CN210793157U - Magnetomotive force rapid conveying system - Google Patents

Abstract

The utility model discloses a magnetomotive force transports system fast, this magnetomotive force transports system fast includes track, walking car and magnetic drive device, wherein: the track is provided with a plurality of driving sections and at least one inertia section, and any two driving sections are connected through one inertia section; the walking vehicle comprises a bogie and a carrying plate arranged on the bogie, and the bogie runs on the track; the magnetic driving device comprises a first driving piece arranged on the driving section and a second driving piece arranged on the bogie, and magnetic force is generated between the second driving piece and the first driving piece so as to drive the walking vehicle to move along the track. The utility model discloses technical scheme simplifies walking car and orbital structure, has reduced the maintenance cost, still has resources are saved, energy saving's effect simultaneously.

Description

Magnetomotive force rapid conveying system

Technical Field

The utility model relates to a track traffic technical field, in particular to magnetomotive force transports system fast.

Background

With the continuous development of human society, the transportation technology is changed day by day, and as the scale of cities is increased, the pressure of the existing road transportation is increased. The conventional road transportation can not meet the transportation requirements of people due to the problems of traffic jam, high pollution and the like, and the rail transit has a special rail to avoid the problem of traffic jam, so that the rail transit is widely popularized. However, most of the existing rail transit systems are driven by a rotating motor and a mechanical transmission mechanism, and energy loss exists in the process of converting the rotating motion of the motor into the motion of the vehicle along the rail, and the structures of the vehicle and the rail are complex, so that the maintenance cost is high.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing a magnetomotive force rapid transportation system, aims at simplifying the structure of walking car and track, reduces the maintenance cost.

In order to achieve the above object, the utility model provides a magnetomotive force transports system fast, include:

the track is provided with a plurality of driving sections and at least one inertia section, and any two driving sections are connected through one inertia section;

the walking vehicle comprises a bogie and a carrying plate arranged on the bogie, and the bogie runs on the track; and

and the magnetic driving device comprises a first driving piece arranged on the driving section and a second driving piece arranged on the bogie, and magnetic force is generated between the second driving piece and the first driving piece so as to drive the travelling vehicle to move along the track.

Preferably, the driving section is linearly disposed, and the inertia section is arcuately disposed in a horizontal plane.

Preferably, the track comprises two parallel rails, and the first driving member comprises a long stator of a linear motor installed between the two rails; the second driving piece comprises a vehicle side induction plate installed at the bottom of the bogie; or

The track comprises two parallel steel rails, and the first driving piece comprises a ground side induction plate arranged between the two steel rails; the second driving piece comprises a stator of a linear motor arranged at the bottom of the bogie.

Preferably, the track comprises two parallel rails, and the first driving member comprises a long stator of a linear motor installed between the two rails;

the second driving piece comprises a plurality of rotor magnetic poles arranged at the bottom of the bogie, and the rotor magnetic poles are arranged at intervals along the extending direction of the track.

Preferably, the bogie comprises a frame and a pair wheel mounted on the lower side of the frame, the carrying plate is mounted on the frame, the pair wheel comprises an axle, axle boxes and wheels, two axle boxes and two wheels are arranged on the axle, the two axle boxes are respectively mounted at two ends of the axle, the two wheels are respectively mounted at two ends of the axle, and the two wheels are located between the two axle boxes;

the walking vehicle further comprises a first vibration damping piece, one end of the first vibration damping piece is connected with the axle box, and the other end of the first vibration damping piece is connected with the lower surface of the framework.

Preferably, the walking vehicle further comprises a second vibration damping member, one end of the second vibration damping member is connected with the carrying plate, and the other end of the second vibration damping member is connected with the framework.

Preferably, the walking vehicle further comprises a locking piece arranged on the delivery plate, and the locking piece is used for fixing the object to be carried placed on the delivery plate.

Preferably, the number of the walking vehicles is multiple, and the walking vehicles are detachably connected in sequence along the length direction of the track.

Preferably, the magnetomotive force rapid transport system further comprises: the control device is connected with each converter, the converters are connected with the first driving piece in a one-to-one correspondence mode, and two adjacent converters form a power supply interval on the track;

the control device is used for controlling the adjacent power supply sections to supply power to the fault sections when any power supply section has a fault.

