CN113581722A

CN113581722A - Computer-based traffic planning design link simulation automatic access device

Info

Publication number: CN113581722A
Application number: CN202110938121.0A
Authority: CN
Inventors: 郭茜; 梁先登; 苑文萍; 冯轩; 张胜伟; 蒲丹丹; 李浩浩; 刘敏; 王笑语; 陈政
Original assignee: Zhengzhou Communications Planning Survey & Design Institute
Current assignee: Zhengzhou Transportation Planning Survey Design And Research Institute Co ltd
Priority date: 2021-08-16
Filing date: 2021-08-16
Publication date: 2021-11-02
Anticipated expiration: 2041-08-16
Also published as: CN113581722B

Abstract

The invention relates to a computer-based automatic access device for simulating a traffic planning and designing link, which effectively solves the problem of model searching or model random losing and random releasing in the traffic planning and designing simulation link, adopts a computer control mode, accurately selects a model to automatically fetch and deliver the model, and ensures that the whole simulation process is more efficient and convenient; this device uses the computer to click the model that needs, and the inside transmission of device can put into the conveyer belt with the model dish that is equipped with the model and see off, treats to use or the simulation back that finishes, puts into the conveyer belt with the model dish on, send the dish model to holding the trench position by conveyer belt cooperation extrusion ring, then send back under transmission and hold the groove, make whole analog process simple, convenient.

Description

Computer-based traffic planning design link simulation automatic access device

Technical Field

The invention relates to the field of traffic road planning, in particular to a computer-based traffic planning design link simulation automatic access device.

Background

The traffic planning design is an important guarantee for establishing a perfect and comprehensive transportation system, is a fundamental measure for solving the current road traffic, is an effective way for obtaining the optimal traffic benefit, is an important link for realizing the scientific and modern management of urban traffic and fully utilizing the existing road traffic facilities; before road construction, traffic planning design needs to be carried out on the road section or among intersections according to actual requirements or requirements, and through the planning design of road section traffic and experimental simulation, optimal planning is confirmed from the road section or the intersections for implementation; in the real life, when carrying out the traffic planning simulation, go to look for the model according to the drawing of oneself planning, then put the simulation, current road planning simulation phase, look for the model and can waste a lot of time, after the simulation is accomplished, do not classify and put or lose everywhere, make the next simulation need more time to go to look for to not only can not reach the effect in the simulation, still can waste time.

In view of the above, we provide a computer-based traffic planning design link simulation automatic access device for solving the above problems.

Disclosure of Invention

Aiming at the situation and overcoming the defects of the prior art, the invention provides the computer-based traffic planning design link simulation automatic access device, which adopts a computer control mode and accurately selects a model to automatically access the model, so that the whole simulation process is more efficient and convenient; this device uses the computer to click the model that needs, and the inside transmission of device can put into the conveyer belt with the model dish that is equipped with the model and see off, treats to use or the simulation back that finishes, puts into the conveyer belt with the model dish on, send the dish model to holding the trench position by conveyer belt cooperation extrusion ring, then send back under transmission and hold the groove, make whole analog process simple, convenient.

Automatic device of fetching and depositing of traffic planning design link simulation based on computer, the power distribution box comprises a box body and is characterized in that, the inside a plurality of grooves that hold that are equipped with of box and hold inslot slidable mounting have the model dish, the cooperation of model dish is installed transmission and is made the model dish carry out longitudinal sliding holding inslot, the conveying groove has been seted up to the box inside, the conveying belt is installed in the inside rotation of conveying groove, the conveying belt passes through the transmission drive, conveyer belt one side is rotated and is installed the extrusion ring, extrusion ring fixed surface installs compression spring and the compression spring other end and installs the leather strap.

