CN114290447A - Self-suction fusion type anti-channeling flow type plate cutting equipment for interior decoration - Google Patents

Abstract

The invention discloses self-absorption fusion type anti-channeling indoor decoration plate cutting equipment which comprises a bottom plate, bearing columns, a frame, an intermediate type bidirectional anti-diffusion parallel cutting mechanism, an airflow narrow-channel circulation type high-speed adsorption combination mechanism and a sealing compaction mechanism, wherein every two bearing columns are symmetrically arranged at two ends of the upper wall of the bottom plate in a group, the frame is arranged on one side, away from the bottom plate, of the bearing columns, the intermediate type bidirectional anti-diffusion parallel cutting mechanism is arranged on the frame, and the airflow narrow-channel circulation type high-speed adsorption combination mechanism is arranged on the upper wall of the bottom plate. The invention belongs to the technical field of plate processing, and particularly relates to self-suction fusion type anti-channeling flow type plate cutting equipment for interior decoration; the invention provides a self-suction fusion type anti-channeling indoor decoration plate cutting device which can restrain the fixed range of a crumb-containing gas, prevent the crumb-containing gas from irregularly channeling everywhere, can perform low-crumb processing on a plate cutting environment and can perform self-service fusion adsorption on the crumb-containing gas.

Description

Self-suction fusion type anti-channeling flow type plate cutting equipment for interior decoration

Technical Field

The invention belongs to the technical field of plate processing, and particularly relates to self-suction fusion type anti-channeling flow type plate cutting equipment for interior decoration.

Background

Nowadays, in order to promote quality of life, build good life and study atmosphere, most people all can decorate the house of oneself, especially along with the rapid development of trades such as real estate, also make the fitment trade constantly enlarge, the demand of fitment panel has been improved equally, but the panel specification that most purchase is single, can not be fine satisfy the in-service use, can not reach the decoration effect of ideal, consequently just need use cutting device, according to fitment structural design, cut fitment panel, in order to satisfy diversified demand, the decoration efficiency is improved.

The existing plate cutting equipment has the following problems:

1. the plate can generate a large amount of chip-containing gas in the cutting process, the chip-containing gas flows everywhere when the plate is cut by the conventional plate cutting equipment, and the chip-containing gas generated by cutting cannot be inhibited in a fixed range, so that the cutting environment of the plate is full of the chip-containing gas, and the health of operators is seriously threatened;

2. most of the traditional chip-containing gas purification adopts dust removal equipment for simple filtration and then is discharged, but after the dust removal equipment is used for a long time, a filtering mechanism is blocked, so that the dust removal equipment cannot be used continuously;

3. the existing cutting equipment cannot simultaneously cut a plurality of plates synchronously, so that the use efficiency of the cutting equipment is low.

Disclosure of Invention

Aiming at the situation and overcoming the defects of the prior art, the scheme provides a self-absorption fusion type anti-channeling plate cutting device for interior decoration, aiming at the problem of channeling the chip-containing gas everywhere, the device creatively combines a flow range fixing structure, a high-precision horizontal advancing mechanism and a multipurpose principle (enabling objects to have a composite function to replace other objects) and is applied to the technical field of plate processing, through the arranged middle type bidirectional anti-diffusion parallel cutting mechanism, under the mutual matching of the advancing driving mechanism, the bidirectional cutting mechanism and the dust suppression bearing mechanism, under the interference of the sealing and compacting mechanism, the high-precision positioning cutting of the plate is realized, the suppression of irregular channeling of the chip-containing gas everywhere is realized, the problems that the prior art is difficult to solve that the plate is required to be subjected to sealing cutting (the plate cutting generates a large amount of chip-containing gas, pollute the surrounding environment, serious threat operating personnel's health), do not seal the contradiction technical problem of cutting (traditional panel cuts and generally adopts artifical manual promotion panel to be close to the cutter and cuts, thereby is difficult to realize cutting the seal of panel) again.

Meanwhile, the self-absorption type water mist fusion adsorption of the gas containing scraps is realized by combining a Venturi effect principle (pressure intensity is reduced near the gas flowing at high speed so as to generate adsorption) under the double action of the guide pipe through the arranged airflow narrow-channel circulation type high-speed adsorption combination mechanism, the wood scraps adsorbed on the filter screen are cleaned under the gravity factor of water flow through the continuous impact of the water mist on the filter screen, and the problem that the filter equipment is easy to block in the long-time filtering work, which is difficult to solve in the prior art, is solved.

Therefore, the self-suction fusion type anti-channeling indoor decoration plate cutting equipment can restrain the fixed range of the chip-containing gas, prevent the chip-containing gas from irregularly channeling everywhere, perform low-chip treatment on a plate cutting environment and perform self-service fusion adsorption on the chip-containing gas.

The technical scheme adopted by the scheme is as follows: the scheme provides a self-absorption fusion type anti-channeling indoor decoration plate cutting device which comprises a bottom plate, bearing columns, a frame, an intermediate type bidirectional anti-diffusion parallel cutting mechanism, an airflow narrow-passage circulating high-speed adsorption combination mechanism and a sealing compaction mechanism, wherein the bearing columns are symmetrically arranged at two ends of the upper wall of the bottom plate in pairs as a group, the frame is arranged at one side of the bearing columns, which is far away from the bottom plate, the intermediate type bidirectional anti-diffusion parallel cutting mechanism is arranged on the frame, the airflow narrow-passage circulating high-speed adsorption combination mechanism is arranged on the upper wall of the bottom plate, the sealing compaction mechanism is arranged on the intermediate type bidirectional anti-diffusion parallel cutting mechanism, the intermediate type bidirectional anti-diffusion parallel cutting mechanism comprises an advancing driving mechanism, a bidirectional cutting mechanism and a dust suppression bearing mechanism, the advancing driving mechanism is arranged on the inner wall of the frame, and the bidirectional cutting mechanism is arranged between the advancing driving mechanisms, the dust suppression bearing mechanism is arranged inside the frame on one side of the bidirectional cutting mechanism.

