CN116872370A - Multifunctional stone slicer - Google Patents

Abstract

The invention relates to the technical field of cutting equipment, in particular to a multifunctional stone slicer, which comprises a slicer rack, a collecting frame arranged on the slicer rack, a transferring device arranged on the slicer rack and positioned below the collecting frame, a guide plate arranged on one lateral side of the transferring device, a first cutting device arranged above the guide plate, an avoidance hole arranged on the guide plate and used for the cutting device to pass through, a second cutting device, a moving device used for moving stone cut by the first cutting device to the second cutting device, a conveying belt arranged below the second cutting device and a collecting device arranged at the top of the conveying belt.

Description

Multifunctional stone slicer

Technical Field

The invention relates to the technical field of cutting equipment, in particular to a multifunctional stone slicer.

Background

The existing stone plate rough machining is carried out by manually moving the single stone plate back and forth on a cutting machine to cut the single stone plate into long single pieces, and then cutting one end of the long single stone plate opposite to one piece of the cutting machine, so that the cutting efficiency is low; the cutting machine is used for cutting, the cutting piece is arranged vertically, the other side is arranged horizontally, the stone plate is manually moved to the horizontal cutting machine for cutting after being vertically cut, the cutting machine is more complicated to use, the stone plate is required to be positioned and fixed when being transversely cut for the first time, then the stone plate is positioned after being placed on the transverse shaft cutting machine, at the moment, the stone plates are easily damaged due to transverse extrusion when being clamped and positioned through the transverse shaft, the stone plates are worn on the side edges of the stone plates, machining precision errors and cracking defects are caused when part of the stone plates are caused due to the fact that the stone plates are transversely extruded, the transverse cutting tools of the stone plates are complex, and the stone plates are required to be placed one by one when being cut by a single piece, so that the cutting efficiency is low.

Disclosure of Invention

Therefore, in order to solve the problems, the invention provides a multifunctional stone slicer which solves the technical problem that the efficiency is low due to the fact that a two-axis cutting machine is used for cutting, two times of carrying and positioning are manually carried out on stone materials, and then a single stone plate is manually cut one by one.

In order to achieve the above purpose, the present invention adopts the following technical scheme: the utility model provides a multi-functional stone material slicer, including the slicer frame, locate the collection frame in the slicer frame, locate the slicer frame and be located the transfer device of collection frame below, locate the deflector of the horizontal one side of transfer device, locate the first cutting device above the deflector, locate on the deflector and be used for dodging the hole that first cutting device passed, the second cutting device, be used for moving the mobile device that first cutting device cut stone material to the second cutting device, locate the conveyer belt below the second cutting device, locate the collection device at conveyer belt top;

the second cutting device comprises a first cutting blade and a second cutting blade which are rotationally arranged on the slicing machine frame, a fixed shaft which is rotationally arranged on the slicing machine frame, a cylinder which is rotationally arranged on the outer side of the fixed shaft, a first driving device which is used for driving the cylinder to rotate, a first clamping block which is arranged on the two lateral sides of the cylinder, a square hole which is arranged on the outer side of the cylinder and is close to the first clamping block, a first protruding shaft which is arranged in the cylinder and is close to the fixed shaft, a second protruding shaft which is arranged in the cylinder and is close to the outer side edge, a swinging block which is rotationally arranged on the first protruding shaft, a second clamping block which is rotationally arranged on one side of the swinging block, a spacing groove which is arranged on the swinging block and is close to the second clamping block, a rotating wheel which is rotationally arranged on the spacing groove position on the swinging block, a first mounting block which is fixedly arranged on the spacing groove position on the swinging block, a second mounting block, a first elastic piece which is arranged on the first mounting block and the second mounting block, a third mounting block which is arranged on the other side of the swinging block, a fourth mounting block which is arranged on the second protruding shaft, a second mounting block which is close to the fixed on the fixed shaft, a second elastic piece which is arranged between the third mounting block and the third mounting block which is arranged on the second protruding shaft, a second elastic piece which is arranged between the third mounting block and the third mounting block which is arranged between the third clamping block and the second clamping block.

