CN108202969B - Clean bottle flake conveying device and conveying method for producing regenerated fibers - Google Patents

Abstract

The invention relates to a clean bottle flake conveying device and a conveying method for producing regenerated fibers, and belongs to the technical field of environment-friendly fibers. When the blanking amount is controlled, the clean bottle flake conveying device in the prior art needs to be adjusted, the blanking pipeline cannot be sealed better in the adjusting process of the material control device, and the dry clean bottle flakes can often block the plugboard sliding chute, so that the blanking amount is difficult to control. The invention comprises a conveying device body, a material control mechanism, a sealing mechanism, a material conveying mechanism, a wind direction adjusting mechanism and a wind guiding mechanism, wherein the material control mechanism, the sealing mechanism, the material conveying mechanism, the wind direction adjusting mechanism and the wind guiding mechanism are all arranged on the conveying device body, the material control mechanism is matched with the sealing mechanism, and the wind direction adjusting mechanism is matched with the wind guiding mechanism. The conveying device has high sealing performance, the device provides a power source for the conveying device through the blowing fan on one hand, and increases wind power through the wind direction adjusting mechanism which provides the power source for the conveying device on the other hand.

Description

Clean bottle flake conveying device and conveying method for producing regenerated fibers

Technical Field

The invention relates to a clean bottle flake conveying device and a conveying method for producing regenerated fibers, and belongs to the technical field of environment-friendly fibers.

Background

Clean bottle piece conveyor is in many is arranged in clean bottle piece transport after drying, clean bottle piece conveyor among the prior art when controlling blanking volume, need adjust accuse material device, can not be better at the in-process that accuse material device adjusted with blanking pipeline seal, dry clean bottle piece often can block up the picture peg spout, lead to blanking volume to be difficult to control, clean bottle piece whereabouts is behind, blow it away through the fan, be difficult to form the pulse wind wave, wind-force is little, can lead to the clean bottle piece that falls in the pipeline to be difficult to blow clean, lack monitoring device when clean bottle piece backward flow, the clean bottle piece of backward flow will influence the normal operating of unit.

In view of this, patent document No. 2014207051599 discloses a bottle chip conveying device, which comprises a conveying belt and a bottomless and non-cover groove container, wherein a containing cavity is arranged in the groove container, the upper part of the containing cavity is a feed inlet, the lower part of the containing cavity is a discharge outlet, and the conveying belt is arranged below the discharge outlet; the method is characterized in that: the bottle chip forming device is characterized by further comprising a supporting device for supporting the bottle chip, wherein the supporting device is arranged in the groove container, and a plurality of diversion holes are formed between the supporting device and the groove container. The comparison file has the defects of poor sealing effect, small wind power and the like.

Disclosure of Invention

The invention aims to overcome the defects in the prior art and provide a clean bottle flake conveying device and a conveying method for producing regenerated fibers, which have reasonable structural design.

