CN210258952U - Bottle conveying device - Google Patents

Abstract

The utility model relates to a bottle conveyor belongs to the lane conveyor technical field of beverage bottle. The utility model comprises a multi-channel area conveyor belt and a lane changing area conveyor belt, wherein the tail end of the multi-channel area conveyor belt is connected with the front end of the lane changing area conveyor belt; the lane changing area conveyor belt is provided with a driving motor B; the multi-channel area conveyor belt is provided with a plurality of conveyor belts which are arranged side by side, and each conveyor belt is provided with a driving motor A; the front end of the lane changing area conveyor belt is provided with single-row bottle conveying branch channels corresponding to the conveyor belts of the multi-lane area conveyor belt one by one, two sides of each single-row bottle conveying branch channel are provided with a guide piece in a matching mode, the tail ends of the single-row bottle conveying branch channels are matched to form a single-row bottle conveying main channel, and the axis direction of the single-row bottle conveying main channel is the same as the conveying direction of the lane changing area conveyor belt. The utility model discloses simple structure, the whole length of conveyer belt is less, has practiced thrift the occupation of land space greatly, is particularly useful for the transport of square bottle.

Description

Bottle conveying device

Technical Field

The utility model relates to a bottle conveyor belongs to the lane conveyor technical field of beverage bottle.

Background

In the drinks packing production process, the beverage bottle of beverage bottle manufacture factory production will carry out empty bottle washing before getting into the filling, after the washing is accomplished, gets into the filling process, carries out gland sealing packing production operation to the beverage bottle after the filling, and after the gland was accomplished, carries out the optometry, rejects the nonconforming product that has quality defect, then pastes the trade mark, and dress box, vanning operation accomplish the whole production flow of product.

At present, wine bottles of a packaging production line are often conveyed in a single channel before being cleaned. The wine bottle of popular white spirit product production water line will realize that the single channel is carried and have two kinds of modes, firstly rely on artifical single channel to put the bottle, secondly the whole tray of manipulator is carried to a plurality of conveyer belts, utilizes the difference in speed between the different conveyer belts to realize that the multichannel becomes the single channel transportation. The manual single-channel bottle placing mode is slow in speed and low in efficiency, and the mode cannot meet the requirements of the times along with the rising of labor cost and the national requirement on industry 4.0; the second method usually requires a long conveyor belt, consumes more energy and has low space utilization rate, and the bottles are usually turned when the way is changed, so that the bottle labels are easily ground.

SUMMERY OF THE UTILITY MODEL

The utility model discloses the technical problem that will solve is: provides a bottle conveying device with simple structure and higher space utilization rate.

For solving the technical problem the utility model discloses the technical scheme who adopts is: the bottle conveying device comprises a multi-channel area conveying belt and a lane changing area conveying belt, wherein the tail end of the multi-channel area conveying belt is connected with the front end of the lane changing area conveying belt; the lane changing area conveyor belt is provided with a driving motor B; the multi-channel area conveyor belt is provided with a plurality of conveyor belts which are arranged side by side, and each conveyor belt is provided with a driving motor A; the front end of the lane changing area conveyor belt is provided with single-row bottle conveying branch channels corresponding to the conveyor belts of the multi-lane area conveyor belt one by one, two sides of each single-row bottle conveying branch channel are provided with a guide piece in a matching mode, the tail ends of the single-row bottle conveying branch channels are matched to form a single-row bottle conveying main channel, and the axis direction of the single-row bottle conveying main channel is the same as the conveying direction of the lane changing area conveyor belt.

Further, the method comprises the following steps: the single-row bottle conveying main channel is arranged in the middle of the width direction of the conveying belt in the lane changing area, and a single-row bottle conveying branch channel and the single-row bottle conveying main channel which are positioned in the middle are arranged along the same central axis.

Further, the method comprises the following steps: the tail end of the multi-channel area conveyor belt is provided with a lifting rod A, the lifting rod A is arranged along the width direction of the multi-channel area conveyor belt, and the lifting rod A is provided with a driving mechanism for driving the lifting rod A to vertically lift; an induction shifting fork A is arranged on one side, facing the front end of the multi-channel area conveyor belt, of the lifting rod A, a photoelectric system A matched with the induction shifting fork A is arranged on the lifting rod A, each conveyor belt of the multi-channel area conveyor belt is provided with a group of induction shifting forks A and a photoelectric system A, and the photoelectric system A is electrically connected with the control system; the driving mechanisms of the driving motor A, the driving motor B and the lifting rod A are electrically connected to the control system.