As a further preferred option of the scheme, the advancing driving mechanism comprises through grooves, racks, guide rails, sliders, a bearing frame, an advancing motor, a gear and a driving shaft, wherein the through grooves are symmetrically arranged on the inner walls of two sides of the frame, the through grooves are arranged in a through manner, the racks are symmetrically arranged on the upper wall and the bottom wall of the through grooves, the guide rails are symmetrically arranged on the upper wall and the bottom wall of the frame in pairs as a group, the sliders are arranged on the guide rails in a sliding manner, the bearing frame is arranged on one side of the sliders, which is far away from the guide rails, the advancing motor is arranged at one end, which is far away from the sliders, of the bearing frame, the driving shaft is arranged at the power end of the advancing motor, the gear is arranged at one end, which is far away from the advancing motor, the gear is arranged between the racks, and the gear is meshed with the racks; the bidirectional cutting mechanism comprises cutting plates, a cutting motor, a motor groove, cutting grooves, guide ports, guide pipes and cutting knives, wherein the cutting plates are arranged between driving shafts, the driving shafts are rotatably arranged on the side walls of the cutting plates, the guide ports are symmetrically arranged on the side walls of the cutting plates, the guide pipes penetrate through the guide ports and are arranged on the inner wall of a frame, the cutting grooves are arranged at the middle position of the upper wall of the cutting plates and are communicated with each other, the motor groove is arranged on the upper wall of the cutting plates on one side of the cutting grooves, the motor groove is communicated with the motor groove, the cutting motor is arranged in the motor groove, the power end of the cutting motor penetrates through the inner wall of the motor groove and is rotatably arranged on the inner wall of the cutting groove, the cutting knives are arranged at the power end of the cutting motor, and the cutting knives are arranged in the cutting grooves; the dust suppression bearing mechanism comprises connecting columns, bearing boxes, strip-shaped grooves and inlet grooves, wherein the bearing boxes are symmetrically arranged above and below the cutting plate, the bearing boxes are arranged inside the frame on one side of the cutting plate, multiple groups of the connecting columns are arranged between the side wall of the bearing box and the inner wall of the frame, the bearing box is a cavity with one open end, the strip-shaped grooves are arranged on the side wall of the bearing box, the strip-shaped grooves are arranged in a through manner, the strip-shaped grooves are oppositely arranged, the inlet grooves are arranged on one side of the bearing box close to the cutting plate, the inlet grooves are arranged in a through manner, and the strip-shaped grooves are communicated with the strip-shaped grooves; the travelling motor drives the driving shaft to rotate, the driving shaft drives the gear to rotate, the gear is meshed with the rack, the gear advances along the rack roller, the travelling motor drives the bearing frame to move, the bearing frame slides along the guide rail through the sliding block to enable the travelling motor to stably advance, the driving shaft rotates around the side wall of the cutting plate in the moving process, the driving shaft drives the cutting plate to horizontally move, the cutting motor drives the cutting knife to rotate through the power end, the plate is placed inside the bearing box through the opening, the cutting knife enters the bearing box through the inlet groove in the advancing process, and the cutting knife moves along the strip-shaped groove to cut the plate placed inside the bearing box.

Preferably, the airflow narrow-passage circulating high-speed adsorption combining mechanism comprises a scrap recovery mechanism, a gas purification mechanism and an atomization adsorption mechanism, wherein the scrap recovery mechanism is arranged on the upper wall of one end, close to the cutting plate, of the bottom plate, the gas purification mechanism is arranged on the upper wall of the bottom plate on one side of the scrap recovery mechanism, the atomization adsorption mechanism is arranged on the side wall of the gas purification mechanism, the scrap recovery mechanism comprises a scrap storage box, an air suction pump, a collecting pipe, an exhaust pipe, a filter plate, an air outlet pipe and a scrap collecting port, the scrap storage box is arranged on the upper wall of the bottom plate below the cutting plate, the air suction pump is arranged on one side, far away from the frame, of the scrap storage box, the collecting pipe penetrates through the frame and is arranged between the guide pipe and the power input end of the air suction pump, the exhaust pipe is arranged between the power output end of the air suction pump and the scrap storage box, and a plurality of air outlet pipes are arranged on one side, far away from the air suction pump, of the scrap storage box, the air outlet pipe is arranged on the side wall of the bottom of the scrap storage box, the filter plate is arranged on the inner wall of one end, close to the air outlet pipe, of the scrap storage box, the plurality of scrap collecting ports are arranged on the side wall of the guide pipe, and the scrap collecting ports are arranged oppositely; the gas purification mechanism comprises a purification box, a partition plate, wide pipes, narrow pipes, mist suction ports, a mixing fan, a filter screen and an exhaust port, wherein the purification box is arranged on the upper wall of a bottom plate on one side, close to the frame, of the scrap storage box, the partition plate is symmetrically arranged on the inner walls of two ends of the purification box, multiple groups of the wide pipes are arranged on the side wall of the partition plate in a penetrating manner, the narrow pipes are communicated and arranged between the wide pipes, the narrow pipes are arranged between the partition plates, multiple groups of the mist suction ports are arranged on the side wall of the narrow pipes, the mixing fan is arranged inside the wide pipes at one end, far away from the air outlet pipe, of the purification box, the exhaust port is arranged on one side, far away from the scrap storage box, of the exhaust pipe penetrates through the purification box and is arranged on the wide pipes, and the filter screen is arranged on the inner wall of one end, far away from the scrap storage box, of the purification box; the atomization and adsorption mechanism comprises an atomization motor, a water storage cavity, a water spray pipe and an atomization pipe, the atomization motor is arranged on the side wall of the purification box, the water storage cavity is arranged between a partition plate at one end of the purification box close to the scrap storage box and the inner wall of the purification box, the atomization pipe is communicated between the water storage cavity and the power input end of the atomization motor, and the water spray pipe is communicated with the side wall of the purification box between the power output end of the atomization motor and the partition plate; cutting knife produces a large amount of chips and chip-containing gas when cutting the board, the produced chips and chip-containing gas are stroked between the bearing boxes, the air suction pump sucks the chips and chip-containing gas into the guide pipe through the chip collecting port, the chips and chip-containing gas enter the chip storage box through the exhaust pipe through the collecting pipe, the chips are filtered by the filter plate and then stay in the chip storage box, the chip-containing gas enters the wide-channel pipe through the air outlet pipe, the atomizing motor extracts water in the water storage cavity through the atomizing pipe, the water is atomized by the atomizing motor and then is discharged into the purifying box between the partition plates through the water mist pipe, the chip-containing gas rapidly passes through the narrow-channel pipe under the support of Venturi effect, the pressure near the high-speed flowing gas is reduced, so that the adsorption effect is generated on the water mist, the chip-containing gas adsorbing the water mist continuously flows to impact the mixing fan, and the mixing fan rotates under the action of impact force, the mixing fan fuses the stirring to containing bits air current and water smoke, and the air current after the stirring is discharged through the gas vent after the filter screen filters, and water smoke can become rivers after assaulting the filter screen, drives the filterable saw-dust of filter screen downwards and flows into the purifying box bottom and save under the gravity factor to avoid taking place the phenomenon of jam.

