CN221020058U - Waste collection structure for filter element cutting machine - Google Patents

Abstract

The utility model relates to the technical field of filter element cutting machines, in particular to a waste collection structure for a filter element cutting machine. The technical scheme includes that the filter core comprises a machine body and a cutting cavity arranged in the machine body, wherein a bearing frame for bearing and placing a filter core is arranged on the inner wall of the bottom of the cutting cavity; the cutting cavity comprises a guide slope arranged on one side of the bearing frame, and a collection box for containing filter element waste is arranged at the bottom end of the slope surface of the guide slope; a lifting cavity is formed in the machine body, and a cutting mechanism for cutting the core body of the filter element is arranged in the lifting cavity; the bearing frame is provided with a rotating groove, and an auxiliary discharging mechanism for overturning and discharging the core body of the filter element is rotatably arranged in the rotating groove. The utility model has novel and compact structure, has the structure of separating and automatically collecting the qualified filter element and the waste filter element, has high machining automation degree of the cutting machine and is safer in cutting machining.

Description

Waste collection structure for filter element cutting machine

Technical Field

The utility model relates to the technical field of filter element cutting machines, in particular to a waste collection structure for a filter element cutting machine.

Background

The special iron core cutting machine is needed to be applied to iron core production and processing, is mainly used for cutting the two end faces of the filter core to be flush, provides guarantee for the sealing performance of the next hot-melt welding, and is one of filter core production lines. The cutting rotation speed of the existing filter element cutting machine is adjustable, filter elements with various specifications can be cut, the operation is controlled by a servo programming system, the traditional complicated manual filter element fixing mode is omitted, the filter elements are automatically clamped, the blades are used for 360-degree double-rotation cutting, and the filter element core body is cut very efficiently. Because the purpose of filter core cutting machine is with the unnecessary partial cutting of core, consequently can produce the waste material after the cutting, current cutting machine does not possess the automatic structure of collecting to the waste material is concentrated, artifical waste material and qualified filter core's letter sorting of taking part in when the cutting, and manual sorting not only needs to throw into more labours but also can have certain security risk, so the performance of filter core cutting machine remains to improve. In view of this, we propose a cartridge cutter with a structure that automatically separates scrap from acceptable cores for transport and collection.

Disclosure of utility model

The utility model aims at solving the problems that the existing cutting machine in the background technology does not have a structure for automatically collecting waste in a centralized manner, waste and a qualified filter element are manually involved in sorting during cutting, more labor is required to be input for manual sorting, and a certain safety risk exists, and provides the filter element cutting machine with the structure for automatically conveying and collecting the waste and the qualified filter element separately.

The technical scheme of the utility model is as follows: the waste collection structure for the filter element cutting machine comprises a machine body and a cutting cavity arranged in the machine body, wherein a bearing frame for bearing and placing the filter element core is arranged on the inner wall of the bottom of the cutting cavity;

The cutting cavity comprises a guide slope arranged on one side of the bearing frame, and a collection box for containing filter element waste is arranged at the bottom end of the slope surface of the guide slope;

A lifting cavity is formed in the machine body, and a cutting mechanism for cutting the core body of the filter element is arranged in the lifting cavity;

The bearing frame is provided with a rotating groove, and an auxiliary discharging mechanism for overturning and discharging the core body of the filter element is rotatably arranged in the rotating groove;

a through hole is formed between the cutting cavity and the lifting cavity, a servo motor is connected to the inner wall of the through hole, a gear is connected to the output end of the servo motor, a rack meshed with the gear is arranged on one side of the gear, and a connecting block arranged in the rotating groove in a rotating mode is arranged at the top of the rack.

Optionally, a substrate for bearing the collection box is fixedly connected to one side of the machine body, and the substrate is used for collecting the cut waste in a centralized manner.

Optionally, one side of cutting cavity is provided with the absorbing dust absorption mechanism of iron fillings when cutting mechanism cuts, dust absorption mechanism is including seting up the air intake at the organism lateral wall, and one side of air intake is connected with the tuber pipe, install dust absorption fan on the tuber pipe, dust absorption mechanism's setting is arranged in the unified discharge of impurity absorption such as the iron powder that produces in cutting processing, reduces the rubbish and remains in the cutting cavity.

