CN111891643A

CN111891643A - Power supply mechanism of continuous elevator

Info

Publication number: CN111891643A
Application number: CN202010758403.8A
Authority: CN
Inventors: 蒋坤; 白振成; 高光辉
Original assignee: SHANGHAI DAMON LOGISTICS TECHNOLOGY CO LTD; Zhejiang Damon Technology Co Ltd
Current assignee: SHANGHAI DAMON LOGISTICS TECHNOLOGY CO LTD; Zhejiang Damon Technology Co Ltd
Priority date: 2020-07-31
Filing date: 2020-07-31
Publication date: 2020-11-06

Abstract

The invention discloses a power supply mechanism of a continuous elevator, which is arranged in the continuous elevator, the continuous elevator comprises a first flexible part, a second flexible part and a plurality of elevator trolleys, the first flexible part and the second flexible part are in the shape of a ring, the first flexible part and the second flexible part are parallel and spaced and are not arranged side by side, the elevator trolleys are simultaneously and movably connected with the first flexible part and the second flexible part, the power supply mechanism of the continuous elevator comprises a ring-shaped power supply sliding contact line, a plurality of power taking brushes and a plurality of conductive slip rings, the spacing from any point of the power supply sliding contact line to the first flexible part or the second flexible part is the same, the power taking brushes are arranged on the elevator trolleys and always keep a sliding contact state with the power supply sliding contact line, and the conductive slip rings are fixed on the elevator trolleys. The invention has the advantages that the power supply device can supply power for the electric equipment of the elevator trolley, the functions of the elevator trolley are enriched, and the power supply mode keeps a stable state along with the movement of the elevator trolley.

Description

Power supply mechanism of continuous elevator

Technical Field

The invention relates to a power supply mechanism of a continuous elevator, which is mainly applied to the technical field of logistics conveying.

Background

At present, in the related technical field of logistics transportation, most of trolleys do not have power and cannot be equipped with electric equipment, so that the functions are poor, for example, the trolleys can only be used for transporting goods with larger sizes through devices or equipment matched with the trolleys, the matching performance of the matched devices or equipment on the transportation of small goods and soft package goods is poor, and in addition, the protection performance of the matched devices or equipment on the transportation of fragile goods is poor.

For example, prior art publication No. CN105398921A discloses a take lifting machine of double chain hoist system, including the crane, the guide rail, double chain hoist system, and carry a thing chassis and balancing weight, double chain hoist system includes the support frame, driven shaft and driving shaft, the driving shaft is installed in the left and right sides position at the lift frame top and parallel with the left and right sides on year thing chassis with the driven shaft, the driving shaft both ends are equipped with double sprocket, the driven shaft both ends are equipped with single sprocket, outside sprocket passes through chain one end and carries the thing chassis and be connected in the double sprocket, the other end is connected with the balancing weight, inboard sprocket is walked around single sprocket through chain one end and is carried the thing chassis and be connected in the double sprocket, the other end is connected with the. The carrying chassis of the elevator is not provided with electric power and a corresponding power supply device, so that the carrying chassis only can play a role of carrying goods, and the carrying chassis is weak in functionality.

Disclosure of Invention

The technical problem to be solved by the invention is to provide a power supply mechanism of a continuous elevator, which can supply power for electric equipment of an elevator trolley, enrich the functions of the elevator trolley, and keep a stable state along with the movement of the elevator trolley in a power supply mode.

The invention is realized by the following technical scheme.