Preferably, transmission installs in the inside reciprocal lead screw of box and reciprocal lead screw thread fit including rotating has square piece, the box is inside to be seted up with square piece complex square groove, the rack is installed to model dish one side, the inside drive tooth's socket of having seted up of box, the rack toothing has the rotation to install in the drive gear of drive tooth's socket lateral wall, square hole and square piece cooperation slip are seted up at the drive gear center, charging magnet and electric connection in the computer are installed to drive gear inside square hole one side, it installs trigger switch and trigger switch electric connection in the computer to hold the groove lateral wall.

Preferably, the conveying belt is rotatably mounted in the conveying groove through a driving roller and a driven roller, a first helical gear is coaxially and fixedly mounted at one end of the driving roller close to the reciprocating screw rod, a second helical gear rotatably mounted in the box body is meshed with the first helical gear, and the second helical gear is connected to the reciprocating screw rod through a belt.

Preferably, the drive roll is provided with screw thread and drive roll screw-thread fit near reciprocal lead screw one end and installs the initiative sleeve, the driven voller is provided with screw thread and driven voller screw-thread fit near reciprocal lead screw one end and installs driven sleeve, initiative sleeve and driven sleeve cooperation extrusion ring carry out rotary motion, the inside race groove and the race groove upper wall that is provided with of box has seted up the shifting chute, the extrusion ring be provided with the fixed block of race groove complex and the inside rotation of fixed block install the leading wheel.

Preferably, a plurality of extension springs are slidably mounted on the side wall of the extrusion ring, the other ends of the extension springs are mounted inside the box body, a rotating gear is coaxially mounted on the side wall of the driven roller which is symmetrical to one side of the driving roller, a first inclined block is transversely slidably mounted on one side of the moving groove away from the conveying belt, a first spring is fixedly mounted at one end of the first inclined block, one end of the first spring is fixedly mounted inside the box body, the first inclined block is connected to a first take-up pulley rotatably mounted inside the box body through a wire rope, the first take-up pulley is connected with a first incomplete gear meshed with the rotating gear through a first belt, a first torsion spring is mounted on one side of the first incomplete gear, a second inclined block is slidably mounted at one end of the moving groove away from the first inclined block, a second spring is fixedly mounted at one end of the second inclined block, one end of the second spring is fixedly mounted inside the box body, and the second inclined block is connected to a second take-up pulley rotatably mounted inside the box body through a wire rope, the second take-up pulley is connected with a second incomplete gear meshed with the rotating gear through a second belt, and a second torsion spring is installed on one side of the second incomplete gear.

Preferably, the side wall of the model disc, which is far away from one side of the conveying belt, is rotatably provided with a plurality of rotating wheels, one side of the rack fixedly arranged on the model disc is provided with a third spring, and the other end of the third spring is provided with a single tooth which transversely slides on the rack.

Preferably, one side of the conveying belt is provided with a placing disc arranged inside the box body.

The beneficial effects of the technical scheme are as follows:

(1) the computer-based traffic planning design link simulation automatic access device adopts a computer control mode, a motor is used for driving a lead screw, and the lead screw is matched with characteristics of a square block and a charging magnet, so that a model is accurately selected, a model disc with the model is sent out of a containing groove and placed on a conveying belt for selection;

(2) when the device utilizes set up the screw thread on conveyer belt drive roll and the driven voller to make and put back the model, the extrusion ring extrusion of drive is put into the model dish of model, makes the model dish get into and holds the groove, then transports by transmission and holds the inslot.

Drawings

FIG. 1 is a schematic view of the overall structure of the present invention;

FIG. 2 is a side cross-sectional structural schematic view of the present invention;

FIG. 3 is a schematic view of the transmission of the present invention;

FIG. 4 is a schematic side view of the transmission of the present invention;

FIG. 5 is a schematic view of a transmission structure of the conveyor belt of the present invention;

FIG. 6 is a schematic sectional view of the case according to the present invention;

FIG. 7 is a schematic cross-sectional view of an extrusion ring according to the present invention;

FIG. 8 is a schematic view of the extrusion ring control structure of the present invention;

FIG. 9 is a schematic view of a model disk structure of the present invention;

FIG. 10 is a schematic view of the drive gear of the present invention;

FIG. 11 is a schematic view of the extrusion ring of the present invention;

FIG. 12 is a schematic view of the initial position of the model plate according to the present invention;

FIG. 13 is a schematic view of the movement of the squeeze ring of the present invention.

