CN112756275A - Aviation logistics transportation ground service classifier and using method - Google Patents
Aviation logistics transportation ground service classifier and using method Download PDFInfo
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- CN112756275A CN112756275A CN202011610241.XA CN202011610241A CN112756275A CN 112756275 A CN112756275 A CN 112756275A CN 202011610241 A CN202011610241 A CN 202011610241A CN 112756275 A CN112756275 A CN 112756275A
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- arc
- seat
- falling
- fixedly connected
- ground service
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B07—SEPARATING SOLIDS FROM SOLIDS; SORTING
- B07C—POSTAL SORTING; SORTING INDIVIDUAL ARTICLES, OR BULK MATERIAL FIT TO BE SORTED PIECE-MEAL, e.g. BY PICKING
- B07C5/00—Sorting according to a characteristic or feature of the articles or material being sorted, e.g. by control effected by devices which detect or measure such characteristic or feature; Sorting by manually actuated devices, e.g. switches
- B07C5/34—Sorting according to other particular properties
- B07C5/3412—Sorting according to other particular properties according to a code applied to the object which indicates a property of the object, e.g. quality class, contents or incorrect indication
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B07—SEPARATING SOLIDS FROM SOLIDS; SORTING
- B07C—POSTAL SORTING; SORTING INDIVIDUAL ARTICLES, OR BULK MATERIAL FIT TO BE SORTED PIECE-MEAL, e.g. BY PICKING
- B07C5/00—Sorting according to a characteristic or feature of the articles or material being sorted, e.g. by control effected by devices which detect or measure such characteristic or feature; Sorting by manually actuated devices, e.g. switches
- B07C5/36—Sorting apparatus characterised by the means used for distribution
- B07C5/361—Processing or control devices therefor, e.g. escort memory
- B07C5/362—Separating or distributor mechanisms
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B64—AIRCRAFT; AVIATION; COSMONAUTICS
- B64F—GROUND OR AIRCRAFT-CARRIER-DECK INSTALLATIONS SPECIALLY ADAPTED FOR USE IN CONNECTION WITH AIRCRAFT; DESIGNING, MANUFACTURING, ASSEMBLING, CLEANING, MAINTAINING OR REPAIRING AIRCRAFT, NOT OTHERWISE PROVIDED FOR; HANDLING, TRANSPORTING, TESTING OR INSPECTING AIRCRAFT COMPONENTS, NOT OTHERWISE PROVIDED FOR
- B64F1/00—Ground or aircraft-carrier-deck installations
- B64F1/32—Ground or aircraft-carrier-deck installations for handling freight
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02W—CLIMATE CHANGE MITIGATION TECHNOLOGIES RELATED TO WASTEWATER TREATMENT OR WASTE MANAGEMENT
- Y02W30/00—Technologies for solid waste management
- Y02W30/10—Waste collection, transportation, transfer or storage, e.g. segregated refuse collecting, electric or hybrid propulsion
Abstract
The invention belongs to the field of air transportation, and particularly relates to an air logistics transportation ground service classifier and a using method, wherein the using method comprises the following steps: the ground service transportation forklift is moved to a loading position through the ground service forklift, and the landing bearing adapter is convenient for the connection of unloading; unloading articles fall into the falling bearing connector, intermittently fall into the omnibearing scanner in batches for omnibearing strip scanning through the driving of the omnibearing scanner, fall onto the directional conveyer and do the reciprocating operation; the directional transport divider receives signals transmitted by the omnibearing scanner, further determines three modes of forward rotation, reverse rotation and immobility, and realizes classification through the directional transport divider; can be in the in-process of ground service discharge and transportation, classify the parcel according to the bar code display position automatically, high-efficient promotion conveying efficiency.
Description
Technical Field
The invention belongs to the field of air transportation, and particularly relates to an air logistics transportation ground service classifier and a using method.