A power supply mechanism of a continuous elevator is arranged in the continuous elevator, the continuous elevator comprises a first flexible part, a second flexible part and a plurality of elevator trolleys which are in the same shape and size, the first flexible part and the second flexible part are both annular and are in transmission connection through a plurality of transmission wheels, the first flexible part and the second flexible part are parallel at intervals and are not arranged side by side, the elevator trolleys are simultaneously and movably connected with the first flexible part and the second flexible part, the power supply mechanism of the continuous elevator comprises an annular power supply sliding contact line, a plurality of power taking brushes and a plurality of conductive slip rings, the distance from any point of the power supply sliding contact line to the first flexible part or the second flexible part is the same, the power taking brushes are arranged on the elevator trolleys and are always in sliding contact with the power supply sliding contact line, and the conductive slip rings are fixed on the elevator trolleys, and is connected with an electricity taking brush and an electricity utilization device of a hoist trolley.

As a further improvement of the present invention, the power supply trolley wire has a larger loop shape than the first flexure or the second flexure, and the power supply trolley wire is disposed on the periphery of the first flexure or the second flexure.

As a further development of the invention, the power supply trolley line is coplanar with the first flexure or the second flexure.

As a further improvement of the invention, the electricity-taking brush is movably connected with the hoisting machine trolley, can rotate in the plane of the power supply sliding contact line and is in sliding contact with the power supply sliding contact line.

As a further improvement of the invention, the electricity taking brush comprises a connecting part and an electric brush part, the connecting part and the electric brush part are fixedly connected, the connecting part is sleeved on a frame of the elevator trolley in a sliding mode, and the electric brush part is in sliding contact with the power supply sliding contact line.

As a further improvement of the present invention, the brush portion includes two portions, and both of the two portions and the connecting portion are in a Y-shaped configuration.

As a further improvement of the invention, the electric equipment of the elevator is a belt conveyor, and the belt conveyor is arranged on the frame of the elevator trolley and is used for bearing and conveying goods.

As a further improvement of the invention, the continuous hoister comprises two first flexible parts which are arranged side by side and two second flexible parts which are arranged side by side, the single first flexible part and the single second flexible part which are positioned closest are taken as a group of transmission mechanisms, the two groups of transmission mechanisms are in mirror symmetry, and the hoister trolley is movably connected with the two first flexible parts and the two second flexible parts simultaneously.

As a further improvement of the present invention, the first flexible element and the second flexible element are chains formed by connecting chain links, and all the transmission wheels corresponding to the first flexible element and the second flexible element are chain wheels.

The invention has the beneficial effects that:

the power supply trolley is provided with the power supply sliding contact line which is structurally matched with the first flexible part or the second flexible part, so that the power utilization problem of the elevator trolley is solved, the functionality of the elevator trolley is improved, the elevator trolley moves to any position, the power taking brush can be stably contacted with the power supply sliding contact line, the power supply stability is improved, in addition, the moving path of the elevator trolley is reasonable, the power supply sliding contact line setting difficulty is correspondingly simplified, the stable horizontal state keeping in the moving process is ensured by the connection mode of the elevator trolley, the first flexible part and the second flexible part, and the stable contact of the power taking brush and the power supply sliding contact line is also correspondingly ensured.

Drawings

The preferred embodiments of the present invention will hereinafter be described in detail to facilitate understanding of the objects and advantages of the invention, with reference to the accompanying drawings, in which:

FIG. 1 is a schematic elevation view of a multi-level sorter assembly;

FIG. 2 is a schematic top view of a multi-level sorter assembly;

FIG. 3 is a schematic view of a first embodiment of the arrangement of the continuous elevator, the inlet conveyer path and the outlet conveyer path;

FIG. 4 is a schematic view of a second embodiment of the arrangement of the continuous elevator, the inlet conveyer path and the outlet conveyer path;

FIG. 5 is a schematic view of a third embodiment of the arrangement of the continuous elevator, the inlet conveyer path and the outlet conveyer path;

fig. 6 is a schematic front view of a continuous hoist;

fig. 7 is a schematic top view of a continuous hoist;

FIG. 8 is a side view of the infeed lane and the continuous lift;

FIG. 9 is a side view of the exit conveyor run and the continuous lift;

FIG. 10 is a front schematic view of the elevator car;