Specifically, sealed compaction mechanism includes cylinder, compaction axle and compacting plate, the bearing box one side of keeping away from the bar groove is located for a set of symmetry to two liang of cylinders, the compaction axle runs through the bearing box and locates the cylinder power end, the cylinder power end is located to the compacting plate, and inside the bearing box was located to the compacting plate, the cylinder power end extension drove the compacting plate and carries out the compaction fixedly to panel.

Wherein, the frame lateral wall is equipped with the controller.

Preferably, the controller is respectively and electrically connected with the advancing motor, the cutting motor, the air suction pump, the atomizing motor and the cylinder.

Furthermore, one end of the bearing box, which is far away from the cutting plate, is provided with a sealing door and a rotating shaft, the rotating shaft is arranged on the inner wall of the opening of the bearing box, and the sealing door is rotatably arranged on the rotating shaft.

The beneficial effect who adopts above-mentioned structure this scheme to gain is as follows: this scheme provides one kind from root cause department restrain contain bits gaseous production, can independently fuse absorbent from inhaling the formula of fusion and prevent scurrying flow pattern panel cutting equipment for interior decoration from the beneficial effect as follows:

1. the bidirectional cutting structure is combined with the anti-diffusion bearing structure, and the plate is cut accurately in a restraining mode under the intervention of the horizontal advancing mechanism;

2. under the support of a Venturi effect principle, pressure intensity can be reduced near gas flowing at a high speed, so that adsorption is generated, automatic fusion adsorption of chip-containing gas and water mist is achieved, the adsorbed water mist is blocked through the arranged filter screen, the adhered moisture debris is blocked on the side wall of the filter screen due to the increase of a body machine, the water mist can change into water flow after impacting the filter screen, the water flow is accumulated on the surface of the filter screen under the impact of the water mist for a long time, and the wood chips filtered by the filter screen are driven by the water flow to flow downwards to the bottom of the purification box to be stored under the action of gravity;

3. in order to recycle larger scraps, the larger scraps are collected through a preset storage mechanism, so that the subsequent use of the scraps is facilitated;

4. under the matching use of the bearing box, the bidirectional cutting mechanism and the inlet groove, the cutting knife enters the bearing box from the inlet groove, the plate is cut along the strip-shaped groove by the inlet groove without deviation, and scrap-containing gas generated in the cutting process is collected among the bearing boxes in a centralized manner, so that the outflow of the scrap-containing gas is avoided, and the spreading phenomenon of the scrap-containing gas is eliminated from the root part;

5. under the condition of no mixing and stirring equipment, the impact force of the air flow drives the mixing fan to rotate, so that the self-service fusion of the air flow containing the scraps and the water mist is realized;

6. the guide pipe is arranged according to the multipurpose principle, so that on one hand, the guide cutting of the cutting plate is realized, and on the other hand, the automatic collection of the scraps and the scraps-containing air flow is realized, and the intervention of dust collection equipment from the outside is avoided;

7. an automatic structure is adopted, the plate during cutting is prevented from being manually pressed, the plate is automatically compacted through an arranged air cylinder, and a power end of the air cylinder extends to drive a compacting plate to compact and fix the plate;

8. through the arranged middle type bidirectional anti-diffusion parallel cutting mechanism, under the condition that the advancing driving mechanism, the bidirectional cutting mechanism and the dust suppression bearing mechanism are mutually matched for use, and under the interference of the sealing compaction mechanism, automatic positioning cutting of the plate is realized, the use of labor force is greatly reduced, and errors generated by matching among a plurality of driving devices are avoided through single-power driving;

9. the serial treatment of the scraps and the scrap-containing gas is realized through the arranged airflow narrow-passage circulation type high-speed adsorption combination mechanism, and the purification and discharge of the scrap-containing gas and the centralized recycling of larger scraps are completed under the intervention of the scrap recovery mechanism, the gas purification mechanism and the atomization adsorption mechanism;

10. overcome traditional panel cutting means, used manual promotion panel to be close to the mode that the cutter cut.