The invention solves the problems by adopting the following technical scheme: this a clean bottle piece conveyor for producing regenerated fiber, including conveyor body, accuse material mechanism, sealing mechanism, defeated material mechanism, wind direction adjustment mechanism and wind-guiding mechanism are all installed on the conveyor body, accuse material mechanism cooperates with sealing mechanism, wind direction adjustment mechanism cooperates with wind-guiding mechanism, its structural feature lies in: the conveying device comprises a conveying device body, wherein the conveying device body comprises a blanking pipeline, a conveying pipeline, a discharging pipeline, a feeding pipeline, a blowing pipeline and a blowing air guide block, the air guide mechanism comprises a material control inserting plate, a material control inserting plate guide surface, a material control screw, a material control support and a material control hand wheel, the sealing mechanism comprises a left sealing block, a right sealing block, a left sealing sliding block, a right sealing sliding block, a left sealing spring, a right sealing spring, a left sealing block guide surface, a right sealing block guide surface, a sealing plate guide surface and a sealing plate reset spring, the conveying mechanism comprises a conveying spiral, the air direction regulating mechanism comprises an air direction regulating shaft, an air direction regulating plate and an air direction regulating motor, and the air guide mechanism comprises a driving air guide shaft, a driven air guide plate, a driving synchronous pulley, a driven synchronous pulley, a synchronous belt, an air guide motor and a feed back monitoring sensor; the blanking pipeline is internally provided with a left control material inserting plate chute and a right control material inserting plate chute, the left control material inserting plate chute is arranged on the left wall surface of the blanking pipeline, the right control material inserting plate chute is arranged on the right wall surface of the blanking pipeline, the top surface of the left control material inserting plate chute is provided with a left sealing block mounting cavity, the top surface of the right control material inserting plate chute is provided with a right sealing block mounting cavity, the wall surface of the left sealing block mounting cavity is provided with a left sealing chute, the wall surface of the right sealing block mounting cavity is provided with a right sealing chute, the blanking pipeline is provided with a control material inserting plate mounting hole, the left control material inserting plate chute and the right control material inserting plate chute are communicated with the control material inserting plate mounting hole, the top surface of the control material inserting plate mounting hole is provided with a sealing plate mounting cavity, the blanking pipeline is communicated with a material conveying pipeline, the material conveying pipeline is communicated with a discharging pipeline, the discharging pipeline is arranged at the end part of the material conveying pipeline, the blanking pipeline is communicated with the feeding pipeline, the feeding pipeline is communicated with the blowing pipeline, the blowing air guide block is arranged in the blowing pipeline, the resistance of the blowing pipeline to wind is reduced, the utilization rate of wind is increased, the material control bracket is arranged outside the blanking pipeline, the material control hand wheel is rotatably arranged on the material control bracket, the material control plugboard passes through the material control plugboard mounting hole and is inserted on the blanking pipeline, the left side of the material control plugboard is positioned in the left material control plugboard chute, the right side of the material control plugboard is positioned in the right material control plugboard chute, the material control plugboard guide surface is arranged at one side of the material control plugboard, the material control plugboard guide surface is positioned in the blanking pipeline, the material control screw is arranged at the other side of the material control plugboard, the material control screw passes through the material control bracket, the material control hand wheel is sleeved on the material control screw, the left sealing slide block is arranged on the wall surface of the left sealing block, one end of the left sealing spring is connected with the left sealing block, the other end of the left sealing spring is connected with the left sealing block installation cavity, the left sealing block guide surface is arranged at the bottom of the left sealing block, the left sealing block is installed in the left sealing block installation cavity, the left sealing slide block is embedded in the left sealing slide groove, the right sealing slide block is installed on the wall surface of the right sealing block, one end of the right sealing spring is connected with the right sealing block, the other end of the right sealing spring is connected with the right sealing block installation cavity, the right sealing block guide surface is arranged at the bottom of the right sealing block, the right sealing block is installed in the right sealing block installation cavity, the right sealing slide block is embedded in the right sealing slide groove, the sealing plate is installed in the sealing plate installation cavity, the sealing plate guide surface is arranged at the bottom of the sealing plate, the sealing plate is connected with the sealing plate installation cavity through the sealing plate reset spring, the left sealing block guide surface, the right sealing block guide surface and the sealing plate guide surface are in contact with the material control plugboard guide surface, the material conveying spiral is installed in a material conveying pipeline and comprises a material conveying section and a material discharging section, the material conveying section is connected with the material discharging section, the material discharging section is provided with taper, the material discharging section is positioned above the material discharging pipeline and is convenient for clean bottle flakes to fall down, the wind direction adjusting plate is installed on the wind direction adjusting shaft, the wind direction adjusting shaft is connected with the wind direction adjusting motor, the driving air deflector and the driving synchronous pulley are both installed on the driving air deflector shaft, the driven air deflector and the driven synchronous pulley are both installed on the driven air deflector shaft, the driving air deflector shaft and the driven air deflector shaft are both rotatably installed on the material blowing pipeline and are both positioned in the material blowing pipeline, the driving synchronous belt wheel is connected with the driven synchronous belt wheel through a synchronous belt, the driving air guide shaft is connected with the air guide motor, the return material monitoring sensor is arranged on the blowing pipeline and is positioned on one side of an air outlet of the blowing pipeline, the return material monitoring sensor is connected with the air guide motor, the driving air guide plate and the driven air guide plate are matched with the wind direction adjusting mechanism, and when the driving air guide plate and the driven air guide plate are level, the driving air guide plate and the driven air guide plate form a closed return material baffle; when a distance exists between the driving air deflector and the driven air deflector, the driving air deflector and the driven air deflector form an air guide channel. When the material control plugboard is positioned in the blanking pipeline, the left sealing block guide surface and the right sealing block guide surface are in contact with the material control plugboard guide surface, so that the left material control plugboard chute and the right material control plugboard chute are sealed, and the situation that the left material control plugboard chute and the right material control plugboard chute are blocked by a dry clean bottle piece, so that the material control plugboard cannot move is avoided; when the material control plugboard is completely opened, the sealing plate guide surface is contacted with the material control plugboard guide surface, so that the overflow of dry clean bottle flakes in the blanking pipeline is avoided, and the tightness of the blanking pipeline is ensured.

Further, the material conveying mechanism further comprises a material conveying motor, a material conveying driving belt wheel, a material conveying driven belt wheel and a material conveying belt, wherein the material conveying driving belt wheel is arranged on the material conveying motor, the material conveying driven belt wheel is arranged on the material conveying section, and the material conveying driving belt wheel is connected with the material conveying driven belt wheel through the material conveying belt. And the dried and clean bottle flakes are conveyed to the end part of the conveying pipeline through the conveying screw, so that the reflux of the dried and clean bottle flakes is avoided.

Further, an internal thread is arranged on the material control hand wheel, an external thread is arranged on the material control screw rod, and the material control hand wheel is connected with the material control screw rod through threads. The blanking amount is convenient to adjust by rotating the material control hand wheel, and the control is more convenient and accurate.

Further, the left sealing sliding block and the right sealing sliding block are T-shaped sliding blocks, the left sealing sliding groove and the right sealing sliding groove are T-shaped sliding grooves, the number of the left sealing sliding block, the right sealing sliding block, the left sealing sliding groove and the right sealing sliding groove is multiple, the left sealing sliding block is in one-to-one correspondence with the left sealing sliding groove, and the right sealing sliding block is in one-to-one correspondence with the right sealing sliding groove. Defining the direction in which the left and right seal blocks slide.

Further, the left sealing spring, the right sealing spring and the sealing plate return spring are compression springs. The reset of the left sealing block, the right sealing block and the sealing plate is realized, and the overflow of the dried clean bottle flakes is avoided.

Further, the shape of blowing material pipeline is the cuboid, the quantity of wind direction regulating plate is six, six wind direction regulating plates are all installed on wind direction regulating shaft along the circumference of wind direction regulating shaft, and the contained angle between every two wind direction regulating plates is 60, the width of wind direction regulating plate is the same with the height of blowing material pipeline, all be provided with the fillet on six wind direction regulating plates, reduce wind direction regulating plate and blow the friction between the pipeline.

Further, an air inlet of the blowing pipeline is connected with a blowing fan. Providing a power source for the conveying device.

Further, when the driving air guide plate and the driven air guide plate form an air guide channel, the driving air guide plate is parallel to the driven air guide plate, and the air guide channel comprises a forward air guide channel and a reverse air guide channel.

