CN114701036B

CN114701036B - Magnet extrusion embedding device for wood furniture processing

Info

Publication number: CN114701036B
Application number: CN202210539596.7A
Authority: CN
Inventors: 张俊竹; 刘小洪; 苏镜科; 杨楚君; 王荣发
Original assignee: Shunde Polytechnic
Current assignee: Shunde Polytechnic
Priority date: 2022-05-18
Filing date: 2022-05-18
Publication date: 2022-11-11
Anticipated expiration: 2042-05-18
Also published as: CN114701036A

Abstract

The invention relates to the field of furniture processing and producing devices, in particular to a magnet extruding and embedding device for processing wooden furniture. The invention places the material to be processed on the material conveying component; after the material is fixed, the slotting component works to slot the surface of the material in the embedding groove. And after slotting is finished, taking the material and embedding the components for working. After the magnet is embedded, the material returns to the material conveying assembly, and the processed material is discharged; according to the invention, through arranging the lifting assembly, the clamping assembly, the magnet conveying assembly, the material taking embedding assembly and the slotting assembly, the automation performance of the embedding device is improved, the clamping stability of materials is improved in a working state, the automatic feeding and automatic discharging capabilities of the whole device are improved, the working efficiency of the embedding device is effectively improved, and the practicability and the automation effect of the embedding device are improved.

Description

Magnet extrusion embedding device for wood furniture processing

Technical Field

The invention relates to the field of furniture processing and producing devices, in particular to a magnet extruding and embedding device for processing wooden furniture.

Background

When wooden furniture is processed, it is sometimes necessary to embed magnet material into the ends of the wood blocks to achieve the desired requirements. The traditional manual one end of magnet is put into the reservation mounting hole of billet, then strikes the embedding at that rubber hammer.

The invention with publication number CN113787582A discloses a magnet extrusion embedding device for wood furniture processing, which comprises a supporting mechanism, a positioning mechanism and an extrusion mechanism; the supporting mechanism comprises a base platform; the positioning mechanism is fixedly connected to the supporting mechanism and used for fixing and positioning the wood block; the extrusion mechanism is arranged on one side of the supporting mechanism and used for extruding the magnet material into an embedded hole which is formed in advance in the wood block, and the base is fixedly connected to the lower side of the base station. The device will treat the magnet material of embedding in the billet and the magnet piece laminating of this device, location through positioning mechanism, preformed hole one-to-one on the position of magnet material and the billet, flexible subassembly extension, can promote first briquetting and press the magnet material to the preformed hole of billet in, and simultaneously, the second briquetting presses the magnet material to the preformed hole of billet in, because the magnetism of the magnet piece of device is fixed, so as long as will treat the magnet and the magnet piece actuation of embedding, can confirm the polarity of treating the magnet of embedding.

However, the above prior art has the following drawbacks: the device's automation performance is lower to under operating condition, it is relatively poor to improve the centre gripping stability of material, improve whole device and lack automatic feeding and automatic unloading ability, lead to whole embedding device's work efficiency, be unfavorable for improving embedding device's practicality and automatic effect.

Disclosure of Invention

The invention provides a magnet extruding and embedding device for processing wooden furniture, aiming at the technical problems in the background technology.

The technical scheme of the invention is as follows: a magnet extrusion embedding device for processing wooden furniture comprises a rack, a material conveying assembly, a lifting assembly, a clamping assembly, a magnet conveying assembly, a material taking embedding assembly and a slotting assembly.

The material conveying component and the magnet conveying component are arranged on the rack; the material conveying component and the magnet conveying component are respectively positioned at two ends of the lifting component.

The lifting component is arranged on the frame. The clamping assembly comprises an upper clamping piece and a lower clamping piece; the upper clamping piece is arranged at the lifting end of the lifting assembly; the lower clamping pieces are arranged on the rack and positioned at two sides of the material conveying assembly; the material is located between the upper clamping piece and the lower clamping piece. Get material embedding component and fluting subassembly setting and hold at lifting unit's lift, get material embedding component and fluting subassembly and be located between material conveying subassembly and the magnet conveying subassembly.