Drawings

FIG. 1 is a schematic view of the overall structure of a self-suction fusion type anti-channeling flow type cutting apparatus for indoor decoration plates according to the present invention;

FIG. 2 is a first perspective view of a cutting apparatus for self-suction fusion type anti-channeling indoor decoration plate according to the present invention;

FIG. 3 is an exploded view of a self-suction fusion type anti-channeling flow type cutting apparatus for indoor decoration plate material according to the present invention;

FIG. 4 is a front view of the self-suction fusion type anti-channeling indoor decoration plate cutting device according to the present invention;

FIG. 5 is a top view of a self-suction fusion type anti-channeling flow type cutting apparatus for indoor decoration panels according to the present invention;

FIG. 6 is a partial sectional view A-A of FIG. 5;

FIG. 7 is a sectional view of portion B-B of FIG. 4;

FIG. 8 is a side view of a cutting apparatus for a self-suction fusion type anti-channeling indoor decorative sheet proposed in the present embodiment;

fig. 9 is a schematic structural view of a self-suction fusion type anti-channeling flow type advancing driving mechanism of a plate cutting device for interior decoration according to the present invention;

fig. 10 is a schematic structural view of a bidirectional cutting mechanism of a self-suction fusion type anti-channeling flow type plate cutting device for interior decoration according to the present invention;

fig. 11 is a schematic structural view of a self-suction fusion type anti-channeling flow type bearing box of a plate cutting device for interior decoration according to the present invention;

FIG. 12 is a schematic structural view of a gas purification mechanism of a self-suction fusion type anti-channeling flow type cutting apparatus for interior decoration panels according to the present invention;

fig. 13 is a circuit diagram of a self-suction fusion type anti-channeling flow type indoor decoration plate cutting device controller provided by the scheme;

FIG. 14 is a circuit diagram of a traveling motor, a cutting motor and an atomizing motor of the self-absorption fusion type anti-channeling flow type indoor decoration plate cutting device provided by the scheme;

FIG. 15 is a circuit diagram of a suction pump of a self-suction fusion type anti-channeling flow type interior decoration sheet cutting apparatus according to the present invention;

FIG. 16 is a circuit diagram of a cylinder of a self-suction fusion type anti-channeling flow type cutting device for interior decoration panels according to the present invention;

fig. 17 is a schematic block diagram of a self-suction fusion type anti-channeling flow type cutting device for indoor decoration plates according to the scheme.

Wherein, 1, a bottom plate, 2, a bearing column, 3, a frame, 4, an intermediate type bidirectional diffusion-proof parallel cutting mechanism, 5, a traveling driving mechanism, 6, a through groove, 7, a rack, 8, a guide rail, 9, a slide block, 10, a bearing frame, 11, a traveling motor, 12, a gear, 13, a driving shaft, 14, a bidirectional cutting mechanism, 15, a cutting plate, 16, a cutting motor, 17, a motor groove, 18, a cutting groove, 19, a guide port, 20, a guide pipe, 21, a dust suppression bearing mechanism, 22, a connecting column, 23, a bearing box, 24, a strip-shaped groove, 25, an inlet groove, 26, an airflow narrow-passage type high-speed adsorption combining mechanism, 27, a waste scrap recycling mechanism, 28, a scrap storage box, 29, an air suction pump, 30, a collecting pipe, 31, an exhaust pipe, 32, a filter plate, 33, an air outlet pipe, 34, a gas purification mechanism, 35, a purification box, 36, a partition plate, 37, a wide-passage pipe, 38. the device comprises a narrow pipe 39, a mist suction port 40, a mixing fan 41, a filter screen 42, an atomizing adsorption mechanism 43, an atomizing motor 44, a water storage cavity 45, a water mist pipe 46, an atomizing pipe 47, a sealing compaction mechanism 48, a cylinder 49, a compaction shaft 50, a compaction plate 51, a controller 52, a cutting knife 53, an exhaust port 54, a scrap collecting port 55, a sealing door 56 and a rotating shaft.

The accompanying drawings are included to provide a further understanding of the present solution and are incorporated in and constitute a part of this specification, illustrate embodiments of the solution and together with the description serve to explain the principles of the solution and not to limit the solution.

Detailed Description

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 only a part of the embodiments of the present invention, and not all of the embodiments; all other embodiments obtained by a person of ordinary skill in the art based on the embodiments in the present disclosure without any creative effort belong to the protection scope of the present disclosure.

In the description of the present solution, it is to be understood that the terms "upper", "lower", "front", "rear", "left", "right", "top", "bottom", "inner", "outer", etc. indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and simplicity of description, but do not indicate or imply that the device or element referred to must have a specific orientation, be constructed and operated in a specific orientation, and thus, should not be construed as limiting the present solution.

As shown in fig. 1-3, the present invention provides a self-absorption fusion type anti-channeling indoor decoration plate cutting apparatus, which comprises a bottom plate 1, a bearing column 2, a frame 3, an intermediate type bidirectional anti-diffusion parallel cutting mechanism 4, an airflow narrow-passage circulation type high-speed adsorption combining mechanism 26 and a sealing and compacting mechanism 47, wherein the bearing column 2 is symmetrically arranged at two ends of the upper wall of the bottom plate 1 in pairs, the frame 3 is arranged at one side of the bearing column 2 away from the bottom plate 1, the intermediate type bidirectional anti-diffusion parallel cutting mechanism 4 is arranged on the frame 3, the airflow narrow-passage circulation type high-speed adsorption combining mechanism 26 is arranged on the upper wall of the bottom plate 1, the sealing and compacting mechanism 47 is arranged on the intermediate type bidirectional anti-diffusion parallel cutting mechanism 4, the intermediate type bidirectional anti-diffusion parallel cutting mechanism 4 comprises a traveling driving mechanism 5, a bidirectional cutting mechanism 14 and a dust suppression bearing mechanism 21, the traveling driving mechanism 5 is arranged on the inner wall of the frame 3, the two-way cutting mechanism 14 is arranged between the advancing driving mechanisms 5, and the dust suppression bearing mechanism 21 is arranged inside the frame 3 at one side of the two-way cutting mechanism 14.

