CN216266587U - Full-automatic wood connecting machine assembly line - Google Patents

Abstract

The utility model discloses a full-automatic wood connecting machine assembly line, which relates to the technical field of wood connecting equipment and comprises a conveying device, a feeding device, a pressing device, an extruding device and a cutting device, wherein the conveying device comprises a conveying platform and a pre-connecting platform, the pre-connecting platform is provided with a conveying mechanism, a plurality of first press wheels movably connected to the pre-connecting platform and a plurality of first guide wheels movably connected to the pre-connecting platform, and the first press wheels and the first guide wheels are arranged oppositely; the feeding device is arranged on the feeding platform, and the feeding platform is provided with a plurality of second pressing wheels, first auxiliary wheels and a plurality of second guide wheels which are arranged corresponding to the second pressing wheels and the first auxiliary wheels; the compressing device comprises a first compressing device and a second compressing device, and the first compressing device and the second compressing device are used for compressing the wood; the extrusion device is used for extruding the timber to ensure that the connection between the short timbers is firmer; the cutting device is used for cutting and forming the wood. The utility model improves the efficiency of wood production.

Description

Full-automatic wood connecting machine assembly line

Technical Field

The utility model relates to the technical field of wood splicing equipment, in particular to a full-automatic wood splicing machine assembly line.

Background

The wood connecting machine is a special complete machine for connecting short wood, can effectively reduce resource waste and improve the utilization rate of the wood, but the existing wood connecting machine is easy to deviate in the wood conveying process when realizing butt joint, so that the butt joint is easy to deviate, and the existing wood connecting machine is low in automation degree and low in production efficiency.

SUMMERY OF THE UTILITY MODEL

In order to solve the problems, the utility model provides a full-automatic wood connecting machine assembly line, which solves the problems that the automation degree of a wood connecting machine is low, the production efficiency is low, and deviation is easy to occur in the wood conveying process.

In order to achieve the above purposes, the utility model provides a technical scheme, a full-automatic wood connecting machine assembly line, which comprises a conveying device, a feeding device, a pressing device, an extruding device and a cutting device, wherein the conveying device comprises a conveying platform and a pre-connecting platform for conveying wood, the pre-connecting platform is provided with a conveying mechanism, a plurality of first press wheels movably connected to the pre-connecting platform and a plurality of first guide wheels movably connected to the pre-connecting platform, and the first press wheels and the first guide wheels are arranged oppositely; the feeding device is arranged on the feeding platform, a plurality of second pressing wheels and first auxiliary wheels are arranged on the feeding platform, and a plurality of second guide wheels are arranged on the second pressing wheels and the first auxiliary wheels in an opposite mode; the compressing device comprises a first compressing device and a second compressing device, and the first compressing device and the second compressing device are used for compressing the wood; the extrusion device is used for extruding the timber to ensure that the connection between the short timbers is firmer; the cutting device is used for cutting and forming the wood.

Further, conveying platform includes the conveyer belt, the first motor that is used for driving the conveyer belt to carry is connected to the conveyer belt.

Furthermore, conveying mechanism includes the first conveying chain that transversely sets up on the grafting platform in advance and the vertical second conveying chain that sets up in first conveying chain one side, first conveying chain connects the second motor, the third motor is connected to the second conveying chain.

Furthermore, one side of the pre-joint platform is provided with a first delay induction probe and a second delay induction probe, the first delay induction probe and the second delay induction probe are used for inducing an adjusting wire, the lower end of the adjusting wire is movably connected with a movable block, and the movable block is connected with a first pressing wheel.

Further, material feeding unit includes first cylinder, the fly leaf is connected to first cylinder, set up first sprocket on the fly leaf, the fourth motor is connected to first sprocket, the second sprocket is connected to first sprocket, the first auxiliary wheel of second sprocket coaxial coupling, first auxiliary wheel sets up on feeding platform, the last auxiliary hole that sets up of feeding platform makes first auxiliary wheel and sets up in the cooperation of the second auxiliary wheel of auxiliary hole lower extreme, the feeding platform lower extreme sets up the fifth motor and is used for driving the work of second auxiliary wheel.

