WO2019154166A1 - 充电刀、充电刀总成和轨道交通系统 - Google Patents

充电刀、充电刀总成和轨道交通系统 Download PDF

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Publication number
WO2019154166A1
WO2019154166A1 PCT/CN2019/073570 CN2019073570W WO2019154166A1 WO 2019154166 A1 WO2019154166 A1 WO 2019154166A1 CN 2019073570 W CN2019073570 W CN 2019073570W WO 2019154166 A1 WO2019154166 A1 WO 2019154166A1
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WO
WIPO (PCT)
Prior art keywords
charging
rail
rail vehicle
blade
receiving surface
Prior art date
Application number
PCT/CN2019/073570
Other languages
English (en)
French (fr)
Inventor
尹双
袁清辉
陈冲
裘骏
Original Assignee
比亚迪股份有限公司
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Publication date
Application filed by 比亚迪股份有限公司 filed Critical 比亚迪股份有限公司
Publication of WO2019154166A1 publication Critical patent/WO2019154166A1/zh

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    • BPERFORMING OPERATIONS; TRANSPORTING
    • B60VEHICLES IN GENERAL
    • B60LPROPULSION OF ELECTRICALLY-PROPELLED VEHICLES; SUPPLYING ELECTRIC POWER FOR AUXILIARY EQUIPMENT OF ELECTRICALLY-PROPELLED VEHICLES; ELECTRODYNAMIC BRAKE SYSTEMS FOR VEHICLES IN GENERAL; MAGNETIC SUSPENSION OR LEVITATION FOR VEHICLES; MONITORING OPERATING VARIABLES OF ELECTRICALLY-PROPELLED VEHICLES; ELECTRIC SAFETY DEVICES FOR ELECTRICALLY-PROPELLED VEHICLES
    • B60L5/00Current collectors for power supply lines of electrically-propelled vehicles
    • B60L5/38Current collectors for power supply lines of electrically-propelled vehicles for collecting current from conductor rails
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B60VEHICLES IN GENERAL
    • B60LPROPULSION OF ELECTRICALLY-PROPELLED VEHICLES; SUPPLYING ELECTRIC POWER FOR AUXILIARY EQUIPMENT OF ELECTRICALLY-PROPELLED VEHICLES; ELECTRODYNAMIC BRAKE SYSTEMS FOR VEHICLES IN GENERAL; MAGNETIC SUSPENSION OR LEVITATION FOR VEHICLES; MONITORING OPERATING VARIABLES OF ELECTRICALLY-PROPELLED VEHICLES; ELECTRIC SAFETY DEVICES FOR ELECTRICALLY-PROPELLED VEHICLES
    • B60L5/00Current collectors for power supply lines of electrically-propelled vehicles
    • B60L5/40Current collectors for power supply lines of electrically-propelled vehicles for collecting current from lines in slotted conduits

Definitions

  • the present application relates to the field of rail vehicle technology, and more particularly to a charging knife, a charging knife assembly and a rail transit system.
  • the rail vehicles are charged by the station area.
  • the single-sided planar contact method of the upper and lower sides is used once, and the flow receiving area is limited, and the charging stability and safety are poor.
  • the present application is intended to address at least one of the technical problems existing in the prior art. To this end, the present application proposes a charging knife that can achieve double-sided contact flow, increase the flow receiving area, optimize the flow state, and improve charging stability and safety.
  • the present application also proposes a charging knife assembly having the above charging knife.
  • the present application also proposes a rail transit system comprising the charging knife assembly described above.
  • the charging blade extends in the traveling direction of the rail vehicle, and in the direction perpendicular to the traveling direction of the rail vehicle, the opposite side surfaces of the charging blade are respectively provided a first flow receiving surface and a second flow receiving surface, from an end of the charging knife adjacent to the rail vehicle to an end remote from the rail vehicle, the first flow receiving surface and the second flow receiving surface The spacing between the two is gradually reduced.
  • the first flow receiving surface and the second flow receiving surface can be contacted with the charging rail to realize double-sided flow receiving, the flow receiving area is increased, the flow receiving state can be optimized, and the first receiving
  • the change of the spacing between the flow surface and the second flow receiving surface can ensure a certain contact pressure between the charging knife and the charging rail, which can improve the contact stability, thereby effectively improving the flow stability and reducing the probability of sparking. , improved security.
  • one of the first flow receiving surface and the second flow receiving surface extends vertically, and wherein the other one extends obliquely with respect to the vertical direction; or, the first subject The flow surface and the second flow receiving surface extend obliquely in a direction toward each other.
  • the cross-sectional area of the charging blade gradually decreases from the central portion toward both ends in the traveling direction of the rail vehicle.
  • the charging knife is provided with a receiving groove adapted to mount a wire nose, and the receiving groove is provided at an end of the charging knife near the rail vehicle.
  • the receiving groove extends in a vertical direction to an end face of the charging knife adjacent to the rail vehicle.
  • the receiving groove communicates the first flow receiving surface and the second flow receiving surface in a lateral direction.
  • the charging blade assembly includes: a connecting rod, one end of the connecting rod is connected to the rail vehicle; a charging knife, the charging knife is the charging knife described above, A charging knife is coupled to an end of the connecting rod remote from the rail vehicle.
  • the charging knife can be conveniently and reliably connected to the rail vehicle through the connecting rod, and the charging knife can contact the charging rail by using the first flow receiving surface and the second flow receiving surface to realize double-sided receiving
  • the flow increases the flow receiving area, and the flow receiving state can be optimized, and the distance between the first flow receiving surface and the second flow receiving surface changes, which can ensure a certain contact pressure between the charging knife and the charging rail, which can improve
  • the contact stability can effectively improve the flow stability, reduce the probability of sparking, and improve safety.
  • a rail transit system includes: a power supply device, a track, a charging rail, and a rail vehicle, the rail including a rail beam extending in a traveling direction of the rail vehicle; and the charging rail has a traveling along the rail vehicle a charging slot extending in a direction, the charging rail is electrically connected to the power supply device; the rail vehicle is seated on the rail, and the rail vehicle is provided with the charging knife assembly described above, and the charging knife is adapted Sliding along the charging slot in a clutchable manner.
  • the rail transit system of the embodiment of the present application by providing the rail vehicle according to the above embodiment of the present application, there is an advantage that the charging flow receiving area is large, the current receiving state is good, the charging stability and the reliability are high.
  • the rail transit system further includes: a detecting device and a controller, the detecting device is configured to detect relative position information of the charging knife and the charging slot; the controller and the detecting respectively The device is connected to the power supply device, and the controller controls the power supply device according to the relative position information detected by the detecting device to electrify when the charging knife contacts the charging slot, and to charge the battery The knife is powered off when it is separated from the charging slot.
  • FIG. 1 is a schematic illustration of a power collector shoe in accordance with some embodiments of the present application.
  • Figure 2 is a side view of the collector shoe illustrated in Figure 1;
  • Figure 3 is a cross-sectional view of the power collector shoe illustrated in Figure 1;
  • Figure 4 is an enlarged view of a portion A circled in Figure 3;
  • Figure 5 is an exploded view of the collector shoe illustrated in Figure 1;
  • FIG. 6 is a schematic view of a power collecting shoe according to other embodiments of the present application.
  • Figure 7 is a plan view showing a portion of the structure of the collector shoe illustrated in Figure 6;
  • Figure 8 is a side elevational view showing a portion of the structure of the power collector shoe illustrated in Figure 6;
  • Figure 9 is an exploded perspective view showing a portion of the structure of the collector shoe illustrated in Figure 6;
  • Figure 10 is a schematic view of the collector shoe illustrated in Figure 6, wherein the carriage is in an initial position;
  • Figure 11 is another schematic view of the collector shoe illustrated in Figure 6, wherein the carriage slides to an initial position
  • FIG. 12 is a cross-sectional view of a charging knife assembly of a power collector shoe according to an embodiment of the present application
  • Figure 13 is a cross-sectional view showing a partial structure of a power collector shoe according to an embodiment of the present application.
  • Figure 14 is a front elevational view of a charging knife in accordance with an embodiment of the present application.
  • FIG. 15 is a side view of a charging knife in accordance with an embodiment of the present application.
  • FIG. 16 is a top plan view of a charging blade in accordance with an embodiment of the present application.
  • FIG. 17 is a partial plan view of a charging rail in accordance with an embodiment of the present application.
  • Figure 18 is a cross-sectional view of a charging rail in accordance with an embodiment of the present application.
  • FIG. 19 is a perspective view of a partial structure of a rail transit system according to an embodiment of the present application.
  • 20 is a side view of a partial structure of a rail transit system according to an embodiment of the present application.
  • 21 is a schematic diagram showing a partial structure of a rail transit system according to an embodiment of the present application.
  • 22 is a schematic structural view of a rail vehicle according to an embodiment of the present application.
  • FIG. 23 is a schematic structural view of a rail transit system according to an embodiment of the present application.
  • 100 collector shoe; 200: insulating seat; 300: charging rail; 400: insulator;
  • 10a bracket; 10b: carriage; 101: through hole; 102: support; 1021: bump; 103: accommodating groove;
  • 21 connecting rod; 22: limiting piece; 23: limiting part; 24: line nose; 211: stop boss;
  • 611 first outer side plate; 601: first groove; 612: second outer side plate; 602: second groove; 621: first inner side plate; 622: second inner side plate; 65: anti-scratch inner hook; 66: drain hole;
  • 71 insulating bracket; 710: mounting groove; 72: insulating compact;
  • 800 rail vehicle; 810: car body; 820: power storage device;
  • 900 rail transit system
  • 910 power supply device
  • 920 track.
  • connection In the description of the present application, it should be noted that the terms “installation”, “connected”, and “connected” are to be understood broadly, and may be fixed or detachable, for example, unless otherwise specifically defined and defined. Connected, or integrally connected; can be mechanical or electrical; can be directly connected, or indirectly connected through an intermediate medium, can be the internal communication of the two components.
  • Connected, or integrally connected can be mechanical or electrical; can be directly connected, or indirectly connected through an intermediate medium, can be the internal communication of the two components.
  • the specific meanings of the above terms in the present application can be understood in the specific circumstances for those skilled in the art.
  • Modern electric locomotives generally use flexible contact nets or third-rail rigid power supply systems for on-board power supply.
  • the supercapacitor energy storage system that uses station charging can not only beautify the landscape along the line, but also save A large cost of building a car-mounted power supply system.
  • the railway vehicle is provided with a collector shoe, and the suspension type charging rail is used to charge the power storage device of the rail vehicle in the station area.
  • the weight of the hanging charging rail is large, the installation difficulty is high, and the anti-rolling arc system is not provided, and the arcing phenomenon is easy to occur in the station area when the power is turned off, and the safety is poor.
  • the adaptability of the collector shoe and the charging rail is poor, especially for the limited offset adaptability generated after the tire is blown, and the file is easily generated. Track accident.
  • the sipe charging system applied to the automobile adopts the two-way bearing translation technology to adapt to the small range of swing that may occur in the automobile. Due to the indeterminate characteristics of the road driving route and the active adaptation function of the sipe, the structure of the charging knife device is complicated.
  • the various control systems included increase the manufacturing cost, and the two-drive motors for translation and stripping also increase the weight of the device and are not suitable for use on rail vehicles.
  • the existing sipe charging system is a single-sided planar contact method of the upper and lower sides, and the flow receiving area is limited, and the charging stability and safety are poor.
  • the present application proposes a charging knife 20, a charging knife assembly (2) and a rail transit system 900.
  • the power collector shoe 100 for a rail vehicle 800 includes a bracket 10a, a charging blade assembly 2, and a cushioning member 3.
  • the bracket 10a can be connected to the rail vehicle 800 to mount the collector shoe 100 on the vehicle body 810 of the rail vehicle 800.
  • the bracket 10a can be an insulating member to reduce the influence of the bracket 10a on the charging process and improve the charging stability.
  • the charging blade assembly 2 is movably coupled to the bracket 10a in a direction approaching and away from the bracket 10a (ie, in the up and down direction shown) to charge the charging knife assembly 2 and When the rail 300 comes into contact, the charging blade assembly 2 can avoid a serious collision with the charging rail 300 by its own movement.
  • the cushioning member 3 can be respectively connected to the bracket 10a and the charging blade assembly 2 to provide cushioning to the charging blade assembly 2, so that the charging blade assembly 2 can be flexibly moved when it is in contact with the charging rail 300, and can be in the charging knife assembly. 2 Provide buffering during charging contact with the charging rail 300 to slow down the collision.
  • the cushioning member 3 may be an elastic member.
  • the cushioning member 3 may be a spring as illustrated; or the cushioning member 3 may also be an automatically controllable electric push rod (not shown) or automatically controllable. Cylinder (not shown).
  • the cushioning member 3 can be deformed when subjected to a force, and at the same time, a damping force that hinders the relative displacement between the charging blade assembly 2 and the bracket 10a can be provided, which is not only simple and compact in structure, but also easy to disassemble and has a good cushioning effect.
  • the "automatically controllable electric push rod” refers to an electric push rod having an active control function
  • the “automatically controllable air cylinder” refers to an air cylinder having an active control function.
  • the charging blade assembly 2 can be buffered by the cushioning member 3, so that the charging blade assembly 2 can be subjected to its own force.
  • the situation is adaptively moved in the direction of approaching and away from the bracket 10a, and the collision between the charging knife assembly 2 and the charging rail 300 can be slowed down, and the buffering effect is good, thereby reducing the probability of damage of the charging knife assembly 2 due to a violent collision.
