CN221676580U - Gear hub processing waste collection device - Google Patents

Abstract

The utility model belongs to the technical field of gear hub processing, in particular to a gear hub processing waste collection device, which comprises a shell; a processing main body is arranged in the middle of the shell; a feed inlet is formed in the middle of the shell; the middle part of the feed inlet is obliquely arranged; two groups of motors are arranged outside the shell; the output end of the motor is fixedly connected with a rotating plate; the rotating plate is arranged in the shell; the end part of the rotating plate is hinged with a connecting piece; the end part of the connecting piece is hinged with a separation net; the separation net is arranged on the inner wall of the shell in a sliding way; can separate coolant liquid and metal residue, reduce both and pile up the back together, troublesome phenomenon appears when the staff needs to retrieve metal residue, cooperation connecting piece simultaneously for separation net carries out the back and forth movement, thereby accelerates the stability when both are separated.

Description

Gear hub processing waste collection device

Technical Field

The utility model relates to the technical field of gear hub processing, in particular to a gear hub processing waste collection device.

Background Art

A gear hub is a mechanical component with teeth on its edge that can continuously mesh and transmit power. It is a commonly used part in mechanical equipment.

When manufacturing a gear hub, a machining tool is usually used to cut off the tooth group at the edge of the gear raw material. In order to reduce the excessive temperature of the gear hub during machining, coolant is usually used in conjunction with it.

Through long-term observation, it is found that the existing gear hub will produce more metal residues during production. Because more coolant is sprayed during processing, the coolant and the metal residues are mixed together, which makes it inconvenient to collect the waste. Therefore, a gear hub processing waste collection device is proposed to solve the above problem.

Utility Model Content

In order to make up for the deficiencies of the prior art and solve at least one technical problem raised in the background technology, the utility model provides a gear hub processing waste collection device.

The technical solution adopted by the utility model to solve its technical problems is: the gear hub processing waste collection device described in the utility model comprises a shell; a processing body is installed in the middle of the shell; a feed port is opened in the middle of the shell; the middle of the feed port is inclined; two groups of motors are installed on the outside of the shell; a rotating plate is fixedly connected to the output end of the motor; the rotating plate is arranged inside the shell; a connecting piece is hinged at the end of the rotating plate; a separation net is hinged at the end of the connecting piece; the separation net is slidably arranged on the inner wall of the shell; the coolant and the metal residue can be separated, thereby reducing the troublesome phenomenon that the staff needs to recover the metal residue after the two are piled up together.

Preferably, two groups of fixing ropes are fixed to the bottom of the separation net; a fixing piece is fixed to the bottom of the fixing rope; a magnet is fixed to the middle of the fixing piece; and the two groups of magnets are arranged to repel each other to improve the accuracy of the magnets in collecting metal residues.

Preferably, two groups of slides are slidably connected in the middle of the feed port; a pull rope is fixed to the bottom of the slide; the pull rope is arranged in a linear array in the middle of the slide; the end of the pull rope is fixed to the top of the separation net; an elastic rope is fixed to the top of the slide; the end of the elastic rope is fixed to the inner wall of the feed port; this reduces the problem of a large amount of impurities accumulating in the middle of the feed port, which makes cleaning troublesome over a long period of time.

Preferably, a Velcro is installed in the middle of the magnet; this can reduce the trouble caused by the staff cleaning the metal residue in the middle of the magnet due to the certain suction force between the metal residue and the magnet.

Preferably, a storage box is slidably connected to the middle of the shell; a handle is fixedly connected to the middle of the storage box; the storage box is arranged at the bottom of the separation net; the coolant inside the shell can be collected, reducing the trouble of taking out or collecting the coolant.

Preferably, a plurality of limit blocks are fixedly connected to the ends of the separation net; the limit blocks are slidably arranged on the inner wall of the shell; the deviation phenomenon of the separation net during movement can be reduced, and the stability of the separation net during operation can be improved.