Furthermore, the first pressing device comprises a first oil cylinder, the first oil cylinder is arranged at the upper end of a first support, the output end of the first oil cylinder is connected with a first induction block arranged in the first support, the bottom of the first induction block is connected with a first pressing block, two ends of the first induction block are arranged in first sliding grooves at two sides of the first support, and a first induction probe is arranged at the position, close to the middle of the first sliding groove, of the outer side of the first support;

the second pressing device comprises a pressing plate, the pressing plate is connected with second oil cylinders arranged on two sides of a first auxiliary plate at the upper end of the pressing plate, a guide plate is arranged on one side of the pressing plate, a second air cylinder and a third air cylinder are arranged on the guide plate, and the second air cylinder and the third air cylinder are arranged at two ends of the guide plate.

Furthermore, two ends of the first auxiliary plate are provided with synchronous mechanisms, each synchronous mechanism comprises a toothed clamping strip arranged at two ends of the first auxiliary plate and a gear meshed with the toothed clamping strip, and a synchronous shaft is arranged in each gear.

Furthermore, the extrusion device comprises a third oil cylinder and a fourth oil cylinder, the third oil cylinder is arranged at the upper end of the second support, the output end of the third oil cylinder is connected with a second induction block arranged in the second support, the bottom of the second induction block is connected with a second pressing block, two ends of the second induction block are arranged in second sliding grooves at two sides of the second support, and a second induction probe is arranged at the position, close to the middle of the second sliding groove, of the outer side of the second support; and the fourth oil cylinder is used for controlling the second support to walk left and right.

Furthermore, the cutting device comprises a plurality of third pressing wheels, a second auxiliary plate, a cutting mechanism, a third pressing block connected with a fourth cylinder, the third auxiliary plate, a fourth auxiliary plate, a third induction probe arranged on one side of the cutting platform and a toothed sliding block arranged on one side of the cutting platform, wherein the third pressing wheels and the second auxiliary plate are arranged oppositely; the cutting mechanism comprises a cutting hole arranged on the cutting platform, a cutting knife is arranged at the lower end of the cutting hole, the cutting knife is connected to one end of the auxiliary shaft, the other end of the auxiliary shaft is connected with the output end of the sixth motor through a triangular belt, and the lower end of the auxiliary shaft is connected with the fifth air cylinder; the sliding connection sliding part is arranged on the sliding part with teeth, a fourth induction probe is arranged on the sliding part and used for inducting a plate arranged at one end of the fourth induction probe, the plate is hinged to the sliding part, and a spring is arranged on the plate and abutted to the sliding part.

Furthermore, a sixth air cylinder is further arranged on the cutting platform and used for ejecting the cut wood to the forming frame.

The utility model has the beneficial effects that: the wood butt joint device is provided with the first pressing wheels, the first guide wheels, the second pressing wheels and the second guide wheels, the first pressing wheels are matched with the first guide wheels, the second pressing wheels are matched with the second guide wheels, deviation of wood in the conveying process is avoided, and therefore the wood is prevented from being not accurately butted.

Drawings

FIG. 1 is a schematic structural diagram of a conveying apparatus according to the present embodiment;

FIG. 2 is a schematic structural view of a feeding device and a pressing device according to the present embodiment;

FIG. 3 is a schematic structural diagram of the extruding device and the cutting device according to the present embodiment;

FIG. 4 is a schematic structural diagram of the first pressing wheel and the first guide wheel in this embodiment;

FIG. 5 is a schematic view of a connection structure of the sliding member and the toothed sliding block according to the present embodiment;

fig. 6 is a schematic structural view of the first pressing device in this embodiment.

