CN214564766U - Force transmission mechanism, side shift cantilever positioner and remove contact net - Google Patents

Abstract

The utility model relates to a power transmission mechanism, side shift cantilever positioner and removal contact net, including the moving member, pass power piece and rotary mechanism, wherein, rotary mechanism sets up at the cantilever structurally, pass the power piece setting on rotary mechanism, the moving member sets up on passing power piece. The force transmission piece is used for transmitting force to the cantilever structure and pushing or pulling the cantilever structure to rotate; the moving part moves to compress or stretch the force transmission part, and the force transmission part forms thrust or pulls to drive the sleeve part to move; the sleeve transmits force to the wrist-arm structure, thereby pushing or pulling the wrist-arm structure to rotate. The utility model discloses can effectively eliminate the influence that construction error brought.

Description

Force transmission mechanism, side shift cantilever positioner and remove contact net

Technical Field

The utility model belongs to electronic railway removes the contact net field, concretely relates to water conservancy transmission mechanism, side shift cantilever positioner and remove the contact net.

Background

In the traditional railway loading and unloading, a diesel locomotive is adopted to pull a truck to enter and exit a loading and unloading operation area, the mode needs to replace a traction machine head, the railway locomotive is difficult to dispatch and has low efficiency, so that the resource waste is caused, and when a heavy-duty train is encountered, a plurality of shunting diesel locomotives are often needed to meet the traction requirement; in some coal mine departments, a dead zone is set in a loading and unloading operation area by a method that an electric locomotive slides through the loading and unloading operation area by inertia, so that the safety of the loading and unloading operation is ensured. The method of using the inertia of the electric locomotive to slide through the coal loading and unloading operation area is difficult to control the parking point of the locomotive, once the parking space is improperly controlled, the electric locomotive stops in the non-electricity area, and the train can be moved to the electricity area only by spending high rescue cost.

With the propulsion of the electric traction of railways, the electric locomotives are adopted to replace the internal combustion locomotives in the transportation of China railway trunks. Electrification is realized in a cargo handling line or warehousing maintenance, a rigid movable contact network is adopted, the existing rigid movable contact network system is complex in structure and inconvenient to install, the requirement on the use condition of the line is high, the structural reliability is poor, if the moving section of the movable contact network is at one side of the whole rail, one mode is to use a motor to drag a catenary cable, so that the contact cable is laterally moved to one side of the rail, and the mode has the conditions of insufficient dragging force and unstable operation for the long-distance movable contact network; in the other mode, the motor or the electric push rod is used for driving the rotating bracket to rotate so as to drive the moving section side of the whole moving contact net to move to one side of the rail, and in the mode, the bus bar is integrally arranged at the tail end of the rotating bracket, so that the driving synchronism of the motor or the electric push rod is difficult to control.

At present, one mode uses and is connected with wire rope on the heavy anchor arm, and wire rope passes through the assembly pulley, utilizes electric actuator's cooperation to realize the recovery of contact net, and another mode utilizes motor drive runing rest to realize the side and move.

With the innovation of the electrified railway technology, technical personnel in the field continuously innovate, upgrade the technical innovation and provide an electrified mobile contact network which can meet the requirements of cargo handling lines or warehousing maintenance.

SUMMERY OF THE UTILITY MODEL

In the prior art, a flexible movable contact net is also used, and a motor is used for directly dragging a catenary on one side of the flexible contact net to move a contact line to one side of a rail; also there is the cantilever that adopts mechanical drive to raise the contact net, even raise and also can not move the contact net to the railway outside completely, still can influence the loading and unloading of large cargo, if adopt and rotate the cantilever, with the contact net horizontal hunting to railway one side, also there is the defect that can not swing railway one side completely, its existence is following not enough:

1. expansion with heat and contraction with cold certainly can cause the extension of contact wire, catenary, probably leads to bow net trouble (train pantograph and catenary trouble), for example the compensation arrangement that adjusts the cable tension falls to the ground, the cantilever skew, locator breaks away from serious incident such as. If the contact wire is loosened and wound on a pantograph (a transverse plate which is high above the locomotive head) of the train, the contact net rod is dragged down, the locomotive falls off the track, and the carriage falls down, so that the consequence is very serious.

2. The carrier cable and the contact line are fixedly arranged on the rotating wrist arm, and construction errors exist in the spacing and verticality between the stand columns and the tension degree of the carrier cable and the contact line between the wrist arms.

According to the main technical policy of the existing railway, 5000t heavy-load freight trains are driven, the effective length of the arrival and departure line of a station is 1050m, 10000t heavy-load freight trains are driven on a special coal conveying line, and the effective length of the arrival and departure line of part of stations is 1700 m. For such a long-distance heavy-duty train, for example, a ten thousand-ton heavy-duty train of 1400m to 1700m, due to the influence of thermal expansion and cold contraction and the existence of construction errors, when the moving contact net rotates above the railway or to the side of the railway, the moving contact net may not rotate in place.

The existing method is that a weight is arranged at one end of a mobile contact network, a dragging mechanism is arranged at the other end of the mobile contact network, and a catenary cable and/or a contact line are/is pulled by the dragging mechanism, so that the contact line is moved from one side edge of a rail to the upper side of the rail or from the upper side of the rail to one side edge of the rail.

