portion of the track having a linear dimension between 0.01 mm and 0.1 mm. In some embodiments, the system is configured to remove an outer portion of the track having a linear dimension between 0.1 mm and 1.0 mm. In some embodiments, the system is configured to remove an outer portion of the track having a linear dimension between 1.0 mm and 5.0 mm.

In some embodiments, the liquid jet processing head is configured to provide a liquid jet to the track at an angle relative to the ground plane. In some embodiments, the system further comprises a second and third liquid-jet processing head in fluid communication with the ultra-high pressure liquid pump and configured to provide second and third liquid jets, respectively, to the rail at second and third angles, respectively, relative to the ground plane. In some embodiments, the system further comprises fourth, fifth, and sixth liquid-spray treatment heads in fluid communication with the ultra-high pressure liquid pump and configured to provide fourth, fifth, and sixth liquid sprays, respectively, at fourth, fifth, and sixth angles, respectively, relative to the ground plane to a second trajectory opposite the first trajectory.

In some embodiments, the liquid-jet processing head is affixed to a positioning system attached to the frame. The positioning system is configured to adjustably position the liquid-jet treatment head relative to the track. In some embodiments, the positioning system includes at least one of a robotic arm or a gantry (gantry) attached to the frame and movable independently of the frame. In some embodiments, the second frame is configured to engage the rail. The second frame is movable relative to the frame during operation of the ultra-high pressure liquid ejection system. In some embodiments, the second frame includes a liquid reservoir fluidly connected to the ultra-high pressure liquid pump. In some embodiments, the liquid reservoir has a capacity of at least 1000 liters.

In some embodiments, a generator is disposed on the second frame and is operably connected to the ultra-high pressure liquid pump. In some embodiments, the liquid jet processing head is configured to process the rail as the second frame translates along the rail. In some embodiments, the system includes a nozzle fluidly connected to the liquid-ejecting treatment head. In some embodiments, the liquid jetting system includes an abrasive supply system fluidly connected to the liquid-jet processing head and configured to introduce a stream of abrasive into the liquid jet. In some embodiments, the ultra-high pressure liquid pump is configured to generate liquid jets of at least 20000 PSI (or optionally higher limits, e.g., 30000 PSI, 40000 PSI, 50000 PSI, 60000 PSI, 70000 PSI, 80000 PSI, 90000 PSI, or 100000 PSI) for rail cutting operations or retrofit (re-profile) operations. In some embodiments, the ultra-high pressure liquid pump is configured to generate liquid jets between 200 to 2000 PSI for track cleaning operations or surface treatment operations (e.g., and also for low pressure applications).

In another aspect, the invention features a method of operating an ultra-high pressure liquid ejection system. The method includes positioning a translatable frame having a liquid ejection processing head fluidly connected to an ultra-high pressure liquid pump relative to a track. The method also includes providing pressurized fluid forming a liquid jet contacting the rail to the liquid jet processing head via the ultra-high pressure liquid pump. The method also includes translating the liquid-jet processing head relative to the rail, thereby performing a processing operation along a direction of translation of the rail over a linear length of the rail.

In some embodiments, the frame includes one or more wheels configured to engage the track. In some embodiments, movement of the ultra-high pressure liquid pump corresponds to translation of the frame. In some embodiments, the ultra-high pressure liquid pump is fixedly connected to the frame. In some embodiments, the ultra-high pressure liquid pump is provided on a unit separate from the frame and is movable at a different speed than the frame. In some embodiments, the liquid jet processing head is configured to provide a liquid jet to the track at an angle relative to the ground plane. In some embodiments, the pressurized fluid is at least 20000 PSI, or optionally a higher limit, such as 30000 PSI, 40000 PSI, 50000 PSI, 60000 PSI, 70000 PSI, 80000 PSI, 90000 PSI, or 100000 PSI during rail cutting and retreading operations. In some embodiments, the pressurized fluid is between 200 to 2000 PSI during a track cleaning operation or a surface treatment operation. In some embodiments, the ultra-high pressure liquid pump is included in a second frame that is movable independently of the first frame during operation of the liquid injection system. In some embodiments, the method further comprises translating the second frame at a different speed than the frame during operation of the liquid ejection system.

