CN221312707U - Numerical control sawing machine for iron core machining - Google Patents

Abstract

The utility model discloses a numerical control sawing machine for iron core machining, and relates to the technical field of iron core machining. The numerical control sawing machine comprises a numerical control sawing machine body, a baffle frame and a driving pump, wherein a workbench is arranged on the upper surface of the numerical control sawing machine body, limit grooves are formed in the left side and the right side of the upper surface of the workbench, and a blower and a dust pump are respectively arranged on the left side and the right side of the baffle frame. This numerical control sawing machine for iron core processing is provided with dust pump and coarse chip groove, start the air-blower and draw the dust pump, it inhales to draw the dust pump through inhaling light piece and the dust that produce when the interior iron core of frame is cut to be kept off through the bits pipe, and carry piece and dust to the fine dust incasement through chip removal pipe, the air-blower blows great bits and granule that produce in the iron core cutting to the coarse chip inslot through tuber pipe and flexible pipe air-out, and under the vibrations effect that produces in the during operation of equipment, make bits and granule carry to carrying baffle from the coarse chip groove, and carry to the coarse chip incasement through carrying baffle, thereby be convenient for collect and classify the piece.

Description

Numerical control sawing machine for iron core machining

Technical Field

The utility model relates to the technical field of iron core machining, in particular to a numerical control sawing machine for iron core machining.

Background

When the transformer works, alternating current exists in the coil, and magnetic flux generated by the alternating current is of course alternating. This changing magnetic flux generates an induced current in the core, and the induced current generated in the core circulates in a plane perpendicular to the direction of the magnetic flux, so that eddy currents and eddy current losses similarly cause the core to generate heat. In order to reduce eddy current loss, the iron core of the transformer is laminated by silicon steel sheets insulated from each other, so that eddy current passes through a smaller section in a long and narrow loop to increase the resistance of an eddy current path, and meanwhile, silicon in silicon steel increases the resistivity of a material and also plays a role in reducing the eddy current. In the process of processing the iron core, the size of the iron core needs to be controlled according to the required size of the transformer.

If the saw machine for processing the steel with the bulletin number of CN217044843U comprises a bottom plate and a C-shaped frame, generated scraps can be blocked during cutting, the situation that the scraps hurt workers is avoided, and the use safety of the saw machine is further improved. However, the device has certain defects;

When processing the work piece, only stop the piece to producing when cutting through the opening box, neglected the collection to the piece, the piece directly splashes in the gap of bottom plate and equipment, needs the manual work to clear up after the cutting is accomplished, and the piece clearance degree of difficulty in gap department is great simultaneously, wastes time and energy more.

We have therefore proposed a numerical control sawing machine for machining cores so as to solve the problems set forth above.

Disclosure of utility model

The utility model aims to provide a numerical control sawing machine for iron core machining, which solves the problems that when a workpiece is machined by the existing sawing machine in the market, the existing sawing machine in the market provided by the background technology only blocks generated fragments during cutting by an open box, the collection of the fragments is omitted, the fragments are directly splashed into gaps of a bottom plate and equipment, manual cleaning is needed after the cutting is finished, and meanwhile, the fragments at the gaps are difficult to clean, so that time and labor are wasted.

In order to achieve the above purpose, the present utility model provides the following technical solutions: the utility model provides a numerical control sawing machine for iron core processing, includes numerical control sawing machine body, keeps off frame and driving pump, the last surface mounting of numerical control sawing machine body has the workstation, and the below of workstation is provided with movable gear, first rack and second rack, and the top of workstation is provided with the limiting plate moreover, the spacing groove has been seted up to the upper surface left and right sides of workstation, and the outside of workstation is installed and is kept off the frame, and the inner wall that keeps off the frame is connected with the limiting plate through electric telescopic handle moreover, air-blower and dust pump are installed respectively to the left and right sides that keeps off the frame, the coarse chip groove has been seted up to the right side upper surface of workstation, and the driving pump is installed to the top of workstation, and the cutting wheel is installed to the below of driving pump moreover.

Preferably, a bearing seat is installed at the inner bottom of the workbench, a rotating shaft is installed on the bearing seat, a rotating structure is formed between the rotating shaft and the bearing seat, and a movable gear is installed at the upper end of the rotating shaft.

By adopting the structural design, the rotating shaft can rotate along the bearing seat when being stressed, so that the movable gear on the rotating shaft drives the rotating shaft to rotate when being stressed.