Through the continuous research and practice of the applicant, the above solution enables the effective implementation of driving the catenary and/or contact line to move to one side of the rail or above the rail, but in practice a new problem arises: the cantilever is arranged to rotate rightwards to drive the contact line and the catenary to move to one side of the rail, due to the characteristic of expansion with heat and contraction with cold of the contact line and the catenary, when the rightmost cantilever moves to one side of the rail (the cantilever is approximately parallel to the rail and can be understood as completely swinging to one side to leave a space above the rail), the rest of the cantilevers do not completely rotate to one side of the rail (the cantilever can be understood as not completely swinging to the rail once in the whole overhead contact system, for the long-distance overhead contact system, the swinging stops when swinging to the upper side of the rail side, because the rightmost cantilever swings in place), the rotation cantilever farther away from the right cantilever is smaller in offset, namely when the rightmost cantilever stops rotating, the rest of the cantilevers do not rotate to the position, particularly for the heavy-load train suitable for the long distance, the displacement is about 1600m, when the rightmost cantilever stops rotating after being in place, other cantilevers far away from the right-end cantilever are still in a state of not rotating in place, even above the side of a rail, so that the loading and unloading operation of other goods such as large goods yards, containers and the like can be influenced; in addition, due to the fact that the pantograph does not rotate in place, the pantograph is poor in power taking and contact or cannot contact and take power, and the driving-in or the driving-out of the freight train is affected.

The applicant has had a drawback in the part of the disclosure of the invention, and the proposal aimed at explaining this technical problem is also part of the creation of the invention, and the solution to this technical problem is not known in the prior art.

The existing flexible contact network technology comprises the existing practical application technology and does not disclose the defect and a related solution in the prior patent application document, the applicant believes that the scheme for solving the technical defect is provided in the industry for the first time, if the defect cannot be solved, the operation problem of the mobile contact network is directly influenced, so that the potential safety hazard exists in the commercial process of the mobile contact network, and therefore, the applicant provides a set of complete solution through research and applies for intellectual property protection.

In order to realize the purpose, the applicant provides a set of technical scheme which can effectively solve the defect that the movement of a catenary and a contact line is not in place in the existing mobile contact network, and compared with a rigid contact network, the mobile contact network has the advantages of lower cost, more reliable operation, less weather influence and simpler maintenance; the contact net provided by the application overcomes the defect that the original dragging mode is adopted for moving, the gravity supplementing mode is used for moving, and the integral movement of a longer distance (1600m-1700m) can be realized by effectively improving the existing contact net. The locomotive can meet the requirement of cargo handling lines or warehousing maintenance of the existing freight trains of the locomotives, and can be effectively applied to heavy-duty trains such as ten-thousand-ton trains.

In order to achieve the above purpose, it is a conventional practice to fix the catenary and the contact wire to the rotation wrist, and the rotation of the rotation wrist drives the catenary and the contact wire to move from one side of the rail to the upper side of the rail or from the upper side of the rail to one side of the rail. The applicant provides a mode of subverting the traditional arrangement through continuous research and innovation, namely the carrier cable and the contact wire are not fixedly fixed on the rotating wrist arm, so that the carrier cable and the contact wire can not be influenced by construction errors, thermal expansion and cold contraction in the rotating process.

The applicant provides two-direction technical ideas, wherein the first is that the catenary directly makes reciprocating movement on the cantilever structure, the mode also directly omits a catenary clamping seat and a contact wire contact seat in the traditional sense, and the second is that pulling force or pushing force formed in the movement process of the catenary is transmitted to the cantilever structure through a force transmission piece so as to push or pull the cantilever structure to rotate; of course, the other mode can be adopted, the cantilever structure is driven to rotate, and the force formed in the rotation process of the cantilever structure is transmitted to the catenary through the force transmission piece, so that the catenary is driven or pulled to move. The core thinking is that the carrier cable is not fixed to be died on the cantilever structure, only if not fixed to be died, just can overcome the influence that construction error brought to and overcome expend with heat and contract with cold and lead to the carrier cable not in place to rotate the problem, also only if not fixed to be died, just can realize further formation compensation, this patent maximum innovation point also is different from prior art's biggest difference point, and it has brought beneficial effect, has solved the technical problem that prior art can not the technique.

As for the driving mode of the cantilever structure, the dragging mechanisms at the two ends of the catenary and the contact line are not the research points of the patent, and the default patent is that the catenary and the contact line can be pulled to move left or right, or the cantilever structure can be driven to rotate, including using a rotating motor to drive the cantilever structure to rotate, or using an electric push rod or a hydraulic push rod to push the cantilever structure to rotate, namely, the catenary and the contact line can be pulled to move from one side of the rail to the upper side of the rail or from the upper side of the rail to one side of the rail.

In order to achieve the above object, the present invention provides in a first aspect a force transmission mechanism for use in a cantilever structure of a mobile contact system, comprising a moving member, a force transmission member and a rotating mechanism, wherein the rotating mechanism is disposed on the cantilever structure, and the force transmission member is used for transmitting a force to the cantilever structure to push or pull the cantilever structure to rotate; or

The force transmission piece is used for transmitting force to the moving piece and pushing or pulling the moving piece to move.

Further, the force transmission piece adopts the following mode:

first, the force-transmitting member includes a pushing member disposed on a moving member;

secondly, the force transfer member comprises an elastic force transfer member; or

Thirdly, the force transfer member comprises a pushing member and an elastic force transfer member.