Background
Patent number is CN201710110904.3 discloses aviation logistics transportation ground service classifier cloth coiling mechanism, especially relates to aviation logistics transportation ground service classifier cloth coiling mechanism for textile production. The invention aims to solve the technical problem of providing a cloth winding device for textile production, which is convenient to use, simple to operate, smooth in cloth winding, smooth in shearing, high in shearing speed and capable of improving the working speed, of an aviation logistics transportation ground service classifier. In order to solve the technical problem, the invention provides a cloth winding device for textile production of the aviation logistics transportation ground service classifier, which comprises a base, a first sliding block, a screw rod, a first cylinder, a right side plate, a placing frame, a left side plate, a fixing plate, a first bearing seat, a first rotating shaft, a thumb cylinder and the like; the base right side is opened there is the spout, and the spout internal sliding is equipped with first slider, and the even spaced screw hole of opening of base front side of first slider middle part and spout front side has the screw rod through threaded connection in the screw hole. According to the cloth cutting device, the first roller rotates to roll the cloth, and the cutter cuts the cloth. But the device cannot quickly sort the goods according to the barcode display during transportation after unloading.
Disclosure of Invention
The invention aims to provide an aviation logistics transportation ground service classifier, which has the beneficial effects that packages are automatically classified according to the bar code display positions in the ground service unloading and transportation process, and the transportation efficiency is efficiently improved.
The purpose of the invention is realized by the following technical scheme:
the invention aims to provide an aviation logistics transportation ground service classifier which comprises a falling bearing adapter, a ground service transportation fork saddle, a falling classification seat, an all-dimensional scanner and a directional distributor, wherein the upper end and the lower end of the ground service transportation fork saddle are respectively and fixedly connected to the falling bearing adapter and the falling classification seat, the falling bearing adapter is communicated with the falling classification seat, the all-dimensional scanner is rotatably connected in the falling classification seat, and the directional distributor is fixedly connected to the ground service transportation fork saddle and the falling classification seat.
As a further optimization of the invention, the falling bearing adapter comprises an upper collecting slope box, a left fixed slide seat, a falling extension landslide seat, two connection electric telescopic rods and a classification falling round hole, wherein the left end of the upper collecting slope box is fixedly connected with the left fixed slide seat, the falling extension landslide seat is connected in the left fixed slide seat in a sliding manner through a slide block, the falling extension landslide seat is connected at the upper end of the upper collecting slope box in a sliding manner, the two connection electric telescopic rods are respectively and fixedly connected at the two ends of the upper collecting slope box, the two ends of the falling extension landslide seat are respectively and fixedly connected on the telescopic rods of the two connection electric telescopic rods, and the classification falling round hole is arranged at the lower end of the.
As a further optimization of the invention, the ground service transportation forklift seat comprises a lower bottom plate, a lower classification sliding baffle frame, two slot seats and a motor protection frame, wherein the lower classification sliding baffle frame is longitudinally and slidably connected on the lower bottom plate through a sliding block, the two slot seats are uniformly and fixedly connected at the lower end of the lower bottom plate, and the motor protection frame is fixedly connected on the lower bottom plate.
As a further optimization of the invention, the falling classification seat comprises a central falling cylinder, three discharge grooves, three collection arc-shaped frames, a longitudinal rack chute and an internal rotation round hole, wherein the lower end of the central falling cylinder is fixedly connected to the lower bottom plate, the three discharge grooves are uniformly communicated and arranged on the central falling cylinder, the three collection arc-shaped frames are uniformly and fixedly connected to the outer wall of the central falling cylinder and the lower bottom plate, the longitudinal rack chute is arranged on the outer wall of the central falling cylinder, and the internal rotation round hole is arranged in the central falling cylinder.
As a further optimization of the invention, the omnibearing scanner comprises a scanning driving motor, a driving rotary table, a driving hinged rod, a driving rack, a driving reciprocating gear, a scanning rotary shaft, a cross-shaped arc-shaped scanning seat, two arc-shaped baffles, two arc-shaped grooves and four strip-shaped infrared scanners, wherein the scanning driving motor is fixedly connected on a lower bottom plate through a motor fixing seat, the driving rotary table is fixedly connected on a transmission shaft of the scanning driving motor, two ends of the driving hinged rod are respectively hinged at the eccentric part of the driving rotary table and the lower end of the driving rack, the driving rack is slidably connected in a longitudinal rack sliding groove through a limiting slide block, the driving rack is meshed with the driving reciprocating gear for transmission, the scanning rotary shaft is rotatably connected in a rotary round hole, the cross-shaped arc-shaped scanning seat is fixedly connected on the scanning rotary shaft, the two, two arc flutings evenly set up on cross arc scanning seat, and four bar infrared scanner evenly fixed connection are at cross arc scanning seat inner wall.
