CN220282544U - Promotion formula graphite feeding structure - Google Patents

Abstract

The utility model provides a pushing type graphite feeding structure which comprises a vibrating tray, an adapter plate positioned below a discharging pipe of the vibrating tray, a first pusher and a second pusher positioned on the adapter plate, a feeding track positioned on the left side of the adapter plate and a third pusher, wherein the other end of the feeding track is connected with a graphite guide piece, a receiving track opening on the adapter plate is communicated with an outlet of the discharging pipe of the vibrating tray, the first pusher and the first track are on the same straight line, the second pusher and the second track are on the same straight line, the feeding track is positioned under the second track, the third pusher and the feeding track are on the same straight line, and positioning notches are formed in the receiving opening track, the first track, the second track and the feeding track. The utility model provides a promotion formula graphite feeding structure can directly observe the running state of graphite in the outward appearance at first, and when whole machine was operated, the motion route of graphite was clearly visible, can change the track of different internal diameters in the face of not unidimensional graphite, and application range is wider.

Description

Promotion formula graphite feeding structure

Technical Field

The utility model belongs to the technical field of graphite embedding machines, and particularly relates to a push type graphite feeding structure.

Background

The shaft is a cylindrical object that passes through the middle of the bearing or the middle of the wheel or the middle of the gear, but is also somewhat square. A shaft is a mechanical part that supports and rotates with a rotating part to transmit motion, torque, or bending moment. Typically in the form of a metal round rod, the segments may have different diameters. The parts in the machine that are in rotary motion are mounted on the shaft.

The graphite copper sleeve bearing is a widely applied shaft sleeve product. The graphite copper sleeve bearing has the characteristic of graphite particles and mainly plays a role in lubrication. In addition, a strong lubrication effect can be formed between the shaft and the bearing in the use process, so that serious surface friction is avoided, loss is reduced, and the application rate and the service life can be improved. Graphite copper sleeve bearings have many advantages. 1. Bearing capacity is outstanding: the bearing capacity of the graphite copper sleeve bearing is very strong, and the bearing can be said to be outstanding in the application aspect of the same type of products, so that the bearing is suitable for the production requirements in the heavy industrial field. At present, the market technology is mature and the demand is large. The need for other types of products is exceeded in the heavy industry. 2. Self-contained lubrication characteristics: the graphite copper sleeve bearing has a lubricating effect, so that friction force can be prevented from being formed, and durability of the bearing is improved. It is appreciated by the buyer that this will not cause significant wear even over a long period of time. Few other materials have this functional value, and bearings made using this feature are indeed highly accepted by consumers. 3. The service life is long: the advantages of the graphite copper sleeve bearing are many, and the graphite copper sleeve bearing can still be used for a long time by utilizing the self lubrication effect even if other lubricating oil is not added. 4. The operation method is flexible: the operation method is very flexible, can be processed in the assembly process, and is not easy to make mistakes. The flexible operation is convenient for enterprises to process and produce, and the efficiency of production can be effectively improved. Because of the four advantages, the method is accepted in a plurality of industry fields, and the demand in the fields related to engineering construction and design is large. The self-lubricating graphite embedding machine has the advantages that the self-lubricating effect is incomparable with other materials, and the lubricating cost can be reduced, so that the graphite embedding machine can be used. The normal operating of inlaying graphite machine, leaving the feed mechanism, feed mechanism plays one end and receives graphite, and graphite is sent out to one end in the graphite guide, and traditional feed mechanism is inclined, and graphite flow's passageway is by last slope design down promptly, and when the passageway is because wearing and tearing and inner wall is not smooth, the flow of graphite is unobstructed, influences feed efficiency, has to change new track and satisfies the operation demand.

In view of this, we have made technical innovations on the basis of existing devices.

Disclosure of Invention

In response to one or more of the above deficiencies or improvements in the prior art, the present utility model provides a push type graphite loading structure.

In order to achieve the purpose, the utility model provides a pushing type graphite feeding structure which comprises a vibrating tray, an adapter plate positioned below a discharging pipe of the vibrating tray, a first pusher and a second pusher positioned on the adapter plate, a feeding track and a third pusher positioned on the left side of the adapter plate, wherein the other end of the feeding track is connected with a graphite guide piece.

Further, the impeller is of a structure that an air cylinder is matched with a telescopic rod, and the end heads of the telescopic rod are located in each slideway or track.

Further, the inside of the material receiving port track, the first track, the second track and the feeding track all comprise positioning notches, and graphite can be accurately fed into the graphite guide piece.

