CN211516221U - Magnet cutting device with push function - Google Patents

Abstract

The utility model discloses a magnet cutting device with a pushing function, which comprises a bottom plate, wherein a vertical side plate is arranged on the bottom plate; the vertical side plates are connected with sliding blocks in a sliding mode in the vertical direction, and the lower ends of the sliding blocks are provided with cutting assemblies; the vertical side plate is provided with a power assembly used for driving the sliding block to move up and down and a pushing assembly driven by the power assembly, a conveying table is arranged below the cutting assembly on the vertical side plate, a cutting table is arranged at the output end close to the conveying table on the bottom plate, a strong magnetic baffle is arranged on the side face of the cutting table far away from the conveying table, and the pushing assembly is used for pushing magnets adsorbed on the strong magnetic baffle; the cutting device is simple in structure, the up-and-down movement of the cutting assembly can be achieved without manual control, meanwhile, the pushing of the cut magnet can be completed, and the cutting efficiency of the magnet can be greatly improved.

Description

Magnet cutting device with push function

Technical Field

The utility model relates to a magnet production and processing field, in particular to magnet cutting device with propelling movement function.

Background

The magnet has iron, cobalt, nickel and other atoms, and the internal structure of the atoms is special, so that the magnet has magnetic moment. Bar magnet usually needs to cut in the production process, and magnet cutting device is the mechanical equipment that cuts magnet, and simultaneously, magnet cutting device plays a position of making the weight in industrial manufacturing work to magnet cutting device's application is very extensive, and it cuts the magnet piece mainly through the cutting machine, makes the shape of magnet piece adapt to social demand more.

When using, the existing magnet cutting device needs to be manually fixed on the magnet, then the magnet is cut by pulling the handle to control the up-and-down motion of the cutting piece, and the cut-off magnet is manually taken down after cutting, so that the cutting efficiency is very low, and the production efficiency of the magnet is greatly influenced.

Disclosure of Invention

An object of the utility model is to provide a device of magnet cutting to solve the problem that above-mentioned background art provided.

In order to achieve the above object, the utility model provides a following technical scheme: a magnet cutting device with a pushing function comprises a bottom plate, wherein a vertical side plate is arranged on the bottom plate; the vertical side plates are connected with sliding blocks in a sliding mode in the vertical direction, and the lower ends of the sliding blocks are provided with cutting assemblies; the improved magnetic iron sheet conveying device is characterized in that a power assembly used for driving the sliding block to move up and down and a pushing assembly driven by the power assembly are arranged on the vertical side plate, a conveying table is arranged below the cutting assembly on the vertical side plate, a cutting table is arranged at the output end close to the conveying table on the bottom plate, a strong magnetic baffle is arranged on the side face, away from the conveying table, of the cutting table, and the pushing assembly is used for pushing magnets adsorbed on the strong magnetic baffle.

According to the technical scheme, when the magnet cutting device with the pushing function is used, a magnet to be cut is placed on the conveying table, the magnet to be cut is pushed to enable one end of the magnet to be cut to be located on the cutting table and to abut against the strong magnetic baffle, then the cutting assembly is started, the power assembly is started at the same time, the power assembly drives the cutting assembly to move up and down through the sliding block when working, the pushing assembly is driven to work in a reciprocating mode, the magnet to be cut is cut when the cutting assembly moves down, the cut magnet cannot fall under the action of the strong magnetic baffle, and meanwhile the power assembly drives the pushing assembly to retract rapidly; when the cutting assembly moves upwards, the power assembly drives the pushing assembly to extend out to push the magnets adsorbed on the strong magnetic baffle forwards; so as to push the magnet to be cut to abut against the strong magnetic baffle plate and finish the next cutting; the cutting device is simple in structure, the up-and-down movement of the cutting assembly can be achieved without manual control, meanwhile, the pushing of the cut magnet can be completed, and the cutting efficiency of the magnet can be greatly improved.

In a further technical scheme, a vertical groove is formed in the surface, facing the side plate, of the sliding block, and vertical clamping grooves are formed in the left side surface and the right side surface of the vertical groove; the vertical side plate is provided with a fixed block extending into the vertical groove, and two sides of the fixed block are provided with convex blocks extending into the vertical clamping grooves; this setting can realize that the sliding block is steadily moved from top to bottom.