Preferably, the control device includes: the interval power supply module comprises a first power supply loop, a second power supply loop, a switch circuit, a first voltage detection circuit, a second voltage detection circuit and a control circuit;

the switch circuit is connected between the first power supply loop and the second power supply loop, the first voltage detection circuit is connected in parallel on the first power supply loop, the second voltage detection circuit is connected in parallel on the second power supply loop, a signal output end of the first voltage detection circuit and a signal output end of the second voltage detection circuit are respectively connected with a signal end of the control circuit, and a controlled end of the switch circuit is connected with a control end of the control circuit;

the first voltage detection circuit is used for detecting the working voltage of the first power supply loop and outputting a first voltage feedback signal;

the second voltage detection circuit is used for detecting the working voltage of the second power supply loop and outputting a second voltage feedback signal;

the control circuit is configured to determine a working state of the first power supply loop or the second power supply loop according to the first voltage feedback signal and the second voltage feedback signal, and control the switching circuit to be turned on when the first power supply loop or the second power supply loop works abnormally, so that the first power supply loop or the second power supply loop supplies power to another power supply loop.

The technical scheme of the utility model is that the first driving piece is arranged on the driving section of the guide rail, the second driving piece is arranged on the bogie of the traveling vehicle, magnetic force is generated between the second driving piece and the first driving piece to drive the traveling vehicle to move along the rail, so that the traveling vehicle is driven by adopting a linear driving mode, a rotating motor is prevented from being arranged on the traveling vehicle, the structure of a magnetic power rapid transportation system is simplified, and the maintenance cost is reduced; in addition, this scheme still adopts the track that has drive section and inertia section, is connected through an inertia section between two arbitrary drive sections, and first driving piece only installs in the drive section, and consequently, the walking car only receives magnetic force drive when traveling in the drive section, and when traveling in the inertia section, can rely on self inertia to continue to move. So, because the length of laying of first driving piece reduces greatly, can show on the one hand and reduce the cost of laying, on the other hand has also reduced the power supply volume of first driving piece, realizes resources are saved, the effect of energy saving.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings needed to be used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the structures shown in the drawings without creative efforts.

Fig. 1 is a schematic structural view of a traveling vehicle on a track in an embodiment of the magnetomotive force rapid transportation system of the present invention;

FIG. 2 is a schematic structural view of the walking vehicle of FIG. 1;

FIG. 3 is a schematic structural view of the magnetic driving apparatus of FIG. 1 in one embodiment;

FIG. 4 is a schematic structural view of the magnetic driving apparatus of FIG. 1 in another embodiment;

FIG. 5 is a schematic structural view of the magnetic drive apparatus of FIG. 1 in a preferred embodiment;

FIG. 6 is a schematic diagram of a portion of the track of FIG. 1 in one embodiment;

FIG. 7 is a schematic diagram of the magnetomotive force rapid transportation system when multiple traveling vehicles are used in tandem operation;

FIG. 8 is a schematic diagram of the magnetomotive force rapid transport system of the present invention employing an interval power supply scheme;

FIG. 9 is a schematic diagram of the power supply for the magnetomotive force rapid transport system of FIG. 8;

fig. 10 is a circuit diagram of a control circuit of the magnetomotive force rapid transport system of fig. 9.

The reference numbers illustrate:

the objects, features and advantages of the present invention will be further described with reference to the accompanying drawings.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative efforts belong to the protection scope of the present invention.

It should be noted that, if directional indications (such as upper, lower, left, right, front and rear … …) are involved in the embodiment of the present invention, the directional indications are only used to explain the relative position relationship between the components, the motion situation, etc. in a specific posture (as shown in the drawings), and if the specific posture is changed, the directional indications are changed accordingly.

In addition, if there is a description relating to "first", "second", etc. in the embodiments of the present invention, the description of "first", "second", etc. is for descriptive purposes only and is not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include at least one such feature. In addition, the technical solutions in the embodiments may be combined with each other, but it must be based on the realization of those skilled in the art, and when the technical solutions are contradictory or cannot be realized, the combination of the technical solutions should not be considered to exist, and is not within the protection scope of the present invention.

The utility model provides a magnetomotive force transports system fast.

In an embodiment of the present invention, referring to fig. 1, fig. 2 and fig. 6, the magnetomotive force rapid transportation system 1 includes:

the track 10 is provided with a plurality of driving sections 101 and at least one inertia section 102, and any two driving sections 101 are connected through one inertia section 102;

the walking vehicle 20 comprises a bogie 210 and a carrying plate 220 arranged on the bogie 210, wherein the bogie 210 runs on the track 10; and

the magnetic driving device 30 includes a first driving member 310 mounted on the driving section 101, and a second driving member 320 mounted on the bogie 210, wherein a magnetic force is generated between the first driving member 310 and the second driving member 320 to drive the traveling carriage 20 to move along the track 10.