  • Extending the service life of the collector shoe 100 and the charging rail 300 greatly simplifies the structure and reduces the assembly difficulty and cost compared to the oscillating collector shoe 100 of the related art.
  • the charging blade assembly 2 includes a link 21 and a charging blade 20.
  • one end of the link 21 may be connected to the rail vehicle 800, and the charging blade 20 is the above-described charging blade 20, and the charging blade 20 is connected to one end of the link 21 remote from the rail vehicle 800.
  • the charging blade 20 can be conveniently and reliably connected to the rail vehicle 800 through the connecting rod 21, and the charging blade 20 can be charged by the first flow receiving surface 201 and the second flow receiving surface 202.
  • the rail 300 is in contact, the double-sided flow is realized, the flow receiving area is increased, the flow receiving state can be optimized, and the distance between the first flow receiving surface 201 and the second flow receiving surface 202 is changed to ensure the charging knife 20 and charging.
  • the rail 300 has a certain contact pressure between the rails 300, which can improve the contact stability, thereby effectively improving the flow stability, reducing the probability of sparking, and improving safety.
  • the charging knife assembly 2 is relatively movable relative to the rail vehicle 800 in a direction perpendicular to the rail vehicle 800.
  • the bracket 10a may be provided with a through hole 101, and one end of the link 21 (for example, the upper end shown) is movably extended into the through hole 101, and the charging blade 20 may be coupled to the other end of the link 21 ( That is, the lower end of the figure is connected.
  • the charging blade 20 can be brought into contact with the charging rail 300, and the cushioning member 3 can be connected to the bracket 10a and the link 21.
  • the link 21 can be moved in the up and down direction in the through hole 101, in the process, the charging blade 20 can be connected.
  • the rod 21 is moved in the up and down direction, and the cushioning member 3 is connected to the bracket 10a and the link 21, respectively, to provide cushioning for the charging blade 20 to slow the collision between the charging blade 20 and the charging rail 300.
  • the cushioning member 3 may be an elastic member, for example, the cushioning member 3 may be a spring.
  • the cushioning member 3 can be sleeved on the outer peripheral surface of the connecting rod 21.
  • the occupying space of the cushioning member 3 can be reduced, and the structural layout can be optimized.
  • the cushioning member 3 can be used to provide a stable and uniform cushioning force and a buffering effect. Further improvement.
  • the link 21 may have a stop boss 211 against which the cushioning member 3 can be restrained.
  • the cushioning member 3 is first sleeved on the connecting rod 21, and one end of the connecting rod 21 (for example, the upper end shown) is inserted into the through hole 101 of the bracket 10a, so that one end of the cushioning member 3 is stopped.
  • the other end i.e., the lower end shown
  • the stop boss 211 is abutted against the stop boss 211, so that assembly and positioning can be achieved, assembly difficulty is low, and assembly efficiency can be improved.
  • the stop boss 211 may be an annular boss, that is, the stop boss 211 may be configured to surround the circumferential closed loop shape of the link 21. Therefore, the stopper boss 211 can stop the buffer member 3 over the entire circumference, the stopper effect is good, the stopper failure can be avoided, and the stability and the cushioning reliability can be effectively improved.
  • the structure of the present application is not limited thereto, and the stop bosses 211 may also be a plurality of intervals arranged along the circumferential direction of the link 21, which is not to be construed as limiting the present application.
  • a plurality can be understood as at least two, for example, three, four or five, so that the cushioning member 3 is stably stopped against the stopper boss 211.
  • the distal end of the connecting rod 21 remote from the charging blade 20 may be mounted with a limiting member 22 that moves with the connecting rod 21, and is limited to
  • the bit member 22 is located on the side of the bracket 10a that faces away from the charging blade 20 (for example, the upper side of the drawing).
  • the stopper 22 abuts against the upper side of the bracket 10a to restrict the link 21 from continuing downward, so that the link 21 can be prevented from The through hole 101 is disengaged; and when the link 21 is moved upward, the stopper 22 can move upward in synchronization with the link 21. In this way, not only is the structure simple and compact, but the cushioning stability can be further improved.
  • the limiting member 22 may be a limiting pin that is disposed on the connecting rod 21; or, as shown in FIG. 1 to FIG. 3, the limiting member 22 may be a threaded engagement with the end of the connecting rod 21
  • the bit nut has convenient disassembly and assembly, good stability and low cost.
  • a support portion 4 may be connected to the bracket 10a.
  • the support portion 4 includes: a support rod 41 and a collar 42, and the collar 42 and the bracket 10a are at the connecting rod 21.
  • the extending direction (for example, in the up and down direction of the drawing) is spaced apart, and the collar 42 may be located on a side of the bracket 10a adjacent to the charging blade 20 (ie, the lower side of the illustration), wherein the link 21 is movable Nested inside the collar 42.
  • one end (for example, the illustrated upper end) of the support rod 41 may be coupled to the bracket 10a, the support rod 41 extends in a direction away from the bracket 10a (ie, downward), and the collar 42 may be coupled to the other end of the support rod 41 ( That is, the lower end of the figure is connected, wherein the link 21 is movably nested within the collar 42.
  • the collar 42 can be supported and fixed on the bracket 10a by the support rod 41, and the collar 42 is spaced apart from the bracket 10a.
  • the link 21 can be moved within the collar 42 and the through hole 101, and is connected to the bracket 10a by being disposed.
  • the collar 42 can improve the smoothness of the movement of the connecting rod 21, and at the same time, the collar 42 can also provide guiding for the connecting rod 21, so as to avoid the phenomenon that the connecting rod 21 can not move in the through hole 101 due to the deviation. Can effectively improve reliability.
  • the support rods 41 may include at least two spaced apart around the collar 42 .
  • the support rods 41 may be two illustrated, or the support rods 41 may be three or four.
  • the support rod 41 can be inclined toward the collar 42 in a direction away from the bracket 10a (for example, in the downward direction shown), and the other end of the support rod 41 (ie, the lower end shown) can be engaged with the collar
  • the outer peripheral faces of 42 are connected.
  • the plurality of support bars 41 can provide support for the collar 42 in the circumferential direction, which can improve the stability and reliability of the collar 42, and facilitate the telescopic movement of the link 21.
  • a limiting portion 23 may be disposed between the connecting rod 21 and the collar 42 for limiting.
  • the limiting portion 23 may be a rectangular key, and the outer peripheral surface of the connecting rod 21 may be provided with a mounting key groove, and the inner peripheral surface of the collar 42 may be provided with a through key groove, and the rectangular key is installed at In the installation keyway, when the connecting rod 21 moves, the rectangular key is driven to move vertically in the through keyway, so that the connecting rod 21 can be vertically moved, and the connecting rod 21 is restricted to rotate around its axial direction, thereby avoiding the charging knife. Assembly 2 rotates to improve reliability.
  • the collector shoe 100 may include a sliding seat assembly 1, a carriage 10b, a charging blade assembly 2, and a resilient returning structure 5.
  • the sliding seat assembly 1 is adapted to be coupled to a vehicle body 810 of a rail vehicle 800, and the carriage 10b is slidably coupled to the sliding seat assembly 1 in a lateral direction, that is, the carriage 10b is coupled to the sliding seat assembly 1 and The carriage 10b is slidable relative to the carriage 10b assembly in the lateral direction.
  • “longitudinal” as used in the present application can be understood as a direction parallel to the traveling direction of the rail vehicle 800
  • lateral can be understood as a direction perpendicular to the traveling direction of the rail vehicle 800
  • “vertical” can be It is understood to be the height direction of the rail vehicle 800.
  • the front-rear direction is the longitudinal direction
  • the left-right direction is the horizontal direction
  • the up-and-down direction is the vertical direction.
  • the charging knife assembly 2 is coupled to the carriage 10b so that when the carriage 10b slides relative to the sliding seat assembly 1, the charging blade 20 is slid by the carriage 10b, so that the charging blade assembly 2 can be assembled with respect to the carriage 10b.
  • Moving in the lateral direction allows the charging blade assembly 2 to move in the width direction of the vehicle body 810 with respect to the rail vehicle 800. Thereby, the influence of the file or the rail caused by the deviation of the vehicle body 810 can be effectively alleviated, and the charging stability can be improved.
  • the elastic returning structure 5 is connectable to the carriage 10b and the sliding seat assembly 1, respectively, and the elastic returning structure 5 often drives the carriage 10b to return to the initial position.
  • the elastic returning structure 5 always drives the carriage 10b to move to the initial position, that is, the elastic returning structure 5 always supplies the driving force to the carriage 10b, and the carriage 10b is reset to the initial position.
  • the so-called "initial position” generally means that the optimal position for docking with the charging rail 300 is determined according to the design, but the installation position of the charging rail 300 is changed due to the mounting accuracy and the like.
  • the charging blade assembly 2 is adaptively movable in the lateral direction with respect to the sliding seat assembly 1, and the elastic returning structure 5 always drives the carriage 10b to move to the initial position.
  • the charging knife assembly 2 tends to be offset with respect to the charging rail 300.
  • the carriage 10b slides relative to the sliding seat assembly 1 to make the charging knife assembly 2 Moving in the lateral direction relative to the sliding seat assembly 1, so that the charging blade assembly 2 and the charging rail 300 form a better fit to accommodate the offset of the vehicle body 810; at the same time, the elastic reset structure 5 drives the carriage 10b Move to the initial position.
  • the carriage 10b is reset to the initial position under the driving of the elastic return structure 5, and the charging blade assembly 2 can also form a better fit with the charging rail 300.
  • the charging blade assembly 2 can be adapted to the offset of the vehicle body 810 by the sliding of the carriage 10b with respect to the sliding seat assembly 1 in the lateral direction, and the elastic reset structure 5 can be used to drive the carriage 10b to the initial position. Therefore, the offset of the charging blade assembly 2 can be compensated when the vehicle body 810 is displaced, and the charging blade assembly 2 can be restored to the normal position when the vehicle body 810 is not displaced, thereby enabling the charging blade assembly.
  • the structure is simpler, not only under the extreme conditions of the vehicle body 810 offset excessively and after the tire bursting It can still be used normally, reducing the probability of causing a sickle or rail accident and improving the charging stability.
  • the sliding seat assembly 1 may be formed with a sliding groove 11 extending in the lateral direction, and the sliding frame 10b is slidably engaged with the sliding groove 11 in the lateral direction. That is, the carriage 10b slides along the chute 11 on the slide base assembly 1.
  • the structure is simple, easy to process, and easy to assemble.
  • one side of the chute 11 in the vertical direction (for example, the up and down direction shown) is open to form an open side, and the vertical direction is perpendicular to the lateral direction, perpendicular to In the transverse section, the inner side of the chute 11 is gradually contracted in the direction toward the open side of the chute 11, and the side of the carriage 10b may have a shape adapted to the inner side of the chute 11.
  • the carriage 10b can be slid in the lateral direction in the chute 11, and the carriage 10b can be prevented from being disengaged from the chute 11 in the vertical direction, and the stability is good and the reliability is high.
  • the chute 11 can be open downward. That is, the sliding seat assembly 1 is formed with a chute 11 extending in the lateral direction and opening downward in the vertical direction, and the chute 11 is configured as a structure which is tapered downward in the vertical direction, and the carriage 10b is configured to be slippery
  • the slot 11 is adapted to a downwardly constricted configuration, the carriage 10b is adapted to fit within the chute 11 and the slider can slide laterally along the chute 11.
  • the shape of the chute 11 can be prevented to prevent the carriage 10b from coming off the chute 11 due to its own gravity, and the structure is simple and the design is ingenious.
  • the chute 11 may be formed as a trapezoidal groove having a beveled inner side surface, and a cross section perpendicular to the lateral direction of the carriage 10b is formed in a trapezoid shape engageable with the trapezoidal groove.
  • the chute 11 and the carriage 10b may also be formed to fit other shapes.
  • the inner side surface of the chute 11 forms a cylindrical surface
  • the side surface of the carriage 10b forms a cylindrical surface. In this regard, it is not to be construed as limiting the present application.
  • At least one of the inner side surface of the chute 11 and the side surface of the carriage 10b may be provided with an oil storage tank 12, and the lubricating oil tank 12 may store lubricating oil. Or grease, etc.
  • the oil reservoir 12 is formed on the side of the carriage 10b as shown in FIG. 9; alternatively, the oil reservoir 12 may be formed on the inner side of the chute 11; or, on the carriage 10b and inside the chute 11 An oil reservoir 12 can be provided on the side.
  • the carriage 10b is provided with a support 102
  • the elastic return structure 5 may include two elastic members 51, and the two elastic members 51 are distributed on the support 102.
  • the two sides are opposite to each other in the lateral direction, and the elastic member 51 is connectable to the holder 102 and the slider assembly 1.
  • the upper surface of the carriage 10b is provided with a support 102.
  • the two elastic members 51 are respectively connected to the left and right sides of the support 102, and the two elastic members 51 respectively The sliding seat assembly 1 is connected.
  • the two elastic members 51 can elastically connect the carriage 10b and the sliding seat assembly 1 on both sides, so that the elastic deformation of the elastic member 51 allows the carriage 10b to slide in the sliding groove 11, and the elastic member 51
  • the restored state can often drive the carriage 10b to return to the initial position, the structure is simple and compact, the assembly is convenient and fast, and the drive is stable and reliable.
  • the elastic member 51 may be a spring
  • the carriage 10b is provided with a receiving groove 103
  • the receiving groove 103 may extend in the lateral direction, and at least a part of the elastic member 51 It can be accommodated in the accommodating groove 103.
  • the upper surface of the carriage 10b is provided with two accommodating grooves 103 with openings facing upward, and the two springs are respectively accommodated in the accommodating grooves 103. Therefore, the mounting space can be provided for the elastic member 51 through the accommodating groove 103.