As a further optimization of the invention, the directional conveyor comprises a fixed circular plate, three classification pushing plates, three arc-shaped top seats, three arc-shaped convex top blocks, a lower rotary table and a variable frequency signal receiving motor, wherein the fixed circular plate is fixedly connected with the lower end of the inner wall of the central lower barrel, the outer ends of the three classification pushing plates are uniformly and rotatably connected in the fixed circular plate, the three arc-shaped top seats are respectively and fixedly connected with the lower sides of the inner ends of the three classification pushing plates, the arc-shaped convex top blocks are attached to the arc-shaped top seats, the three arc-shaped convex top blocks are all fixedly connected on the lower rotary table, the lower rotary table is fixedly connected on a transmission shaft of the variable frequency signal receiving motor, and the variable frequency signal receiving motor is.
As a further optimization of the invention, the strip-shaped infrared scanner is in the shape of a semicircular arc.
As a further optimization of the invention, the arc-shaped convex top blocks are provided with three arc-shaped convex top blocks, the included angles among the three arc-shaped convex top blocks are respectively 100 degrees, 120 degrees and 140 degrees, and the initial position of the central arc-shaped convex top block is attached to the arc-shaped top seat.
The use method of the air logistics transportation ground service classifier comprises the following steps:
the method comprises the following steps: the ground service transportation forklift is moved to a loading position through the ground service forklift, and the landing bearing adapter is convenient for the connection of unloading;
step two: unloading articles fall into the falling bearing connector, intermittently fall into the omnibearing scanner in batches for omnibearing strip scanning through the driving of the omnibearing scanner, fall onto the directional conveyer and do the reciprocating operation;
step three: the directional transport divider receives signals transmitted by the omnibearing scanner, further determines three modes of positive rotation, reverse rotation and immobility, and realizes classification through the directional transport divider.
Compared with the prior art, the technical scheme provided by the invention has the advantages that the packages are automatically classified according to the bar code display positions in the ground service unloading and transporting process, so that the transporting efficiency is efficiently improved; the method comprises the steps of determining the condition of a bar code package by intermittently scanning the package in the falling process in 360 degrees in an all-around manner, classifying package information, and distributing the package information to a designated area in the falling process; the unloading and the transportation of the air transportation can be conveniently linked.
Drawings
FIG. 1 is a first general structural diagram of the present invention;
FIG. 2 is a second overall structural schematic of the present invention;
FIG. 3 is a first schematic view of a drop load adapter of the present invention;
FIG. 4 is a second schematic view of the drop load adapter of the present invention;
FIG. 5 is a schematic structural view of the ground transportation fork lift seat of the present invention;
FIG. 6 is a schematic view of the drop sorting seat of the present invention;
FIG. 7 is a first schematic view of the omni-directional scanner of the present invention;
FIG. 8 is a second schematic structural view of the omni-directional scanner of the present invention;
FIG. 9 is a first schematic structural view of the directional distributor of the present invention;
fig. 10 is a second structural schematic diagram of the directional distributor of the present invention.
In the figure: a drop load adapter 1; an upper collecting slope box 1-1; a left fixed slide 1-2; 1-3 of a falling extension landslide seat; two connected electric telescopic rods 1-4; classifying falling round holes 1-5; a ground transportation forklift seat 2; a lower bottom plate 2-1; a lower classification sliding block frame 2-2; 2-3 of a slot seat; 2-4 of a motor protection frame; a drop sorting seat 3; a central drop tube 3-1; a discharge tank 3-2; collecting the arc-shaped frames 3-3; 3-4 of a longitudinal rack sliding groove; rotating the round holes 3-5; an omnidirectional scanner 4; a scanning drive motor 4-1; the driving turntable 4-2; driving the hinge rod 4-3; a driving rack 4-4; driving a reciprocating gear 4-5; 4-6 of a scanning rotating shaft; 4-7 of a cross arc scanning seat; 4-8 parts of arc-shaped baffle plates; 4-9 of arc-shaped slot; 4-10 of a strip-shaped infrared scanner; a directional distribution conveyor 5; a fixed circular plate 5-1; a classification propulsion plate 5-2; 5-3 of an arc top seat; 5-4 of an arc-shaped convex top block; 5-5 parts of a lower rotary table; the frequency conversion signal receives the motor 5-6.
