CN219566621U - Carbon-point conveying device with guide mechanism - Google Patents

Abstract

The utility model discloses a carbon rod conveying device with a guide mechanism, wherein a conveying groove of the carbon rod conveying device is connected with a feeding tooth through the guide mechanism, the guide mechanism comprises a guide hopper, a feed inlet of the guide hopper is positioned below an outlet of the conveying groove and is used for receiving carbon rods, a guide piece is rotatably arranged between a discharge opening of the guide hopper and the feeding tooth, a plurality of horizontally extending discharge grooves along the conveying groove are arranged on the guide piece, and the guide piece is connected with a driving piece and drives the guide piece to rotate through the driving piece so that the carbon rods at the discharge openings are loaded and conveyed by the discharge grooves and are placed in the feeding groove. According to the utility model, the guide hopper of the guide mechanism is convenient for receiving the carbon rods, the carbon rods can be loaded in the discharge groove of the guide member, and then conveyed and placed in the feed groove of the feed tooth one by one through the rotation of the guide member, so that the carbon rods can be smoothly conveyed from the centerless grinding machine to the end surface grinding machine for processing, the phenomena of carbon rod blockage and clamping are avoided, and the processing efficiency is improved.

Description

A carbon rod conveying device provided with a material guide mechanism

technical field

The utility model relates to the technical field of rod conveying, in particular to a carbon rod conveying device provided with a material guiding mechanism.

Background technique

The outer circle processing equipment of battery carbon rod is centerless grinder, and the end face processing equipment of battery carbon rod is end face grinder. At present, the discharge port of the centerless grinder is connected with the feed port of the end grinder by a non-powered chute, and then transported to the end grinder by the feeding teeth, and the carbon rod moves freely down the chute under the action of gravity. Uncontrollable, when the output is high, blockages often occur at the discharge port of the centerless grinder, the chute and the feed port of the end grinder. In the case of untimely manual intervention, overgrinding at one end will occur, so that unqualified carbon rods are mixed into the finished carbon rods, and there is no way to sort and inspect, which will lead to a large number of product scraps.

Utility model content

The technical problem to be solved by the utility model is to overcome the deficiencies of the prior art and provide a carbon rod conveying device equipped with a material guide mechanism, which can make the carbon rod convey smoothly and avoid the occurrence of carbon rod blockage and jamming.

In order to solve the above technical problems, the utility model adopts the following technical solutions:

A carbon rod conveying device provided with a material guide mechanism, comprising a conveying trough, one end of the conveying trough is connected to the discharge port of a centerless grinder, the other end of the conveying trough is connected to the feeding teeth of the end surface grinder, and the conveying The trough transports the carbon rods output from the centerless grinder and transports the carbon rods to the feeding teeth. The feeding trough is connected with the feeding teeth through a material guide mechanism. The material guide mechanism includes a guide hopper, and the feed inlet of the guide hopper is located The bottom of the outlet of the conveying trough is used to receive carbon rods. A guide member is installed between the discharge port of the guide hopper and the feeding teeth. The guide member is provided with a plurality of discharge holes extending horizontally along the conveying trough. The guide is connected with a driver and drives the guide to rotate through the driver so that each discharge trough loads and transports the carbon rod at the discharge port and places each carbon rod in the feed trough of the feed tooth.

Further, the material guide includes a rotating shaft that rotates horizontally, a plurality of the feeding troughs are evenly distributed along the circumference of the rotating shaft, and the feeding troughs extend along the horizontal direction.

Further, the rotating shaft is connected with rotating gears, and the driving member includes freely rotating transmission teeth, and the transmission teeth are engaged with the feeding teeth and the rotating teeth respectively, and rotate synchronously with the feeding teeth to drive the rotating teeth to rotate synchronously.

Further, the side end of the discharge opening away from the upper part of the feeding tooth is close to the upper part of the material guide, and the side end of the discharge opening close to the upper part of the feeding tooth is located between the upper part of the feeding tooth and the upper part of the material guide.

Further, flexible material guide plates are provided on both sides of the material guide hopper extending along the conveying direction of the conveying trough, and the two flexible material guide plates are close to each other and extend toward the discharge port.

