CN211990654U - Split type iron chip cleaning mechanism - Google Patents

Abstract

The utility model discloses a to open iron fillings clearance mechanism, including X axle planker, X axle guide rail, first buffer, Y axle planker, X axle cylinder, Y axle guide rail, run-to-run mechanism first mounting panel, run-to-run mechanism second mounting panel, Y axle cylinder, run-to-run coupling mechanism, second buffer and brush, set up X axle guide rail on X axle planker both sides respectively, set up first buffer on X axle guide rail both ends respectively, set up Y axle planker on the X axle guide rail, Y axle planker one side is connected with X axle cylinder, set up Y axle guide rail on Y axle planker both sides respectively, set up run-to-run mechanism first mounting panel and run-to-run mechanism second mounting panel on the Y axle guide rail respectively, the utility model discloses simple structure, through cylinder cooperation X axle planker, X axle guide rail and Y axle planker, Y axle guide rail removal brush, carry out iron fillings clearance work, will be directional to the mould both sides removal, can not splash, and replaces air blowing and manual brushes to carry out scrap iron cleaning work.

Description

Split type iron chip cleaning mechanism

Technical Field

The utility model relates to a mould clearance technical field, concretely relates to open iron fillings clearance mechanism.

Background

Scrap iron that the mould is broken down in the stamping process can be left over on the mould, and the general condition is cleared away it from the mould through the method of blowing, perhaps manual handling with the brush, and this has influenced machining efficiency greatly, and the blowing can produce the pollution to the surrounding environment, and the oil stain splashes, and the smear metal orientation uncertainty that flies. Generally, when the molding process is completed, a mess or residue (having a certain chemical composition and physical characteristics) is often left on the mold. The final cleaning requirements are also different for different types of residues. Resins like polyvinyl chloride generate gases that corrode many types of die steel. Other residues are separated from the flame retardant and antioxidant and can cause corrosion of the steel. Still other pigment colorants cause the steel to rust and the rust is difficult to remove. Even ordinary sealing water, if left on an untreated mold surface for too long, can also cause damage to the mold.

Therefore, the mold should be cleaned as necessary according to a given production cycle. Each time the die is removed from the press, the die porosity must first be opened to remove all oxide dirt and rust from the non-critical areas of the die and die plate to prevent it from slowly corroding the steel surfaces and edges. In many cases, even after cleaning, some uncoated or rust-prone mold surfaces quickly develop rust again. Therefore, even if it takes a long time to brush the unprotected mold, surface rusting cannot be completely avoided. In general, when the surface of a mold is cleaned by high-pressure pulverization using hard plastic, glass beads, walnut shells, aluminum granules, etc. as an abrasive, if the abrasive is used too frequently or improperly, the abrasive may cause voids on the surface of the mold, so that residues are liable to adhere to the surface of the mold, resulting in more residues and abrasion, or causing phenomena such as premature breakage or burrs of the mold, which is rather disadvantageous for cleaning the mold.

SUMMERY OF THE UTILITY MODEL

The utility model aims to overcome the defects of the prior art and provide a split scrap iron cleaning mechanism, which comprises an X-axis carriage, an X-axis guide rail, a first buffer, a Y-axis carriage, an X-axis cylinder, a Y-axis guide rail, a split mechanism first mounting plate, a split mechanism second mounting plate, a Y-axis cylinder, a split connecting mechanism, a second buffer and a brush, wherein the X-axis guide rail is respectively arranged on two sides of the X-axis carriage, the first buffer is respectively arranged on two ends of the X-axis guide rail, the Y-axis carriage is arranged on the X-axis guide rail, one side of the Y-axis carriage is connected with the X-axis cylinder, the Y-axis guide rail is respectively arranged on two sides of the Y-axis carriage, the split mechanism first mounting plate and the split mechanism second mounting plate are respectively arranged on the Y-axis guide rail, and are mutually connected through the split connecting mechanism, the Y-axis cylinder is arranged on one side of the Y-axis carriage and is connected with the split mechanism second mounting plate, and two ends of the Y-axis carriage are respectively provided with a second buffer, and brushes are respectively arranged below the first mounting plate of the split mechanism and the second mounting plate of the split mechanism.