In the figure: 100-a conveying device; 110-a transport platform; 111-a conveyor belt; 112-a first motor; 120-a pre-grafting platform; 121-a first pinch roller; 122-a first guide wheel; 123-a first conveyor chain; 124-a second conveyor chain; 125-a second motor; 126-first delay sensing probe; 127-a second time delay inductive probe; 128-adjusting filaments;

200-a feeding device; 210-a second puck; 220-a second guide wheel; 230-a first cylinder; 240-a first sprocket; 250-a second sprocket; 260-a first auxiliary wheel; 270-auxiliary wells; 280-a fifth motor;

300-a compacting device; 310-a first compression device; 311-a first cylinder; 312 — a first sensing block; 313-a first compact; 314-a first runner; 315-a first inductive probe; 320-a second hold-down device; 321-a pressing plate; 322-a second cylinder; 323-a guide plate; 324-a second cylinder; 325-a third cylinder; 326-toothed snap bar; 327-synchronizing shaft;

400-an extrusion device; 410-a third oil cylinder; 412-a second sensing block; 413-second briquettes; 414-a second chute; 415-a second inductive probe;

500-a cutting device; 510-a third pinch roller; 520-a second auxiliary plate; 530-a cutting mechanism; 531-cutting the hole; 532-cutting knife; 533-auxiliary shaft; 534-a sixth electric machine; 535-fifth cylinder; 540-fourth cylinder; 550-third briquetting; 560-third auxiliary plate; 570-a fourth auxiliary plate; 580-third inductive probe; 590-toothed slider; 591-a slider; 592-a fourth inductive probe; 593-a plate; 600-sixth cylinder.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present invention clearer, the technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are some, but not all, embodiments of the present invention. The components of embodiments of the present invention generally described and illustrated in the figures herein may be arranged and designed in a wide variety of different configurations. Thus, the following detailed description of the embodiments of the present invention, presented in the figures, is not intended to limit the scope of the utility model, as claimed, but is merely representative of selected embodiments of the utility model. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

The utility model provides a technical scheme, a full-automatic wood connecting machine assembly line, which comprises a conveying device 100, a feeding device 200, a pressing device 300, an extruding device 400 and a cutting device 500, wherein the conveying device 100 comprises a conveying platform 110 and a pre-connecting platform 120, the conveying platform 110 is used for conveying wood, the pre-connecting platform 120 is provided with a conveying mechanism, a plurality of first press wheels 121 movably connected to the pre-connecting platform 120 and a plurality of first guide wheels 122 movably connected to the pre-connecting platform 120, and the first press wheels 121 and the first guide wheels 122 are arranged oppositely; the first pressing wheel 121 and the first guide wheel 122 are matched with each other to prevent timber from deviating, the feeding device 200 is arranged on the feeding platform, a plurality of second pressing wheels 210 and first auxiliary wheels 260 are arranged on the feeding platform, and a plurality of second guide wheels 220 are arranged on the second pressing wheels 210 and the first auxiliary wheels 260 in an opposite mode; the second pressing wheel 210, the first auxiliary wheel 260 and the second guide wheel 220 are mutually matched to prevent timber from deviating, the pressing device 300 comprises a first pressing device 310 and a second pressing device 320, and the first pressing device 310 and the second pressing device 320 are used for pressing timber; the pressing device 400 is used for pressing the wood to make the connection between the short woods more firm; the cutting device 500 is used for cutting and shaping wood.

In this embodiment, the conveying platform 110 includes a conveying belt 111, and the conveying belt 111 is connected to a first motor 112 for driving the conveying belt 111 to convey.

Specifically, the wood falls onto the conveying platform 110, and the first motor 112 operates to drive the conveying belt 111 to convey the wood onto the pre-receiving platform 120.

In this embodiment, the conveying mechanism includes a first conveying chain 123 transversely disposed on the pre-joint platform 120 and a second conveying chain 124 vertically disposed on one side of the first conveying chain 123, the first conveying chain 123 is connected to a second motor 125, and the second conveying chain 124 is connected to a third motor.