Further, a plurality of horizontally extending strip-shaped protrusions are provided on the opposite surfaces of the two flexible material guide plates.

Further, the bottom end of the conveying trough is provided with a slot hole that passes through up and down, and at least one pusher plate that moves along the conveying direction of the conveying trough is provided in the slot hole, and the pusher plate is connected with the driving mechanism and passed through The driving mechanism drives the pushing plate to push the carbon rods in the conveying trough to move along the conveying direction of the conveying trough.

Further, the driving mechanism includes a bracket and a transmission belt, the transmission belt is rotatably mounted on the bracket, and each of the pushing plates is fixedly connected to the transmission belt.

Further, a plurality of the pushing plates are evenly distributed on the transmission belt along the conveying direction of the conveying trough, and the distance between two adjacent pushing plates is greater than the length of the carbon rod.

Further, the conveying trough is set obliquely downward to the guide hopper by a centerless grinder.

Compared with the prior art, the utility model has the advantages of:

The utility model is convenient to receive each carbon rod through the material guide hopper of the material guide mechanism, and each carbon rod can be loaded in the discharge groove of the material guide member, and then transported and placed one by one in the feed groove of the feed tooth through the rotation of the material guide member , so that each carbon rod can be smoothly transported from the centerless grinder to the end grinder for processing, avoiding the occurrence of carbon rod blockage and jamming, and thus improving the processing efficiency.

Description of drawings

Fig. 1 is a front structural schematic diagram of a carbon rod conveying device provided with a material guide mechanism.

Fig. 2 is a top structural schematic diagram of a carbon rod conveying device provided with a material guide mechanism.

Fig. 3 is a side structural schematic view of a carbon rod conveying device provided with a material guiding mechanism.

illustration:

1. Conveying trough; 11. Slot hole; 2. Centerless grinder; 21. Outlet; 3. End surface grinder; 31. Feeding tooth; 32. Feeding trough; 4. Carbon rod; 5. Guide mechanism; 51. Guide Hopper; 511, material inlet; 512, discharge port; 513, flexible material guide plate; 5131, strip protrusion; 52, material guide; 521, discharge trough; 522, rotating shaft; Driving part; 531, transmission gear; 6, pusher plate; 61, driving mechanism; 611, bracket; 612, transmission belt.

Detailed ways

Below in conjunction with accompanying drawing and specific embodiment the utility model is described in further detail.

As shown in Figures 1 to 3, the carbon rod conveying device provided with a material guide mechanism in this embodiment includes a conveying trough 1, one end of the conveying trough 1 is connected to the discharge port 21 of the centerless grinder 2, and the other end of the conveying trough 1 One end is connected with the feeding tooth 31 of the end surface grinder 3, the conveying groove 1 transports the carbon rod 4 output from the centerless grinder 2 and conveys the carbon rod 4 to the feeding tooth 31, and the conveying groove 1 is connected with the feeding tooth 31 through the material guide mechanism 5, The material guide mechanism 5 includes a material guide hopper 51, the material inlet 511 of the material guide hopper 51 is located below the outlet of the delivery tank 1 and is used to receive the carbon rod 4, and a material guide is installed between the discharge port 512 of the material guide hopper 51 and the feed tooth 31. 52, the material guide 52 is provided with a plurality of discharge troughs 521 extending horizontally along the conveying trough 1, the material guide 52 is connected with a driver 53 and drives the material guide 52 to rotate through the driver 53 to make each discharge The trough 521 loads and transports the carbon rods 4 at the discharge port 512 and places each carbon rod 4 in the feeding trough 32 of the feeding tooth 31 . The hopper 51 of the material guide mechanism 5 is convenient to receive each carbon rod 4, and each carbon rod 4 can be loaded in the discharge groove 521 of the material guide 52, and then by the rotation of the material guide 52, it is transported and placed on the feed tooth one by one. 31 in the feeding groove 32, so that each carbon rod 4 can be smoothly transported from the centerless grinder 2 to the end grinder 3 for processing, avoiding the occurrence of carbon rod blockage and jamming, and then improving the processing efficiency.