Preferably, the lifting assembly comprises a lifting rod, a screw motor and a lifting seat; the lifting rod is arranged on the frame; the lifting seat driven by the screw motor is arranged on the lifting rod in a sliding manner, and the lifting seat is arranged as a lifting end of the lifting component.

Preferably, the upper clamping piece comprises a first driving motor, a first rotating shaft, a first cylinder mounting seat, a first telescopic cylinder and a clamping plate; a rotating shaft I driven by a driving motor I is rotatably arranged at the lifting end of the lifting assembly; the first cylinder mounting seat is arranged on the first rotating shaft; the cylinder body end of the telescopic cylinder I is arranged on the cylinder mounting seat I; the clamping plate is arranged at the piston end of the first telescopic cylinder.

Preferably, the lower clamping piece comprises a material lifting seat, a material lifting slope and a telescopic cylinder II; the material lifting slopes are arranged on the rack and are positioned at two sides of the material conveying assembly; the cylinder body end of the telescopic cylinder II is arranged on the rack; the material lifting seat is arranged at the piston end of the telescopic cylinder II and is connected with the material lifting slope in a sliding mode.

Preferably, the magnet conveying assembly comprises a magnet conveying belt and a conveying belt mounting seat; the conveyor belt mounting seat is arranged at the upper end of the lifting component; the magnet conveyer belt sets up on the conveyer belt mount pad.

Preferably, the magnet conveyor belt is provided with a first electromagnet; the first electromagnet is connected with the magnet in an adsorption mode.

Preferably, the material taking embedded assembly comprises a driving motor II, a rotating shaft II, a cylinder mounting seat II, a telescopic cylinder III, a material taking frame, a driving motor III, a rotating shaft III and a material taking electromagnet; a second rotating shaft driven by a second driving motor is rotatably arranged at the lifting end of the lifting assembly; the cylinder mounting base II is arranged on the rotating shaft II; the cylinder body end of the telescopic cylinder III is arranged on the cylinder mounting seat II; the material taking frame is arranged at the piston end of the telescopic cylinder III; a rotating shaft III driven by a driving motor III is rotationally arranged on the material taking frame; the material taking electromagnet is arranged on the rotating shaft III.

Preferably, the slotting component comprises a driving motor IV, a rotating shaft IV, a cylinder mounting seat III, a telescopic cylinder IV, a slotting frame and a slotting cutter; a rotating shaft IV driven by a driving motor IV is rotationally arranged at the lifting end of the lifting assembly; the cylinder mounting seat III is arranged on the rotating shaft IV; the cylinder body end of the telescopic cylinder IV is arranged on the cylinder mounting seat III; the slotted frame is arranged at the piston end of the telescopic cylinder IV; the slotting cutter is arranged on the slotting frame.

The working method of the magnet extrusion embedding device for wood furniture processing comprises the following steps:

s1, placing a material to be processed on a material conveying assembly; and magnetically adsorbing the magnet to be embedded on the magnet conveying assembly.

S2, conveying the materials to a material lifting slope after the materials are conveyed by the material conveying assembly, and ascending the slope to enable the materials to reach a material lifting seat; the material lifting seat enables materials to be kept above the material conveying assembly, and meanwhile the clamping plate is driven by the telescopic cylinder I to press the materials downwards, so that the materials are fixed between the material lifting seat and the clamping plate.

And S3, after the material is fixed, the slotting component works, and the driving motor IV and the telescopic cylinder IV drive the slotting cutter to slot the embedded groove on the surface of the material.

S4, after slotting is finished, the material taking embedding assembly works, the telescopic cylinder III and the driving motor III drive the material taking electromagnet to take the magnets from the magnet conveying assembly, and the magnets are extruded into the embedding grooves.