Specifically, the wood is conveyed to the first conveying chain 123 of the pre-joint platform 120, at this time, the wood enters the lower end of the first pressing wheel 121, one side of the wood is controlled and guided by the first guide wheel 122, the other side of the wood is abutted to the second conveying chain 124, the second motor 125 drives one conveying chain to convey the wood, the third motor drives the second conveying chain 124 to convey the wood, and at this time, the first conveying chain 123 and the second conveying chain 124 synchronously convey the wood.

In this embodiment, a first delay induction probe 126 and a second delay induction probe 127 are disposed on one side of the pre-joint platform 120, the first delay induction probe 126 and the second delay induction probe 127 are used for inducing an adjusting wire 128, a movable block is movably connected to the lower end of the adjusting wire 128, and the movable block is connected to the first pressing wheel 121.

Specifically, the preferable delay time of the first delay induction probe 126 and the second delay induction probe 127 is 1 second, when the wood is conveyed fully on the pre-joint platform 120, the wood is stopped to 1 second at the lower end of the first pressing wheel 121 connected with the adjusting wire 128 where the first induction probe 315 is located, at this time, the first pressing wheel 121 jacks up the adjusting wire 128 through the movable block, the adjusting wire 128 enters the induction range of the first induction probe 315 and stops to 1 second, at this time, the first induction probe 315 transmits a signal to the feeding device 200, so that the first auxiliary wheel 260 of the feeding device 200 starts to work, and the second induction probe 415 and the first induction probe 315 work on the same principle.

In this embodiment, the feeding device 200 includes a first cylinder 230, the first cylinder 230 is connected to a movable plate, a first sprocket 240 is disposed on the movable plate, the first sprocket 240 is connected to a fourth motor, the first sprocket 240 is connected to a second sprocket 250, the second sprocket 250 is coaxially connected to a first auxiliary wheel 260, the first auxiliary wheel 260 is disposed on the feeding platform, an auxiliary hole 270 is disposed on the feeding platform, so that the first auxiliary wheel 260 is matched with a second auxiliary wheel disposed at the lower end of the auxiliary hole 270, and a fifth motor 280 is disposed at the lower end of the feeding platform and used for driving the second auxiliary wheel to operate.

Specifically, preferably, the number of the first auxiliary wheel 260 and the number of the second auxiliary wheel are two, when wood is conveyed to the feeding device 200, the movable plate is lifted by the first air cylinder 230, the movable plate lifts the first auxiliary wheel 260 through the mutual matching of the first chain wheel 240 and the second chain wheel 250, so that the wood can pass through, the fourth motor and the fifth motor 280 work to drive the first auxiliary wheel 260 and the second auxiliary wheel to rotate, and the first auxiliary wheel 260 and the second auxiliary wheel are mutually matched to convey the wood to the first pressing device 310.

In this embodiment, the first pressing device 310 includes a first oil cylinder 311, the first oil cylinder 311 is disposed at the upper end of the first bracket, the output end of the first oil cylinder 311 is connected to a first sensing block 312 disposed in the first bracket, the bottom of the first sensing block 312 is connected to a first pressing block 313, two ends of the first sensing block 312 are disposed in first sliding slots 314 at two sides of the first bracket, and a first sensing probe 315 is disposed at a position close to the middle of the first sliding slot 314 outside the first bracket;

specifically, the timber is conveyed to the first pressing device 310, the first sensing block 312 and the first pressing block 313 are lifted by the first oil cylinder 311, when the first sensing block 312 slides in the first sliding groove 314 to the sensing range of the first sensing probe 315, the first oil cylinder 311 stops rising, and then the timber is conveyed to the second pressing device 320.

The second pressing device 320 includes a pressing plate 321, the pressing plate 321 is connected to second oil cylinders 322 disposed on two sides of the first auxiliary plate at the upper end of the pressing plate 321, a guide plate 323 is disposed on one side of the pressing plate 321, a second air cylinder 324 and a third air cylinder 325 are disposed on the guide plate 323, and the second air cylinder 324 and the third air cylinder 325 are disposed at two ends of the guide plate 323.

