CN116922591A - Cutting device - Google Patents

Abstract

The invention discloses a cutting device, and belongs to the technical field of cutting machines. The cutting device comprises a box body, a workbench arranged on the box body and a cutting assembly arranged on the box body, wherein the workbench comprises a bedplate for bearing a workpiece, and a first cutting groove is formed in the bedplate along a first direction; the platen is connected to the box in a sliding mode along a first direction, when the platen slides towards the cutting assembly, the cutting assembly penetrates through the first cutting groove, so that the cutting assembly cuts a workpiece on the platen, and the sliding stroke of the platen is larger than the cutting stroke of the workpiece. The cutting device provided by the invention can realize automatic cutting, prolong the cutting length and improve the cutting quality.

Description

Cutting device

Technical Field

The invention relates to the technical field of cutting machines, in particular to a cutting device.

Background

In the prior art, the platen and the cutting tool mainly comprise the following two arrangement schemes, firstly, the cutting tool is arranged on one side of the platen, when the cutting tool is used for cutting fragile workpieces to be cut such as ceramics, the cut workpieces on the side, opposite to the platen, of the cutting tool need manual support, so that the workpieces are prevented from falling on the ground and are broken, and the labor input is increased. The two platens are arranged at intervals, the cutting tool is arranged between the two platens, and the two platens are respectively used for supporting a cut workpiece without manual support; however, when the two platens are fixed respectively, the two platens have a height difference due to installation errors and the like, and a moving speed difference may exist in the moving process, so that the cutting precision is affected, and the cutting quality is poor. In addition, in the existing structure, the moving distance of the platen is the same as the cutting size of the workpiece, and errors possibly exist in the moving process of the platen to shorten the moving distance, so that the cutting size of the workpiece is difficult to meet the expected requirement.

Disclosure of Invention

The invention aims to provide a cutting device which can realize automatic cutting, prolong the cutting length and improve the cutting quality.

To achieve the purpose, the invention adopts the following technical scheme:

in one aspect, a cutting device is provided, including a case, a table disposed on the case, and a cutting assembly disposed on the case, the table including a platen for carrying a workpiece, the platen having a first cutting slot along a first direction; the platen is slidably connected to the box body along the first direction, when the platen slides towards the cutting assembly, the cutting assembly penetrates through the first cutting groove, so that the cutting assembly cuts the workpiece on the platen, and the sliding stroke of the platen is larger than that of the workpiece.

Optionally, the cutting device further comprises a driving component arranged on the box body and a power supply component for supplying power to the driving component, and the power supply component is arranged outside the box body.

Optionally, the surface of the platen has a working plane, the platen has a first projection on the working plane, and the power supply assembly has a second projection on the working plane, the second projection being located within the first projection.

Optionally, the cutting device further comprises a driving component arranged on the box body and a switch for controlling the driving component, and the switch is arranged outside the box body.

Optionally, the cutting device comprises a sliding assembly, the sliding assembly comprises a track and a sliding sleeve moving on the track, the track is connected with the box body, and the sliding sleeve is connected with the platen.

Optionally, the sliding sleeve has a movement slot through which the sliding sleeve can slide out of an end of the rail such that a sliding travel of the platen is greater than or equal to a length of the rail.

Optionally, the cutting device further comprises a main fence detachably connected to the platen, and a first side of the main fence is used for abutting against the workpiece.

Optionally, a plurality of installation positions are provided on the platen, when the main leaning gate is installed in a plurality of installation positions respectively, the first side of the main leaning gate and the first direction are arranged in different included angles, and the main leaning gate can be alternatively installed in one of the installation positions.

Optionally, a second cutting groove is concavely formed in the first side of the main leaning grid towards the second side of the main leaning grid, and when the first side of the main leaning grid is perpendicular to the first cutting groove, the second cutting groove is communicated with the first cutting groove.

Optionally, a locking component for locking the workbench is arranged on the box body, so that the workbench is static relative to the box body.

In another aspect, a cutting apparatus is provided, including a case, a table disposed on the case, and a cutting assembly disposed on the case, the table including a platen for carrying a workpiece, the platen having a first cutting slot along a first direction; the bedplate is connected to the box body in a sliding manner along the first direction, and when the bedplate slides towards the cutting assembly, the cutting assembly penetrates through the first cutting groove so that the cutting assembly cuts the workpiece on the bedplate; the cutting device further includes a power assembly having a surface with a work plane, the platen having a first projection on the work plane, the power assembly having a second projection on the work plane, the second projection being at least partially within the first projection.

The invention has the beneficial effects that:

according to the cutting device provided by the invention, the first cutting groove is formed by the two symmetrical table boards, the moving direction of the first cutting groove is the same as that of the table boards, the cutting assembly penetrates through the first cutting groove, and the table boards slide towards the cutting assembly, so that workpieces on the table boards can be automatically cut along the first direction; the sliding travel of the platen is larger than the cutting travel of the workpiece, namely the sliding travel of the platen is larger than the cutting length of the workpiece, so that the cutting length of the workpiece is increased, and the cutting size of the workpiece is ensured to meet the expected requirement. The platen is an integral structure, and the work piece is born on the platen, prevents to appear the difference in height, and can the monoblock platen remove together, prevents to appear moving speed difference, has improved cutting accuracy and cutting quality, and the work piece after the cutting is located the platen of first cutting groove both sides respectively, need not manual support or extra bearing structure, and it is more convenient to use.

Drawings

Fig. 1 is a schematic structural view of a cutting device according to a first embodiment of the present invention;

FIG. 2 is a side view of a cutting device according to a first embodiment of the present invention;

FIG. 3 is a schematic view of a stage moving process according to a first embodiment of the present invention;

FIG. 4 is a top view of a cutting device according to a first embodiment of the present invention;

FIG. 5 is a schematic view of a first perspective cutting apparatus without a table according to an embodiment of the present invention;

FIG. 6 is a schematic structural view of a sliding assembly according to a first embodiment of the present invention;

FIG. 7 is a cross-sectional view of a slide assembly according to a first embodiment of the present invention;

FIG. 8 is an exploded view of a slide assembly according to a first embodiment of the present invention;

FIG. 9 is a schematic view of a cutting apparatus with a partial table according to a first embodiment of the present invention;

FIG. 10 is a schematic view of a second perspective cutting apparatus without a table according to a first embodiment of the present invention;

FIG. 11 is a schematic view of an elastic assembly according to a first embodiment of the present invention mounted on a platen;

FIG. 12 is a schematic view of a bottom side structure of a workbench according to a first embodiment of the invention;

FIG. 13 is an enlarged view of FIG. 12 at I;

FIG. 14 is a schematic view of a top side structure of a table according to a first embodiment of the present invention;

FIG. 15 is an enlarged view of FIG. 12 at II;

FIG. 16 is a cross-sectional view of an angle adjuster and a primary grid according to a first embodiment of the present invention;

FIG. 17 is a schematic view of the bottom side of a main backrest according to a first embodiment of the present invention;

FIG. 18 is an enlarged view at III of FIG. 17;

FIG. 19 is a schematic view of the top side of a main gate according to an embodiment of the present invention;

FIG. 20 is a cross-sectional view A-A of FIG. 19;

FIG. 21 is a B-B cross-sectional view of FIG. 19;

FIG. 22 is an enlarged view at IV of FIG. 14;

FIG. 23 is a schematic view of a first adjusting assembly according to a first embodiment of the present invention;

fig. 24 is an enlarged view at v of fig. 12;

FIG. 25 is a schematic view of a second adjusting assembly according to a first embodiment of the present invention;

FIG. 26 is an enlarged view at VI of FIG. 12;

FIG. 27 is a schematic view of a second adjustment assembly provided in accordance with a first embodiment of the present invention mounted on a platen;

FIG. 28 is a schematic view of a structure of an auxiliary backrest on a platen according to a first embodiment of the present invention;

FIG. 29 is an enlarged view at VII of FIG. 10;

FIG. 30 is an exploded view of a cutting device upper heel assembly according to one embodiment of the present invention;

FIG. 31 is an enlarged view at VIII of FIG. 30;

FIG. 32 is a schematic view of a third perspective cutting apparatus without a table according to an embodiment of the present invention;

FIG. 33 is a C-C cross-sectional view of FIG. 32;

FIG. 34 is a D-D sectional view of FIG. 32;

FIG. 35 is an enlarged view at IX of FIG. 34;

FIG. 36 is a partial view of a heel knife assembly according to one embodiment of the present invention;

FIG. 37 is an exploded view of the heel knife assembly from one perspective provided by the first embodiment of the present invention;

FIG. 38 is an exploded view of the heel knife assembly from another perspective provided by the first embodiment of the present invention;

FIG. 39 is a schematic view of a cutting apparatus without a table according to a seventh embodiment of the present invention;

fig. 40 is an enlarged view at x of fig. 39.