  • the space layout is reasonable, and the structure can be made more compact.
  • the elastic member 51 can be limited by the accommodating groove 103 to prevent the elastic member 51 from being generated. Dislocation and failure can improve stability and reliability.
  • the elastic member 51 for the offset recovery may be replaced by other elastic members such as a rubber spring or an air spring, or may be replaced by a pneumatic system having an active control system. This is understandable to those skilled in the art and will not be described herein.
  • the support 102 may include two bumps 1021.
  • the two bumps 1021 may be laterally spaced apart, and the two bumps 1021 may be respectively located in the charging knife assembly 2 and
  • the two sides of the joint of the carriage 10b on the one hand, can provide a space for the connection of the charging blade 20 and the carriage 10b, thereby improving the space utilization rate, and on the other hand, improving the mounting stability of the elastic member 51.
  • the charging blade assembly 2 is movably connected to the carriage 10b in a vertical direction, and the vertical direction is a direction perpendicular to the lateral direction.
  • the up and down direction of the figure is Vertically, and between the charging blade 20 and the carriage 10b, a cushioning member 3 is provided, and the cushioning member 3 can be connected to the connecting rod 21 and the carriage 10b, respectively, to provide cushioning to the charging blade assembly 2.
  • the bracket 10a described above can be configured as a carriage 10b.
  • the charging blade assembly 2 can move not only in the lateral direction but also in the vertical direction. Therefore, the vehicle body 810 can be adapted to the offset of the vehicle body 810 in the width direction thereof, and the vertical collision between the charging knife assembly 2 and the charging rail 300 can be buffered.
  • the structure is simple and compact, the buffering effect is good, and the charging stability and reliability are reliable. More sexual.
  • the charging blade assembly 2 of the collector shoe 100 includes a charging blade 20, which will be described in detail below with reference to the drawings.
  • the charging blade 20 can extend in the traveling direction of the rail vehicle 800 (for example, the front-rear direction shown), and in the direction perpendicular to the traveling direction of the rail vehicle 800, the opposite of the charging blade 20.
  • the first flow receiving surface 201 and the second flow receiving surface 202 are respectively disposed on both sides. That is, the first flow receiving surface 201 and the second flow receiving surface 202 are formed on the opposite side surfaces of the charging blade 20, respectively. That is, the charging blade 20 has two flow receiving faces that are oppositely disposed.
  • the distance between the first flow receiving surface 201 and the second flow receiving surface 202 is gradually reduced by one end of the charging blade 20 near the rail vehicle 800 to an end remote from the rail vehicle 800.
  • one end of the charging blade 20 near the rail vehicle 800 is defined as a "first end”
  • one end of the charging blade 20 away from the rail vehicle 800 is defined as a "second end”.
  • the "first end” can be understood as the upper end of the charging blade 20, and the “second end” can be understood as the lower end of the charging blade 20.
  • the interval between the first flow receiving surface 201 and the second flow receiving surface 202 gradually decreases from the upper end to the lower end.
  • the spacing between the first flow receiving surface 201 and the second flow receiving surface 202 may also gradually decrease from the lower end to the upper end.
  • the first flow receiving surface 201 and the second flow receiving surface 202 can be contacted with the charging rail 300, the double-sided flow can be realized, the flow receiving area can be increased, the flow receiving state can be optimized, and the first flow receiving surface 201 can be optimized.
  • the change in the distance between the second flow receiving surface 202 and the second charging surface 202 can ensure a certain contact pressure between the charging blade 20 and the charging rail 300.
  • the charging blade 20 can be improved.
  • the contact stability with the charging rail 300 can effectively improve the flow stability, reduce the probability of sparking, and improve safety.
  • one of the first flow receiving surface 201 and the second flow receiving surface 202 may extend vertically, and the other of them extends obliquely with respect to the vertical direction; or, the first flow receiving surface 201 And the second flow receiving surface 202 extend obliquely in a direction toward each other. Therefore, the first flow receiving surface 201 and the second flow receiving surface 202 of the charging blade 20 can be configured in different shapes to fit the charging rails 300 of different configurations, and the structure is simple and convenient for processing.
  • the charging blade 20 extends in the traveling direction of the rail vehicle 800, and in the vertical section, the charging blade 20 has a shape that gradually contracts from the first end edge to the second end edge.
  • the charging blade 20 in the example shown in Fig. 15, in the direction away from the carriage 10b (i.e., the bracket 10a), the charging blade 20 is gradually contracted to the shape of the edge of the charging blade 20, that is, the charging blade 20 is gradually tapered from the upper edge. Shrink to the lower edge.
  • the two laterally opposite side faces of the charging blade 20 can be configured as the first flow receiving surface 201 and the second flow receiving surface 202, respectively, and the flow receiving area is larger, and the stability and reliability are better.
  • the cross-sectional area of the charging blade 20 is gradually reduced from the middle to the both ends of the charging blade 20 in the traveling direction of the rail vehicle 800. It should be noted that at least one of the two end portions of the charging blade 20 may be in a shape that gradually contracts to the edge of the charging blade 20 in the traveling direction of the rail vehicle 800. As shown in FIG. 16, at least one of the two end portions of the charging blade 20 in the front-rear direction may be in a shape that gradually contracts to the edge of the charging blade 20 in the front-rear direction. For example, in the example illustrated in FIG.
  • the cross-sectional area of the front end of the charging blade 20 is gradually decreased forward, and the cross-sectional area of the rear end of the charging blade 20 is gradually decreased backward, that is, the charging blade 20 is configured as a two-way wedge shape.
  • the double side contacts the current collection.
  • the "two-way wedge shape" means that the charging blade 20 gradually changes from wide to narrow from the first end to the second end as viewed from the side view, and has a structure in which the width is gradually changed from the first end to the second end, and the both ends are gradually changed.
  • the structure of the present application is not limited thereto, and the charging blade 20 may also be configured in such a manner that the end of the one end in contact with the charging rail 300 gradually decreases toward the end surface.
  • the end of the charging blade 20 first contacts the charging rail 300, and by designing the charging blade 20 to gradually decrease toward the end in the longitudinal direction, a guiding function can be provided to facilitate the charging knife 20 Smooth contact and cooperation with the charging rail 300 can not only reduce the collision, reduce the wear, but also improve the matching precision, thereby improving the charging stability.
  • the charging blade 20 may be provided with a receiving groove 203 adapted to mount the wire nose 24, and the receiving groove 203 may be provided at one end of the charging blade 20 near the rail vehicle 800.
  • the receiving groove 203 may extend in the vertical direction to the end face of the charging blade 20 near the rail vehicle 800.
  • the receiving groove 203 can communicate with the first flow receiving surface 201 and the second flow receiving surface 202 in a traveling direction perpendicular to the rail vehicle 800, that is, the receiving groove 203 can penetrate the first flow receiving surface 201 and the first direction in the lateral direction.
  • the second receiving surface 202 For example, as shown in FIGS.
  • the upper end of the charging blade 20 is provided with a receiving groove 203 which is configured to extend vertically to the upper end surface of the charging blade 20 and to extend to both ends in the left-right direction to
  • the three flow opening faces 201 and the three flow opening faces of the second flow receiving surface 202 are installed in the receiving groove 203. In this way, not only is it easy to manufacture and manufacture, but also the installation and positioning of the wire nose 24 is facilitated, the type is more compact, the flow stability is good, the reliability is high, and the assembly efficiency is high.
  • the rail vehicle 800 includes a vehicle body 810 and the above-described power collector shoe 100 according to the embodiment of the first aspect of the present application.
  • the vehicle body 810 may be provided with an insulating seat 200, and the vehicle body 810 has a power storage device.
  • Device 820, collector shoe 100 can be relatively fixedly coupled to insulative housing 200, and collector shoe 100 is electrically coupled to power storage device 820.
  • the collector shoe 100 may be mounted on the bottom of the vehicle body 810.
  • the collector shoe 100 and the charging rail 300 are in the side contact type of the upper contact type contact body.
  • the structure of the present application is not limited thereto, and the collector shoe 100 may also be in other forms such as side mounting or inverted mounting, which will be understood by those skilled in the art, and therefore will not be described in detail herein.
  • the charging knife 20 can be provided with a buffer by the cushioning member 3, so that the charging knife assembly 2 can be subjected to the force according to itself.
  • the situation is adaptively moved vertically so that the collision between the charging blade 20 and the charging rail 300 can be buffered.
  • the elastic resetting structure 5 can be used to constantly drive the carriage 10b to return to the initial position, thereby The offset of the charging blade assembly 2 can be compensated when the vehicle body 810 is offset, and the charging blade assembly 2 can be reset to the normal position when the vehicle body 810 is not displaced, thereby reducing the offset due to the body 810.
  • the impact of the sickle or the rail can be used to constantly drive the carriage 10b to return to the initial position, thereby The offset of the charging blade assembly 2 can be compensated when the vehicle body 810 is offset, and the charging blade assembly 2 can be reset to the normal position when the vehicle body 810 is not displaced, thereby reducing the offset due to the body 810. The impact of the sickle or the rail.
  • the first flow receiving surface 201 and the second flow receiving surface 202 of the charging blade 20 are in contact with the charging rail 300, so that the double-sided flow can be realized, the flow receiving area is increased, and the first flow receiving surface 201 and the second receiving surface are
  • the change of the spacing between the flow surfaces 202 can make the charging knife 20 and the charging rail 300 have a certain contact pressure, and the flow stability is good, the probability of occurrence of electric spark can be reduced, the safety is high, and the state of the flow can be optimized.
  • a rail transit system 900 includes: a power supply device 910, a track, a charging rail 300, and a rail vehicle 800, which may be the rail vehicle 800 described above in accordance with an embodiment of the second aspect of the present application.
  • the power supply device 910 may be disposed in the platform area of the rail vehicle 800, and the rail 920 may include a rail beam extending in the traveling direction of the rail vehicle 800, and the traveling direction of the vehicle is the longitudinal direction of the vehicle, that is, the longitudinal direction described above.
  • the charging rail 300 has a charging slot 6 extending along the traveling direction of the rail vehicle 800.
  • the charging rail 300 is electrically connected to the power supply device 910.
  • the rail vehicle 800 sits on the rail beam, and the charging knife assembly 2 is adapted to be clutched along the charging slot. 6 slides.
  • the term “coupable connection” means that the charging blade assembly 2 can be in contact with the charging slot 6 or separated from the charging slot 6.
  • the charging knife assembly 2 and the power supply unit 910, the charging rail 300, the collector shoe 100, and the power storage device 820 are adapted to constitute a charging circuit for charging the power storage device 820.
  • the rail transit system 900 of the embodiment of the present application by providing the rail vehicle 800 according to the embodiment of the second aspect of the present application, the collision between the charging blade 20 and the charging rail 300 can be buffered, and the file caused by the deviation of the vehicle body 810 can be reduced. Or the influence of the rails reduces the probability of damage to the charging blade 20 and the charging rail 300, and can prolong the service life. Moreover, the double-sided flow can be realized, the flow stability and safety are improved, and the flow state is optimized.
  • the charging rail 300 is also optimized.
  • the charging rail 300 may have a charging slot 6 extending in the longitudinal direction (ie, the traveling direction of the rail vehicle 800), and the two laterally opposite surfaces of the charging slot 6 respectively form a first supply surface. 61 and a second supply surface 62. That is to say, the charging tank 6 has two supply surfaces that are oppositely disposed.
  • the spacing between the first supply surface 61 and the second supply surface 62 gradually decreases from the first end to the second end.
  • the spacing between the first supply surface 61 and the second supply surface 62 gradually decreases from the upper end to the lower end.
  • the spacing between the first supply surface 61 and the second supply surface 62 may also gradually decrease from the lower end to the upper end.
  • the first supply surface 61 and the second supply surface 62 of the charging rail 300 can be contacted with the charging blade 20 of the rail vehicle 800 to realize double-sided supply flow, which can increase the supply area, and the first supply
  • the variation of the spacing between the flow surface 61 and the second supply surface 62 can ensure a certain contact pressure between the charging blade 20 and the charging slot 6, and can improve the contact stability between the charging rail 300 and the charging blade 20, thereby improving Charging stability can reduce the probability of sparks and improve safety.
  • the charging slot 6 may be an elastic slot.
  • the charging groove 6 when the charging groove 6 is subjected to a force, it has a characteristic of elastic deformation, and when the external force is released, it can be restored to its original state. Therefore, when the charging blade 20 is in contact with the charging rail 300, the charging blade 20 is fitted into the charging slot 6. At this time, the charging groove 6 can be elastically deformed, so that the charging blade 20 can be formed by the elastic restoring force. By clamping the force, the contact pressure is supplied from the lateral sides to the charging blade 20, which can further improve the flow stability of the charging contact surface and optimize the flow quality.
  • the charging rail 300 may include: a first outer side plate 611 and a second outer side plate 612 that are laterally opposed, and first and second inner side plates 621 and 221 that are laterally opposed Inner side plate 622.
  • first end of the first outer side plate 611 eg, the illustrated upper end
  • the first end of the first outer side plate 611 may be spaced apart from the first end of the second outer side plate 612 (ie, the upper end of the illustration), and the second side of the first outer side plate 611 The end (ie, the lower end of the illustration) is coupled to the second end of the second outer side panel 612 (ie, the lower end of the illustration).
  • the first inner side plate 621 and the second inner side plate 622 are located between the first outer side plate 611 and the second outer side plate 612, the first end of the first inner side plate 621 is connected to the first end of the first outer side plate 611, and the second inner side The first end of the plate 622 is coupled to the first end of the second outer side plate 612, and the first inner side plate 621 and the second inner side plate 622 extend obliquely toward each other.