Preferably, the split connecting mechanism comprises a main connecting plate, a first auxiliary connecting plate, a second auxiliary connecting plate and a central rotating shaft, the central rotating shaft is arranged at the center of the main connecting plate and connected with the Y-axis carriage, two ends of the main connecting plate are respectively connected with the first auxiliary connecting plate and the second auxiliary connecting plate through pin shafts, the first auxiliary connecting plate is connected with the first mounting plate of the split mechanism, and the second auxiliary connecting plate is connected with the second mounting plate of the split mechanism.

Preferably, the X-axis carriage and the Y-axis carriage are both provided with chip grooves, an open slot is formed in one end of the X-axis carriage, which is far away from the Y-axis cylinder, and a template is arranged in the open slot.

Preferably, the first buffer and the second buffer are both fixed on the X-axis carriage and the Y-axis carriage through buffer fixing frames.

Preferably, the Y-axis cylinder is fixed on the Y-axis carriage, a piston rod of the Y-axis cylinder is connected with the second mounting plate of the split mechanism, the X-axis cylinder is fixed on the Y-axis carriage, and a piston rod of the X-axis cylinder is fixedly connected with the baffle at the tail end of the X-axis guide rail.

The utility model has the advantages that: simple structure, high durability and convenient operation, through cylinder cooperation X axle planker, X axle guide rail and Y axle planker, Y axle guide rail removes the brush, carry out iron fillings cleaning work, iron fillings will be directional to the mould both sides removal, can not splash, replace blowing and artifical brush to carry out iron fillings cleaning work, greatly improve work efficiency, avoid polluting the surrounding environment, the oil stain splashes, the smear metal orientation uncertainty of flying, clean mechanism clears up the mould behind the punching press at every turn, can save the clearance time, can reduce the wearing and tearing of mould effectively simultaneously.

Drawings

The invention will now be described, by way of example, with reference to the accompanying drawings, in which:

fig. 1 is a schematic perspective view of the present invention;

fig. 2 is a schematic top view of the present invention;

fig. 3 is a schematic top view of the first mounting plate and the second mounting plate of the half-open mechanism of the present invention when they are opened.

In the figure: 1. an X-axis carriage; 2. an X-axis guide rail; 3. a first buffer; 4. a Y-axis carriage; 5. an X-axis cylinder; 6. a Y-axis guide rail; 7. a first mounting plate of the split mechanism; 8. a second mounting plate of the split mechanism; 9. a Y-axis cylinder; 10. a split connection mechanism; 11. a second buffer; 12. a brush; 13. an open slot; 14. a template; 15. a chip groove; 16. a main connection plate; 17. a first auxiliary connecting plate; 18. a second auxiliary connecting plate; 19. a central rotating shaft.

Detailed Description

Any feature disclosed in this specification may be replaced by alternative features serving equivalent or similar purposes, unless expressly stated otherwise. That is, unless expressly stated otherwise, each feature is only an example of a generic series of equivalent or similar features.

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

In the description of the present invention, it should be noted that the terms "upper", "lower", "inner", "outer", "front end", "rear end", "both ends", "one end", "the other end", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and simplification of description, but do not indicate or imply that the device or element to be referred must have a specific orientation, be constructed in a specific orientation, and be operated, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first" and "second" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present invention, it is to be noted that, unless otherwise explicitly specified or limited, the terms "mounted", "provided", "connected", and the like are to be construed broadly, such as "connected", which may be a fixed connection including welding, riveting, bonding, and the like; or the detachable connection comprises a threaded connection, a key connection, a pin connection and the like; or integrally connected; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meaning of the above terms in the present invention can be understood in specific cases to those skilled in the art.