Specifically, the timber is conveyed to the second pressing device 320, the second cylinder 322 drives the pressing plate 321 to lift upwards to enable the timber to pass through, and the second cylinder 324 and the third cylinder 325 drive the guide plate 323 to adapt to the width of the timber and prevent the timber from deviating.

In this embodiment, the two ends of the first auxiliary plate are provided with a synchronization mechanism, the synchronization mechanism includes a toothed clamping strip 326 provided at the two ends of the first auxiliary plate, and a gear engaged with the toothed clamping strip 326, and a synchronization shaft 327 is provided in the gear.

Specifically, the two ends of the pressure plate 321 can be lifted synchronously by the arrangement of the synchronous mechanism.

In this embodiment, the extrusion device 400 includes a third oil cylinder 410 and a fourth oil cylinder, the third oil cylinder 410 is disposed at the upper end of the second bracket, the output end of the third oil cylinder 410 is connected to a second induction block 412 disposed in the second bracket, the bottom of the second induction block 412 is connected to a second pressing block 413, two ends of the second induction block 412 are disposed in second sliding grooves 414 at two sides of the second bracket, and a second induction probe 415 is disposed at the outer side of the second bracket near the middle of the second sliding grooves 414;

specifically, the wood enters the extrusion device 400 from the second pressing device 320, the third cylinder 410 drives the second sensing block 412 and the second pressing block 413 to lift upwards, and when the second sensing block 412 slides in the second sliding groove 414 to reach the sensing range of the second sensing probe 415, the operation stops.

And the fourth oil cylinder is used for controlling the second bracket to walk left and right.

Specifically, when the timber is cut, the third oil cylinder 410 drives the second pressing block 413 to press the timber tightly, and the fourth oil cylinder drives the extrusion device 400 to move rightwards to further butt the timber, so that the butt joint of the timber is more compact.

In this embodiment, the cutting device 500 includes a plurality of third pressing wheels 510, a second auxiliary plate 520, a cutting mechanism 530, a third pressing block 550 connected to the fourth cylinder 540, a third auxiliary plate 560, a fourth auxiliary plate 570, a third inductive probe 580 disposed on one side of the cutting platform, and a toothed slider 590 disposed on one side of the cutting platform, where the third pressing wheels 510 and the second auxiliary plate 520 are disposed opposite to each other; the cutting mechanism 530 comprises a cutting hole 531 arranged on the cutting platform, a cutting knife 532 is arranged at the lower end of the cutting hole 531, the cutting knife 532 is connected to one end of an auxiliary shaft 533, the other end of the auxiliary shaft 533 is connected with the output end of a sixth motor 534 through a triangular belt, and the lower end of the auxiliary shaft 533 is connected with a fifth cylinder 535; the toothed sliding block 590 is slidably connected with a sliding part 591, a fourth induction probe 592 is arranged on the sliding part 591 and used for inducing a plate 593 arranged at one end of the fourth induction probe 592, the plate 593 is hinged on the sliding part 591, and a spring arranged on the plate 593 abuts against the sliding part 591.

Specifically, timber is carried to cutting device 500 from extrusion device 400, third pinch roller 510 prevents the timber skew with second accessory plate 520 mutually supports, be carried to the butt plate when timber, make the spring on the plate 593 compressed, the plate 593 gets into the response scope of fourth inductive probe 592, fourth inductive probe 592 gives cutting mechanism 530 with signal transmission, fourth cylinder 540 drives third briquetting 550 and compresses tightly timber this moment, sixth motor 534 drives cutting knife 532 through auxiliary shaft 533 and rotates, fifth cylinder 535 passes through auxiliary shaft 533 and pushes up cutting knife 532 through cutting hole 531, cut off timber.

In particular, the third inductive probe 580 acts as a deceleration.

Specifically, the sliding member 591 can slide on the toothed sliding block 590 to adjust the position, so that different lengths of timbers can be cut according to requirements.