Further, the transfer device includes locating the first rotating block in the slicer frame, rotationally locate the first pivot at first rotating block middle part, be used for driving the rotatory first motor of first rotating shaft, set firmly in the first connecting block that the first motor was kept away from one side of first motor, locate the first guide pillar in the slicer frame, locate first connecting block between the first connecting block, the removal post in the first guide pillar outside is located in the slip, the transfer piece in the removal post outside is located in the slip, the second guide pillar in the guide block is located in the slip, rotate and locate the first hinge piece that the transfer piece is close to second guide pillar one side, and locate the first spring between first hinge piece and the first rotating block, first hinge piece and second guide pillar one side fixed connection, collection frame bottom is equipped with the perforation that is used for a stone material board to pass, collection frame bottom is equipped with the guiding hole, the transfer piece top is equipped with the extension that is used for passing perforation and guiding hole.

By adopting the technical scheme, the invention has the beneficial effects that:

this multi-functional stone material slicer uses through the cooperation of second cutting device and transfer device, can be with rectangular stone material board automatic movement sideslip after the cutting of first cutting device, then cuts into the smaller stone material board of width, and this structure cutting speed of second cutting device is faster, does benefit to stone material board rough machining, and this second cutting device cuts stone material board efficiency is faster, and the workman only needs to throw into the stone material board on collecting the frame and can cut the stone material board, is fit for medium or small-scale production factory.

When the transfer block moves to the middle position, the first spring is compressed and extruded to the minimum, the resistance received at the moment is high, the moving speed is also reduced, the moving speed of the first section of the stone plate at the bottom of the collecting frame is reduced slowly to reduce friction with the perforation of the collecting frame, the spring force of the first spring at the right section is reduced, and when the transfer block moves to the right, the first spring releases the spring force to eject the transfer block rightwards at a higher speed, a thrust is generated to the stone plate contacted with the extension part, the stone plate is pushed out instantly, and the phenomenon that the stone plate with the insufficient thrust stays on the guide plate is avoided.

The first supporting plate is driven to move backwards through the moving platform, the stone plate on the other side is adsorbed and transferred, the long strip-shaped stone plate can be simultaneously rotated and kept parallel to the second cutting device in the moving process of the long strip-shaped stone plate through the transferring device, and the stone plate after moving is kept in a transverse cutting state with the second cutting device.

The collecting device can vertically collect the stone plates, the vertically collected stone plates are not easy to damage, the operation process is stable, and the defect that the existing stone plates are easy to damage due to transverse movement in the stacking and conveying process is avoided.

The adsorption plate of the adsorption component can be a sucker, and the adsorption plate is not easy to fall off in the ceramic tile transferring process.

Drawings

Fig. 1 is a schematic structural view of the present invention.

Fig. 2 is a schematic front view of the transfer device of the present invention.

Fig. 3 is a schematic view showing a partial structure of the transfer device of the present invention.

Fig. 4 is a schematic front view of the mobile device of the present invention.

Fig. 5 is a schematic view of a part of a mobile device according to the present invention.

Fig. 6 is a schematic elevational view of the second cutting device of the present invention.

Fig. 7 is a plan view schematically showing a partial structure of a second cutting device of the present invention.

Fig. 8 is a schematic view showing a partial structure of a second cutting device of the present invention.

Fig. 9 is a schematic elevational view of the structure of the collecting device of the present invention.

Fig. 10 is a schematic view of a front view of a partial structure of a collecting device according to the present invention.

Fig. 11 is a schematic view of a partial structure of the collecting device according to the present invention from a rear view.