In a further technical scheme, the power assembly comprises a first motor, the first motor is installed behind a vertical side plate, an output shaft of the first motor penetrates through the vertical side plate and extends into a vertical groove, a clamping sleeve is fixedly arranged on the output shaft of the first motor, and a convex edge extending into a vertical clamping groove is arranged on the circumferential side surface of the clamping sleeve; a first gear is fixedly installed on an output shaft of the first motor penetrating through the vertical side plate, a second gear meshed with the first gear is rotatably connected to the left side of the first gear on the vertical side plate, and a third gear meshed with the first gear is rotatably connected to the right side of the first gear; a first rack is arranged on the left side of the sliding block along the vertical direction, and a second rack is arranged on the right side of the sliding block along the vertical direction; a first sector gear is coaxially arranged on the second gear and is used for being meshed with the first rack to drive the sliding block to move downwards; and a second sector gear is coaxially arranged on the third gear and is used for being meshed with a second rack to drive the sliding block to move upwards.

Through the technical scheme, the first motor drives the first gear to rotate when rotating, the first gear drives the second gear and the third gear to rotate in different directions when rotating, the second gear drives the first sector gear to rotate when rotating, the first sector gear drives the sliding block to move downwards through the first rack, and meanwhile, the second sector gear is disengaged from the second rack; when the first sector gear is disengaged from the first rack, the second sector gear is engaged with the second rack to drive the sliding block to move upwards; when the second sector gear is disengaged from the second rack, the first sector gear is engaged with the first rack to drive the sliding block to move downwards, so that circulation is formed to realize the up-and-down movement of the sliding block.

In a further technical scheme, the pushing assembly comprises a pushing rack, a first pushing shaft and a second pushing shaft, a first fixing ring and a second fixing ring are arranged below a second gear on the vertical side plate, the first pushing shaft is rotatably connected in the first fixing ring along a direction perpendicular to the sliding block and the moving direction, and the second pushing shaft is rotatably connected in the second fixing ring and is parallel to the first pushing shaft; the first pushing shaft and the second pushing shaft are connected through a pushing belt; a first pushing gear is arranged at one end, far away from the pushing belt, of the first pushing shaft, and a third rack meshed with the first pushing gear is arranged on the sliding block; the vertical side plate is provided with a pushing hole along the length direction of the pushing table, the pushing rack is connected in the pushing hole in a sliding mode, and a second pushing gear meshed with the pushing rack is arranged at one end, far away from the pushing belt, of the second pushing shaft.

Through the technical scheme, when the sliding block moves downwards, the first pushing shaft is driven to rotate through the engagement of the third rack and the first pushing gear, the second pushing shaft is driven to rotate through the pushing belt when the first pushing shaft rotates, and the second pushing shaft drives the pushing rack to retract into the pushing hole through the second pushing gear; the first push shaft is driven to rotate through the engagement of the third rack and the first push gear when the sliding block moves upwards, the first push shaft drives the second push shaft to rotate through the push belt when rotating, the second push shaft drives the push rack to stretch out from the push hole through the second push gear, and the magnet adsorbed on the strong magnetic baffle is pushed forwards.

In a further technical scheme, the cutting assembly comprises a cutting motor fixedly installed at the bottom of the sliding block, and a cutting blade is arranged on an output shaft of the cutting motor; this setting passes through the cutting motor and drives the cutting piece and rotate, and then realizes the cutting to magnet.

In a further technical scheme, two convex plates are arranged on the conveying table side by side along the movement direction of the magnet to be cut, and the width of a placing groove formed between the convex plates at the two sides is the same as that of the magnet to be cut; this arrangement can prevent the magnet from shaking in the front-rear direction when the magnet is cut.

In a further technical scheme, two top plates are arranged above the two convex plates on the vertical side plates, and the distance between each top plate and the upper surface of the conveying table is the same as the height of the magnet to be cut; this arrangement can prevent the magnet from shaking in the vertical direction when the magnet is cut.

