CN114889336B - Auxiliary feeding equipment convenient for laser printing - Google Patents

Abstract

The invention relates to a feeding device, in particular to an auxiliary feeding device convenient for laser printing. The technical problems to be solved are as follows: the auxiliary feeding equipment for the laser printing is convenient for automatically transporting raw materials to finish laser printing and transporting the raw materials after the laser printing is finished. The technical scheme of the invention is as follows: an auxiliary feeding device convenient for laser printing comprises a shell, a base, a controller, an observation window and the like; the middle of the upper part of the shell is provided with an opening, the left side of the upper part of the shell is provided with a blanking opening, the right front side of the lower part of the shell is provided with a rectangular groove, the left side and the right side of the lower part of the shell are both connected with a base, the left front side of the upper part of the shell is provided with a controller, and the middle of the upper part of the shell is provided with an observation window. According to the invention, the connecting rod is driven to move leftwards through the object placing plate and is matched with the wedge-shaped rod, the pressing rod is driven to move downwards, and the contact rod and the baffle are pushed to move outwards, so that raw materials fall on the object placing plate, and the effect of automatic quantitative feeding is achieved.

Description

Auxiliary feeding equipment convenient for laser printing

Technical Field

The invention relates to a feeding device, in particular to an auxiliary feeding device convenient for laser printing.

Background

At present, when carrying out laser printing, need people to settle the raw materials manually to after the raw materials is printed, take out the raw materials again manually, consume the manpower, and inefficiency, secondly when laying the raw materials, can't guarantee once just can the raw materials to put, if the raw materials do not put regular can influence final raw materials printing result, at the same time after the raw materials is printed, the raw materials if directly falls out, then not only is inconvenient to collect and probably leads to the raw materials to be damaged.

Therefore, it is necessary to develop an auxiliary feeding device for laser printing, which can automatically transport raw materials to complete laser printing and can transport out the raw materials after laser printing.

Disclosure of Invention

In order to overcome the defects in the prior art, the technical problems to be solved are as follows: the auxiliary feeding equipment for the laser printing is convenient for automatically transporting raw materials to finish laser printing and transporting the raw materials after the laser printing is finished.

The technical scheme of the invention is as follows: auxiliary feeding equipment for laser printing is convenient for, including: the base is connected with two sides of the lower part of the shell; the controller is arranged on one side of the upper part of the shell; the observation window is arranged in the middle of the upper part of the shell, and is convenient for observing the condition of raw materials; the movable assembly is arranged at the lower side of the inner part of the shell; and the placing component is arranged between the lower side of the inner part of the shell and the moving component.

As a preferred technical solution of the present invention, the moving assembly includes: the first support frame is symmetrically connected with the lower side of the inner part of the shell; the first guide rods are symmetrically connected between the first support frames; the screw rod is rotatably connected between the middle parts of the first support frames; the sliding plate is connected with the screw rod through threads and is in sliding connection with the first guide rod; the motor is arranged on one side of the lower part in the shell, and one side of an output shaft of the motor is connected with the screw rod; the first idler wheels are rotatably connected to two sides of the lower portion of the sliding plate.

As a preferred technical solution of the present invention, the placement component includes: the contact frame is symmetrically connected with the lower side of the inner part of the shell; the two sides of the upper part of the sliding plate are connected with the first sliding sleeve; the inner sides of the first sliding sleeves are connected with the second sliding sleeves in a sliding manner; the object placing plate is connected between the upper parts of the second sliding sleeves; and the two sides of the lower part of the object placing plate are both rotationally connected with the second roller which is contacted with the contact frame.

As a preferable technical scheme of the invention, the invention also comprises a blanking component, wherein the blanking component comprises: the second support frame is connected to one side of the lower part in the shell; the blanking cylinder is connected to one side of the upper part of the second support frame, and the upper part of the blanking cylinder is connected with the shell; the second guide rods are symmetrically connected between the two sides of the lower part of the blanking cylinder and the shell; the baffle plate is connected between the second guide rods at both sides in a sliding manner; the first springs are symmetrically connected between the baffle plate and the blanking barrel, and the first springs are wound on the second guide rod; the blanking cylinder is connected with the first guide rod; the third guide rod is connected with the compression rod in a sliding manner; the second spring is connected between the compression bar and the third guide rod and is wound on the third guide rod; the middle of the outer side of the upper part of the baffle is connected with the contact rods which are contacted with the downward moving compression bars; the wedge-shaped rods are connected to two sides of the compression bar; the connecting rods are symmetrically connected with one side of the lower part of the object placing plate and then contact with the wedge-shaped rods after moving leftwards.