Detailed Description

The foregoing and other technical matters, features and effects of the present invention will be apparent from the following detailed description of the embodiments, which is to be read in connection with the accompanying drawings of fig. 1 to 13. The structural contents mentioned in the following embodiments are all referred to the attached drawings of the specification.

Exemplary embodiments of the present invention will be described below with reference to the accompanying drawings.

The first embodiment provides a traffic planning design link simulation device based on a computer 2, which comprises a box body 1 and a computer 2, the automatic model arranging device comprises a projector 3 and a model arranging tray 4, wherein a computer 2 is installed on the upper wall of a box body 1, the projector 3 is installed on the upper wall of the box body 1 in a longitudinal sliding mode, the model arranging tray 4 is installed on the upper wall of the box body 1, a plurality of containing grooves 5 are formed in the box body 1, and model trays 6 are installed in the containing grooves 5 in the sliding mode, the model trays 6 are provided with a transmission device in a matching mode, the transmission device enables the model trays 6 to slide longitudinally in the containing grooves 5, the transmission device is connected with a motor installed on the side wall of the box body 1, the motor is electrically connected to the computer 2, a conveying groove 7 is formed in the box body 1, a conveying belt 8 is installed in the conveying groove 7 in a rotating mode, the conveying belt 8 is driven by the transmission device, an extrusion ring 9 is installed on one side of the conveying belt 8 in a rotating mode, a compression spring 10 is fixedly installed on the surface of the extrusion ring 9, and a leather strip 11 is installed at the other end of the compression spring 10; when the simulation is carried out, a person draws on the computer 2 and transmits the drawing to the projector 3 to be displayed on the surface of the model placing disc 4, the person clicks a required model, then the computer 2 drives the motor to rotate, so that the transmission device sends the required model to the conveyer belt 8, the conveyer belt 8 is driven to rotate by the transmission device, so that the model placing disc 6 containing the model is sent out of the box body 1 for simulation use by a worker, after the simulation of the worker is finished, the model is placed in the model placing disc 6 and then placed on the conveyer belt 8, the motor drives the transmission device to rotate reversely, so that the conveyer belt 8 also rotates reversely, the conveyer belt 8 rotates reversely, so that the extruding ring 9 moves towards the conveyer belt 8, until a leather strip 11 provided with a compression spring 10 on the extruding ring 9 is abutted against the model placing disc 6, then the conveyer belt 8 and the extruding ring 9 rotate synchronously, so that the model placing disc 6 is sent to the position of the placing groove 5 and slides towards the inside of the placing groove 5 under the action of the compression spring 10, the sliding position is returned to the inside of the containing groove 5 by a transmission device.