Preferably, the first rack and the second rack are parallel to each other, the movable gear is located between the first rack and the second rack, the movable gear is meshed with the first rack and the second rack, connecting strips are installed above the first rack and the second rack, the connecting strips are in staggered design, penetrate through the limiting grooves, a sliding structure is formed between the limiting grooves, and the connecting strips are fixedly connected with the bottom surface of the limiting plate.

By adopting the structural design, the electric telescopic rod is started, the electric telescopic rod pushes the limiting plate, the limiting plate pushes the first rack, the first rack drives the movable gear to rotate, and then the movable gear drives the second rack to move along the direction opposite to the first rack, so that the limiting plates on the left side and the right side relatively move, the iron core is fixed through the limiting plate, and the iron core is prevented from shifting in the cutting process.

Preferably, the right side of keeping off the frame is provided with the coarse chip case, and the fine chip case is installed to the top of coarse chip case, and the coarse chip case is linked together with the coarse chip groove through carrying the baffle, and the bottom surface of coarse chip groove is slope structural design moreover.

By adopting the structural design, the iron core blows larger scraps and particles generated in the cutting process into the coarse scraps tank under the action of the air blower, and the scraps and the particles are conveyed from the coarse scraps tank to the conveying baffle plate under the action of vibration force generated during the operation of the equipment and conveyed into the coarse scraps tank through the conveying baffle plate.

Preferably, an air outlet pipe is arranged above the blower, the air outlet pipe penetrates through the baffle frame, a telescopic pipe is arranged on the right side of the air outlet pipe, an air outlet nozzle is arranged at the lower end of the telescopic pipe, and the telescopic pipe is positioned in the baffle frame.

By adopting the structural design, the telescopic pipe is adjusted to the position of cutting the iron core, the blower is started, and the blower blows larger scraps and particles generated in the cutting of the iron core into the coarse scraps groove through the air outlet pipe and the air outlet of the telescopic pipe.

Preferably, the dust suction pipe and the chip removal pipe are respectively arranged on the upper side and the lower side of the dust suction pump, the chip suction pipe is communicated with the inside of the baffle frame, and the chip removal pipe is connected with the chip box.

By adopting the structural design, the dust pump is started, light scraps and dust generated when the iron core in the baffle frame is cut are sucked by the dust pump through the scraps suction pipe, and the scraps and the dust are conveyed into the scraps box through the scraps suction pipe.

Compared with the prior art, the utility model has the beneficial effects that: this numerical control sawing machine is used in iron core processing:

1. The movable gear, the first rack and the second rack are arranged, the electric telescopic rod is started, the electric telescopic rod pushes the limiting plate, the limiting plate pushes the first rack, the first rack drives the movable gear to rotate, and then the movable gear drives the second rack to move along the direction opposite to the first rack, so that the limiting plates on the left side and the right side relatively move, the iron core is fixed through the limiting plate, and the iron core is prevented from shifting in the cutting process;

2. Be provided with dust pump and coarse chip groove, start air-blower and dust pump, the dust pump will keep off the light piece and dust suction that produce when the frame inner core cuts through inhaling the bits pipe, and carry piece and dust to the fine chip incasement through the chip removal pipe, the air-blower blows great bits strip and the granule that produce in the core cutting to the coarse chip inslot through air-out pipe and flexible pipe air-out, and under the vibrations effect that produces in the equipment during operation, make bits strip and granule carry to carrying baffle from the coarse chip groove, and carry to the coarse chip incasement through carrying baffle, thereby be convenient for collect and classify the piece.

Drawings

FIG. 1 is a schematic diagram of a front view structure of the present utility model;

FIG. 2 is an enlarged schematic view of the structure of FIG. 1A according to the present utility model;

FIG. 3 is an enlarged schematic view of the structure of FIG. 1B according to the present utility model;

FIG. 4 is an enlarged schematic view of the structure of FIG. 1 at C according to the present utility model;

FIG. 5 is a schematic view of the position structure of a first rack and a second rack according to the present utility model;

FIG. 6 is a schematic top view of the table of the present utility model;

FIG. 7 is a schematic diagram of the cross-sectional structure of the coarse chip tank of the present utility model.