In this embodiment, the material guide 52 includes a rotating shaft 522 that rotates horizontally, a plurality of discharging troughs 521 are evenly distributed along the circumference of the rotating shaft 522 , and the feeding troughs 32 extend along the horizontal direction. A plurality of evenly distributed feeding slots 521 can be matched with the feeding slot 32 so that the carbon rod 4 can be placed in the feeding slot 32 more smoothly.

In this embodiment, the rotating shaft 522 is connected with a rotating gear 523, and the driving member 53 includes a freely rotating transmission tooth 531. The transmission tooth 531 is meshed with the feeding gear 31 and the rotating gear 523 respectively and rotates synchronously with the feeding gear 31 to drive the rotating gear 523. synchronous rotation. The transmission tooth 531 is movably connected, and can drive the transmission tooth 531 to rotate in the direction opposite to the feed tooth 31 under the rotation of the feed tooth 31, and the transmission tooth 531 meshes with the rotary tooth 523 at the same time, thereby driving the rotary tooth 523 towards the feeding The tooth 31 rotates in the same direction, and the rotating tooth 523 drives the rotating shaft 522 and the feeding chute 521 to rotate, and then the carbon rod 4 placed in the feeding chute 521 is transported towards the top of the feeding tooth 31.

In this embodiment, the side end of the discharge port 512 away from the upper part of the feeding tooth 31 is close to the upper part of the material guide 52, and the side end of the discharge port 512 close to the upper part of the feeding tooth 31 is located at the upper part of the feeding tooth 31 and the upper part of the material guide 52. between. The heights on both sides of the discharge port 512 are set so that the discharge port 512 faces the material guide 52 close to the top of the feed tooth 31, which is convenient for loading and transporting the carbon rod 4, and prevents the carbon rod 4 from moving away from the feed tooth 31 from the material guide 52. One side falls.

In this embodiment, flexible material guide plates 513 are provided on both sides of the material guide hopper 51 extending along the conveying direction of the conveying trough 1 , and the two flexible material guide plates 513 are close to each other and extend toward the discharge port 512 . The carbon rod 4 falling from the conveying tank 1 can be buffered into the hopper 51 through the flexible material guide plate 513 , which can prevent the carbon rod 4 from being damaged and reduce noise.

In this embodiment, a plurality of horizontally extending strip-shaped protrusions 5131 are provided on opposite surfaces of the two flexible material guide plates 513 . The plurality of horizontally arranged bar-shaped protrusions 5131 can further provide guidance for the carbon rod 4, so that the carbon rod 4 can be placed horizontally better.

In this embodiment, the bottom end of the conveying trough 1 is provided with a slotted hole 11 that penetrates up and down. The slotted hole 11 is provided with at least one pushing plate 6 that moves along the conveying direction of the conveying trough 1. The pushing plate 6 and the driving mechanism 61 Connect and drive the pushing plate 6 through the driving mechanism 61 to push the carbon rod 4 in the delivery tank 1 to move along the delivery direction of the delivery tank 1 . The carbon rod 4 can be pushed smoothly into the guide hopper 51 through the pusher plate 6 moving along the slot 11, which can further avoid the occurrence of carbon rod blockage and jamming.

In this embodiment, the driving mechanism 61 includes a bracket 611 and a transmission belt 612 , the transmission belt 612 is rotatably mounted on the bracket 611 , and each pushing plate 6 is fixedly connected with the transmission belt 612 . A plurality of pusher plates 6 can be installed through the transmission belt 612, and a plurality of carbon rods 4 can be pushed to move.

In this embodiment, a plurality of pushing plates 6 are evenly distributed on the transmission belt 612 along the conveying direction of the conveying trough 1 , and the distance between two adjacent pushing plates 6 is greater than the length of the carbon rod 4 . By setting the spacing between the pusher plates 6 , the carbon rods 4 can be further made to enter the hopper 51 in an orderly and spaced manner.

In this embodiment, the conveying trough 1 is set obliquely downward to the guide hopper 51 by the centerless grinder 2 . The inclined setting of the conveying trough 1 can facilitate the sliding of the carbon rods 4 , thereby reducing the wear of the carbon rods 4 and also reducing the burden on the transmission belt 612 .

The above descriptions are only preferred implementations of the present utility model, and the protection scope of the present utility model is not limited to the above-mentioned embodiments. For those skilled in the art, the improvement and transformation obtained under the premise of not departing from the technical concept of the utility model should also be regarded as the protection scope of the utility model.