In the figure:

1. a work table; 11. a platen; 111. a first cutting groove; 112. a mounting hole; 113. a finger lead; 114. identification; 115. a plug-in groove; 116. a limit part; 1161. a protrusion; 117. a via hole; 12. a protection block; 13. a main leaning gate; 131. a second cutting groove; 132. a protrusion; 133. an L-shaped operating member; 134. a spring plate; 135. a jack; 14. an auxiliary leaning grid; 141. a splicing boss; 15. an angle adjuster; 151. a housing; 16. a first adjustment assembly; 161. an adjusting pin; 1611. the outer edge is convex; 162. a rotating wheel; 163. a plug pin; 17. a second adjustment assembly; 171. a rotation shaft; 172. an operating member; 173. a limiting shaft; 174. a spring; 18. a bracket;

2. a case; 21. a cross bar; 22. a baffle; 3. a cutting assembly; 31. a cutting member; 32. a limiting block; 33. a heel knife assembly; 331. a follower rest; 3311. a heel seat body; 3312. a first mounting boss; 33121. limiting slotting; 33122. a limit protrusion; 3313. a second mounting boss; 33131. limiting through holes; 3314. a second identification protrusion; 332. a knife following plate; 3321. a first connection hole; 3322. a second connection hole; 333. an adapter; 3331. a first elongated aperture; 3332. a boss; 341. a water baffle; 342. an upper shield; 335. an L-shaped cutter following plate; 35. a locking assembly; 351. a locking shaft; 3511. a first connection portion; 3512. a second connecting portion; 352. an elastic baffle; 353. a handle; 3531. a first identification protrusion;

4. A power supply assembly; 5. a switch;

6. a sliding assembly; 61. a track; 611. a connection part; 62. a sliding sleeve; 62A, a motion groove; 621. a bearing body; 6211. a mounting groove; 6212. a first slot; 622. a ball; 623. a spacer; 6231. a third slot; 624. a housing; 6241. ear plates; 6242. a second slot; 625. a blocking cylinder;

71. a first guide rail; 72. a second guide rail;

8. an elastic component; 81. an elastic member; 82. a fixing frame;

9. a locking assembly.

Detailed Description

In order to make the technical problems solved by the present invention, the technical solutions adopted and the technical effects achieved more clear, the technical solutions of the embodiments of the present invention will be described in further detail below with reference to the accompanying drawings, and it is obvious that the described embodiments are only some embodiments of the present invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

In the description of the present invention, unless explicitly stated and limited otherwise, the terms "connected," "connected," and "fixed" are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally formed; can be mechanically or electrically connected; 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 will be understood in specific cases by those of ordinary skill in the art.

In the present invention, unless expressly stated or limited otherwise, a first feature "above" or "below" a second feature may include both the first and second features being in direct contact, as well as the first and second features not being in direct contact but being in contact with each other through additional features therebetween. Moreover, a first feature being "above," "over" and "on" a second feature includes the first feature being directly above and obliquely above the second feature, or simply indicating that the first feature is higher in level than the second feature. The first feature being "under", "below" and "beneath" the second feature includes the first feature being directly under and obliquely below the second feature, or simply means that the first feature is less level than the second feature.

Example 1

The embodiment provides a cutting device, which comprises a box body 2, a workbench 1 arranged on the box body 2 and a cutting assembly 3 arranged on the box body 2, and can be used for cutting workpieces such as ceramic tiles.

Specifically, as shown in fig. 1, the table 1 includes a platen 11 for carrying a workpiece, the platen 11 being provided with a first cutting groove 111 in a first direction; the platen 11 is slidably connected to the case 2 along a first direction, when the platen 11 slides toward the cutting assembly 3, the cutting assembly 3 is disposed through the first cutting slot 111, so that the cutting assembly 3 cuts the workpiece on the platen 11, and the sliding stroke of the platen 11 is greater than the cutting stroke of the workpiece.

The first cutting groove 111 is formed by two symmetrical platens 11, the moving direction of the platens 11 is the same, the cutting assembly 3 is arranged in the first cutting groove 111 in a penetrating mode, and the platens 11 slide towards the cutting assembly 3, so that workpieces on the platens 11 can be automatically cut in the first direction; because the sliding travel of the platen 11 is larger than the cutting travel of the workpiece, that is, the sliding travel of the platen 11 is larger than the cutting length of the workpiece, the cutting length of the workpiece is increased, and the cutting size of the workpiece is ensured to meet the expected requirement. The platen 11 is an integral structure, the workpiece is supported on the platen 11, the height difference is prevented, the whole platen 11 can move together, the moving speed difference is prevented, the cutting precision and the cutting quality are improved, the cut workpiece is respectively positioned on the platens 11 on two sides of the first cutting groove 111, manual support or an additional support structure is not needed, and the use is more convenient.

In this embodiment, as shown in fig. 1, the first direction is the X direction, the second direction is the Y direction, the third direction is the Z direction, and the first direction, the second direction and the third direction are perpendicular to each other. Further, in this embodiment, the first direction is a front-back direction of the cutting device, the second direction is a left-right direction of the cutting device, and the third direction is an up-down direction of the cutting device.

Typically, the sliding travel of the platen 11 is slightly greater than the cutting travel of the workpiece, alternatively, the sliding travel of the platen 11 may be 3 inches, 4 inches, 5 inches to 10 inches greater than the cutting travel of the workpiece.

Optionally, as shown in fig. 2, the cutting device further includes a driving assembly provided on the case 2 and a power supply assembly 4 for supplying power to the driving assembly, and the driving assembly is used for driving the platen 11 to reciprocate in the first direction. Specifically, the power supply assembly 4 is arranged outside the box body 2, so that on one hand, when the power supply assembly 4 needs to be connected with a power supply, the operation is convenient, and on the other hand, the internal space of the box body 2 is compact, and the power supply assembly 4 is arranged outside, so that the layout is convenient. In other embodiments, the platen 11 may be manually pushed to reciprocate, which is not limited.

Optionally, referring to fig. 1 to fig. 4, the surface of the platen 11 has a working plane, the platen 11 has a first projection on the working plane, the power component 4 has a second projection on the working plane, and the second projection is located in the first projection, so that the power component 4 is prevented from protruding out of the platen 11 along the second direction or the third direction, and the compactness of the structure is improved; during the movement of the platen 11, the second projection of the power supply assembly 4 mounted on the case 2 is always ensured to be in the first projection, so as to limit the movement distance of the platen 11 and prevent the platen 11 from slipping due to overlarge sliding distance. Specifically, the power supply assembly 4 is disposed below the platen 11, and the power supply assembly 4 is disposed at a distance from the lower surface of the platen 11 to prevent the power supply assembly 4 from interfering with the platen 11 during movement.

Optionally, as shown in fig. 2, the cutting device further includes a driving component disposed on the case 2 and a switch 5 for controlling the driving component, the driving component is started and stopped conveniently by setting the switch 5, and the switch 5 is disposed outside the case 2, so as to facilitate operation. Specifically, with reference to fig. 2-4, the switch 5 has a third projection on the working plane, the third projection is in the first projection, the switch 5 is prevented from protruding from the platen 11 along the second direction or the third direction, the compactness of the structure is improved, and the switch 5 is located on the box 2 and is arranged at a distance from the platen 11, so that interference can not occur.

In this embodiment, the device further includes a transmission assembly (not shown in the figure), the transmission assembly adopts a gear and rack structure, for example, the gear is rotatably connected to the box 2, a rack is fixed on the platen 11 on the workbench 1, the rack and the gear are meshed for transmission, the driving assembly includes a motor (not shown in the figure), the motor drives the gear to rotate, and drives the rack to move, so that the movement of the platen 11 is realized, and the travel of the platen 11 is not limited by the gear and the rack.