S5, after the magnet is embedded, the second telescopic cylinder resets, the material returns to the material conveying assembly, and discharging of the processed material is achieved.

Compared with the prior art, the technical scheme of the invention has the following beneficial technical effects: placing a material to be processed on a material conveying assembly; and magnetically adsorbing the magnet to be embedded on the magnet conveying assembly. After the material is conveyed by the material conveying assembly, the clamping assembly clamps the material. After the material is fixed, the slotting component works to slot the surface of the material in the embedding groove. After the slotting is finished, the material taking and embedding assembly works, the magnet is taken from the magnet conveying assembly, and the magnet is extruded into the embedding slot. After the magnet is embedded, the material returns to the material conveying assembly, and the processed material is discharged; according to the invention, through arranging the lifting assembly, the clamping assembly, the magnet conveying assembly, the material taking embedding assembly and the slotting assembly, the automation performance of the embedding device is improved, the clamping stability of materials is improved in a working state, the automatic feeding and automatic discharging capabilities of the whole device are improved, the working efficiency of the embedding device is effectively improved, and the practicability and the automation effect of the embedding device are improved.

Drawings

Fig. 1 is a schematic structural diagram of an embodiment of the present invention in an embedded operating state.

Fig. 2 is a schematic structural diagram of a material taking working state according to an embodiment of the present invention.

FIG. 3 is a schematic diagram of the material transfer assembly, the lifting assembly, and the clamping assembly in one embodiment of the present invention.

Fig. 4 is a schematic view of a material take-off insert assembly according to an embodiment of the present invention.

FIG. 5 is a schematic structural view of a slotted assembly in accordance with an embodiment of the present invention.

FIG. 6 is a schematic diagram of a magnet conveying assembly according to an embodiment of the present invention.

Reference numerals: 1. a frame; 2. a material transfer assembly; 3. a lifting assembly; 4. a clamping assembly; 5. a magnet transfer assembly; 6. taking a material embedding component; 7. a slotting component; 8. material preparation; 9. a magnet; 10. a lifting rod; 11. a lead screw motor; 12. a lifting seat; 13. an upper clamping member; 14. a lower clamping member; 15. driving a motor I; 16. rotating a first shaft; 17. a first cylinder mounting seat; 18. a telescopic cylinder I; 19. a material lifting seat; 20. the material is lifted up to a slope; 21. a second telescopic cylinder; 22. a magnet conveyor belt; 23. a conveyor belt mounting seat; 24. a second driving motor; 25. a second rotating shaft; 26. a second cylinder mounting seat; 27. a telescopic cylinder III; 28. a material taking frame; 29. driving a motor III; 30. a third rotating shaft; 31. taking the electromagnet; 32. driving a motor IV; 33. rotating the shaft four; 34. a third cylinder mounting seat; 35. a telescopic cylinder IV; 36. slotting a slot frame; 37. a slotting cutter; 38. and (4) clamping the plate.

Detailed Description

Example one

The invention provides a magnet extrusion embedding device for processing wooden furniture, which comprises a rack 1, a material conveying component 2, a lifting component 3, a clamping component 4, a magnet conveying component 5, a material taking embedding component 6 and a slotting component 7.

As shown in fig. 1-2, the material conveying assembly 2 and the magnet conveying assembly 5 are arranged on the frame 1; the material conveying component 2 and the magnet conveying component 5 are respectively positioned at two ends of the lifting component 3.

The lifting component 3 is arranged on the frame 1. The clamping assembly 4 comprises an upper clamping piece 13 and a lower clamping piece 14; the upper clamping piece 13 is arranged at the lifting end of the lifting component 3; the lower clamping pieces 14 are arranged on the rack 1 and positioned at two sides of the material conveying assembly 2; the material 8 is located between an upper clamp 13 and a lower clamp 14. Get material embedding component 6 and fluting subassembly 7 and set up the lift end at lifting unit 3, get material embedding component 6 and fluting subassembly 7 and be located between material conveying component 2 and magnet conveying component 5.