Reference numerals in the drawings: 1. a collection rack; 2. a transfer device; 3. a guide plate; 4. a first cutting device; 5. avoidance holes; 6. a second cutting device; 7. a mobile device; 8. a conveyor belt; 9. a collecting device; 201. a first rotating block; 202. a first rotating shaft; 203. a first motor; 204. a guide block; 205. a first connection block; 206. a first guide post; 207. a moving column; 208. a transfer block; 209. a first hinge block; 210. a first spring; 211. an extension; 212. a second guide post; 1a, perforating; 1b, a guide hole; 701. a first support plate; 702. a first gear; 703. a second gear; 704. a second motor; 705. a second support plate; 706. a second rotating shaft; 707. a drive cylinder; 708. a third support plate; 709. a suction cup; 710. a third rotating shaft; 711. a first connecting piece; 712. a second connecting piece; 713. a third connecting piece; 601. a first cutting blade; 602. a second cutting blade; 603. a fixed shaft; 604. a cylinder; 605. a first driving device; 606. a first clamping block; 607. square holes; 608. a first protruding shaft; 609. a second protruding shaft; 610. a swinging block; 611. a second clamping block; 612. a spacing groove; 613. a rotating wheel; 614. a first mounting block; 615. a second mounting block; 616. a first elastic member; 617. a third mounting block; 618. a fourth mounting block; 619. a second elastic member; 620. a cam; 901. a bottom post; 902. a support frame; 903. a drive gear; 904. a driven gear; 905. a swing gear; 906. a swinging rod; 907. a guide shaft; 908. a first transfer plate; 909. an adsorption assembly; 910. a cross bar; 911. a first swing rod; 912. the second swing rod; 913. raising the plate; 914. a guide wheel; 9a, a second driving device; 915. a second transfer plate; 916. an adsorption plate; 917. a guide post; 918. a limiting plate; 919. a chute; 920. and a third elastic member.

Detailed Description

The invention will now be further described with reference to the drawings and detailed description.

Referring to fig. 1 to 11, the present embodiment provides a multifunctional stone slicer, comprising a slicer rack, a collecting rack 1 arranged on the slicer rack, a transfer device 2 arranged on the slicer rack and positioned below the collecting rack 1, a guide plate 3 arranged on one lateral side of the transfer device 2, a first cutting device 4 arranged above the guide plate 3, a avoiding hole 5 arranged on the guide plate 3 and used for the first cutting device 4 to pass through, a second cutting device 6, a moving device 7 used for moving the first cutting device 4 to cut stone to the second cutting device 6, a conveying belt 8 arranged below the second cutting device 6, and a collecting device 9 arranged at the top of the conveying belt 8, the second cutting device 6 comprises a first cutting blade 601 and a second cutting blade 602 rotatably arranged on the slicing machine frame, a fixed shaft 603 rotatably arranged on the slicing machine frame, a cylinder 604 rotatably arranged outside the fixed shaft 603, a first driving device 605 for driving the cylinder 604 to rotate, a first clamping block 606 arranged on two lateral sides of the cylinder 604, a square hole 607 arranged outside the cylinder 604 and close to the first clamping block 606, a first protruding shaft 608 arranged in the cylinder 604 and close to the fixed shaft 603, a second protruding shaft 609 arranged in the cylinder 604 and close to the outer side edge, a swinging block 610 rotatably arranged on the first protruding shaft 608, a second clamping block 611 rotatably arranged on one side of the swinging block 610, a spacing groove 612 arranged on the swinging block 610 and close to the second clamping block 611, a rotating wheel 613 rotatably arranged on the spacing groove 612 on the swinging block 610, a first mounting block 614 fixedly arranged on the spacing groove 612 on the swinging block 610, a second mounting block 615 arranged on the second clamping block 611, a first elastic piece 616 arranged on the first mounting block 614 and the second mounting block 615, a third mounting block 616 arranged on the other side of the swinging block 610, the first cutting blade 601 and the second cutting blade 602 are arranged at intervals, the rotating wheel 613 is attached to the cam 620, and the distance from the second mounting block 615 to the first protruding shaft 608 is greater than the distance from the third mounting block 617 to the first protruding shaft 608.