FIG. 11 is a schematic top view of the elevator car;

FIG. 12 is a schematic view of the relationship between the power take-off brushes and the power supply trolley lines;

FIG. 13 is a side schematic view of a sorter;

FIG. 14 is a schematic view of a first embodiment of an exit conveyor and sorter arrangement;

FIG. 15 is a schematic view of a second embodiment of an exit conveyor and sorter arrangement;

FIG. 16 is an axial schematic view of a reciprocating cart;

FIG. 17 is a schematic diagram of a first embodiment of a grid, destination arrangement;

fig. 18 is a schematic diagram of a second embodiment of a cell and destination arrangement.

Detailed Description

The invention is explained in more detail below with reference to the drawings and exemplary embodiments.

The terms of orientation of up, down, left, right, front, back, top, bottom, and the like as referred to or as may be referred to in this specification are defined with respect to the configuration shown in the drawings, and the terms "inner" and "outer" refer to directions toward and away from the geometric center of a particular component and are relative terms, and thus may be changed accordingly depending on the position and the state of use of the particular component. Therefore, these and other directional terms should not be construed as limiting terms.

Referring to fig. 1 and 2, a multi-level sorter assembly includes: continuous lifting machine 1, sorting machine 2, multilayer entry transfer way 3, multilayer export transfer way 4, be equipped with the multilayer in a vertical range entry transfer way 3, be equipped with the multilayer in another vertical range export transfer way 4, continuous lifting machine 1 docks with multilayer

entry transfer way

3 and 4 goods of multilayer export transfer way respectively, multilayer export transfer way 4 docks with 2 goods of sorting machine simultaneously, and the mode of continuous lifting machine 1 is many-in many-out promptly, and the approximate flow of transportation of multilayer letter sorting assembly is as follows: the multilayer inlet conveying channel 3 conveys the goods of each layer into the continuous elevator 1, the continuous elevator 1 divides the goods into the corresponding outlet conveying channels 4, and then the sorting machine 2 sorts the goods in layers.

Regarding the specific arrangement of the continuous elevator 1, the inlet conveyer path 3 and the outlet conveyer path 4, in the first embodiment, as shown in fig. 3, the inlet conveyer path 3 and the multi-layer outlet conveyer path 4 are provided on both sides of the continuous elevator 1, in the second embodiment, as shown in fig. 4, the inlet conveyer path 3 is provided on both sides of the continuous elevator 1, and the outlet conveyer path 4 is provided on one side, and in the third embodiment, as shown in fig. 5, the inlet conveyer path 3 is provided on one side of the continuous elevator 1, and the outlet conveyer path 4 is provided on both sides. How the settings are specifically set depends on the specific application.

Referring to fig. 6 and 7, the continuous hoisting machine 1 includes a hoisting machine frame 10, and a first flexible part 11, a second flexible part 12, and a plurality of hoisting trolleys 13 installed in the hoisting machine frame 10, wherein the first flexible part 11 and the second flexible part 12 are both in transmission connection by four

chain wheels

110 and 120 and are identical annular members, and both are identical in shape and running direction, specifically, both are substantially rectangular. The first flexure 11 is spaced parallel to the second flexure 12 and is not in a side-by-side positional relationship. In addition, the first flexure 11 has two vertical portions, one is a rising portion and the other is a falling portion, and with reference to the perspective of fig. 2, the first flexure 11 runs in a clockwise direction, the vertical portion on the left side is a rising portion and the vertical portion on the right side is a falling portion, and similarly, the vertical portion on the left side of the second flexure 12 is a rising portion and the vertical portion on the right side is a falling portion. The elevator trolleys 13 are arranged in series, maintain a horizontal state as a whole, and are movably connected with the first flexible part 11 and the second flexible part 12. Therefore, the total path of the elevator trolley 13 is matched with the shapes of the first flexible part 11 and the second flexible part 12, is a rectangular circulating total path, and is formed by connecting a left vertical ascending path, an upper horizontal right moving path, a right vertical descending path and a lower horizontal left moving path corresponding to the running directions of the first flexible part 11 and the second flexible part 12.