As a preferable technical scheme of the invention, the invention also comprises a material returning component, wherein the material returning component comprises: the lower part side in the shell is connected with the fourth guide rod; the fourth guide rod is connected with the movable frame in a sliding manner; the third spring is connected between the movable frame and the shell and is wound on the fourth guide rod; the push plate is connected to one side of the upper part of the movable frame; the groove drum is rotatably connected to one side of the lower part in the shell, and the movable frame is pushed to move forwards when the groove drum rotates; the ratchet wheel is connected to one side of the groove drum; the sliding rail is connected to one side of the lower part in the shell; the sliding block is connected to the inner side of the sliding rail in a sliding manner; the sliding block is connected with the sliding rail through a first spring; the upper part of the sliding block is connected with the supporting rod; the wedge-shaped block is connected with one side of the upper part of the supporting rod in a sliding manner and is contacted with the connecting rod at one side after rightward movement; the fifth spring is connected between the wedge block and the supporting rod; a ratchet bar, wherein one side of the lower part of the supporting rod is connected with the ratchet bar which can be meshed with the ratchet wheel when moving leftwards in a sliding manner; the ratchet bar and the supporting rod are uniformly connected with four sixth springs at intervals; the fixed rod is connected with one side of the lower part in the shell, and the fixed rod contacted with the wedge-shaped block after rightward movement is connected with one side of the lower part in the shell.

As a preferable technical scheme of the invention, the invention also comprises a centering component, wherein the centering component comprises: the two sides of the lower part of the storage plate are connected with the fifth guide rod; the sliding frame is connected between the fifth guide rods in a sliding manner; the seventh springs are symmetrically connected between the sliding frame and the object placing plate, and the seventh springs are wound on the fifth guide rod; the pushing blocks are uniformly connected with the upper part of the sliding frame at intervals and are connected with the object placing plate in a sliding mode; the special-shaped rods are connected with two sides of the lower part of the sliding frame respectively, and the special-shaped rods are in contact with the contact frame.

As a preferable technical scheme of the invention, the invention further comprises a collecting component, wherein the collecting component is arranged at one side of the lower part of the shell.

As a preferred technical solution of the present invention, the collecting assembly includes: the discharging plate is connected to one side of the lower part of the shell and is positioned on the lower side of the rectangular groove of the shell; the third support frame is connected to one side of the lower part of the shell; the collecting frame is connected with one side of the third supporting frame and is used for collecting raw materials; the movable plate is connected with the inner side of the collecting frame in a sliding manner and is used for buffering; and the eighth springs are symmetrically connected between the movable plate and the collecting frame.

The beneficial effects are that: (1) According to the invention, the connecting rod is driven to move leftwards through the object placing plate and is matched with the wedge-shaped rod, the pressing rod is driven to move downwards, and the contact rod and the baffle are pushed to move outwards, so that raw materials fall on the object placing plate, and the effect of automatic quantitative feeding is achieved.

(2) According to the invention, the wedge-shaped block and the ratchet bar are pushed to move rightwards by the connecting rod, and the wedge-shaped block is matched with the fixed rod, so that the ratchet bar moves leftwards and resets, the ratchet and the grooved drum are driven to rotate, the movable frame and the push plate are pushed to move forwards, the raw materials are pushed out, the effect of automatically pushing out the raw materials after laser printing is achieved, and the efficiency is improved.

(3) According to the invention, the special-shaped rod is driven by the object placing plate to move leftwards and away from the contact frame, so that the pushing block moves downwards to reset, after the raw materials fall on the object placing plate, the special-shaped rod is driven by the object placing plate to move rightwards, the special-shaped rod is driven by the contact frame to move upwards, the pushing block is driven to move upwards, the raw material straightening effect is automatically driven, and the raw materials can be accurately printed.