Wherein the first driving device 605 drives the cylinder 604 to rotate, the cylinder 604 drives the first clamping block 606 on the outer side to rotate in the rotating process of the cylinder 604, the first clamping block 606 and the second clamping block 611 are at a certain interval, reference can be made to the attached drawings of the specification, then the transferring device 2 transfers the cut stone slab between the first clamping block 606 and the second clamping block 611, the cylinder 604 continues to rotate, as the first protruding shaft 608 and the second protruding shaft 609 are fixedly arranged in the cylinder 604, the swinging block 610 is driven to rotate when the cylinder 604 rotates, the rotating wheel 613 is attached to the cam 620 on the outer side of the fixed shaft 603 to rotate in the rotating process of the swinging block 610, the protruding direction of the cam 620 is close to the positions of the first cutting blade 601 and the second cutting blade 602, the first clamping block 606 on the outer side of the cylinder 604 is rotated to be close to the positions of the first cutting blade 601 and the second cutting blade 602, the contact position of the cam 620 and the rotating wheel 613 is far away from the connection position of the cam 620 and the cylinder 604, then the rotating wheel 613 is attached to the cam 620 to drive the swinging block 610 to incline and rotate towards the first clamping block 606, the swinging block 610 rotates to drive the second clamping block 611 to move towards the first clamping block 606, the first clamping block 606 and the second clamping block 611 complete clamping of the stone plate, then the first clamping block 606 and the second clamping block 611 clamp the stone plate through the first cutting piece 601 and the second cutting piece 602 along with the continued rotation of the cylinder 604, the cylinder 604 continues to rotate to cut the stone plate into the stone plate with smaller width, after the completion, the rotating wheel 613 is attached to the position of the cam 620 close to the fixed shaft 603, the swinging block 610 rotates under the action of the first elastic piece 616 and the second elastic piece 619 to drive the second clamping block 611 to move towards the opposite position of the first clamping block 606, the interval distance between the first clamping block 606 and the second clamping block 611 is enlarged, so that the stone plate is clamped continuously, through the cooperation of second cutting device 6 and transfer device 2, can be with rectangular stone material board automatic movement sideslip after the cutting of first cutting device 4, then cut into the smaller stone material board of width, this structure cutting speed of second cutting device 6 is faster, do benefit to stone material board rough machining, and it is higher to solve this problem needs the cost, and the manual work that cuts needs put the stone material board one by one, and availability factor is low, and this second cutting device 6 cuts stone material board inefficiency, and the workman only needs to throw into the stone material board on collecting frame 1 and can cut the stone material board, is fit for medium or small-scale production factory.

The transfer device 2 comprises a first rotating block 201 arranged on the slicing machine frame, a first rotating shaft 202 rotatably arranged in the middle of the first rotating block 201, a first motor 203 used for driving the first rotating shaft 202 to rotate, a guide block 204 fixedly arranged on one side, away from the first motor 203, of the first rotating shaft 202, a first connecting block 205 arranged on the slicing machine frame, a first guide pillar 206 arranged between the first connecting blocks 205, a moving column 207 arranged on the outer side of the first guide pillar 206 in a sliding manner, a transfer block 208 arranged on the outer side of the moving column 207 in a sliding manner, a second guide pillar 212 arranged in the guide block 204 in a sliding manner, a first hinging block 209 rotatably arranged on one side, close to the second guide pillar 212, of the transfer block 208, and a first spring 210 arranged between the first hinging block 209 and the first rotating block 201, wherein the first hinging block 209 is fixedly connected with one side, a through hole 1a through which a stone plate passes is arranged at the bottom of the collection frame 1, a guide hole 1b is arranged at the bottom of the collection frame 1, and an extension 211 used for passing through the through hole 1a and the guide hole 1b is arranged at the top of the transfer block 208.