Further, the conveying method of the clean bottle flake conveying device for producing regenerated fibers is characterized by comprising the following steps of: the method comprises the following steps:

the first step: the dried clean bottle flakes fall into a blanking pipeline, and the material control screw rod stretches and contracts by rotating the material control hand wheel, and the material control screw rod drives the material control plugboard to move, so that the blanking amount of the material conveying pipeline is regulated;

and a second step of: when the material control hand wheel rotates and the material control inserting plate moves into the blanking pipeline, the left sealing block guide surface and the right sealing block guide surface are contacted with the material control inserting plate guide surface, so that the left sealing block and the right sealing block slide upwards, and the blanking amount is reduced; or when the material control hand wheel rotates, the material control plugboard moves outwards of the blanking pipeline, the left sealing block slides downwards through the left sealing spring, the left material control plugboard sliding chute is sealed through the left sealing block, the right material control plugboard sliding chute is sealed through the right sealing block, the dry clean bottle piece is prevented from entering the left material control plugboard sliding chute and the right material control plugboard sliding chute, the movement of the material control plugboard is influenced, the sealing performance of the material control plugboard is reduced, when the sealing plate falls down through the sealing plate reset spring, and the sealing plate guide surface contacts with the material control plugboard guide surface, the material control plugboard is completely opened, and the blanking amount is maximum;

and a third step of: conveying the dried clean bottle flakes in the conveying pipeline into the discharging pipeline through the conveying screw, conveying the dried clean bottle flakes into the discharging pipeline sequentially through the conveying section and the discharging section, and then falling into the conveying pipeline;

fourth step: blowing the clean bottle flakes dried in the feeding pipeline to the next working procedure by wind flow generated by the blowing fan through the blowing pipeline; and the first step to the fourth step are sequentially carried out.

Further, in the fourth step, when the return monitoring sensor detects that the dry clean bottle flakes are returned to the blowing pipeline, the return monitoring sensor feeds back signals to the air guide motor to enable the driving air guide plate and the driven air guide plate to form a return baffle, the blowing fan stops working at the moment, the returned dry clean bottle flakes are blown clean through rotation of the wind direction adjusting mechanism, and then the return monitoring sensor feeds back the signals for detecting that the dry clean bottle flakes are blown clean to the air guide motor to enable the driving air guide plate and the driven air guide plate to form an air guide channel; the wind-guiding motor is used for controlling the driving synchronous belt pulley and the driven synchronous belt pulley to synchronously rotate, when the wind-guiding motor positively rotates, the driving wind-guiding plate and the driven wind-guiding plate form a positive wind-guiding channel, and at the moment, the wind-direction adjusting mechanism positively rotates; when the wind-guiding motor reversely rotates, the driving wind-guiding plate and the driven wind-guiding plate form a reverse wind-guiding channel, and at the moment, the wind direction regulating mechanism reversely rotates; the wind blown by the blowing fan flows through the forward wind guide channel and then is combined with the wind generated by forward rotation of the wind guide motor, and the wind blown by the blowing fan flows through the reverse wind guide channel and then is combined with the wind generated by reverse rotation of the wind guide motor; and then the dried clean bottle flakes are blown to the next process.

Compared with the prior art, the invention has the following advantages:

1. the conveying device has higher sealing performance, when the material control plugboard is positioned in the blanking pipeline, the left sealing block guide surface and the right sealing block guide surface are in contact with the material control plugboard guide surface, so that the left material control plugboard chute and the right material control plugboard chute are sealed, and the situation that the left material control plugboard chute and the right material control plugboard chute are blocked by a dry clean bottle piece, so that the material control plugboard cannot move is avoided; when the material control plugboard is completely opened, the sealing plate guide surface is contacted with the material control plugboard guide surface, so that the overflow of dry clean bottle flakes in the blanking pipeline is avoided, and the tightness of the blanking pipeline is ensured.

2. The conveying device provides a power source for the material blowing fan through the material blowing fan on one hand, and provides a power source for the material blowing fan through the wind direction adjusting mechanism on the other hand, when wind blown by the material blowing fan flows through the forward wind guide channel and contacts with the wind direction adjusting plate, the wind direction adjusting plate rotates forward, and forward pulse wind waves are formed in the forward rotation process of the wind direction adjusting plate; or when the wind blown by the blowing fan flows through the reverse wind guide channel and contacts with the wind direction adjusting plate, the wind direction adjusting plate reversely rotates, and reverse pulse type wind waves are formed in the reverse rotation process of the wind direction adjusting plate; the wind power can be increased to blow the clean bottle flakes dried in the feeding pipeline to the next working procedure more cleanly.

3. When the return monitoring sensor detects that the dry clean bottle flakes are returned to the blowing pipeline, the return monitoring sensor feeds signals back to the air guide motor, so that the driving air guide plate and the driven air guide plate form a return baffle, the blowing fan stops working at the moment, the dry clean bottle flakes are prevented from returning, and the returned dry bottle flakes are blown clean and then continue to work after being blown clean through the rotation of the wind direction adjusting mechanism.

4. Through the conveying device, waste plastic bottles can be recovered for spinning and reutilization, so that the waste plastic bottles are prevented from polluting the environment, and meanwhile, the production cost is reduced.

Drawings

Fig. 1 is a schematic perspective view of a conveying device according to an embodiment of the present invention.

Fig. 2 is a schematic left-hand view of a conveying apparatus according to an embodiment of the present invention.

Fig. 3 is a schematic view of the IV-IV cross-sectional structure of fig. 2.

Fig. 4 is a schematic view of the V-V cross-section structure of fig. 2.

Fig. 5 is a schematic diagram of a left-view broken structure of a conveyor body according to an embodiment of the present invention.

FIG. 6 is a schematic view of the VI-VI cross-sectional structure of FIG. 5.

Fig. 7 is an enlarged view of the portion VIII in fig. 6.

FIG. 8 is a schematic view of the section VII-VII of FIG. 6.