(4) According to the invention, after the raw materials are pushed out, the raw materials slide down onto the movable plate along the discharging plate to push the movable plate to move downwards, and finally, the raw materials are taken away from the movable plate, so that the effect of collecting the raw materials after laser printing is convenient, the buffering effect can be achieved, and the raw materials are prevented from being damaged.

Drawings

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

Fig. 2 is a schematic perspective view of a first part of the present invention.

Fig. 3 is a schematic perspective view of a second part of the present invention.

Fig. 4 is a schematic perspective view of a third portion of the present invention.

Fig. 5 is a schematic perspective view of a first part of a moving assembly according to the present invention.

Fig. 6 is a schematic perspective view of a second part of the moving assembly of the present invention.

Fig. 7 is a schematic view of the installation of the placement module of the present invention.

Fig. 8 is a schematic view of a partial perspective view of a placement module according to the present invention.

Fig. 9 is a schematic installation view of the blanking assembly of the present invention.

Fig. 10 is an enlarged view of section a of the present invention.

Fig. 11 is a schematic partial perspective view of a blanking assembly according to the present invention.

Fig. 12 is a schematic view of a part of a perspective structure of a blanking assembly and a placement assembly according to the present invention.

Fig. 13 is a schematic view of the installation of the reject assembly of the present invention.

Fig. 14 is a schematic partial perspective view of a material returning assembly according to the present invention.

FIG. 15 is a schematic view of the installation of the centering assembly of the present invention.

Fig. 16 is a schematic installation view of the collection assembly of the present invention.

Wherein: 1-base, 2-housing, 3-controller, 4-viewing window, 5-moving assembly, 501-first support frame, 502-first guide bar, 503-lead screw, 504-motor, 505-slide, 506-first roller, 6-placement assembly, 601-contact frame, 602-first slide, 603-second slide, 604-placement plate, 605-second roller, 7-blanking assembly, 701-second support frame, 702-blanking cylinder, 703-second guide bar, 704-baffle, 705-first spring, 706-third guide bar, 707-plunger, 708-second spring, 709-contact bar, 710-wedge bar, 711-link, 8-return assembly, 801-fourth guide bar, 802-movable frame, 803-third spring, 804-push plate, 805-slot cylinder, 806-ratchet, 807-slide, 808-slide, 809-fourth spring, 810-support bar, 811-wedge block, 812-fifth spring, 813-rack, 814-sixth spring, 815-fixed bar, 1003-9-guide bar, 709-second spring, 709-third spring, 803-third spring, 804-push plate, 805-collection plate, 1005-collection plate, eight-collection plate, 10-support frame, and others.

Detailed Description

The invention will now be described in more detail with reference to the drawings and specific examples, which are not intended to limit the invention thereto.

Example 1

The utility model provides an auxiliary feeding equipment for laser printing of being convenient for, as shown in fig. 1-8, including base 1, shell 2, controller 3, observation window 4, remove subassembly 5 and place subassembly 6, open in the middle of shell 2 upper portion has the opening, open in shell 2 upper portion left side has the blanking mouth, open in shell 2 lower part right front side has the rectangular channel, shell 2 lower part left and right sides all is connected with base 1, controller 3 is installed to shell 2 upper portion left front side, install observation window 4 in the middle of the shell 2 upper portion, the inside downside of shell 2 is equipped with removes subassembly 5, be equipped with between shell 2 inside downside and remove subassembly 5 and place subassembly 6.

The moving assembly 5 comprises a first supporting frame 501, a first guide rod 502, a screw rod 503, a motor 504, a sliding plate 505 and a first roller 506, wherein the left side and the right side of the lower part of the inner part of the shell 2 are symmetrically connected with the first supporting frame 501, the front side and the rear side of the inner part of the shell 2 are symmetrically connected with the first guide rod 502, the screw rod 503 is rotationally connected between the middle parts of the first supporting frames 501, the sliding plate 505 is connected with the screw rod 503 through threads, the sliding plate 505 is slidably connected with the first guide rod 502, the right side of the lower part of the inner part of the shell 2 is provided with the motor 504, the left side of an output shaft of the motor 504 is connected with the screw rod 503, and the front side and the rear side of the lower part of the sliding plate 505 are rotationally connected with the first roller 506.