The utility model is beneficial in that:

1. The gear hub processing waste collection device described in the utility model can separate the coolant from the metal residue by arranging a separation net in the middle of the shell, thereby reducing the troublesome phenomenon that the workers need to recover the metal residue after the two are piled up together, and at the same time, cooperate with the connecting parts to make the separation net move back and forth, thereby accelerating the stability when the two are separated.

2. The utility model describes a gear hub processing waste collection device, which has a magnet at the bottom of the separation net, to reduce the problem of waste of metal residue materials when cleaning the coolant because the coolant contains some smaller metal residues when discharging the coolant inside the shell. The repulsive force of two groups of magnets of the same color is matched to increase the collection area of the magnets, thereby improving the accuracy of the magnets in collecting metal residues.

BRIEF DESCRIPTION OF THE DRAWINGS

In order to more clearly illustrate the embodiments of the utility model or the technical solutions in the prior art, the drawings required for use in the embodiments or the description of the prior art will be briefly introduced below. Obviously, the drawings described below are only some embodiments of the utility model. For ordinary technicians in this field, other drawings can be obtained based on these drawings without paying creative labor.

FIG1 is a schematic diagram of a three-dimensional structure of the present invention;

FIG2 is a schematic diagram of a three-dimensional cross-sectional structure of the present invention;

FIG3 is a schematic diagram of the rotating plate structure in the present invention;

FIG4 is a schematic diagram of the magnet structure in the utility model;

FIG. 5 is a schematic diagram of the structure of the slide plate in the utility model.

In the figure: 1. Shell; 11. Processing body; 12. Feed port; 13. Motor; 14. Turntable; 15. Connector; 16. Separation net; 2. Fixing rope; 21. Fixing piece; 22. Magnet; 3. Slide plate; 31. Draw rope; 32. Elastic rope; 4. Velcro; 5. Storage box; 51. Handle; 6. Limit block; 7. Baffle.

DETAILED DESCRIPTION

The following will be combined with the drawings in the embodiments of the utility model to clearly and completely describe the technical solutions in the embodiments of the utility model. Obviously, the described embodiments are only part of the embodiments of the utility model, not all of the embodiments. Based on the embodiments in the utility model, all other embodiments obtained by ordinary technicians in this field without creative work are within the scope of protection of the utility model.

As shown in Fig. 1-3, a gear hub processing waste collection device comprises a shell 1; a processing body 11 is installed in the middle of the shell 1; a feed port 12 is opened in the middle of the shell 1; the middle of the feed port 12 is inclined; two sets of motors 13 are installed on the outside of the shell 1; a rotating plate 14 is fixedly connected to the output end of the motor 13; the rotating plate 14 is arranged inside the shell 1; a connecting piece 15 is hinged at the end of the rotating plate 14; a separation net 16 is hinged at the end of the connecting piece 15; the separation net 16 is slidingly arranged on the inner wall of the shell 1; when working, the staff needs to place the shell 1 on the ground, then fix the gear to be processed in the middle of the processing body 11, and turn on the shell 1 switch to process the gear, by setting a separation net in the middle of the shell 1 16, so that the metal residue produced by the gear after being processed will fall on the middle of the separation net 16, and at this time, part of the coolant will flow along the small holes in the middle of the separation net 16 to the bottom of the separation net 16 for collection. At the same time, the staff only needs to turn on the motor 13 switch to make the motor 13 drive the rotating plate 14 to rotate. Because the rotating plate 14, the connecting piece 15 and the separation net 16 are hinged, the separation net 16 will move back and forth in the middle of the shell 1 at this time, thereby separating part of the coolant in the metal residue. This step can separate the coolant from the metal residue, reducing the troublesome phenomenon when the staff needs to recover the metal residue after the two are piled up together, and at the same time, cooperate with the connecting piece 15 to make the separation net 16 move back and forth, thereby accelerating the stability of the separation of the two.