In the second embodiment, on the basis of the first embodiment, referring to fig. 3 and fig. 4, the transmission device includes a reciprocating screw rod 12 rotatably installed inside the box body 1, the reciprocating screw rod 12 is in threaded fit with a square block 13 (made of iron), a square groove 14 matched with the square block 13 is formed inside the box body 1, a guide strip is installed on the upper wall of the square block 13 and is matched with the square groove 14, a rack 15 is installed on one side of the model disc 6, a driving tooth groove 16 is formed inside the box body 1, the rack 15 is meshed with a driving gear 17 rotatably installed on the side wall of the driving tooth groove 16, a square hole 18 is formed in the center of the driving gear 17, the square hole 18 is matched with the square block 13 to slide, and a charging magnet 19 is installed on one side of the square hole 18 of the driving gear 17 and is electrically connected to the computer 2; when the computer 2 selects a model, the charging magnet 19 in the driving gear 17 corresponding to the model is charged and has magnetism, the computer 2 starts the motor to rotate forwards, so that the square block 13 reciprocates along the reciprocating screw rod 12, when the square block 13 moves to the driving tooth space 16 of the selected model, the square block starts to be matched with the square hole 18 in the driving gear 17, the charging magnet 19 is installed on the side wall of the square hole 18, and the charging magnet 19 has magnetism after being charged, so that the square block 13 is adsorbed by the charging magnet 19 when sliding into the square hole 18, the other end of the square block 13 is matched with the square groove 14 and continues to slide into the square hole 18 until the square block 13 leaves the square groove 14 and the whole square block 13 is in the driving tooth space 16, and at the moment, the front end of the square block 13 is attracted by the charging magnet 19 installed on the side wall of the square hole 18, the rotation direction constraint of the square groove 14 is lost, the reciprocating screw rod 12 drives the square block 13 to rotate with the driving gear 17, the driving gear 17 is meshed with a rack 15 arranged on the side wall of the model disc 6, and the driving gear 17 rotates to drive the model disc 6 to be discharged out of the containing groove 5 and be sent to the conveying belt 8; when the simulation is finished and the model disc 6 needs to be sent back to the containing groove 5, a user triggers the computer 2 to select to put back the model disc 6, the model disc 6 is put on the conveyer belt 8, the computer 2 enables the motor to rotate reversely, the conveyer belt 8 also rotates reversely, the conveyer belt 8 sends the model disc 6 to the containing groove 5, the motor rotates reversely to drive the reverse rotation of the driving gear 17, the driving gear 17 rotates reversely to move the rack 15 engaged with the driving gear 17, the model disc 6 is sent into the containing groove 5 until the model disc 6 is abutted against the trigger switch 20, the trigger switch 20 is electrically connected with the computer 2, the computer 2 controls the charging magnet 19 to lose power, the square block 13 is not attracted by the charging magnet 19, when the square block 13 and the driving gear 17 rotate to the initial position (namely the matching state position of the square block 13 and the square groove 14), the square block 13 is separated from the driving gear 17 and slides to the square groove 14, at this time, the square block 13 is restricted by rotation and moves linearly until the worker selects a model.

In the third embodiment, on the basis of the first embodiment, referring to fig. 5, the conveyor belt is rotatably mounted in the conveyor groove 7 through a driving roller 21 and a driven roller 22, a first bevel gear 23 is coaxially and fixedly mounted at one end of the driving roller 21 close to the reciprocating screw rod 12, a second bevel gear 24 rotatably mounted in the box body 1 is meshed with the first bevel gear 23, and the second bevel gear 24 is connected to the reciprocating screw rod 12 through a belt; after the computer 2 selects a model, the motor is started to drive the reciprocating screw rod 12 to rotate, the second bevel gear 24 connected with the reciprocating screw rod 12 through a belt rotates, the second bevel gear 24 drives the first bevel gear 23 to rotate, the first bevel gear 23 drives the driving roller 21 to rotate, and the driving roller 21 rotates to enable the conveying belt 8 to rotate together with the driven roller 22.