Fig. 9 is an enlarged view of the portion IX in fig. 8.

Fig. 10 is a schematic perspective view of a sealing mechanism according to an embodiment of the present invention.

Fig. 11 is a schematic perspective view of a sealing mechanism according to an embodiment of the present invention.

Fig. 12 is a schematic perspective view of a sealing mechanism according to an embodiment of the present invention.

Fig. 13 is a schematic perspective view of a material control mechanism according to an embodiment of the present invention.

Fig. 14 is a schematic view of a feed back baffle formed by a driving air deflector and a driven air deflector according to an embodiment of the present invention.

Fig. 15 is a schematic diagram of a forward wind guiding channel formed by a driving wind guiding plate and a driven wind guiding plate according to an embodiment of the present invention.

Fig. 16 is a schematic view of a structure of an anti-wind guiding channel formed by a driving wind guiding plate and a driven wind guiding plate according to an embodiment of the present invention.

In the figure: the conveying device comprises a conveying device body B1, a material control mechanism B2, a sealing mechanism B3, a material conveying mechanism B4, a wind direction adjusting mechanism B5, a wind guiding mechanism B6, a blanking pipeline B11, a conveying pipeline B12, a blanking pipeline B13, a feeding pipeline B14, a blowing pipeline B15, a blowing wind guiding block B16, a material control inserting plate B21, a material control inserting plate guiding surface B22, a material control screw rod B23, a material control bracket B24, a material control hand wheel B25, a left sealing block B31, a right sealing block B32, a left sealing block B33, a right sealing block B34, a left sealing spring B35, a right sealing spring B36, a left sealing block guiding surface B37, a right sealing block guiding surface B38, a sealing plate B39, a sealing plate guiding surface B391 and a sealing plate reset spring B392 the material conveying spiral B41, the material conveying motor B42, the material conveying driving belt wheel B43, the material conveying driven belt wheel B44, the material conveying belt B45, the wind direction adjusting shaft B51, the wind direction adjusting plate B52, the wind direction adjusting motor B53, the driving wind guiding shaft B61, the driven wind guiding shaft B62, the driving wind guiding plate B63, the driven wind guiding plate B64, the driving synchronous belt wheel B65, the driven synchronous belt wheel B66, the synchronous belt B67, the wind guiding motor B68, the material returning monitoring sensor B69, the left material control plug board chute B111, the right material control plug board chute B112, the left sealing block installation cavity B113, the right sealing block installation cavity B114, the left sealing chute B115, the right sealing chute B116, the material control plug board installation hole B117 and the sealing plate installation cavity B118.

Detailed Description

The present invention will be described in further detail by way of examples with reference to the accompanying drawings, which are illustrative of the present invention and not limited to the following examples.

Examples

Referring to fig. 1 to 16, it should be understood that the structures, proportions, sizes, etc. shown in the drawings attached hereto are merely used in conjunction with the disclosure of the present specification and should not be construed as limiting the scope of the present invention, but rather should be construed as falling within the scope of the present disclosure without affecting the efficacy and achievement of the present invention. In the present specification, the terms "upper", "lower", "left", "right", "middle" and "a" are used for descriptive purposes only and are not intended to limit the scope of the invention, but are also intended to be within the scope of the invention without any substantial modification to the technical content.

The clean bottle piece conveying device for producing regenerated fibers in the embodiment comprises a conveying device body B1, a material control mechanism B2, a sealing mechanism B3, a material conveying mechanism B4, a wind direction adjusting mechanism B5 and a wind guiding mechanism B6, wherein the material control mechanism B2, the sealing mechanism B3, the material conveying mechanism B4, the wind direction adjusting mechanism B5 and the wind guiding mechanism B6 are all installed on the conveying device body B1, the material control mechanism B2 is matched with the sealing mechanism B3, and the wind direction adjusting mechanism B5 is matched with the wind guiding mechanism B6.

The conveying device body B1 in this embodiment includes a blanking pipeline B11, a conveying pipeline B12, a blanking pipeline B13, a feeding pipeline B14, a blowing pipeline B15 and a blowing air guide block B16, the material control mechanism B2 includes a material control plugboard B21, a material control plugboard guide surface B22, a material control screw B23, a material control support B24 and a material control hand wheel B25, the sealing mechanism B3 includes a left sealing block B31, a right sealing block B32, a left sealing slide B33, a right sealing slide B34, a left sealing spring B35, a right sealing spring B36, a left sealing block guide surface B37, a right sealing block guide surface B38, a sealing plate B39, a sealing plate guide surface B391 and a sealing plate return spring B392, the conveying mechanism B4 includes a conveying spiral B41, the air direction adjusting mechanism B5 includes an air direction adjusting shaft B51, an air direction adjusting plate B52 and an air direction adjusting motor B53, the air guide mechanism B6 includes a driving air guide shaft B61, a driven air guide shaft B62, a driving air guide plate B63, a driven air guide plate B64, a driving air guide plate B65, a driven air guide plate B65, a driving synchronous pulley B66, a synchronous pulley B68, a synchronous pulley B and a synchronous pulley B69, and a synchronous pulley B68.

The blanking pipeline B11 in this embodiment is provided with left accuse material picture peg spout B111 and right accuse material picture peg spout B112, left accuse material picture peg spout B111 sets up the left wall at blanking pipeline B11, right accuse material picture peg spout B112 sets up the right wall at blanking pipeline B11, the top surface of left accuse material picture peg spout B111 is provided with left sealing block installation cavity B113, the top surface of right accuse material picture peg spout B112 is provided with right sealing block installation cavity B114, the wall of left sealing block installation cavity B113 is provided with left sealing spout B115, the wall of right sealing block installation cavity B114 is provided with right sealing spout B116, be provided with accuse material picture peg mounting hole B117 on the blanking pipeline B11, left accuse material picture peg spout B111 and right accuse material picture peg spout B112 all communicate with accuse material picture peg mounting hole B117, the top surface of accuse material picture peg mounting hole B117 is provided with sealing plate installation cavity B118.