  • the opposing surfaces of the first inner side plate 621 and the second inner side plate 622 respectively form a first current supply surface 61 and a second current supply surface 62.
  • the charging rail 300 can be designed as a hollow "shell” type, and the charging rail 300 can be configured as a semi-rigid charging rail 300, which can not only reduce the self-weight of the charging rail 300, but also optimize the structure, facilitate processing and manufacturing, and can reduce cost.
  • the semi-rigid charging rail 300 can generate a certain elastic deformation, thereby providing a contact pressure by utilizing its own elastic return "clamping" force to ensure stable flow of the charging contact surface.
  • first outer side plate 611 may be recessed toward the second outer side plate 612 to form a first recess 601, and a portion of the second outer side plate 612 may face the first outer side plate 611.
  • the recesses are formed to form a second recess 602.
  • the first groove 601 and the second groove 602 may be oppositely disposed.
  • the strength of the first side panel and the second side panel can be enhanced, so that the strength of the charging rail 300 can be improved, and the first recess 601 and the second recess Slot 602 may also facilitate installation and positioning of charging rail 300, as will be described in detail below in connection with specific embodiments.
  • the second end of the first inner side panel 621 and the second end of the second inner side panel 622 may be bent away from each other.
  • the lower end of the first inner side plate 621 is bent away from the second inner side plate 622, and the lower end of the second inner side plate 622 is bent away from the first inner side plate 621.
  • the free ends of the first inner side plate 621 and the second inner side plate 622 can be respectively bent to form inner hooks, and on the other hand, it is advantageous to form a smooth first supply surface 61 and second supply surface 62 such that the charging rail 300
  • the structure is more compact, and the charging knife 20 is matched with the charging slot 6.
  • the charging knife 20 and the charging rail 300 can be effectively prevented from being scraped, that is, the anti-scratch inner hook 65 is formed, which reduces wear and reduces noise. It also reduces the appearance of sparks.
  • the second end of the first inner side plate 621 and the first recess 601 may be spaced apart in the vertical direction, and the second end of the second inner side plate 622 may be opposite to the second recess 602. They can be spaced apart in the vertical direction.
  • the free end of the first inner side plate 621 is spaced apart from the first groove 601
  • the free end of the second inner side plate 622 is spaced apart from the second groove 602.
  • the charging blade 20 When the charging blade 20 is in contact with the charging slot 6, the charging blade 20 is in contact with the first inner plate 621 and the second inner plate 622, respectively, by spacing the second segment of the first inner plate 621 from the first groove 601, and The second end of the second inner side plate 622 is spaced apart from the second recess 602 to provide space for the deformation of the first inner side plate 621 and the second inner side plate 622 to avoid interference, and the elastic characteristics of the charging rail 300 can be made. Effectively play, it is conducive to achieving stable flow.
  • the charging rail 300 can be a symmetrical structure.
  • the charging rail 300 may be an integrally formed metal member, that is, the first outer side plate 611, the second outer side plate 612, the first inner side plate 621, and the second inner side plate 622 may be integrally processed. forming.
  • the charging rail 300 may be formed by folding a thin metal piece.
  • the metal member has superior rigidity and toughness, and the shape of the charging rail 300 can make the charging rail 300 have a certain rigidity, and the charging rail 300 can exert better elastic characteristics, thereby achieving an effect of one plus one and two. To make the flow quality and charging stability better.
  • the charging rail 300 may be provided with a drain hole 66 communicating with the charging tank 6.
  • the drain hole 66 may be provided at the lowest surface in the direction of gravity after the charging rail 300 is installed.
  • At least one end of the charging rail 300 in the longitudinal direction may be provided with a guiding section 63 having a guiding groove 64 communicating with the charging groove 6, the guiding groove 64
  • the laterally opposite surfaces are gradually expanded in a direction away from the charging slot 6.
  • one or both ends of the charging rail 300 are provided with a guiding section 63 having a guiding groove 64 which communicates with the charging groove 6, and the lateral dimension of the guiding groove 64 is The direction gradually increases away from the charging slot 6.
  • the charging blade 20 moves synchronously with the vehicle body 810, and when the rail vehicle 800 travels to the station area for charging, the charging blade 20 is moved from one end into the charging slot 6, and is in contact with the charging rail 300.
  • the guiding section 63 is disposed at the end of the charging rail 300, so that the charging blade 20 can be moved into the guiding slot 64 first, and then moved into the charging slot 6. Since the guiding slot 64 is configured to be tapered away from the charging slot 6, the guiding slot 64 can be The charging knife 20 is provided with a guiding function so that the charging blade 20 can smoothly transition from the no-charging rail 300 zone to the charging rail 300 zone. In this way, the charging knife 20 can be prevented from colliding with the charging rail 300, the probability of damage can be reduced, and the service life can be prolonged.
  • the guiding section 63 constitutes a bifurcated guiding belt, and the contact force between the charging blade 20 and the contact surface of the charging rail 300 gradually increases as the charging blade 20 slides into the charging rail 300 due to the side branching. There is a tendency that the contact force between the charging blade 20 and the contact surface of the charging rail 300 gradually decreases as the charging blade 20 slides out of the charging rail 300. Under the combined action of the contact force and the cushioning member 3, the charging blade assembly 2 moves vertically toward the bracket 10a when the rail vehicle 800 is pitted, and moves away from the bracket 10a when the rail vehicle 800 is out of position.
  • the charging circuit is connected, and the charging circuit is disconnected when the outbound displacement dynamic is satisfied, thereby achieving the “post-touch path, taking off the front”.
  • the purpose of the "breaking” can reduce the occurrence of arcing that may occur when the collector shoe 100 and the charging rail 300 are in contact or disengaged.
  • the “post-contact path, the break-off circuit” means that the collector shoe 100 is in contact with the charging rail 300 and then the charging circuit is turned on, and the charging circuit is disconnected before the collector shoe 100 and the charging rail 300 are about to be disengaged. .
  • the first current receiving surface 201 of the charging blade 20 can be in contact with the first current supply surface 61 of the charging slot 6, and the second flow receiving surface 202 of the charging blade 20 can be The second supply surface 62 of the charging tank 6 is in contact. That is, the charging blade 20 is in contact with the charging groove 6 on both sides. That is, the charging blade 20 and the charging slot 6 are charged by the double-side collecting method, and the upper and lower single-sided contact collecting methods adopted in the prior art are not only simple and compact in structure, but also have high flow reliability and good stability. .
  • the charging blade 20 is interference-fitted with the charging slot 6.
  • the spacing between the first supply surface 61 and the second supply surface 62 of the charging slot 6 is smaller than the corresponding positions of the first flow receiving surface 201 and the second flow receiving surface 202 of the charging blade 20.
  • the angle formed between the first flow receiving surface 201 and the second flow receiving surface 202 of the charging blade 20 is not less than that formed between the first supply surface 61 and the second supply surface 62 in the free state of the charging rail 300. The angle of the.
  • the rail transit system 900 may further include: a detecting device and a controller, wherein the detecting device is configured to detect relative position information of the charging blade 20 and the charging slot 6, and the controller may respectively be connected to the detecting device and the power supply The device 910 is connected, and the controller can control the power supply device 910 according to the relative position information detected by the detecting device to energize when the charging blade 20 is in contact with the charging slot 6, and is powered off when the charging blade 20 is separated from the charging slot 6.
  • the controller controls whether the power supply device 910 supplies power according to whether the charging blade 20 and the charging slot 6 are in contact.
  • the controller controls the power supply device 910 not to supply power until the detecting device detects that the charging blade 20 is in contact with the charging slot 6, and controls the power supply device 910 to be energized to make the charging circuit Turning on, charging the power storage device 820; and when the detecting device detects that the charging blade 20 and the charging slot 6 are about to be separated, the control device controls the power supply device 910 to stop supplying power, disconnects the charging circuit, and stops charging the power storage device 820.
  • the "contact path, the break-off" can be realized according to the relative position of the charging blade 20 and the charging groove 6, so that the arcing phenomenon can be effectively prevented, and the charging safety can be further improved.
  • the detecting means may be a displacement sensor that detects the displacement between the charging blade 20 and the charging slot 6, or the detecting means may be a pressure sensor that detects the force of the charging slot 6.
  • the detecting device is not limited to the above examples, and may be replaced by other devices capable of detecting the relative positions of the charging blade 20 and the charging slot 6. Those skilled in the art may select the detecting device according to the above description. No specific limitation.
  • the rail transit system 900 can buffer the collision between the charging blade 20 and the charging rail 300, reduce the influence of the file or the rail caused by the deviation of the vehicle body 810, and reduce the charging knife 20 and charging.
  • the probability of damage to the rail 300 can extend the service life.
  • the charging rail 300 capable of double-sided supply and the charging blade 20 capable of double-sided flow, and in conjunction with the detecting device and the controller the "contact path, the disconnection of the disconnecting circuit" between the charging blade 20 and the charging slot 6 can be realized. It has the advantages of good flow stability, high reliability and high safety.
  • the rail transit system 900 includes a power supply device 910, a track 920, a charging rail 300, and a rail vehicle 800.
  • the charging rail 300 is fixed on the insulator 400, the insulator 400 is installed in the platform, and the charging rail 300 is connected to the power supply device 910 in the station.
  • the insulator 400 includes an insulating bracket 71 and an insulating compact 72.
  • the insulating bracket 71 has a mounting groove 710, and a part of the charging rail 300 is fitted in the mounting recess 710.
  • the insulating compact 72 The insulating holder 71 is fixed by bolts, wherein the insulating block 72 protrudes to the first groove 601 and the second groove 602 of the charging rail 300 and is pressed against the first groove 601 and the second groove 602. On the side, the fastening effect on the charging rail 300 is achieved.
  • the charging rail 300 can be two symmetrical parts, and the figure shows a section of the charging rail 300.
  • each part includes a scratch-resistant inner hook 65, a contact rail section, a rail top, a rail waist, and a groove bottom which are sequentially connected.
  • the section, the groove slope section, the rail seat straight section, the rail seat slope section and the rail seat bottom section are connected to the bottom sections of the two parts.
  • the rail vehicle 800 has a collector shoe 100 that is coupled to a power storage device 820 within the vehicle body 810.
  • the collector shoe 100 mainly includes a sliding seat assembly 1, a sliding frame 10b, a charging knife assembly 2, an elastic reset structure 5, and a cushioning member 3.
  • the sliding seat assembly 1 is fixedly connected to the insulating seat 200 of the vehicle body 810 by a fastener, and the sliding frame 10b and the sliding seat assembly 1 are connected by a trapezoidal groove to achieve a translational connection, and other components are directly or indirectly installed.
  • a connecting rod 21 including a charging knife assembly 2 the connecting rod 21 passes through the collar 42 and the through hole 101 in the sliding frame 10b, and the outer circumference of the connecting rod 21 is sleeved with a buffering member 3, and the connecting rod 21
  • the lower end is connected to the charging knife 20, and the upper end of the connecting rod 21 is fixed by the limiting nut, so that the cushioning member 3 has a certain amount of compression to prevent the sliding frame 10b from being detached due to the elastic force, and the connecting rod 21 and the charging knife 20 are connected by the fastener.
  • the cushioning member 3 When the charging shoe is in the free state, the cushioning member 3 is in a compressed state, so that the charging blade 20 always maintains a downward movement tendency, but remains in the original position due to the limit action of the connecting rod 21 and the limiting nut at this time.
  • the charging blade 20 is subjected to the resultant force in the direction of the connecting rod 21 due to the action of the guiding groove 64 and the inclination of the contact surface.
  • the resultant force overcomes the compressive force of the cushioning member 3, causing the link 21 to move upward until the charging blade 20 and the charging rail 300 are in stable contact.
  • 14-16 are three views of the charging blade 20. Due to the current collecting type of the side contact of the charging blade 20, in order to ensure a certain contact pressure, the knife-to-groove mating surface is inclined at a certain angle, so the charging blade 20 is specially formed into a wedge shape, and the overall shape is that the upper width is gradually narrowed downward, and the front and rear are guided. Gradually widened towards the middle.
  • the middle portion of the charging blade 20 has a receiving groove 203, and the receiving groove 203 has a size matching the size of the wire nose 24. 12 and 13 respectively illustrate the state before and after the installation of the wire nose 24, in which the wire nose 24 is inserted into the corresponding position of the receiving groove 203, and the hexagonal bolt is used to realize the stable connection of the wire nose 24 and the charging blade 20.
  • the elastic return structure 5 includes two springs symmetrically distributed, one end of each spring is pressed against the sliding seat assembly 1 and the other end acts on the support 102 of the carriage 10b, and each spring has a certain pre-preparation
  • the slewing sleeve 10b is provided with a receiving groove 103 for mounting a spring.
  • the spring is defined between the sliding seat assembly 1 and the sliding frame 10b and is received in the accommodating groove 103 to prevent the spring from jumping out. Limit function.
  • the offset compensation function is mainly realized by the sliding seat assembly 1, the carriage 10b and two springs.
  • the sliding seat assembly 1 and the sliding frame 10b are engaged by the trapezoidal groove, so that the sliding frame 10b can smoothly slide back and forth relative to the sliding seat assembly 1; two springs symmetrically arranged by pre-compression, one end of each spring acts on
  • the fixed sliding seat assembly 1 has the other end acting on the slidable carriage 10b.
  • a laterally-embedded assembly can be employed, the slide assembly 1 including extending laterally
  • the first slider seat 111 and the second slider holder 112 extend in the lateral direction, and the two are fixed by bolts.