As shown in Figures 2 and 4, two groups of fixing ropes 2 are fixedly connected to the bottom of the separation net 16; a fixing part 21 is fixedly connected to the bottom of the fixing rope 2; a magnet 22 is fixedly connected to the middle of the fixing part 21; the two groups of magnets 22 are set to repel each other; when working, by setting the magnet 22 at the bottom of the separation net 16, the magnet 22 will adsorb and collect part of the metal residue in the coolant at the bottom of the separation net 16, and cooperate with the upward force of the separation net 16 and the two groups of magnets 22 to approach each other to generate a repulsive force, so that the magnet 22 repeatedly swings inside the coolant, thereby collecting part of the metal residue inside the coolant. This step can reduce the problem of wasting metal residue materials when cleaning the coolant when the coolant inside the shell 1 is discharged because the coolant contains some smaller metal residues. The repulsive force of the two groups of magnets 22 of the same color is matched, thereby increasing the collection area of the magnet 22 and improving the accuracy of the magnet 22 in collecting metal residues.

As shown in Figures 2 and 5, two groups of slide plates 3 are slidably connected in the middle of the feed port 12; a pull rope 31 is fixed to the bottom of the slide plate 3; the pull rope 31 is arranged in a linear array in the middle of the slide plate 3; the end of the pull rope 31 is fixed to the top of the separation net 16; an elastic rope 32 is fixed to the top of the slide plate 3; the end of the elastic rope 32 is fixed to the inner wall of the feed port 12; during operation, by arranging a sliding slide plate 3 in the middle of the feed port 12, the separation net 16 will pull the slide plate 3 with the help of the pull rope 31 when it moves, so that the slide plate 3 slides on the inner wall of the feed port 12, and at the same time, after the separation net 16 moves upward, it will cooperate with the force of the elastic rope 32 being stretched and reset to reset the position, and this step is repeated. This step can improve the cleanliness of the inner wall of the feed port 12 and reduce the problem of more impurities accumulated in the middle of the feed port 12, which makes it difficult to clean after a long time.

As shown in Figure 4, a Velcro 4 is installed in the middle of the magnet 22; when working, by setting the Velcro 4 in the middle of the magnet 22, the absorbed impurities will adhere to the middle of the Velcro 4, so that when the metal residue adsorbed and collected in the middle of the magnet 22 needs to be cleaned, it is only necessary to remove the Velcro 4 from the middle of the magnet 22. This step can reduce the troublesome phenomenon caused by the staff when cleaning the metal residue in the middle of the magnet 22 due to the certain suction force between the metal residue and the magnet 22.

As shown in Figures 1 and 2, a storage box 5 is slidably connected to the middle of the shell 1; a handle 51 is fixedly connected to the middle of the storage box 5; the storage box 5 is arranged at the bottom of the separation net 16; during operation, by arranging the storage box 5 in the middle of the shell 1, the coolant will enter the middle of the storage box 5. When the coolant in the storage box 5 needs to be taken out, it is only necessary to pull the storage box 5 so that the storage box 5 slides in the middle of the shell 1. This step can collect the coolant in the shell 1, reducing the problem of trouble when the coolant needs to be taken out or collected.

As shown in Figure 2, multiple groups of limit blocks 6 are fixedly connected to the end of the separation net 16; the limit blocks 6 are slidably set on the inner wall of the shell 1; when working, by setting the limit blocks 6 at the end of the separation net 16, the limit blocks 6 limit the position of the separation net 16. This step can reduce the deviation of the separation net 16 during movement and improve the stability of the separation net 16 during operation.

As shown in Figure 2, two groups of baffles 7 are fixedly connected to the end of the separation net 16; the baffle 7 is set near the motor 13; when working, the baffle 7 is set at the end of the separation net 16, so that the baffle 7 will block part of the metal residue on the top of the separation net 16. This step can reduce the phenomenon that when the metal residue on the top of the separation net 16 is collected, the separation net 16 is frequently shaken, causing the metal residue at the edge of the separation net 16 to spill into the storage box 5.