In some embodiments, the liquid jet processing head is configured to provide a liquid jet to the track at an angle relative to the ground plane. In some embodiments, the frame further comprises a second liquid-jet treatment head and a third liquid-jet treatment head fluidly connected to the ultra-high pressure liquid pump. In some embodiments, the method further comprises providing pressurized fluid forming second and third liquid jets to the second and third liquid jet processing heads, respectively, via the ultra-high pressure liquid pump, the second and third liquid jets contacting the trajectory at second and third angles, respectively, relative to the ground plane. In some embodiments, the ultra-high pressure liquid injection system includes fourth, fifth and sixth liquid injection process heads in fluid communication with the ultra-high pressure liquid pump. In some embodiments, the method further comprises providing pressurized fluid forming fourth, fifth, and sixth liquid jets to fourth, fifth, and sixth liquid jet processing heads, respectively, via the ultra-high pressure liquid pump, the fourth, fifth, and sixth liquid jets contacting the trajectory at fourth, fifth, and sixth angles, respectively, relative to the ground plane.

In another aspect, the invention features a curved spray nozzle for an ultra-high pressure liquid spray system. The curved spray nozzle includes a frame configured to engage the rail. The curved spray nozzle also includes at least two liquid-jet treatment heads attached to the frame at different angles relative to the ground plane. The curved spray nozzle also includes an ultra-high pressure liquid pump fluidly connected to the at least two liquid-spray treatment heads and configured to provide pressurized fluid to each of the at least two liquid-spray treatment heads to form one liquid spray that contacts the rail. In some embodiments, the at least two liquid-jet treatment heads are positioned to provide liquid jets that intersect each other at an acute angle to create jets having different trajectories that create a smooth polished surface (finish) on the trajectory during a treatment operation without nodules (burls) remaining after the initial cutting operation.

In another aspect, the invention features another method of operating an ultra-high pressure liquid injection system. The method includes positioning a translatable frame on two rails spaced a distance from each other, the translatable frame having (i) a set of wheels for contacting the two rails, and (ii) two sets of three liquid-jet treatment heads fluidly connected to an ultra-high pressure liquid pump, each set of three liquid-jet treatment heads for one of the two rails. The method also includes providing pressurized fluid from the ultra-high pressure liquid pump forming two groups of three liquid jets contacting the two tracks to two groups of three liquid jet processing heads. The method further includes translating the frame relative to the track, thereby performing a processing operation along a direction of translation over a linear length of the track.

In another aspect, the invention features a translatable ultra-high pressure liquid injection system. The system includes a first device for maintaining mechanical contact with the rail. The system also includes a second device for providing a liquid jet contacting the track, the second device being attached to the first device and configured to maintain a distance from the track. The system further includes a third device for supplying pressurized liquid to the second device, the third device being in fluid communication with the second device.

In some embodiments, the present invention is capable of retrofitting a rail (e.g., repairing or resurfacing a damaged rail area or volume), removing the need for maintenance, and removing only a small width (e.g., about 0.03 mm) of rail material in the process. In some embodiments, a "bent jet" abrasive water jet nozzle is capable of fanning the liquid jet and/or redirecting the water jet in a bent manner. Such curved spray nozzles can be formed by intersecting two linear or curved water sprays at an acute angle, such that a merged spray is formed and flows with a changing trajectory before encountering the trajectory, or can be curved via another means. In some embodiments, the invention uses two connected mobile units that may have different speeds relative to each other (e.g. they may have different or intermittent movements, one carrying the cutting head and the other carrying the liquid reservoir). In some embodiments, the movement of the cutting head can have multiple components (e.g., movement of the system itself along the track and movement of the hanger or arm relative to the system). In some embodiments, the water jet cutting head positioning mechanism is slidable along one or more rails being treated. In some embodiments, the surface of the track can be treated with a liquid spray (e.g., a lower pressure water spray below about 20000 PSI (e.g., 200-.