Referring to fig. 6 and 7 in combination with fig. 8 and 9, the multiple layers of the inlet conveyer ways 3 correspond to a left vertical ascending path of the elevator trolley 13, the multiple layers of the outlet conveyer ways 4 correspond to a right vertical descending path of the elevator trolley 13, because the elevator trolley 13 continuously moves along the total moving path thereof, the elevator trolley is butted with the goods of the inlet conveyer ways 3 in the ascending process, in the process, the horizontal height of the inlet conveyer ways 3 when the inlet conveyer ways 3 start to convey the goods is higher than the horizontal height of the elevator trolley 13, a sensor (not shown in the figure) is arranged on the inlet conveyer ways 3 to measure the length of the goods (the length of the goods in the conveying direction), and the height drop height in the butting process is designed according to the length of the goods, the basic principle is that the shorter the goods are the smaller the drop height, the longer goods are the larger, so that the impact force of dropping the goods can be reduced to protect the goods, especially for fragile goods, the hoist trolley 13 is butted with the goods on the outlet conveying channel 4 in the descending process, in the process, the horizontal height of the hoist trolley 13 when the hoist trolley 13 conveys the goods is higher than the horizontal height of the outlet conveying channel 4, a sensor (not shown in the figure) is arranged on the hoist trolley 13 to measure the length of the goods, and the height drop during the butting process is designed according to the length of the goods.

Referring to fig. 8 and 9, the entrance conveyor path 3 includes a conveying section 31 and a buffer section 32 which run independently and are connected, and the buffer section 32 is in cargo connection with the elevator car 13. The conveying section 31 and the buffer section 32 are both set as belt conveyors, and the conveying speed and the speed difference between the conveying speed and the buffer section are set according to practical application conditions. In addition, the outlet conveying passage 4 is also provided as a belt conveyor.

With continued reference to fig. 6 and 7, further, the first flexible component 11 and the second flexible component 12 are both provided in two, the two first flexible components 11 are arranged side by side, the two second flexible components 12 are arranged side by side, the single first flexible component 11 and the second flexible component 12 which are closest to each other are used as a group of transmission mechanisms, and the two groups of transmission mechanisms are in mirror symmetry, referring to fig. 3, the distance between the two first flexible components 11 is greater than the distance between the two second flexible components 12, or vice versa. The hoist trolley 13 is movably connected with the two first flexible parts 11 and the two second flexible parts 12 at the same time, namely the hoist trolley 13 can be supported by four connecting points to improve the stability in the moving process, maintain the horizontal state and avoid the inclination phenomenon. In addition, the rectangular projection surfaces formed by the first flexible part 11 and the second flexible part 12 are partially overlapped, and the first flexible part 11 and the second flexible part 12 of the same group of transmission mechanisms are spaced, so that the problem of mechanical interference cannot occur in the arrangement that the projection surfaces are partially overlapped, and the space volume occupied by the continuous lifting machine 1 can be compressed, so that the continuous lifting machine has a reasonable and compact structure.

Any one of all the transmission wheels corresponding to the first flexible part 11 and the second flexible part 12 is selected as a driving wheel, and all the other transmission wheels are driven wheels. In this embodiment, the elevator frame 10 is fixedly installed with a motor 14, and one of the driving wheels of the second flexible member 12 is used as a driving wheel 120-1 and is assembled on the motor 14. In addition, at least one of the transmission wheels corresponding to the first flexible part 11 is a tension wheel 110-A with adjustable position, and at least one of the transmission wheels corresponding to the second flexible part 12 is a tension wheel 120-A with adjustable position, so that the running stability of the hoister trolley 13 can be improved by adjusting the tension degrees of the first flexible part 11 and the second flexible part 12.