Specifically, as shown in fig. 1, the case 2 is provided with a bar 21, and the bar 21 can be supported on the ground, and in addition, the bar 21 can also be used as a handle, and when the cutting device is moved, the bar 21 can be held for movement. Specifically, the case 2 may be provided with a bar 21 in front of and behind and/or in the left and right thereof.

Specifically, as shown in fig. 5, a housing chamber is formed in the case 2, and a liquid is provided in the housing chamber for dust-proofing the workpiece to be cut.

Alternatively, as shown in fig. 5 to 7, the cutting device comprises a sliding assembly 6, the sliding assembly 6 comprises a rail 61 and a sliding sleeve 62 moving on the rail, and the rail 61 is connected with the case 2; sliding sleeve 62 is connected with workbench 1; the sliding sleeve 62 moves along the rail 61, so that the movement precision of the workbench 1 is improved, deflection is prevented, and the cutting precision of a workpiece on the workbench 1 is further improved. In this embodiment, the rail 61 is provided to extend in the first direction. Specifically, the sliding sleeve 62 is provided with a movement groove 62A, the sliding sleeve 62 can slide out of the end of the track 61 through the movement groove 62A, and the sliding stroke of the sliding sleeve 62 on the track 61 is increased, so that the sliding stroke of the workbench 1 is greater than or equal to the length of the track 61, namely, the sliding stroke of the workbench 1 is greater than the cutting length of a workpiece, thereby increasing the cutting length of the workpiece and ensuring that the cutting size of the workpiece meets the expected requirement.

Specifically, referring to fig. 6 and 7, the rail 61 has a connection portion 611, and the rail 61 is provided on the case 2 through the connection portion 611; the sliding sleeve 62 is sleeved on the rail 61, the sliding sleeve 62 is slidably connected with the rail 61, and the moving groove 62A can pass through the connecting part 611. During the movement, the connection portion 611 does not limit the movement of the movement groove 62A, so that at least part of the sliding sleeve 62 can pass through the connection portion 611 to slide out of the connection portion 611 of the rail 61, thereby prolonging the stroke length of the sliding sleeve 62 and ensuring the sliding stroke of the platen 11 on the table 1.

In this embodiment, referring to fig. 7 and 8, the sliding sleeve 62 includes a bearing body 621, the bearing body 621 has a first slot 6212, the first slot 6212 forms part of the movement slot 62A, the first slot 6212 is provided with a ball 622 at a contact point with the track 61, and by providing the ball 622, sliding friction between the bearing body 621 and the track 61 is changed into rolling friction, so that friction force between the sliding sleeve 62 and the track 61 is reduced, and service life is prolonged.

Specifically, referring to fig. 7 and 8, the inner wall of the bearing body 621 is adapted to the outer shape of the rail 61, and the bearing body 621 is circumferentially limited to the rail 61; further, a plurality of mounting grooves 6211 are formed in the inner wall of the bearing body 621, a plurality of rows of balls 622 are arranged in the mounting grooves 6211, and a row of balls 622 are arranged in each mounting groove 6211, so that the number of the balls 622 is increased, and friction force is further reduced.

Optionally, referring to fig. 7 and 8, the sliding sleeve 62 further includes a housing 624, the housing 624 having a second slot 6242, the housing 624 being sleeved on the outer periphery of the bearing body 621, the second slot 6242 forming part of the movement slot 62A, the housing 624 being for connection with the table 1; on the one hand, by the cooperation of the housing 624 and the bearing body 621, the housing 624 is connected to the table 1, and the bearing body 621 is slidably connected to the rail 61, thereby realizing the sliding connection of the table 1 to the rail 61; in addition, in order to facilitate processing of the bearing body 621, the length of the bearing body 621 may be reduced, and a plurality of bearing bodies 621 may be provided, where the plurality of bearing bodies 621 are all provided in the same housing 624 to form an integral structure, so as to facilitate installation.

Because the structure of the bearing body 621 is complex and the processing cost is high, further, the sliding sleeve 62 further comprises a spacing frame 623, the spacing frame 623 and the bearing body 621 are respectively penetrated in the shell 624 along the central line direction of the shell 624, the spacing frame 623 is penetrated in the track 61, the spacing frame 623 is provided with a third slot 6231, the third slot 6231 forms part of the moving slot 62A, and the number of the used bearing bodies 621 is reduced by arranging the spacing frame 623, so that the cost is reduced; further, the spacer 623 may be slidably coupled to the rail 61 to improve sliding stability, or the spacer 623 may be uncoupled from the rail 61 to reduce friction.

Alternatively, the plurality of bearing bodies 621 and the plurality of spacers 623 may be disposed at intervals from each other according to the use requirement; in this embodiment, two bearing bodies 621 are provided, and a spacer 623 is provided between the two bearing bodies 621.

Alternatively, referring to fig. 7 and 8, the outer periphery of the housing 624 is provided with an ear plate 6241, the ear plate 6241 is provided with a mounting hole, and a fastener passes through the mounting hole and a connection hole on the table 1, so that the ear plate 6241 is connected with the table 1, and the detachable connection is performed by the fastener, so that the disassembly and assembly are convenient.

Optionally, referring to fig. 6 and 8, the sliding sleeve 62 further includes a blocking barrel 625 that can be sleeved on the track 61, where the blocking barrel 625 is connected to an end of the housing 624, the blocking barrel 625 abuts against the bearing body 621, and the blocking barrel 625 is used for limiting an axial direction of the bearing body 621, so as to avoid slipping between the bearing body 621 and the housing 624.

Specifically, as shown in fig. 7, the connection portion 611 is a support block protruding from the outer periphery of the rail 61, the support block is fixed to the case 2, and the notch size of the movement groove 62A is larger than the width size of the support block.

Alternatively, as shown in fig. 5, the sliding assembly 6 is provided with a plurality of rails 61 arranged in parallel, and a support block is fixed to the side wall of the case 2, and at least one sliding sleeve 62 is provided on each rail 61. In this embodiment, two rails 61 are provided on the case 2, two sliding sleeves 62 are provided on each rail 61, the two sliding sleeves 62 are symmetrically and alternately arranged, and the two sliding sleeves 62 can respectively extend out of two ends of the rail 61; specifically, two rails 61 are disposed on two sides of the cutting assembly 3, and sliding sleeves 62 on the two rails 61 are respectively connected with the platen 11 on the workbench 1, so that the platen 11 is uniformly stressed, and the sliding sleeves 62 are prevented from interfering with the cutting assembly 3.

Optionally, the cutting device further includes an adjusting block, a cam-shaped adjusting block is disposed on a side surface of the track 61, the adjusting block rotates to drive the track 61 to adjust a position along the second direction, and the distance between the adjusting block and the cutting assembly 3 is adjusted, and the platen 11 is connected to the sliding sleeve 62, so that parallelism between the platen 11 and the cutting assembly 3 can be adjusted, and cutting accuracy is improved.

Optionally, the housing 2 is provided with a locking assembly 9 for locking the table 1, so that the table 1 is stationary relative to the housing 2, which is particularly suitable when the cutting device is used for transporting, storing or cutting long workpieces without the movement of the table 11. Specifically, as shown in fig. 5, the outer case 2 is provided with a rib position with inclination and a locking pin with a spring, the rib position is provided with a first mounting hole, the platen 11 is provided with a second mounting hole, the locking pin can be arranged through the first mounting hole and the second mounting hole so that the platen 11 is fixed on the outer case 2, and the platen 11 is locked against sliding. The locking pin is pressed by the spring to press the rib, the rib with inclination can provide a fuzzy alignment function in a certain range, and the first mounting hole can be automatically aligned in a certain range, so that the operation is convenient.

In this embodiment, the cutting device includes a guide rail assembly, as shown in fig. 5 and 9, between the table 1 and the case 2, the guide rail assembly is disposed along the first direction, and is used together with the sliding assembly 6 to improve the sliding accuracy of the table 1 on the case 2 along the first direction. Specifically, as shown in fig. 5, the guide rail assembly includes a first guide rail 71 provided to the table 1 and a second guide rail 72 provided to the case 2, the first guide rail 71 and the second guide rail 72 being engaged and having a relative motion; further, one of the first guide rail 71 and the second guide rail 72 is provided with a guide boss, and the other is provided with a guide groove matched with the guide boss.