Using one or more of the above unique features, the entire liquid-ejection system (e.g., including pumps, fluid supplies, cutting heads, etc.) can function while moving and handling one or more rails (e.g., servicing and performing preventative maintenance on one or more rails). The invention can thus provide a quick, inexpensive and clean way to repair old or damaged rails, as well as to perform preventive maintenance on existing rails. The present invention is capable of performing processing at most, including near corners and through intersections, anywhere and anytime. In some embodiments, the present invention is highly flexible from a logistical perspective, particularly when compared to a train of prisons, which can be very difficult and time consuming to move. In some embodiments, the present invention provides negligible heat input into the track (e.g., track temperature does not exceed 90 ℃, which has no appreciable effect on the track), and this can increase the overall life of the product and track.

In some embodiments, the present invention is environmentally friendly, e.g., capable of using recycled water, sand, and metal. In some embodiments, the present invention produces a low noise level compared to the prior art. In some embodiments, the present invention does not generate any sparks, which can make the present invention uniquely suited for resurfacing rails in certain higher risk environments (e.g., near chemical plants, in tunnels, and over waterways). In some embodiments, the present invention produces highly accurate results, which results in less repetitive work or less adjustment to the need to be performed. In some embodiments, the present invention provides high quality surface polishing, for example using a nodule removing tool (which can operate on a rail after a primary cutting operation is performed), and/or can include one or more "curved" jets (or "curved jet nozzles") as described herein.

In some embodiments, the present invention supports at least two types of processing: surfacing and refreshing. Surface treatment can include removal of only chemical layers (e.g., non-steel or rail materials), and abrasives are not typically used for such applications. Refurbishment can include the removal of surface layers of the rails, and for such applications, abrasives are typically used. In some applications, only 0.1-0.2 mm of the track is removed. In other applications, the present invention can remove 1.0-2.0 mm of track. Such a process can help the track last for 5-10 years of normal use before further maintenance or replacement is required. In some embodiments, the cutting head can be positioned anywhere between 0.1 mm to 60 mm (e.g., 0.1 mm, 0.125 ", 0.5", or 1.5 ") away from the track for cutting applications. In some other embodiments, the cutting head can be positioned anywhere between 20-50 cm away from the track for spraying applications. In some embodiments, a finishing machine (e.g., using sandpaper) can be applied to the rail after the cutting head without transferring any substantial heat into the rail. In some embodiments, only the inner edge of each rail is processed, as the outer edge does not contact the wheels of the rail mounted train and therefore does not need to be processed. In some embodiments, the diameter of the nozzle (e.g., the orifice size) can be selected based on the operation to be performed. For example, an orifice size of about 0.010 "-0.045", optionally 0.010-0.025 ", optionally 0.010-0.016 can be used. In some embodiments, a mixing tube having a diameter about two to three times as large as the orifice can be used.

Drawings

The foregoing discussion will be more readily understood based on the following detailed description of the invention when taken in conjunction with the accompanying drawings.

1A-1B are perspective views of a truck mounted water jet rail treatment system disposed on a rail according to an illustrative embodiment of the invention;

FIG. 2 is a close-up perspective view of a truck mounted water jet rail treatment engagement motion system (motion system) according to an illustrative embodiment of the invention;

FIG. 3 is a perspective view of a positioning mechanism for a water-jet trajectory processing system that is dragged in operation after the water-jet trajectory moves a cutting unit (MCU) in accordance with an illustrative embodiment of the invention;

FIG. 4 is a top view of a positioning system for a water jet track MCU mounted on two tracks in accordance with an illustrative embodiment of the invention;

FIG. 5 is a perspective view of a cutting head attached to a positioning system while handling rails in accordance with an illustrative embodiment of the invention;

FIG. 6 is a schematic illustration of water jets of an MCU treating a surface of a rail according to an illustrative embodiment of the invention;

FIG. 7A is a side view of three water jet cutting heads treating a surface of a track according to an illustrative embodiment of the invention;