Detailed Description
The present invention will be described in further detail with reference to the accompanying drawings.
The fixed connection in the device can be fixed by welding, thread fixing and the like, the rotary connection can be realized by baking the bearing on a shaft, a spring retainer groove or an inter-shaft baffle is arranged on the shaft or a shaft hole, the axial fixation of the bearing is realized by clamping an elastic retainer ring in the spring retainer groove or the inter-shaft baffle, and the rotation is realized by the relative sliding of the bearing; different connection modes are used in combination with different use environments.
The first embodiment is as follows:
as shown in fig. 1-10, aviation logistics transportation ground service classifier bears adapter 1, ground service transportation fork seat 2, whereabouts classification seat 3, all-round scanner 4 and directional distributor 5 including the whereabouts, ground service transportation fork seat 2 upper and lower both ends respectively fixed connection bear adapter 1 and whereabouts classification seat 3 on the whereabouts, the whereabouts bears adapter 1 intercommunication whereabouts classification seat 3, all-round scanner 4 rotates to be connected in whereabouts classification seat 3, directional distributor 5 fixed connection is on ground service transportation fork seat 2 and whereabouts classification seat 3. The ground service transportation forklift seat 2 is displaced to a discharging position through the ground service forklift, and the connection of discharging is facilitated through the falling bearing connector 1; the unloaded goods fall into the falling bearing connector 1, intermittently fall into the omnibearing scanner 4 in batches for omnibearing strip scanning through the driving of the omnibearing scanner 4, then fall onto the directional separate conveyor 5, and the process is repeated; the directional separating and transporting device 5 receives signals transmitted by the omnibearing scanner 4, further determines three modes of positive rotation, negative rotation and immobility, and realizes classification through the directional separating and transporting device 5; the packages can be automatically classified according to the bar code display positions in the ground service unloading and transporting process, so that the transporting efficiency is efficiently improved; the method comprises the steps of determining the condition of a bar code package by intermittently scanning the package in the falling process in 360 degrees in an all-around manner, classifying package information, and distributing the package information to a designated area in the falling process; the unloading and the transportation of the air transportation can be conveniently linked.
The second embodiment is as follows:
as shown in FIGS. 1 to 10, the present embodiment further illustrates the first embodiment, the falling load adapter 1 includes an upper collecting slope case 1-1, a left fixed slide 1-2, a falling extension slope base 1-3, two connection electric telescopic rods 1-4 and classified falling circular holes 1-5, the left end of the upper collecting slope case 1-1 is fixedly connected with the left fixed slide 1-2, the falling extension slope base 1-3 is slidably connected in the left fixed slide 1-2 through a slide block, the falling extension slope base 1-3 is slidably connected at the upper end of the upper collecting slope case 1-1, the two connection electric telescopic rods 1-4 are respectively fixedly connected at the two ends of the upper collecting slope case 1-1, the two ends of the falling extension slope base 1-3 are respectively fixedly connected to the telescopic rods of the two connection electric telescopic rods 1-4, the classification falling round holes 1-5 are arranged at the lower end of the inner wall of the upper collecting slope box 1-1. The device is conveyed to an appointed position through a forklift, the two linked electric telescopic rods 1-4 are used for propelling the falling extension landslide seats 1-3 to slide on the upper collection slope box 1-1 and the left fixed sliding seat 1-2 and cling to the unloading position of the airplane, so that goods fall into the upper collection slope box 1-1 conveniently for transportation, and the falling of packages is facilitated through the classified falling round holes 1-5.
The third concrete implementation mode:
as shown in fig. 1 to 10, in the present embodiment, to further explain the second embodiment, the ground service transportation forklift seat 2 includes a lower plate 2-1, a lower classification sliding block frame 2-2, two slot sockets 2-3 and a motor protection frame 2-4, the lower classification sliding block frame 2-2 is longitudinally and slidably connected to the lower plate 2-1 through a slider, the two slot sockets 2-3 are uniformly and fixedly connected to the lower end of the lower plate 2-1, and the motor protection frame 2-4 is fixedly connected to the lower plate 2-1. The lower classification sliding baffle frame 2-2 is slid to prevent the stacked goods from falling off from the lower bottom plate 2-1, and meanwhile, the goods can be conveniently unloaded to be unloaded.