In the fourth embodiment, on the basis of the third embodiment, as shown in fig. 7 and 8, a screw thread is provided at one end of the driving roller 21 close to the reciprocating screw rod 12, a driving sleeve 25 is installed at the driving roller 21 in a screw thread fit manner, a screw thread is provided at one end of the driven roller 22 close to the reciprocating screw rod 12, a driven sleeve 26 is installed at the driven roller 22 in a screw thread fit manner, the driving roller 21 and the driven roller 22 have the same screw thread direction and length, the driving sleeve 25 and the driven sleeve 26 cooperate with the extrusion ring 9 to perform a rotational motion, a belt groove 27 is provided inside the case 1, a moving groove 28 is provided on the upper wall of the belt groove 27, the extrusion ring 9 is provided with a fixed block 29 cooperating with the moving groove 28, a guide wheel 30 is rotatably installed inside the fixed block 29, a plurality of extension springs 31 are slidably installed on the side wall of the extrusion ring 9, the other ends of the extension springs 31 are installed inside the case 1, and rotating gears 32 are coaxially installed on the side walls of the driven roller 22 symmetrical to one side of the driving roller 21, a first inclined block 33 is transversely and slidably installed on one side of the moving groove 28 far away from the conveying belt 8, a first spring 34 is fixedly installed at one end of the first inclined block 33, one end of the first spring 34 is fixedly installed inside the box body 1, a guide strip is installed on the top wall of the first inclined block 33, the first inclined block 33 is connected with a first take-up pulley 35 rotatably installed inside the box body 1 through a wire rope, the first take-up pulley 35 is connected with a first incomplete gear 37 meshed with the rotating gear 32 through a first belt 36, a first torsion spring 48 is installed at one end of the first incomplete gear 37, a second inclined block 38 is slidably installed at one end of the moving groove 28 far away from the first inclined block 33, a second spring 39 is fixedly installed at one end of the second inclined block 38, one end of the second spring 39 is fixedly installed inside the box body 1, a guide strip is installed on the top wall of the second inclined block 38, the second inclined block 38 is rotatably installed inside the box body 1 through a second take-up pulley 40 connected with the wire rope, the second take-up pulley 40 is connected with a second incomplete gear 41 meshed with the rotating gear 32 through a second belt 46, one end of the second incomplete gear 41 is provided with a second torsion spring 47, and one side of the conveying belt 8 is provided with a placing disc 45 arranged inside the box body 1; in the initial state, the fixed block 29 on the extrusion ring 9 is positioned in the center of the moving groove 28 (namely, in the middle of the first inclined block 33 and the second inclined block 38), the first stub gear 37 and the second stub gear 41 are always meshed with the rotating gear 32 under the action of the first torsion spring 48 and the second torsion spring 47, the first inclined block 33 and the second inclined block 38 are respectively propped against the side wall of the moving groove 28 under the action of the first spring 34 and the second spring 39, when the conveying belt 8 rotates forwards (namely, the motor rotates forwards, the model disc 6 is conveyed to the conveying chain), at the moment, the driving sleeve 25 and the driven sleeve 26 which are matched with the driving roller 21 and the driven roller 22 rotate forwards due to the forward rotation of the driving roller 21 and the driven roller 22, and because the fixed block 29 installed on the extrusion ring 9 is positioned in the moving groove 28, the driving sleeve 25 and the driven sleeve 26 slide away from the conveying belt 8 under the action of the driving roller 21 and the driven roller 22, and the fixed block 29 slides a certain distance and then contacts with the first inclined block 33, the sliding is continued to be carried out in the direction away from the conveyer belt 8, the first inclined plane block 33 is extruded to the position of the top wall of the first inclined plane block 33 to the side wall of the moving groove 28, the fixed block 29 is continued to move out of the moving groove 28, at the moment, the first inclined plane block 33 is not extruded by the fixed plate, under the action of the first spring 34, the first inclined plane block 33 slides towards the inside of the moving groove 28 until the top wall of the first inclined plane block 33 is pressed against the side wall of the moving groove 28, at the moment, the conveyer belt 8 forwards transfers the model disc 6 to the material taking position, under the continuous rotation of the conveyer belt 8, the fixed plate slides out of the moving groove 28, the driving sleeve 25 is in threaded fit with the driving roller 21 to reach the end, the driven sleeve 26 is in threaded fit with the driven roller 22 to reach the end, at the moment, the rotation of the driving roller 21 and the driven roller 22 drives the rotation of the driving sleeve 25 and the driven sleeve 26, the extrusion ring 9 also rotates under the rotation of the driving sleeve 25 and the driven sleeve 26, the guide wheel 30 rotatably mounted on the fixed block 29 rotates along the outer wall of the moving groove 28 to provide the guide function, because the extrusion ring 9 continuously slides in the direction away from the conveying chain, the extension spring 31 which is slidably arranged on the side wall of the extrusion ring 9 is