The force transmission device further comprises a kit, wherein the kit is directly or indirectly arranged on the rotating mechanism, and the force transmission piece is arranged in the kit;

the moving part moves to push or pull the force transmission part, and the force transmission part forms thrust or pulls to drive the sleeve part to move; or

The cantilever structure rotates to push or pull the force transmission piece, and the force transmission piece forms thrust or pulls to drive the moving piece to move.

Furthermore, the pushing piece is arranged on the moving piece, and in the moving process of the moving piece, the pushing piece can directly or indirectly act on the sleeve.

Furthermore, the moving part compresses or stretches the elastic force transmission part through the pushing part to form pushing force or pulling force, and the sleeve part transmits the pushing force or the pulling force to the cantilever structure, so that the cantilever structure is pushed or pulled to rotate; or

The cantilever structure drives the external member to rotate, the external member directly or indirectly compresses or stretches the elastic force transmission member to form a pushing force or a pulling force, and the external member transmits the pushing force or the pulling force to the moving member so as to push or pull the moving member to move.

Further, the pushing piece is provided with an extending surface extending outwards;

when the force transmission piece comprises a pushing piece, the extension surface can be directly/indirectly pressed and contacted on the sleeve piece in the moving process; or

When the force transfer piece comprises the pushing piece and the elastic force transfer piece, the extension surface can be in press contact with the elastic force transfer piece in the moving process.

Furthermore, a supporting rotating shaft is arranged in the rotating mechanism and can rotate, and the sleeve is directly or indirectly arranged on the supporting rotating shaft.

Further, still include middle connecting piece, the external member sets up on middle connecting piece, middle connecting piece sets up on supporting the pivot.

Further, the moving part adopts any one of the following modes:

the first method comprises the following steps: the moving piece adopts a catenary; or

And the second method comprises the following steps: the moving member comprises a moving member body and catenary wires arranged at two ends of the moving member body.

The utility model discloses the second aspect provides a remove contact net side and move cantilever positioner, including the cantilever structure, wherein, at least one cantilever structure uses foretell power transmission mechanism.

The utility model discloses the third aspect provides a remove contact net, move cantilever positioner including at least one adoption foretell removal contact net side. Or; at least one cantilever structure in the mobile overhead line system uses the force transmission mechanism.

The contact lines are arranged as follows:

the first method comprises the following steps: the suspension device also comprises a suspension piece, wherein one end of the suspension piece is arranged on the catenary, and the other end of the suspension piece is connected with the contact line; or

And the second method comprises the following steps: the contact wire is arranged on the cantilever structure through the clamping structure;

further, when the first mode is used: the connecting piece is connected with the suspension piece at one end and is directly or indirectly arranged on the cantilever structure; or

The connecting piece is directly or indirectly arranged on the rotating mechanism.

The utility model adopts the above technical scheme at least have following beneficial effect:

1) the thrust or the pulling force formed in the catenary process acts on the cantilever structure by adopting the force transmission mechanism, so that the cantilever structure is pulled or pushed to rotate, the cantilever can be generally rotatably arranged on the stand column and can rotate under the action of any pushing force, and therefore, the force transmission piece is used for pushing or pulling the supporting device to rotate, even if one supporting device on the most edge rotates in place (the supporting device in place generally swings to one side of a railway), only the catenary needs to be further pulled, the force transmission piece can be used for pushing or pulling the further rotation of the cantilever structure to realize compensation, and the problem that all the cantilevers cannot swing in place in the existing mobile contact network can be solved.

2) The moving piece (carrier cable) and the cantilever structure have a relative movement relationship, the moving piece is arranged in a sliding mode, and the influence caused by construction errors and expansion with heat and contraction with cold is effectively overcome.

3) Adopt the utility model provides a flexible contact net carrier cable atress is more even, and the time limit for a project is short, receives factors such as weather, difference in temperature to influence for a short time, but the wide application improves on the basis of current contact net in various rugged environment, long service life, a great deal of advantage such as easy to assemble and maintenance, fixed contact net structure are similar.

4) Adopt the utility model provides a contact wire, ten thousand tons of heavy load trains will not adopt diesel locomotive to shunting the operation again, have overcome traditional needs multi-vehicle separation, can't pull the condition of heavy load train even, can satisfy ten thousand tons of train goods handling circuit or the demand of warehousing maintenance effectively, have improved work efficiency, very big expense of purchasing diesel locomotive, saved current to the diesel locomotive allocate, the cost of labor such as maintenance and overhaul.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings 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 these drawings without creative efforts.

FIG. 1 is a schematic view of the rotation of a movable contact net under the influence of thermal expansion and cold contraction and construction errors in the prior art;

FIG. 2 shows a first embodiment of the force transfer mechanism of the present invention;

FIG. 3 shows a second embodiment of the force transfer mechanism of the present invention;

FIG. 4 shows a third embodiment of the force transfer mechanism of the present invention;

FIG. 5 shows a fourth embodiment of the force transfer mechanism of the present invention;

FIG. 6 shows a fifth embodiment of the force transfer mechanism of the present invention;

FIG. 7 is a schematic view of the structure of the present invention with an intermediate connecting member;

FIG. 8 shows a first embodiment of the contact wire arrangement of the present invention;

FIG. 9 shows a second embodiment of the contact wire arrangement of the present invention;

fig. 10 is one of the schematic structural diagrams of the mobile contact net of the present invention;

fig. 11 is a second schematic view of the mobile contact system of the present invention.