As shown in fig. 7 and 9, the traveling driving mechanism 5 includes a through groove 6, a rack 7, a guide rail 8, a slider 9, a carrier 10, a traveling motor 11, a gear 12 and a driving shaft 13, the through groove 6 is symmetrically disposed on the inner walls of both sides of the frame 3, the through groove 6 is through-disposed, the rack 7 is symmetrically disposed on the upper wall and the bottom wall of the through groove 6, the guide rails 8 are symmetrically disposed on the upper wall and the bottom wall of the frame 3 in pairs, the slider 9 is slidably disposed on the guide rail 8, the carrier 10 is disposed on a side of the slider 9 away from the guide rail 8, the traveling motor 11 is disposed on one end of the carrier 10 away from the slider 9, the driving shaft 13 is disposed on the power end of the traveling motor 11, the gear 12 is disposed on one end of the driving shaft 13 away from the traveling motor 11, the gear 12 is disposed between the racks 7, and the gear 12 is engaged with the rack 7; as shown in fig. 3, 5, 7 and 10, the bidirectional cutting mechanism 14 includes a cutting plate 15, a cutting motor 16, a motor groove 17, a cutting groove 18, a guide port 19, a guide tube 20 and a cutting blade 52, the cutting plate 15 is disposed between the driving shafts 13, the driving shafts 13 are rotatably disposed on the side walls of the cutting plate 15, the guide ports 19 are symmetrically disposed on the side walls of the cutting plate 15, the guide tube 20 penetrates through the guide port 19 and is disposed on the inner wall of the frame 3, the cutting groove 18 is disposed at the middle position of the upper wall of the cutting plate 15, the cutting groove 18 is disposed in a penetrating manner, the motor groove 17 is disposed on the upper wall of the cutting plate 15 on one side of the cutting groove 18, the motor groove 17 is disposed in a penetrating manner, the cutting motor 16 is disposed in the motor groove 17, the power end of the cutting motor 16 penetrates through the inner wall of the motor groove 17 and is rotatably disposed on the inner wall of the cutting groove 18, the cutting blade 52 is disposed on the power end of the cutting motor 16, and the cutting blade 52 is disposed in the cutting groove 18; as shown in fig. 11, the dust suppression bearing mechanism 21 includes a connection column 22, a bearing box 23, strip-shaped grooves 24 and an inlet groove 25, the bearing box 23 is symmetrically disposed above and below the cutting plate 15, the bearing box 23 is disposed inside the frame 3 on one side of the cutting plate 15, multiple groups of the connection columns 22 are disposed between the side wall of the bearing box 23 and the inner wall of the frame 3, the bearing box 23 is a cavity with an open end, the strip-shaped grooves 24 are disposed on the side wall of the bearing box 23, the strip-shaped grooves 24 are arranged in a through manner, the strip-shaped grooves 24 are oppositely disposed, the inlet groove 25 is disposed on one side of the bearing box 23 close to the cutting plate 15, the inlet groove 25 is arranged in a through manner, and the strip-shaped grooves 24 are communicated with the strip-shaped grooves 24; the driving shaft 13 is driven by the advancing motor 11 to rotate, the driving shaft 13 drives the gear 12 to rotate, the gear 12 is meshed with the rack 7, the gear 12 rolls along the rack 7 to advance, the advancing motor 11 drives the bearing frame 10 to move, the bearing frame 10 slides along the guide rail 8 through the sliding block 9 to enable the advancing motor 11 to stably advance, the driving shaft 13 rotates around the side wall of the cutting plate 15 in the moving process, the driving shaft 13 drives the cutting plate 15 to horizontally move, the cutting motor 16 drives the cutting knife 52 to rotate through the power end, the plate is placed inside the bearing box 23 through the opening, the cutting knife 52 enters the bearing box 23 through the inlet groove 25 in the advancing process, and the cutting knife 52 moves along the strip-shaped groove 24 to cut the plate placed inside the bearing box 23.