By the arrangement of the cutting device, wherein the stone plates are piled on the collecting rack 1, then the first motor 203 drives the first rotating shaft 202 to rotate, the first rotating shaft 202 rotates to drive the guide block 204 to rotate, the guide block 204 drives the second guide post 212 to rotate from left to right, the second guide post 212 drives the transfer block 208 to move from one lateral side to the other side of the first guide post 206 through the first hinging block 209, the extension part 211 at the top of the transfer block 208 passes through the guide hole 1b and the perforation 1a at the bottom of the slicing machine rack, since the width and the height of the last stone plate at the bottom of the collecting rack 1 are the same as those of the perforation 1a, the extension part 211 passes through the perforation 1a to drive the stone plate to slide out from the bottom of the collecting rack 1, and since the first spring 210 is arranged between the first hinging block 209 and the guide block 204, and when the transfer block 208 moves to the middle position, the first spring 210 is compressed and pressed to the minimum, the resistance force is large, the moving speed will be reduced, the first moving speed of the stone plate at the bottom of the collecting rack 1 is reduced slowly, friction with the perforation 1a of the collecting rack 1 is reduced, the spring force ejected by the first spring 210 at the right section is reduced, when moving to the right, the first spring 210 releases the spring force, the transferring block 208 ejects right at a higher speed, a thrust force is generated to the stone plate contacted with the extension 211, the stone plate is pushed out instantly, the stone plate is prevented from staying on the guide plate 3 due to insufficient thrust force, after the completion, the first motor 203 continues to rotate, the transferring block 208 is driven to move from the top to the bottom of the moving column 207 when the guide block 204 continues to rotate, as the first rotating shaft 202 continues to rotate, the moving column 207 and the transferring block 208 move to the lower left through the first guide post 206 and then rotate through the second guide post 212, the transfer block 208 moves from the bottom to the top of the first guide pillar 206 through the first hinging block, and can avoid the perforation 1a and the guide hole 1b at the bottom of the collecting frame 1 in the back moving process, so that the stone at the bottom of the collecting frame 1 is prevented from being pushed out in the back moving process, and the stone plate can be continuously moved out through the reciprocating movement of the transfer block 208; the moving stone plate is guided downwards through the inclination of the guide plate 3, the stone plate is cut into long rectangular shapes through the first cutting device 4, then the moving device 7 moves the cut stone plate to the second cutting device 6 in a rotating way after moving downwards to the bottom, the long stone plate is cut into a plurality of short stone plates, the short stone plates are output through the conveying belt 8, and the collecting device 9 collects the short stone plates again.

The first clamping block 606 and the second clamping block 611 are rubber blocks, so that protection of the stone plate can be improved.

The moving device 7 includes a first support plate 701, a moving platform 7a for driving the first support plate 701 to move back and forth, a first gear 702 rotatably disposed on the first support plate 701, a second gear 703 meshed with the first gear 702, a second motor 704 for driving the second gear 703 to rotate, a second support plate 705 fixedly disposed on the second gear 703, a second rotating shaft 706 rotatably disposed in an end portion of the second support plate 705, a driving cylinder 707 disposed at a bottom portion of the second rotating shaft 706, a third support plate 708 disposed at a bottom portion of the driving cylinder 707, a suction cup 709 disposed in a middle portion of the third support plate 708, a third rotating shaft 710 fixedly disposed on a top surface of the first support plate 701, a first connecting piece 711 fixedly disposed at a top portion of the second rotating shaft 706, a second connecting piece 712 fixedly disposed at a top portion of the third rotating shaft 710, and a third connecting piece 713 disposed between the first connecting piece 711 and the second connecting piece 712, wherein the first gear 702 is rotatably disposed outside the third rotating shaft 710.

The moving device 7 is arranged, wherein the driving cylinder 707 drives the third supporting plate 708 to move downwards, the sucking disc 709 on the third supporting plate 708 adsorbs the cut stone slab, then the second motor 704 drives the second gear 703 to rotate, the second gear 703 rotates to drive the first gear 702 to rotate, the first gear 702 rotates to drive the second supporting plate 705 at the top to rotate, the second supporting plate 705 moves to the upper part of the rear second cutting device 6, the second connecting sheet 712 drives the first connecting sheet 711 to rotate through the third connecting sheet 713 in the rotating process of the second supporting plate 705, the first connecting sheet 711 rotates to drive the second rotating shaft 706 to rotate, the second rotating shaft 706 rotates to keep the stone slab adsorbed by the sucking disc 709 at the bottom parallel to the second cutting device 6, then the driving cylinder 707 drives the third supporting plate 708 to move downwards, the stone slab in the sucking disc 709 moves out into the second cutting device 6, then the second motor 704 drives the second supporting plate 705 to rotate through the second gear 703, the moving platform drives the first supporting plate 701 to move backwards, and the stone slab at the other side to adsorb and transfer through the third rotating shaft 710, and the stone slab 2 can keep the stone slab moving transversely to the second cutting device 6 in the state parallel to the second cutting device 6.

