CN217749558U - Nanocrystalline alloy is with cutting device who has anti skew structure - Google Patents

Abstract

The utility model discloses a cutting device with an anti-deviation structure for nanocrystalline alloy, which comprises a cutting groove, wherein the cutting groove is arranged at the upper end of a cutting table, a cutting machine is arranged in the cutting groove, a motor is arranged below the cutting table, and the output end of the motor is connected with the cutting machine into an integral structure; side limiting plate, its setting is in the top of cutting bed, and side limiting plate is provided with two, and two side limiting plates all set up in one side of cutting cut groove, the top of cutting bed is provided with first mounting bracket, and just first mounting bracket passes through the screw connection with the cutting bed, the below of first mounting bracket is provided with the crane, the inboard and the crane below of side limiting plate all are provided with the gyro wheel, and the gyro wheel all rotates with side limiting plate and crane to be connected. This cutting device can play spacing effect to the nanocrystalline alloy of cutting, can release the effort buffering that the cutting produced, and indirect improvement nanocrystalline alloy cutting accuracy, cutting effect is better.

Description

Nanocrystalline alloy is with cutting device who has anti skew structure

Technical Field

The utility model relates to a nanocrystalline alloy cutting technical field specifically is a nanocrystalline alloy is with cutting device who has anti skew structure.

Background

In the field of power electronics, with the maturity of high-frequency inversion technology, a large amount of traditional high-power linear power supplies are replaced by high-frequency switching power supplies, and in order to improve efficiency and reduce volume, the working frequency of the switching power supplies is higher and higher, so that higher requirements are provided for soft magnetic materials in the switching power supplies, and nanocrystalline alloys are produced. The nanocrystalline alloy is soft magnetic alloy with a nanocrystalline structure obtained by heat treatment on the basis of amorphous alloy, and has more excellent soft magnetic performance, so that the manufacturing process and the using process of the amorphous alloy material are energy-saving green energy-saving products which are mainly developed in the new century, and the nanocrystalline alloy needs to be cut by means of a cutting device. At present, cutting device is when cutting the nanocrystalline alloy, and the cutting effort that the cutting produced can drive the nanocrystalline alloy shake, and the nanocrystalline alloy lacks effectual limiting displacement, can make the nanocrystalline alloy skew appear, leads to the nanocrystalline alloy precision of cutting to descend, can not satisfy the use.

In view of the above problems, innovative design is urgently needed based on the cutting device with an anti-offset structure for the original nanocrystalline alloy.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a nanocrystalline alloy is with cutting device who has anti skew structure to the cutting effort of proposing the cutting production in solving above-mentioned background art can drive the nanocrystalline alloy shake, and the nanocrystalline alloy lacks effectual limiting displacement, can make the nanocrystalline alloy skew appear, leads to the nanocrystalline alloy precision of cutting to descend, can not satisfy the problem of using.

In order to achieve the above object, the utility model provides a following technical scheme: a cutting device with an anti-offset structure for a nanocrystalline alloy comprises a cutting table;

the cutting machine is arranged in the cutting groove, a motor is arranged below the cutting table and connected with the cutting table through screws, and the output end of the motor is connected with the cutting machine into an integral structure;

the side limiting plate is arranged above the cutting table, the two side limiting plates are arranged on one side of the cutting groove, the first mounting frame is arranged above the cutting table and is connected with the cutting table through screws, the lifting frame is arranged below the first mounting frame, the rollers are arranged on the inner side of the side limiting plate and below the lifting frame, and the rollers are connected with the side limiting plates and the lifting frame in a rotating mode.

Preferably, the upper end of cutting bed is provided with the spout, and the spout is provided with two, two the below of side limiting plate all is provided with the slider, and slider and side limiting plate pass through bolted connection, the one end of slider extends to the inside of spout, and slider and cutting bed sliding connection, the both sides of cutting bed all are provided with adjusting screw, and adjusting screw's one end extends to the inside of spout, adjusting screw and slider threaded connection, and adjusting screw and cutting bed rotate to be connected.

Preferably, an electric telescopic rod is arranged above the first mounting frame, and the electric telescopic rod is connected with the first mounting frame and the lifting frame through screws.

Preferably, the upper end of the cutting table is provided with a scale strip, the scale strip and the cutting table are connected into an integral structure, and the scale strip is arranged on one side of the cutting groove.

Preferably, one side of the first mounting rack is provided with a second mounting rack, the second mounting rack is connected with the cutting table through screws, a through chute is formed in the second mounting rack, and an infrared emitter is arranged below the through chute.

Preferably, the cutting groove is internally provided with a ball, the ball is in rolling connection with the cutting table, and the ball is in sliding connection with the cutting machine.