FIG. 7B is a front-view (head-on view) of three water jet cutting heads treating a surface of a rail according to an illustrative embodiment of the invention;

FIG. 7C is an illustration of a track 750 that has been subjected to processing operations in accordance with an illustrative embodiment of the present invention;

FIG. 8 is a flow chart of a method of operating an ultra-high pressure liquid injection system in accordance with an illustrative embodiment of the invention;

FIG. 9A is an illustration of a curved spray nozzle for a liquid ejecting material handling system having two cutting heads with straight nozzles in accordance with an illustrative embodiment of the invention;

FIG. 9B is an illustration of a curved spray nozzle for a liquid spray material handling system having one straight nozzle and one curved nozzle in accordance with an illustrative embodiment of the present invention;

10A-10C are illustrations of several fluid flow profiles of liquid ejected from different liquid ejection cutting head nozzles according to an illustrative embodiment of the invention;

11A-11B are cross-sectional illustrations of a track cutting scheme through several geometries of one or more liquid jets, according to an illustrative embodiment of the invention;

fig. 12A-12G are illustrations of several grinding and cutting configurations for one or more orbital treatment liquid jets, according to an illustrative embodiment of the invention.

Detailed Description

Fig. 1A-1B are perspective views of a truck mounted water jet track treatment system (mobile cutting unit or MCU) 100 disposed on a track 124 according to an illustrative embodiment of the invention. As shown, MCU 100 includes a truck 104, which truck 104 can be any suitable road-rail vehicle (e.g., based on Volvo D13). The MCU 100 also includes an electric power source 108 (e.g., a 185 kVA generator), a fluid supply 112 (e.g., one or more water tanks), and an ultra-high pressure water injection system 116 (e.g., an endrocax or maxim pump as provided by seashore (Hypertherm, Inc.). The power source 108 is capable of generating constant and regular power to power the water jet cutting components of the water jet system 116, such as boosters and/or pumps that minimize pressure spikes and drops. The fluid supply 112 can include one or more reservoirs carrying cutting liquid (e.g., having a capacity of at least 1000 liters, such as about 4000 liters) and can be stored in one or more containers, e.g., concentrated toward the middle of the truck or dispersed throughout the truck for more uniform weight distribution. The cutting liquid may be purified water, water jet cutting slurry or another suitable mixture. The water jet system 116 can be configured to process and/or cut at ultra high pressures (e.g., about 60000 PSI). In some applications, the system 100 can mix abrasives (e.g., garnet) provided into a high pressure water jet to enhance cutting and/or processing operations with a supplied fluid.

The water jet system 116 includes at least one cutting head (e.g., as shown and described below) to treat the track 124. The cutting head may be connected to a pump of the water jet system 116 via a flexible pipe or hose to cause movement in the system. In some embodiments, the water jet system 116 can include a plurality (e.g., six) of cutting heads. The water jet system 116 can also include a gantry, robotic arm, or other positioning mechanism to orient the water jet cutting head relative to the rail 124 (e.g., as shown and described below) being serviced. The water jet system 116 can also include a CNC controller (such as Edge provided by the seashore corporation)^®A connection system) to position the cutting head and/or to control the process parameters thereof. Thus, the present invention can include a platform housing a generator, a water jet pump and/or intensifier, a cutting head, cutting fluid, abrasive, and a controller, all of which are fully operational when moved.

MCU 100 includes a rail engaging motion system 120, which rail engaging motion system 120 is capable of engaging with rail 124 and maintaining mechanical contact with rail 124. Prior to operation, truck 104 may be able to travel as it would normally be (e.g., as shown in fig. 2, with track engaging motion system 200 in the disengaged position) to set itself on track 124. The system 120 can include a nodule removal tool that pulls the cutting head to remove and/or crush any existing nodules. This nodule removal tool may be part of the rear wheel (trailing wheel) on the positioning mechanism 300 or a separate attachment. During operation, the track engagement motion system 120 can be lowered into position and lift the truck 104 so that the truck tires 128 do not maintain contact with the ground or the track 124 (e.g., as shown in fig. 1A). The MCU 100 can then move along the track 124 using the track engaging motion system 120 to move about the track during track processing operations (e.g., cleaning or cutting). Thus, the MCU 100 can be a self-contained, fully functional and mobile water jet cutting system. In some embodiments, one or more components of the system may be mobile even though they are not directly engaged with the track 124.