The placing assembly 6 comprises a contact frame 601, a first sliding sleeve 602, a second sliding sleeve 603, a placing plate 604 and a second roller 605, wherein the contact frame 601 is symmetrically connected with the front side and the rear side of the lower part of the inner part of the shell 2, the front side and the rear side of the upper part of the sliding plate 505 are respectively connected with the first sliding sleeve 602, the inner side of the first sliding sleeve 602 is respectively connected with the second sliding sleeve 603 in a sliding manner, the placing plate 604 is connected between the upper parts of the second sliding sleeve 603, the front side and the rear side of the lower part of the placing plate 604 are respectively connected with the second roller 605 in a rotating manner, and the second roller 605 is in contact with the contact frame 601.

When a user needs to use the device to print and feed materials for laser, firstly, the motor 504 is started forward by controlling the controller 3 to drive the screw rod 503 to rotate forward, so that the sliding plate 505 and the first roller 506 move leftwards, the first sliding sleeve 602, the second sliding sleeve 603, the object placing plate 604 and the second roller 605 are driven to move leftwards, the second roller 605 moves along the contact frame 601, after the second roller 605 moves to the inclined plane of the contact frame 601, under the action of gravity, the second sliding sleeve 603, the object placing plate 604 and the second roller 605 move downwards at the same time, after the second roller 605 is far away from the inclined plane of the contact frame 601, the second sliding sleeve 603, the object placing plate 604 and the second roller 605 do not move downwards any more, and after the object placing plate 604 moves leftwards to the lower part of the blanking opening of the shell 2, the raw materials to be printed by laser are placed on the object placing plate 604 from the blanking opening, at the moment, and then the motor 504 is started reversely by controlling the controller 3, the screw rod 503 is driven to reversely rotate, so as to drive the sliding plate 505 and the first roller 506 to move rightwards, drive the first sliding sleeve 602, the second sliding sleeve 603, the object placing plate 604, the second roller 605 and the raw material to move rightwards, when the second roller 605 moves to the inclined surface of the contact frame 601, the second sliding sleeve 603 and the object placing plate 604 are driven to move upwards, after the second roller 605 is far away from the inclined surface of the contact frame 601, the second sliding sleeve 603, the object placing plate 604, the second roller 605 and the raw material do not move upwards any more, and when the raw material moves to the position right below the opening of the shell 2, the laser printing of the raw material can be completed, then the first sliding sleeve 602, the second sliding sleeve 603, the object placing plate 604, the second roller 605 and the raw material continue to move rightwards, the second roller 605 moves to the inclined surface of the contact frame 601 again, and the operations are repeated, so that the second sliding sleeve 603, the object placing plate 604, the second roller 605 and the raw materials move downwards simultaneously and then move right, the raw materials can be taken out and collected manually after the raw materials move to the rectangular groove position, then the motor 504 is started forward through the control controller 3 again to drive the screw rod 503 to rotate forward, the operation is repeated, the first sliding sleeve 602, the second sliding sleeve 603, the object placing plate 604 and the second roller 605 move leftwards, after the second roller 605 moves to the inclined surface of the contact frame 601, the second sliding sleeve 603, the object placing plate 604 and the second roller 605 are driven to move upwards again, after the second roller 605 is far away from the inclined surface of the contact frame 601, the second sliding sleeve 603, the object placing plate 604 and the second roller 605 stop moving upwards, the object placing plate 604 returns to the original position, and thus the operation is repeated, after the user observes that all raw materials are printed through the observation window 4, the motor 504 is closed through the control controller 3, and the effect of automatically transporting the raw materials to finish laser printing can be achieved.