Further, the method comprises the following steps: the front end of multichannel district conveyer belt is provided with counter A, and each conveyer belt top of multichannel district conveyer belt all is provided with counter A, and counter A electric connection is in control system.

Further, the method comprises the following steps: the front end of the multi-channel area conveyor belt is provided with an upper bottle area conveyor belt, and the tail end of the upper bottle area conveyor belt is connected with the front end of the multi-channel area conveyor belt; the upper bottle area conveying belt is provided with a plurality of bottle conveying stations along the width direction, and each bottle conveying station corresponds to the conveying belts of the plurality of area conveying belts one by one; the upper bottle area conveyor belt is provided with a driving motor C.

Further, the method comprises the following steps: the tail end of the upper bottle area conveyor belt is provided with a lifting rod B, the lifting rod B is arranged along the width direction of the upper bottle area conveyor belt, and the lifting rod B is provided with a driving mechanism for driving the lifting rod B to vertically lift; an induction shifting fork B is arranged on one side of the lifting rod B, which faces the front end of the upper bottle area conveyor belt, a photoelectric system B matched with the induction shifting fork B is arranged on the lifting rod B, a group of induction shifting forks B and the photoelectric system B are arranged at each bottle conveying station of the upper bottle area conveyor belt, and the photoelectric system B is electrically connected with the control system; the driving mechanisms of the driving motor C and the lifting rod B are electrically connected to the control system.

Further, the method comprises the following steps: the front end of the upper bottle area conveyor belt is provided with a counter B, the counter B is arranged above each bottle conveying station of the upper bottle area conveyor belt, and the counter B is electrically connected to the control system.

Further, the method comprises the following steps: the guide piece is provided with a protection strip on one side facing the central line of the single-row bottle conveying branch channel, the length direction of the protection strip is parallel to the central line of the single-row bottle conveying branch channel, and the height position of the protection strip is matched with the height position of a process protection surface of a bottle to be conveyed.

Further, the method comprises the following steps: the multi-zone conveyor belt is provided with partition plates on two sides of each conveyor belt along the conveying direction; the outer surface of the partition board is provided with a protection strip, the length direction of the protection strip is parallel to the conveying direction of the multi-channel conveying belt, and the height position of the protection strip is matched with the height position of the process protection surface of the bottle to be conveyed.

Further, the method comprises the following steps: the upper bottle area conveying belt is provided with partition plates on two sides of each bottle conveying station along the conveying direction; the outer surface of the partition board is provided with a protection strip, the length direction of the protection strip is parallel to the conveying direction of the multi-channel conveying belt, and the height position of the protection strip is matched with the height position of the process protection surface of the bottle to be conveyed.

The utility model has the advantages that: in practice, the bottles are generally transported in trays, the bottles being arranged in a plurality of rows and columns, the number of bottles being m × n, and correspondingly, the multi-lane conveyor belt being designed with m or n conveyor belts. The driving motor B of the lane changing area conveyor belt is started in advance, the driving motors A of the multi-lane area conveyor belt are in a full-running state in the initial state, and a group of bottles are completely transferred to the tail end of the multi-lane area conveyor belt; then, stopping running the driving motor A, and only keeping one driving motor A to continue running; the bottles enter a single-row bottle conveying branch channel corresponding to the driving motor A, and are finally conveyed to a single-row bottle conveying main channel under the guiding action of a guide piece; when the transfer of all the bottles on the conveyor belt which is in operation in the multi-channel area is finished, the driving motor A of the conveyor belt stops operating, the next driving motor A is started, and the bottles on the next conveyor belt are continuously transferred to the single-row bottle transfer main channel; and repeating the steps until all the bottles on the multi-channel area conveyor belt are transferred. When the lane changing area conveyor belt runs, the single-row bottle conveyor belt at the downstream of the lane changing area conveyor belt normally runs to realize single-channel bottle conveying. The utility model is suitable for a beverage bottle can be realized by the multichannel transport conversion and is carried for the single track after unstacking in the packaging production, before the wash-bottle, is particularly useful for the transport of square bottle. The utility model discloses simple structure, the whole length of conveyer belt is less, has practiced thrift the occupation of land space greatly, the extensive production of drinks of being convenient for. In addition, the protection strips arranged on the outer side of the guide piece can enable the process protection surface of the wine bottle to form a space with the guide piece when the wine bottle is conveyed, and the phenomenon of decoration firing and scratching is avoided.