Specifically, the magnetomotive force rapid transport system 1 mainly comprises a track 10, a traveling vehicle 20 and a magnetic driving device 30, wherein the traveling vehicle 20 comprises a bogie 210 and a carrying plate 220, the traveling vehicle 20 is arranged on the track 10 in a sliding mode through the bogie 210, the carrying plate 220 is arranged on the upper side of the bogie 210, and the carrying plate 220 can be used for carrying people and/or goods. For example, when the pallet 220 is used for cargo transportation, cargo may be carried directly on the pallet 220 or a container (e.g., a container) may be mounted on the pallet 220 to enhance the loading and unloading of the cargo. The magnetomotive force rapid transportation system 1 can be applied to various occasions, such as on the ground, on a viaduct or in an underground tunnel, and is not limited in particular.

The magnetic driving apparatus 30 includes a first driving member 310 and a second driving member 320 capable of generating a magnetic force in an energized state, wherein a direction of the magnetic force generated between the first driving member 310 and the second driving member 320 is set along an extending direction of the track 10, and since the first driving member 310 is mounted on the track 10, the second driving member 320 is mounted on the bogie 210 of the carriage 20, thereby driving the carriage 20 to move relative to the track 10 under the driving of the magnetic force generated by the first driving member 310 and the second driving member 320.

It should be noted that the first driving member 310 is usually laid along the track 10, and long-distance laying inevitably causes a straight surge in the laying cost of the track 10, and thus actual production at medium and long distances cannot be realized. In this embodiment, in order to reduce the cost, the track 10 has the driving sections 101 and the inertia sections 102, any two driving sections 101 are connected through one inertia section 102, and the first driving member 310 is only installed on the driving section 101, so that the traveling vehicle 20 is driven by the magnetic force only when traveling through the driving section 101, and can continue to move by its own inertia when traveling through the inertia section 102. So, because the length of laying of first driving piece 310 reduces greatly, can show the laying cost that reduces on the one hand, on the other hand has also reduced the power supply volume of first driving piece 310, realizes resources are saved, the effect of energy saving.

The utility model discloses technical scheme is through installing first driving piece 310 on the drive section 101 of guide rail, install second driving piece 320 on the bogie 210 of walking car 20, second driving piece 320 drives walking car 20 and removes along track 10 under the magnetic force effect of first driving piece 310, realized adopting the linear driving mode to drive walking car 20, avoid installing the rotating electrical machines on walking car 20, the structure of the quick transport system 1 of magnetomotive force has been simplified, maintenance cost is reduced.

Further, in the present embodiment, the driving link 101 is linearly provided in the horizontal plane, and the inertia link 102 is arcuately provided in the horizontal plane, so that the track 10 is curved in the inertia link 102, and the traveling vehicle 20 can be steered. When the traveling vehicle 20 passes through the inertia section 102, the traveling vehicle 20 is not driven by magnetic force, and only moves by means of inertia, so that the condition that the speed of the traveling vehicle 20 is too high when the vehicle turns is avoided, the risk probability of potential safety hazard of curve rollover of the traveling vehicle 20 is reduced, and the safety of the magnetomotive force rapid transportation system 1 is ensured.

It should be noted that, for the track 10, the inertia segment 102 may be disposed at a turning position of the track 10, and may also be disposed in a straight line segment of the track 10, at this time, the inertia segment 102 may also be disposed in a straight line, and the straight line segment and the inertia segment 102 are sequentially and alternately disposed, so as to reduce a laying length of the first driving member 310 at the straight line segment of the track 10, and achieve the effects of saving resources and saving energy.

In one embodiment of this embodiment, referring to fig. 3, the magnetic driving device 30 is implemented by using a structure of a long stator linear induction motor, wherein: the track 10 comprises two parallel arranged rails 100, the first driving member 310 comprises a long stator 311 of a linear motor installed between the two rails 100; the second driver 320 includes a vehicle-side sensing plate 321 mounted to the bottom of the bogie 210. The long stator 311 of the linear motor located between the ground rails 100 is fed with three-phase sinusoidal alternating current, so that a rotating magnetic field is generated in the air gap, the rotating magnetic field cuts the vehicle-side induction plate 321, an induced current is generated in the vehicle-side induction plate 321, the induced current interacts with the air gap magnetic field to generate electromagnetic force, and the electromagnetic force makes the vehicle-side induction plate 321 move relative to the ground, so as to push the traveling vehicle 20 to move on the rails 100. The vehicle-side induction plate 321 is preferably a metal plate capable of generating an induction current in a magnetic field, and more preferably an aluminum plate.