Example 2

Based on the embodiment 1, as shown in fig. 1, fig. 2, fig. 3, fig. 9, fig. 10, fig. 11, fig. 12, fig. 13, fig. 14, fig. 15 and fig. 16, the blanking assembly 7 further comprises a blanking assembly 7, the blanking assembly 7 comprises a second supporting frame 701, a blanking barrel 702, a second guide rod 703, a baffle 704, a first spring 705, a third guide rod 706, a pressing rod 707, a second spring 708, a contact rod 709, a wedge rod 710 and a connecting rod 711, the left side of the lower part of the inside of the shell 2 is connected with the second supporting frame 701, the right side of the upper part of the second supporting frame 701 is connected with the blanking barrel 702, the upper part of the blanking barrel 702 is connected with the shell 2, the front side and the rear side of the lower part of the blanking barrel 702 are symmetrically connected with the second guide rod 703, the baffle 704 is connected with the second guide rod 703 between the front side and the rear side of the second guide rod 703 in a sliding mode, the baffle 704 is symmetrically connected with the blanking barrel 702 in a left-right side, the first spring 705 is wound on the second guide rod 703, the right side of the blanking barrel 702 is connected with the third guide rod 706, the third guide rod 706 is connected with the wedge rod 709 is connected with the upper side of the third guide rod 706, the wedge rod 709 is connected with the wedge rod 709, the pressing rod is connected with the lower side of the wedge rod 706, the upper side is connected with the lower side of the wedge rod 706, the pressing rod is connected with the lower side of the pressing rod 706, the middle is connected with the pressing rod 706, and the lower side is connected with the lower side of the lower rod 706, and the front and the lower rod is connected with the lower rod 706, and the lower rod is connected with the lower rod 706.

Raw materials are sequentially put into the blanking cylinder 702, in an initial state, when the baffle 704 is used for blocking the raw materials, the baffle 604 moves leftwards, the connecting rod 711 is driven to move leftwards, after the connecting rod 711 contacts the wedge-shaped rod 710, the wedge-shaped rod 710 and the pressing rod 707 are pushed to move downwards, the second spring 708 is stretched, after the pressing rod 707 contacts the contact rod 709, the contact rod 709 and the baffle 704 are pushed to move outwards, the first spring 705 is stretched, the lowest raw materials drop downwards onto the baffle 604, then the baffle 604 and the raw materials move rightwards, after the connecting rod 711 is driven to move rightwards and away from the wedge-shaped rod 710, the pressing rod 707 is driven to move upwards under the action of the second spring 708, after the pressing rod 707 is far away from the contact rod 709, the baffle 704 is pushed to move inwards to reset, and the rest raw materials are blocked, and the automatic quantitative feeding effect is achieved.

The material returning assembly 8 comprises a fourth guide rod 801, a movable frame 802, a third spring 803, a push plate 804, a groove tube 805, a ratchet 806, a slide rail 807, a slide block 808, a fourth spring 809, a support rod 810, a wedge block 811, a fifth spring 812, a ratchet bar 813, a sixth spring 814 and a fixed rod 815, wherein the fourth guide rod 801 is connected to the right side of the inner lower portion of the housing 2, the movable frame 802 is connected to the upper portion of the fourth guide rod 801 in a sliding manner, the third spring 803 is connected between the movable frame 802 and the housing 2, the third spring 803 winds on the fourth guide rod 801, the upper portion of the movable frame 802 is connected to the push plate 804, the right front side of the inner lower portion of the housing 2 is rotatably connected with the groove tube 805, the slide block 805 is pushed to move forwards by the movable frame 802 when the groove tube 805 rotates, the rear side of the groove tube 805 is connected with the ratchet 806, the slide block 808 is connected to the right rear side of the inner lower portion of the housing 2, the fourth spring 809 is connected to the right side of the slide block 808, the support rod 810 is connected to the upper portion of the support rod 810, the left side of the support rod 810 is connected to the left side of the slide block 810 is connected to the right side of the slide block 814, the wedge block 811 is connected to the right side of the wedge block 811 after the right side of the slide block is uniformly arranged between the slide block 810 and the right side of the slide block 810, and the wedge block 811 is contacted with the wedge block 811 after the right side of the wedge block is contacted with the right side of the wedge block 811.