The split scrap iron cleaning mechanism shown in fig. 1-3 comprises an X-axis carriage 1, an X-axis guide rail 2, a first buffer 3, a Y-axis carriage 4, an X-axis cylinder 5, a Y-axis guide rail 6, a split mechanism first mounting plate 7, a split mechanism second mounting plate 8, a Y-axis cylinder 9, a split connecting mechanism 10, a second buffer 11 and a brush 12, wherein the X-axis guide rail 2 is respectively arranged on two sides of the X-axis carriage 1, the first buffer 3 is respectively arranged on two ends of the X-axis guide rail 2, the Y-axis carriage 4 is arranged on the X-axis guide rail 2, one side of the Y-axis carriage 4 is connected with the X-axis cylinder 5, the Y-axis guide rail 6 is respectively arranged on two sides of the Y-axis carriage 4, a split mechanism first mounting plate 7 and a split mechanism second mounting plate 8 are respectively arranged on the Y-axis guide rail 6, and the split mechanism first mounting plate 7 and the split mechanism second mounting plate 8 are connected with each other through the split connecting mechanism 10, a Y-axis cylinder 9 is arranged on one side of the Y-axis carriage 4 and connected with a second mounting plate 8 of the split mechanism, second buffers 11 are respectively arranged at two ends of the Y-axis carriage 4, and brushes 12 are respectively arranged below the first mounting plate 7 of the split mechanism and the second mounting plate 8 of the split mechanism. The split connecting mechanism 10 comprises a main connecting plate 16, a first auxiliary connecting plate 17, a second auxiliary connecting plate 18 and a central rotating shaft 19, the central rotating shaft 19 is arranged at the center of the main connecting plate 16 and connected with the Y-axis carriage 4, two ends of the main connecting plate 16 are respectively connected with the first auxiliary connecting plate 17 and the second auxiliary connecting plate 18 through pin shafts, the first auxiliary connecting plate 17 is connected with the first mounting plate 7 of the split mechanism, and the second auxiliary connecting plate 18 is connected with the second mounting plate 8 of the split mechanism. The X-axis carriage 1 and the Y-axis carriage 4 are both provided with chip grooves 15, an open slot 13 is formed in one end, far away from the Y-axis cylinder 9, of the X-axis carriage 1, and a template 14 is arranged in the open slot 13. The first buffer 3 and the second buffer 11 are fixed on the X-axis carriage 1 and the Y-axis carriage 4 through buffer fixing frames. The Y-axis cylinder 9 is fixed on the Y-axis carriage 4, a piston rod of the Y-axis cylinder 9 is connected with the second mounting plate 8 of the split mechanism, the X-axis cylinder 5 is fixed on the Y-axis carriage 4, and a piston rod of the X-axis cylinder 5 is fixedly connected with a baffle at the tail end of the X-axis guide rail 2. The arrangement of the scrap discharge groove 15 prevents scrap iron from staying on the X-axis carriage 1 and the Y-axis carriage 4, so that the Y-axis carriage 4 cannot smoothly slide on the X-axis carriage 1; the first mounting plate 7 of the split mechanism and the second mounting plate 8 of the split mechanism cannot smoothly slide on the Y-axis carriage 4, so that scrap iron can be conveniently cleaned. The main connecting plate 16 can rotate by taking the central rotating shaft 19 as a rotating center, the first auxiliary connecting plate 17 and the second auxiliary connecting plate 18 are movably connected with the main connecting plate 16, and the first auxiliary connecting plate 17, the first mounting plate 7 of the split mechanism, the second auxiliary connecting plate 18 and the second mounting plate 8 of the split mechanism are also movably connected. The first buffer 3 and the second buffer 11 are both hydraulic buffers and are of the type AC 1416-2C.