In another embodiment of this embodiment, referring to fig. 4, the magnetic driving device 30 is implemented by using a structure of a short stator linear induction motor, wherein: the track 10 comprises two parallel rails 100, and the first driving member 310 comprises a ground side induction plate 312 installed between the two rails 100; the second drive member 320 includes a stator 322 of a linear motor mounted to the bottom of the bogie 210. The stator 322 of the linear motor located at the bottom of the bogie 210 is fed with three-phase sinusoidal alternating current, so that a rotating magnetic field is generated in the air gap, the rotating magnetic field cuts the ground-side induction plate 312, an induction current is generated in the ground-side induction plate 312, the induction current interacts with the air gap magnetic field to generate an electromagnetic force, and the electromagnetic force causes the stator 322 of the linear motor to move relative to the ground, so as to push the traveling vehicle 20 to move on the steel rail 100. The ground-side induction plate 312 is preferably a metal plate capable of generating an induction current in a magnetic field, and more preferably an aluminum plate.

In a preferred embodiment of this embodiment, referring to fig. 5, the magnetic driving device 30 is implemented by using a structure of a long stator synchronous linear motor, wherein: the track 10 comprises two parallel arranged rails 100, the first driving member 310 comprises a long stator 311 of a linear motor installed between the two rails 100; the second driving member 320 includes a plurality of mover poles 323 installed at the bottom of the bogie 210, and the plurality of mover poles 323 are arranged at intervals along the extending direction of the track 10. The long stator 311 of the linear motor located between the ground rails 100 is fed with three-phase sinusoidal alternating current to generate a rotating magnetic field in the air gap, and the mover magnetic pole 323 has magnetism and moves under the action of the rotating magnetic field to push the traveling carriage 20 to move on the rails 100. It is understood that the mover poles 323 may be formed of permanent magnets and/or electromagnetic coils.

It can be understood that, in the embodiment, the traveling vehicle 20 directly adopts the linear driving mode, so that the energy consumption loss caused when the conventional motor converts the rotary motion into the linear motion is avoided, and the driving efficiency is further improved.

In this embodiment, with continued reference to fig. 1 and 2, the bogie 210 includes a frame 212 and a pair of wheels 211 mounted on a lower side of the frame 212, the carrying plate 220 is mounted on the frame 212, the pair of wheels 211 includes an axle 211a, an axle box 211b, and wheels 211c, the axle box 211b and the wheels 211c are both provided with two axle boxes 211b, the two axle boxes 211b are respectively mounted on two ends of the axle 211a, the two wheels 211c are respectively mounted on two ends of the axle 211a, and the two wheels 211c are located between the two axle boxes 211 b; the traveling vehicle 20 further includes a first damper 213, and one end of the first damper 213 is connected to the axle box 211b and the other end is connected to the lower surface of the frame 212. The wheel 211c is in contact with the rail 100, the wheel 211c and the axle 211a are connected by a bearing, and the axle box 211b contains lubricating oil, so that the bearing can be lubricated, and the frictional resistance between the wheel 211c and the axle 211a can be reduced. By providing the first vibration dampers 213, vibration of the traveling vehicle 20 during traveling can be reduced and a noise reduction effect can be achieved.

Further, the traveling vehicle 20 further includes a second vibration damper 230, and one end of the second vibration damper 230 is connected to the pallet 220 and the other end is connected to the frame 212. In this way, the first vibration damper 213 and the second vibration damper 230 achieve a two-stage vibration damping effect, and can significantly reduce the vibration of the traveling vehicle 20 during traveling and reduce noise.

In this embodiment, the walking vehicle 20 further includes a locking element 240 disposed on the carrying board 220, and the locking element 240 is used for fixing the object to be carried placed on the carrying board 220 to the carrying board 220. Of course, the locking elements 240 may also be used to secure containers (e.g., containers) to the pallet 220. In some preferred embodiments, the locking member 240 is preferably an electrically controlled lock, and the electrically controlled lock is connected to a speed sensor of the control system, when the traveling vehicle 20 travels, the speed sensor detects a speed change of the traveling vehicle 20, so as to feed back a control electrical signal to the control system, and the control system sends an automatic locking signal to the electrically controlled lock, so that the object to be carried is firmly fixed to the carrying board 220, thereby ensuring the safety during the transportation of the goods.