Claims (10)

1. A carbon rod conveying device provided with a material guide mechanism, characterized in that it includes a conveying trough (1), one end of the conveying trough (1) is connected to the discharge port (21) of the centerless grinder (2), The other end of the conveying trough (1) is connected with the feeding tooth (31) of the end grinder (3), and the conveying trough (1) conveys the carbon rod (4) output from the centerless grinder (2) and the carbon rod ( 4) Convey to the feeding tooth (31), the conveying trough (1) is connected with the feeding tooth (31) through the material guiding mechanism (5), the material guiding mechanism (5) includes a material guiding hopper (51), the The material inlet (511) of the guide hopper (51) is located below the outlet of the conveying trough (1) and is used to receive the carbon rod (4), the discharge port (512) of the guide hopper (51) and the feed tooth (31) A material guide (52) is rotated between them, and the material guide (52) is provided with a plurality of discharge troughs (521) extending horizontally along the conveying trough (1), and the material guide (52) The drive member (53) is connected and the guide member (52) is driven to rotate by the drive member (53) so that each discharge chute (521) loads and transports the carbon rods (4) at the discharge port (512) and each The carbon rod (4) is placed in the feeding groove (32) of the feeding tooth (31). 2. The carbon rod conveying device provided with a material guide mechanism according to claim 1, characterized in that, the material guide (52) includes a horizontally rotating shaft (522), and a plurality of the discharge troughs (521 ) are uniformly distributed along the circumference of the rotating shaft (522), and the feeding trough (32) extends along the horizontal direction. 3. The carbon rod conveying device equipped with a material guide mechanism according to claim 2, characterized in that, the rotating shaft (522) is connected with a rotating tooth (523), and the driving member (53) includes a freely rotating transmission teeth (531), the transmission teeth (531) are meshed with the feeding teeth (31) and the rotating teeth (523) respectively, and rotate synchronously with the feeding teeth (31) to drive the rotating teeth (523) to rotate synchronously. 4. The carbon rod conveying device equipped with a material guide mechanism according to claim 1, characterized in that, the side end of the discharge port (512) away from the upper part of the feed tooth (31) is close to the material guide (52) The upper part of the discharge port (512) near the upper part of the feeding tooth (31) is located between the upper part of the feeding tooth (31) and the upper part of the material guide (52). 5. The carbon rod conveying device provided with a material guide mechanism according to claim 1, characterized in that, both sides of the guide hopper (51) extending along the conveying direction of the conveying trough (1) are provided with flexible material guides plate (513), the two flexible material guide plates (513) are close to each other and extend toward the discharge port (512). 6. The carbon rod conveying device provided with a material guide mechanism according to claim 5, characterized in that a plurality of horizontally extending strip-shaped protrusions ( 5131). 7. The carbon rod conveying device provided with a material guide mechanism according to any one of claims 1-6, characterized in that, the bottom end of the conveying trough (1) is provided with a slot hole (11) penetrating up and down , the slot hole (11) is provided with at least one pushing plate (6) moving along the conveying direction of the conveying trough (1), the pushing plate (6) is connected with the driving mechanism (61) and passed through the driving mechanism (61) Drive the pushing plate (6) to push the carbon rod (4) in the conveying trough (1) to move along the conveying direction of the conveying trough (1). 8. The carbon rod conveying device provided with a material guide mechanism according to claim 7, characterized in that, the driving mechanism (61) includes a bracket (611) and a transmission belt (612), and the transmission belt (612) is rotatably installed On the bracket (611), each of the pushing plates (6) is fixedly connected with the transmission belt (612). 9. The carbon rod conveying device provided with a material guide mechanism according to claim 8, characterized in that, a plurality of said pushing plates (6) are evenly distributed on the transmission belt (612) along the conveying direction of the conveying trough (1) Above, the distance between two adjacent pusher plates (6) is greater than the length of the carbon rod (4). 10. The carbon rod conveying device provided with a material guide mechanism according to claim 7, characterized in that, the conveying trough (1) is set obliquely downward to the guide hopper (51) by a centerless grinder (2).