Optionally, as shown in fig. 10-13, the cutting device further comprises a resistance mechanism; specifically, the resistance mechanism comprises an elastic component 8 and a baffle 22, one of the elastic component 8 and the baffle 22 is arranged on the box body 2, the other is arranged on the workbench 1, when the workbench 1 moves to a preset position, the elastic component 8 is abutted against the baffle 22, and in the process of moving the workbench 1 from the preset position to the extreme limit position, the elastic component 8 and the baffle 22 are extruded to provide resistance for the workbench 1.

By providing the elastic component 8 and the baffle 22, when the workbench 1 slides to a preset position, the elastic component 8 and the baffle 22 start to contact, and as the workbench 1 continues to slide, extrusion occurs between the elastic component 8 and the baffle 22, and the extrusion force gradually increases. In the process of moving the workbench 1 from a preset position along the X negative direction, the elastic component 8 and the baffle 22 provide gradually increased resistance, so that the speed of a workpiece arranged on the workbench 1 relative to the cutting component 3 on the box body 2 is reduced, the impact force between the cutting component 3 and the workpiece is reduced, the operation is more stable, and the angle of collapse of the cutting piece 31 on the cutting component 3 when the cutting is finished due to improper operation is reduced; simple structure and convenient assembly.

Optionally, the elastic component 8 includes an elastic member 81, where a fixed end of the elastic member 81 is fixed on the workbench 1 or the box 2, and the elastic member 81 may be a spring or other structure, so that the use is convenient. Optionally, the elastic component 8 further includes a fixing frame 82, the elastic member 81 is fixed on the fixing frame 82, the fixing frame 82 is connected to the workbench 1 or the box 2, and the elastic member 81 faces the baffle 22.

Alternatively, the workbench 1 comprises a bedplate 11, one of the elastic component 8 and the baffle 22 is arranged on the side of the bedplate 11 facing the box body 2, and the resistance mechanism is arranged between the bedplate 11 and the sliding surface of the box body 2, so that the structure is prevented from being exposed, and the structure is more compact.

In this embodiment, as shown in fig. 13, the elastic member 81 is fixed to the fixing frame 82, the fixing frame 82 is connected to a side of the platen 11 facing the case 2 by a fastener, and the case 2 is provided with the baffle 22.

Optionally, the distance between the preset position and the limit position is 10mm-15mm, and the distance is too large to influence the overall cutting speed and too small to play a role in preventing the angle collapse.

Optionally, the resistance is 10N-50N, and is too large, so that the cutting difficulty is increased, the overall cutting effect is affected, and the resistance is too small to play a role in preventing angle collapse; preferably, the resistance is 30N.

Optionally, as shown in fig. 1, 2 and 4, a protecting block 12 is detachably connected to one end of the platen 11, and the protecting block 12 can be plugged into the first cutting groove 111, specifically, when the workpiece is cut, the user is located on a side of the case 2 facing away from the protecting block 12. When the platen 11 does not move or moves away from the user, the protection block 12 moves along with the platen 11, so that the structure of the platen 11 can be reinforced; the protective block 12 may be detachable to avoid the cutting assembly 3 when the platen 11 is moved toward the user, or the protective block 12 may be rotatable about an axis parallel to the first direction to avoid the cutting assembly 3.

Optionally, as shown in fig. 1, 3 and 4, the cutting device further includes a main leaning gate 13, where the main leaning gate 13 is detachably connected to the platen 11, a first side of the main leaning gate 13 is used to lean against the workpiece, when the platen 11 slides towards the cutting assembly 3, the cutting assembly 3 will have a force on the workpiece on the platen 11, which is away from the moving direction of the platen 11, and the main leaning gate 13 leans against the workpiece, so that the workpiece can be prevented from moving backwards when being stressed, and the cutting reliability and the cutting precision can be prevented from being affected.

Alternatively, as shown in fig. 1 and fig. 4, a second cutting groove 131 is concavely formed on a first side of the main leaning gate 13 toward a second side of the main leaning gate 13, when the first side of the main leaning gate 13 is perpendicular to the first cutting groove 111, that is, the first side forms a 90 ° angle with the first cutting groove 111, the second cutting groove 131 is communicated with the first cutting groove 111; when the sliding travel of the platen 11 exceeds the cutting travel of the workpiece, the cutting assembly 3 is arranged in the second cutting groove 131 in a penetrating manner, so that the influence of the main leaning gate 13 on the cutting formation of the platen 11 is avoided, and the damage of the main leaning gate 13 caused by cutting on the main leaning gate 13 when the sliding travel of the platen 11 exceeds the cutting travel of the workpiece is avoided. Specifically, the length of the second cutting groove 131 in the first direction is not less than the size by which the sliding stroke of the platen 11 exceeds the cutting stroke of the workpiece.

Further, as shown in fig. 1, the second side of the main leaning board 13 is convexly provided with a protrusion 132, the second cutting groove 131 extends to the protrusion 132, the main leaning board 13 has a narrower structure, and the protrusion 132 can prevent the main leaning board 13 from being divided into two parts by the second cutting groove 131, so that the main leaning board 13 is still in an integral structure, and is convenient and reliable.

Optionally, as shown in fig. 14 and 15, the platen 11 is further provided with an angle adjuster 15, and the main rest 13 adjusts its position on the platen 11 through the angle adjuster 15, so that the installation accuracy of the main rest 13 is improved, the installation accuracy of the workpiece is improved, and the cutting accuracy of the workpiece is further improved.

Alternatively, as shown in fig. 15 and 16, the angle adjuster 15 has a housing 151, the main support 13 is rotatably connected to a first connection plate of the L-shaped operation member 133, a second connection plate of the L-shaped operation member 133 abuts against the housing 151, a spring 134 is further fixed on the main support 13, the spring 134 abuts against the first connection plate, when the installation position of the main support 13 needs to be adjusted, the second connection plate is lifted upwards to separate the main support 13 from the angle adjuster 15, and after the adjustment is completed, the second connection plate is put down to abut against the housing 151 to fix the angle adjuster 15 and the main support 13, so that the movement of the main support 13 is prevented from affecting the installation accuracy.

Alternatively, as shown in fig. 14 and fig. 16 to 19, the workbench 1 comprises a bedplate 11 for placing a workpiece and a main leaning grid 13 arranged on the bedplate 11, wherein the main leaning grid 13 is used for limiting the workpiece; the table 1 further comprises a first adjustment assembly 16 and a second adjustment assembly 17; specifically, the first adjusting component 16 includes a fixed end detachably connected to the platen 11, the main backrest 13 can rotate around the fixed end of the first adjusting component 16 to adjust an angle, and the first adjusting component 16 can be fixed with the main backrest 13; the second adjustment assembly 17 is detachably connected to the platen 11, and the main boom 13 can be fixed to the platen 11 by the second adjustment assembly 17.

When the main backrest 13 is used, firstly, the fixed end of the first adjusting component 16 is connected to the bedplate 11, and the second adjusting component 17 is detached from the bedplate 11; afterwards, the main leaning gate 13 rotates around the fixed end of the first adjusting component 16 to adjust the angle meeting the requirement; finally, the first adjusting assembly 16 is fixed to the main rest 13, and the main rest 13 is fixed to the platen 11 by the second adjusting assembly 17. The main leaning gate 13 rotates around the first adjusting component 16 to achieve fine adjustment of the position of the main leaning gate 13 relative to the bedplate 11, and then the first adjusting component 16 and the second adjusting component 17 lock the main leaning gate 13 on the bedplate 11, so that the installation precision of the main leaning gate 13 is improved, the cutting precision is improved, and the cutting quality is further improved.