In this embodiment, the cutting platform is further provided with a sixth cylinder 600 for ejecting the cut wood to the forming frame.

In the description of the embodiments of the present invention, it should be noted that the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", and the like indicate orientations and positional relationships based on the orientations and positional relationships shown in the drawings or orientations and positional relationships which are usually placed when the products of the present invention are used, and are only used for convenience of describing the present invention and simplifying the description, but do not indicate or imply that the devices or elements indicated must have specific orientations, be constructed and operated in specific orientations, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first," "second," "third," and the like are used solely to distinguish one from another and are not to be construed as indicating or implying relative importance.

In the description of the embodiments of the present invention, it should be further noted that, unless otherwise explicitly stated or limited, the terms "disposed," "mounted," "connected," and "connected" are to be construed broadly and may include, for example, a fixed connection, a detachable connection, or an integral connection; can be mechanically or electrically connected; they may be connected linearly or indirectly through an intermediate medium, or they may be connected internally between two elements. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

In the present invention, unless otherwise expressly stated or limited, the first feature may be present on or under the second feature in direct contact with the first and second feature, or may be present in the first and second feature not in direct contact but in contact with another feature between them. Also, the first feature being above, on or above the second feature includes the first feature being directly above and obliquely above the second feature, or merely means that the first feature is at a higher level than the second feature. A first feature that underlies, and underlies a second feature includes a first feature that is directly under and obliquely under a second feature, or simply means that the first feature is at a lesser level than the second feature.

Claims (10)

1. The utility model provides a full-automatic grafting machine assembly line which characterized in that: the wood cutting machine comprises a conveying device (100), a feeding device (200), a pressing device (300), an extruding device (400) and a cutting device (500), wherein the conveying device (100) comprises a conveying platform (110) for conveying wood and a pre-joint platform (120), a conveying mechanism, a plurality of first pressing wheels (121) movably connected to the pre-joint platform (120) and a plurality of first guide wheels (122) movably connected to the pre-joint platform (120) are arranged on the pre-joint platform (120), and the first pressing wheels (121) and the first guide wheels (122) are arranged oppositely; the feeding device (200) is arranged on the feeding platform, a plurality of second pressing wheels (210) and first auxiliary wheels (260) are arranged on the feeding platform, and a plurality of second guide wheels (220) are arranged on the second pressing wheels (210) and the first auxiliary wheels (260) in a manner of being opposite to each other; the pressing device (300) comprises a first pressing device (310) and a second pressing device (320), and the first pressing device (310) and the second pressing device (320) are used for pressing the timber; the pressing device (400) is used for pressing the timber to enable the connection between the short timbers to be firmer; the cutting device (500) is used for cutting and shaping wood.

2. The full-automatic log receiving machine assembly line of claim 1, characterized in that: the conveying platform (110) comprises a conveying belt (111), and the conveying belt (111) is connected with a first motor (112) for driving the conveying belt (111) to convey.

3. The full-automatic log receiving machine assembly line of claim 1, characterized in that: the conveying mechanism comprises a first conveying chain (123) transversely arranged on the pre-connecting platform (120) and a second conveying chain (124) vertically arranged on one side of the first conveying chain (123), the first conveying chain (123) is connected with a second motor (125), and the second conveying chain (124) is connected with a third motor.

4. A full-automatic splicer assembly line according to any one of claims 1 or 3, wherein: connect platform (120) one side in advance and set up first time delay inductive probe (126) and second time delay inductive probe (127), first time delay inductive probe (126) with second time delay inductive probe (127) are used for responding to adjusting wire (128), adjusting wire (128) lower extreme swing joint movable block, first pinch roller (121) is connected to the movable block.