In the embodiment, a blanking pipeline B11 is communicated with a conveying pipeline B12, the conveying pipeline B12 is communicated with a blanking pipeline B13, the blanking pipeline B13 is arranged at the end part of the conveying pipeline B12, the blanking pipeline B13 is communicated with a feeding pipeline B14, the feeding pipeline B14 is communicated with a blowing pipeline B15, a blowing air guide block B16 is arranged in the blowing pipeline B15, the resistance of the blowing pipeline B15 to wind is reduced, the utilization rate of wind is increased, a material control bracket B24 is arranged outside the blanking pipeline B11, a material control hand wheel B25 is rotatably arranged on the material control bracket B24, a material control plugboard B21 is inserted on the blanking pipeline B11 through a material control plugboard mounting hole B117, the left side of the material control plugboard B21 is positioned in a left material control plugboard chute B111, the right side of the material control plugboard B21 is positioned in a right material control plugboard chute B112, a material control plugboard guide surface B22 is arranged at one side of the plugboard B21, a material control plugboard guide surface B22 is positioned in the blanking pipeline B11, a material control screw rod B23 is arranged at the other side of the material control screw rod B21, and the material control screw B23 passes through the material control bracket B24, the material control hand wheel B25 is sleeved on the material control screw B23, the left sealing slide block B33 is arranged on the wall surface of the left sealing block B31, one end of the left sealing spring B35 is connected with the left sealing block B31, the other end of the left sealing spring B35 is connected with the left sealing block installation cavity B113, the left sealing block guide surface B37 is arranged at the bottom of the left sealing block B31, the left sealing block B31 is arranged in the left sealing block installation cavity B113, the left sealing slide block B33 is embedded in the left sealing slide groove B115, the right sealing slide block B34 is arranged on the wall surface of the right sealing block B32, one end of the right sealing spring B36 is connected with the right sealing block B32, the other end of the right sealing spring B36 is connected with the right sealing block installation cavity B114, the right sealing block guide surface B38 is arranged at the bottom of the right sealing block B32, the right sealing block B32 is arranged in the right sealing block installation cavity B114, the right sealing slide block B34 is embedded in the right sealing slide groove B116, the sealing plate B39 is arranged in the sealing plate installation cavity B118, the sealing plate guide surface B391 is arranged at the bottom of the sealing plate B39, the sealing plate B39 is connected with the sealing plate installation cavity B118 through the sealing plate return spring B392, and the left sealing block guide surface B37, the right sealing block guide surface B38 and the sealing plate guide surface B391 are all in contact with the material control plug board guide surface B22.

The material conveying spiral B41 in this embodiment is installed in the conveying pipeline B12, the material conveying spiral B41 includes conveying section and unloading section, the conveying section is connected with the unloading section, the unloading section is provided with the tapering, the unloading section is located the top of unloading pipeline B13, be convenient for clean bottle piece drops, wind direction regulating plate B52 is installed on wind direction regulating shaft B51, wind direction regulating shaft B51 is connected with wind direction regulating motor B53, initiative aviation baffle B63 and initiative synchronous pulley B65 are all installed on initiative aviation baffle B61, driven aviation baffle B64 and driven synchronous pulley B66 are all installed on driven aviation baffle B62, initiative aviation baffle B61 and driven aviation baffle B62 are all rotated and are installed on blowing pipeline B15, initiative aviation baffle B63 and driven aviation baffle B64 are all located blowing pipeline B15, initiative synchronous pulley B65 is connected with driven synchronous pulley B66 through synchronous belt B67, initiative aviation baffle B61 is connected with air guide motor B68, back monitoring sensor B69 is installed on blowing pipeline B15 and back air guide sensor B69 is located wind power sensor B69 and is connected with blowing pipeline B68 on one side of blowing pipeline B.

The driving air deflector B63 and the driven air deflector B64 in the embodiment are matched with the wind direction adjusting mechanism B5, and when the driving air deflector B63 and the driven air deflector B64 are level, the driving air deflector B63 and the driven air deflector B64 form a closed return baffle; when a distance exists between the driving air deflector B63 and the driven air deflector B64, the driving air deflector B63 and the driven air deflector B64 form an air guide channel.

The material conveying mechanism B4 in the embodiment further comprises a material conveying motor B42, a material conveying driving belt wheel B43, a material conveying driven belt wheel B44 and a material conveying belt B45, wherein the material conveying driving belt wheel B43 is arranged on the material conveying motor B42, the material conveying driven belt wheel B44 is arranged on the material conveying section, and the material conveying driving belt wheel B43 and the material conveying driven belt wheel B44 are connected through the material conveying belt B45; the material control hand wheel B25 is provided with internal threads, the material control screw rod B23 is provided with external threads, and the material control hand wheel B25 is in threaded connection with the material control screw rod B23.

In the embodiment, the left sealing slide block B33 and the right sealing slide block B34 are T-shaped slide blocks, the left sealing slide groove B115 and the right sealing slide groove B116 are T-shaped slide grooves, the number of the left sealing slide block B33, the right sealing slide block B34, the left sealing slide groove B115 and the right sealing slide groove B116 is multiple, the left sealing slide block B33 corresponds to the left sealing slide groove B115 one by one, and the right sealing slide block B34 corresponds to the right sealing slide groove B116 one by one; the left seal spring B35, the right seal spring B36, and the seal plate return spring B392 are compression springs.