In the figure: 1. a moving member; 2. a pusher member; 3. an elastic force transfer member; 4. a rotation mechanism; 41. a support shaft; 5. a wrist-arm structure; 6. a column; 7. a kit; 8. an intermediate connecting member; 9. a moving member body; 10. a catenary cable; 11. a suspension; 12. a connecting member; 13. a clamping structure; 14. a first weight structure; 15. a first weight structure; 16. a dragging mechanism; 17. spreading the noodles; 18. and (4) an intermediate piece.

Detailed Description

Reference will now be made in detail to the exemplary embodiments, examples of which are illustrated in the accompanying drawings. When the following description refers to the accompanying drawings, like numbers in different drawings represent the same or similar elements unless otherwise indicated. The embodiments described in the following exemplary embodiments do not represent all embodiments consistent with the present invention. Rather, they are merely examples of apparatus consistent with certain aspects of the invention, as detailed in the appended claims.

As shown in fig. 1, a schematic diagram of a conventional mobile catenary is configured in such a way that a cantilever rotates rightwards to drive a catenary to move to one side (non-working position) of a rail, because the catenary has construction errors and thermal expansion and cold contraction influences, when a rightmost cantilever a moves to one side of the rail (the cantilever is nearly parallel to the rail to give way to a space above the rail), the rest of the cantilevers (the cantilevers a to d) do not completely rotate to one side of the rail (it can be understood that at least one cantilever in the whole catenary does not completely swing to the rail once, for a long-distance catenary, the swing stops when the cantilever swings to the side above the rail, because the rightmost cantilever swings to the right), the offset of the rotating cantilever farther from the right cantilever is smaller, that is, when the rightmost cantilever stops rotating, the rest of the cantilevers do not rotate to the position, particularly for a heavy-load train suitable for a long distance, the length of about 1600m is moved, when the rightmost cantilever stops rotating after being in place, other cantilevers far away from the right-end cantilever are still in a state of not rotating in place, even above the side of a rail, so that the loading and unloading operation of other goods such as large goods yards, containers and the like can be influenced; in addition, due to the fact that the pantograph does not rotate in place, the pantograph is poor in power taking and contact or cannot contact and take power, and the driving-in or the driving-out of the freight train is affected.

On one hand, the present embodiment provides a force transmission mechanism, which is applied to a wrist arm structure in a mobile contact network, and includes a moving member 1, a force transmission member and a rotating mechanism 4, wherein the rotating mechanism 4 is disposed on the wrist arm structure 5, and in the present embodiment, the force transmission member is used for transmitting force to the wrist arm structure 4, and pushing or pulling the wrist arm structure 4 to rotate; or, the force transmission piece is used for transmitting force to the moving piece 1, and pushing or pulling the moving piece 1 to move. The wrist-arm structure 5 in this embodiment may be disposed on the upright 6, and may be disposed at a position convenient to fix, such as a gantry.

The utility model discloses in directly change traditional inherent scheme, utilize the carrier cable itself as the driving medium, with the setting of its activity (structural for the fixed dead cantilever), the utility model provides a carrier cable can make a round trip gliding at the cantilever structure, has relative movement's relation, the carrier cable can be greater than corresponding cantilever structure rotation horizontal distance along the maximum horizontal migration distance of horizontal direction, and here need supplement the explanation under, only just can have the carrier cable to rotate horizontal distance along the maximum horizontal migration distance of horizontal direction under the gliding condition and can be greater than corresponding cantilever structure rotation horizontal distance. If the carrier cable is fixed on the cantilever structure, the horizontal moving distance of the carrier cable along the horizontal direction is equal to the rotating horizontal distance of the corresponding cantilever structure. Just because of the relative sliding relationship, the construction error and the influence of expansion with heat and contraction with cold can be eliminated. The structure is innovated just because of the relative sliding relationship, the force transmission piece is utilized to transmit force, and when the catenary is pulled (the force initiating end is an external weight or a dragging mechanism pulls the catenary), the force generated in the movement process of the catenary is transmitted to the wrist arm structure to drive the wrist arm structure to rotate to a working position or a non-working position; when the cantilever structure rotates (when the force starting end is that the cantilever structure is driven to rotate by a rotating motor or a push rod and the like), the force for rotating the cantilever structure is transmitted to the moving part (the catenary cable) by the force transmission part through the force bearing part, so that the catenary cable is driven to move. The mode breaks through the traditional thinking that the catenary needs to be fixedly arranged on the cantilever, and the catenary is driven to move by the rotation of the cantilever or is directly pulled to move in the traditional way; the prior relevant technologies (relevant thesis and patent published in the prior art) are all the same, the utility model discloses break through traditional thinking, in the process that the carrier cable removed or rotate pivoted process for there is the relation of relative movement still for carrier cable and/or contact wire, and the biggest horizontal migration distance of carrier cable and/or contact wire along the horizontal direction can be greater than corresponding cantilever structure rotation horizontal distance promptly. The utility model has the advantages that the construction error problem is effectively solved, the expansion and contraction problem of the catenary is effectively solved, the problem that the catenary cannot be swung in place once from the side to the railway due to the expansion and contraction of the catenary and the fixed catenary on the cantilever is explained herein, which is not described herein, and the other major focus of the utility model is that the whole catenary is swung in a side manner, the movable member (catenary) can move back and forth on the cantilever structure due to the sliding arrangement of the movable member, so that the further stroke compensation in place provides a foundation, the elastic force transmission member (such as a spring, and other elastic force transmission members can be used), the energy storage effect of the elastic force transmission member can be used for further pushing or pulling the cantilever structure to swing further to realize the stroke compensation, thus, compared with the existing swinging situation, the scheme can perfectly solve the problem, and particularly for a long-distance, such as 1700M, mobile contact net, the catenary and/or the contact line can be perfectly swung to one side of the railway and the swing is in place. The existing mobile contact line, for example, using a rigid contact line or a flexible contact line, the length of which cannot reach 1700M, or using multiple sections of mobile contact lines for splicing, is complicated in parts and construction and high in cost, and certainly or somebody needs to ask about, if a rotating motor is arranged at the root of each wrist arm, the situation that the wrist arm cannot swing in place indirectly can also be achieved. So the utility model discloses it is a fault rate low to pursue, adopts the utility model discloses a structural style, from present technique say that the fault rate is minimum, and the operation is reliable and stable, and the key is that the operation is easy and simple to handle, and the swing is effectual.