Referring to fig. 10 and 11, the elevator car 13 includes a frame 131 and a shunt bearing portion 132, the shunt bearing portion 132 is horizontally and fixedly connected to the frame 131, and the frame 131 has four shafts horizontally arranged and perpendicular to the plane of the first flexible member 11 and the second flexible member 12, and is movably connected to the two first flexible members 11 and the second flexible member 12 respectively. Specifically, the four shafts of the frame 131 are coupled to the first flexible member 11 and the second flexible member 12 and can rotate around the central axis thereof, that is, the four shafts rotate relative to the first flexible member 11 and the second flexible member 12 when the elevator car 13 moves and turns, so that the elevator car 13 is always kept in a horizontal state. More specifically, the first flexible element 11 and the second flexible element 12 are chains, the corresponding driving

wheels

110 and 120 are chain wheels, the axis of the frame 131 is perpendicular to the plane where the first flexible element 11 and the second flexible element 12 are located, and the chain links of the chains are slidably sleeved on the axis. Compared with other transmission modes, the embodiment adopts chain transmission without elastic sliding and slipping phenomena, has higher accuracy of average transmission ratio, meets the requirement of accurate movement of the hoister trolley, and has better operation reliability and high efficiency; the transmission power is large, the overload capacity is strong, and the limitation to the weight of the goods is low. And secondly, the movable connection stability between the chain and the shaft of the frame is good, when the hoister trolley moves and turns, the shaft rotates relative to the chain, the transition is stable and the hoister trolley is not easy to shake, and in the process, the friction generated between the rotation of the shaft and the chain is small, and the loss of the transmission force is relatively low.

Further, the frame 131 includes a first connecting shaft 1311, two second connecting shafts 1312, and two connecting rods 1313, wherein two ends of the first connecting shaft 1311 are vertically and fixedly connected to one ends of the two connecting rods 1313, respectively, the other end of the connecting rod 1313 is vertically and fixedly connected to the second connecting shaft 1312, two links of the first flexible component 11 are slidably sleeved on the first connecting shaft 1311, the two first flexible components 11 are symmetrical with respect to the first connecting shaft 1311, and two links of the second flexible component 12 are slidably sleeved on the two second connecting shafts 1312, respectively. The frame 131 formed by the first connecting shaft 1311, the two second connecting shafts 1312 and the two connecting rods 1313 is a U-shaped structure, and the shunt bearing part 132 is located at the center of the U-shaped structure and is fixedly connected with the first connecting shaft 1311 through two supporting rods 1314. The frame 131 has a U-shaped structure, so that the overall structure has high rigidity, the installation and fixing environment of the shunt bearing part 132 is relatively stable, and the four connecting positions of the frame 131 with the first flexible element 11 and the second flexible element 12 are respectively positioned at two end positions of the U-shaped structure and two positions close to the turn, namely, the four connecting positions are all positioned on the main body part of the U-shaped structure, on one hand, the actual stress difference of the four connecting positions is small, the weight distribution of the hoist trolley 13 is relatively balanced, the hoist trolley 13 can be kept horizontal as a whole without inclination, on the other hand, the wear degrees of the first flexible part 11, the second flexible part 12, the first connecting shaft 1311 and the second connecting shaft 1312 are not different from each other, so that the condition that the hoist trolley 13 is unbalanced due to excessive local wear is avoided.

The reposition of redundant personnel load-bearing part 132 sets up to the belt feeder and is driven by motor 133, but the belt feeder positive and negative bilateral operation, the belt feeder operation when lifting machine dolly 13 docks with 4 goods in export conveyer way, the goods drops to export conveyer way 4 by lifting machine dolly 13 on, in addition when lifting machine dolly 13 docks with 3 goods in the entry conveyer way, receive by entry conveyer way 3 after dropping to the goods of lifting machine dolly 13, can operate the belt feeder and adjust the position of goods at lifting machine dolly 13, can make the focus of goods and lifting machine dolly 13 keep steady on the one hand, on the other hand sets up for the butt joint of 4 goods in export conveyer way through fine setting goods position.