When the object placing plate 604 and the printed raw material move rightwards, the connecting rod 711 is driven to move rightwards, after the connecting rod 711 moves to contact the wedge-shaped block 811, the supporting rod 810, the sliding block 808 and the ratchet bar 813 are pushed to move rightwards, the fourth spring 809 is compressed, the ratchet bar 813 cannot drive the ratchet 806 to rotate under the action of the sixth spring 814, then after the wedge-shaped block 811 moves to contact the fixed rod 815, the sliding block 808, the supporting rod 810, the wedge-shaped rod 710 and the ratchet bar 813 are pushed to move downwards to be far away from the connecting rod 711, under the action of the fourth spring 809, the sliding block 808, the supporting rod 810, the wedge-shaped rod 710 and the ratchet bar 813 are pushed to move leftwards, the ratchet 806 is driven to rotate, the grooved drum 805 is driven to rotate, the movable frame 802 and the push plate 804 are pushed to move forwards under the action of the third spring 803, the push plate 804 pushes the printed raw materials on the object placing plate 604 forward, a user can collect the raw materials, after the wedge block 811 is far away from the fixed rod 815, the wedge block 811 is pushed to move upward under the action of the fifth spring 812, after the ratchet bar 813 moves left away from the ratchet 806, the movable frame 802 and the push plate 804 are pushed to move backward under the action of the third spring 803 to restore to the original state, then the object placing plate 604 and the connecting rod 711 move left, after the connecting rod 711 contacts the wedge block 811 again, the wedge block 811 is pushed to move downward, the fifth spring 812 is compressed, the connecting rod 711 moves through the wedge block 811, and the wedge block 811 is pushed to move upward under the action of the fifth spring 812 to restore to the original state, so that the effect of automatically pushing out the raw materials after laser printing is achieved, and the efficiency is improved.

The centering assembly 9 is further included, the centering assembly 9 comprises a fifth guide rod 901, a sliding frame 902, a seventh spring 903, a push block 904 and a special-shaped rod 905, the left side and the right side of the lower portion of the storage plate 604 are both connected with the fifth guide rod 901, the sliding frame 902 is connected between the fifth guide rods 901, the seventh spring 903 is symmetrically connected between the sliding frame 902 and the storage plate 604 in a left-right mode, the seventh spring 903 is wound on the fifth guide rod 901, four push blocks 904 are uniformly connected to the upper portion of the sliding frame 902 at intervals, the push blocks 904 are connected with the storage plate 604 in a sliding mode, the special-shaped rods 905 are connected to the front side and the rear side of the lower portion of the sliding frame 902, and the special-shaped rods 905 are in contact with the contact frame 601.

In the initial state, the contact frame 601 props against the special-shaped rod 905, the seventh spring 903 is in a compressed state, when the object placing plate 604 moves leftwards, the fifth guide rod 901, the sliding frame 902 and the special-shaped rod 905 are driven to move leftwards, after the special-shaped rod 905 is far away from the contact frame 601, under the action of the seventh spring 903, the sliding frame 902 and the special-shaped rod 905 are driven to move downwards, then raw materials fall onto the object placing plate 604 from the blanking cylinder 702, the object placing plate 604 and the raw materials move rightwards, the fifth guide rod 901, the sliding frame 902 and the special-shaped rod 905 are driven to move rightwards, after the special-shaped rod 905 moves to contact the contact frame 601, the sliding frame 902 and the special-shaped rod 905 are driven to move upwards, the seventh spring 903 is compressed, the sliding frame 902 and the special-shaped rod 905 are driven to move rightwards, the auxiliary raw materials are printed, after the object placing plate 604 and the raw materials move rightwards, the fifth guide rod 901, the sliding frame 902 and the special-shaped rod 905 are driven to move rightwards, the special-shaped rod 905 are driven to move leftwards, the sliding frame 905 is driven to move leftwards, and the special-shaped rod 905 is driven to move leftwards, the special-shaped rod 905 is driven to move repeatedly, and the special-shaped rod 905 is driven to move the raw material is reset, and the raw material is driven to move upwards, and the raw material is accurately to move the raw material is reset to move the raw material frame 902, and the raw material is reset to move the raw material frame 902.