In this embodiment, the force transmission member adopts the following manner:

first, as shown in fig. 2, the force-transmitting member includes a pushing member 2, and the pushing member 2 is disposed on a moving member 1;

secondly, as shown in fig. 3, the force-transmitting member comprises an elastic force-transmitting member 3; or

Third, as shown in fig. 4, the force-transmitting member comprises a pushing member 2 and an elastic force-transmitting member 3.

The embodiment also comprises a sleeve 7, wherein the sleeve 7 is directly or indirectly arranged on the rotating mechanism 4, and the force transmission piece is arranged in the sleeve 7; the moving piece 1 moves to push or pull the force transmission piece, and the force transmission piece forms thrust or pulls the driving sleeve piece 7 to move; or, the wrist-arm structure 5 rotates to push or pull the force transmission piece, and the force transmission piece forms a pushing force or pulls to drive the moving piece 1 to move.

The force transmission piece in the embodiment has two working modes: the description will now be explained in the form of a first transmission: when the mobile element 1 (in this case the messenger wire 10) is pulled, fig. 2 shows the situation of moving to the right, one end of the force-transmitting element acts on the mobile element 1, the other end of said force-transmitting element acts directly or indirectly on the sleeve 7. The direct action is that the pushing piece 2 directly acts on the sleeve 7, the indirect action is that a part capable of bearing the force with the pushing piece 2 is arranged at any position on the sleeve 7, and the same effect can be achieved through the indirect action of the force bearing part. The pushing piece 2 is arranged on the moving piece 1, the moving piece 1 moves to drive the pushing piece 2 to move to the right, the sleeve piece 7 can be pushed to move together in the moving process, and the sleeve piece 7 is arranged on the cantilever structure 5, so that the cantilever structure 5 is pushed to rotate, and the cantilever structure 5 swings to a working position (the catenary 10 and/or the contact wire are positioned above a railway, and a pantograph can get electricity) or a non-working position (the catenary 10 and/or the contact wire move to one side of the railway to make a space above the railway convenient for cargo loading and unloading, maintenance and other operations). The working principle that the moving part 1 moves leftwards in this embodiment is the same, and is not described again.

It should be added that: the force-bearing part of the present embodiment may be any position of the sleeve 7 itself, and preferably the force-bearing part is two end surfaces (positions indicated by a and B in fig. 2) inside the sleeve 7; in the process that the force transmission piece reciprocates left and right, the force transmission piece (the pushing part or the elastic force transmission piece 3) is abutted against the left end face or the right end face inside the sleeve piece 7, so that the sleeve piece 7 is driven to move, the sleeve piece 7 transmits force to the cantilever structure 5, and the moving piece 1 is driven to rotate the cantilever structure 5; the other implementation form is as follows: the cantilever structure 5 is driven to rotate, and the force bearing part can abut against the force transmission part (the pushing part or the elastic force transmission part 3) in the process that the sleeve part 7 rotates together, so that the moving part 1 (the catenary 10) is pushed or pulled to move.

In addition, the force receiving portion may be another intermediate member (as shown in fig. 6) for receiving force, which is integrally and fixedly disposed on the sleeve 7, for example, the intermediate member may be a stopper, and the force transmitting member transmits pushing force or pulling force during the movement process, as long as the intermediate member can abut against the force transmitting member during the movement process.

Another implementation of the work is: the cantilever structure 5 is driven to rotate to drive the sleeve 7 to rotate, and the sleeve 7 acts on the pushing piece 2 in the rotating process so as to drive the moving piece 1 (the catenary 10) to move. The swing to the working position or the non-working position is realized. The working principle that the moving part 1 moves leftwards in this embodiment is the same, and is not described again.