  • a trapezoidal groove is formed between the first slider seat 111 and the second slider seat 112, and the carriage 10b is configured as a trapezoidal wedge.
  • the two springs are respectively located between the sliding seat assembly 1 and the carriage 10b and are placed on the receiving groove 103. Since both springs are in a compressed state, the position of the spring can be defined by fitting the cover of the sliding seat assembly 1 to the upper portion of the receiving groove 103.
  • the sliding contact surface of the carriage 10b is provided with an oil reservoir 12 in the sliding direction in order to maintain the lubricating effect of the sliding contact surface as much as possible and to reduce friction.

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  • Engineering & Computer Science (AREA)
  • Power Engineering (AREA)
  • Transportation (AREA)
  • Mechanical Engineering (AREA)
  • Current-Collector Devices For Electrically Propelled Vehicles (AREA)
  • Electric Propulsion And Braking For Vehicles (AREA)
  • Charge And Discharge Circuits For Batteries Or The Like (AREA)

Abstract

一种充电刀(20)、充电刀总成(2)和轨道交通系统(900),充电刀(20)沿轨道车辆(800)的行驶方向延伸,且在垂直于轨道车辆(800)的行驶方向的方向上,充电刀(20)的相对的两侧表面分别设有第一受流面(201)和第二受流面(202),由充电刀(20)的靠近轨道车辆(800)的一端至远离轨道车辆(800)的一端,第一受流面(201)和第二受流面(202)之间的间距逐渐减小。

Description

充电刀、充电刀总成和轨道交通系统
相关申请的交叉引用
本申请基于申请号为201810119219.1,申请日为2018年02月06日的中国专利申请提出,并要求该中国专利申请的优先权,该中国专利申请的全部内容在此引入本申请作为参考。
技术领域
本申请涉及轨道车辆技术领域,更具体地,涉及一种充电刀、充电刀总成和轨道交通系统。
背景技术
相关技术中的轨道车辆,有的采取站区充电。在充电时,一遍采用上下面的单面平面接触方式,受流面积有限,充电稳定性和安全性较差。
申请内容
本申请旨在至少解决现有技术中存在的技术问题之一。为此,本申请提出一种充电刀,所述充电刀可以实现双面接触受流,增加了受流面积,可以优化受流状态,提高充电稳定性和安全性。
本申请还提出了一种具有上述充电刀的充电刀总成。
本申请还提出了一种轨道交通系统,所述轨道交通系统包括上述所述的充电刀总成。
根据本申请实施例的充电刀,所述充电刀沿轨道车辆的行驶方向延伸,且在垂直于所述轨道车辆的行驶方向的方向上,所述充电刀的向相对的两侧表面分别设有第一受流面和第二受流面,由所述充电刀的靠近所述轨道车辆的一端至远离所述轨道车辆的一端,所述第一受流面和所述第二受流面之间的间距逐渐减小。
根据本申请实施例的充电刀,可以利用第一受流面和第二受流面与充电轨接触,实现双面受流,增加了受流面积,可以优化受流状态,并且,第一受流面与第二受流面之间的间距变化,能够保证充电刀与充电轨之间具有一定的接触压力,可以提高接触稳定性,从而可以有效提高受流稳定性,降低出现电火花的概率,提高了安全性。
根据本申请的一些实施例,所述第一受流面和所述第二受流面中的其中一个沿竖向延伸,且其中另一个相对于竖向倾斜延伸;或者,所述第一受流面和所述第二受流面沿朝向彼此的方向倾斜延伸。
在本申请的一些实施例中,在沿所述轨道车辆的行驶方向上,所述充电刀的横截面积由中部朝向两端逐渐减小。
根据本申请的一些实施例,所述充电刀上设有适于安装线鼻的容纳槽,所述容纳槽设在所述充电刀的靠近所述轨道车辆的一端。
根据本申请的一些实施例,所述容纳槽在竖向方向上延伸至所述充电刀的靠近所述轨道车辆的端面。
在本申请的一些实施例中,所述容纳槽在横向上连通所述第一受流面和所述第二受流面。
根据本申请的充电刀总成,所述充电刀总成包括:连杆,所述连杆的一端与所述轨道车辆相连;充电刀,所述充电刀为上述所述的充电刀,所述充电刀与所述连杆的远离所述轨道车辆的一端相连。
根据本申请的充电刀总成,充电刀可以通过连杆方便、可靠地连接至轨道车辆上,且充电刀可以利用第一受流面和第二受流面与充电轨接触,实现双面受流,增加了受流面积,可以优化受流状态,并且,第一受流面与第二受流面之间的间距变化,能够保证充电刀与充电轨之间具有一定的接触压力,可以提高接触稳定性,从而可以有效提高受流稳定性,降低出现电火花的概率,提高了安全性。
根据本申请实施例的轨道交通系统,包括:供电装置、轨道、充电轨和轨道车辆,所述轨道包括沿轨道车辆行驶方向延伸的轨道梁;所述充电轨上具有沿所述轨道车辆的行驶方向延伸的充电槽,所述充电轨与所述供电装置电连接;所述轨道车辆跨坐于所述轨道上,所述轨道车辆设有上述所述的充电刀总成,所述充电刀适于可离合地沿所述充电槽滑动。
根据本申请实施例的轨道交通系统,通过设置根据本申请上述实施例的轨道车辆,具有充电受流面积大,受流状态好,充电稳定性和可靠性高等优点。
根据本申请的一些实施例,轨道交通系统还包括:检测装置和控制器,所述检测装置用于检测所述充电刀与所述充电槽的相对位置信息;所述控制器分别与所述检测装置和所述供电装置相连,所述控制器根据所述检测装置检测的所述相对位置信息控制所述供电装置,以在所述充电刀与所述充电槽接触时通电,并在所述充电刀与所述充电槽分离时断电。
本申请的附加方面和优点将在下面的描述中部分给出,部分将从下面的描述中变得明显,或通过本申请的实践了解到。
附图说明
本申请的上述和/或附加的方面和优点从结合下面附图对实施例的描述中将变得明显和容易理解,其中:
图1是根据本申请一些实施例的集电靴的示意图;
图2是图1中示意的集电靴的侧视图;
图3是图1示意的集电靴的剖面图;
图4是图3中圈示的A部的放大图;
图5图1中示意的集电靴的爆炸图;
图6是根据本申请另一些实施例的集电靴的示意图;
图7是图6中示意的集电靴的部分结构的俯视图;
图8是图6中示意的集电靴的部分结构的侧视图;
图9是图6示意的集电靴的部分结构的分解示意图;
图10是图6中示意的集电靴的一个示意图,其中,滑动架位于初始位置;
图11是图6中示意的集电靴的另一个示意图,其中,滑动架滑动至偏离初始位置;
图12是根据本申请实施例的集电靴的充电刀总成的剖视图;
图13是根据本申请实施例的集电靴的部分结构的剖视图;
图14是根据本申请实施例的充电刀的正视图;
图15是根据本申请实施例的充电刀的侧视图;
图16是根据本申请实施例的充电刀的俯视图;
图17是根据本申请实施例的充电轨的部分俯视图;
图18是根据本申请实施例的充电轨的断面图;
图19是根据本申请实施例的轨道交通系统的部分结构的立体图;
图20是根据本申请实施例的轨道交通系统的部分结构的侧视图;
图21是根据本申请实施例的轨道交通系统的部分结构的示意图;
图22是根据本申请实施例的轨道车辆的结构示意图;
图23是根据本申请实施例的轨道交通系统的结构示意图。
附图标记:
100:集电靴;200:绝缘座;300:充电轨;400:绝缘子;
1:滑动座总成;111:第一滑块座;112:第二滑块座;11:滑槽;12:储油槽;
10a:支架;10b:滑动架;101:通孔;102:支座;1021:凸块;103:容置槽;
2:充电刀总成;20:充电刀;201:第一受流面;202:第二受流面;203:容纳槽;
21:连杆;22:限位件;23:限位部;24:线鼻;211:止挡凸台;
3:缓冲件;
4:支撑部;41:支撑杆;42:套环;
5:弹性复位结构;51:弹性件;
6:充电槽;61:第一供流面;62:第二供流面;63:引导段;64:引导槽;
611:第一外侧板;601:第一凹槽;612:第二外侧板;602:第二凹槽;621:第一内侧板;622:第二内侧板;65:防刮擦内钩;66:排污孔;
71:绝缘支架;710:安装凹槽;72:绝缘压块;
800:轨道车辆;810:车体;820:储电装置;
900:轨道交通系统;910:供电装置;920:轨道。
具体实施方式
下面详细描述本申请的实施例,所述实施例的示例在附图中示出,其中自始至终相同或类似的标号表示相同或类似的元件或具有相同或类似功能的元件。下面通过参考附图描述的实施例是示例性的,仅用于解释本申请,而不能理解为对本申请的限制。
在本申请的描述中,需要理解的是,术语“纵向”、“横向”、“宽度”、“上”、“下”、“前”、“后”、“左”、“右”、“顶”、“底”“内”、“外”、“轴向”、“径向”、“周向”等指示的方位或位置关系为基于附图所示的方位或位置关系,仅是为了便于描述本申请和简化描述,而不是指示或暗示所指的装置或元件必须具有特定的方位、以特定的方位构造和操作,因此不能理解为对本申请的限制。此外,限定有“第一”、“第二”的特征可以明示或者隐含地包括一个或者更多个该特征。在本申请的描述中,除非另有说明,“多个”的含义是两个或两个以上。
在本申请的描述中,需要说明的是,除非另有明确的规定和限定,术语“安装”、“相连”、“连接”应做广义理解,例如,可以是固定连接,也可以是可拆卸连接,或一体地连接;可以是机械连接,也可以是电连接;可以是直接相连,也可以通过中间媒介间接相连,可以是两个元件内部的连通。对于本领域的普通技术人员而言,可以具体情况理解上述术语在本申请中的具体含义。
现代电力机车一般采用柔性接触网或第三轨刚性供电系统进行随车供电,对于目前小运量小型化的电力机车,采取站区充电的超级电容储能系统既能美化沿线景观,还能节省建设随车供电系统的一大笔费用。
相关技术中,轨道车辆上设有集电靴,配合悬挂式充电轨,在站区为轨道车辆的储电装置充电。但是,悬挂式充电轨的重量大,安装难度高,同时未设置防拉弧系统,易在站区通断电瞬间出现燃弧现象,安全性差。
而且,相关技术中的轨道车辆,在车辆发生偏移时,集电靴与充电轨的适应性较差,尤其对于车辆爆胎后产生的极限偏移适应能力有限,极易产生襒刀或襒轨事故。而应用于汽车的刀槽充电系统,采用双向轴承平动技术以适应汽车可能出现的小范围左右摆动,由于路面汽车行驶路线不确定的特点及刀槽主动适配功能使得充电刀装置结构复杂,包含的各种控制系统增加了制造成本,供平动及脱刀用的两驱动电机也增加了装置重量,不适于应用至轨道车辆上。
另外,现有的刀槽充电系统,均为上下面的单面平面接触方式,受流面积有限,充电稳定性和安全性较差。
为此,本申请提出了一种充电刀20、充电刀总成(2)和轨道交通系统900。
根据本申请的用于轨道车辆800的集电靴100,包括:支架10a、充电刀总成2和缓冲件3。其中,支架10a可与轨道车辆800相连,以将集电靴100安装在轨道车辆800的车体810上,支架10a可以是绝缘件,以减轻支架10a对充电过程的影响,提高充电稳定性。
如图1-图3所示,充电刀总成2在靠近和远离支架10a的方向上(即,图示的上下方向上)可移动地与支架10a相连,以在充电刀总成2与充电轨300开始接触时,充电刀总成2可以通过自身的移动避免与充电轨300发生严重碰撞。
缓冲件3可分别与支架10a和充电刀总成2相连,以对充电刀总成2提供缓冲,从而使充电刀总成2与充电轨300接触时能够灵活移动,并且可以在充电刀总成2和充电轨300接触充电的过程中提供缓冲,可以减缓碰撞。
可选地,缓冲件3可以是弹性件,例如,缓冲件3可以是图示的弹簧;或者,缓冲件3还可以是可自动控制的电动推杆(图未示出)或可自动控制的气缸(图未示出)。由此,缓冲件3可以在受力时发生形变,同时可以提供阻碍充电刀总成2与支架10a之间发生相对位移的阻尼力,不仅结构简单紧凑,便于拆装,而且缓冲效果好。在此,需要说明的是,所谓“可自动控制的电动推杆”是指具备主动控制功能的电动推杆,所谓“可自动控制的气缸”是指具备主动控制功能的气缸。