The shape of blowing pipeline B15 in this embodiment is the cuboid, and the quantity of wind direction regulating plate B52 is six, and six wind direction regulating plate B52 are all installed on wind direction regulating shaft B51 along the circumference of wind direction regulating shaft B51, and the contained angle between every two wind direction regulating plates B52 is 60, and the width of wind direction regulating plate B52 is the same with the height of blowing pipeline B15, all is provided with the fillet on six wind direction regulating plate B52, reduces the friction between wind direction regulating plate B52 and the blowing pipeline B15.

An air inlet of the blowing pipeline B15 is connected with a blowing fan; when the driving air deflector B63 and the driven air deflector B64 form an air guide channel, the driving air deflector B63 is parallel to the driven air deflector B64, and the air guide channel comprises a forward air guide channel and a reverse air guide channel.

The conveying method of the clean bottle flake conveying device for producing regenerated fibers in the embodiment comprises the following steps:

the first step: the dried clean bottle flakes fall into a blanking pipeline B11, a material control screw rod B23 stretches and contracts by rotating a material control hand wheel B25, and the material control screw rod B23 drives a material control plugboard B21 to move so as to adjust blanking quantity of a material conveying pipeline B12;

and a second step of: when the material control hand wheel B25 rotates, the left sealing block guide surface B37 and the right sealing block guide surface B38 are contacted with the material control hand wheel B22 when the material control hand wheel B21 moves towards the blanking pipeline B11, so that the left sealing block B31 and the right sealing block B32 slide upwards, and the blanking amount is reduced; or when the material control hand wheel B25 rotates, the left sealing block B31 slides downwards through the left sealing spring B35 and the right sealing block B32 slides downwards through the right sealing spring B36, the left material control plugboard chute B111 is sealed through the left sealing block B31, the right material control plugboard chute B112 is sealed through the right sealing block B32, dry clean bottle pieces are prevented from entering the left material control plugboard chute B111 and the right material control plugboard chute B112, the movement of the material control plugboard B21 is influenced, the sealing performance of the material control plugboard B21 is reduced, when the sealing plate B39 falls down through the sealing plate return spring B392, the sealing plate guide surface B391 is in contact with the material control plugboard guide surface B22, the material control plugboard B21 is completely opened, and the blanking amount is maximum;

and a third step of: conveying the dried clean bottle chips in the conveying pipeline B12 into the discharging pipeline B13 through a conveying screw B41, conveying the dried clean bottle chips into the discharging pipeline B13 through a conveying section and a discharging section in sequence, and then falling into the conveying pipeline B14;

fourth step: blowing the clean bottle flakes dried in the feeding pipeline B14 to the next working procedure by wind generated by the blowing fan through a blowing pipeline B15; and the first step to the fourth step are sequentially carried out.

In the fourth step of this embodiment, when the return monitoring sensor B69 detects that the dried clean bottle flakes are reflowed into the blowing pipeline B15, the return monitoring sensor B69 feeds back a signal to the air guide motor B68, so that the driving air guide plate B63 and the driven air guide plate B64 form a return baffle, at this time, the blowing fan stops working, the reflowed dried clean bottle flakes are blown clean by the rotation of the wind direction adjusting mechanism B5, and then the return monitoring sensor B69 feeds back a signal that the dried clean bottle flakes are detected to blow clean to the air guide motor B68, so that the driving air guide plate B63 and the driven air guide plate B64 form an air guide channel; the driving synchronous pulley B65 and the driven synchronous pulley B66 are controlled to synchronously rotate through the wind guide motor B68, when the wind guide motor B68 positively rotates, a positive wind guide channel is formed by the driving wind guide plate B63 and the driven wind guide plate B64, and at the moment, the wind direction adjusting mechanism B5 positively rotates; when the wind-guiding motor B68 reversely rotates, the driving wind-guiding plate B63 and the driven wind-guiding plate B64 form a reverse wind-guiding channel, and at the moment, the wind-direction regulating mechanism B5 reversely rotates; the wind blown by the blowing fan flows through the forward wind guide channel and then is combined with the wind generated by forward rotation of the wind guide motor B68, and the wind blown by the blowing fan flows through the reverse wind guide channel and then is combined with the wind generated by reverse rotation of the wind guide motor B68; and then the dried clean bottle flakes are blown to the next process.

In fig. 14, the return monitoring sensor B69 detects that the dried clean bottle flakes are returned, the blowing fan stops working, the driving air deflector B63 and the driven air deflector B64 form a return baffle, and when the dried clean bottle flakes are blown clean by the rotation of the wind direction adjusting mechanism B5, the driving air deflector B63 and the driven air deflector B64 form an air guide channel.

In fig. 15, when the wind-guiding motor B68 rotates in the forward direction, the driving wind-guiding plate B63 and the driven wind-guiding plate B64 form a forward wind-guiding channel, and the wind blown by the blowing fan flows through the forward wind-guiding channel, and at this time, the wind direction adjusting mechanism B5 rotates in the forward direction; and when the wind blown by the blowing fan and the wind generated by the wind direction adjusting plate B52 during forward rotation of the wind-guiding motor B68 form pulse-type wind waves, the dried clean bottle flakes are blown to the next process.

In fig. 16, when the wind-guiding motor B68 rotates reversely, the driving wind-guiding plate B63 and the driven wind-guiding plate B64 form a reverse wind-guiding channel, and the wind blown by the blowing fan flows through the reverse wind-guiding channel, and at this time, the wind direction adjusting mechanism B5 rotates reversely; when the wind blown by the blowing fan and the wind guiding motor B68 reversely rotate, the wind generated by the wind direction adjusting plate B52 forms pulse type wind waves to blow the dried clean bottle flakes to the next process.

The clean bottle chip in this embodiment is a clean bottle chip after drying.