Fig. 4 is an example to illustrate two working modes of the force transmission member: the moving piece 1 moves leftwards, the pushing piece 2 compresses the elastic force transmission piece 3 to form a thrust pushing sleeve 7, and the sleeve 7 transmits the thrust to the cantilever structure 5 so as to push the cantilever structure 5 to rotate; one end of the spring is not fixed, and the other end of the spring can be fixed on the pushing piece 2 or not fixed on the pushing piece 2.

In another working form, the wrist-arm structure 5 rotates right to drive the sleeve 7 to rotate right, the sleeve 7 exerts force on the pushing piece 2 through the spring, and the pushing piece 2 moves to drive the moving piece 1 (move).

As shown in fig. 5, if one end of the spring is directly or indirectly fixed on the sleeve 7 and the other end of the spring is fixed on the pushing member 2, the moving member 1 moves to the right to stretch the elastic force transmission member 3 through the pushing member 2 to form a pulling force, and the sleeve 7 transmits the pulling force to the cantilever structure 5, so as to pull the cantilever structure 5 to rotate;

in the embodiment, the pushing piece 2 is provided with an extending surface extending outwards; when the force-transmitting member comprises the pushing member 2, the extension surface can be directly/indirectly pressed and contacted on the sleeve member 7 (not shown in the figure) in the moving process; or

As shown in fig. 6, when the force-transmitting member comprises a push member 2 and an elastic force-transmitting member 3, said extension surface 17 can be in pressing contact against the elastic force-transmitting member 32 and/or against the sleeve member 7 during displacement.

As shown in fig. 7, in the present embodiment, the rotating mechanism 4 is provided with a supporting rotating shaft 41, the supporting rotating shaft can rotate, and the sleeve 7 is directly or indirectly arranged on the supporting rotating shaft 41. Fig. 6 shows that the sleeve 7 is arranged directly on the supporting spindle 41.

As shown in fig. 8, the sleeve 7 further comprises an intermediate connecting member 128, the intermediate connecting member 128 is disposed on the intermediate connecting member 128, and the intermediate connecting member 128 is disposed on the supporting rotating shaft 41. The middle connecting piece 128 adopts a cross rod, the kit 7 can be directly arranged on the cross rod, and can also adopt a clamping seat, the clamping seat is arranged on the cross rod, and the kit 7 is arranged on the clamping seat.

It should be added that in this embodiment, the messenger wire 10 can be used as the moving member 1, and this embodiment can be referred to fig. 2 to 5. In the manner shown in fig. 8, the moving member 1 includes a moving member body 9 and messenger wires 1010 disposed at both ends of the moving member body 9. This is just one embodiment of the mobile element 1, whether the messenger wire 10 is integral or the messenger wire 10 is broken, as long as it is able to move the messenger wire 10.

The embodiment also provides a mobile contact network side-shifting cantilever positioning device, which comprises cantilever structures 5, wherein at least one cantilever structure 5 uses the force transmission mechanism. See any of fig. 2-7.

The contact lines of the present embodiment are arranged as follows:

as shown in fig. 8, the first: the suspension device also comprises a suspension piece 11, wherein one end of the suspension is arranged on the catenary 10, and the other end of the suspension is connected with the contact line; or

As shown in fig. 9, the second: the contact line is arranged on the wrist arm structure 5 through the clamping structure 13;

further, when the first mode is used: the wrist-arm structure further comprises a connecting piece 12, one end of the connecting piece 12 is connected with the suspension piece 11, and the connecting piece 12 is directly or indirectly arranged on the wrist-arm structure 5; or

The connecting element 12 is arranged directly or indirectly on the rotary mechanism 4.

The working mode in this embodiment is as follows:

the moving part 1 is forced to move;

the moving piece 1 moves to compress or stretch the force transmission piece, and the force transmission piece forms thrust or pulls to drive the sleeve piece 7 to move;

the sleeve 7 transmits force to the wrist-arm structure 5, thereby pushing or pulling the wrist-arm structure 5 to rotate; or

The wrist-arm structure 5 rotates;

the force transmission piece is compressed or stretched to form a pushing force or a pulling force;

the sleeve 7 transmits pushing force or pulling force to the moving member 1, so as to push or pull the moving member 1 to move.

As a preferred embodiment, the moving member 1 is further pulled, the force transmission member is further compressed or stretched, and the sleeve member 7 directly or indirectly transmits force to the wrist-arm structure 5 through the force transmission member, so as to push or pull the wrist-arm structure 5 to rotate further for stroke compensation; supplementary explanation is needed: because the moving member 1 is arranged on the cantilever structure 5 in a sliding manner, when the cantilever stops rotating, the moving member 1 can be pulled further, for example, when the most upper cantilever in a mobile overhead line system stops rotating (generally rotates to one side of a railway), at this time, a plurality of other cantilever structures 5 are not rotated in place, the moving member 1 can be pulled further, and the elastic force transmission members 3 in the plurality of positioning devices push or pull the cantilever structures 5 to further rotate to realize stroke compensation. Or

The wrist-arm structure 5 is further driven to rotate, and the sleeve 7 directly or indirectly transmits force to the moving member 1 through the force transmission member, so as to push or pull the moving member 1 to further move.