Referring to fig. 10-12 in combination with fig. 6 and 7, the hoist trolley 13 further includes a power supply trolley line 15, the power supply trolley line 15 is fixedly mounted in the hoist frame 10 and is substantially in the shape of a closed rectangle which is the same as and slightly larger than the first flexible member 11 and the second flexible member 12, the power supply trolley line 15 is coplanar with and disposed at the periphery of either the first flexible member 11 or the second flexible member 12, specifically in this embodiment, the power supply trolley line 15 is coplanar with and disposed at the periphery of one of the second flexible members 12, and the distance from any point of the power supply trolley line 15 to the second flexible member 12 is the same. The frame 131 of the elevator trolley 13 is provided with a power taking brush 16, the power taking brush 16 is movably connected to the frame and can rotate in the plane of the power supply sliding contact line 15, the power taking brush 16 is in sliding contact with the power supply sliding contact line 15, the frame 131 of the elevator trolley 13 is also provided with a conductive slip ring 17, and the power taking brush 16 takes power from the power supply sliding contact line 15 and supplies the power to the elevator trolley 13 through the conductive slip ring 17. Specifically, the electricity taking brush 16 includes a connecting portion 161 and a brush portion 162, which are fixedly connected, the connecting portion 161 is slidably sleeved on a first connecting shaft 1311 of the frame 131, the brush portion 162 is in sliding contact with the power supply trolley line 15, the conductive slip ring 17 is sleeved on the first connecting shaft 1311, and is connected to the electricity taking brush 16 and the motor 133 of the belt conveyor.

When the elevator trolley 13 turns, for example, from a left vertical ascending path to an upper horizontal moving path, the connection part 161 of the electricity taking brush 16 rotates relative to the first connection shaft 1311 so that the brush part 162 always keeps a stable sliding contact state with the electricity supply trolley line 15, that is, the elevator trolley 13 can always keep the electricity taking and supplying states in the movement of the elevator trolley 13 along the moving path, and the elevator trolley 13 cannot have power supply interruption or unstable power supply due to the turning of the elevator trolley 13. In addition, the electricity taking brush 16 is preferably provided with two parts in sliding contact with the power supply trolley line 15, the two parts and the connecting part 161 form a Y-shaped integral structure with good support performance, and the stability of the electricity taking brush 16 sliding along with the elevator trolley 13 on the power supply trolley line 15 is improved so as to obtain a stable power transmission state.

Referring to fig. 1 and 13, the sorter 2 includes a sorter frame 20 and a multi-layer sorting conveyor 21, the sorting conveyor 21 is of an elongated structure and is disposed in the sorter frame 20 in layers, and may be disposed in a linear or curved shape according to actual sites, and is in one-to-one correspondence with the exit conveyors 4 and the goods are butted, in a first embodiment, for example, as shown in fig. 14, the position where the sorting conveyor 21 is butted against the exit conveyor 4 is an end portion of the exit conveyor 4, and in a second embodiment, as shown in fig. 15, the position where the sorting conveyor 21 is butted against the exit conveyor 4 is an arbitrary position in a middle portion of the exit conveyor 4. One side or two sides of each layer of sorting conveying channel 21 are provided with a plurality of grids 22 along the length direction, and the grids 22 are in butt joint with the goods of the sorting conveying channel 21. Each layer of sorting conveying channel 21 is provided with a reciprocating trolley 23, and the reciprocating trolley 23 can reciprocate along the length direction of the sorting conveying channel 21 and is in butt joint with the outlet conveying channel 4 and the grids 22.