In the figure: 1. a numerical control sawing machine body; 2. a work table; 3. a bearing seat; 4. a rotating shaft; 5. a movable gear; 6. a first rack; 7. a second rack; 8. a connecting strip; 9. a limiting plate; 10. a limit groove; 11. a coarse scraps box; 12. a fines bin; 13. an electric telescopic rod; 14. a blocking frame; 15. a blower; 16. a dust pump; 17. an air outlet pipe; 18. a telescopic tube; 19. a chip suction pipe; 20. a chip removal tube; 21. a coarse chip groove; 22. a conveying baffle; 23. driving a pump; 24. and (3) a cutting wheel.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Referring to fig. 1-7, the present utility model provides a technical solution: the utility model provides a numerical control sawing machine for iron core processing, including numerical control sawing machine body 1, the workstation 2, bearing frame 3, pivot 4, movable gear 5, first rack 6, second rack 7, connecting strip 8, limiting plate 9, spacing groove 10, coarse chip case 11, fine chip case 12, electric telescopic link 13, keep off frame 14, air-blower 15, dust pump 16, go out tuber pipe 17, flexible pipe 18, inhale the chip pipe 19, chip removal pipe 20, coarse chip groove 21, carry baffle 22, driving pump 23 and cutting wheel 24, the workstation 2 is installed to the upper surface of numerical control sawing machine body 1, the bearing frame 3 is installed to the interior bottom of workstation 2, and install pivot 4 on the bearing frame 3, constitute revolution mechanic between pivot 4 and the bearing frame 3, movable gear 5 is installed to the upper end of pivot 4, pivot 4 can rotate along bearing frame 3 when the atress, thereby make movable gear 5 on pivot 4 drive pivot 4 and rotate when the atress, the lower part of the workbench 2 is provided with a movable gear 5, a first rack 6 and a second rack 7, the first rack 6 and the second rack 7 are mutually parallel, the movable gear 5 is positioned between the first rack 6 and the second rack 7, the movable gear 5 is mutually meshed with the first rack 6 and the second rack 7, connecting strips 8 are arranged above the first rack 6 and the second rack 7, the connecting strips 8 are staggered, the connecting strips 8 penetrate through limit grooves 10 and form a sliding structure between the limit grooves 10, the connecting strips 8 are fixedly connected with the bottom surface of a limit plate 9, an electric telescopic rod 13 is started, the limit plate 9 is pushed by the electric telescopic rod 13, the first rack 6 is pushed by the limit plate 9, the movable gear 5 is driven to rotate by the first rack 6, the second rack 7 is driven by the movable gear 5 to move along the direction opposite to the first rack 6, thereby make limiting plate 9 relative movement of left and right sides, fix the iron core through limiting plate 9, prevent that the iron core from taking place the skew at the in-process of cutting.

The upper part of the workbench 2 is provided with a limiting plate 9, the left and right sides of the upper surface of the workbench 2 are provided with limiting grooves 10, the outer side of the workbench 2 is provided with a baffle frame 14, the right side of the baffle frame 14 is provided with a coarse chip box 11, the upper part of the coarse chip box 11 is provided with a fine chip box 12, the coarse chip box 11 is communicated with the coarse chip groove 21 through a conveying baffle 22, the bottom surface of the coarse chip groove 21 is of an inclined structure design, large chip strips and particles generated in the cutting process of an iron core are blown into the coarse chip groove 21 under the action of a blower 15, and under the action of vibration force generated during the working of equipment, the chip strips and particles are conveyed from the coarse chip groove 21 to the conveying baffle 22 and conveyed into the coarse chip box 11 through the conveying baffle 22, the inner wall of the baffle frame 14 is connected with the limiting plate 9 through an electric telescopic rod 13, the left and right sides of the baffle frame 14 are respectively provided with the blower 15 and a dust pump 16, an air outlet pipe 17 is arranged above the air blower 15, the air outlet pipe 17 penetrates through the baffle frame 14, a telescopic pipe 18 is arranged on the right side of the air outlet pipe 17, an air outlet nozzle is arranged at the lower end of the telescopic pipe 18, the telescopic pipe 18 is positioned in the baffle frame 14, the telescopic pipe 18 is adjusted to the position for cutting the iron core, the air blower 15 is started, the air blower 15 blows air out through the air outlet pipe 17 and the telescopic pipe 18 to blow larger scraps and particles generated in the iron core cutting into a coarse scraps groove 21, a scraps suction pipe 19 and a scraps suction pipe 20 are respectively arranged on the upper side and the lower side of the dust suction pump 16, the scraps suction pipe 19 is communicated with the inside of the baffle frame 14, the scraps suction pipe 20 is connected with the fine scraps box 12, the dust suction pump 16 is started, the scraps and the dust are conveyed into the fine scraps box 12 through the scraps suction pipe 20, the coarse scraps 21 are arranged on the upper surface on the right side of the workbench 2, and a driving pump 23 is installed above the table 2, and a cutting wheel 24 is installed below the driving pump 23.