The fourth concrete implementation mode:
as shown in FIGS. 1 to 10, the third embodiment is further explained in the present embodiment, the falling classification base 3 includes a central falling cylinder 3-1, three discharge slots 3-2, three collection arc frames 3-3, a longitudinal rack sliding slot 3-4 and an inner rotation circular hole 3-5, the lower end of the central falling cylinder 3-1 is fixedly connected to a lower bottom plate 2-1, the three discharge slots 3-2 are uniformly communicated with the central falling cylinder 3-1, the three collection arc frames 3-3 are uniformly and fixedly connected to the outer wall of the central falling cylinder 3-1 and the lower bottom plate 2-1, the longitudinal rack sliding slot 3-4 is arranged on the outer wall of the central falling cylinder 3-1, and the inner rotation circular hole 3-5 is arranged in the central falling cylinder 3-1. Goods fall into the central falling cylinder 3-1 through the classified falling circular holes 1-5, when the two arc-shaped baffles 4-8 of the cross-shaped arc-shaped scanning seat 4-7 in reciprocating rotation block the central falling cylinder 3-1, scanning packages cannot be added, when the two arc-shaped slots 4-9 communicate the central falling cylinder 3-1, the packages fall into the cross-shaped arc-shaped scanning seat 4-7, the packages are subjected to omnibearing dust surface through the four bar-shaped infrared scanners 4-10 in reciprocating rotation, bar codes are prevented from being omitted, package information is determined, the packages fall onto the fixed circular plate 5-1 through the arc-shaped slots 4-9, intermittent package adding and omnibearing scanning are achieved, and package information is obtained.
The fifth concrete implementation mode:
as shown in fig. 1 to 10, the present embodiment further illustrates the fourth embodiment, the omnidirectional scanner 4 includes a scanning driving motor 4-1, a driving turntable 4-2, a driving hinge rod 4-3, a driving rack 4-4, a driving reciprocating gear 4-5, a scanning rotating shaft 4-6, a cross arc scanning seat 4-7, two arc baffles 4-8, two arc slots 4-9, and four strip infrared scanners 4-10, the scanning driving motor 4-1 is fixedly connected to the lower base plate 2-1 through a motor fixing seat, the driving turntable 4-2 is fixedly connected to a transmission shaft of the scanning driving motor 4-1, two ends of the driving hinge rod 4-3 are respectively hinged to an eccentric portion of the driving turntable 4-2 and a lower end of the driving rack 4-4, a driving rack 4-4 is connected in a longitudinal rack sliding groove 3-4 in a sliding mode through a limiting sliding block, the driving rack 4-4 is meshed with a driving reciprocating gear 4-5 for transmission, a scanning rotating shaft 4-6 is connected in a rotating round hole 3-5 in a rotating mode, a cross arc scanning seat 4-7 is fixedly connected on the scanning rotating shaft 4-6, two arc baffles 4-8 are uniformly and fixedly connected on the cross arc scanning seat 4-7, two arc slots 4-9 are uniformly arranged on the cross arc scanning seat 4-7, and four strip-shaped infrared scanners 4-10 are uniformly and fixedly connected on the inner wall of the cross arc scanning seat 4-7. A scanning driving motor 4-1 is connected with electricity to drive a driving rotary disc 4-2 to rotate, and then a driving rack 4-4 is driven to longitudinally reciprocate in a longitudinal rack sliding groove 3-4 through a driving hinge rod 4-3, and further a driving reciprocating gear 4-5 is driven to rotate in a reciprocating mode, so that a scanning rotating shaft 4-6, a cross arc scanning seat 4-7, two arc baffles 4-8, two arc slots 4-9 and four strip-shaped infrared scanners 4-10 rotate in a reciprocating mode in a central falling cylinder 3-1.