The collecting device 9 comprises a bottom post 901, a supporting frame 902 arranged on the bottom post 901 in a sliding manner, a driving gear 903 arranged on one side of the supporting frame 902 in a rotating manner, a second driving device 9a used for driving the driving gear 903 to rotate, a driven gear 904 arranged on one side of the supporting frame 902 in a rotating manner and meshed with the driving gear 903, a swing gear 905 arranged at the rear end of the driving gear 903, a swing rod 906 arranged at the bottom of the swing gear 905, a guide shaft 907 arranged at the bottom of the swing rod 906, a first transfer plate 908 rotationally connected with the guide shaft 907, an adsorption assembly 909 arranged at the bottom of the first transfer plate, a cross rod 910 arranged at the front end face of the driving gear 903, a first swing rod 911 and a second swing rod 912 arranged between the first transfer plate 908 and the cross rod 910 in a rotating manner, a lifting plate 913 arranged at the top of the bottom post 901, and a guide wheel 914 arranged at the outer side of the guide shaft 907 in a rotating manner, wherein the swing gear 905 is meshed with the driven gear 904, the guide wheel 914 is attached to the lifting plate 913, and the lifting plate 913 gradually inclines from left to right from bottom to top.

The setting of collection device 9, wherein absorption subassembly 909 adsorbs the stone slab that the bottom was cut, the second drive arrangement 9a drives driving gear 903 rotation, driving gear 903 rotation drives one side driven gear 904 rotation, driven gear 904 drives swing gear 905 rotation, driving gear 903 rotation 90 degrees, drive horizontal pole 910 and driven gear 904 rotation, simultaneously swing gear 905 drives first transfer board 908 and absorption subassembly 909 rotation 90 degrees through bottom swinging rod 906, the rotation in-process, because first pendulum rod 911 and second pendulum rod 912 are parallel pole, rotatory 90 degrees back, horizontal pole 910 and first transfer board 908 will laminate together, first transfer board 908 can't continue the rotation again this moment, can carry out the location to first transfer board 908, first transfer board 908 is rotatory 90 degrees back, absorption subassembly 909 is 90 degrees also, can carry out vertical collection with the stone slab, the stone slab of vertical collection is difficult to damage, be more stable in the operation process, avoid current stone slab to put in-process sideslip, the shortcoming that leads to easy damage.

The adsorption assembly 909 comprises a second transfer plate 915 slidingly arranged below the first transfer plate 908, a plurality of adsorption discs 916 arranged on the second transfer plate 915, and a guide post 917 arranged in the middle of the second transfer plate 915, wherein the guide post 917 is slidingly connected with the rear side of the second transfer plate 915, a limiting plate 918 is fixedly arranged at the top of the guide post 917, a sliding groove 919 for accommodating the limiting plate 918 is arranged at the rear side of the first transfer plate 908, and a third elastic member 920 is arranged between the limiting plate 918 and the sliding groove 919.

The adsorption assembly 909 is arranged, because the lifting plate 913 is gradually inclined from left to right, when the swinging rod 906 rotates by 90 degrees, the guide wheel 914 on one side of the swinging rod 906 is contacted with the lifting plate 913, the swinging rod 906 drives the supporting frame 902 to rise upwards, then the supporting frame 902 moves down to the first transfer plate 908 gradually close to the cut stone plate on the conveying belt 8 along with the gradual reduction of the inclination angle, then the adsorption disc 916 on the second transfer plate 915 adsorbs the stone plate on the conveying belt 8, the swinging rod 906 rotates by 90 degrees, the guide wheel 914 on one side is contacted with the lifting plate 913, the supporting frame 902 moves upwards, the second transfer plate 915 can be led to avoid the conveying belt 8 in the upward movement process, then the distance between the cross rod 910 and the first transfer plate 908 is gradually reduced, under the action of the cross rod 910, the guide rod 917 drives the second transfer plate 916 to move into the external collection box, the second transfer plate 915 conveniently transfers the cut stone plate, the rotary structure is convenient to transfer tiles, and the tile can be controlled by only a small adsorption disc 709, and the tile can be easily controlled by only needing to be rotated by a small adsorption disc 709.