因此,根据本申请第一方面实施例的用于轨道车辆800的集电靴100,可以通过缓冲件3为充电刀总成2提供缓冲,从而可以使得充电刀总成2能够根据自身的受力情况适应性地在靠近和远离支架10a的方向上移动,可以减缓充电刀总成2与充电轨300的碰撞,缓冲效果好,进而可以降低充电刀总成2因猛烈碰撞而出现损坏的概率,延长集电靴100和充电轨300的使用寿命,相比于相关技术中的摆动式集电靴100,大大简化了结构,降低了装配难度和成本。
根据本申请的充电刀总成2,充电刀总成2包括:连杆21和充电刀20。
具体而言,连杆21的一端可以与轨道车辆800相连,充电刀20为上述所述的充电刀20,充电刀20与连杆21的远离轨道车辆800的一端相连。
根据本申请的充电刀总成2,充电刀20可以通过连杆21方便、可靠地连接至轨道车辆800上,且充电刀20可以利用第一受流面201和第二受流面202与充电轨300接触,实现双面受流,增加了受流面积,可以优化受流状态,并且,第一受流面201与第二受流面202之间的间距变化,能够保证充电刀20与充电轨300之间具有一定的接触压力,可以提高接触稳定性,从而可以有效提高受流稳定性,降低出现电火花的概率,提高了安全性。
根据本申请的一些实施例,在垂直于轨道车辆800的方向上,充电刀总成2相对于轨道车辆800可相对运动。如图5所示,支架10a上可以设有通孔101,连杆21的一端(例如,图示的上端)可移动地伸入通孔101,充电刀20可与连杆21的另一端(即,图示的下端)相连,在充电时,充电刀20可与充电轨300接触受流,缓冲件3可以连接支架10a和连杆21。换言之,在图1-图3所示的示例中,充电刀总成2在上下方向上移动时,连杆21可以在通孔101内沿上下方向移动,在此过程中,充电刀20可由连杆21带动沿上下方向移动,缓冲件3分别与支架10a和连杆21相连,为充电刀20提供缓冲,以减缓充电刀20与充电轨300之间的碰撞。
在本申请的一些实施例中,如图1-图3所示,缓冲件3可以为弹性件,例如,缓冲件3可以为弹簧。缓冲件3可以套设于连杆21的外周面,一方面,可以减小缓冲件3的占用空间,优化结构布局,另一方面,可以利用缓冲件3提供稳定且均匀的缓冲力,缓冲效果进一步提升。
为了便于缓冲件3的安装和定位,连杆21可具有止挡凸台211,缓冲件3可以止抵在支架10a和止挡凸台211之间。在装配时,先将缓冲件3套设在连杆21上,再将连杆21的一端(例如,图示的上端)伸入支架10a的通孔101内,使缓冲件3的一端止抵在支架10a上,另一端(即,图示的下端)止抵在止挡凸台211上,即可实现装配和定位,装配难度低,可以提高装配效率。
根据本申请的一些实施例,止挡凸台211可为环形凸台,即止挡凸台211可以构造为环绕连杆21的周向的闭环形。由此,止挡凸台211可以在整个周向上供缓冲件3止挡,止挡效果好,可以避免止挡失效,可有效提高稳定性和缓冲可靠性。
当然,本申请的结构不限于此,止挡凸台211还可以是沿连杆21的周向间隔设置的多个,对此,不能理解为对本申请的限制。在此,“多个”可以理解为至少两个,例如,三个、四个或五个,以使缓冲件3稳定地止抵在止挡凸台211上。
在本申请的一些实施例中,如图1和图3所示,连杆21的远离充电刀20的(例如, 图示的上端)可以安装有随连杆21移动的限位件22,限位件22位于支架10a的背离充电刀20的一侧(例如,图示的上侧)。例如,在图3所示的示例中,连杆21向下移动到最低位置时,限位件22止抵支架10a的上侧,以限制连杆21继续向下,从而可以防止连杆21从通孔101内脱出;而当连杆21向上移动时,限位件22可以随连杆21同步向上移动。这样,不仅结构简单紧凑,而且可以进一步提高缓冲稳定性。
可选地,限位件22可以是穿设在连杆21上的限位销;或者,如图1-图3所示,限位件22可以是与连杆21的端部螺纹配合的限位螺母,拆装方便,稳定性好,且成本低廉。
根据本申请的一些实施例,如图2和图5所示,支架10a上可以连接有支撑部4,支撑部4包括:支撑杆41和套环42,套环42与支架10a在连杆21的延伸方向上(例如,图示的上下方向上)间隔设置,并且套环42可位于支架10a的邻近充电刀20的一侧(即,图示的下侧),其中,连杆21可移动地嵌套与套环42内。即,支撑杆41的一端(例如,图示的上端)可与支架10a相连,支撑杆41朝向远离支架10a的方向(即,向下)延伸,套环42可与支撑杆41的另一端(即,图示的下端)相连,其中,连杆21可移动地嵌套于套环42内。由此,套环42可以由支撑杆41支撑固定在支架10a上,并且套环42与支架10a间隔开,连杆21可以在套环42内和通孔101内移动,通过设置与支架10a相连的套环42,可以提高连杆21移动的平稳性,同时,套环42还可以为连杆21提供导向,避免出现连杆21因发生偏移而卡在通孔101内无法移动的现象,可以有效提高可靠性。
在本申请的一些实施例中,支撑杆41可以包括环绕套环42间隔设置的至少两个,例如,支撑杆41可以是图示的两个,或者,支撑杆41可以是三个、四个等,支撑杆41可以在朝远离支架10a的方向(例如,在图示的向下的方向)上朝向套环42倾斜,支撑杆41的另一端(即,图示的下端)可与套环42的外周面相连。由此,多个支撑杆41可以在周向上为套环42提供支撑,可以提高套环42的稳定性和可靠性,利于连杆21的伸缩移动。
为了避免连杆21在伸缩移动时发生绕其轴向旋转的现象,连杆21与套环42之间可以设置限位部23以进行限位。举例而言,如图5所示,限位部23可以是矩形键,连杆21的外周面上可以设有安装键槽,套环42的内周面上可以设有贯通键槽,矩形键安装在安装键槽内,连杆21移动时,带动矩形键在贯通键槽内沿竖向移动,可以使连杆21在竖向上移动的同时,限制连杆21绕其轴向发生转动,从而可以避免充电刀总成2发生旋转,可以提高可靠性。
根据本申请的一些实施例,如图6-图11所示,集电靴100可以包括:滑动座总成 1、滑动架10b、充电刀总成2和弹性复位结构5。
滑动座总成1适于与轨道车辆800的车体810相连,滑动架10b沿横向可滑动地与滑动座总成1相连,也就是说,滑动架10b与滑动座总成1相连,且在沿横向的方向上滑动架10b相对于滑动架10b总成可滑动。需要说明的是,本申请中所述的“纵向”可以理解为平行于轨道车辆800的行驶方向的方向、“横向”可以理解为垂直于轨道车辆800的行驶方向的方向、“竖向”可以理解为轨道车辆800的高度方向。例如,在图6所示的示例中,前后方向为纵向,左右方向为横向,上下方向为竖向。
充电刀总成2与滑动架10b相连,以在滑动架10b相对于滑动座总成1滑动时,充电刀20由滑动架10b带动滑动,使充电刀总成2可相对于滑动架10b总成在横向上移动,使得充电刀总成2相对于轨道车辆800可在车体810的宽度方向上移动。由此,可以有效减轻由于车体810偏移所造成的撇刀或撇轨的影响,提高充电稳定性。
弹性复位结构5可分别与滑动架10b和滑动座总成1相连,并且弹性复位结构5常驱动滑动架10b复位至初始位置。在此,需要说明的是,弹性复位结构5始终驱动滑动架10b向初始位置运动,即弹性复位结构5一直为滑动架10b提供驱动力,使滑动架10b向初始位置复位。可以理解的是,所谓“初始位置”,一般情况下是指根据设计确定与充电轨300对接的最佳位置,但是由于安装精度等原因,会导致充电轨300的设置位置变化。通过设置弹性复位结构5,能够在车体810发生偏移时对充电刀总成2的偏移进行补偿,并且可以在车体810未发生偏移时使充电刀总成2恢复到初始位置。
也就是说,充电刀总成2可相对于滑动座总成1在横向上发生适应性移动,弹性复位结构5始终驱动滑动架10b向初始位置移动。这样,当轨道车辆800发生偏移时,充电刀总成2会有相对于充电轨300发生偏移的趋势,此时,滑动架10b相对于滑动座总成1滑动,使充电刀总成2会沿横向相对于滑动座总成1移动,使得充电刀总成2与充电轨300形成较优的配合状态,以适应车体810的偏移;与此同时,弹性复位结构5驱动滑动架10b向初始位置移动。当车体810从偏移位置恢复到正常位置时,在弹性复位结构5的驱动下,滑动架10b复位至初始位置,充电刀总成2同样可与充电轨300形成较优的配合状态。
由此,可以通过滑动架10b相对于滑动座总成1在横向上的滑动使充电刀总成2适应车体810的偏移,并且可以利用弹性复位结构5常驱动滑动架10b复位至初始位置,从而可以在车体810发生偏移时补偿充电刀总成2的偏移,并且可以在车体810未发生偏移时使充电刀总成2恢复到正常位置,进而可以使充电刀总成2能够始终与充电轨300形成较优的配合状态,相比于相关技术中心的双向轴承平动技术,结构更简单,不仅可以在车体810偏移过大及爆胎后的极限工况下仍能正常使用,降低产生襒刀或襒轨 事故的概率,而且可以提高充电稳定性。
如图6、图8和图9所示,滑动座总成1上可以形成有沿横向延伸的滑槽11,滑动架10b沿横向可滑动地与滑槽11配合。即,滑动架10b沿滑动座总成1上的滑槽11滑动。结构简单,便于加工,而且装配方便。
可选地,如图8和图9所示,滑槽11的沿竖向(例如,图示的上下方向)的一侧敞开形成有敞开侧,竖向为垂直于横向的方向,在垂直于横向的截面上,滑槽11的内侧面在朝向滑槽11的敞开侧的方向上逐渐收缩,并且,滑动架10b的侧面可呈与滑槽11的内侧面适配的形状。由此,既可以使滑动架10b在滑槽11内沿横向滑动,也可以防止滑动架10b在竖向上与滑槽11脱离配合,稳定性好,可靠性高。
在本申请的一些实施例中,滑槽11可以向下敞开。也就是说,滑动座总成1上形成有沿横向延伸且在竖向上向下敞开的滑槽11,并且滑槽11构造为在竖向上向下渐缩的结构,滑动架10b构造为与滑槽11适配的向下收缩的结构,滑动架10b适于配合在滑槽11内且滑动座可沿滑槽11在横向上滑动。由此,可以通过滑槽11的形状避免滑动架10b由于自身的重力作用脱离滑槽11,结构简单,设计巧妙。
可选地,在如图9所示的示例中,滑槽11可以形成为内侧面为斜面的梯形槽,滑动架10b的垂直于横向的截面形成为可与梯形槽配合的梯形。当然,滑槽11和滑动架10b还可以形成为相适配其他形状,例如,滑槽11的内侧面形成圆柱面,滑动架10b的侧面形成圆柱面。对此,不能理解为对本申请的限制。
为了提高滑动架10b在滑槽11内的滑动灵活性和平稳性,滑槽11的内侧面和滑动架10b的侧面中的至少一个上可以设有储油槽12,储油槽12内可以存储润滑油或润滑脂等。换言之,储油槽12形成在滑动架10b的侧面上,如图9所示;或者,储油槽12还可以形成在滑槽11的内侧面上;再或者,滑动架10b上和滑槽11的内侧面上可同时设有储油槽12。由此,可以减小滑动架10b与滑槽11之间的摩擦力,使滑动架10b能够灵活顺利地沿横向在滑槽11内滑动,同时,减轻了磨损,降低了噪音。
根据本申请的一些实施例,如图6和图7所示,滑动架10b上设有支座102,弹性复位结构5可以包括两个弹性件51,两个弹性件51分布于支座102的沿横向相背的两侧,并且弹性件51可与支座102和滑动座总成1相连。结合图6-图9所示的示例,滑动架10b的上表面上设有支座102,两个弹性件51分别连接于支座102的左侧和右侧,并且两个弹性件51分别与滑动座总成1相连。这样,两个弹性件51可以在两侧弹性地连接滑动架10b和滑动座总成1,从而可以通过弹性件51的弹性变形允许滑动架10b在滑槽11内滑动,并且,弹性件51的恢复原状的特性能够常驱动滑动架10b复位至初始位置,结构简单紧凑,装配方便快速,且驱动稳定可靠。
在一些实施例中,如图6和图7所示,弹性件51可为弹簧,并且滑动架10b上设有容置槽103,容置槽103可沿横向延伸,并且弹性件51的至少一部分可以容纳于容置槽103内。例如,滑动架10b的上表面上设有两个开口朝上的容置槽103,两个弹簧分别容纳在容置槽103内。由此,可以通过容置槽103为弹性件51提供安装空间,空间布局合理,可以使结构更加紧凑,另外,还可以通过容置槽103为弹性件51提供限位,避免弹性件51因发生错位而失效,可以提高稳定性和可靠性。
需要说明的是,用于偏移回复的弹性件51可以使用橡胶弹簧、空气弹簧等其他弹性元件替代,也可用具备主动控制系统的气压系统替代。这对于本领域技术人员而言是可以理解的,在此不再赘述。
可选地,支座102可以包括两个凸块1021,如图7和图9所示,两个凸块1021可沿横向间隔布置,并且两个凸块1021可分别位于充电刀总成2与滑动架10b的连接处的两侧,一方面,可以为充电刀20和滑动架10b的连接提供让位空间,提高空间利用率,另一方面,可以提高弹性件51的安装稳定性。
根据本申请的一些实施例,充电刀总成2沿竖向可移动地与滑动架10b相连,竖向为垂直于横向的方向,在附图所示的示例中,图示的上下方向即为竖向,并且,充电刀20与滑动架10b之间设有缓冲件3,缓冲件3可分别与连杆21和滑动架10b相连,以对充电刀总成2提供缓冲。可以理解的是,此时,上文所述的支架10a可以构造为滑动架10b。