The sixth specific implementation mode:
as shown in fig. 1 to 10, the fifth embodiment is further illustrated in the present embodiment, the directional distributor 5 includes a fixed circular plate 5-1, three classification propulsion plates 5-2, three arc-shaped footstock 5-3, three arc-shaped jacking blocks 5-4, a lower turntable 5-5 and a variable frequency signal receiving motor 5-6, the fixed circular plate 5-1 is fixedly connected to the lower end of the inner wall of the central falling cylinder 3-1, the outer ends of the three classification propulsion plates 5-2 are uniformly and rotatably connected to the fixed circular plate 5-1, the three arc-shaped footstock 5-3 are respectively and fixedly connected to the lower sides of the inner ends of the three classification propulsion plates 5-2, the arc-shaped jacking blocks 5-4 are attached to the arc-shaped footstock 5-3, and the three arc-shaped jacking blocks 5-4 are all and fixedly connected to the lower turntable 5-5, the lower rotary table 5-5 is fixedly connected to a transmission shaft of a variable frequency signal receiving motor 5-6, and the variable frequency signal receiving motor 5-6 is fixedly connected to the middle end of the lower bottom plate 2-1. The four bar-shaped infrared scanners 4-10 transmit the obtained bar code information to the variable frequency signal receiving motor 5-6 according to the electric signal, and then drive the variable frequency signal receiving motor 5-6 to obtain three kinds of information through information editing, namely, the forward rotation part distance and the reverse rotation part distance of the lower rotating disc 5-5 are respectively driven to keep still, so that the three arc-shaped convex top blocks 5-4 respectively jack up the three arc-shaped top seats 5-3, and further the three classification propelling plates 5-2 are respectively lifted in combination with the falling information of different packages, and the packages are jacked up to fall into the three specified discharge grooves 3-2 and fall into the three determined collection arc frames 3-3 for classified collection.
The seventh embodiment:
as shown in fig. 1 to 10, in the sixth embodiment, the strip-shaped infrared scanner 4-10 is in a shape of a semicircular arc. Convenient all-round scanning.
The specific implementation mode is eight:
as shown in fig. 1 to 10, in this embodiment, a seventh embodiment is further described, three arc-shaped ejecting blocks 5-4 are provided, the included angles between the three arc-shaped ejecting blocks 5-4 are respectively 100 °, 120 ° and 140 °, and the initial position of the arc-shaped ejecting block 5-4 at the center is attached to the arc-shaped ejecting base 5-3. Thereby determining the position and actuation to be jacked.
The use method of the air logistics transportation ground service classifier comprises the following steps:
the method comprises the following steps: the ground service transportation forklift seat 2 is displaced to a discharging position through the ground service forklift, and the connection of discharging is facilitated through the falling bearing connector 1;
step two: the unloaded goods fall into the falling bearing connector 1, intermittently fall into the omnibearing scanner 4 in batches for omnibearing strip scanning through the driving of the omnibearing scanner 4, then fall onto the directional separate conveyor 5, and the process is repeated;
step three: the directional separating and transporting device 5 receives the signals transmitted by the omnibearing scanner 4, further determines three modes of positive rotation, negative rotation and immobility, and realizes classification through the directional separating and transporting device 5.
The working principle of the aviation logistics transportation ground service classifier is as follows: the fork of the forklift is inserted into the two slot seats 2-3, the whole device is transported to a designated position, the two linked electric telescopic rods 1-4 are used for propelling the falling extension landslide seats 1-3 to slide on the upper collection slope box 1-1 and the left fixed slide seat 1-2 and cling to the unloading position of the airplane, so that goods fall into the upper collection slope box 1-1 conveniently for transportation, and the falling of packages is facilitated through the classified falling circular holes 1-5; the lower classification sliding baffle frame 2-2 is slid on the lower bottom plate 2-1 to prevent the stacked goods from falling off, and meanwhile, the goods are conveniently unloaded to be unloaded; a scanning driving motor 4-1 is connected with electricity to drive a driving turntable 4-2 to rotate, and then a driving rack 4-4 is driven to longitudinally reciprocate in a longitudinal rack sliding groove 3-4 through a driving hinge rod 4-3, and further a driving reciprocating gear 4-5 is driven to rotate in a reciprocating manner, so that a scanning rotating shaft 4-6, a cross arc scanning seat 4-7, two arc baffles 4-8, two arc slots 4-9 and four strip-shaped infrared scanners 4-10 rotate in a reciprocating manner in a central falling cylinder 3-1; goods fall into a central falling cylinder 3-1 