The collecting assembly 10 comprises a discharging plate 1001, a third supporting frame 1002, a collecting frame 1003, a movable plate 1004 and an eighth spring 1005, wherein the discharging plate 1001 is connected to the right front side of the lower portion of the housing 2, the discharging plate 1001 is located on the lower side of the rectangular groove of the housing 2, the third supporting frame 1002 is connected to the right front side of the lower portion of the housing 2, the collecting frame 1003 is connected to the front side of the third supporting frame 1002, the movable plate 1004 is connected to the inner side of the collecting frame 1003 in a sliding mode, and the eighth spring 1005 is connected between the movable plate 1004 and the collecting frame 1003 in a bilateral symmetry mode.

After the raw material laser is printed and pushed out, the raw material slides down onto the movable plate 1004 along the discharging plate 1001, under the action of gravity, the movable plate 1004 is pushed to move downwards, the eighth spring 1005 is compressed, the raw material can be completely taken out from the movable plate 1004 after all the raw material laser is printed, under the action of the eighth spring 1005, the movable plate 1004 is pushed to move upwards to restore to the original state, and the effect of conveniently collecting the raw material after laser printing is achieved, so that the buffering effect can be achieved, and the raw material damage is avoided.

While the present disclosure has been shown and described with reference to certain exemplary embodiments thereof, it will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the present disclosure as defined by the appended claims and their equivalents. The scope of the disclosure should, therefore, not be limited to the above-described embodiments, but should be determined not only by the following claims, but also by the equivalents of the following claims.

Claims (6)

1. Auxiliary feeding equipment for facilitating laser printing is characterized by comprising: the base (1) is connected with two sides of the lower part of the shell (2); a controller (3), wherein one side of the upper part of the shell (2) is provided with the controller (3); an observation window (4), wherein the middle of the upper part of the shell (2) is provided with the observation window (4) which is convenient for observing the condition of raw materials; the movable assembly (5) is arranged at the lower side inside the shell (2); the placement component (6) is arranged between the lower side of the interior of the shell (2) and the moving component (5);

The moving assembly (5) comprises: the first support frame (501) is symmetrically connected to the lower side of the interior of the shell (2); the first guide rods (502) are symmetrically connected between the first support frames (501); the screw rod (503) is rotatably connected between the middle parts of the first support frames (501); the sliding plate (505) is connected to the screw rod (503) through threads, and the sliding plate (505) is slidably connected with the first guide rod (502); a motor (504), wherein the motor (504) is installed at one side of the lower part in the shell (2), and one side of the output shaft of the motor (504) is connected with the screw rod (503); the first roller (506) is rotatably connected with the two sides of the lower part of the sliding plate (505);

The placement component (6) comprises: the contact frame (601) is symmetrically connected to the lower side of the inside of the shell (2); the sliding plate comprises a first sliding sleeve (602), wherein the first sliding sleeve (602) is connected to two sides of the upper part of the sliding plate (505); the inner sides of the first sliding sleeves (602) are respectively connected with the second sliding sleeves (603) in a sliding manner; the object placing plate (604) is connected between the upper parts of the second sliding sleeves (603); and the two sides of the lower part of the object placing plate (604) are both rotationally connected with the second roller (605) which is contacted with the contact frame (601).

2. An auxiliary feeding device for facilitating laser printing according to claim 1, further comprising a blanking assembly (7), wherein the blanking assembly (7) comprises: a second supporting frame (701), wherein one side of the lower part in the shell (2) is connected with the second supporting frame (701); a blanking cylinder (702), wherein one side of the upper part of the second supporting frame (701) is connected with the blanking cylinder (702), and the upper part of the blanking cylinder (702) is connected with the shell (2); the second guide rods (703) are symmetrically connected between the two sides of the lower part of the blanking cylinder (702) and the shell (2); the baffle plate (704) is connected between the second guide rods (703) at two sides in a sliding manner; the first springs (705) are symmetrically connected between the baffle plate (704) and the blanking cylinder (702), and the first springs (705) are wound on the second guide rod (703); a third guide rod (706), wherein one side of the blanking cylinder (702) is connected with the third guide rod (706); a pressing rod (707), wherein the pressing rod (707) is connected to the third guide rod (706) in a sliding manner; a second spring (708), the second spring (708) is connected between the pressing rod (707) and the third guide rod (706), and the second spring (708) is wound on the third guide rod (706); a contact lever (709), wherein the contact levers (709) contacting the downward moving compression bar (707) are connected to the middle of the outer side of the upper part of the baffle (704); the wedge-shaped rods (710), and the wedge-shaped rods (710) are connected to two sides of the pressing rod (707); and the connecting rod (711) is symmetrically connected with one side of the lower part of the object placing plate (604), and the connecting rod (711) is contacted with the wedge-shaped rod (710) after moving leftwards.