Drawings

Fig. 1 is a schematic plan view of the present invention;

fig. 2 is a schematic diagram of the control principle of the present invention;

FIG. 3 is a schematic view of the structure of the protective strip on the guide member of the present invention;

the labels in the figure are: 1-bottle feeding area conveyor belt, 2-multi-channel area conveyor belt, 3-lane changing area conveyor belt, 4-single-row bottle conveying branch channel, 5-single-row bottle conveying main channel, 6-guide piece, 7-driving motor A, 8-lifting rod A, 9-induction shifting fork A, 10-photoelectric system A, 11-lifting rod B, 12-induction shifting fork B, 13-photoelectric system B, 14-protection strip and 15-process protection surface.

Detailed Description

The present invention will be further explained with reference to the drawings and the embodiments.

As shown in fig. 1 and 2, the utility model comprises a multi-channel area conveyor belt 2 and a lane-changing area conveyor belt 3, wherein the tail end of the multi-channel area conveyor belt 2 is connected with the front end of the lane-changing area conveyor belt 3; the lane changing area conveyor belt 3 is provided with a driving motor B; the multi-pass zone conveyor 2 has a plurality of conveyors arranged side by side, and each conveyor is provided with a drive motor a 7; the front end of the lane changing area conveyor belt 3 is provided with single-row bottle conveying branch channels 4 corresponding to the conveyor belts of the multi-lane area conveyor belt 2 one by one, two sides of each single-row bottle conveying branch channel 4 are provided with guide pieces 6, the tail ends of the single-row bottle conveying branch channels 4 are matched to form a single-row bottle conveying main channel 5, and the axial direction of the single-row bottle conveying main channel 5 is the same as the conveying direction of the lane changing area conveyor belt 3. Wherein, the guide piece 6 can be a railing or a baffle.

In practice, the bottles are typically transported in trays, arranged in rows and columns. The number of bottles transported by one tray in this example is 15 × 12. Accordingly, the multi-lane zone conveyor 2 is designed with 12 conveyors, each provided with a drive motor a7, for a total of 12 drive motors a 7. In order to simplify the device and a control system thereof, a driving motor B of the lane changing area conveyor belt 3 is set as one, and the driving motor B is started in advance to drive the lane changing area conveyor belt 3 to integrally run. The drive motor a7 of the multi-lane conveyor 2 is initially fully operational, transferring a group of bottles all to the end of the multi-lane conveyor 2; then, the operation of the driving motor A7 is stopped, and only one driving motor A7 is kept to continue to operate; the bottles enter the single-row bottle conveying branch channel 4 corresponding to the driving motor A7, and the bottles are finally conveyed to the single-row bottle conveying main channel 5 under the guiding action of the guide piece 6; when all the bottles on the conveyor belt which is running in the multi-channel area conveyor belt 2 are transferred, the driving motor A7 of the conveyor belt stops running, the next driving motor A7 is started, and the bottles on the next conveyor belt are continuously transferred to the single-row bottle conveying main channel 5; the above steps are repeated until all the bottles of the multi-lane conveyor 2 are transferred. When the lane changing area conveyor belt 3 runs, the single-row bottle conveyor belt at the downstream of the lane changing area conveyor belt 3 normally runs to realize single-channel bottle conveying. The utility model discloses a single bottle conveying branch passageway 4 that guide 6 formed can realize the steady lane change of bottle, is particularly useful for square bottle, and square bottle here indicates that the bottle has partial cross section's outer contour line at least and is the rectangle, and this rectangle cross section structure can form bigger contact surface with guide 6 to guarantee that the lane change data send process of bottle is more reliable and more stable.