It should be added that, in the prior art, when an arm structure at the most extreme swings to the right position and stops rotating (the limit structure can be adopted to block the support device to stop rotating, the limit structure is not a point protected by the present patent, and the limit structure can be blocked and does not rotate in any mode or in the existing mode), the other arm structures far away from the arm structure stopping rotating do not swing to one side of the rail completely, and at this time, the catenary and/or the contact line are further pulled. Of course, this is the most central key technical idea of this patent technology, and conventionally, because the catenary and the contact wire are fixed to the cantilever structure, when one support device at the extreme side is rotated to the position, the catenary and/or the contact wire cannot be further pulled, so that there is a case that the rest support devices in the catenary are not rotated in place.

In order to enable a person who reads the technical staff to clearly understand, the requirement fully disclosed in the patent is met, and why the situation that the rest of cantilever structures are not rotated in place exists, if the rigid contact system is adopted, a rotating motor is arranged on each upright or a plurality of uprights to drive the cantilevers to rotate, the rigid contact system (rigid on a contact line) can gradually transmit force, and the situation that the rotation is not in place does not exist. The high-speed railway is taken in the life, what the subway looked is fixed flexible contact net, and the movable flexible contact net that this patent provided mainly is used in places such as large-scale goods yard, railway container goods handling, warehousing maintenance.

The flexible contact line is adopted between the upright posts, due to construction errors and the influence of expansion with heat and contraction with cold of the contact line and the carrier cable, the contact line is especially long-distance and even used for ten thousand tons of heavy-duty trains, and the situation that the rest supporting devices in the contact line cannot rotate in place is more obvious as the distance is longer. The patent provides a solution based on the angle to find the problem.

So to say, in this field, in such a scenario, conventionally, since the catenary and the contact wire are fixed to the support devices, when the first support device on the extreme side is rotated into position, the catenary and/or the contact wire cannot be pulled further, so that there is a case that the rest of the support devices in the catenary are not rotated into position.

This problem has existed since the day of flexible mobile catenary systems, and prior disclosures of prior art, and none have been found or found to disclose, or more particularly, provide a solution to, the problem for a time. The catenary is movable relative to the cantilever structure; or the contact wire can move relative to the wrist-arm structure. This innovative idea itself breaks through the traditional thinking and subverts the current way of setting the immobilization, which is not a technical solution easily imaginable to the skilled person, but if it can be easily imaginable there should be a prior art disclosure in the field that it is supposed to be immobilized on the support means, and in the prior art disclosed there is no art disclosure that the messenger or the contact wire can be moved further when the most peripheral support means is rotated into place. The patent is one of the largest technical points in the patent, which can further rotate or move to realize compensation.

It should be added that, in the embodiment, the contact line and/or the catenary in the mobile catenary moves from the working position to the non-working position; or moving from the non-working position to the working position, and adopting any one or more combination modes of the following modes:

as shown in fig. 10, the first method: the device comprises a first balance weight structure 14 and a second balance weight structure 15, wherein the first balance weight structure acts on one end of a movable contact net, and the second balance weight structure is arranged at the other end of the movable contact net; the first balance weight structure and the second balance weight structure adjust the working state of the movable contact net from two ends of the movable contact net;

as shown in fig. 11, the second method: the device comprises a balance weight structure (see the arrangement mode of a first balance weight) and a dragging mechanism 16, wherein the balance weight structure acts on one end of a contact net, the dragging mechanism is arranged at the other end of the contact net, and the balance weight structure is dragged by the dragging mechanism to move so as to realize the adjustment of the working state of the contact net;

the third mode is as follows: in the first mode, a rotatable anchor arm mechanism (not shown in the figure) is added, and the anchor arm mechanism is arranged at any end of the overhead line system, or both ends of the overhead line system are arranged; the first balance weight structure and/or the second balance weight structure drive the anchor arm mechanism to rotate, and the rotating anchor arm mechanism drives the carrier cable and/or the contact line to move the contact net to work; or

The fourth mode is that: in the second mode, the rotatable anchor arm mechanism is arranged at any end of the overhead line system, or both ends of the rotatable anchor arm mechanism are arranged;

the balance weight structure directly acts on one end of the contact net, or the balance weight structure drives the anchor arm mechanism to rotate, and the rotating anchor arm mechanism drives the carrier cable and/or the contact net to move the working state of the contact net;

the dragging mechanism directly acts on one end of the contact net, or the dragging mechanism drives the anchor arm mechanism to rotate, and the rotating anchor arm mechanism drives the carrier cable and/or the contact line to move the working state of the contact net; or

The fifth mode is as follows: a rotating motor (not shown in the figures) is used, which is used to drive at least one cantilever structure in the moving catenary to rotate.

Although embodiments of the present invention have been shown and described, it is understood that the above embodiments are exemplary and should not be construed as limiting the present invention, and that variations, modifications, substitutions and alterations can be made to the above embodiments by those of ordinary skill in the art without departing from the scope of the present invention.

Claims (14)

1. Power transmission device, power transmission device is applied to and removes the cantilever structure in the contact net structurally, its characterized in that: the device comprises a moving piece, a force transmission piece and a rotating mechanism, wherein the rotating mechanism is arranged on a cantilever structure;

the force transmission piece is used for transmitting force to the cantilever structure and pushing or pulling the cantilever structure to rotate; or

The force transmission piece is used for transmitting force to the moving piece and pushing or pulling the moving piece to move.