The utility model has the advantages that: when the magnet cutting device with the pushing function is used, a magnet to be cut is placed on a conveying table, the magnet to be cut is pushed to enable one end of the magnet to be cut to be located on a cutting table and to abut against a strong magnetic baffle, then a cutting assembly is started, a power assembly is started at the same time, the power assembly drives the cutting assembly to move up and down through a sliding block when working, the magnet to be cut is cut when the cutting assembly moves down, the cut magnet cannot fall under the action of the strong magnetic baffle, the cut magnet is taken out when the cutting assembly moves up, and the magnet to be cut is pushed to abut against the strong magnetic baffle again to finish next cutting; the cutting device is simple in structure, the up-and-down movement of the cutting assembly can be achieved without manual control, and the cutting efficiency of the magnet can be greatly improved.

Drawings

Fig. 1 is a perspective view of the present invention;

fig. 2 is a right side view of the present invention;

fig. 3 is a schematic diagram of the explosion structure of the present invention;

FIG. 4 is a schematic view of a part of the structure of the present invention;

FIG. 5 is a perspective view of the slider of the present invention;

fig. 6 is a sectional view of the slide block of the present invention;

fig. 7 is an enlarged structural view at a in fig. 4.

Detailed Description

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 is to be understood that the terms "center", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are merely for convenience of description and for simplicity of description, and do not indicate or imply that the device or element referred to must have a particular orientation, be constructed and operated in a particular orientation, and therefore, should not be construed as limiting the present invention.

In the description of the present invention, it should be noted that unless otherwise explicitly stated or limited, the terms "mounted," "connected" and "disposed" are to be construed broadly, and may for example be fixedly connected, disposed, detachably connected, disposed, or integrally connected and disposed. The specific meaning of the above terms in the present invention can be understood in specific cases to those skilled in the art.

Referring to fig. 1-7, in an embodiment of the present invention, a magnet cutting device with a pushing function includes a bottom plate 1, wherein a vertical side plate 2 is disposed on the bottom plate 1; the vertical side plates 2 are connected with sliding blocks 3 in a sliding mode in the vertical direction, and the lower ends of the sliding blocks 3 are provided with cutting assemblies; be equipped with the power component who is used for driving sliding block 3 up-and-down motion on vertical curb plate 2 to and by power component driven propelling movement subassembly, be equipped with in cutting assembly's below on vertical curb plate 2 and carry platform 4, be equipped with cutting bed 5 at the output that is close to carrying platform 4 on bottom plate 1, cutting bed 5 is equipped with strong magnetic baffle 6 on the side of keeping away from and carries the platform, the propelling movement subassembly is used for the propelling movement magnet that adsorbs on strong magnetic baffle 6. The cutting assembly comprises a cutting motor 7 fixedly installed at the bottom of the sliding block 3, and a cutting blade 8 is arranged on an output shaft of the cutting motor 7. Here the lower end of the slide block 3 is provided with a mounting hole (not shown in the figure) in which the cutting motor 7 is fixedly mounted.

A vertical groove 31 is formed in the surface, facing the side plate, of the sliding block 3, and vertical clamping grooves 32 are formed in the left side surface and the right side surface of the vertical groove 31; the vertical side plate 2 is provided with a fixing block 21 extending into the vertical groove 31, and two sides of the fixing block 21 are provided with convex blocks 22 extending into the vertical clamping grooves 32. The power assembly comprises a first motor 9, the first motor 9 is installed behind the vertical side plate 2, an output shaft of the first motor 9 penetrates through the vertical side plate 2 and extends into the vertical groove 31, a clamping sleeve 91 is fixedly arranged on the output shaft of the first motor 9, and a convex edge 92 extending into the vertical clamping groove 32 is arranged on the circumferential side surface of the clamping sleeve 91; the first motor 9 is fixedly provided with a first gear 93 through an output shaft of the vertical side plate 2, a second gear 94 meshed with the first gear 93 is rotatably connected to the left side of the first gear 93 on the vertical side plate 2, and a third gear 95 meshed with the first gear 93 is rotatably connected to the right side of the first gear 93; a first rack 33 is arranged on the left side of the sliding block 3 along the vertical direction, and a second rack 34 is arranged on the right side of the sliding block along the vertical direction; a first sector gear 96 is coaxially arranged on the second gear 94, and the first sector gear 96 is used for meshing with the first rack 33 to drive the sliding block 3 to move downwards; a second sector gear 97 is coaxially arranged on the third gear 95, and the second sector gear 97 is used for meshing with the second rack 34 to drive the sliding block 3 to move upwards.