Working principle: when the numerical control sawing machine for processing the iron core is used, firstly, the iron core to be cut is placed on a workbench 2, an electric telescopic rod 13 is started, the electric telescopic rod 13 pushes a limiting plate 9, the limiting plate 9 pushes a first rack 6, the first rack 6 drives a movable gear 5 to rotate, then the movable gear 5 drives a second rack 7 to move along the direction opposite to the first rack 6, so that the limiting plates 9 on the left side and the right side relatively move, the iron core is fixed through the limiting plates 9, then a blower 15, a dust pump 16 and a driving pump 23 are started, the driving pump 23 drives a cutting wheel 24 to move downwards to cut the iron core, the dust pump 16 sucks light chips and dust generated when the iron core in a baffle frame 14 is cut through a chip suction pipe 19, the chips and dust are conveyed into a fine chip box 12 through a chip suction pipe 20, the blower 15 blows air through an air outlet pipe 17 and a telescopic pipe 18, larger chips and particles generated in the iron core cutting are blown into a coarse chip groove 21, and under the action of vibration force generated when equipment works, the chips and the particles are conveyed from the chip groove 21 to a baffle 22 and conveyed into the coarse chip box 22 through the baffle plate 22 and the coarse chip box 11 to be classified. Thereby completing a series of works. What is not described in detail in this specification is prior art known to those skilled in the art.

Although the present utility model has been described with reference to the foregoing embodiments, it will be apparent to those skilled in the art that modifications may be made to the embodiments described, or equivalents may be substituted for elements thereof, and any modifications, equivalents, improvements and changes may be made without departing from the spirit and principles of the present utility model.

Claims (6)

1. The utility model provides a numerical control sawing machine for iron core processing, includes numerical control sawing machine body (1), keeps off frame (14) and driving pump (23), its characterized in that: the utility model discloses a numerical control sawing machine, including workstation (2) and cutting wheel (24) are installed to the top surface mounting of workstation (1), and workstation (2) below is provided with movable gear (5), first rack (6) and second rack (7), and the top of workstation (2) is provided with limiting plate (9) moreover, limiting groove (10) have been seted up to the upper surface left and right sides of workstation (2), and keep off frame (14) are installed in the outside of workstation (2), and keep off the inner wall of frame (14) and be connected with limiting plate (9) through electric telescopic handle (13), air-blower (15) and dust pump (16) are installed respectively in the left and right sides of fender frame (14), coarse dust groove (21) have been seted up on the right side upper surface of workstation (2), and driving pump (23) are installed to the top of workstation (2), and cutting wheel (24) are installed to the below of driving pump (23) moreover.

2. The numerical control sawing machine for machining iron cores according to claim 1, wherein: the bearing seat (3) is installed at the inner bottom of the workbench (2), the rotating shaft (4) is installed on the bearing seat (3), a rotating structure is formed between the rotating shaft (4) and the bearing seat (3), and the movable gear (5) is installed at the upper end of the rotating shaft (4).

3. The numerical control sawing machine for machining iron cores according to claim 1, wherein: the utility model discloses a sliding structure, including limiting groove (10), connecting strip (8), limiting plate (9), connecting strip (8) staggered design, connecting strip (8) run through in limiting groove (10) to constitute sliding structure between limiting groove (10), connecting strip (8) and limiting plate (9) bottom surface fixed connection in addition, movable gear (5) and intermeshing between first rack (6) and second rack (7) are located between first rack (6) and second rack (7), and movable gear (5) and first rack (6) and second rack (7).

4. The numerical control sawing machine for machining iron cores according to claim 1, wherein: the right side of fender frame (14) is provided with coarse chip case (11), and fine chip case (12) are installed to the top of coarse chip case (11), and coarse chip case (11) are linked together with coarse chip groove (21) through carrying baffle (22), and the bottom surface of coarse chip groove (21) is slope structural design moreover.

5. The numerical control sawing machine for machining iron cores according to claim 1, wherein: an air outlet pipe (17) is arranged above the blower (15), the air outlet pipe (17) penetrates through the baffle frame (14), a telescopic pipe (18) is arranged on the right side of the air outlet pipe (17), an air outlet nozzle is arranged at the lower end of the telescopic pipe (18), and the telescopic pipe (18) is located inside the baffle frame (14).

6. The numerical control sawing machine for machining iron cores according to claim 1, wherein: the dust suction pipe (19) and the chip removal pipe (20) are respectively arranged on the upper side and the lower side of the dust suction pump (16), the chip suction pipe (19) is communicated with the inside of the baffle frame (14), and the chip removal pipe (20) is connected with the chip box (12).