Optionally, the discharge gate that is located the organism back is offered to one side of cutting cavity, one side of discharge gate is located the organism and still corresponds and be provided with the slope, and the convenience on slope is discharged from the discharge gate with the filter core direction after the qualified cutting.

Optionally, install the cylinder two in the organism opposite of discharge gate, the output of cylinder two is connected with the push pedal, still install the movable plate that is used for cutting length to the filter core in the cutting cavity, one side of movable plate is connected with cylinder one, cylinder one with one side inner wall connection of cutting cavity, cylinder one will move the movable plate and promote the cutting length that can shorten the filter core to the one side that is close to cutting mechanism for adjust filter core cutting length.

Optionally, the guide way has been seted up to the bottom of connecting block, the top rotation of rack is connected with articulated piece, articulated piece is located the inner wall slip setting of guide way, and the guide way is used for the removal direction of the while position of the jacking of spacing direction connecting block.

Optionally, a fixing frame is installed on the servo motor and used for assembling and connecting the servo motor with the inner wall of the through hole, and the fixing frame fixes the position of the servo motor at the through hole.

Optionally, the lift mouth has been seted up to one side of through-hole, cutting mechanism is including installing the cylinder III at lift chamber bottom inner wall, the output connection support frame of cylinder III, the support frame internal fixation is provided with driving motor, driving motor's output is connected with the cutting knife to filter core cutting, and cutting mechanism's setting is used for cutting the filter core.

Compared with the prior art, the utility model has the following beneficial technical effects:

1. According to the utility model, the filter element core body to be cut is placed through the arrangement of the bearing frame, the filter element core body is cut through the arrangement of the cutting knife, the filter element core body is pushed by the cylinder at the back of the moving plate, the interference of the filter element core body and the moving plate is enabled to determine the cutting length, the qualified filter element core body can be pushed out through the discharge hole through the arrangement of the push plate after cutting, and the qualified filter element core body is collected in a concentrated manner; the rack is jacked up through rotation of the gear, so that the connecting block rotates along a rotating groove on the bearing frame, filter element cutting waste reserved on the bearing frame and the connecting block is guided and conveyed by combining a guide slope, the waste is collected in the collecting box in a concentrated mode, and the purpose that qualified cores and waste are collected separately is achieved;

2. According to the utility model, the dust collection mechanism is arranged to collect and convey cutting impurities or iron powder when the filter element core body is combined with the cutting knife to cut, so that the environmental sanitation condition of a processing field is improved;

3. In summary, the utility model has novel and compact structure, has the structure of separating and automatically collecting the qualified filter element and the waste filter element, has high degree of automation of cutting machine processing and safer cutting processing.

Drawings

FIG. 1 presents a schematic view of the utility model in front elevation;

FIG. 2 is a schematic side view of FIG. 1;

FIG. 3 is a schematic view of a part of the cross-sectional structure of the body of FIG. 1;

fig. 4 is an exploded view of the rack and the connection block.

Reference numerals:

1. A body; 11. a substrate;

2. A collection box;

3. A dust collection mechanism; 31. an air duct; 32. a dust collection fan;

4. Cutting the cavity; 41. a second cylinder; 42. a push plate; 43. a moving plate; 44. a discharge port; 45. a material guiding slope;

5. A carrier;

6. A lifting cavity;

7. A cutting mechanism; 71. a third cylinder; 72. a driving motor; 73. a cutting knife;

8. An auxiliary blanking mechanism; 81. a gear; 82. a gear; 83. a rack; 84. a hinge block; 85. connecting block, 851, guiding groove.

Detailed Description

The technical scheme of the utility model is further described below with reference to the attached drawings and specific embodiments.

Example 1

As shown in fig. 1-4, the waste collection structure for the filter element cutting machine provided by the utility model comprises a machine body 1 and a cutting cavity 4 arranged in the machine body 1, wherein a bearing frame 5 for bearing and placing the filter element core is arranged on the inner wall of the bottom of the cutting cavity 4, and the upper surface of the bearing frame 5 is arc-shaped; still install in cutting cavity 4 and be used for the holding down plate that corresponds with carrier 5 for will wait to cut the filter core and compress tightly the cutting on carrier 5, not drawing the illustration in this scheme, further also can adopt the mode of manual pressing to stabilize and wait to cut the filter core.