The sorting machine in the prior art also has a multilayer structure, a trolley is arranged in the sorting machine, the trolley moves to other layers in a rail-changing mode, moving tracks of different trolleys are necessarily overlapped, therefore, the sorting sequence is required to be set during sorting so as to avoid the occurrence of a collision phenomenon, and the sorting logic is relatively complex. In addition, the distance between the goods sent out from the receiving goods of the trolley to the grid opening is not the straight shortest distance, and the logic setting that the trolley needs to be decelerated or even stopped to avoid the collision condition is relatively low in sorting efficiency, the invention solves the above problem, so that the distance for the reciprocating trolley 23 to convey the goods is the straight shortest distance for the invention, the collision phenomenon does not need to be considered, the efficiency is greatly improved on the sorting mode compared with the prior art, and the sorting efficiency can be further improved on the basis of the optimized sorting mode by improving the moving speed of the reciprocating trolley 23 on the sorting conveying channel 21 from another aspect.

Referring to fig. 13 and 16 in combination with fig. 1, therefore, further, the sorting conveying path 21 includes two parallel rails 211 and a transmission mechanism, the rails 211 are disposed along the length direction of the sorting conveying path 21, the reciprocating trolley 23 is disposed on the rails 211 and driven by the transmission mechanism to reciprocate, specifically, the reciprocating trolley 23 includes a frame 231 and a sorting carrying portion 232, four traveling wheels 2311 traveling on the rails 211 are mounted at the bottom of the frame 231, and compared with the prior art, the friction resistance is small when traveling, and the high-speed traveling of the reciprocating trolley 23 along the rails 211 can be realized. The transmission mechanism comprises a synchronous belt 241, two transmission shafts 242 and a motor 243, the two transmission shafts 242 are respectively arranged at two ends of the sorting conveying channel 21, the synchronous belt 241 is arranged along the length direction of the sorting conveying channel 21 and is in transmission connection with the two transmission shafts 242, one of the transmission shafts 242 is driven by the motor 243, and the frame 231 of the reciprocating trolley 23 is fixedly connected with the synchronous belt 241.

Further, hold-in range 241 is the disconnection to its width is less than the width of frame 231, the front end and the rear end of frame 231 fixed connection respectively the both ends of hold-in range 241 disconnection, it is concrete, the front end and the rear end of frame 231 are provided with the both ends that clamp splice 2312 is used for the fixed hold-in range 241 of centre gripping respectively, and this kind of mode of setting installation is comparatively convenient, is convenient for adjust the rate of tension of hold-in range 241 in addition, consequently does not need too accurately to the length calculation of hold-in range 241 often in practical application, can solve through the fine setting, is convenient for maintain or change reciprocating type dolly 23.

In addition, in order to improve the stability of the reciprocating trolley 23 traveling on the rails 211, at least one guide wheel 2313 is respectively installed at the bottom of the frame 231 corresponding to each rail 211, the guide wheels 2313 are in sliding fit with the inner side surfaces of the corresponding rails 211, preferably two guide wheels 2313 are respectively installed, and the positions of the four guide wheels 2313 correspond to the four traveling wheels 2311 one by one.

The sorting bearing part 232 is a belt conveyor capable of running in two directions, the conveying direction of the belt conveyor is perpendicular to the running direction of the reciprocating trolley 23, when the reciprocating trolley 23 runs and stops to the corresponding cell 22, the belt conveyor starts to run to push the loaded goods to the corresponding cell 22 to complete goods butt joint, and in addition, the belt conveyor is powered by a drag chain (not shown in the figure) arranged on the sorting conveying channel 21.

Considering that the reciprocating cart 23 of the present invention has a fast traveling speed and a relatively large inertia when starting or stopping, in order to prevent the goods from falling off from the sorting bearing part 232 due to the inertia, the frame 231 of the reciprocating cart 23 is provided with the baffles 2314 at the front end and the rear end respectively, which are higher than the sorting bearing part 232, and the two baffles 2314 limit the goods within the loading range of the diversion bearing part 132, which can avoid the above situation.