Working principle: 1 fixes the gear to be processed in the middle of the processing body 11, and turns on the shell 1 switch to process the gear. A separation net 16 is provided in the middle of the shell 1, so that the metal residue generated by the gear after processing will fall on the middle of the separation net 16. At this time, part of the coolant will flow along the small holes in the middle of the separation net 16 to the bottom of the separation net 16 for collection. At the same time, the staff only needs to turn on the motor 13 switch to make the motor 13 drive the rotating plate 14 to rotate. Because the rotating plate 14, the connecting piece 15 and the separation net 16 are hinged, the separation net 16 will move back and forth in the middle of the shell 1, thereby separating part of the coolant in the metal residue. A magnet 22 is provided at the bottom of the separation net 16, so that the magnet 22 will absorb and collect part of the metal residue in the coolant at the bottom of the separation net 16, and cooperate with the upward force of the separation net 16 and the two groups of magnets 22 to generate a repulsive force, so that the magnet 22 swings repeatedly inside the coolant, thereby Collect some of the metal residue inside the coolant, and set a sliding slide plate 3 in the middle of the feed port 12, so that the separation net 16 can pull the slide plate 3 with the help of the pull rope 31 when it moves, so that the slide plate 3 slides on the inner wall of the feed port 12, and at the same time, after the separation net 16 moves upward, it will cooperate with the elastic rope 32 to reset the position after being stretched, and repeat this process, and set Velcro 4 in the middle of the magnet 22, so that the absorbed impurities will adhere to the middle of the Velcro 4 at this time, so that when the metal residue adsorbed and collected in the middle of the magnet 22 needs to be cleaned, it only needs to remove the Velcro 4 from the middle of the magnet 22, and set a storage box 5 in the middle of the shell 1, so that the coolant will enter the middle of the storage box 5, and when the coolant in the storage box 5 needs to be taken out, it only needs to pull the storage box 5 to slide in the middle of the shell 1, and set a limiting block 6 at the end of the separation net 16, so that the limiting block 6 limits the position of the separation net 16.

The above shows and describes the basic principle, main features and advantages of the utility model. Those skilled in the art should understand that the utility model is not limited by the above embodiments, and the above embodiments and descriptions are only for explaining the principle of the utility model. Without departing from the spirit and scope of the utility model, the utility model may have various changes and improvements, and these changes and improvements fall within the scope of the utility model to be protected.

Claims (6)

1. A gear hub processing waste collection device, comprising a shell (1); a processing body (11) is installed in the middle of the shell (1); a feed port (12) is opened in the middle of the shell (1); the middle of the feed port (12) is inclined; characterized in that: two groups of motors (13) are installed outside the shell (1); a rotating plate (14) is fixedly connected to the output end of the motor (13); the rotating plate (14) is arranged inside the shell (1); a connecting piece (15) is hinged at the end of the rotating plate (14); a separation net (16) is hinged at the end of the connecting piece (15); the separation net (16) is slidably arranged on the inner wall of the shell (1). 2. A gear hub processing waste collection device according to claim 1, characterized in that: two groups of fixing ropes (2) are fixedly connected to the bottom of the separation net (16); a fixing member (21) is fixedly connected to the bottom of the fixing rope (2); a magnet (22) is fixedly connected to the middle of the fixing member (21); and the two groups of magnets (22) are arranged to repel each other. 3. A gear hub processing waste collection device according to claim 2, characterized in that: two groups of slide plates (3) are slidably connected to the middle of the feed port (12); a pull rope (31) is fixedly connected to the bottom of the slide plate (3); the pull rope (31) is arranged in a linear array in the middle of the slide plate (3); the end of the pull rope (31) is fixedly connected to the top of the separation net (16); an elastic rope (32) is fixedly connected to the top of the slide plate (3); the end of the elastic rope (32) is fixedly connected to the inner wall of the feed port (12). 4. A gear hub processing waste collection device according to claim 3, characterized in that a Velcro (4) is installed in the middle of the magnet (22). 5. A gear hub processing waste collection device according to claim 4, characterized in that: a storage box (5) is slidably connected to the middle of the shell (1); a handle (51) is fixedly connected to the middle of the storage box (5); and the storage box (5) is arranged at the bottom of the separation net (16). 6. A gear hub processing waste collection device according to claim 5, characterized in that: a plurality of groups of limit blocks (6) are fixedly connected to the end of the separation net (16); and the limit blocks (6) are slidably arranged on the inner wall of the housing (1).