A discharge hole 44 positioned on the back of the machine body 1 is formed in one side of the cutting cavity 4, and a slope is correspondingly arranged on one side of the discharge hole 44 positioned in the machine body 1; the starting end of the slope is connected with one side of the bearing frame 5, and the ending end is aligned with the bottom frame of the discharge hole 44; the opposite face of the discharge hole 44 is positioned in the machine body 1, a second cylinder 41 is arranged in the machine body 1, the output end of the second cylinder 41 is connected with a push plate 42, the output end of the second cylinder 41 pushes the push plate 42, so that qualified filter elements on the bearing frame 5 and the connecting block 85 are discharged from the discharge hole 44 in combination with slopes, a collecting frame can be placed on one side of the discharge hole 44 or a conveying belt is arranged, and the actual requirements of a factory are specifically combined. The movable plate 43 for cutting the length of the core body of the filter element is further arranged in the cutting cavity 4, one side of the movable plate 43 is connected with the first air cylinder, the first air cylinder is connected with the inner wall of one side of the cutting cavity 4, the output end of the first air cylinder pushes the movable plate 43 to push one side close to the cutting mechanism 7, and therefore the filter element is abutted against the movable plate 43 before cutting, and the movable plate 43 pushes one side close to the cutting mechanism 7, so that the cutting length of the filter element can be adjusted to be short in combination with the fixed cutting position of the cutting mechanism 7, and cutting requirements of different sizes are met.

The cutting cavity 4 comprises a guide slope 45 arranged on one side of the bearing frame 5, and a collection box 2 for containing filter element waste is arranged at the bottom end of the slope surface of the guide slope 45; a base plate 11 for bearing the collection box 2 is fixedly connected to one side of the machine body 1;

A lifting cavity 6 is formed in the machine body 1, and a cutting mechanism 7 for cutting the core body of the filter element is arranged in the lifting cavity 6; the lifting opening is formed in one side of the through opening, the cutting mechanism 7 comprises a third cylinder 71 arranged on the inner wall of the bottom of the lifting cavity 6, the output end of the third cylinder 71 is connected with a supporting frame, a driving motor 72 is fixedly arranged in the supporting frame, the output end of the driving motor 72 is connected with a cutting knife 73 for cutting the core body of the filter element, and the cutting knife 73 continuously pushes the filter element to be cut upwards to be cut through the pushing of the third cylinder 71.

The bearing frame 5 is provided with a rotating groove, and an auxiliary discharging mechanism 8 for overturning and discharging the core body of the filter element is rotatably arranged in the rotating groove;

A through hole is formed between the cutting cavity 4 and the lifting cavity 6, the inner wall of the through hole is connected with a servo motor 81, a fixing frame is arranged on the servo motor 81, and the fixing frame is used for assembling and connecting the servo motor 81 with the inner wall of the through hole; the output end of the servo motor 81 is connected with a gear 82, one side of the gear 82 is provided with a rack 83 meshed with the gear 82, a guide groove is further formed in the through hole, and one side of the rack 83 is connected with a guide block for stably pushing upwards along the guide groove. The top of rack 83 is provided with the connecting block 85 that is located the rotation in groove rotation installation, and guide slot 851 has been seted up to the bottom of connecting block 85, and the top of rack 83 rotates and is connected with articulated piece 84, and articulated piece 84 is located the inner wall slip setting of guide slot 851.

In this embodiment, the cutting knife 73 is operated in a continuous upward rotation cutting gesture by pushing of the third cylinder 71 and starting of the driving motor 72, the purpose of cutting is completed by combining the placed filter element, the push plate 42 is pushed by starting of the second cylinder 41 to realize that qualified filter elements after cutting are discharged from the discharge hole 44 and collected intensively, the cut waste materials are rotated by starting of the servo motor 81, the gear 82 drives the gear 83 to enable the gear 83 to lift up, and as one end of the connecting block 85 is rotationally connected with the bearing frame 5, the hinging block 84 moves along the inner wall of the guiding groove 851 while the top of the gear 83 is pushed up, so that the effect of rotating the connecting block 85 along the connecting end of the bearing frame 5 is realized, and waste materials left on the bearing frame 5 and the connecting block 85 are guided and conveyed into the collecting box 2 through the guiding slope 45 to be collected intensively.