Further, the inner diameters of the material receiving port track, the first track, the second track and the feeding track can be changed according to the size of graphite, and the quick change can be realized due to the fact that the positioning pins are arranged.

In general, the above technical solutions conceived by the present utility model have the following beneficial effects compared with the prior art:

according to the pushing type graphite feeding structure, firstly, the running state of graphite can be directly observed in appearance, and when the whole machine runs, the movement path of the graphite is clearly visible, so that whether the running of the graphite has a problem or not can be visually observed, if the running has the problem, the problem can be immediately known, and the occupied area is large from the traditional inclined flow design and cannot be directly observed.

Drawings

Fig. 1 is a schematic front view of a pushing type graphite feeding structure according to an embodiment of the present utility model.

Detailed Description

The present utility model will be described in further detail with reference to the drawings and examples, in order to make the objects, technical solutions and advantages of the present utility model more apparent. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the utility model.

In addition, the technical features of the embodiments of the present utility model described below may be combined with each other as long as they do not collide with each other.

The proportioning device in the preferred embodiment of the utility model is shown in fig. 1, and the proportioning device comprises a vibrating tray discharging pipe 2, an adapter plate 3 positioned below the vibrating tray discharging pipe 2, a first pusher 4 and a second pusher 5 positioned on the adapter plate 3, a feeding rail 9 and a third pusher 10 positioned on the left side of the adapter plate 3, wherein the other end of the feeding rail 9 is connected with a graphite guide piece, a receiving rail 6, a first rail 7 and a second rail 8 are arranged on the adapter plate 3, three slide ways form a Z-shaped structure, the receiving slide way 6 is connected with an outlet of the vibrating tray discharging pipe 2 and is commonly used for discharging the discharging pipe, the first pusher 4 and the first rail 7 are positioned on a straight line, the second pusher 5 and the second rail 8 are positioned on a straight line, the feeding rail 9 is positioned under the second rail 8, the third pusher 10 and the feeding rail 9 are positioned on a straight line, graphite in the discharging pipe enters the receiving slide way 6 under the action of the first pusher 4, the second pusher 8 under the action of the second pusher 5, and the graphite enters the third pusher 10 under the action of the guiding rail.

Further, the impeller is the structure of cylinder cooperation telescopic link, and the end of telescopic link all is located each slide or track for promote graphite and remove.

Further, the receiving rail 6, the first rail 7, the second rail 8 and the feeding rail 9 all comprise positioning notches, and graphite can be accurately fed into the graphite guide. The inner diameters of the receiving rail 6, the first rail 7, the second rail 8 and the feeding rail 9 can be set according to the change of the graphite, and the inner diameters of the slideway or the rail are 6.5mm when the graphite diameter is 6mm, and the rail with the inner diameter of 8.5mm can be selected for installation when the graphite diameter is 8mm, and the connecting plate 3 and the feeding rail 9 are all connected in a detachable mode, so that the purpose is convenient to replace, further convenient to maintain and capable of being replaced by removing a certain part when damaged.

The power output part of the pusher is a hydraulic buffer, and the hydraulic buffer transmits power to the pusher through a hydraulic pipe.

It will be readily appreciated by those skilled in the art that the foregoing description is merely a preferred embodiment of the utility model and is not intended to limit the utility model, but any modifications, equivalents, improvements or alternatives falling within the spirit and principles of the utility model are intended to be included within the scope of the utility model.

Claims (4)

1. The utility model provides a promotion formula graphite material loading structure, including the vibration dish, be located the keysets of vibration dish discharging pipe below, be located the first impeller on the keysets, the second impeller, be located the left pay-off track of keysets and third impeller, the orbital other end of pay-off links to each other with the graphite guide, a serial communication port, be equipped with on the keysets and connect material track, first track, the second track, three tracks constitute Z style of calligraphy structure, connect material track mouth and vibration dish discharging pipe export to be linked together, first impeller and first track are on a straight line, the second impeller and second track are on a straight line, the pay-off track is located the second track under, the third impeller is on a straight line with the pay-off track.

2. The pushing type graphite feeding structure according to claim 1, wherein the pushing devices are of structures of air cylinders matched with telescopic rods, and the ends of the telescopic rods are located in all tracks.

3. The pushing type graphite feeding structure according to claim 1, wherein the material receiving opening rail, the first rail, the second rail and the feeding rail comprise positioning notches, and graphite can be accurately fed into the graphite guide.

4. The pushing type graphite feeding structure according to claim 1, wherein the inner diameters of the material receiving port track, the first track, the second track and the feeding track can be changed according to the size of graphite, and the positioning pins are arranged, so that quick replacement can be realized.