In this embodiment, the material 8 to be processed is placed on the material transfer assembly 2; the magnet 9 to be embedded is magnetically attracted to the magnet transfer assembly 5. After the material 8 is conveyed by the material conveying assembly 2, the clamping assembly 4 clamps the material 8. After the material 8 is fixed, the slotting component 7 works to slot the surface of the material 8 in a slot. After the slotting is finished, the material taking and embedding assembly 6 works, the magnet 9 is taken from the magnet conveying assembly 5, and the magnet 9 is extruded into the embedding slot. After the magnet 9 is embedded, the material 8 returns to the material conveying assembly 2, and the processed material 8 is discharged; according to the invention, the lifting assembly 3, the clamping assembly 4, the magnet conveying assembly 5, the material taking embedding assembly 6 and the slotting assembly 7 are arranged, so that the automation performance of the embedding device is improved, the clamping stability of the material 8 is improved in a working state, the automatic feeding and automatic discharging capabilities of the whole device are improved, the working efficiency of the embedding device is effectively improved, and the practicability and the automation effect of the embedding device are improved.

Example two

As shown in fig. 1-3, the material conveying assembly 2 and the magnet conveying assembly 5 are arranged on the frame 1; the material conveying component 2 and the magnet conveying component 5 are respectively positioned at two ends of the lifting component 3.

Further, the lifting assembly 3 comprises a lifting rod 10, a screw motor 11 and a lifting seat 12; the lifting rod 10 is arranged on the frame 1; a lifting seat 12 driven by a screw motor 11 is slidably disposed on the lifting rod 10, and the lifting seat 12 is configured as a lifting end of the lifting assembly 3.

In this embodiment, the screw motor 11 drives the lifting seat 12 to slide on the lifting rod 10, so as to drive the upper clamping member 13, the material taking embedding assembly 6 and the slotting assembly 7 to lift relative to the material conveying assembly 2, thereby facilitating the work of slotting and embedding magnets in materials 8 with different specifications with pertinence, and improving the practicability of the invention.

EXAMPLE III

The lifting component 3 is arranged on the frame 1. The clamping assembly 4 comprises an upper clamping piece 13 and a lower clamping piece 14; the upper clamping piece 13 is arranged at the lifting end of the lifting component 3; the lower clamping pieces 14 are arranged on the rack 1 and positioned on two sides of the material conveying assembly 2; the material 8 is located between an upper clamp 13 and a lower clamp 14. Get material embedded component 6 and fluting subassembly 7 and set up the lift end at lifting unit 3, get material embedded component 6 and fluting subassembly 7 and be located between material conveying subassembly 2 and magnet conveying subassembly 5.

Further, the upper clamping piece 13 comprises a first driving motor 15, a first rotating shaft 16, a first cylinder mounting seat 17, a first telescopic cylinder 18 and a clamping plate 38; a rotating shaft I16 driven by a driving motor I15 is rotatably arranged at the lifting end of the lifting assembly 3; the first cylinder mounting seat 17 is arranged on the first rotating shaft 16; the cylinder body end of the telescopic cylinder I18 is arranged on the cylinder mounting seat I17; the clamping plate 38 is disposed at the piston end of the telescopic cylinder one 18.

Further, the lower clamping piece 14 comprises a material lifting seat 19, a material lifting slope 20 and a telescopic cylinder II 21; the material lifting slopes 20 are arranged on the rack 1, and the material lifting slopes 20 are positioned on two sides of the material conveying component 2; the cylinder body end of the telescopic cylinder II 21 is arranged on the rack 1; the material lifting seat 19 is arranged at the piston end of the second telescopic cylinder 21, and the material lifting seat 19 is in sliding connection with the material lifting slope 20.