In this embodiment, as shown in fig. 4, 20 and 22-24, the first adjusting assembly 16 includes a rotating wheel 162 and an adjusting pin 161, the rotating wheel 162 is fixed on the main backrest 13, one end of the adjusting pin 161 is connected to the platen 11, the rotating wheel 162 is rotatably connected to the other end of the adjusting pin 161, and the adjusting pin 161 is eccentrically disposed in the rotating wheel 162; specifically, the platen 11 is provided with a mounting hole 112, and the mounting hole 112 is penetrated by an adjustment pin 161. When the device is used, the adjusting pin 161 is fixed on the platen 11, the main leaning gate 13 is connected to the rotating wheel 162, the main leaning gate 13 is operated, the rotating wheel 162 is driven by the main leaning gate 13 to rotate on the adjusting pin 161, the main leaning gate 13 rotates relative to the platen 11, an angle exists in rotation, and the aim of adjusting the angle is to adjust the angle between the main leaning gate 13 and the cutting piece 31, and the angle perpendicularity between the main leaning gate 13 and the cutting piece 31 is a key parameter.

In other embodiments, the first adjustment assembly 16 includes a runner 162 and an adjustment pin 161, and the primary boom 13 is secured to the runner 162; one end of the adjustment pin 161 is connected to the platen 11, the rotation wheel 162 is rotatably connected to the other end of the adjustment pin 161, and the centroid of the adjustment pin 161 is not on the center axis of the rotation wheel 162, for example, the rotation wheel 162 has an eccentric shape.

Optionally, as shown in fig. 20 and fig. 22-24, the first adjusting assembly 16 further includes a plug 163, and the main backrest 13 is provided with a jack 135, and the plug 163 can be connected with the adjusting pin 161 through the jack 135. The bolt 163 is inserted into the insertion hole 135 of the main leaning grid 13 to fix the main leaning grid 13, the first adjusting component 16 and the bedplate 11 together; simple structure and convenient operation.

Further, an outer edge protrusion 1611 is provided on the top of the adjustment pin 161, and the outer edge protrusion 1611 is fixed on the main backrest 13 to achieve axial limitation.

Alternatively, as shown in fig. 18, 21, 25-27, the second adjustment assembly 17 includes a rotation shaft 171 and a limiting shaft 173, which are rotated relative to the main grid 13 in operation, one end of the rotation shaft 171 passing through the main grid 13 and the platen 11 and protruding out of the platen 11; the limiting shaft 173 is connected to one end of the rotating shaft 171 extending out of the platen 11, and the platen 11 is provided with a limiting portion 116, the limiting portion 116 is used for limiting rotation of the limiting shaft 173 and the rotating shaft 171, and when the limiting shaft 173 is limited by the limiting portion 116, circumferential limiting fixation is achieved.

Specifically, referring to fig. 21 and 24, the second adjusting assembly 17 includes an operating member 172 and a spring 174, the operating member 172 being connected to the other end of the rotation shaft 171, the operating member 172 being capable of abutting against the side of the main rest 13 facing away from the platen 11; the spring 174 is sleeved on the rotating shaft 171, one end of the spring 174 is propped against the operating member 172, the other end of the spring 174 can be propped against the platen 11, the limiting shaft 173 can be separated from the limiting portion 116 by the compression spring 174, the spring 174 automatically bounces, and the limiting shaft 173 automatically props against the limiting portion 116 along the axial direction to realize limiting. When the rotation shaft 171 continues to move downward under the action of the operation member 172, the limiting shaft 173 passes over the limiting portion 116 and reaches the through hole 117, and then is retracted to the main fence 13.

Specifically, as shown in fig. 26, the platen 11 has a through hole 117, the limiting portion 116 includes two protrusions 1161 protruding on the platen 11, a communication groove communicating with the through hole 117 is formed on a side of the two protrusions 1161 facing each other, and a limiting groove is formed on a side of the two protrusions 1161 facing away from each other for limiting the limiting shaft 173.

Specifically, as shown in fig. 28, the platen 11 is provided with a first cutting slot 111 along a first direction, the cutting assembly 3 can pass through the first cutting slot 111, the platen 11 is provided with a plurality of first mounting positions along a second direction, the workbench 1 further comprises a secondary leaning gate 14 detachably connected to the platen 11, a working surface of the secondary leaning gate 14 is arranged at an included angle with a working surface of the platen 11, and the secondary leaning gate 14 can be alternatively mounted at one of the first mounting positions. Allowing the beveled workpiece to be moved in a direction perpendicular to the cutting assembly 3 for quick positioning.

Specifically, the secondary grill 14 is supported on the platen 11 by a bracket 18. Specifically, the 2.5mm scale increment chamfer can be provided, and a better precision controllable decorative chamfer cutting function is provided for a user. Specifically, the platen 11 is provided with a plurality of inserting grooves 115 along the second direction, the bottom of the auxiliary backrest 14 is provided with inserting bosses 141, and the inserting bosses 141 can be optionally inserted into one inserting groove 115 for position adjustment. Further, the insertion groove 115 is a through hole, so that dust is prevented from accumulating in the insertion groove 115, and cleaning is facilitated.

Alternatively, as shown in fig. 10, 29-31, the cutting assembly 3 includes a cutting member 31 and a follower assembly 33, the cutting member 31 rotating about an output shaft, the cutting member 31 being alternatively provided to the output shaft; at least part of the heel knife assembly 33 is arranged at the rear side of the cutting member 31, the heel knife assembly 33 is capable of moving between at least a first position and a second position along a first direction relative to the case 2, and when the heel knife assembly 33 moves from the first position to the second position, the distance between the heel knife assembly 33 and the output shaft increases.

The heel knife assembly 33 can move between a first position and a second position along a first direction, the distance between the heel knife assembly 33 and the output shaft is adjusted, the distance between the heel knife assembly 33 and the cutting piece 31 is further adjusted, the mounting position of the heel knife assembly 33 can be adjusted according to the cutting piece 31, the cutting piece 31 is prevented from cutting the heel knife assembly 33, and the reliability is improved; the first and second positions may be specifically set according to the size of the cutting member 31 and the heel knife assembly 33. The position of the heel knife assembly 33 corresponds to the cutting member 31, so that the heel knife assembly 33 is spaced apart from the corresponding cutting member 31 by a predetermined distance, and the cutting member 31 is prevented from cutting the heel knife assembly 33.

Alternatively, the cutting member 31 comprises at least a first cutting member and a second cutting member of different sizes, the first cutting member being mounted to the output shaft when the heel knife assembly 33 is in the first position and the second cutting member being mounted to the output shaft when the heel knife assembly 33 is in the second position. In this embodiment, the cutting members 31 are saw blades, 7 inch saw blades and 8 inch saw blades, respectively. In other embodiments, a plurality of cutting members 31 may be provided, where the size of the plurality of cutting members 31 is between the size of the first cutting member and the size of the second cutting member, and a plurality of mounting positions are correspondingly provided between the first position and the second position, so as to further improve applicability. Optionally, the heel knife assembly 33 includes a limiting device, and when the heel knife assembly 33 moves to the second position, the limiting device limits the heel knife assembly 33 to move towards the first position, and by setting the limiting device, the installation reliability and the installation precision of the heel knife assembly 33 are improved.

Optionally, as shown in fig. 29, the heel knife assembly 33 is disposed on a mounting seat of the box 2, the limiting device includes a plurality of limiting blocks 32, the mounting seat is provided with a plurality of accommodating grooves along a first direction, each limiting block 32 can extend or retract in the accommodating groove, the heel knife assembly 33 can lean against a side surface of the extending limiting block 32, the heel knife assembly 33 is limited at a corresponding position of the mounting seat through the corresponding limiting block 32, and the size of the heel knife assembly 33 away from the output shaft can be limited according to the size of the limiting block 32. In this embodiment, a limiting block 32 is provided, when the limiting block 32 extends out of the accommodating groove, the heel knife assembly 33 is located at the second position, the heel knife assembly 33 abuts against the side surface of the limiting block 32, and when the limiting block 32 retracts into the accommodating groove, the heel knife assembly 33 is located at the first position.

Specifically, stopper 32 passes through spring coupling in the storage tank, and when the stopper 32 of unnecessary relevant position is spacing, presses stopper 32 in the storage tank through the mount pad, and when the stopper 32 is spacing when needs, the output shaft direction removal is kept away from, removes the top of corresponding stopper 32, makes stopper 32 pop out, carries out new spacing, convenient and reliable. At this time, the limiting block 32 also has fool-proof effect, if the user forgets to adjust the limiting block 32, cutting risk can occur, and when the installation seat is moved, the limiting block 32 can automatically pop up, so that the error of the installation position of the cutter following component 33 is avoided.