3. An auxiliary feeding device for facilitating laser printing according to claim 2, further comprising a material returning assembly (8), wherein the material returning assembly (8) comprises: a fourth guide rod (801), wherein one side of the lower part in the shell (2) is connected with the fourth guide rod (801); a movable frame (802), wherein the fourth guide rod (801) is connected with the movable frame (802) in a sliding manner; a third spring (803), the third spring (803) is connected between the movable frame (802) and the housing (2), and the third spring (803) is wound on the fourth guide rod (801); a push plate (804), wherein one side of the upper part of the movable frame (802) is connected with the push plate (804); the groove drum (805) is rotatably connected to one side of the lower part in the shell (2), and the groove drum (805) pushes the movable frame (802) to move forwards when rotating; a ratchet wheel (806), wherein one side of the groove drum (805) is connected with the ratchet wheel (806); a slide rail (807), wherein one side of the lower part in the housing (2) is connected with the slide rail (807); a slider (808), the inside of the sliding rail (807) is connected with the slider (808) in a sliding way; a fourth spring (809), the fourth spring (809) being connected between the slider (808) and the sliding rail (807); the upper part of the sliding block (808) is connected with the supporting rod (810); a wedge block (811), wherein the wedge block (811) contacting the link (711) on the right side is slidably connected to the upper side of the support rod (810); a fifth spring (812), wherein the fifth spring (812) is connected between the wedge block (811) and the support rod (810); a ratchet bar (813), wherein one side of the lower part of the supporting bar (810) is connected with the ratchet bar (813) which can be meshed with the ratchet wheel (806) when moving leftwards in a sliding manner; the ratchet bars (813) and the support rods (810) are uniformly connected with four sixth springs (814) at intervals; and a fixing rod (815), wherein one side of the lower part in the shell (2) is connected with the fixing rod (815) contacted with the wedge-shaped block (811) after rightward movement.

4. An auxiliary feeding device for facilitating laser printing according to claim 3, further comprising a centering assembly (9), the centering assembly (9) comprising: the fifth guide rod (901) is connected to both sides of the lower part of the object placing plate (604); a sliding frame (902), wherein the sliding frame (902) is connected between the fifth guide rods (901) in a sliding way; a seventh spring (903), wherein the seventh spring (903) is symmetrically connected between the sliding frame (902) and the object placing plate (604), and the seventh spring (903) is wound on the fifth guide rod (901); the pushing blocks (904) are uniformly connected with the four pushing blocks (904) at intervals on the upper part of the sliding frame (902), and the pushing blocks (904) are connected with the object placing plate (604) in a sliding mode; the special-shaped rods (905) are connected to two sides of the lower portion of the sliding frame (902), and the special-shaped rods (905) are in contact with the contact frame (601).

5. An auxiliary feeding apparatus for facilitating laser printing according to claim 4, further comprising a collecting member (10), said collecting member (10) being provided at a lower portion side of said housing (2).

6. An auxiliary feeding device for facilitating laser printing according to claim 5, wherein the collecting assembly (10) comprises: the discharging plate (1001) is connected to one side of the lower portion of the shell (2), and the discharging plate (1001) is located on the lower side of the rectangular groove of the shell (2); a third supporting frame (1002), wherein one side of the lower part of the shell (2) is connected with the third supporting frame (1002); a collecting frame (1003), wherein one side of the third supporting frame (1002) is connected with the collecting frame (1003) for collecting raw materials; a movable plate (1004), wherein the movable plate (1004) for buffering is connected to the inner side of the collecting frame (1003) in a sliding manner; and an eighth spring (1005), wherein the eighth spring (1005) is symmetrically connected between the movable plate (1004) and the collecting frame (1003).