也就是说,充电刀总成2不仅可以在横向上移动,而且可以在竖向上移动。由此,既可以适应车体810在其宽度方向上的偏移,也可以缓冲充电刀总成2与充电轨300接触时竖向上的碰撞,结构简单紧凑,缓冲效果好,充电稳定性和可靠性更高。
集电靴100的充电刀总成2包括充电刀20,下面结合附图对充电刀20进行详细描述。
如图14-16所示,充电刀20可沿轨道车辆800的行驶方向(例如,图示的前后方向)延伸,并且在垂直于轨道车辆800的行驶方向的方向上,充电刀20的相对的两侧面分别设有第一受流面201和第二受流面202。也就是说,充电刀20的沿横向相对的两侧面上分别形成有第一受流面201和第二受流面202。即,充电刀20具有相对设置的两个受流面。
其中,由充电刀20的靠近轨道车辆800的一端至远离所述轨道车辆800的一端,第一受流面201和第二受流面202之间的间距逐渐减小。这里定义充电刀20的靠近轨道车辆800的一端为“第一端”,定义充电刀20的远离轨道车辆800的一端为“第二端”。所述的“第一端”可以理解为充电刀20的上端,所述的“第二端”可以理解为 充电刀20的下端。例如,在图15所示的示例中,第一受流面201和第二受流面202之间的间距从上端向下端逐渐减小。或者,第一受流面201和第二受流面202之间的间距也可以从下端向上端逐渐减小。
由此,可以利用第一受流面201和第二受流面202与充电轨300接触,实现双面受流,增加了受流面积,可以优化受流状态,并且,第一受流面201与第二受流面202之间的间距变化,能够保证充电刀20与充电轨300之间具有一定的接触压力,相比于相关技术中的上下单面接触集电方式,可以提高充电刀20与充电轨300的接触稳定性,从而可以有效提高受流稳定性,降低出现电火花的概率,提高了安全性。
根据本申请的一些实施例,第一受流面201和第二受流面202中的其中一个可沿竖向延伸,并且其中另一个相对于竖向倾斜延伸;或者,第一受流面201和第二受流面202沿朝向彼此的方向倾斜延伸。由此,可以将充电刀20的第一受流面201和第二受流面202构造为不同的形状,以适配不同构造的充电轨300,结构简单,方便加工。
可选地,充电刀20沿轨道车辆800的行驶方向延伸,在沿竖向的截面上,充电刀20呈从第一端边沿逐渐收缩至第二端边沿的形状。例如,在如图15所示的示例中,在远离滑动架10b(即,支架10a)的方向上,充电刀20呈逐渐收缩至充电刀20的边沿的形状,即充电刀20从上端边沿逐渐收缩至下端边沿。由此,可以使充电刀20的在横向上相对的两个侧面分别构造为第一受流面201和第二受流面202,受流面积更大,稳定性和可靠性更佳。
在本申请的一些实施例中,在沿轨道车辆800的行驶方向上,充电刀20的横截面积由充电刀20的中部至两端逐渐减小。需要说明的是,在沿轨道车辆800的行驶方向上,充电刀20的两个端部中的至少一个可以呈逐渐收缩至充电刀20边沿的形状。如图16所示,充电刀20沿前后方向的两个端部中的至少一个可呈沿前后方向逐渐收缩至充电刀20边沿的形状。例如,在图16示的示例中,充电刀20的前端的横截面积向前逐渐减小,且充电刀20的后端的横截面积向后逐渐减小,即充电刀20构造为双向楔形,且双侧面接触集电。需要说明的是,所谓“双向楔形”是指,充电刀20从侧视图看为从第一端向第二端由宽向窄逐渐变化,俯视图看为中间宽且两端窄逐渐变化的结构。当然,本申请的结构不限于此,充电刀20还可以构造为先与充电轨300接触的一端的横截面向端面逐渐减小的形状。
可以理解的是,轨道车辆800行进时,充电刀20的端部先与充电轨300接触,通过将充电刀20设计为在纵向上向端部逐渐减小,可以提供导向作用,利于充电刀20与充电轨300顺利接触并配合,不仅可以减轻碰撞,减小磨损,而且可以提高配合精度,进而可以提高充电稳定性。
根据本申请的一些实施例,充电刀20上可以设有适于安装线鼻24的容纳槽203,容纳槽203可以设在充电刀20的靠近轨道车辆800的一端。可选地,容纳槽203在竖向方向上可以延伸至充电刀20的靠近轨道车辆800的端面。可选地,容纳槽203在垂直于轨道车辆800的行驶方向上可以连通第一受流面201和第二受流面202,即容纳槽203在横向上可以贯通第一受流面201和第二受流面202。例如,如图12-图16所示,充电刀20的上端设有容纳槽203,容纳槽203被构造为在竖向上延伸至充电刀20的上端面、且在左右方向上两端分别延伸至第一受流面201和第二受流面202的三面开口槽,线鼻24安装在容纳槽203内。这样,不仅便于加工制造,而且便于实现线鼻24的安装和定位,型式更紧凑,受流稳定性好,可靠性高,装配效率高。
根据本申请第二方面实施例的轨道车辆800,包括车体810和上述根据本申请第一方面实施例的集电靴100,车体810上可以设有绝缘座200,车体810具有储电装置820,集电靴100可与绝缘座200相对固定地连接,并且集电靴100与储电装置820电连接。
可选地,集电靴100可以安装在车体810底部,在图19-图21所示的示例中,集电靴100与充电轨300为上接触式接触体侧部受流方式。当然,本申请的结构不限于此,集电靴100还可以是侧面安装或倒立安装等其他形式,这对于本领域的技术人员而言是可以理解的,故在此不再详述。
根据本申请实施例的轨道车辆800,通过设置根据本申请上述第一方面实施例的集电靴100,可以通过缓冲件3为充电刀20提供缓冲,使得充电刀总成2可以根据自身受力情况适应性地在竖向上移动,从而可以缓冲充电刀20与充电轨300之间的碰撞。
并且,通过将滑动架10b相对于滑动座总成1在横向上的滑动使充电刀总成2适应车体810的偏移,可以利用弹性复位结构5常驱动滑动架10b复位至初始位置,从而可以在车体810发生偏移时补偿充电刀总成2的偏移,并在车体810未发生偏移时使充电刀总成2复位到正常位置,进而可以减轻由于车体810偏移造成的撇刀或撇轨的影响。
同时,利用充电刀20的第一受流面201和第二受流面202与充电轨300接触,可以实现双面受流,增大了受流面积,第一受流面201和第二受流面202之间的间距变化,可以使充电刀20与充电轨300之间具有一定的接触压力,受流稳定性好,可以降低出现电火花的概率,安全性高,可优化受流状态。
根据本申请第三方面实施例的轨道交通系统900,包括:供电装置910、轨道、充电轨300和轨道车辆800,轨道车辆800可以是上述根据本申请第二方面实施例的轨道车辆800。
其中,供电装置910可以设在轨道车辆800的站台区,轨道920可以包括沿轨道车辆800行驶方向延伸的轨道梁,车辆的行驶方向为车辆的长度方向,也即上文中所述的 纵向方向。充电轨300具有沿轨道车辆800的行驶方向延伸的充电槽6,充电轨300与供电装置910电连接,轨道车辆800跨坐于轨道梁上,充电刀总成2适于可离合地沿充电槽6滑动。需要说明的是,所谓“可离合地相连”是指,充电刀总成2可以和充电槽6接触,也可与充电槽6分离。
当轨道车辆800运行至站台充电区时,充电刀总成2与供电装置910、充电轨300、集电靴100和储电装置820适于构成充电回路为储电装置820充电。
根据本申请实施例的轨道交通系统900,通过设置根据本申请第二方面实施例的轨道车辆800,能够缓冲充电刀20与充电轨300之间的碰撞,减轻车体810偏移造成的撇刀或撇轨的影响,降低了充电刀20和充电轨300出现损坏的概率,可以延长使用寿命。并且,可以实现双面受流,提高了受流稳定性和安全性,优化了受流状态。
根据本申请的一些实施例,还对充电轨300进行了优化设计。
结合图17-图21所示,充电轨300可具有沿纵向(即,轨道车辆800的行进方向)延伸的充电槽6,充电槽6的沿横向相对的两个表面分别形成第一供流面61和第二供流面62。也就是说,充电槽6具有相对设置的两个供流面。
其中,在沿竖向的方向上,第一供流面61和第二供流面62之间的间距从第一端向第二端逐渐减小。例如,在图示的示例中,第一供流面61和第二供流面62之间的间距从上端向下端逐渐减小。或者,第一供流面61和第二供流面62之间的间距也可以从下端向上端逐渐减小。
由此,可以利用充电轨300的第一供流面61和第二供流面62与轨道车辆800的充电刀20接触,实现双面供流,可以增大供流面积,并且,第一供流面61和第二供流面62之间的间距变化,能够保证充电刀20与充电槽6之间具有一定的接触压力,可以提高充电轨300与充电刀20的接触稳定性,从而可以提高充电稳定性,可以降低出现电火花的概率,安全性也得以提高。
根据本申请的一些实施例,充电槽6可为弹性槽。也就是说,充电槽6受力时具备发生弹性形变的特性,并且外力解除时可以恢复原状。由此,充电刀20与充电轨300接触时,充电刀20配合至充电槽6内,此时,充电槽6可发生一定的弹性变形,从而可以利用自身弹性回复力形成对充电刀20的“夹持”力,从横向两侧为充电刀20提供接触压力,可以进一步提高充电接触面的受流稳定性,优化受流质量。
在一些实施例中,如图17和图21所示,充电轨300可以包括:沿横向相对的第一外侧板611和第二外侧板612,以及沿横向相对的第一内侧板621和第二内侧板622。其中,第一外侧板611的第一端(例如,图示的上端)可与第二外侧板612的第一端(即,图示的上端)间隔开,并且第一外侧板611的第二端(即,图示的下端)与第二外侧板 612的第二端(即,图示的下端)相连。第一内侧板621和第二内侧板622位于第一外侧板611和第二外侧板612之间,第一内侧板621的第一端与第一外侧板611的第一端相连,第二内侧板622的第一端与第二外侧板612的第一端相连,第一内侧板621和第二内侧板622朝向彼此倾斜延伸。其中,第一内侧板621和第二内侧板622的相对的表面分别形成第一供流面61和第二供流面62。
由此,可以将充电轨300设计为中空的“壳状”型式,将充电轨300构造为半刚性充电轨300,不仅能减轻充电轨300的自重,而且可以优化结构,便于加工制造,可以降低成本。与相关技术中的刚性接触轨和柔性接触网相比,半刚性充电轨300可产生一定的弹性变形,从而利用自身弹性回复“夹持”力提供接触压力,确保充电接触面的稳定受流。
可选地,如图17和图20所示,第一外侧板611的一部分可以朝向第二外侧板612凹陷以形成第一凹槽601,第二外侧板612的一部分可以朝向第一外侧板611凹陷以形成第二凹槽602。可选地,第一凹槽601和第二凹槽602可以相对设置。这样,通过设计第一凹槽601和第二凹槽602,可以加强第一侧板和第二侧板的强度,从而可以提高充电轨300的强度,并且,第一凹槽601和第二凹槽602还可利于充电轨300的安装和定位,这将在下文中结合具体实施例进行详细描述。
在本申请的一些实施例中,第一内侧板621的第二端和第二内侧板622的第二端可以朝相互远离的方向弯折。具体而言,在如图17所示的示例中,第一内侧板621的下端远离第二内侧板622弯折,第二内侧板622的下端远离第一内侧板621弯折。由此,第一内侧板621和第二内侧板622的自由端可以分别弯折形成内钩,一方面,利于形成平滑的第一供流面61和第二供流面62,使得充电轨300的结构更加紧凑,便于充电刀20与充电槽6配合,另一方面,可以有效避免充电刀20与充电轨300发生刮擦,即形成防刮擦内钩65,减轻了磨损,减小噪音,而且还可以减少电火花的出现。
如图17和图21所示,第一内侧板621的第二端与第一凹槽601在竖向方向上可以间隔开,第二内侧板622的第二端可与第二凹槽602在竖向方向上可以间隔开。换言之,在纵向方向上的投影中,第一内侧板621的自由端与第一凹槽601间隔设置,第二内侧板622的自由端与第二凹槽602间隔设置。充电刀20与充电槽6接触充电时,充电刀20分别与第一内侧板621和第二内侧板622接触,通过将第一内侧板621的第二段与第一凹槽601间隔设置,并将第二内侧板622的第二端与第二凹槽602间隔设置,可为第一内侧板621和第二内侧板622的形变提供空间,避免发生干涉,可以使充电轨300的弹性特性得以有效发挥,利于实现稳定受流。
可选地,充电轨300可为对称结构。在本申请的一些实施例中,充电轨300可为一 体成型的金属件,也就是说,第一外侧板611、第二外侧板612、第一内侧板621以及第二内侧板622可以一体加工成型。例如,充电轨300可以由薄板金属件卷折而成。
这样,不仅可以优化供流效果,而且便于加工,可以降低成本。另外,金属件具备较优的刚性和韧性,配合上述充电轨300的形状,可以使充电轨300具备一定刚度的同时使充电轨300能够发挥更佳的弹性特性,实现一加一大于二的效果,使受流质量和充电稳定性更佳。
为了便于将充电槽6内沉积的雨水和泥沙排出,充电轨300上可以设有与充电槽6联通的排污孔66。在本申请的一些实施例中,排污孔66可以设在充电轨300安装后沿重力方向的最低面。由此,集聚在充电槽6内的泥沙和雨水可以在重力的作用下从排污孔66中自行排出,无需人工操作,减少了维护投入,而且可以提高安全性。