Optionally, as shown in fig. 31, the heel knife assembly 33 includes an adapter 333 and a heel knife plate 332 disposed on the adapter 333, the adapter 333 is adjustably mounted on a mounting seat of the case 2 along a first direction, the heel knife plate 332 is disposed on one side of the cutting member 31 along the first direction, and a predetermined distance is kept between the heel knife plate 332 and the corresponding cutting member 31, so as to avoid damage caused by cutting the cutting member 31 onto the heel knife plate 332.

Optionally, a first adjusting structure is disposed on the adapter 333, and the adapter 333 is adjustably mounted on the mounting base through the first adjusting structure, so that the adapter 333 is convenient to adjust the mounting position on the mounting base.

Specifically, as shown in fig. 29 and 31, the first adjusting structure includes two first elongated holes 3331 formed on the adapter 333, the first elongated holes 3331 are formed in a first direction along a length direction of the adapter, the adapter is formed on the adapter, and fasteners are inserted into the first elongated holes 3331 and the adapter holes to fix the adapter 333 on the adapter, and the adapter 333 moves along the first direction through the first elongated holes 3331 to be adjusted, and the adapter 333 and the adapter are detachably connected by the fasteners to facilitate adjustment.

Optionally, as shown in fig. 29 and 31, the heel knife assembly 33 further includes a heel knife holder 331, and the heel knife plate 332 and the adapter 333 are connected by the heel knife holder 331, and the heel knife holder 331, the heel knife plate 332 and the adapter 333 are separately arranged, so as to facilitate processing and use.

Optionally, the contact surface between the follower rest 331 and the adapter 333 is not greater than 1mm, so as to improve the mounting accuracy between the follower rest 331 and the adapter 333. Optionally, one of the adapter 333 and the follower 331 is formed with a boss 3332, and the other is correspondingly formed with a plug hole capable of being plugged into the boss 3332, so as to facilitate assembly and disassembly.

Optionally, the cutting assembly 3 further comprises a protection system to prevent splashing of the water flow.

Specifically, as shown in fig. 32 and 33, the protection system further includes an upper shield 342 covering the cutting member 31, and generally, the upper shield 342 is directly locked to the heel plate 332 by a locking button, so that a gap is necessarily formed between the heel plate and the tile, and water mist is splashed. In this embodiment, a connecting member (not shown) is disposed on the heel knife plate 332, the upper shield 342 is connected to the heel knife plate 332 through the connecting member, the upper shield 342 can rotate slightly up and down around the connecting member, and the front end of the upper shield 342 can compress the tile surface under its own weight, so as to reduce water mist splashing. At least at the front end, will not splash towards the user. Small amplitude rotation allows the upper shield 342 to pass smoothly without interfering too much with the tile. In addition, the structure of the simplified version can be connected with a piece, and the bolt in the locking button is changed into a flat shaft or a square shaft to realize similar functions, so that the description is omitted. When the user changes the cutting member 31, the upper shield 342 needs to be removed and even the water blocking structure is more, and the upper shield 342 and the knife plate 332 are integrally and quickly detached and assembled, so that the user experience can be greatly improved.

Alternatively, as shown in fig. 33, the heel knife plate 332 is provided with an elongated slot in a vertical direction, the upper shield 342 is provided with a connection hole, and a fastener is inserted through the elongated slot and the connection hole to connect the upper shield 342 with the heel knife plate 332. Specifically, as shown in fig. 33, the guard system includes a water baffle 341, the water baffle 341 being disposed on the opposite side of the cutting member 31 from the knife assembly 33, to block water from splashing from underneath the platen 11 onto the user.

Specifically, the protection system further includes a lower shield (not shown in the drawings) covering the cutting member 31, the lower shield is detachably connected to the heel knife assembly 33, and the lower shield can rotate around a center line parallel to the second direction, so that the lower shield is not required to be detached when the cutting member 31 is replaced, the operation steps of replacing the cutting member 31 are simplified, and the user experience is improved.

Alternatively, as shown in fig. 32-38, the heel knife assembly 33 includes a heel knife holder 331, a heel knife plate 332, and a locking assembly 35; specifically, the heel seat 331 is disposed on the case 2, and the heel seat 331 is provided with a mounting hole; the follower 332 is disposed at a rear side of the cutting member 31 along the first direction and is detachably connected with the follower seat 331; the locking assembly 35 includes a locking shaft 351, the locking shaft 351 is disposed in the mounting hole, a locking state and an unlocking state are provided between the locking assembly 35 and the heel blade 332, when the locking assembly is located in the locking state, the locking assembly 35 locks the heel blade holder 331 and the heel blade 332, and when the locking assembly is located in the unlocking state, the heel blade holder 331 and the heel blade 332 can be separated from each other.

The upper shield 342 is connected to the heel knife plate 332, when the cutting member 31 is replaced, the heel knife plate 332 can be detached from the heel knife plate 331 only by placing the locking component 35 in an unlocking state, so that the upper shield 342 is detached, when the locking component 35 is placed in a locking state, the heel knife plate 332 can be mounted on the heel knife plate 331, and the heel knife plate 332 is detached from the heel knife plate 331 by operating the locking component 35, so that the operation is convenient. The locking shaft 351 can enable the locking shaft 351 to be connected with the heel seat 331 in the mounting hole, so that the locking assembly 35 is stably connected with the heel seat 331, and connection reliability of the heel knife plate 332 and the heel seat 331 can be improved. The locking component 35 is used for replacing the fastener, so that the situation that the heel knife plate 332 is connected with the heel knife seat 331 unstably due to loosening of the fastener in the long-time use or transportation process is avoided, and the connection reliability is improved through the locking of the locking component 35.

In this embodiment, as shown in fig. 32-38, a first connecting hole 3321 and a second connecting hole 3322 are formed on the cutter plate 332, the locking shaft 351 can be inserted into the mounting hole and the first connecting hole 3321, a first connecting portion 3511 and a second connecting portion 3512 are provided on the circumference of the locking shaft 351, when the locking assembly 35 is in a locked state, the second connecting portion 3512 faces the second connecting hole 3322, the locking shaft 351 is clamped in the first connecting hole 3321, when the locking assembly 35 is in an unlocked state, the first connecting portion 3511 faces the second connecting hole 3322, and the locking shaft 351 can be separated from the cutter plate 332 through the second connecting hole 3322.

When the locking mechanism works, the locking shaft 351 is rotated to enable the second connecting portion 3512 to face the second connecting hole 3322, the locking shaft 351 is clamped in the first connecting hole 3321, and the locking assembly 35 is in a locking state; the locking shaft 351 is rotated to orient the first coupling portion 3511 toward the second coupling hole 3322, the locking shaft 351 is separated from the cutter plate 332 by the second coupling hole 3322, and the locking assembly 35 is in an unlocked state. Through setting up the trompil shape and the trompil size of first connecting hole 3321 and second connecting hole 3322 and the appearance and the size of first connecting portion 3511 and second connecting portion 3512, only need rotate locking axle 351 can realize locking axle 351 and with the locking of cutting board 332 or unblock, simple structure is reliable, convenient to use. In addition, the locking shaft 351 is clamped in the first connecting hole 3321, so that the circumferential rotation of the cutter-following plate 332 around the locking shaft 351 is avoided, the cutter-following plate 332 is prevented from loosening along the circumference Xiang Fasheng, and the mounting accuracy is improved.

Alternatively, with continued reference to fig. 35, the first connection hole 3321 is a circular hole, the cross section of the first connection portion 3511 is circular arc-shaped, and the radius of the circular arc of the first connection portion 3511 is the same as the radius of the first connection hole 3321; the cross section of the second connecting portion 3512 is flat, the second connecting hole 3322 is a flat hole, the width of the second connecting portion 3512 is not greater than the width of the second connecting hole 3322, and the diameter of the first connecting hole 3321 is greater than the width of the second connecting hole 3322. Specifically, as shown in fig. 34 and 35, when the flat shape is oriented to the flat hole, the circular arc shape is engaged in the circular hole, so that the heel blade 332 and the locking shaft 351 are locked; when the circular arc shape faces the flat hole, the flat shape can enter the flat hole, and the width of the flat shape is not larger than the width of the flat hole, so that the following blade 332 can be separated from the locking shaft 351. By providing the circular hole and the circular arc-shaped first connection portion 3511, the locking shaft 351 is conveniently rotated in the circular hole. In this embodiment, the first and second connection portions 3511 and 3512 are alternately disposed, and the second connection portion 3512 is formed by two opposite flat connection portions 3512 and two opposite arc-shaped first connection portions 3511.