Fig. 3 is a perspective view of positioning mechanism 300 of an aqueous jet track handling system being towed in operation after an aqueous jet track Moves Cutting Unit (MCU) 304 in accordance with an illustrative embodiment of the present invention. The positioning mechanism 300 allows for a large number of independent movements of the cutting head along the track 308 without relying on the motion of the MCU 304 itself. In some embodiments, the positioning mechanism 300 can be included within a retractor 312 (or attachable automobile or other suitable moving member) connected to the MCU 304. The retractor 312 can be a hanger-type mechanism that controls movement of the cutting head. As the MCU 304 pulls (or pushes) the retractor 312 forward, the cutting head processes the passing track 308. In this configuration, the hanger can move the cutting head while the MCU 304 is in motion (e.g., augmenting motion provided by the MCU 304 itself into processing operations on the track) or allow the system to be operated in a section by section (e.g., processing sections of the track 308 while the MCU 304 is stationary).

Fig. 4 is a top view of a positioning system 400 for a water jet track MCU mounted on two tracks 404A, 404B, according to an illustrative embodiment of the present invention. In operation, the mobile truck system (e.g., as shown and described above) is positioned on the railroad rails 404A, 404B such that the truck can travel along the rails 404A, 404B it handles. The positioning system 400 includes at least one cutting head 408, and once positioned on the tracks 404A, 404B, the cutting head 408 is oriented relative to the tracks 404A, 404B to be processed. The generator supplies power to the water jet pump and/or intensifier, control mechanism and/or hanger and CNC. The intensifier receives water from the water reservoir and pressurizes the water to an ultra-high pressure (e.g., above 20000 psi), and preferably to about 60000 psi and/or other high pressures known in the water jet cutting industry (e.g., about 90000 psi). Pressurized water is directed through a pipe 416 to the cutting head 408 where the water mixes with the abrasive (e.g., garnet). As the water jet 412 exits the cutting head 408, it cuts or cuts away a portion of the track 404A.

FIG. 5 is a perspective view of a cutting head 500 attached to a positioning system 504 while processing a track 508 (via liquid jets 512) according to an illustrative embodiment of the invention. The positioning mechanism 504 may provide controlled movement of the cutting head 500 relative to the frame of the positioning mechanism 504, moving the jets in any number of patterns and/or profiles across and/or along the track 508. In some embodiments, the motion path of the MCU (as shown above), the positioning mechanism 504, and/or the cutting head 508 are varied or controlled relative to each other sufficiently to result in a desired cut polishing surface, shape, and/or contour on the track 508. In some embodiments, the positioning mechanism 504 controls the cutting head 500 relative to the track 508 it cuts. Such features may be important because the tracks may be imprecise and can vary in width-for example they may not be perfectly straight or may only be straight enough or well-positioned enough to support the train. In another embodiment, multiple cutting heads are provided on the positioning mechanism 504 and moved relative to each other to create multiple profiles on a track or to cut on more than one track (e.g., as described in more detail below).

The present invention can provide improved positioning and movement of conventional liquid jet cutting heads. A typical cutting head is movable (e.g. in the x-y direction) on a fixed grid, but in the present invention an angle adjustment mechanism can be provided to move the angle of the liquid jet relative to the track. Such a mechanism can have significant advantages in the context of the present invention because of the unique angle desired and the proximity to the ground. For example in typical liquid jet cutting equipment, how wide the cutting head is not important, but in this context there are more stringent geometrical constraints. For example, the cutting head needs to be positioned high enough away from the ground so that it does not encounter debris on the ground, such as stones or screws rising up from the base of the rail-but low enough to actually contact the track, and adjustable to contact the track at a desired angle. The space available for the cutting heads in an installation comprising a plurality of cutting heads becomes particularly tight, especially if they are positioned low from the ground. For such cases, the invention can include narrower, thinner cutting heads.