compressed; the forward rotation of the driven roller 22 drives the rotating gear 32 to rotate forward, the forward rotation of the rotating gear 32 drives the second incomplete gear 41 to rotate forward, the second incomplete gear 41 rotates to enable the second take-up pulley 40 to rotate through a belt, the cord between the take-up pulley and the second inclined plane block 38 is shrunk, the rotation angle of the incomplete gear enables the distance of the cord shrunk by the take-up pulley to be the distance from the top wall of the second inclined plane block 38 to slide to the other side wall of the moving groove 28, and the first incomplete gear 37 cannot be rotated by the forward rotation of the rotating gear 32 due to the meshing position relation of the first incomplete gear 37 and the rotating gear 32, so that the first inclined plane block 33 is at the initial position; when the model disc 6 needs to be put back after the simulation is finished, the motor rotates reversely to reversely rotate the conveying chain, the driving roller 21 and the driven roller 22 also rotate reversely, the driving sleeve 25 and the driven sleeve 26 also rotate reversely, the tension spring 31 is in a compressed state and always pushes against the extrusion ring 9 to move towards the conveying chain direction, at the moment, the driven roller 22 rotates reversely, the rotating gear 32 rotates reversely to rotate the second incomplete gear 41 meshed with the rotating gear, the second incomplete gear 41 rotates the second take-up pulley 40 reversely through the second belt 46 to loosen the wire between the second take-up pulley 40 and the second inclined plane block 38, the second inclined plane block 38 pushes the top wall of the second inclined plane block 38 against the side wall of the moving groove 28 under the action of the second spring 39 (namely, the reverse rotation of the rotating gear 32 drives the reverse rotation of the first incomplete gear 37, the reverse rotation of the first incomplete gear 37 rotates the first take-up pulley 35 connected through the first belt 36, the wire rope between the first take-up pulley 35 and the first inclined block 33 is contracted, the first inclined block 33 is pulled to slide to the other side wall of the moving groove 28, the fixed block 29 is opened to enter the position of the moving groove 28, the extrusion ring 9 is reversely rotated to the position of the fixed block 29 to the position of the moving groove 28, the extrusion ring 9 slides towards the conveying belt 8 under the action of the tension spring 31, the fixed block 29 enters the moving groove 28, the extrusion ring 9 is moved towards the conveying chain all the time by the reverse rotation of the driving roller 21 and the driven roller 22 until the fixed block 29 slides to the position of the second inclined block 38, the fixed block 29 slides to extrude the second inclined block 38 to slide until the second inclined block 38 is completely extruded, the driving sleeve 25 and the driven sleeve 26 slide towards the conveying belt 8 under the screw thread action of the driving roller 21 and the driven roller 22, the fixed block 29 slides out of the moving groove 28, the second inclined block 38 rebounds to the moving groove 28 under the action of the second spring 39, at the moment, the thread of the driving sleeve 25 is matched with the thread of the driving roller 21 at the topmost end, the thread of the driven sleeve 26 is matched with the thread of the driven roller 22 at the topmost end, the rotation of the driving roller 21 and the driven roller 22 causes the driving sleeve 25 and the driven sleeve 26 to rotate without further thread rotation, so that the extrusion ring 9 rotates reversely along with the conveying belt 8, the guide wheel 30 of the fixed block 29 on the extrusion ring 9 rotates and guides along with the outer side wall of the moving groove 28, the leather strips 11 on the extrusion ring 9, which are used for fixing the compression springs 10, are positioned on the conveying belt 8, the model disc 6 is placed on the placing disc 45 on the conveying belt 8 (in order to prevent the model disc 6 from moving due to the fact that the model disc 6 is too close to the containing groove 5, the conveying belt 8 moves with the model disc 6, the compression springs 10 are not contacted with the model disc 6, the acting force for placing in the containing groove 5 is not engaged with the rack 15), when one side of the model disc 6 close to the extrusion ring 9 is contacted and extruded by the compression springs 10, the model disc 6 rotates along with the extrusion ring 9 where the compression spring 10 is located, the compression spring 10 extrudes the model disc 6 to slide along the inner wall of the box body 1 until the model disc 6 slides to the position of the containing groove 5, the model disc 6 slides to the containing groove 5 under the action of the compression spring 10 until the fixed rack 15 of the model disc 6 is meshed with the driving gear 17, the driving gear 17 rotates reversely due to the reverse rotation of the motor, the driving gear 17 is meshed with the rack 15 to rotate so that the model disc 6 is sent to the inside of the containing groove 5, at the moment, the extension spring 31 in sliding connection with the extrusion ring 9 is in a stretched state, after the conveyer belt 8 rotates forwards, the ropes of the second bevel block 38 and the second take-up wheel 40 are contracted so that the second bevel block 38 is compressed to the side wall position of the moving groove 28, and the extension spring 31 is stretched to provide acting force for the extrusion ring 9 to move to the moving groove 28.