In order to ensure that the lane-changing conveying process of the bottles is more stable and reliable, the included angle between the central axis of the single-row bottle conveying branch channel 4 and the central axis of the single-row bottle conveying main channel 5 cannot be too large, and the included angle is set as a lane-changing inclined angle. Under the condition of meeting the parameter of the originally designed lane-changing inclination angle, the larger the number of the channels spaced between the single-row bottle conveying branch channel 4 and the single-row bottle conveying main channel 5 is, the longer the conveying belt length corresponding to the single-row bottle conveying branch channel 4 is. For shortening the length of lane change district conveyer belt 3, further improve space utilization, the utility model discloses a following embodiment: the single-row bottle conveying main channel 5 is arranged in the middle of the lane changing area conveying belt 3 in the width direction, and a single-row bottle conveying branch channel 4 and the single-row bottle conveying main channel 5 which are positioned in the middle are arranged along the same central axis. According to the embodiment shown in fig. 1, the multi-lane conveyor 2 is designed with 12 conveyors, the front end of the lane-changing conveyor 3 is provided with 12 single-row bottle conveying branch channels 4, the most edge of the lane-changing conveyor is marked as the 1 st single-row bottle conveying branch channel 4, and the 6 th or 7 th single-row bottle conveying branch channel 4 and the single-row bottle conveying main channel 5 are arranged along the same central axis.

In order to realize the automatic control of 2 conveying bottles of multichannel district conveyer belt, the utility model discloses a following embodiment: the tail end of the multi-channel area conveyor belt 2 is provided with a lifting rod A8, a lifting rod A8 is arranged along the width direction of the multi-channel area conveyor belt 2, and a driving mechanism for driving the lifting rod A8 to vertically lift is configured on the lifting rod A8; an induction shifting fork A9 is arranged on one side of the lifting rod A8 facing the front end of the multi-channel conveying belt 2, a photoelectric system A10 matched with the induction shifting fork A9 is arranged on the lifting rod A8, each conveying belt of the multi-channel conveying belt 2 is provided with a group of induction shifting forks A9 and a photoelectric system A10, and the photoelectric system A10 is electrically connected with a control system; the driving mechanisms of the driving motor A7, the driving motor B and the lifting rod A8 are all electrically connected with a control system.

When the multi-channel conveyor belt 2 starts to run, the lifting rod A8 is at a low working position, in order to improve conveying efficiency, the driving motor A7 of the multi-channel conveyor belt 2 is in a full running initial state, the whole bottle is pushed forwards, when the bottle is conveyed to the tail end position of the multi-channel conveyor belt 2, the bottle is in contact with the induction shifting fork A9, the induction shifting fork A9 generates an action command, the photoelectric system A10 induces and generates a signal, the signal is transmitted to the control system, the control system controls the driving motor A7 to stop running, and the conveyor belt corresponding to the induction shifting fork A9 stops running; when all the induction shifting forks A9 generate action commands, the bottles on the multi-channel conveyor belt 2 are completely conveyed to the tail end position of the multi-channel conveyor belt 2, the control system controls the lifting rod A8 to move upwards to a high working position, and the lifting rod A8 is higher than the height of the bottles so as to avoid interference on the continuous conveying of the bottles, and the next bottle lane changing and transferring process can be carried out. The control system controls the driving motor B to be started in advance, then the first driving motor A7 is started, after all bottles on the corresponding first conveyor belt are transferred, the driving motor A7 of the first conveyor belt stops running, the next driving motor A7 is started, and the bottles on the next conveyor belt are continuously transferred to the single-row bottle transfer main channel 5; the above steps are repeated until all the bottles of the multi-lane conveyor 2 are transferred. Since the number of bottles on each conveyor belt is designed in advance, the transfer time of the corresponding single conveyor belt in the process can be calculated, and the running time of each drive motor A7 and the starting sequence among the drive motors A7 can be designed into a corresponding control program in the control system in advance to realize automatic transfer. After all bottles of the multi-channel area conveyor belt 2 are transferred, the next working cycle is started, the lifting rod A8 descends to the low working position, the driving motor A7 runs completely, the sensing shifting fork A9 is restored to the original position, and the bottles are continuously loaded at the front end of the multi-channel area conveyor belt 2. The utility model provides a control system preferably adopts the PLC system, and is simple reliable. Furthermore, it should be noted that, the utility model provides a "lifter A8 sets up along the width direction of multichannel district conveyer belt 2", can be that lifter A8 sets up along the whole width direction of multichannel district conveyer belt 2, also can be that lifter A8 sets up along the width direction interval of multichannel district conveyer belt 2, and lifter A8 can set up wholly promptly, also can each conveyer belt independent setting respectively. When each conveyor belt is respectively and independently provided with a lifting rod A8, when bottles on a certain conveyor belt reach a position contacted with an induction shifting fork A9, the corresponding induction shifting fork A9 generates an action command, the conveyor belt stops running, and the lifting rod A8 corresponding to the conveyor belt can be lifted to a high-position working position firstly without waiting for all the induction shifting forks A9 to generate the action command; similarly, when all the bottles on one conveyor belt have been transferred to the main single-row bottle conveying passage 5, the lifting rod A8 corresponding to the conveyor belt can be lowered to the lower working position first, and there is no need to wait for all the bottles on all the conveyor belts to be transferred to the main single-row bottle conveying passage 5. Among the plurality of conveyors, the lifting rod A8 may preferably be integrally provided when the timing of conveying the bottles to the end position of the multi-lane conveyor 2 is not different; in the case of bottles transported to the end of the multi-lane conveyor 2 with a large difference in time, the lifting bar A8 can preferably be arranged independently; when the bottles on a certain conveyor belt reach the position contacted with the sensing shifting fork A9, namely the bottles are conveyed to the end position of the multi-channel conveyor belt 2, thereby indicating that the bottles on the certain conveyor belt enter a channel-changing preparation state and waiting for the next channel-changing conveying; the bottles on this conveyor can be given priority to the next lane change conveyor without waiting for all the bottles on the conveyor to be conveyed to the end position of the multi-lane conveyor 2. The utility model provides a lifter A8 can adopt various lift actuating mechanism among the prior art, preferably adopts cylinder elevating gear in this embodiment. The lifting rod A8 in this embodiment preferably adopts a mode that each conveyor belt is independently provided with an intercepting cylinder, and 12 intercepting cylinders are arranged in total and correspond to 12 conveyor belts of the multi-channel area conveyor belt 2 one by one.