Further, referring to fig. 7, in order to improve the transportation capability of the magnetic power rapid transportation system 1, the number of the traveling vehicles 20 may be multiple, and the multiple traveling vehicles 20 are detachably connected in sequence along the length direction of the track 10, so that the multiple traveling vehicles 20 can be operated in a reconnection manner, and the transportation capability is improved.

In this embodiment, referring to fig. 8, the magnetomotive force rapid transport system 1 further includes: the control device 40, the power supply station 50 and the plurality of converters 60, the plurality of converters 60 are sequentially connected end to end, the control device 40 is respectively connected with each converter 60, the converters 60 are correspondingly connected with the first driving member 310 one by one, and two adjacent converters 60 form a power supply interval on the track 10; the control device 40 is configured to control the adjacent power supply sections to supply power to the failure section when any power supply section fails. The number of the power supply stations 50 is plural, and any one power supply station 50 may be distributed between two adjacent converters 60.

It can be understood that the magnetomotive force rapid transportation system 1 adopts a scheme of interval power supply, when a traveling vehicle 20 runs in each power supply area, the control device 40 controls the converter 60 in the corresponding power supply area to be switched on, so as to supply power to the power supply area, and ensure the normal running of the traveling vehicle 20 in the power supply area. In the practical application process, the transportation line usually adopts the high-voltage transmission mode to carry out long distance transmission, and when the transmission line is along with the increase of line, power loss also can progressively increase. And the section power supply mode is adopted, so that the length of a power line in each power supply section can be greatly reduced, and the reduction of power loss is facilitated. In addition, the control device 40 also realizes the function of supplying power to the power supply section with faults, so that the transportation reliability and the practicability of the magnetomotive force rapid transportation system 1 are improved.

Further, referring to fig. 8 to 10, the control device 40 includes a section power supply module 400, where the section power supply module 400 includes a first power supply circuit 410, a second power supply circuit 420, a switch circuit 430, a first voltage detection circuit 440, a second voltage detection circuit 450, and a control circuit 460; the switching circuit 430 is connected between the first power supply loop 410 and the second power supply loop 420, the first voltage detection circuit 440 is connected in parallel to the first power supply loop 410, the second voltage detection circuit 450 is connected in parallel to the second power supply loop 420, a signal output end of the first voltage detection circuit 440 and a signal output end of the second voltage detection circuit 450 are respectively connected with a signal end of the control circuit 460, and a controlled end of the switching circuit 430 is connected with a control end of the control circuit 460; a first voltage detection circuit 440, configured to detect a working voltage of the first power supply loop 410 and output a first voltage feedback signal; the second voltage detection circuit 450 is configured to detect a working voltage of the second power supply loop 420 and output a second voltage feedback signal; the control circuit 460 is configured to determine an operating state of the first power supply loop 410 or the second power supply loop 420 according to the first voltage feedback signal and the second voltage feedback signal, and control the switch circuit 430 to be turned on when the first power supply loop 410 or the second power supply loop 420 operates abnormally, so that the first power supply loop 410 or the second power supply loop 420 supplies power to another power supply loop.

With further reference to fig. 9 and 10, the magnetomotive force rapid transport system 1 includes a power supply interval a and a power supply interval B, where the power supply interval a is a first power supply loop 410, the power supply interval B is a second power supply loop 420, and when the first power supply loop 410 and the second power supply loop 420 work normally, the contactor KM is in a disconnected state; when power supply of any one of the power supply regions a and B is interrupted, namely one of the first power supply loop 410 and the second power supply loop 420 is abnormal, the control circuit 460 sends an extended power supply instruction, the relay K3 is powered on, and the corresponding auxiliary contact is also pulled in. The voltage detection relays K1 and K2 can ensure that under normal working conditions, the extended power supply instruction is triggered by mistake in time, and the KM contactor cannot be powered on or off.

In addition, not generally, the braking scheme of the magnetic power rapid transportation system 1 may have various implementation manners, for example, a reverse current may be introduced into the magnetic driving device 30 to generate an electromagnetic braking force opposite to the traveling direction of the traveling vehicle 20, so as to control the deceleration and braking of the traveling vehicle 20; or the wheels 211c of the traveling vehicle 20 may be braked by a conventional mechanical braking structure (including a drum brake structure, a disc brake structure, etc.), so as to achieve a deceleration and braking effect; alternatively, other structures for increasing the wind resistance of the traveling vehicle 20 and the friction between the wheels 211c and the ground may be used to achieve the deceleration and braking effects of the traveling vehicle 20, which are not illustrated herein.