In this embodiment, as shown in fig. 35, 37 and 38, a gap is formed on one side of the second connecting hole 3322 facing away from the first connecting hole 3321, the second connecting portion 3512 can pass through the gap to enter and exit the second connecting hole 3322, and the heel knife plate 332 can be separated from the heel knife plate 332 through the gap. In other embodiments, the notch may be correspondingly arranged according to the structure such as the follower seat 331, so as to face other directions, thereby facilitating operation.

In other embodiments, when the second connection hole 3322 does not have a notch, the locking shaft 351 may be withdrawn from the second connection hole 3322.

Optionally, as shown in fig. 37, the locking assembly 35 further includes a handle 353, the handle 353 is connected to one end of the locking shaft 351, the handle 353 is provided with a first identification protrusion 3531, and the follower seat 331 is provided with a second identification protrusion 3314; when the locking assembly 35 is in a locking state, the first identification protrusion 3531 and the second identification protrusion 3314 are staggered, the first identification protrusion 3531 can be abutted against the follower seat 331, the second identification protrusion 3314 is abutted against the handle 353, and the first identification protrusion 3531 and the second identification protrusion 3314 can be circumferentially limited while the axial limiting is performed, so that a safety protection effect is achieved; when the locking assembly 35 is in the unlocked state, the first marking protrusion 3531 abuts against the second marking protrusion 3314 to play a role in marking, and the locking assembly 35 is confirmed to be in the locked state before the cutting device cuts, otherwise, danger occurs.

36-38, the heel seat 331 includes a heel seat body 3311 and a first mounting boss 3312 disposed on the heel seat body 3311, wherein the first mounting boss 3312 is provided with a limiting slot 33121, the heel blade plate 332 can be inserted into the limiting slot 33121, the first mounting boss 3312 is provided with a mounting hole, the groove wall of the limiting slot 33121 can limit the heel blade plate 332, and the mounting precision of the heel blade plate 332 is improved; in this embodiment, the limiting slots 33121 limit the two sidewalls of the follower plate 332 along the second direction.

In this embodiment, as shown in fig. 37 and 38, the groove wall of the limiting groove 33121 is provided with a limiting protrusion 33122, and the limiting protrusion 33122 is used for contacting with the side surface of the heel knife plate 332, so as to further improve the mounting accuracy of the heel knife plate 332 along the second direction.

36-38, the locking assembly 35 further includes an elastic blocking piece 352, the locking shaft 351 penetrates through the mounting hole, one end of the elastic blocking piece 352 is fixed on the protruding end of the locking shaft 351, and the other end of the elastic blocking piece can elastically abut against the first mounting boss 3312, so that axial limiting of the locking shaft 351 is achieved; specifically, one end of the locking shaft 351 is limited with the first mounting boss 3312 by the elastic stopper 352, and the other end is limited axially with the second identification boss 3314 by the first identification boss 3531. Specifically, the elastic blocking piece 352 includes a blocking piece and a spring connected to one side of the blocking piece, the blocking piece abuts against the first mounting boss 3312, the blocking piece and the spring are both sleeved on the locking shaft 351, and one end of the spring may be fixed to the locking shaft 351 by welding, abutting or the like.

Optionally, as shown in fig. 36 and 37, the heel seat 331 includes a heel seat body 3311 and a second mounting boss 3313 disposed on the heel seat body 3311, the second mounting boss 3313 is provided with a limiting through hole 33131, the locking shaft 351 can be inserted into the limiting through hole 33131, the limiting through hole 33131 is communicated with the mounting hole, the limiting through hole 33131 is used for circumferentially limiting the locking shaft 351, mounting reliability is improved, and when mounting, the locking shaft 351 is directly inserted into the limiting through hole 33131, alignment is reduced, and operation is convenient.

In this embodiment, as shown in fig. 33, 39 and 40, one of the adapter 333 and the heel seat 331 is provided with a boss 3332, and the other one is provided with a plug hole capable of being plugged into the boss 3332, so that no-clearance fit can be realized through the fit of the boss 3332 and the plug hole, the installation precision of the adapter 333 and the heel seat 331 is improved, the adapter 333 and the heel seat 331 can be simultaneously pulled out for secondary insertion during the disassembly of the heel seat 332, the previous adjustment precision cannot be lost, and the disassembly is convenient. In this embodiment, the adapter 333 is provided with a boss 3332, and the follower seat 331 is provided with a socket hole. Further, a plurality of bosses 3332 may be provided on the adapter 333 to achieve position adjustment.

In this embodiment, as shown in fig. 40, the boss 3332 is a circular truncated cone, the demolding angle of the mating surface of the circular truncated cone and the plugging hole is not large, and the circular truncated cone can be regarded as not being easy to be separated in use, and the inclination angle of the circular truncated cone has a guiding function, so that the installation is convenient. In other embodiments, the boss 3332 may be a cylinder, a half or a fraction of a conical surface, which is not limited.

Example two

The embodiment provides a cutting device, which comprises a box body 2, a workbench 1 arranged on the box body 2 and a cutting assembly 3 arranged on the box body 2, wherein the workbench 1 comprises a bedplate 11 for bearing a workpiece, and a first cutting groove 111 is formed in the bedplate 11 along a first direction; the platen 11 is slidably connected to the case 2 along a first direction, and when the platen 11 slides towards the cutting assembly 3, the cutting assembly 3 is inserted into the first cutting slot 111, so that the cutting assembly 3 cuts a workpiece on the platen 11; the cutting device further comprises a power supply assembly, the surface of the platen 11 having a working plane, the platen 11 having a first projection on the working plane, the power supply assembly 4 having a second projection on the working plane, the second projection being at least partially within the first projection.

The moving direction of the first cutting groove 111 is the same as that of the platen 11, and when the platen 11 slides towards the cutting assembly 3, the cutting assembly 3 penetrates through the first cutting groove 111, so that the workpiece on the platen 11 is automatically cut along the first direction; the platen 11 is an integral structure, the workpiece is supported on the platen 11, the height difference is prevented, the whole platen 11 can move together, the moving speed difference is prevented, the cutting precision and the cutting quality are improved, the cut workpiece is respectively positioned on the platens 11 on two sides of the first cutting groove 111, manual support or an additional support structure is not needed, and the use is more convenient. In addition, the power supply assembly 4 can be prevented from protruding from the platen 11 along the second direction or the third direction, and the structural compactness is improved; during the movement of the platen 11, the second projection of the power supply assembly 4 mounted on the case 2 is always ensured to be in the first projection, so as to limit the movement distance of the platen 11 and prevent the platen 11 from slipping due to overlarge sliding distance.

Example III

The embodiment provides a cutting device, which comprises a workbench 1 for placing a workpiece and a box body 2 for supporting the workbench 1, and further comprises a cutting assembly 3 arranged on the box body 2, wherein the cutting assembly 3 comprises a plurality of cutting pieces 31 and a cutter following assembly 33, and one of the plurality of cutting pieces 31 is alternatively connected with an output shaft and rotates around the output shaft; the follower assembly 33 is movable in a first direction relative to the housing 2 and is restrained at a different distance from the output shaft.

By providing a plurality of cutting members 31, the cutting requirements of different materials can be satisfied; the following knife assembly 33 can move along the first direction, the distance between the following knife assembly 33 and the output shaft is adjusted, the distance between the following knife assembly 33 and the cutting piece 31 is further adjusted, the installation position of the following knife assembly 33 can be adjusted according to the different sizes of the cutting piece 31, the cutting piece 31 is prevented from cutting the following knife assembly 33, the reliability is improved, and the applicability of cutting different materials can be improved by installing the cutting pieces 31 with different sizes on the output shaft; when the small-sized cutting member 31 is replaced, the follow blade assembly 33 is moved toward the output shaft, and when the large-sized cutting member 31 is replaced, the follow blade assembly 33 is moved away from the output shaft. The position of the heel knife assembly 33 corresponds to the corresponding size of the cutting member 31 such that the heel knife assembly 33 is spaced a predetermined distance from the corresponding cutting member 31, thereby preventing the cutting member 31 from cutting the heel knife assembly 33.