As shown in fig. 1, the airflow narrow-passage circulation type high-speed adsorption combining mechanism 26 includes a scrap recovery mechanism 27, a gas purification mechanism 34 and an atomization adsorption mechanism 42, the scrap recovery mechanism 27 is disposed on the upper wall of one end of the bottom plate 1 close to the cutting plate 15, the gas purification mechanism 34 is disposed on the upper wall of the bottom plate 1 on one side of the scrap recovery mechanism 27, and the atomization adsorption mechanism 42 is disposed on the side wall of the gas purification mechanism 34; as shown in fig. 3, 4 and 6, the scrap recycling mechanism 27 includes a scrap storage box 28, an air pump 29, a collecting pipe 30, an air exhaust pipe 31, a filter plate 32, an air outlet pipe 33 and a scrap collecting port 54, the scrap storage box 28 is disposed on the upper wall of the bottom plate 1 below the cutting plate 15, the air pump 29 is disposed on one side of the scrap storage box 28 away from the frame 3, the collecting pipe 30 penetrates through the frame 3 and is communicated between the guide pipe 20 and the power input end of the air pump 29, the air exhaust pipe 31 is communicated between the power output end of the air pump 29 and the scrap storage box 28, multiple sets of air outlet pipes 33 are communicated with one side of the scrap storage box 28 away from the air pump 29, the air outlet pipe 33 is disposed on the bottom side wall of the scrap storage box 28, the filter plate 32 is disposed on the inner wall of one end of the scrap storage box 28 close to the air outlet pipe 33, multiple sets of scrap collecting ports 54 are disposed on the side wall of the guide pipe 20, and the scrap collecting ports 54 are disposed opposite to each other; as shown in fig. 4, 6 and 12, the gas purifying mechanism 34 includes a purifying box 35, a partition 36, a wide pipe 37, a narrow pipe 38, a mist suction port 39, a mixing fan 40, a filter screen 41 and an exhaust port 53, the purifying box 35 is disposed on the upper wall of the bottom plate 1 on one side of the scrap storage box 28 close to the frame 3, the partition 36 is symmetrically disposed on the inner walls of both ends of the purifying box 35, a plurality of groups of wide pipes 37 are disposed on the side wall of the partition 36, the narrow pipes 38 are disposed between the wide pipes 37, the narrow pipes 38 are disposed between the partitions 36, a plurality of groups of mist suction ports 39 are disposed on the side wall of the narrow pipes 38, the mixing fan 40 is disposed inside the wide pipe 37 on one end of the purifying box 35 far from the air outlet pipe 33, the exhaust port 53 is disposed on one side of the purifying box 35 far from the scrap storage box 28, one end of the exhaust pipe 31 far from the scrap storage box 28 is disposed on the wide pipe 37, and the filter screen 41 is disposed on the inner wall on one end of the purifying box 35 far from the scrap storage box 28; as shown in fig. 2, the atomizing adsorption mechanism 42 includes an atomizing motor 43, a water storage chamber 44, a water mist pipe 45 and an atomizing pipe 46, the atomizing motor 43 is disposed on the side wall of the purifying tank 35, the water storage chamber 44 is disposed between the partition plate 36 at one end of the purifying tank 35 close to the chip storage tank 28 and the inner wall of the purifying tank 35, the atomizing pipe 46 is communicated between the water storage chamber 44 and the power input end of the atomizing motor 43, and the water mist pipe 45 is communicated with the side wall of the purifying tank 35 between the power output end of the atomizing motor 43 and the partition plate 36; the cutting knife 52 generates a large amount of chips and chip-containing gas when cutting the plate, the generated chips and chip-containing gas go around between the carrying boxes 23, the suction pump 29 sucks the chips and chip-containing gas into the guide pipe 20 through the chip collecting port 54, the chips and chip-containing gas enter the chip storage box 28 through the exhaust pipe 31 through the collecting pipe 30, the chips are filtered by the filter plate 32 and then stay in the chip storage box 28, the chip-containing gas enters the wide pipe 37 through the outlet pipe 33, the atomizing motor 43 sucks water in the water storage cavity 44 through the atomizing pipe 46, the water is atomized by the atomizing motor 43 and then is discharged into the purifying box 35 between the partition plates 36 through the water mist pipe 45, the chip-containing gas rapidly passes through the narrow pipe 38 under the support of the venturi effect, the pressure near the gas flowing at high speed can be reduced, so that the adsorption effect is generated on the water mist, the chip-containing gas adsorbing the water mist continuously flows to impact the mixing fan 40, mix fan 40 and take place to rotate under the effect of impact force, mix fan 40 and merge the stirring to containing bits air current and water smoke, and the air current after the stirring is discharged through gas vent 53 after filter 41 filters, and water smoke can become rivers after assaulting filter 41, drives the filterable saw-dust of filter 41 and flows into the purifying box 35 bottom downwards and save under the gravity factor to avoid taking place the phenomenon of jam.

As shown in fig. 2 and 6, the sealing and compacting mechanism 47 includes a cylinder 48, a compacting shaft 49 and a compacting plate 50, the cylinder 48 is symmetrically disposed on one side of the carrying box 23 away from the strip-shaped groove 24, the compacting shaft 49 penetrates through the carrying box 23 and is disposed at a power end of the cylinder 48, the compacting plate 50 is disposed at the power end of the cylinder 48, the compacting plate 50 is disposed inside the carrying box 23, and the power end of the cylinder 48 extends to drive the compacting plate 50 to compact and fix the plate.

As shown in fig. 1, the side wall of the frame 3 is provided with a controller 51.

As shown in fig. 13 to 16, the controller 51 is electrically connected to the travel motor 11, the cutting motor 16, the suction pump 29, the atomizing motor 43, and the air cylinder 48, respectively.

As shown in fig. 8, a sealing door 55 and a rotating shaft 56 are provided at an end of the carrying case 23 away from the cutting board 15, the rotating shaft 56 is provided at an inner wall of an opening of the carrying case 23, and the sealing door 55 is rotatably provided at the rotating shaft 56.

In particular, in the initial state, the cutting plate 15 is positioned above the scrap box 28, and the sealing door 55 is rotated about the rotating shaft 56 to maintain the vertical state.

In the first embodiment, the plate to be cut is positioned.

Specifically, pulling sealing door 55, sealing door 55 rotates around pivot 56 and opens, places the weight of box 23 inside with panel, and one side that sealing door 55 was kept away from to panel offsets with the inner wall of weight of box 23, places and accomplishes back sealing door 55 and rotates around pivot 56 and close, and controller 51 control cylinder 48 starts, and cylinder 48 power end extension drives compacting plate 50 and carries out the compaction to panel fixedly.

In the second embodiment, the positioned plate is cut based on the above embodiment.

Specifically, the controller 51 controls the cutting motor 16 to start, the cutting motor 16 drives the cutting blade 52 to rotate at a high speed through a power end, the rotating shaft 56 controls the advancing motor 11 to start, the advancing motor 11 drives the driving shaft 13 to rotate, the driving shaft 13 drives the gear 12 to rotate, the gear 12 is meshed with the rack 7, the gear 12 rolls along the rack 7 to advance, the advancing motor 11 drives the bearing frame 10 to move, the bearing frame 10 slides along the guide rail 8 through the slide block 9 to enable the advancing motor 11 to stably advance, the driving shaft 13 rotates around the side wall of the cutting plate 15 in the moving process, the driving shaft 13 drives the cutting plate 15 to horizontally move, the cutting plate 15 moves along the guide pipe 20 through the guide port 19, the cutting plate 15 drives the cutting blade 52 to enter the bearing box 23 through the inlet slot 25 to cut the plate, the cutting blade 52 moves along the strip-shaped slot 24 to perform bidirectional cutting on the plate placed in the bearing box 23, after the two plates are cut, the rotating shaft 56 controls the advancing motor 11 to start to drive the cutting knife 52 to return to the initial position, the sealing door 55 is pulled, the sealing door 55 rotates around the rotating shaft 56 to be opened, the rotating shaft 56 controls the cylinder 48 to start, the power end of the cylinder 48 is shortened to drive the compacting plate 50 to be far away from the plates, the plates are taken out of the bearing box 23 after being in a loose state, new plates are put into the bearing box, and the positioning and fixing of the plates are completed by repeating the positioning operation.