The above only is the preferred embodiment of the present invention, not limiting the scope of the present invention, all the equivalent structure changes made by the contents of the specification and the drawings under the inventive concept of the present invention, or the direct/indirect application in other related technical fields are included in the patent protection scope of the present invention.

Claims (10)

1. A magnetomotive force rapid transport system, comprising:

the track is provided with a plurality of driving sections and at least one inertia section, and any two driving sections are connected through one inertia section;

the walking vehicle comprises a bogie and a carrying plate arranged on the bogie, and the bogie runs on the track; and

and the magnetic driving device comprises a first driving piece arranged on the driving section and a second driving piece arranged on the bogie, and magnetic force is generated between the second driving piece and the first driving piece so as to drive the travelling vehicle to move along the track.

2. Magnetomotive force rapid transport system according to claim 1, wherein said drive section is arranged linearly and said inertia section is arranged arcuately in a horizontal plane.

3. Magnetomotive rapid transport system according to claim 1, wherein said track comprises two parallel arranged rails, said first drive member comprising a long stator of a linear motor mounted between said rails; the second driving piece comprises a vehicle side induction plate installed at the bottom of the bogie; or

The track comprises two parallel steel rails, and the first driving piece comprises a ground side induction plate arranged between the two steel rails; the second driving piece comprises a stator of a linear motor arranged at the bottom of the bogie.

4. Magnetomotive rapid transport system according to claim 1, wherein said track comprises two parallel arranged rails, said first drive member comprising a long stator of a linear motor mounted between said rails;

the second driving piece comprises a plurality of rotor magnetic poles arranged at the bottom of the bogie, and the rotor magnetic poles are arranged at intervals along the extending direction of the track.

5. Magnetomotive force rapid transport system according to claim 1, wherein said bogie comprises a frame and an axle box mounted on the frame, and wherein said pallet is mounted on said frame, and wherein said axle box and said wheels are provided in two, and wherein said axle box is mounted on each end of said axle, and wherein said wheels are located between said axle boxes;

the walking vehicle further comprises a first vibration damping piece, one end of the first vibration damping piece is connected with the axle box, and the other end of the first vibration damping piece is connected with the lower surface of the framework.

6. Magnetomotive rapid transport system according to claim 5, wherein said walking vehicle further comprises a second vibration dampening member, said second vibration dampening member being connected at one end to said pallet and at the other end to said frame.

7. Magnetomotive force rapid transport system according to claim 1, wherein said walking vehicle further comprises a locking element provided on said pallet board for securing a load placed on said pallet board to said pallet board.

8. Magnetomotive force rapid transport system according to claim 1, wherein said travelling vehicles are in plurality, and a plurality of travelling vehicles are detachably connected in sequence along the length direction of said track.

9. The magnetomotive force rapid transportation system according to any one of claims 1 to 8, further comprising a control device, a power supply station and a plurality of current transformers, wherein the plurality of current transformers are sequentially connected end to end, the control device is respectively connected with each current transformer, the current transformers are connected with the first driving member in a one-to-one correspondence manner, and two adjacent current transformers form a power supply interval on the track;

the control device is used for controlling the adjacent power supply sections to supply power to the fault sections when any power supply section has a fault.

10. Magnetomotive force rapid transport system according to claim 9, wherein said control means comprises: the interval power supply module comprises a first power supply loop, a second power supply loop, a switch circuit, a first voltage detection circuit, a second voltage detection circuit and a control circuit;

the switch circuit is connected between the first power supply loop and the second power supply loop, the first voltage detection circuit is connected in parallel on the first power supply loop, the second voltage detection circuit is connected in parallel on the second power supply loop, a signal output end of the first voltage detection circuit and a signal output end of the second voltage detection circuit are respectively connected with a signal end of the control circuit, and a controlled end of the switch circuit is connected with a control end of the control circuit;

the first voltage detection circuit is used for detecting the working voltage of the first power supply loop and outputting a first voltage feedback signal;

the second voltage detection circuit is used for detecting the working voltage of the second power supply loop and outputting a second voltage feedback signal;

the control circuit is configured to determine a working state of the first power supply loop or the second power supply loop according to the first voltage feedback signal and the second voltage feedback signal, and control the switching circuit to be turned on when the first power supply loop or the second power supply loop works abnormally, so that the first power supply loop or the second power supply loop supplies power to another power supply loop.

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