Compared with the prior art, the beneficial effects of the utility model are that:

1. the utility model discloses a device is through side limiting plate, crane, electric telescopic handle and adjusting screw's setting, and side limiting plate and crane can play spacing effect simultaneously from the nanocrystalline alloy horizontal and longitudinal plane of cutting, prevent nanocrystalline alloy skew effectively, and electric telescopic handle drives the crane and goes up and down, and adjusting screw drives the side limiting plate and removes along the spout, can carry on spacingly to the nanocrystalline alloy of unidimensional not. The problem that the nanocrystalline alloy deflects due to the cutting action force of the nanocrystalline alloy is solved.

2. The utility model discloses a device is through the setting that link up spout, infra-red transmitter, lock nut and threaded rod, and infra-red transmitter sends infrared irradiation to fix a position cutting point position, link up the spout and make infra-red transmitter can remove, thereby fix a position different cutting points, lock nut and threaded rod can be fixed to the infra-red transmitter who removes. The problem of the cutting point position appear shifting and rely on human eyes to observe clearly under the cutting effect is solved.

Drawings

Fig. 1 is a schematic view of the overall structure of the present invention;

FIG. 2 is a connection relationship diagram of the side limiting plate, the lifting frame and the cutting table of the utility model;

FIG. 3 is a connection diagram of the cutting machine and the cutting table of the present invention;

fig. 4 is a connection relation diagram of the infrared emitter and the second mounting bracket of the present invention.

In the figure: 1. cutting table; 2. a side limiting plate; 3. a first mounting bracket; 4. a lifting frame; 5. an electric telescopic rod; 6. a scale bar; 7. adjusting the screw rod; 8. a second mounting bracket; 9. cutting the groove; 10. a through chute; 11. an infrared emitter; 12. locking the nut; 13. a threaded rod; 14. a cutter; 15. a chute; 16. a slider; 17. a roller; 18. a motor; 19. a ball bearing; 20. and (4) rolling the groove.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the 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.

Referring to fig. 1-4, the present invention provides an embodiment: a cutting device with an anti-offset structure for a nanocrystalline alloy comprises a cutting table 1;

the cutting groove 9 is arranged at the upper end of the cutting table 1, the cutting machine 14 is arranged inside the cutting groove 9, the motor 18 is arranged below the cutting table 1, the motor 18 is connected with the cutting table 1 through a screw, the output end of the motor 18 is connected with the cutting machine 14 into an integral structure, and the cutting machine 14 is driven to rotate under the action of the motor 18, so that the cutting angle is adjusted;

side limiting plate 2, it sets up the top at cutting bed 1, side limiting plate 2 is provided with two, and two side limiting plate 2 all set up in the one side of cutting cut groove 9, the top of cutting bed 1 is provided with first mounting bracket 3, and first mounting bracket 3 passes through the screw connection with cutting bed 1, the below of first mounting bracket 3 is provided with crane 4, the inboard and crane 4 below of side limiting plate 2 all are provided with gyro wheel 17, and gyro wheel 17 all rotates with side limiting plate 2 and crane 4 to be connected, can play spacing effect to the nanocrystalline alloy of cutting through side limiting plate 2 and crane 4, can prevent that nanocrystalline alloy from taking place the skew under the cutting effort.

Please refer to fig. 1 and fig. 2, the upper end of the cutting table 1 is provided with a sliding slot 15, the sliding slot 15 is provided with two sliding blocks 16, the lower portions of the two side limiting plates 2 are provided with sliding blocks 16, the sliding blocks 16 are connected with the side limiting plates 2 through screws, one end of each sliding block 16 extends into the sliding slot 15, the sliding blocks 16 are connected with the cutting table 1 in a sliding manner, the two sides of the cutting table 1 are provided with adjusting screws 7, one end of each adjusting screw 7 extends into the corresponding sliding slot 15, the adjusting screws 7 are connected with the sliding blocks 16 in a threaded manner, the adjusting screws 7 are rotatably connected with the cutting table 1, the sliding blocks 16 can be driven to slide in the sliding slots 15 through rotating the adjusting screws 7, the distance between the two side limiting plates 2 is adjusted along with the movement of the sliding blocks 16, and the cutting point position can be adjusted.

Referring to fig. 1 and 2, an electric telescopic rod 5 is arranged above the first mounting frame 3, the electric telescopic rod 5 is connected with the first mounting frame 3 and the lifting frame 4 through screws, the lifting frame 4 is driven to lift through the electric telescopic rod 5, and the lifting frame 4 can limit the nanocrystalline alloys with different thicknesses along with the lifting.

Referring to fig. 1, the upper end of the cutting table 1 is provided with a scale strip 6, the scale strip 6 is connected with the cutting table 1 into an integral structure, the scale strip 6 is arranged on one side of the cutting groove 9, and the side control limiting plate 2 can be adjusted quickly and accurately through the scale strip 6.