FIG. 6 is a schematic illustration of water jetting of an MCU 600 treating a rail surface 604 according to an illustrative embodiment of the invention. As shown, small strips of the track 608 (e.g., with surface irregularities) can be removed, leaving a clean polished surface on the track surface 604. In some embodiments, the present invention can handle over 500 meters of track per hour. In this way, the use of water jets can provide significant advantages on grinding trains that are banned in tunnels, near chemical plants when the risk of fire is high (such as dry conditions) and in many other cases. Still further, certain tracks used for freight trains are extremely stiff and cannot be reshaped using grinding trains. The water jets effect the trimming, elimination or delay of these rails for the need for very expensive replacement. In some embodiments, the invention includes a pump, a high pressure water dispensing line, and/or a cutting head positioned on a moving frame to ride on or over a track. This platform is then physically connected to a stationary generator or grid or land-based power (land power) or local water supply. During processing operations in which the liquid jet(s) refurbish and/or reshape the rail (e.g., cut and/or remove portions of the rail), the distance from the nozzle to the rail varies between about 0.1 millimeters and about 39 millimeters; generally in the range of about 0.1 millimeters and about 13 millimeters; and in some embodiments preferably in the range of about 0.1 millimeters to about 4 millimeters. The distance between the tips of the nozzles of the liquid-jet cutting head can be selected based on the processing operation being performed. In some embodiments, it is preferable to choose as small a distance as possible to minimize liquid jet spray dispersion in the environment and to have a compact and accurate focus point and/or impact point on the track being processed.

The liquid jet itself is usually circular in that it is ejected from the nozzle of the water jet cutting head and has a diameter controlled by the mixing tube and/or orifice of the liquid jet cutting head. The diameter of the liquid jet as it emerges from the nozzle tip is in the range of about 0.005 inches to about 0.120 inches; and optionally in the range of about 0.0075 inches to about 0.045 inches; and optionally between about 0.010 inches and 0.025 inches. In some embodiments, a preferred range is between about 0.010 inches and 0.016 inches. Typically the mixing tube is about three times as large as the orifice, however in some embodiments it can be about 2 times as large. The diameter of the liquid jet can be adjusted and/or selected based on the selected course. The cross-sectional area of the liquid jet stream at the impingement point and/or the focused point on the rail is typically in the range of about 0.00002 inches square to about 0.06 inches square; and can range from about 0.00004 square inches to about 0.0016 square inches; and can range from about 0.00008 square inches and 0.0005 square inches. In some embodiments, this range is preferably between about 0.00008 square inches and 0.0002 square inches.

FIG. 7A is a side view of three water jet cutting heads 704, 708, 712 treating a track surface 716 according to an illustrative embodiment of the invention. In this figure, the water jet cutting head 704 provides a first water jet 720, which first water jet 720 impinges on the rail surface 716 at a first angle relative to the ground. As the system translates in the left-to-right direction, the second water jet cutting head 708 passes through substantially the same treatment area as just contacted by the first water jet 720, said second water jet cutting head 708 providing a second water jet 724 that impinges on the rail surface 716 at a second angle relative to the ground. Additional rail material is removed due to the different second water jets 724 in positioning and angle relative to the rail surface 716. Third water jet cutting head 712 provides third water jet 728 that impinges on track 716 at a third angle relative to the ground surface 728, again removing additional track material due to the different positioning and angle of third water jet 728. Details of the impingement can be seen in FIG. 7B, which is a front view of the three water jet cutting heads 704, 708, 712 of FIG. 7A. Fig. 7C is an illustration of a track 750 that has been subjected to a treatment operation (e.g., by water jets as shown and described above) in accordance with an illustrative embodiment of the invention. The finished rail 750 includes a polished inner edge 754 that can have a reduced height and/or width compared to an unpolished outer edge 758, and can have a smooth, brand-new appearance free from wear and tear, such as oxidation and surface buckling (dings). Further details of possible cutting geometries for multiple cutting heads are shown below in fig. 11A-11B and 12A-12G.