Furthermore, the terms "first," "second," and the like, are used for descriptive purposes only and are not to be construed as indicating or implying a relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defining "a first" or "a second" may explicitly or implicitly include one or more such feature. In the description of the present invention, the meaning of "a plurality" is two or more, unless explicitly defined otherwise.

In the present invention, unless explicitly specified and limited otherwise, the terms "mounted," "connected," "secured," and the like are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally formed; can be directly connected or indirectly connected through an intermediate medium, and can be communicated with the inside of two elements or the interaction relationship of the two elements. The specific meaning of the above terms in the present invention can be understood by those of ordinary skill in the art according to the specific circumstances.

In the present invention, unless expressly stated or limited otherwise, a first feature "up" or "down" a second feature may be the first and second features in direct contact, or the first and second features in indirect contact via an intervening medium. Moreover, a first feature being "above," "over" and "on" a second feature may be a first feature being directly above or obliquely above the second feature, or simply indicating that the first feature is level higher than the second feature. The first feature being "under", "below" and "beneath" the second feature may be the first feature being directly under or obliquely below the second feature, or simply indicating that the first feature is less level than the second feature.

In the description of the present specification, a description referring to terms "one embodiment," "some embodiments," "examples," "specific examples," or "some examples," etc., means that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the present invention. In this specification, schematic representations of the above terms are not necessarily directed to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples. Furthermore, the different embodiments or examples described in this specification and the features of the different embodiments or examples may be combined and combined by those skilled in the art without contradiction.

While the invention has been particularly shown and described with reference to a preferred embodiment, it will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims.

Claims (6)

1. The multifunctional stone slicer is characterized by comprising a slicer rack, a collecting frame (1) arranged on the slicer rack, a transferring device (2) arranged on the slicer rack and positioned below the collecting frame (1), a guide plate (3) arranged on one lateral side of the transferring device (2), a first cutting device (4) arranged above the guide plate (3), an avoidance hole (5) arranged on the guide plate (3) and used for the first cutting device (4) to pass through, a second cutting device (6), a moving device (7) used for moving stones cut by the first cutting device (4) to the second cutting device (6), a conveying belt (8) arranged below the second cutting device (6) and a collecting device (9) arranged at the top of the conveying belt (8);

the second cutting device (6) comprises a first cutting blade (601) and a second cutting blade (602) which are rotatably arranged on the frame of the slicing machine, a fixed shaft (603) which is rotatably arranged on the frame of the slicing machine, a cylinder (604) which is rotatably arranged on the outer side of the fixed shaft (603), a first driving device (605) which is used for driving the cylinder (604) to rotate, first clamping blocks (606) which are arranged on two lateral sides of the cylinder (604), square holes (607) which are arranged on the outer side of the cylinder (604) and are close to the first clamping blocks (606), a first protruding shaft (608) which is arranged in the cylinder (604) and is close to the fixed shaft (603), a second protruding shaft (609) which is arranged in the cylinder (604) and is close to the outer side edge, a swinging block (610) which is rotatably arranged on one side of the swinging block (608), a spacing groove (612) which is arranged on the swinging block (610) and a rotating wheel (613) which is rotatably arranged on the spacing groove (612) on the swinging block (610), a first mounting block (614) which is fixedly arranged on the swinging block (610), a second mounting block (614) which is arranged on the second mounting block (615), and a second mounting block (615) which is rotatably arranged on the first mounting block (615) and a second mounting block (615) which are rotatably mounted on the first mounting block (615) and the second mounting block (mounting device) The rotary wheel (613) is attached to the cam (620) by being arranged at intervals of a third mounting block (617) arranged on the other side of the swinging block (610), a fourth mounting block (618) arranged on the outer side of the second protruding shaft (609), a second elastic piece (619) arranged between the third mounting block (617) and the fourth mounting block (618) and a cam (620) arranged on the outer side of the fixed shaft (603).