Example IV

The embodiment provides a cutting device, which comprises a box body 2, a workbench 1 arranged on the box body 2 and a cutting assembly 3 arranged on the box body 2, wherein the workbench 1 comprises a bedplate 11, a main leaning grid 13, a first adjusting assembly 16 and a second adjusting assembly 17, the bedplate 11 is used for placing workpieces, and a plurality of groups of second installation positions are arranged on the bedplate 11; the main leaning gate 13 is arranged on the bedplate 11, and the main leaning gate 13 is used for limiting a workpiece; the first adjusting component 16 and the second adjusting component 17 can be alternatively locked at one of the plurality of groups of second installation positions, and when the main leaning grid 13 is fixed on the bedplate 11 through the first adjusting component 16 and the second adjusting component 17, the limiting surface of the main leaning grid 13 and the cutting piece 31 on the cutting component 3 form an included angle with corresponding angles.

When the main leaning grid 13 is respectively arranged at a plurality of second installation positions, the first side of the main leaning grid 13 is arranged at different included angles with the first direction, so that the aim of cutting a workpiece at a plurality of cutting angles to meet various modeling requirements can be fulfilled, and various cutting requirements are met. In this embodiment, referring to fig. 4, two guiding wires 113 are disposed on the platen 11, one guiding wire 113 forms an included angle of 22.5 ° with the extending direction of the first cutting groove 111, the other guiding wire 113 forms an included angle of 45 ° with the extending direction of the first cutting groove 111, and the first side of the main leaning grid 13 can be flush with the guiding wire 113, so that the side surface of the workpiece can be flush with the guiding wire 113 to accurately cut a corresponding angle. Alternatively, the guide line 113 is parallel to the extending direction of the first cutting groove 111, and the operator may hold the main fence 13 for hand-pushing cutting.

Further, referring to fig. 4, the mounting structure is provided on the platen 11, and the main fence 13 is detachably connected to the mounting structure on the platen 11. When different angles need to be cut, the main leaning grid 13 is convenient to disassemble and assemble. Further, referring to fig. 4, the table 11 is provided with a logo 114, and the logo 114 may indicate numbers such as 22.5 or 45 ° for easy recognition. Specifically, the specific structures of the first adjusting component 16 and the second adjusting component 17 need only be referred to as the first embodiment, and will not be described again.

Example five

The embodiment provides a cutting device, which comprises a box body 2, a workbench 1 arranged on the box body 2 and a cutting assembly 3 arranged on the box body 2, wherein the workbench 1 comprises a table board 11 for placing a workpiece, a main leaning gate 13 and a first adjusting assembly 16, the main leaning gate 13 is arranged on the table board 11, and the main leaning gate 13 is used for limiting the workpiece; the first adjusting component 16 comprises a fixed end detachably connected to the platen 11, the main leaning gate 13 can rotate around the fixed end of the first adjusting component 16 to adjust the angle, and the first adjusting component 16 can be fixed with the main leaning gate 13. In this embodiment, compared with the first embodiment, the main fence 13 is mounted on the platen 11 by using only the first adjusting assembly 16, and the structure is simple.

Example six

The embodiment provides a cutting device, which comprises a box body 2, a workbench 1 arranged on the box body 2 and a cutting assembly 3 arranged on the box body 2, wherein the workbench 1 comprises a table board 11 for placing a workpiece, a main leaning gate 13 and a second adjusting assembly 17, the main leaning gate 13 is arranged on the table board 11, and the main leaning gate 13 is used for limiting the workpiece; the second adjustment assembly 17 is detachably connected to the platen 11, and the main boom 13 can be fixed to the platen 11 by the second adjustment assembly 17. In this embodiment, compared with the first embodiment, the main fence 13 is mounted on the platen 11 by using only the second adjusting assembly 17, and the structure is simple.

Example seven

The difference between this embodiment and the first embodiment is that, as shown in fig. 39 and 40, the heel knife assembly 33 includes an L-shaped heel knife plate 335, which includes a transverse plate and a longitudinal plate that are connected to each other, the longitudinal plate is disposed on one side of the cutting member 31 along the first direction, the upper shield 342 is connected to the longitudinal plate, and the transverse plate is connected to the heel knife seat by a fastener, so as to facilitate disassembly and assembly.

It is to be understood that the above examples of the present invention are provided for clarity of illustration only and are not limiting of the embodiments of the present invention. Other variations or modifications of the above teachings will be apparent to those of ordinary skill in the art. It is not necessary here nor is it exhaustive of all embodiments. Any modification, equivalent replacement, improvement, etc. which come within the spirit and principles of the invention are desired to be protected by the following claims.

Claims (11)

1. The cutting device comprises a box body (2), a workbench (1) arranged on the box body (2) and a cutting assembly (3) arranged on the box body (2), and is characterized in that the workbench (1) comprises a bedplate (11) for bearing a workpiece, and a first cutting groove (111) is formed in the bedplate (11) along a first direction; the platen (11) is slidably connected to the box body (2) along the first direction, when the platen (11) slides towards the cutting assembly (3), the cutting assembly (3) penetrates through the first cutting groove (111), so that the cutting assembly (3) cuts the workpiece on the platen (11), and the sliding stroke of the platen (11) is larger than that of the workpiece.

2. The cutting device according to claim 1, further comprising a drive assembly arranged on the housing (2) and a power supply assembly (4) for supplying power to the drive assembly, the power supply assembly (4) being arranged outside the housing (2).

3. Cutting device according to claim 2, characterized in that the surface of the platen (11) has a working plane, the platen (11) having a first projection on the working plane, the power supply assembly (4) having a second projection on the working plane, the second projection being located within the first projection.

4. Cutting device according to claim 2, characterized in that it further comprises a drive assembly arranged on the housing (2) and a switch (5) for controlling the drive assembly, the switch (5) being arranged outside the housing (2).

5. Cutting device according to claim 1, characterized in that it comprises a sliding assembly (6), said sliding assembly (6) comprising a track (61) and a sliding sleeve (62) moving on said track (61), said track (61) being connected to said box (2), said sliding sleeve (62) being connected to said platen (11).

6. Cutting device according to claim 5, wherein the sliding sleeve (62) has a movement slot (62A), the sliding sleeve (62) being able to slide out of the end of the track (61) through the movement slot (62A) such that the sliding travel of the platen (11) is greater than or equal to the length of the track (61).

7. A cutting device according to any one of claims 1-6, further comprising a main fence (13), the main fence (13) being detachably connected to the table (11), a first side of the main fence (13) being adapted to abut the workpiece.

8. The cutting device according to claim 7, wherein a plurality of mounting locations are provided on the platen (11), and when the main rest (13) is mounted on the plurality of mounting locations, the first side of the main rest (13) forms different angles with the first direction, and the main rest (13) can be selectively mounted on one of the mounting locations.

9. The cutting device according to claim 7, wherein a first side of the main boom (13) is concavely provided with a second cutting groove (131) towards a second side of the main boom (13), the second cutting groove (131) being in communication with the first cutting groove (111) when the first side of the main boom (13) is perpendicular to the first cutting groove (111).

10. Cutting device according to claim 1, characterized in that the housing (2) is provided with a locking assembly (9) for locking the table (1) such that the table (1) is stationary relative to the housing (2).

11. The cutting device comprises a box body (2), a workbench (1) arranged on the box body (2) and a cutting assembly (3) arranged on the box body (2), and is characterized in that the workbench (1) comprises a bedplate (11) for bearing a workpiece, and a first cutting groove (111) is formed in the bedplate (11) along a first direction; the bedplate (11) is connected to the box body (2) in a sliding manner along the first direction, and when the bedplate (11) slides towards the cutting assembly (3), the cutting assembly (3) penetrates through the first cutting groove (111) so that the cutting assembly (3) cuts the workpiece on the bedplate (11); the cutting device further comprises a power supply assembly (4), the surface of the platen (11) has a working plane, the platen (11) has a first projection on the working plane, and the power supply assembly (4) has a second projection on the working plane, and the second projection is at least partially located in the first projection.