FIG. 8 is a flowchart of a method 800 of operating an ultra-high pressure liquid ejection system, according to an illustrative embodiment of the invention. In a first step 802, a translatable frame is positioned relative to a track, the translatable frame having a liquid ejection processing head fluidly connected to an ultra-high pressure liquid pump. In a second step 804, a liquid jet processing head is provided, via an ultra high pressure liquid pump, the pressurized fluid forming a liquid jet contacting the rail. In a third step 806, the liquid jet processing head is translated relative to the rail, thereby performing a processing operation (e.g., shaping, refreshing, or removing a portion of the rail) along the direction of translation of the rail over the linear length of the rail.

Fig. 9A is an illustration of a curved spray nozzle 904 (collectively referred to as a "curved spray nozzle") for a liquid-ejecting material processing system having two cutting heads 908, 912 with straight nozzles, according to an illustrative embodiment of the invention. The cutting head 908 is provided to be defined by a first vector v₁The illustrated velocity exiting primary water jet 916 while the cutting head 912 is provided to be defined by a second vector v₂Secondary water jets 920 are shown exiting at a velocity. First water spray 916 intersect secondary water jets 920 at an angle 924 to form a third water jet having a third vector v₁₂A third water spray 928 at a compound speed is shown. Third vector v₁₂Can have a v-based₁And v₂Which causes third water jets 928 to assume different trajectories. Third water jet 928 can contact rail 932 at contact point or surface 936. This contact can enable "lighter contacts" and create a buffed, polished, or polished edge, rather than a jagged or skewed edge. For example, as the fluid exits the cutting heads 908, 912 in the form of a liquid jet, it can become affected by several environmental factors including air resistance, turbulence, etc. (which can as a whole have an overall effect (net effect) of smoothing on harder edges). These factors can increase as the fluid jet exits the cutting heads 908, 912 and travels a greater distance away from the cutting heads 908, 912. The cutting heads 908, 912 can be mounted to a frame 940 that holds them in place. The spray can have many shapes, such as linear, curvilinear, fan, or convex fan (bulging fan) shapes, as shown below in fig. 10A-C.

FIG. 9B is an illustration of another curved spray nozzle 954 for a liquid spray material handling system having one straight nozzle 958 and one curved nozzle 962, according to an illustrative embodiment of the invention. The cutting head 958 is provided to be driven by a first vector v₃The illustrated velocity exiting first water jet 966 while the cutting head 962 is provided to be defined by a second vector v₄The velocity exiting secondary water spray 970 is shown. First water jet 966 intersects second water jet 970 at an angle 974 to form a jet having a third vector v₃₄The third water jet 978 is shown at a combined velocity. Composite velocity vector v₃₄Can have a v-based₃And v₄Which causes third water jet 978 to assume a different trajectory, for example as shown above in fig. 9A. Third water jet 978 can contact track 982 at a contact point or surface 986. As above, the contact can enable "lighter contacts" and create a shiny, polished or polished edge, rather than a smooth, polished or polished edgeWith a serrated edge or a skewed edge. In some embodiments, a "curved" water jet nozzle redirects the water jet in a curved manner so as to reach multiple surfaces of the rail (e.g., side or lower surfaces of the rail) or impinge on the workpiece at a particular angle. This configuration can reduce or eliminate debris from processing and/or provide much greater control over the bevel (angling). The cutting heads 958, 962 can be mounted to a frame 990 that holds them in place and/or maneuvers them about the tracks 982. One or more cutting heads (e.g., 962) can be bent to allow for more important and accurate positioning and to avoid problems of larger straight cutting heads spatially interfering with each other. The spray can have many shapes, such as linear, curvilinear or fan-shaped. In one embodiment, the water spray is substantially circular and radially symmetric (e.g., not a flat spray).