2. The force transmission mechanism of claim 1, wherein: the force transmission piece adopts the following mode:

first, the force-transmitting member includes a pushing member disposed on a moving member;

secondly, the force transfer member comprises an elastic force transfer member; or

Thirdly, the force transfer member comprises a pushing member and an elastic force transfer member.

3. The force transmission mechanism of claim 2, wherein: the force transmission piece is arranged in the sleeve;

the moving part moves to push or pull the force transmission part, and the force transmission part forms thrust or pulls to drive the sleeve part to move; or

The cantilever structure rotates to push or pull the force transmission piece, and the force transmission piece forms thrust or pulls to drive the moving piece to move.

4. The force transmission mechanism of claim 2, wherein: the pushing piece is arranged on the moving piece, and in the moving process of the moving piece, the pushing piece can directly or indirectly act on the sleeve.

5. The force transmission mechanism of claim 3, wherein: the moving piece compresses or stretches the elastic force transmission piece through the pushing piece to form pushing force or pulling force, and the sleeve piece transmits the pushing force or the pulling force to the cantilever structure so as to push or pull the cantilever structure to rotate; or

The cantilever structure drives the external member to rotate, the external member directly or indirectly compresses or stretches the elastic force transmission member to form a pushing force or a pulling force, and the external member transmits the pushing force or the pulling force to the moving member so as to push or pull the moving member to move.

6. The force transmission mechanism of claim 4 or 5, wherein: the pushing piece is provided with an extending surface extending outwards;

when the force transmission piece comprises a pushing piece, the extension surface can be directly/indirectly pressed and contacted on the sleeve piece in the moving process; or

When the force-transmitting member comprises a pushing member and an elastic force-transmitting member, said extension surface is capable of being in pressing contact against the elastic force-transmitting member and/or against the sleeve during movement.

7. The force transmission mechanism of claim 3 or 5, wherein: the rotary mechanism is provided with a supporting rotating shaft, the supporting rotating shaft can rotate, and the sleeve is directly or indirectly arranged on the supporting rotating shaft.

8. The force transmission mechanism of claim 7, wherein: still include intermediate junction spare, the external member sets up on intermediate junction spare, intermediate junction spare sets up on supporting the pivot.

9. The force transmission mechanism according to any one of claims 1 to 5, wherein: the moving part adopts any one of the following modes:

the first method comprises the following steps: the moving piece adopts a catenary; or

And the second method comprises the following steps: the moving member comprises a moving member body and catenary wires arranged at two ends of the moving member body.

10. Remove contact net side and move cantilever positioner, its characterized in that: comprising a wrist-arm structure, wherein at least one wrist-arm structure uses a force transmission mechanism according to any of claims 1 to 9.

11. Remove contact net, its characterized in that: the device comprises at least one mobile contact net side shift cantilever positioning device according to claim 10; or

At least one cantilever structure in the mobile catenary using the force transmission mechanism of any of claims 1 to 9.

12. The mobile catenary of claim 11, wherein: the contact lines are arranged as follows:

the first method comprises the following steps: the suspension device also comprises a suspension piece, wherein one end of the suspension piece is arranged on the catenary, and the other end of the suspension piece is connected with the contact line; or

And the second method comprises the following steps: the contact wire is arranged on the wrist arm structure through the clamping structure or on the supporting rotating shaft of the rotating mechanism through the clamping structure.

13. The mobile catenary of claim 12, wherein: when the first approach is used: the connecting piece is connected with the suspension piece at one end and is directly or indirectly arranged on the cantilever structure; or

The connecting piece is directly or indirectly arranged on the rotating mechanism.

14. The mobile catenary of claim 13, wherein: moving a contact line and/or a catenary in the contact network from a working position to a non-working position; or moving from the non-working position to the working position, and adopting any one or more combination modes of the following modes:

the first mode is as follows: the first weight structure acts on one end of a movable contact net, and the second weight structure is arranged at the other end of the movable contact net; the first balance weight structure and the second balance weight structure adjust the working state of the movable contact net from two ends of the movable contact net;

the second mode is as follows: the device comprises a balance weight structure and a dragging mechanism, wherein the balance weight structure acts on one end of a contact network, the dragging mechanism is arranged at the other end of the contact network, and the balance weight structure is dragged by the dragging mechanism to move so as to realize the adjustment of the working state of the movable contact network;

the third mode is as follows: in the first mode, a rotatable anchor arm mechanism is additionally arranged, and the anchor arm mechanism is arranged at any end of the overhead line system or at both ends of the overhead line system; the first balance weight structure and/or the second balance weight structure drive the anchor arm mechanism to rotate, and the rotating anchor arm mechanism drives the carrier cable and/or the contact line to move the contact net to work; or

The fourth mode is that: in the second mode, the rotatable anchor arm mechanism is arranged at any end of the overhead line system, or both ends of the rotatable anchor arm mechanism are arranged;

the balance weight structure directly acts on one end of the contact net, or the balance weight structure drives the anchor arm mechanism to rotate, and the rotating anchor arm mechanism drives the carrier cable and/or the contact net to move the working state of the contact net;

the dragging mechanism directly acts on one end of the contact net, or the dragging mechanism drives the anchor arm mechanism to rotate, and the rotating anchor arm mechanism drives the carrier cable and/or the contact line to move the working state of the contact net; or

The fifth mode is as follows: a rotating motor is adopted and used for driving at least one cantilever structure in the movable contact net to rotate.

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