In this embodiment, the material 8 to be processed is placed on the material transfer assembly 2; the magnet 9 to be embedded is magnetically attracted to the magnet transfer assembly 5. After being conveyed by the material conveying component 2, the material 8 reaches the material lifting slope 20 and goes up the slope, so that the material reaches the material lifting seat 19; the material lifting seat 19 keeps the material 8 above the material conveying assembly 2, and the clamping plate 38 is driven by the first telescopic cylinder 18 to press down the material 8, so that the material 8 is fixed between the material lifting seat 19 and the clamping plate 38. After the material 8 is fixed, the slotting component 7 works to slot the surface of the material 8 in the embedding groove. After slotting is finished, the material taking embedding assembly 6 works, after embedding of the magnet 9 is finished, the telescopic cylinder II 21 resets, the material 8 returns to the material conveying assembly 2, and discharging of the processed material 8 is achieved.

Example four

As shown in fig. 1-3 and 6, the material transfer assembly 2 and the magnet transfer assembly 5 are disposed on the frame 1; the material conveying component 2 and the magnet conveying component 5 are respectively positioned at two ends of the lifting component 3.

The lifting component 3 is arranged on the frame 1. The clamping assembly 4 comprises an upper clamping piece 13 and a lower clamping piece 14; the upper clamping piece 13 is arranged at the lifting end of the lifting component 3; the lower clamping pieces 14 are arranged on the rack 1 and positioned on two sides of the material conveying assembly 2; the material 8 is located between an upper clamp 13 and a lower clamp 14. Get material embedding component 6 and fluting subassembly 7 and set up the lift end at lifting unit 3, get material embedding component 6 and fluting subassembly 7 and be located between material conveying component 2 and magnet conveying component 5.

Further, the magnet conveying assembly 5 comprises a magnet conveying belt 22 and a belt mounting seat 23; the conveyor belt mounting seat 23 is arranged at the upper end of the lifting component 3; the magnet conveyor 22 is disposed on the conveyor mount 23.

Further, an electromagnet I is arranged on the magnet conveyor belt 22; the first electromagnet is connected with the magnet 9 in an adsorption mode.

In this embodiment, the material 8 to be processed is placed on the material transfer assembly 2; the magnet 9 to be embedded is magnetically attracted to the magnet transfer assembly 5. When the magnet conveyor belt 22 conveys the magnet 9, the first electromagnet is connected with the magnet 9 in an adsorption mode, and when the material taking embedding assembly 6 takes materials from the magnet 9, the first electromagnet is powered off and is separated from the magnet 9.

EXAMPLE five

The invention provides a magnet extruding and embedding device for processing wooden furniture, which comprises a rack 1, a material conveying component 2, a lifting component 3, a clamping component 4, a magnet conveying component 5, a material taking and embedding component 6 and a slotting component 7.

As shown in fig. 1-5, the material conveying assembly 2 and the magnet conveying assembly 5 are arranged on the frame 1; the material conveying component 2 and the magnet conveying component 5 are respectively positioned at two ends of the lifting component 3.

Further, the material taking embedded assembly 6 comprises a second driving motor 24, a second rotating shaft 25, a second air cylinder mounting seat 26, a third telescopic air cylinder 27, a material taking frame 28, a third driving motor 29, a third rotating shaft 30 and a material taking electromagnet 31; a second rotating shaft 25 driven by a second driving motor 24 is rotatably arranged at the lifting end of the lifting assembly 3; the second cylinder mounting seat 26 is arranged on the second rotating shaft 25; the cylinder body end of the telescopic cylinder III 27 is arranged on the cylinder mounting seat II 26; the material taking frame 28 is arranged at the piston end of the telescopic cylinder III 27; a rotating shaft III 30 driven by a driving motor III 29 is rotationally arranged on the material taking frame 28; the material taking electromagnet 31 is arranged on the third rotating shaft 30.