10A-10C are illustrations of several fluid flow profiles of liquid ejected from different liquid ejection cutting head nozzles according to an illustrative embodiment of the invention. As can be seen in FIG. 10A, the fluid flowing along the left side of the (flow down) straight nozzle will have a velocity equal to or approximately equal to the fluid flowing along the right side, such that v₁=v₂And the fluid will initially be ejected as a direct jet (since the external air resistance across the jet will be substantially balanced) and will gradually dissipate. However, in a curved nozzle, the fluid flowing along the left side can have a smaller velocity than the fluid flowing along the right side because the fluid on the right side subtends a greater arc during its travel. In this case, v₂Can be greater than v₁And can be asymmetric in the external forces (e.g., air resistance) encountered by the fluid as it exits the nozzle. As a result, a "fan-shaped" jet can be ejected, such as shown in fig. 10B. In some examples, the flow profile in fig. 10A or 10B can be linear from a side view, as shown on the left side of fig. 10C (flow profile (1)), but local deformation in the geometry of the nozzle can also cause the profile to bulge, as shown on the right side of fig. 10C (flow profile (2)).

11A-11B are cross-sectional illustrations of several geometric orbital cutting schemes by one or more liquid jets, according to an illustrative embodiment of the invention. Fig. 11A shows a first rail 1104, the first rail 1104 being divided with three cuts, first removing the segment 1108, second removing the segment 1112, and again removing the segment 1116. In some embodiments, air resistance, turbulence, and other effects may have the overall effect of "smoothing" out these hard lines, as described above. Thus, continuous cutting can contribute to an overall smoother polishing surface. Fig. 11B shows a second rail 1140, which is likewise divided into three segments, for example, a first segment 1160, a second segment 1162, and a third segment 1164, by three jets 1150, 1152, 1554.

Fig. 12A-12G are illustrations of several retrofitting, reshaping, and/or cutting configurations for one or more rail treatment liquid jets, according to an illustrative embodiment of the invention. In fig. 12A, a rail 1202 (shown in cross-section) receives a jet 1206 at a first angle from a first cutting head 1204 for a grinding operation. In fig. 12B-12C, the same tracks (shown as 1212, 1222 at different points in time) receive second and third jets 1216, 1226 at second and third angles, respectively, from second and third cutting heads 1214, 1224, respectively, for similar operation. In fig. 12D-12F, the track 1232 (also shown as 1242, 1252 at different points in time) receives liquid sprays 1236, 1246, 1256 from the cutting heads 1234, 1244, 1254 and removes the track sections 1238, 1248, 1258. In fig. 12G, the same track 1260 receives liquid jets 1264A, 1264B, 1264C from cutting heads 1262A, 1262B, 1262C, which liquid jets 1264A, 1264B, 1264C intersect the track for a refurbishing operation and are each dispersed in a spray pattern.

These configurations are exemplary and illustrate the wide variety of cutting and grinding operations that can be achieved by the present invention. In some embodiments, the present invention can be used for refurbishment and/or refurbishment. For example, in a retrofit operation, the plurality of nozzles may be positioned longitudinally, perpendicular to the rail, or at another angle with respect to the rail. In some embodiments, to remove material, the nozzle is positioned close to the rail (e.g., so that the jet velocity is high and is less affected by dissipative forces such as air resistance). In some embodiments, the nozzle is positioned further away from the rail during the polishing operation. In some embodiments, the angle of impact can depend on the force required at the time of impact, which can in turn depend on the operation to be achieved (e.g., severe damage can warrant a different angle than lighter damage). In a refurbishing operation, to remove the undesired layer from the rail, one or more nozzles can be positioned longitudinally with respect to the rail, for example as in fig. 12G. As the speed of the MCU can be varied, the amount of abrasive used can be varied. In some embodiments, to remove very thick and hard layers, the MCU can travel at less than 1 mph (e.g., 0.1-0.5 mph). For less fixed layers, the MCU can travel faster, e.g., up to 25 mph.

While the present invention has been particularly shown and described with reference to a particular preferred embodiment, it will be understood by those skilled in the art that various changes in form and detail may be made therein without departing from the spirit and scope of the invention as defined by the following claims.