The working principle of the specific embodiment is as follows: firstly, a template 14 is placed in an open slot 13, then an X-axis cylinder 5 works to enable a Y-axis carriage 4 to make linear reciprocating motion on an X-axis guide rail 2 of the X-axis carriage 1, so that the working position of the Y-axis carriage 4 is adjusted, meanwhile, a Y-axis cylinder 9 works to enable a main connecting plate 16 to rotate by taking a central rotating shaft 19 as a rotating center, and a first auxiliary connecting plate 17 and a second auxiliary connecting plate 18 are matched to drive a first mounting plate 7 of a folio mechanism and a second mounting plate 8 of the folio mechanism to make linear reciprocating motion on a Y-axis guide rail 6 of the Y-axis carriage 4, so that a brush 12 moves along with the main connecting plate, scrap iron cleaning work is carried out, the brush 12 is reset after being cleaned once every stamping, and the operation is repeated in a circulating.

The present invention is not limited to the foregoing embodiments. The invention extends to any novel feature or any novel combination of features disclosed in this specification, and to any novel method or process steps or any novel combination of features disclosed.

Claims (5)

1. The utility model provides a to open iron fillings clearance mechanism, includes X axle planker (1), X axle guide rail (2), first buffer (3), Y axle planker (4), X axle cylinder (5), Y axle guide rail (6), to opening mechanism first mounting panel (7), to opening mechanism second mounting panel (8), Y axle cylinder (9), to opening coupling mechanism (10), second buffer (11) and brush (12), its characterized in that: the novel split type hair brush is characterized in that X-axis guide rails (2) are arranged on two sides of an X-axis carriage (1) respectively, first buffers (3) are arranged at two ends of the X-axis guide rails (2) respectively, Y-axis carriages (4) are arranged on the X-axis guide rails (2), one sides of the Y-axis carriages (4) are connected with an X-axis cylinder (5), Y-axis guide rails (6) are arranged on two sides of the Y-axis carriages (4) respectively, split mechanism first mounting plates (7) and split mechanism second mounting plates (8) are arranged on the Y-axis guide rails (6) respectively and are connected with each other through split connecting mechanisms (10), Y-axis cylinders (9) are arranged on one sides of the Y-axis carriages (4) and are connected with the split mechanism second mounting plates (8), second buffers (11) are arranged at two ends of the Y-axis carriages (4) respectively, and hairbrushes (7) and the split mechanism second mounting plates (8) are arranged below the split mechanism first mounting plates (7) and the split mechanism second mounting plates (8) respectively 12).

2. The split iron scrap cleaning mechanism according to claim 1, wherein: the split connecting mechanism (10) comprises a main connecting plate (16), a first auxiliary connecting plate (17), a second auxiliary connecting plate (18) and a central rotating shaft (19), the central rotating shaft (19) is arranged at the center of the main connecting plate (16) and connected with a Y-axis carriage (4), two ends of the main connecting plate (16) are connected with the first auxiliary connecting plate (17) and the second auxiliary connecting plate (18) through pin shafts respectively, the first auxiliary connecting plate (17) is connected with a first mounting plate (7) of the split mechanism, and the second auxiliary connecting plate (18) is connected with a second mounting plate (8) of the split mechanism.

3. The split iron scrap cleaning mechanism according to claim 1, wherein: the X-axis carriage (1) and the Y-axis carriage (4) are both provided with chip removal grooves (15), an open slot (13) is formed in one end, far away from the Y-axis cylinder (9), of the X-axis carriage (1), and a template (14) is arranged in the open slot (13).

4. The split iron scrap cleaning mechanism according to claim 1, wherein: the first buffer (3) and the second buffer (11) are fixed on the X-axis carriage (1) and the Y-axis carriage (4) through buffer fixing frames.

5. The split iron scrap cleaning mechanism according to claim 1, wherein: the Y-axis cylinder (9) is fixed on the Y-axis carriage (4), a piston rod of the Y-axis cylinder (9) is connected with the second mounting plate (8) of the split mechanism, the X-axis cylinder (5) is fixed on the Y-axis carriage (4), and a piston rod of the X-axis cylinder (5) is fixedly connected with a tail end baffle of the X-axis guide rail (2).

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