In the fifth embodiment, on the basis of the first embodiment, referring to fig. 6, a plurality of rotating wheels 42 are rotatably mounted on the side wall of the model disk 6 far away from the conveyor belt 8, a first spring 34 is mounted on one side of a rack 15 fixedly mounted on the model disk 6, and a single tooth 44 transversely sliding on the rack 15 is mounted at the other end of the first spring 34; when the driving gear 17 is matched with the square block 13 to rotate, the driving gear 17 is meshed with a single tooth 44 which is slidably arranged on the rack 15 through a third spring 43, the driving gear 17 rotates to enable the single tooth 44 to slide towards the direction of the conveying belt 8, the rack 15 is driven to be meshed with the driving gear 17, and the model disc 6 is sent out to the conveying belt 8; when the compression spring 10 fixed on the extrusion ring 9 extrudes the model disc 6 to move, the rotating wheel 42 on the model disc 6 slides along the inner wall of the box body 1 to prevent the model disc 6 from being damaged by friction with the inner wall of the box body 1, the model disc 6 moves to the position of the containing groove 5 and slides into the containing groove 5 under the action of the compression spring 10 until the driving gear 17 is meshed with the rack 15, the driving gear 17 rotates reversely to feed the model disc 6 into the containing groove 5, the model disc 6 is fed into the containing groove 5, the trigger switch 20 is extruded, the trigger switch 20 sends a signal to the computer 2, the computer 2 cuts off the power of the charging magnet 19 after processing, the square block 13 is not attracted by the charging magnet 19 inside the driving gear 17, the model disc 6 is fed into the innermost part of the containing groove 5, the driving gear 17 is meshed with the single tooth 44 fixedly connected with the rack 15 through the third spring 43, the driving gear 17 is meshed with the single tooth 44 to rotate all the time, at the moment, the driving gear 17 and the square block 13 continue to rotate until the square block 13 rotates to the position matched with the square groove 14, the square block 13 is separated from the square hole 18 of the driving gear 17 and slides into the square groove 14, then the computer 2 is clicked by a person to select, and the square block is matched with the driving gear 17 again to be sent out of the model disc 6.