根据本申请的一些实施例,如图18和图19所示,充电轨300的沿纵向的至少一端可设有引导段63,引导段63具有与充电槽6联通的引导槽64,引导槽64的沿横向相对的表面在远离充电槽6的方向上渐扩。换言之,在轨道车辆800的行进方向上,充电轨300的一端或者两端设有引导段63,引导段63具有引导槽64,引导槽64与充电槽6连通,并且引导槽64的横向尺寸在远离充电槽6的方向上逐渐增大。
由此,轨道车辆800行进过程中,充电刀20随车体810同步移动,轨道车辆800行进至站区进行充电时,充电刀20从一端移入充电槽6,与充电轨300接触。在充电轨300的端部设置引导段63,可以使充电刀20先移入引导槽64,然后再移入充电槽6,由于引导槽64被构造为远离充电槽6渐扩的结构,引导槽64可为充电刀20提供引导作用,使充电刀20可以平稳地从无充电轨300区过渡至充电轨300区。这样,可以避免充电刀20与充电轨300发生剧烈碰撞,降低损坏的概率,可以延长使用寿命。
并且,引导段63构成了分叉式引导带,由于侧面分叉的存在,使得充电刀20滑入充电轨300时,充电刀20与充电轨300的接触面之间的接触力呈逐渐变大的趋势,充电刀20滑出充电轨300时,充电刀20与充电轨300的接触面之间的接触力呈逐渐减小的趋势。在该接触力和缓冲件3的共同作用下,充电刀总成2在轨道车辆800进站时沿竖向朝向支架10a移动,且在轨道车辆800出站时远离支架10a移动。
由此,通过监控充电刀总成2的位置变化情况,使得符合进站位移动态时,连通充电回路,满足出站位移动态时断开充电回路,以此方式可以达到“触后通路,脱前断路”的目的,可以减少集电靴100与充电轨300在接触或脱离瞬间可能出现的燃弧现象的发生。需要说明的是,所谓“触后通路,脱前断路”是指,集电靴100与充电轨300接触后再接通充电回路,在集电靴100与充电轨300将要脱离前断开充电回路。
可选地,充电刀20与充电槽6接触时,充电刀20的第一受流面201可与充电槽6 的第一供流面61接触,充电刀20的第二受流面202可与充电槽6的第二供流面62接触。也就是说,充电刀20与充电槽6双面接触。即,充电刀20与充电槽6采用双侧面集电方式充电,相较于现有技术中采用的上下单面接触集电方式,不仅结构简单紧凑,而且受流可靠性高,稳定性好。
为了确保充电刀20与充电槽6接触后能保持最佳的贴合,充电刀20与充电槽6过盈配合。换言之,在自由状态下,充电槽6的第一供流面61和第二供流面62之间的间距小于充电刀20的第一受流面201和第二受流面202的对应位置处的宽度。或者,充电刀20的第一受流面201与第二受流面202之间形成的夹角不小于充电轨300在自由状态下第一供流面61与第二供流面62之间形成的夹角。由此,充电刀20在充电槽6内滑动时,充电刀20的第一受流面201和第二受流面202稳定地挤压充电槽6的第一供流面61和第二供流面62,可以使受流稳定性更佳。
根据本申请的一些实施例,轨道交通系统900还可以包括:检测装置和控制器,其中,检测装置可用于检测充电刀20与充电槽6的相对位置信息,控制器可分别与检测装置和供电装置910相连,控制器可以根据检测装置检测的相对位置信息控制供电装置910,以在充电刀20与充电槽6接触时通电,并在充电刀20与充电槽6分离时断电。
也就是说,控制器根据充电刀20和充电槽6是否接触来控制供电装置910是否供电。当检测装置检测到充电刀20与充电槽6未接触时,控制器控制供电装置910不供电,直到检测装置检测到充电刀20与充电槽6接触时,控制控制供电装置910通电,使充电回路接通,为储电装置820充电;而当检测装置检测到充电刀20与充电槽6即将分离时,控制装置控制供电装置910停止供电,断开充电回路,停止为储电装置820充电。
即,可以根据充电刀20与充电槽6的相对位置,实现“接触通路,脱前断路”,从而可以有效避免燃弧现象发生,可以进一步提高充电安全性。
可选地,检测装置可以是检测充电刀20与充电槽6之间的位移的位移传感器,或者,检测装置可以是检测充电槽6的受力的压力传感器。当然,检测装置不限于以上的举例,还可以由其他能够检测充电刀20和充电槽6的相对位置的器件替代,本领域技术人员可以根据上文的描述对检测装置进行选择,本申请对此不作具体限定。
总而言之,根据本申请实施例的轨道交通系统900,能够缓冲充电刀20与充电轨300之间的碰撞,减轻车体810偏移造成的撇刀或撇轨的影响,降低了充电刀20和充电轨300出现损坏的概率,可以延长使用寿命。而且,通过设置能够双面供流的充电轨300和能够双面受流的充电刀20,并配合检测装置和控制器,可以实现充电刀20与充电槽6的“接触通路,脱前断路”,具有受流稳定性好、可靠性高、安全性高等优点。
下面结合附图描述根据本申请一个实施例的轨道交通系统900。该轨道交通系统900包括供电装置910,轨道920、充电轨300和轨道车辆800。
其中,充电轨300固定在绝缘子400上,绝缘子400安装在站台内,充电轨300与站内供电装置910相连。具体而言,如图20所示,绝缘子400包括绝缘支架71和绝缘压块72,绝缘支架71具有安装凹槽710,充电轨300的一部分贴合在该安装凹槽710内,绝缘压块72通过螺栓固定在绝缘支架71上,其中,绝缘压块72伸出至充电轨300的第一凹槽601和第二凹槽602处并压紧在第一凹槽601和第二凹槽602的侧面上,实现对充电轨300的紧固作用。
充电轨300可以是对称的两部分,图示意了充电轨300的截面,在该截面上,每一部分包括依次相连的防刮擦内钩65、接触轨段、轨顶、轨腰、凹槽底段、凹槽斜段、轨座直段、轨座斜段和轨座底段,两部分的轨座底段相连。
轨道车辆800具有集电靴100,集电靴100与车体810内的储电装置820相连。其中,集电靴100主要包括:滑动座总成1、滑动架10b、充电刀总成2和弹性复位结构5和缓冲件3。
其中,滑动座总成1通过紧固件与车体810的绝缘座200固连,滑动架10b与滑动座总成1通过梯形槽配合方式实现可平动连接,其他组件均直接或间接的安装于滑动架10b上:包括充电刀总成2的连杆21,连杆21穿过套环42和滑动架10b上的通孔101,连杆21的外周套设有缓冲件3,连杆21下端与充电刀20相连,连杆21上端通过限位螺母加以固定,使缓冲件3具备一定的压缩量,防止由于弹力作用而脱离滑动架10b,连杆21与充电刀20通过紧固件相连。
充电靴在自由状态下,缓冲件3处于压缩状态,使得充电刀20始终保持有向下运动的趋势,但由于此时连杆21与限位螺母的限位作用而保持原位。在通过分叉式引导带运行至充电刀20完全嵌入充电槽6的过程中,由于引导槽64的作用及接触面倾角存在,使得充电刀20受沿连杆21的方向的合力作用,此时的合力克服缓冲件3的压缩力,使连杆21向上移动,直至充电刀20和充电轨300稳定接触。
图14-图16为充电刀20三视图。由于采用充电刀20侧面接触的集电型式,为了保证一定的接触压力,刀-槽配合面均倾斜一定角度,因此充电刀20特制为楔形,整体形状为上部宽度向下逐渐变窄,前后导向面向中部逐渐加宽。其中,充电刀20的中部位置有容纳槽203,该容纳槽203尺寸与线鼻24大小相匹配。图12和图13分别示意了线鼻24安装前后的状态,此时线鼻24插入该容纳槽203相应位置处,采用内六角螺栓实现线鼻24与充电刀20的稳定连接。
弹性复位结构5包括对称分布的两个弹簧,每个弹簧的一端抵压在滑动座总成1上, 且另一端作用在滑动架10b的支座102上,并且每个弹簧都具备一定的预压量,滑动架10b上设有用于安装弹簧的容置槽103,弹簧被定为在滑动座总成1和滑动架10b之间且容纳在容置槽103内,以防止弹簧跳出,起到限位作用。
偏移补偿功能主要通过滑动座总成1,滑动架10b及两个弹簧实现。其中,滑动座总成1与滑动架10b通过梯形槽配合,使得滑动架10b可相对滑动座总成1沿横向往返顺利滑动;受预压对称布置的两个弹簧,每个弹簧的一端作用在固连的滑动座总成1上,另一端作用在可滑动的滑动架10b处,当滑动架10b未受到沿弹簧轴向作用力时,在对称的预压力作用下,滑动架10b处于中间初始位置,即平衡位置;当受到外力作用时,两个弹簧的平衡关系被打破,滑动架10b开始朝受力方向移动,当外力消失后,在预压力作用下滑动架10b又回到平衡位置。
由于滑动架10b的支座102的存在,使得滑动架10b不能使用端部滑入的方式进行装配,在一些实施例中,可以采用侧向嵌入式装配法,滑动座总成1包括沿横向延伸的第一滑块座111和沿横向延伸第二滑块座112,二者通过螺栓固连。
其中,第一滑块座111和第二滑块座112之间形成梯形槽,滑动架10b构造为梯形楔。装配后,两个弹簧分别位于滑动座总成1和滑动架10b之间并卧于容置槽103之上。由于两个弹簧均处于压缩状态,配合滑动座总成1对容置槽103上部的封盖,可以实现对弹簧的位置限定。另外,滑动架10b的滑动接触面沿滑动方向开有储油槽12,以便尽可能的保持滑动接触面的润滑效果,减小摩擦。
对比图10和图11,当充电刀20受到左侧的作用力时,滑动架10b会顺着梯形槽向受力方向移动,受力一侧的偏移弹簧受到二次压缩而另一侧弹簧得以舒张,右侧受力时同理;当处于自由状态时在两弹簧平衡力作用下最后稳定于中间初始位置,即可实现偏移补偿功能。
根据本申请实施例的轨道车辆800以及轨道交通系统900的其他构成以及操作对于本领域普通技术人员而言都是已知的,这里不再详细描述。
在本说明书的描述中,参考术语“一个实施例”、“一些实施例”、“示意性实施例”、“示例”、“具体示例”、或“一些示例”等的描述意指结合该实施例或示例描述的具体特征、结构、材料或者特点包含于本申请的至少一个实施例或示例中。在本说明书中,对上述术语的示意性表述不一定指的是相同的实施例或示例。而且,描述的具体特征、结构、材料或者特点可以在任何的一个或多个实施例或示例中以合适的方式结合。
尽管已经示出和描述了本申请的实施例,本领域的普通技术人员可以理解:在不脱离本申请的原理和宗旨的情况下可以对这些实施例进行多种变化、修改、替换和变型, 本申请的范围由权利要求及其等同物限定。

Claims (10)

  1. 一种充电刀,其特征在于,所述充电刀沿轨道车辆的行驶方向延伸,且在垂直于所述轨道车辆的行驶方向的方向上,所述充电刀的相对的两侧表面分别设有第一受流面和第二受流面,由所述充电刀的靠近所述轨道车辆的一端至远离所述轨道车辆的一端,所述第一受流面和所述第二受流面之间的间距逐渐减小。
  2. 根据权利要求1所述的充电刀,其特征在于,所述第一受流面和所述第二受流面中的其中一个沿竖向延伸,且其中另一个相对于竖向倾斜延伸;或者,所述第一受流面和所述第二受流面沿朝向彼此的方向倾斜延伸。
  3. 根据权利要求2所述的充电刀,其特征在于,在沿所述轨道车辆的行驶方向上,所述充电刀的横截面积由中部朝向两端逐渐减小。
  4. 根据权利要求1-3中任一项所述的充电刀,其特征在于,所述充电刀上设有适于安装线鼻的容纳槽,所述容纳槽设在所述充电刀的靠近所述轨道车辆的一端。
  5. 根据权利要求4所述的充电刀,其特征在于,所述容纳槽在竖向方向上延伸至所述充电刀的靠近所述轨道车辆的端面。
  6. 根据权利要求5所述的充电刀,其特征在于,所述容纳槽在横向上连通所述第一受流面和所述第二受流面。
  7. 一种充电刀总成,其特征在于,所述充电刀总成包括:
    连杆,所述连杆的一端与所述轨道车辆相连;
    充电刀,所述充电刀为根据权利要求1-6中任一项所述的充电刀,所述充电刀与所述连杆的远离所述轨道车辆的一端相连。
  8. 根据权利要求7所述的充电刀总成,其特征在于,在垂直于所述轨道车辆的方向上,所述充电刀总成相对于所述轨道车辆可相对运动。
  9. 一种轨道交通系统,包括:
    供电装置;
    轨道,所述轨道包括沿所述轨道车辆行驶方向延伸的轨道梁;
    充电轨,所述充电轨上具有沿所述轨道车辆的行驶方向延伸的充电槽,所述充电轨与所述供电装置电连接;
    轨道车辆,所述轨道车辆跨坐于所述轨道上,所述轨道车辆设有根据权利要求7或8所述的充电刀总成所述充电刀适于可离合地沿所述充电槽滑动。
  10. 根据权利要求9所述的轨道交通系统,其特征在于,还包括:
    检测装置,所述检测装置用于检测所述充电刀与所述充电槽的相对位置信息;
    控制器,所述控制器分别与所述检测装置和所述供电装置相连,所述控制器根据所述检测装置检测的所述相对位置信息控制所述供电装置,以在所述充电刀与所述充电槽接触时通电,并在所述充电刀与所述充电槽分离时断电。
PCT/CN2019/073570 2018-02-06 2019-01-29 充电刀、充电刀总成和轨道交通系统 WO2019154166A1 (zh)

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