The pushing assembly comprises a pushing rack 10, a first pushing shaft 101 and a second pushing shaft 102, a first fixing ring 103 and a second fixing ring 104 are arranged below a second gear on the vertical side plate 2, the first pushing shaft 101 is rotatably connected in the first fixing ring 103 along a direction perpendicular to the sliding block 3 and the moving direction, and the second pushing shaft 102 is rotatably connected in the second fixing ring 104 and is parallel to the first pushing shaft 101; the first pushing shaft 101 and the second pushing shaft 102 are connected through a pushing belt 105; a first pushing gear 106 is arranged at one end of the first pushing shaft 101 far away from the pushing belt 105, and a third rack 35 meshed with the first pushing gear 106 is arranged on the sliding block 3; a pushing hole 201 is formed in the vertical side plate along the length direction of the pushing table, the pushing rack 10 is connected in the pushing hole 201 in a sliding mode, and a second pushing gear 107 meshed with the pushing rack 10 is arranged at one end, far away from the pushing belt 105, of the second pushing shaft 102.

Two convex plates 41 are arranged on the conveying table 4 side by side along the movement direction of the magnet to be cut, and the width of a placing groove formed between the convex plates 41 on the two sides is the same as that of the magnet to be cut. Two top plates 42 are arranged above the two convex plates 41 on the vertical side plates 2, and the distance between each top plate 42 and the upper surface of the conveying table 4 is the same as the height of the magnet to be cut.

When the magnet cutting device with the pushing function is used, a magnet to be cut is placed between two convex plates 41 on a conveying table 4, the magnet to be cut is pushed to enable one end of the magnet to be cut to be located on a cutting table 5 and to abut against a strong magnetic baffle 6, then a cutting motor 7 is started to drive a cutting piece 8 to rotate, the first motor 9 is controlled to rotate at the same time, the first motor 9 drives a first gear 93 to rotate when rotating, the first gear 93 drives a second gear 94 and a third gear 95 to rotate in different directions when rotating, the second gear 94 drives a first sector gear 96 to rotate when rotating, and the third gear 95 drives a second sector gear 97 to rotate when rotating; first sector gear 96 drives sliding block 3 downstream through first rack 33, and meanwhile second sector gear 97 breaks away from the meshing with second rack 34, treats cutting magnet through cutting piece 8 and cuts during sliding block 3 downstream, and the magnet that cuts away can not drop under strong magnetic baffle 6 effect.

When the second sector gear 97 is disengaged from the second rack 34, the first sector gear 96 is engaged with the first rack 33 to drive the sliding block 3 to move downwards to cut the magnet to be cut, the first pushing shaft 101 is driven to rotate through the engagement of the third rack 35 and the first pushing gear 106 when the sliding block 3 moves downwards, the first pushing shaft 101 drives the second pushing shaft 102 to rotate through the pushing belt 105 when rotating, and the second pushing shaft 102 drives the pushing rack 10 to be quickly retracted into the pushing hole 201 through the second pushing gear 107, so that the magnet to be cut is abutted to the strong magnetic baffle 6 again.

When the first sector gear 96 is disengaged from the first rack 33, the second sector gear 97 is engaged with the second rack 34 to drive the sliding block 3 to move upwards, the sliding block 3 drives the cutting blade 8 to move upwards when moving upwards, the first pushing shaft 101 is driven to rotate through the engagement of the third rack 35 and the first pushing gear 106 when moving upwards, the second pushing shaft 102 is driven to rotate through the pushing belt 105 when the first pushing shaft 101 rotates, the second pushing shaft 102 drives the pushing rack 10 to rapidly extend out of the pushing hole 201 through the second pushing gear 107, and the magnet adsorbed on the strong magnetic baffle 6 is pushed forwards. So far, circulation is formed to realize the up-and-down movement of the cutting assembly; the cutting device is simple in structure, the up-and-down movement of the cutting assembly can be achieved without manual control, and the cutting efficiency of the magnet can be greatly improved.