Third embodiment, this embodiment is based on the above embodiment, and carries out the environmental protection emission to the dirty gas that produces in the panel cutting process.

Specifically, when the cutting knife 52 cuts the sheet material, a large amount of chips and chip-containing gas are generated, the generated chips and chip-containing gas wander between the carrying boxes 23, the controller 51 controls the air pump 29 to start, the air pump 29 sucks the chips and the chip-containing gas into the guide pipe 20 through the chip collecting port 54, the chips and the chip-containing gas enter the chip storage box 28 through the air exhaust pipe 31 via the collecting pipe 30, the chips are filtered by the filter plate 32 and then remain in the chip storage box 28, the chip-containing gas enters the wide pipe 37 through the air exhaust pipe 33, the atomizing motor 43 extracts moisture in the water storage cavity 44 through the atomizing pipe 46, the moisture is atomized by the atomizing motor 43 and then is discharged into the purifying box 35 between the partition plates 36 through the water mist pipe 45, the chip-containing gas rapidly passes through the narrow pipe 38 under the support of the venturi effect, and pressure reduction is generated near the gas flowing at high speed, therefore, the water mist is adsorbed, the chip-containing gas adsorbing the water mist continuously flows to impact the mixing fan 40, the mixing fan 40 rotates under the action of impact force, the chip-containing gas flow and the water mist are mixed and stirred by the mixing fan 40, the stirred gas flow is filtered by the filter screen 41 and then discharged through the exhaust port 53, the water mist is changed into water flow after impacting the filter screen 41, sawdust filtered by the filter screen 41 is driven to flow downwards to the bottom of the purification box 35 to be stored under the action of gravity, and therefore the phenomenon of blockage is avoided; repeating the above operations when using the product for the next time.

It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

Although embodiments of the present solution have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the solution, the scope of which is defined in the appended claims and their equivalents.

The present solution and its embodiments have been described above, but the description is not limited thereto, and what is shown in the drawings is only one of the embodiments of the present solution, and the actual structure is not limited thereto. In summary, those skilled in the art should appreciate that they can readily use the present disclosure without inventive faculty to devise similar arrangements and embodiments without departing from the spirit and scope of the present disclosure.

Claims (10)

1. The utility model provides a from inhaling formula of fusion anti-channeling flow pattern for interior decoration board cutting equipment, includes bottom plate (1), bears post (2) and frame (3), its characterized in that: the device is characterized by further comprising an intermediate bidirectional diffusion-proof parallel cutting mechanism (4), an airflow narrow-passage circulating high-speed adsorption combination mechanism (26) and a sealing compaction mechanism (47), wherein every two bearing columns (2) are symmetrically arranged at two ends of the upper wall of the bottom plate (1) in a group, the frame (3) is arranged on one side, away from the bottom plate (1), of the bearing columns (2), the intermediate bidirectional diffusion-proof parallel cutting mechanism (4) is arranged on the frame (3), the airflow narrow-passage circulating high-speed adsorption combination mechanism (26) is arranged on the upper wall of the bottom plate (1), the sealing compaction mechanism (47) is arranged on the intermediate bidirectional diffusion-proof parallel cutting mechanism (4), the intermediate bidirectional diffusion-proof parallel cutting mechanism (4) comprises an advancing driving mechanism (5), a bidirectional cutting mechanism (14) and a dust suppression bearing mechanism (21), the advancing driving mechanism (5) is arranged on the inner wall of the frame (3), the bidirectional cutting mechanism (14) is arranged between the advancing driving mechanisms (5), and the dust suppression bearing mechanism (21) is arranged inside the frame (3) on one side of the bidirectional cutting mechanism (14).

2. The cutting apparatus for a self-suction fusion type anti-channeling flow-through type interior decoration plate material as claimed in claim 1, wherein: the advancing driving mechanism (5) comprises a through groove (6), a rack (7), a guide rail (8), a sliding block (9), a bearing frame (10), an advancing motor (11), a gear (12) and a driving shaft (13), wherein the through groove (6) is symmetrically arranged on the inner walls of two sides of the frame (3), the through groove (6) is arranged in a through manner, the rack (7) is symmetrically arranged on the upper wall and the bottom wall of the through groove (6), the guide rail (8) is symmetrically arranged on the upper wall and the bottom wall of the frame (3) in a group, the sliding block (9) is arranged on the guide rail (8) in a sliding manner, the bearing frame (10) is arranged on one side of the sliding block (9) far away from the guide rail (8), the advancing motor (11) is arranged at one end of the bearing frame (10) far away from the sliding block (9), the driving shaft (13) is arranged at the power end of the advancing motor (11), and the gear (12) is arranged at one end of the driving shaft (13) far away from the advancing motor (11), the gear (12) is arranged between the racks (7), and the gear (12) is meshed with the racks (7).

3. The cutting apparatus for a self-suction fusion type anti-channeling flow-through type interior decoration plate material as claimed in claim 2, wherein: the bidirectional cutting mechanism (14) comprises a cutting plate (15), a cutting motor (16), a motor groove (17), a cutting groove (18), a guide port (19), a guide pipe (20) and a cutting knife (52), wherein the cutting plate (15) is arranged between driving shafts (13), the driving shafts (13) are rotatably arranged on the side walls of the cutting plate (15), the guide port (19) is symmetrically arranged on the side walls of the cutting plate (15), the guide pipe (20) penetrates through the guide port (19) and is arranged on the inner wall of a frame (3), the cutting groove (18) is arranged at the middle position of the upper wall of the cutting plate (15), the cutting groove (18) is arranged in a penetrating way, the motor groove (17) is arranged on the upper wall of the cutting plate (15) on one side of the cutting groove (18), the cutting motor (16) is arranged in the motor groove (17) in a penetrating way, the power end of the cutting motor (16) penetrates through the inner wall of the motor groove (17) and is rotatably arranged on the inner wall of the cutting groove (18), the cutting knife (52) is arranged at the power end of the cutting motor (16), and the cutting knife (52) is arranged in the cutting groove (18).