The above description is only for the purpose of illustrating the present invention, and it should be understood that the present invention is not limited to the above embodiments, and various modifications conforming to the spirit of the present invention are within the scope of the present invention.

Claims

1. Automatic device of fetching and depositing of traffic planning design link simulation based on computer, including box (1), its characterized in that, box (1) inside is equipped with a plurality of grooves (5) that hold and holds inslot (5) slidable mounting has model dish (6), transmission and transmission make model dish (6) carry out longitudinal sliding holding in groove (5) are installed in the cooperation of model dish (6), conveying groove (7) have been seted up to box (1) inside, conveying belt (8) are installed in conveying groove (7) internal rotation, conveyer belt (8) are through the transmission drive, conveyer belt (8) one side is rotated and is installed extrusion ring (9), extrusion ring (9) fixed surface installs compression spring (10) and compression spring (10) other end and installs leather strap (11).

2. The computer-based automatic access device for simulating traffic planning design links according to claim 1, wherein the transmission device comprises a reciprocating screw rod (12) rotatably mounted inside the box body (1), the reciprocating screw rod (12) is in threaded fit with a square block (13), a square groove (14) matched with the square block (13) is formed inside the box body (1), a rack (15) is mounted on one side of the model disc (6), a driving tooth groove (16) is formed inside the box body (1), the rack (15) is meshed with a driving gear (17) rotatably mounted on the side wall of the driving tooth groove (16), a square hole (18) is formed in the center of the driving gear (17), the square hole (18) is matched with the square block (13) to slide, a charging magnet (19) is mounted on one side of the square hole (18) in the driving gear (17) and is electrically connected to the computer (2), the side wall of the containing groove (5) is provided with a trigger switch (20), and the trigger switch (20) is electrically connected to the computer (2).

3. The computer-based traffic planning design link simulation automatic access device according to claim 1, wherein the conveyor belt is rotatably mounted on the conveyor groove (7) through a driving roller (21) and a driven roller (22), a first bevel gear (23) is coaxially and fixedly mounted at one end of the driving roller (21) close to the reciprocating screw rod (12), a second bevel gear (24) rotatably mounted inside the box body (1) is meshed with the first bevel gear (23), and the second bevel gear (24) is connected to the reciprocating screw rod (12) through a belt.

4. The computer-based automatic access device for traffic planning design link simulation according to claim 3, wherein a screw thread is arranged at one end of the driving roller (21) close to the reciprocating screw rod (12), a driving sleeve (25) is installed on the driving roller (21) in a screw thread fit manner, a screw thread is arranged at one end of the driven roller (22) close to the reciprocating screw rod (12), a driven sleeve (26) is installed on the driven roller (22) in a screw thread fit manner, the driving sleeve (25) and the driven sleeve (26) are matched with the extrusion ring (9) to perform rotary motion, a belt groove (27) is arranged inside the box body (1), a moving groove (28) is formed in the upper wall of the belt groove (27), a fixed block (29) matched with the moving groove (28) is arranged on the extrusion ring (9), and a guide wheel (30) is installed inside the fixed block (29) in a rotating manner.

5. The computer-based traffic planning design link simulation automatic access device according to claim 4, wherein a plurality of extension springs (31) are slidably mounted on the side wall of the extrusion ring (9), the other ends of the extension springs (31) are mounted inside the box body (1), a rotating gear (32) is coaxially mounted on the side wall of the driven roller (22) which is symmetrical on one side of the driving roller (21), a first inclined surface block (33) is transversely slidably mounted on one side of the moving groove (28) far away from the conveying belt (8), a first spring (34) is fixedly mounted at one end of the first inclined surface block (33), one end of the first spring (34) is fixedly mounted inside the box body (1), the first inclined surface block (33) is connected to a first take-up pulley (35) which is rotatably mounted inside the box body (1) through a wire rope, and the first take-up pulley is connected to a first incomplete gear (37) meshed with the rotating gear (32) through a first belt (36), first torsional spring (48) is installed to first incomplete gear (37) one side, moving bath (28) are kept away from first sloping piece (33) one end slidable mounting have second sloping piece (38) and second sloping piece (38) one end fixed mounting have second spring (39), second spring (39) one end fixed mounting is inside box (1), second sloping piece (38) are connected in the inside second take-up pulley (40) of rotation installation box (1) through cotton rope, second take-up pulley (40) are connected with second incomplete gear (41) that mesh in rotating gear (32) through second belt (46), second torsional spring (47) are installed to second incomplete gear (41) one side.

6. The computer-based traffic planning design link simulation automatic access device according to claim 1, wherein the side wall of the model disc (6) far away from the side of the conveyor belt (8) is rotatably provided with a plurality of rotating wheels (42), one side of the rack (15) fixedly arranged on the model disc (6) is provided with a third spring (43), and the other end of the third spring (43) is provided with a single tooth (44) transversely sliding on the rack (15).

7. The computer-based traffic planning design link simulation automatic access device according to claim 1, characterized in that a placing tray (45) installed inside the box body (1) is arranged at one side of the conveying belt (8).