In addition, the front end of multichannel district conveyer belt 2 is provided with counter A, and each conveyer belt top of multichannel district conveyer belt 2 all is provided with counter A, and counter A electric connection is in control system. After the counter A is arranged, on one hand, the counting of the number of the bottles conveyed by the multi-channel area conveying belt 2 is conveniently realized, and on the other hand, the automatic production is convenient. In combination with the control mode of the multi-channel conveyor belt 2, after the lifting rod A8 descends to a low working position and the driving motor A7 runs completely, the counter A starts counting before bottles are placed at the front end of the multi-channel conveyor belt 2; after the number of bottles counted by the counter A reaches the set number, the front end of the multi-channel area conveyor belt 2 stops feeding the bottles, so that the bottle conveying number in a transfer period of the multi-channel area conveyor belt 2 can be controlled, congestion at the tail end of the multi-channel area conveyor belt 2 is avoided, and the running time of the driving motor A7 in bottle lane changing transfer is designed conveniently according to the bottle conveying number. After the front end of the multi-channel conveyor belt 2 stops feeding bottles, the conveyor belt of the multi-channel conveyor belt 2 continues to run until the bottles trigger the induction shifting fork A9.

In order to improve the production efficiency, the front end of the multi-channel area conveyor belt 2 is provided with an upper bottle area conveyor belt 1, and the tail end of the upper bottle area conveyor belt 1 is connected with the front end of the multi-channel area conveyor belt 2; the upper bottle area conveyor belt 1 is provided with a plurality of bottle conveying stations along the width direction, and each bottle conveying station corresponds to the conveyor belt of the multi-channel area conveyor belt 2 one by one; the upper bottle area conveyor 1 is provided with a drive motor C. After the bottles are completely conveyed to the tail ends of the multi-channel area conveyor belts 2, in the process that the multi-channel area conveyor belts 2 transfer the bottles to the single-row bottle conveying main channel 5, the bottle feeding area conveyor belts 1 can be prepared in advance, the bottles are conveyed to the tail ends of the bottle feeding area conveyor belts 1 in advance, and continuous production is facilitated. In this embodiment, the multi-lane conveyor 2 is designed with 12 conveyors, so that the upper bottle lane conveyor 1 has 12 corresponding bottle conveying stations along its width direction.