Please refer to fig. 1 and 4, a second mounting frame 8 is arranged on one side of the first mounting frame 3, the second mounting frame 8 is connected with the cutting table 1 through screws, a through chute 10 is arranged on the second mounting frame 8, an infrared emitter 11 is arranged below the through chute 10, a threaded rod 13 is arranged above the infrared emitter 11, the threaded rod 13 is connected with the infrared emitter 11 through screws, one end of the threaded rod 13 penetrates through the through chute 10 and extends to the top of the second mounting frame 8, the threaded rod 13 is connected with the second mounting frame 8 in a sliding manner, a locking nut 12 is arranged above the second mounting frame 8, the locking nut 12 is connected with the threaded rod 13 in a threaded manner, infrared rays emitted by the infrared emitter 11 can be used for positioning the cutting point, the through chute 10 enables the infrared emitter 11 to be adjusted in a sliding manner, different cutting point positions are positioned, and the threaded rod 13 and the locking nut 12 can fix the infrared emitter 11.

Referring to fig. 3, a rolling groove 20 is disposed at the lower end of the cutting machine 14, a ball 19 is disposed inside the cutting groove 9, the ball 19 is connected to the cutting table 1 in a rolling manner, one end of the ball 19 extends into the cutting groove 9, the ball 19 is connected to the cutting machine 14 in a sliding manner, and the ball 19 and the rolling groove 20 can guide and limit the rotating cutting machine 14.

The working principle is as follows: during the use, place the nanocrystalline alloy on cutting bed 1, it is rotatory to open motor 18 and drive cutting machine 14, adjust the cutting angle, and aim at nanocrystalline alloy cutting machine 14, rotatory adjusting screw 7 drives side limiting plate 2 and removes along spout 15, contact gyro wheel 17 on the side limiting plate 2 with the both sides wall of nanocrystalline alloy can, drive electric telescopic handle 5 drives crane 4 and goes up and down, contact gyro wheel 17 on the crane 4 with the upper end of nanocrystalline alloy, play spacing effect to the nanocrystalline alloy of cutting, can prevent that the cutting effort from causing the skew of nanocrystalline alloy. Infrared emitter 11 sends infrared irradiation cutting point position, fixes a position cutting point position, can observe cutting offset amplitude better, link up spout 10 and make infrared emitter 11 can the translation to fix a position different cutting point positions, lock nut 12 and threaded rod 13 can play fixed effect to infrared emitter 11.

Those not described in detail in this specification are well within the skill of the art.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that various changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (6)

1. A cutting device with an anti-offset structure for nanocrystalline alloys comprises a cutting table (1), and is characterized in that:

the cutting table comprises a cutting groove (9) which is arranged at the upper end of a cutting table (1), a cutting machine (14) is arranged inside the cutting groove (9), a motor (18) is arranged below the cutting table (1), the motor (18) is connected with the cutting table (1) through a screw, and the output end of the motor (18) is connected with the cutting machine (14) into an integral structure;

side limiting plate (2), its setting is in the top of cutting bed (1), and side limiting plate (2) are provided with two, and two side limiting plate (2) all set up the one side in cutting groove (9), the top of cutting bed (1) is provided with first mounting bracket (3), and just first mounting bracket (3) pass through bolted connection with cutting bed (1), the below of first mounting bracket (3) is provided with crane (4), the inboard and crane (4) below of side limiting plate (2) all are provided with gyro wheel (17), and gyro wheel (17) all rotate with side limiting plate (2) and crane (4) and are connected.

2. The cutting device with the anti-offset structure for the nanocrystalline alloy according to claim 1, wherein: the upper end of cutting bed (1) is provided with spout (15), and spout (15) are provided with two, two the below of side limiting plate (2) all is provided with slider (16), and slider (16) and side limiting plate (2) pass through screw connection, the one end of slider (16) extends to the inside of spout (15), and slider (16) and cutting bed (1) sliding connection, the both sides of cutting bed (1) all are provided with adjusting screw (7), and the one end of adjusting screw (7) extends to the inside of spout (15), adjusting screw (7) and slider (16) threaded connection, and adjusting screw (7) rotate with cutting bed (1) and be connected.

3. The cutting device with the anti-offset structure for the nanocrystalline alloy according to claim 1, wherein: an electric telescopic rod (5) is arranged above the first mounting frame (3), and the electric telescopic rod (5) is connected with the first mounting frame (3) and the lifting frame (4) through screws.

4. The cutting device with an anti-offset structure for nanocrystalline alloy according to claim 1, characterized in that: the cutting table is characterized in that a graduated scale strip (6) is arranged at the upper end of the cutting table (1), the graduated scale strip (6) and the cutting table (1) are connected into an integral structure, and the graduated scale strip (6) is arranged on one side of a cutting groove (9).

5. The cutting device with the anti-offset structure for the nanocrystalline alloy according to claim 1, wherein: one side of the first mounting rack (3) is provided with a second mounting rack (8), the second mounting rack (8) is connected with the cutting table (1) through screws, a through chute (10) is arranged on the second mounting rack (8), and an infrared transmitter (11) is arranged below the through chute (10).

6. The cutting device with the anti-offset structure for the nanocrystalline alloy according to claim 1, wherein: the inside of cutting groove (9) is provided with ball (19), and ball (19) and cutting bed (1) rolling connection, ball (19) and cutting machine (14) sliding connection.

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