through classified falling circular holes 1-5, when two arc-shaped baffles 4-8 of a cross-shaped arc-shaped scanning seat 4-7 which rotates in a reciprocating manner block the central falling cylinder 3-1, scanning packages cannot be added, when two arc-shaped slots 4-9 communicate the central falling cylinder 3-1, the packages fall into the cross-shaped arc-shaped scanning seat 4-7, the packages are subjected to omnibearing smudging through four strip-shaped infrared scanners 4-10 which rotate in a reciprocating manner, bar codes are avoided from being omitted, package information is determined, and then the packages fall onto a fixed circular plate 5-1 through the arc-shaped slots 4-9, so that intermittent package adding and omnibearing scanning are realized, and package information is obtained; the four bar-shaped infrared scanners 4-10 transmit the obtained bar code information to a variable frequency signal receiving motor 5-6 according to electric signals, and then drive the variable frequency signal receiving motor 5-6 to obtain three kinds of information through information editing, namely, the distance of a forward rotation part and the distance of a reverse rotation part of a lower rotating disc 5-5 are respectively driven to keep the distance and the distance, so that three arc-shaped convex top blocks 5-4 respectively jack up three arc-shaped top seats 5-3, and further three classification propelling plates 5-2 are respectively lifted in combination with falling information of different packages, and the packages are jacked up to fall into three specified discharge grooves 3-2 and fall into three determined collection arc-shaped frames 3-3 for classification collection; the packages can be automatically classified according to the bar code display positions in the ground service unloading and transporting process, and the transporting efficiency is efficiently improved; the method comprises the steps of determining the condition of a bar code package by intermittently scanning the package in the falling process in 360 degrees in an all-around manner, classifying package information, and distributing the package information to a designated area in the falling process; the unloading and the transportation of the air transportation can be conveniently linked.
The above description is not intended to limit the present invention, and the present invention is not limited to the above examples, and variations, modifications, additions and substitutions which may be made by those skilled in the art within the spirit of the present invention are within the scope of the present invention.
Claims (9)
1. Aviation logistics transportation ground service classifier bears linker (1), ground service transportation fork saddle (2), whereabouts classification seat (3), all-round scanner (4) and directional fortune ware (5), its characterized in that including the whereabouts: ground service transportation fork saddle (2) upper and lower both ends respectively fixed connection bear link up ware (1) and whereabouts classification seat (3) on the whereabouts, the whereabouts bears link up ware (1) intercommunication whereabouts classification seat (3), all-round scanner (4) rotate to be connected in whereabouts classification seat (3), directional distribution ware (5) fixed connection is on ground service transportation fork saddle (2) and whereabouts classification seat (3).
2. The air logistics transport ground service classifier of claim 1, wherein: the falling bearing adapter (1) comprises an upper collecting slope box (1-1), a left fixed sliding seat (1-2), a falling extension landslide seat (1-3), two connection electric telescopic rods (1-4) and classified falling round holes (1-5), wherein the left end of the upper collecting slope box (1-1) is fixedly connected with the left fixed sliding seat (1-2), the falling extension landslide seat (1-3) is connected in the left fixed sliding seat (1-2) in a sliding manner through a sliding block, the falling extension landslide seat (1-3) is connected at the upper end of the upper collecting slope box (1-1) in a sliding manner, the two connection electric telescopic rods (1-4) are respectively and fixedly connected at the two ends of the upper collecting slope box (1-1), the two ends of the falling extension landslide seat (1-3) are respectively and fixedly connected on telescopic rods of the two connection electric telescopic rods (1-4), the classification falling round holes (1-5) are arranged at the lower end of the inner wall of the upper collecting slope box (1-1).
3. The air logistics transport ground service classifier of claim 2, wherein: the ground service transportation forklift seat (2) comprises a lower base plate (2-1), a lower classification sliding block frame (2-2), two slot seats (2-3) and a motor protection frame (2-4), wherein the lower classification sliding block frame (2-2) is longitudinally and slidably connected onto the lower base plate (2-1) through a sliding block, the two slot seats (2-3) are uniformly and fixedly connected to the lower end of the lower base plate (2-1), and the motor protection frame (2-4) is fixedly connected onto the lower base plate (2-1).