In this embodiment, the material 8 to be processed is placed on the material transfer assembly 2; the magnet 9 to be embedded is magnetically attracted to the magnet transfer assembly 5. After the material 8 is clamped and fixed by the clamping component 4, the slotting component 7 performs slotting, and after slotting is finished, the material taking embedding component 6 works to enable the telescopic cylinder III 27 and the driving motor III 29 to drive the material taking electromagnet 31 to take the material of the magnet 9 from the magnet conveying component 5, and the magnet 9 is extruded into the embedding groove. After the magnet 9 is embedded, the second telescopic cylinder 21 resets, the material 8 returns to the material conveying assembly 2, and the processed material 8 is discharged.

Example six

Further, the slotting component 7 comprises a driving motor four 32, a rotating shaft four 33, a cylinder mounting seat three 34, a telescopic cylinder four 35, a slotting rack 36 and a slotting cutter 37; a rotating shaft four 33 driven by a driving motor four 32 is rotatably arranged at the lifting end of the lifting assembly 3; the cylinder mounting seat III 34 is arranged on the rotating shaft IV 33; the cylinder body end of the telescopic cylinder IV 35 is arranged on the cylinder mounting seat III 34; the slotted frame 36 is arranged at the piston end of the telescopic cylinder IV 35; the slotter knife 37 is provided on the slotter frame 36.

In this embodiment, the material 8 to be processed is placed on the material transfer assembly 2; the magnet 9 to be embedded is magnetically attracted to the magnet transfer assembly 5. After the material 8 is fixed by the clamping component 4, the slotting component 7 works, the four driving motors 32 drive the four rotating shafts 33 to rotate at the lifting ends of the lifting components 3, and the four telescopic cylinders 35 drive the slotting tools 37 to slot the surface of the material 8 in the embedding grooves, so that the working efficiency of the material taking embedding component 5 on the next step is improved.

It is to be understood that the above-described embodiments of the present invention are merely illustrative of or explaining the principles of the invention and are not to be construed as limiting the invention. Therefore, any modification, equivalent replacement, improvement and the like made without departing from the spirit and scope of the present invention should be included in the protection scope of the present invention. Further, it is intended that the appended claims cover all such variations and modifications as fall within the scope and boundary of the appended claims, or the equivalents of such scope and boundary.

Claims

1. A magnet extrusion embedding device for wooden furniture processing comprises a rack (1) and is characterized by comprising a material conveying assembly (2), a lifting assembly (3), a clamping assembly (4), a magnet conveying assembly (5), a material taking embedding assembly (6) and a slotting assembly (7);

the material conveying component (2) and the magnet conveying component (5) are arranged on the rack (1); the material conveying component (2) and the magnet conveying component (5) are respectively positioned at two ends of the lifting component (3); the lifting component (3) is arranged on the frame (1); the clamping assembly (4) comprises an upper clamping piece (13) and a lower clamping piece (14); the upper clamping piece (13) is arranged at the lifting end of the lifting component (3); the lower clamping pieces (14) are arranged on the rack (1) and are positioned on two sides of the material conveying assembly (2); the material (8) is positioned between the upper clamping piece (13) and the lower clamping piece (14); the material taking embedded component (6) and the slotting component (7) are arranged at the lifting end of the lifting component (3), and the material taking embedded component (6) and the slotting component (7) are positioned between the material conveying component (2) and the magnet conveying component (5);

the lifting component (3) comprises a lifting rod (10), a screw motor (11) and a lifting seat (12); the lifting rod (10) is arranged on the frame (1); a lifting seat (12) driven by a screw motor (11) is arranged on the lifting rod (10) in a sliding manner, and the lifting seat (12) is arranged as a lifting end of the lifting component (3);

the upper clamping piece (13) comprises a first driving motor (15), a first rotating shaft (16), a first cylinder mounting seat (17), a first telescopic cylinder (18) and a clamping plate (38); a first rotating shaft (16) driven by a first driving motor (15) is rotatably arranged at the lifting end of the lifting assembly (3); the first cylinder mounting seat (17) is arranged on the first rotating shaft (16); the cylinder body end of the telescopic cylinder I (18) is arranged on the cylinder mounting seat I (17); the clamping plate (38) is arranged at the piston end of the first telescopic cylinder (18);