In addition, it should be noted that the specific embodiments described in the present specification may vary from part to part, from name to name, etc., and the above description in the present specification is merely illustrative of the structure of the present invention. All equivalent or simple changes of the structure, characteristics and principle according to the inventive concept are included in the protection scope of the present patent. Those skilled in the art may make various modifications or additions to the described embodiments or substitutions in a similar manner without departing from the scope of the invention as defined in the accompanying claims.

Claims (10)

1. The utility model provides a clean bottle piece conveyor for producing regenerated fiber, includes conveyor body, accuse material mechanism, sealing mechanism, defeated material mechanism, wind direction adjustment mechanism and wind-guiding mechanism are all installed on the conveyor body, accuse material mechanism cooperates with sealing mechanism, wind direction adjustment mechanism cooperates with wind-guiding mechanism, its characterized in that: the conveying device comprises a conveying device body, wherein the conveying device body comprises a blanking pipeline, a conveying pipeline, a discharging pipeline, a feeding pipeline, a blowing pipeline and a blowing air guide block, the air guide mechanism comprises a material control inserting plate, a material control inserting plate guide surface, a material control screw, a material control support and a material control hand wheel, the sealing mechanism comprises a left sealing block, a right sealing block, a left sealing sliding block, a right sealing sliding block, a left sealing spring, a right sealing spring, a left sealing block guide surface, a right sealing block guide surface, a sealing plate guide surface and a sealing plate reset spring, the conveying mechanism comprises a conveying spiral, the air direction regulating mechanism comprises an air direction regulating shaft, an air direction regulating plate and an air direction regulating motor, and the air guide mechanism comprises a driving air guide shaft, a driven air guide plate, a driving synchronous pulley, a driven synchronous pulley, a synchronous belt, an air guide motor and a feed back monitoring sensor; the blanking pipeline is internally provided with a left control material inserting plate chute and a right control material inserting plate chute, the left control material inserting plate chute is arranged on the left wall surface of the blanking pipeline, the right control material inserting plate chute is arranged on the right wall surface of the blanking pipeline, the top surface of the left control material inserting plate chute is provided with a left sealing block mounting cavity, the top surface of the right control material inserting plate chute is provided with a right sealing block mounting cavity, the wall surface of the left sealing block mounting cavity is provided with a left sealing chute, the wall surface of the right sealing block mounting cavity is provided with a right sealing chute, the blanking pipeline is provided with a control material inserting plate mounting hole, the left control material inserting plate chute and the right control material inserting plate chute are communicated with the control material inserting plate mounting hole, the top surface of the control material inserting plate mounting hole is provided with a sealing plate mounting cavity, the blanking pipeline is communicated with a material conveying pipeline, the material conveying pipeline is communicated with a discharging pipeline, the discharging pipeline is arranged at the end part of the material conveying pipeline, the blanking pipeline is communicated with the feeding pipeline, the feeding pipeline is communicated with the blowing pipeline, the blowing air guide block is arranged in the blowing pipeline, the resistance of the blowing pipeline to wind is reduced, the utilization rate of wind is increased, the material control bracket is arranged outside the blanking pipeline, the material control hand wheel is rotatably arranged on the material control bracket, the material control plugboard passes through the material control plugboard mounting hole and is inserted on the blanking pipeline, the left side of the material control plugboard is positioned in the left material control plugboard chute, the right side of the material control plugboard is positioned in the right material control plugboard chute, the material control plugboard guide surface is arranged at one side of the material control plugboard, the material control plugboard guide surface is positioned in the blanking pipeline, the material control screw is arranged at the other side of the material control plugboard, the material control screw passes through the material control bracket, the material control hand wheel is sleeved on the material control screw, the left sealing slide block is arranged on the wall surface of the left sealing block, one end of the left sealing spring is connected with the left sealing block, the other end of the left sealing spring is connected with the left sealing block installation cavity, the left sealing block guide surface is arranged at the bottom of the left sealing block, the left sealing block is installed in the left sealing block installation cavity, the left sealing slide block is embedded in the left sealing slide groove, the right sealing slide block is installed on the wall surface of the right sealing block, one end of the right sealing spring is connected with the right sealing block, the other end of the right sealing spring is connected with the right sealing block installation cavity, the right sealing block guide surface is arranged at the bottom of the right sealing block, the right sealing block is installed in the right sealing block installation cavity, the right sealing slide block is embedded in the right sealing slide groove, the sealing plate is installed in the sealing plate installation cavity, the sealing plate guide surface is arranged at the bottom of the sealing plate, the sealing plate is connected with the sealing plate installation cavity through the sealing plate reset spring, the left sealing block guide surface, the right sealing block guide surface and the sealing plate guide surface are in contact with the material control plugboard guide surface, the material conveying spiral is installed in a material conveying pipeline and comprises a material conveying section and a material discharging section, the material conveying section is connected with the material discharging section, the material discharging section is provided with taper, the material discharging section is positioned above the material discharging pipeline and is convenient for clean bottle flakes to fall down, the wind direction adjusting plate is installed on the wind direction adjusting shaft, the wind direction adjusting shaft is connected with the wind direction adjusting motor, the driving air deflector and the driving synchronous pulley are both installed on the driving air deflector shaft, the driven air deflector and the driven synchronous pulley are both installed on the driven air deflector shaft, the driving air deflector shaft and the driven air deflector shaft are both rotatably installed on the material blowing pipeline and are both positioned in the material blowing pipeline, the driving synchronous belt wheel is connected with the driven synchronous belt wheel through a synchronous belt, the driving air guide shaft is connected with the air guide motor, the return material monitoring sensor is arranged on the blowing pipeline and is positioned on one side of an air outlet of the blowing pipeline, the return material monitoring sensor is connected with the air guide motor, the driving air guide plate and the driven air guide plate are matched with the wind direction adjusting mechanism, and when the driving air guide plate and the driven air guide plate are level, the driving air guide plate and the driven air guide plate form a closed return material baffle; when a distance exists between the driving air deflector and the driven air deflector, the driving air deflector and the driven air deflector form an air guide channel.