In the first embodiment, as shown in fig. 17, the plurality of cells 22 located on the same side of the sorting conveyance path and in a vertical positional relationship with each other correspond to different destinations, respectively, and are suitable for a general sorting situation. In a second embodiment, as shown in fig. 18, a plurality of the compartments 22 located on the same side of the sorting conveyor and in a vertical relationship with each other correspond to the same destination, which can improve the sorting efficiency of a large number of goods with the same destination.

Finally, it should be noted that: the above embodiments are only used to illustrate the technical solution of the present invention, and not to limit the same; although the present invention has been described in detail with reference to the foregoing embodiments, those skilled in the art will understand that: the technical solutions described in the foregoing embodiments can be modified, or some technical features can be equivalently replaced; and the modifications or the substitutions do not make the essence of the corresponding technical solutions depart from the scope of the technical solutions of the embodiments of the present invention.

Claims

1. A power supply mechanism of a continuous elevator is characterized by being arranged in the continuous elevator, the continuous elevator comprises a first flexible part, a second flexible part and a plurality of elevator trolleys which are the same in shape and size, the first flexible part and the second flexible part are both annular and are in transmission connection through a plurality of transmission wheels, the first flexible part and the second flexible part are parallel, spaced and not arranged side by side, the elevator trolleys are movably connected with the first flexible part and the second flexible part simultaneously, the power supply mechanism of the continuous elevator comprises an annular power supply sliding contact line, a plurality of power taking brushes and a plurality of conductive slip rings, the distance from any point of the power supply sliding contact line to the first flexible part or the second flexible part is the same, the power taking brushes are arranged on the elevator trolleys and always keep sliding contact with the power supply sliding contact line, and the conductive slip rings are fixed on the elevator trolleys, and is connected with an electricity taking brush and an electricity utilization device of a hoist trolley.

2. The power feeding mechanism of a continuous elevator as claimed in claim 1, wherein the power feeding trolley wire has a larger loop shape than the loop shape of the first flexible member or the second flexible member, and the power feeding trolley wire is disposed on the outer periphery of the first flexible member or the second flexible member.

3. The power feeding mechanism of a continuous elevator as claimed in claim 2, wherein the power feeding trolley line is coplanar with the first flexible member or the second flexible member.

4. The power supply mechanism of the continuous elevator as claimed in claim 3, wherein the power take-off brush is movably connected to the elevator car to be rotatable in a plane of the power supply trolley line and to be in sliding contact with the power supply trolley line.

5. The power supply mechanism of the continuous elevator as claimed in claim 4, wherein the power supply brush comprises a connecting portion and a brush portion, the connecting portion and the brush portion are fixedly connected, the connecting portion is slidably sleeved on the frame of the elevator car, and the brush portion is in sliding contact with the power supply trolley line.

6. The power feeding mechanism of a continuous elevator as set forth in claim 5, wherein the brush portion comprises two parts, both of which are Y-shaped with respect to the connecting portion.

7. The power supply mechanism of the continuous elevator as claimed in claim 1, wherein the power utilization device of the elevator is a belt conveyor mounted on the frame of the elevator car and used for carrying and transporting goods.

8. The power supply mechanism of the continuous hoister according to claim 1, wherein the continuous hoister comprises two first flexible parts arranged side by side and two second flexible parts arranged side by side, the single first flexible part and the single second flexible part which are positioned nearest to each other are used as a group of transmission mechanisms, the two groups of transmission mechanisms are in mirror symmetry, and the hoister trolley is movably connected with the two first flexible parts and the two second flexible parts simultaneously.

9. The power supply mechanism of the continuous elevator as claimed in claim 8, wherein the first flexible member and the second flexible member are chains formed by connecting chain links, and all the transmission wheels corresponding to the first flexible member and the second flexible member are chain wheels.