In order to realize the automatic control of the upper bottle area conveyor belt 1, the tail end of the upper bottle area conveyor belt 1 is provided with a lifting rod B11, a lifting rod B11 is arranged along the width direction of the upper bottle area conveyor belt 1, and a driving mechanism for driving the lifting rod B11 to vertically lift is arranged on the lifting rod B11; an induction shifting fork B12 is arranged on one side of the lifting rod B11 facing the front end of the upper bottle area conveyor belt 1, a photoelectric system B13 matched with the induction shifting fork B12 is arranged on the lifting rod B11, a group of induction shifting forks B12 and a photoelectric system B13 are arranged at each bottle conveying station of the upper bottle area conveyor belt 1, and the photoelectric system B13 is electrically connected with a control system; the driving mechanisms of the driving motor C and the lifting rod B11 are electrically connected to the control system. The utility model provides a lifter A8 and lifter B11 can adopt various lift actuating mechanism among the prior art, preferably adopt cylinder elevating gear in this embodiment. The lifting rod B11 in the embodiment preferably adopts an integrated intercepting cylinder to cover all 12 bottle conveying stations, and when the upper bottle area conveying belt 1 stops running, the intercepting cylinder falls down to press the bottle mouth, so that the forward inertia of the bottle can be weakened, and the bottle is prevented from being squeezed in the front direction.

When the upper bottle area conveyor belt 1 starts to operate, the lifting rod B11 is at a low working position, when bottles are conveyed to the tail end position of the upper bottle area conveyor belt 1, the bottles are in contact with the induction shifting fork B12, the induction shifting fork B12 generates an action command, the photoelectric system B13 induces and generates a signal, the signal is transmitted to the control system, after all the induction shifting forks B12 generate the action command, the situation that the bottles on the upper bottle area conveyor belt 1 are completely conveyed to the tail end position of the upper bottle area conveyor belt 1 is indicated, the control system controls the driving motor C to stop operating, the upper bottle area conveyor belt 1 stops operating, the upper bottle area conveyor belt 1 waits for the command of the control system, and the bottles are conveyed to the front end of the multi. Before the upper bottle area conveyor belt 1 conveys the bottles to the front end of the multi-channel area conveyor belt 2, the control system needs to control the lifting rod B11 to move upwards to a high-position working position in advance, at the moment, the lifting rod B11 is higher than the height of the bottles so as to avoid interference on continuous conveying of the bottles, and at the moment, the bottles can be conveyed to the front end of the multi-channel area conveyor belt 2.

The front end of the upper bottle area conveyor belt 1 is provided with a counter B, the counter B is arranged above each bottle conveying station of the upper bottle area conveyor belt 1, and the counter B is electrically connected to the control system. After the counter B is arranged, on one hand, the counting of the number of bottles conveyed by the conveying belt 1 in the bottle feeding area is conveniently realized, and on the other hand, the automatic production is convenient. Go up bottle district conveyer belt 1 and multiple pass district conveyer belt 2 and adopt the same length design usually, combine the control mode of bottle district conveyer belt 1 and multiple pass district conveyer belt 2 in the preceding, the bottle quantity of keeping in on last bottle district conveyer belt 1 equals multiple pass district conveyer belt 2 and transports quantity at a duty cycle's bottle. After a group of bottles temporarily stored on the upper bottle area conveyor belt 1 are completely transferred to the multi-channel area conveyor belt 2, the next working period of the upper bottle area conveyor belt 1 is entered, the lifting rod B11 descends to a low working position, the driving motor C runs, at the moment, the induction shifting fork B12 is restored to the original position, and the bottles are continuously loaded at the front end of the upper bottle area conveyor belt 1. Before bottles are loaded at the front end of the conveyor belt 1 in the bottle loading area, the counter B starts to count; after the bottle quantity of counter B statistics reaches the settlement figure, then go up the bottle and distinguish the front end of conveyer belt 1 and stop the bottle, steerable bottle of distinguishing in the conveyer belt 1 transports the quantity in a cycle like this, avoids appearing blocking up at the end of going up bottle district conveyer belt 1, also is convenient for simultaneously and the work phase-match of multichannel district conveyer belt 2. After the front end of the bottle feeding area conveyor belt 1 stops feeding bottles, the bottle feeding area conveyor belt 1 continuously runs until the bottles trigger the induction shifting fork B12.