It is obvious to a person skilled in the art that the invention is not restricted to details of the above-described exemplary embodiments, but that it can be implemented in other specific forms without departing from the spirit or essential characteristics of the invention. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Furthermore, it should be understood that although the present description refers to embodiments, not every embodiment may contain only a single embodiment, and such description is for clarity only, and those skilled in the art should integrate the description, and the embodiments may be combined as appropriate to form other embodiments understood by those skilled in the art.

Claims (7)

1. The utility model provides a magnet cutting device with push function, includes the bottom plate, its characterized in that: the bottom plate is provided with a vertical side plate; the vertical side plates are connected with sliding blocks in a sliding mode in the vertical direction, and the lower ends of the sliding blocks are provided with cutting assemblies; the improved magnetic iron sheet conveying device is characterized in that a power assembly used for driving the sliding block to move up and down and a pushing assembly driven by the power assembly are arranged on the vertical side plate, a conveying table is arranged below the cutting assembly on the vertical side plate, a cutting table is arranged at the output end close to the conveying table on the bottom plate, a strong magnetic baffle is arranged on the side face, away from the conveying table, of the cutting table, and the pushing assembly is used for pushing magnets adsorbed on the strong magnetic baffle.

2. A magnetic cutting apparatus with a pushing function according to claim 1, characterized in that: a vertical groove is formed in the surface, facing the side plate, of the sliding block, and vertical clamping grooves are formed in the left side surface and the right side surface of the vertical groove; the vertical side plates are provided with fixing blocks extending into the vertical grooves, and two sides of each fixing block are provided with convex blocks extending into the vertical clamping grooves.

3. A magnetic cutting apparatus with a pushing function according to claim 2, characterized in that: the power assembly comprises a first motor, the first motor is installed behind the vertical side plate, an output shaft of the first motor penetrates through the vertical side plate and extends into the vertical groove, a clamping sleeve is fixedly arranged on the output shaft of the first motor, and a convex edge extending into the vertical clamping groove is arranged on the circumferential side surface of the clamping sleeve; a first gear is fixedly installed on an output shaft of the first motor penetrating through the vertical side plate, a second gear meshed with the first gear is rotatably connected to the left side of the first gear on the vertical side plate, and a third gear meshed with the first gear is rotatably connected to the right side of the first gear; a first rack is arranged on the left side of the sliding block along the vertical direction, and a second rack is arranged on the right side of the sliding block along the vertical direction; a first sector gear is coaxially arranged on the second gear and is used for being meshed with the first rack to drive the sliding block to move downwards; and a second sector gear is coaxially arranged on the third gear and is used for being meshed with a second rack to drive the sliding block to move upwards.

4. A magnetic cutting apparatus with a pushing function as claimed in claim 3, wherein: the pushing assembly comprises a pushing rack, a first pushing shaft and a second pushing shaft, a first fixing ring and a second fixing ring are arranged below a second gear on the vertical side plate, the first pushing shaft is rotatably connected in the first fixing ring along a direction perpendicular to the sliding block and the moving direction, and the second pushing shaft is rotatably connected in the second fixing ring and is parallel to the first pushing shaft; the first pushing shaft and the second pushing shaft are connected through a pushing belt; a first pushing gear is arranged at one end, far away from the pushing belt, of the first pushing shaft, and a third rack meshed with the first pushing gear is arranged on the sliding block; the vertical side plate is provided with a pushing hole along the length direction of the pushing table, the pushing rack is connected in the pushing hole in a sliding mode, and a second pushing gear meshed with the pushing rack is arranged at one end, far away from the pushing belt, of the second pushing shaft.

5. A magnetic cutting apparatus with a pushing function according to claim 2, characterized in that: the cutting assembly comprises a cutting motor fixedly installed at the bottom of the sliding block, and a cutting blade is arranged on an output shaft of the cutting motor.

6. A magnetic cutting apparatus with a pushing function according to claim 1, characterized in that: carry the bench to be equipped with two flanges side by side along waiting to cut magnet direction of motion, the width of the standing groove that forms between the flange of both sides is the same with the width of waiting to cut magnet.

7. A magnetic cutting apparatus with a pushing function according to claim 1, characterized in that: two top plates are arranged above the two convex plates on the vertical side plates, and the distance between each top plate and the upper surface of the conveying table is the same as the height of the magnet to be cut.

Images