Example two

As shown in fig. 1-4, based on the first embodiment, a dust collection mechanism 3 for absorbing scrap iron during cutting of the cutting mechanism 7 is arranged on one side of the cutting cavity 4, the dust collection mechanism 3 comprises an air inlet formed in the side wall of the machine body 1, the air inlet corresponds to the position of the cutting blade 73, an air pipe 31 is connected to one side of the air inlet, and a dust collection fan 32 is mounted on the air pipe 31.

In this embodiment, powder or impurities generated when the cutting knife 73 cuts the filter element are conveyed into the air pipe 31 through the air inlet to be collected in a concentrated manner through the arrangement of the dust collection fan 32, and a dust collection box and the like can be installed at the tail end of the air pipe 31 to collect the impurities.

The above-described embodiments are merely a few alternative embodiments of the present utility model, and many alternative modifications and combinations of the above-described embodiments will be apparent to those skilled in the art based on the technical solutions of the present utility model and the related teachings of the above-described embodiments.

Claims (8)

1. Waste collection structure for filter core cutting machine, its characterized in that includes:

The filter element comprises a machine body (1) and a cutting cavity (4) arranged in the machine body (1), wherein a bearing frame (5) for bearing and placing the filter element core is arranged on the inner wall of the bottom of the cutting cavity (4);

The cutting cavity (4) comprises a guide slope (45) arranged on one side of the bearing frame (5), and a collection box (2) for containing filter element waste is arranged at the bottom end of the slope of the guide slope (45);

A lifting cavity (6) is formed in the machine body (1), and a cutting mechanism (7) for cutting the core body of the filter element is arranged in the lifting cavity (6);

a rotary groove is formed in the bearing frame (5), and an auxiliary discharging mechanism (8) for overturning and discharging the filter core body is rotatably arranged in the rotary groove;

A through hole is formed between the cutting cavity (4) and the lifting cavity (6), a servo motor (81) is connected to the inner wall of the through hole, a gear (82) is connected to the output end of the servo motor (81), a rack (83) meshed with the gear (82) is arranged on one side of the gear (82), and a connecting block (85) arranged in the rotating groove in a rotating mode is arranged at the top of the rack (83).

2. The waste collection structure for a filter element cutting machine according to claim 1, wherein a base plate (11) for bearing the collection box (2) is fixedly connected to one side of the machine body (1).

3. The waste collection structure for the filter element cutting machine according to claim 1, wherein a dust collection mechanism (3) for absorbing scrap iron during cutting of the cutting mechanism (7) is arranged on one side of the cutting cavity (4), the dust collection mechanism (3) comprises an air inlet formed in the side wall of the machine body (1), an air pipe (31) is connected to one side of the air inlet, and a dust collection fan (32) is arranged on the air pipe (31).

4. The waste collection structure for a filter element cutting machine according to claim 1, wherein a discharge port (44) positioned on the back surface of the machine body (1) is formed in one side of the cutting cavity (4), and a slope is correspondingly arranged in one side of the discharge port (44) positioned in the machine body (1).

5. The waste collection structure for a filter element cutting machine according to claim 4, wherein a second cylinder (41) is installed in the machine body (1) opposite to the discharge hole (44), an output end of the second cylinder (41) is connected with a push plate (42), a moving plate (43) for cutting the filter element core is further installed in the cutting cavity (4), one side of the moving plate (43) is connected with a first cylinder, and the first cylinder is connected with an inner wall of one side of the cutting cavity (4).

6. The waste collection structure for a filter element cutting machine according to claim 1, wherein a guide groove (851) is formed in the bottom of the connecting block (85), a hinge block (84) is rotatably connected to the top of the rack (83), and the hinge block (84) is slidably arranged on the inner wall of the guide groove (851).

7. The waste collection structure for a filter element cutting machine according to claim 1, wherein a fixing frame is mounted on the servo motor (81), and the fixing frame is used for assembling and connecting the servo motor (81) with the inner wall of the through hole.

8. The waste collection structure for the filter element cutting machine according to claim 1, wherein a lifting opening is formed in one side of the through opening, the cutting mechanism (7) comprises a third cylinder (71) mounted on the inner wall of the bottom of the lifting cavity (6), the output end of the third cylinder (71) is connected with a supporting frame, a driving motor (72) is fixedly arranged in the supporting frame, and the output end of the driving motor (72) is connected with a cutting knife (73) for cutting the filter element core.