As shown in fig. 3, the guide member 6 is provided with a protective strip 14 on a side facing the centerline of the single row bottle conveying branch passage 4, the length direction of the protective strip 14 is parallel to the centerline of the single row bottle conveying branch passage 4, and the height position of the protective strip 14 is adapted to the height position of the technical protective surface 15 of the bottles to be conveyed. The craft protection surface 15 of the bottle can be generally a craft surface needing protection, such as a decoration firing pattern or a bottle label. The protective strip 14 arranged outside the guide piece 6 can ensure that the craft protective surface 15 of the wine bottle can form a spacing space with the guide piece 6 when the wine bottle is conveyed, thereby avoiding the phenomenon of decoration firing and scratching.

The technical protection surface 15 of the bottle can be arranged on one side of the outer surface of the bottle, or can be respectively arranged on two sides of the outer surface of the bottle.

For the process protection surfaces 15 arranged on both sides of the outer surface of the bottle, the following embodiments are preferred: for the same single-row bottle conveying branch channel 4, the protection strips 14 on each side are two parallel strips, wherein one protection strip 14 is positioned below the lowest point of the technical protection surface 15 of the bottle to be conveyed, and the other protection strip 14 is positioned above the highest point of the technical protection surface 15 of the bottle to be conveyed. Therefore, the technical protection surface 15 can be positioned between the two protection strips 14 to play a better protection role, and meanwhile, the bottle conveying process can be more stable and reliable by adopting the structure of the two protection strips 14.

For the process protection surface 15 provided on the side of the outer surface of the bottle, the following embodiments are preferably used: for the same single-row bottle conveying branch channel 4, one side of the single-row bottle conveying branch channel is provided with a protective strip 14, and the other side of the single-row bottle conveying branch channel is provided with two protective strips 14 which are arranged in parallel; of the two protective strips 14 on the same side, one protective strip 14 is positioned below the lowest point of the technical protective surface 15 of the bottle to be conveyed, and the other protective strip 14 is positioned above the highest point of the technical protective surface 15 of the bottle to be conveyed. In practice, the side of the bottle having the technical protection surface 15 corresponds to the side of the two protection bars 14, the technical protection surface 15 being located at a position between the two protection bars 14 to prevent the technical protection surface 15 from being frosted. The other side of the bottle then corresponds to a single protective bar 14, the bar 14 being normally positioned half way up the bottle. Due to the design of the protection structure, the process protection surface 15 can prevent the abrasion, and material reduction and bottle falling prevention are considered.

The utility model provides an go up bottle district conveyer belt 1, multichannel district conveyer belt 2 and lane change district conveyer belt 3, all preferred adoption stainless steel conveyer belt. The multi-channel area conveyor belt 2 can be additionally provided with partition plates on two sides of each conveyor belt along the conveying direction; partition plates can be additionally arranged on the two sides of each bottle conveying station of the bottle feeding area conveying belt 1 along the conveying direction; the baffle can make the bottle of two adjacent rows not influence each other in transfer process to the baffle still can prevent that the bottle from rotating or toppling over, and the baffle preferably adopts stainless steel. The spacers can be provided in the same way with reference to the arrangement of the protective strips 14 outside the guides 6, in order to prevent the technical protective surface 15 from being abraded.

Claims (10)

1. Bottle conveyor, its characterized in that: the device comprises a multi-channel area conveyor belt (2) and a lane changing area conveyor belt (3), wherein the tail end of the multi-channel area conveyor belt (2) is connected with the front end of the lane changing area conveyor belt (3); the lane changing area conveyor belt (3) is provided with a driving motor B; the multi-channel area conveyor belt (2) is provided with a plurality of conveyor belts which are arranged side by side, and each conveyor belt is provided with a driving motor A (7); the front end on lane change district conveyer belt (3) has single bottle conveying branch passageway (4) corresponding with the conveyer belt one-to-one of multichannel district conveyer belt (2), and guide (6) all have been set to the both sides of every single bottle conveying branch passageway (4), and the end cooperation of single bottle conveying branch passageway (4) forms single bottle conveying main entrance (5), and the axis direction of single bottle conveying main entrance (5) is the same with the direction of transfer of lane change district conveyer belt (3).