5. The full-automatic log receiving machine assembly line of claim 1, characterized in that: the feeding device (200) comprises a first air cylinder (230), the first air cylinder (230) is connected with a movable plate, a first chain wheel (240) is arranged on the movable plate, the first chain wheel (240) is connected with a fourth motor, the first chain wheel (240) is connected with a second chain wheel (250), the second chain wheel (250) is coaxially connected with a first auxiliary wheel (260), the first auxiliary wheel (260) is arranged on a feeding platform, an auxiliary hole (270) is formed in the feeding platform, so that the first auxiliary wheel (260) is matched with a second auxiliary wheel arranged at the lower end of the auxiliary hole (270), and a fifth motor (280) is arranged at the lower end of the feeding platform and used for driving the second auxiliary wheel to work.

6. The full-automatic log receiving machine assembly line of claim 1, characterized in that: the first pressing device (310) comprises a first oil cylinder (311), the first oil cylinder (311) is arranged at the upper end of a first support, the output end of the first oil cylinder (311) is connected with a first induction block (312) arranged in the first support, the bottom of the first induction block (312) is connected with a first pressing block (313), two ends of the first induction block (312) are arranged in first sliding grooves (314) on two sides of the first support, and a first induction probe (315) is arranged on the outer side of the first support, close to the middle of the first sliding grooves (314);

the second pressing device (320) comprises a pressing plate (321), the pressing plate (321) is connected with second oil cylinders (322) arranged on two sides of a first auxiliary plate at the upper end of the pressing plate (321), a guide plate (323) is arranged on one side of the pressing plate (321), a second air cylinder (324) and a third air cylinder (325) are arranged on the guide plate (323), and the second air cylinder (324) and the third air cylinder (325) are arranged at two ends of the guide plate (323).

7. The full-automatic log receiving machine assembly line of claim 6, wherein: and two ends of the first auxiliary plate are provided with synchronous mechanisms, each synchronous mechanism comprises a toothed clamping strip (326) arranged at two ends of the first auxiliary plate and a gear meshed with the toothed clamping strip (326), and a synchronous shaft (327) is arranged in the gear.

8. The full-automatic log receiving machine assembly line of claim 1, characterized in that: the extrusion device (400) comprises a third oil cylinder (410) and a fourth oil cylinder, the third oil cylinder (410) is arranged at the upper end of a second support, the output end of the third oil cylinder (410) is connected with a second induction block (412) arranged in the second support, the bottom of the second induction block (412) is connected with a second pressing block (413), two ends of the second induction block (412) are arranged in second sliding grooves (414) on two sides of the second support, and a second induction probe (415) is arranged on the outer side of the second support, close to the middle of the second sliding grooves (414); and the fourth oil cylinder is used for controlling the second support to walk left and right.

9. The full-automatic log receiving machine assembly line of claim 1, characterized in that: the cutting device (500) comprises a plurality of third pressing wheels (510), a second auxiliary plate (520), a cutting mechanism (530), a third pressing block (550) connected with a fourth air cylinder (540), a third auxiliary plate (560), a fourth auxiliary plate (570), a third induction probe (580) arranged on one side of the cutting platform and a toothed sliding block (590) arranged on one side of the cutting platform, wherein the third pressing wheels (510) and the second auxiliary plate (520) are arranged oppositely; the cutting mechanism (530) comprises a cutting hole (531) arranged on the cutting platform, a cutting knife (532) is arranged at the lower end of the cutting hole (531), the cutting knife (532) is connected to one end of an auxiliary shaft (533), the other end of the auxiliary shaft (533) is connected with the output end of a sixth motor (534) through a triangular belt, and the lower end of the auxiliary shaft (533) is connected with a fifth cylinder (535); the toothed sliding block (590) is connected with a sliding piece (591) in a sliding mode, a fourth induction probe (592) is arranged on the sliding piece (591) and used for inducing a plate (593) arranged at one end of the fourth induction probe (592), the plate (593) is hinged on the sliding piece (591), and a spring is arranged on the plate (593) and abuts against the sliding piece (591).

10. The full-automatic log receiving machine assembly line of claim 9, wherein: and the cutting platform is also provided with a sixth air cylinder (600) for ejecting the cut wood to the forming frame.

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