2. A multi-function stone slicer according to claim 1, wherein: the transfer device (2) comprises a first rotating block (201) arranged on the frame of the slicing machine, a first rotating shaft (202) rotatably arranged in the middle of the first rotating block (201), a first motor (203) used for driving the first rotating shaft (202) to rotate, a guide block (204) fixedly arranged on one side of the first rotating shaft (202) far away from the first motor (203), a first connecting block (205) arranged on the frame of the slicing machine, a first guide post (206) arranged between the first connecting blocks (205), a moving column (207) slidingly arranged on the outer side of the first guide post (206), a transfer block (208) slidingly arranged on the outer side of the moving column (207), a second guide post (212) slidingly arranged in the guide block (204), a first hinging block (209) rotatably arranged on one side of the transfer block (208) close to the second guide post (212), and a first spring (210) arranged between the first hinging block (209) and the first rotating block (201), the first hinging block (209) is fixedly connected with one side of the second guide post (212), the bottom of the collecting frame (1) is provided with a perforation (1 a) for a stone plate to pass through, the bottom surface of the collecting frame (1) is provided with a guide hole (1 b), and the top of the transfer block (208) is provided with an extension part (211) which is used for penetrating through the perforation (1 a) and the guide hole (1 b).

3. A multi-function stone slicer according to claim 1, wherein: the first clamping block (606) and the second clamping block (611) are rubber blocks.

4. A multi-function stone slicer according to claim 3 wherein: the moving device (7) comprises a first supporting plate (701), a moving platform (7 a) for driving the first supporting plate (701) to move back and forth, a first gear (702) rotationally arranged on the first supporting plate (701), a second gear (703) meshed with the first gear (702), a second motor (704) for driving the second gear (703) to rotate, a second supporting plate (705) fixedly arranged on the second gear (703), a second rotating shaft (706) rotationally arranged in the end part of the second supporting plate (705), a driving cylinder (707) arranged at the bottom of the second rotating shaft (706), a third supporting plate (708) arranged at the bottom of the driving cylinder (707), a sucker (709) arranged in the middle of the third supporting plate (708), a third rotating shaft (710) fixedly arranged on the top surface of the first supporting plate (701), a first connecting piece (711) fixedly arranged on the top of the third rotating shaft (710), a second connecting piece (712) fixedly arranged on the top of the third rotating shaft (710) and a third connecting piece (713) arranged between the first connecting piece (711), and the third connecting piece (713) fixedly arranged on the top of the third rotating shaft (710), and the third connecting piece (702) and the third rotating shaft (710).

5. The multi-purpose stone slicer of claim 4, wherein: the collecting device (9) comprises a bottom column (901), a supporting frame (902) arranged on the bottom column (901) in a sliding mode, a driving gear (903) arranged on one side of the supporting frame (902) in a rotating mode, a second driving device (9 a) used for driving the driving gear (903) to rotate, a driven gear (904) arranged on one side of the supporting frame (902) in a rotating mode and meshed with the driving gear (903), a swing gear (905) arranged at the rear end of the driving gear (903), a swing rod (906) arranged at the bottom of the swing gear (905), a guide shaft (907) arranged at the bottom of the swing rod (906), a first transfer plate (908) connected with the guide shaft (907) in a rotating mode, an adsorption assembly (909) arranged at the bottom of the first transfer plate, a cross rod (910) arranged on the front end face of the driving gear (903), a first swing rod (911) and a second swing rod (914) in a rotating mode, a lifting plate (913) arranged at the top of the bottom column (901) and a guide wheel (914) arranged on the outer side of the guide shaft (907), the swing gear (905) in a rotating mode, the swing gear (905) and the guide wheel (912) are meshed with the driven gear (904) from the driven gear (904) in a rotating mode, and the guide plate (913) is gradually lifted from the left side to the right side.

6. The multi-purpose stone slicer of claim 5, wherein: the adsorption component (909) comprises a second transfer plate (915) which is arranged below the first transfer plate (908) in a sliding manner, a plurality of adsorption discs (916) which are arranged on the second transfer plate (915) and a guide column (917) which is arranged in the middle of the second transfer plate (915), wherein the guide column (917) is in sliding connection with the rear side of the second transfer plate (915), a limiting plate (918) is fixedly arranged at the top of the guide column (917), a sliding groove (919) for accommodating the limiting plate (918) is formed in the rear side of the first transfer plate (908), and a third elastic piece (920) is arranged between the limiting plate (918) and the sliding groove (919).