2. The bottle conveying apparatus according to claim 1, wherein: the single-row bottle conveying main channel (5) is arranged in the middle of the width direction of the lane changing area conveying belt (3), and a single-row bottle conveying branch channel (4) and the single-row bottle conveying main channel (5) which are positioned in the middle are arranged along the same central axis.

3. The bottle conveying apparatus according to claim 1, wherein: the tail end of the multi-channel area conveyor belt (2) is provided with a lifting rod A (8), the lifting rod A (8) is arranged along the width direction of the multi-channel area conveyor belt (2), and the lifting rod A (8) is provided with a driving mechanism for driving the lifting rod A to vertically lift; an induction shifting fork A (9) is arranged on one side, facing the front end of the multi-channel area conveyor belt (2), of the lifting rod A (8), a photoelectric system A (10) matched with the induction shifting fork A (9) is arranged on the lifting rod A (8), each conveyor belt of the multi-channel area conveyor belt (2) is provided with a group of induction shifting forks A (9) and the photoelectric system A (10), and the photoelectric system A (10) is electrically connected with a control system; the driving mechanisms of the driving motor A (7), the driving motor B and the lifting rod A (8) are electrically connected to the control system.

4. The bottle conveying apparatus according to claim 3, wherein: the front end of multichannel district conveyer belt (2) is provided with counter A, and each conveyer belt top of multichannel district conveyer belt (2) all is provided with counter A, and counter A electric connection is in control system.

5. The bottle conveying apparatus according to any one of claims 1 to 4, wherein: an upper bottle area conveyor belt (1) is arranged at the front end of the multi-channel area conveyor belt (2), and the tail end of the upper bottle area conveyor belt (1) is connected with the front end of the multi-channel area conveyor belt (2); the upper bottle area conveyor belt (1) is provided with a plurality of bottle conveying stations along the width direction, and each bottle conveying station corresponds to the conveyor belt of the multi-channel area conveyor belt (2) one by one; the upper bottle area conveyor belt (1) is provided with a driving motor C.

6. The bottle conveying apparatus as set forth in claim 5, wherein: the tail end of the upper bottle area conveyor belt (1) is provided with a lifting rod B (11), the lifting rod B (11) is arranged along the width direction of the upper bottle area conveyor belt (1), and the lifting rod B (11) is provided with a driving mechanism for driving the lifting rod B to vertically lift; an induction shifting fork B (12) is arranged on one side, facing the front end of the upper bottle area conveyor belt (1), of the lifting rod B (11), a photoelectric system B (13) matched with the induction shifting fork B (12) is arranged on the lifting rod B (11), a group of induction shifting forks B (12) and the photoelectric system B (13) are arranged on each bottle conveying station of the upper bottle area conveyor belt (1), and the photoelectric system B (13) is electrically connected with a control system; the driving mechanisms of the driving motor C and the lifting rod B (11) are electrically connected to the control system.

7. The bottle conveying apparatus according to claim 6, wherein: the front end of the upper bottle area conveyor belt (1) is provided with a counter B, the counter B is arranged above each bottle conveying station of the upper bottle area conveyor belt (1), and the counter B is electrically connected to the control system.

8. The bottle conveying apparatus according to any one of claims 1 to 4, wherein: the guide piece (6) is provided with a protective strip (14) at one side facing the central line of the single-row bottle conveying branch channel (4), the length direction of the protective strip (14) is parallel to the central line of the single-row bottle conveying branch channel (4), and the height position of the protective strip (14) is matched with the height position of a technical protective surface (15) of the bottles to be conveyed.

9. The bottle conveying apparatus according to any one of claims 1 to 4, wherein: the multi-channel area conveyor belt (2) is provided with partition plates on two sides of each conveyor belt along the conveying direction; the outer surface of the partition board is provided with a protective strip (14), the length direction of the protective strip (14) is parallel to the conveying direction of the multi-channel area conveying belt (2), and the height position of the protective strip (14) is matched with the height position of a process protective surface (15) of a bottle to be conveyed.

10. The bottle conveying apparatus as set forth in claim 5, wherein: the upper bottle area conveyor belt (1) is provided with partition plates on two sides of each bottle conveying station along the conveying direction; the outer surface of the partition board is provided with a protective strip (14), the length direction of the protective strip (14) is parallel to the conveying direction of the multi-channel area conveying belt (2), and the height position of the protective strip (14) is matched with the height position of a process protective surface (15) of a bottle to be conveyed.

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