4. The air logistics transportation ground service classifier of claim 3, wherein: the falling classification seat (3) comprises a central falling cylinder (3-1), three discharge grooves (3-2), three collection arc frames (3-3), a longitudinal rack sliding groove (3-4) and a rotary round hole (3-5), the lower end of a central falling cylinder (3-1) is fixedly connected on a lower bottom plate (2-1), three discharge grooves (3-2) are uniformly communicated and arranged on the central falling cylinder (3-1), three collecting arc-shaped frames (3-3) are uniformly and fixedly connected on the outer wall of the central falling cylinder (3-1) and the lower bottom plate (2-1), a longitudinal rack sliding groove (3-4) is arranged on the outer wall of the central falling cylinder (3-1), and an internal rotation round hole (3-5) is arranged in the central falling cylinder (3-1).
5. The air logistics transportation ground service classifier of claim 4, wherein: the all-dimensional scanner (4) comprises a scanning driving motor (4-1), a driving turntable (4-2), a driving hinge rod (4-3), a driving rack (4-4), a driving reciprocating gear (4-5), a scanning rotating shaft (4-6), a cross arc scanning seat (4-7), two arc baffles (4-8), two arc slots (4-9) and four strip infrared scanners (4-10), wherein the scanning driving motor (4-1) is fixedly connected on a lower base plate (2-1) through a motor fixing seat, the driving turntable (4-2) is fixedly connected on a transmission shaft of the scanning driving motor (4-1), two ends of the driving hinge rod (4-3) are respectively hinged at the eccentric part of the driving turntable (4-2) and the lower end of the driving rack (4-4), a driving rack (4-4) is connected in a longitudinal rack sliding groove (3-4) in a sliding mode through a limiting sliding block, the driving rack (4-4) is meshed with a driving reciprocating gear (4-5) for transmission, a scanning rotating shaft (4-6) is connected in a rotating round hole (3-5) in a rotating mode, a cross arc scanning seat (4-7) is fixedly connected to the scanning rotating shaft (4-6), two arc baffles (4-8) are uniformly and fixedly connected to the cross arc scanning seat (4-7), two arc slots (4-9) are uniformly arranged on the cross arc scanning seat (4-7), and four strip infrared scanners (4-10) are uniformly and fixedly connected to the inner wall of the cross arc scanning seat (4-7).
6. The air logistics transportation ground service classifier of claim 5, wherein: the directional distribution conveyor (5) comprises a fixed circular plate (5-1), three classification pushing plates (5-2), three arc-shaped top seats (5-3), three arc-shaped convex top blocks (5-4), a lower rotary table (5-5) and a variable frequency signal receiving motor (5-6), wherein the fixed circular plate (5-1) is fixedly connected with the lower end of the inner wall of a central falling cylinder (3-1), the outer ends of the three classification pushing plates (5-2) are uniformly and rotatably connected in the fixed circular plate (5-1), the three arc-shaped top seats (5-3) are respectively and fixedly connected with the lower sides of the inner ends of the three classification pushing plates (5-2), the arc-shaped convex top blocks (5-4) are attached to the arc-shaped top seats (5-3), and the three arc-shaped convex top blocks (5-4) are all fixedly connected on the lower rotary table (5-5), the lower turntable (5-5) is fixedly connected to a transmission shaft of the variable frequency signal receiving motor (5-6), and the variable frequency signal receiving motor (5-6) is fixedly connected to the middle end of the lower bottom plate (2-1).
7. The air logistics transportation ground service classifier of claim 6, wherein: the strip-shaped infrared scanner (4-10) is in a semi-circular arc shape.
8. The air logistics transportation ground service classifier of claim 7, wherein: the arc-shaped convex ejecting blocks (5-4) are arranged in three numbers, the included angles among the three arc-shaped convex ejecting blocks (5-4) are respectively 100 degrees, 120 degrees and 140 degrees, and the initial position of the arc-shaped convex ejecting block (5-4) at the center is attached to the arc-shaped ejecting seat (5-3).
9. Use of the air logistics transport ground service classifier of claim 8, wherein:
the method comprises the following steps: the ground service transportation forklift seat (2) is displaced to a discharging position through the ground service forklift, and the connection of discharging is facilitated through the falling bearing connector (1);
step two: the unloaded goods fall into the falling bearing connector (1), intermittently fall into the omnibearing scanner (4) in batches for omnibearing strip scanning by the driving of the omnibearing scanner (4), then fall onto the directional separating conveyor (5), and the process is repeated;
step three: the directional transport divider (5) receives signals transmitted by the omnibearing scanner (4), further determines three modes of positive rotation, negative rotation and immobility, and realizes classification through the directional transport divider (5).
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