2. The clean bottle chip conveyor for producing regenerated fibers according to claim 1, wherein: the material conveying mechanism further comprises a material conveying motor, a material conveying driving belt wheel, a material conveying driven belt wheel and a material conveying belt, wherein the material conveying driving belt wheel is arranged on the material conveying motor, the material conveying driven belt wheel is arranged on the material conveying section, and the material conveying driving belt wheel is connected with the material conveying driven belt wheel through the material conveying belt.

3. The clean bottle chip conveyor for producing regenerated fibers according to claim 1, wherein: the material control hand wheel is provided with internal threads, the material control screw rod is provided with external threads, and the material control hand wheel is connected with the material control screw rod through threads.

4. The clean bottle chip conveyor for producing regenerated fibers according to claim 1, wherein: the left sealing slide block and the right sealing slide block are T-shaped slide blocks, the left sealing slide groove and the right sealing slide groove are T-shaped slide grooves, the number of the left sealing slide blocks, the right sealing slide blocks, the left sealing slide grooves and the right sealing slide grooves is multiple, the left sealing slide blocks are in one-to-one correspondence with the left sealing slide grooves, and the right sealing slide blocks are in one-to-one correspondence with the right sealing slide grooves.

5. The clean bottle chip conveyor for producing regenerated fibers according to claim 1, wherein: the left sealing spring, the right sealing spring and the sealing plate return spring are compression springs.

6. The clean bottle chip conveyor for producing regenerated fibers according to claim 1, wherein: the shape of blowing material pipeline is the cuboid, the quantity of wind direction regulating plate is six, six wind direction regulating plates are all installed on wind direction regulating shaft along the circumference of wind direction regulating shaft, and the contained angle between every two wind direction regulating plates is 60, the width of wind direction regulating plate is the same with the height of blowing material pipeline, all be provided with the fillet on six wind direction regulating plates, reduce wind direction regulating plate and blow the friction between the pipeline.

7. The clean bottle chip conveyor for producing regenerated fibers according to claim 1, wherein: an air inlet of the blowing pipeline is connected with a blowing fan.

8. The clean bottle chip conveyor for producing regenerated fibers according to claim 1, wherein: when the driving air guide plate and the driven air guide plate form an air guide channel, the driving air guide plate is parallel to the driven air guide plate, and the air guide channel comprises a forward air guide channel and a reverse air guide channel.

9. A conveying method of a clean bottle chip conveying apparatus for producing regenerated fibers according to any one of claims 1 to 8, characterized in that: the method comprises the following steps:

the first step: the dried clean bottle flakes fall into a blanking pipeline, and the material control screw rod stretches and contracts by rotating the material control hand wheel, and the material control screw rod drives the material control plugboard to move, so that the blanking amount of the material conveying pipeline is regulated;

and a second step of: when the material control hand wheel rotates and the material control inserting plate moves into the blanking pipeline, the left sealing block guide surface and the right sealing block guide surface are contacted with the material control inserting plate guide surface, so that the left sealing block and the right sealing block slide upwards, and the blanking amount is reduced; or when the material control hand wheel rotates, the material control plugboard moves outwards of the blanking pipeline, the left sealing block slides downwards through the left sealing spring, the left material control plugboard sliding chute is sealed through the left sealing block, the right material control plugboard sliding chute is sealed through the right sealing block, the dry clean bottle piece is prevented from entering the left material control plugboard sliding chute and the right material control plugboard sliding chute, the movement of the material control plugboard is influenced, the sealing performance of the material control plugboard is reduced, when the sealing plate falls down through the sealing plate reset spring, and the sealing plate guide surface contacts with the material control plugboard guide surface, the material control plugboard is completely opened, and the blanking amount is maximum;

and a third step of: conveying the dried clean bottle flakes in the conveying pipeline into the discharging pipeline through the conveying screw, conveying the dried clean bottle flakes into the discharging pipeline sequentially through the conveying section and the discharging section, and then falling into the conveying pipeline;

fourth step: blowing the clean bottle flakes dried in the feeding pipeline to the next working procedure by wind flow generated by the blowing fan through the blowing pipeline; and the first step to the fourth step are sequentially carried out.

10. The conveying method of a clean bottle chip conveying apparatus for producing regenerated fibers according to claim 9, wherein: in the fourth step, when the return monitoring sensor detects that the dry clean bottle flakes are returned into the blowing pipeline, the return monitoring sensor feeds back signals to the air guide motor to enable the driving air guide plate and the driven air guide plate to form a return baffle, the blowing fan stops working at the moment, the returned dry clean bottle flakes are blown to be clean through rotation of the wind direction adjusting mechanism, and then the return monitoring sensor feeds back the signals for detecting that the dry clean bottle flakes are blown to the air guide motor to enable the driving air guide plate and the driven air guide plate to form an air guide channel; the wind-guiding motor is used for controlling the driving synchronous belt pulley and the driven synchronous belt pulley to synchronously rotate, when the wind-guiding motor positively rotates, the driving wind-guiding plate and the driven wind-guiding plate form a positive wind-guiding channel, and at the moment, the wind-direction adjusting mechanism positively rotates; when the wind-guiding motor reversely rotates, the driving wind-guiding plate and the driven wind-guiding plate form a reverse wind-guiding channel, and at the moment, the wind direction regulating mechanism reversely rotates; the wind blown by the blowing fan is combined with the wind generated by the forward rotation of the wind-guiding motor after passing through the forward wind-guiding channel, and the wind blown by the blowing fan is combined with the wind generated by the reverse rotation of the wind-guiding motor after passing through the reverse wind-guiding channel; and then the dried clean bottle flakes are blown to the next process.