the lower clamping piece (14) comprises a material lifting seat (19), a material lifting slope (20) and a telescopic cylinder II (21); the material lifting slopes (20) are arranged on the rack (1), and the material lifting slopes (20) are positioned on two sides of the material conveying assembly (2); the cylinder body end of the telescopic cylinder II (21) is arranged on the rack (1); the material lifting seat (19) is arranged at the piston end of the telescopic cylinder II (21), and the material lifting seat (19) is in sliding connection with the material lifting slope (20);

the magnet conveying assembly (5) comprises a magnet conveying belt (22) and a conveying belt mounting seat (23); the conveyor belt mounting seat (23) is arranged at the upper end of the lifting component (3); the magnet conveyor belt (22) is arranged on the conveyor belt mounting seat (23); an electromagnet I is arranged on the magnet conveyor belt (22); the electromagnet I is connected with the magnet (9) in an adsorption manner;

the material taking embedded component (6) comprises a driving motor II (24), a rotating shaft II (25), a cylinder mounting seat II (26), a telescopic cylinder III (27), a material taking frame (28), a driving motor III (29), a rotating shaft III (30) and a material taking electromagnet (31); a second rotating shaft (25) driven by a second driving motor (24) is rotatably arranged at the lifting end of the lifting assembly (3); the second cylinder mounting seat (26) is arranged on the second rotating shaft (25); the cylinder body end of the telescopic cylinder III (27) is arranged on the cylinder mounting seat II (26); the material taking frame (28) is arranged at the piston end of the telescopic cylinder III (27); a third rotating shaft (30) driven by a third driving motor (29) is rotationally arranged on the material taking frame (28); the material taking electromagnet (31) is arranged on the rotating shaft III (30);

the slotting component (7) comprises a driving motor IV (32), a rotating shaft IV (33), a cylinder mounting seat III (34), a telescopic cylinder IV (35), a slotting frame (36) and a slotting cutter (37); a rotating shaft IV (33) driven by a driving motor IV (32) is rotatably arranged at the lifting end of the lifting assembly (3); the cylinder mounting seat III (34) is arranged on the rotating shaft IV (33); the cylinder body end of the telescopic cylinder IV (35) is arranged on the cylinder mounting seat III (34); the slotted frame (36) is arranged at the piston end of the telescopic cylinder IV (35); the slotting cutter (37) is arranged on the slotting bracket (36).

2. The working method of the magnet pressing and embedding device for wooden furniture processing as claimed in claim 1, characterized by comprising the following steps:

s1, placing a material (8) to be processed on a material conveying assembly (2); magnetically adsorbing a magnet (9) to be embedded on a magnet conveying assembly (5);

s2, conveying the materials (8) through the material conveying assembly (2), and then reaching a material lifting slope (20) and ascending the slope to enable the materials to reach a material lifting seat (19); the material lifting seat (19) enables the material (8) to be kept above the material conveying assembly (2), and meanwhile, the clamping plate (38) is driven by the telescopic cylinder I (18) to press down the material (8), so that the material (8) is fixed between the material lifting seat (19) and the clamping plate (38);

s3, after the material (8) is fixed, the slotting component (7) works, and the driving motor IV (32) and the telescopic cylinder IV (35) drive the slotting cutter (37) to slot the surface of the material (8) in an embedded groove;

s4, after slotting is finished, the material taking embedding assembly (6) works, the telescopic air cylinder III (27) and the driving motor III (29) drive the material taking electromagnet (31) to take materials of the magnet (9) from the magnet conveying assembly (5), and the magnet (9) is extruded into the embedding slot;

s5, after the magnet (9) is embedded, the second telescopic cylinder (21) resets, the material (8) returns to the material conveying assembly (2), and the processed material (8) is discharged.