4. The cutting apparatus for a self-suction fusion type anti-channeling flow-through type interior decoration plate material as claimed in claim 3, wherein: press down dirt and bear mechanism (21) including spliced pole (22), bearing box (23), bar groove (24) and import groove (25), bearing box (23) symmetry is located the top and the below of sanction board (15), and inside frame (3) of sanction board (15) one side were located in bearing box (23), between bearing box (23) lateral wall and frame (3) inner wall was located to spliced pole (22) multiunit, bearing box (23) are one end open-ended cavity, bearing box (23) lateral wall is located in bar groove (24), and bar groove (24) set up for lining up, bar groove (24) set up relatively, one side that bearing box (23) is close to sanction board (15) is located in import groove (25), and bar groove (24) are linked together with bar groove (24) for lining up the setting up in import groove (25).

5. The cutting apparatus for a self-suction fusion type anti-channeling flow-through type interior decoration plate material as claimed in claim 4, wherein: airflow narrow passage circulation type high-speed adsorption combination mechanism (26) includes that the sweeps retrieves mechanism (27), gaseous purification mechanism (34) and atomizing adsorption mechanism (42), the sweeps is retrieved mechanism (27) and is located one of bottom plate (1) and is served the wall near cutting board (15), gaseous purification mechanism (34) are located bottom plate (1) upper wall that the sweeps retrieved mechanism (27) one side, gaseous purification mechanism (34) lateral wall is located in atomizing adsorption mechanism (42).

6. The cutting apparatus for a self-suction fusion type anti-channeling flow-through type interior decoration plate material as claimed in claim 5, wherein: the scrap recycling mechanism (27) comprises a scrap storage box (28), an air suction pump (29), a collecting pipe (30), an exhaust pipe (31), a filter plate (32), an air outlet pipe (33) and a scrap collecting port (54), wherein the scrap storage box (28) is arranged on the upper wall of the bottom plate (1) below the cutting plate (15), the air suction pump (29) is arranged on one side, away from the frame (3), of the scrap storage box (28), the collecting pipe (30) penetrates through the frame (3) and is communicated between the guide pipe (20) and the power input end of the air suction pump (29), the exhaust pipe (31) is communicated between the power output end of the air suction pump (29) and the scrap storage box (28), a plurality of groups of air outlet pipes (33) are communicated with one side, away from the air suction pump (29), of the air outlet pipes (33) are arranged on the bottom side wall of the scrap storage box (28), the filter plate (32) is arranged on the inner wall of one end, close to the air outlet pipe (33), of the scrap storage box (28), a plurality of groups of chip collecting openings (54) are arranged on the side wall of the guide pipe (20), and the chip collecting openings (54) are arranged oppositely.

7. The cutting apparatus for a self-suction fusion type anti-channeling flow-through type interior decoration plate material as claimed in claim 6, wherein: the gas purification mechanism (34) comprises a purification box (35), a partition plate (36), a wide pipeline (37), a narrow pipeline (38), a mist suction port (39), a mixing fan (40), a filter screen (41) and an exhaust port (53).

8. The cutting apparatus for a self-suction fusion type anti-channeling flow-through type interior decoration plate material as claimed in claim 7, wherein: the purification box (35) is arranged on the upper wall of the bottom plate (1) at one side of the scrap storage box (28) close to the frame (3), the partition plates (36) are symmetrically arranged on the inner walls of the two ends of the purifying box (35), a plurality of groups of wide-channel pipes (37) are arranged on the side walls of the partition plates (36) in a penetrating way, the narrow-channel pipes (38) are communicated and arranged between the wide-channel pipes (37), the narrow-channel pipes (38) are arranged between the partition plates (36), a plurality of groups of the mist absorbing openings (39) are arranged on the side wall of the narrow channel pipe (38), the mixing fan (40) is arranged inside the wide channel pipe (37) at one end of the purifying box (35) far away from the air outlet pipe (33), the exhaust port (53) is arranged on one side of the purifying box (35) far away from the scrap storage box (28), one end of the exhaust pipe (31) far away from the scrap storage box (28) penetrates through the purification box (35) and is communicated with the wide-channel pipe (37), the filter screen (41) is arranged on the inner wall of one end of the purifying box (35) far away from the scrap storage box (28).

9. The cutting apparatus for a self-suction fusion type anti-channeling flow-through type interior decoration plate material as claimed in claim 8, wherein: atomizing adsorption apparatus constructs (42) including atomizing motor (43), water storage chamber (44), water smoke pipe (45) and atomizing pipe (46), purifying box (35) lateral wall is located in atomizing motor (43), baffle (36) and purifying box (35) inner wall that purifying box (35) are close to storage bits case (28) one end are located in water storage chamber (44), atomizing pipe (46) intercommunication is located between water storage chamber (44) and atomizing motor (43) power input end, purifying box (35) lateral wall between atomizing motor (43) power output end and baffle (36) is located in water smoke pipe (45) intercommunication.

10. The cutting apparatus for a self-suction fusion type anti-channeling flow-through type interior decoration plate material as claimed in claim 9, wherein: sealed compaction mechanism (47) include cylinder (48), compaction axle (49) and compacting plate (50), two liang of being a set of symmetry in cylinder (48) locate the one side of keeping away from bar groove (24) of bearing box (23), compaction axle (49) run through bearing box (23) and locate cylinder (48) power end, cylinder (48) power end is located in compacting plate (50), and compacting plate (50) are located inside bearing box (23).

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