CN212400018U - Anhydrous plastic film master batch dust cleaning device - Google Patents

Abstract

The utility model discloses an anhydrous cleaning device for plastic film master batch dust, which comprises a tank body, a stirring and friction mechanism, a blowing mechanism, a connecting cover plate and a rotating perforated plate; the utility model discloses a reciprocal spiral motion orbit that is about two soft ring bodies of friction stir carries out friction stir to the master batch for adnexed dust drops and upwards blows away through the air current on the master batch, the utility model discloses sewage is gone out the dust and need not the loaded down with trivial details operation of water waste resource and later stage stoving, the utility model discloses a structure that the liquid was annotated to the inside cavity of silica gel material ring body that the soft ring body adoption of friction stir is, so very big reduction with the collision strength of master batch, the production of the powder and the tiny granule of the part collision after having avoided the master batch collision.

Description

Anhydrous plastic film master batch dust cleaning device

Technical Field

The utility model relates to an anhydrous formula plastic film master batch dust belt cleaning device.

Background

At present, the cleaning of plastic film master batches is generally to send the master batches into a tank filled with clear water for cleaning, then stir the master batches through a stirring support in the tank to remove dust, so that the cleaning work of the master batches is realized, and after cleaning, the master batches are collected and then dried through a dryer; above-mentioned cleaning methods is with master batch submergence then carry out rotatory collision formula's stirring through stirring the support and washs, so make partly master batch have the powder and the tiny granule dispersion of part collision after the collision in aqueous, so cause original waste, the powder of collision and the master batch of tiny granule are difficult for collecting moreover, and collection work is loaded down with trivial details, and the master batch through the washing still need carry out extra stoving process in addition, has increased the energy consumption, the utility model develops a need not washing and plastic film master batch belt cleaning device who dries.

SUMMERY OF THE UTILITY MODEL

To the weak point of above-mentioned prior art, the utility model provides a problem do: the plastic film master batch cleaning device does not need washing and drying.

In order to solve the above problem, the utility model discloses the technical scheme who takes as follows:

an anhydrous cleaning device for plastic film master batch dust comprises a tank body, a stirring friction mechanism, a blowing mechanism, a connecting cover plate and a rotating perforated plate; the upper end of the tank body is provided with a connecting cover plate; exhaust holes are uniformly formed in the two sides of the connecting cover plate respectively; a rotary perforated plate is rotatably clamped and mounted below the inner part of the tank body; the rotating perforated plate divides the interior of the tank body into an upper friction stirring cavity and a lower airflow blowing cavity; the stirring friction mechanism is arranged in the friction stirring cavity; the friction stir mechanism comprises a driving motor, a rotating shaft, a positioning gear ring body, two positioning blocks, two rotating screws, two floating internal thread rings, two upper driven gears and a friction stir soft ring body; the driving motor is arranged in the middle of the outer side of the upper end of the connecting cover plate; the lower end of the driving motor is connected with the rotating shaft; the driving motor controls the rotating shaft to do reciprocating forward and reverse rotation movement; the lower end of the rotating shaft extends into the friction stirring cavity and is connected to the middle of the upper end of the rotating porous plate; the positioning gear ring body is arranged on the inner side of the periphery of the upper end of the friction stirring cavity; a gear ring surface is arranged on the inner side of the periphery of the positioning gear ring body; two ends of the inner side of the positioning gear ring body are respectively connected with an upper driven gear in a meshing way; the lower ends of the upper driven gears are respectively connected with a rotating screw; the rotating screw rods are respectively in threaded connection with floating internal thread rings in a penetrating manner; the outer sides of the periphery of the floating internal thread ring are respectively provided with a friction stirring soft ring body; the lower ends of the rotating screw rods are respectively and rotationally clamped at the upper ends of the positioning blocks; the lower end of the positioning block is fixedly connected to two sides of the upper end of the rotary perforated plate through connecting short rods; the blowing mechanism is arranged in the airflow blowing cavity; the air blowing mechanism comprises two air inlet box bodies, a transverse vent pipe, a longitudinal vent pipe, an induced draft fan and an air supply cover; two sides in the airflow blowing cavity are respectively provided with an air inlet box body; the outer side wall of the gas inlet box body is provided with a gas inlet hole; the inner sides of the gas inlet box bodies are respectively provided with a transverse vent pipe; the lower end of the longitudinal vent pipe is connected with the inner end of the transverse vent pipe, and the upper end of the longitudinal vent pipe is provided with an air supply cover; the air supply cover is positioned right below the rotating porous plate; and an induced draft fan is arranged on the longitudinal vent pipe.

Furthermore, one side of the floating internal thread ring is provided with a rectangular positioning hole; a limiting rod with a rectangular section is connected to the rectangular positioning hole in a penetrating manner; the lower end of the limiting rod is fixedly connected to one side of the upper end of the positioning block.

Furthermore, a positioning rotary ring groove is formed in the upper end of the positioning block; the lower end of the rotating screw is provided with a positioning rotating tooth; the rotary screw rod is rotatably clamped in the positioning rotary ring groove at the upper end of the positioning block through the positioning rotary teeth at the lower end.

Furthermore, a rotary clamping ring groove is formed in the inner side of the periphery below the inner part of the tank body; the outer sides of the periphery of the rotating perforated plate are provided with rotating clamping rings; the rotary perforated plate is rotatably clamped on the rotary clamping ring groove around the lower part inside the tank body through the rotary clamping ring on the periphery of the rotary perforated plate.

Further, the friction stirring soft ring body is made of a silica gel material; an annular cavity is arranged inside the friction stirring soft ring body; liquid is injected into the annular cavity.

The beneficial effects of the utility model

The utility model discloses a reciprocal spiral motion orbit that is about two soft ring bodies of friction stir carries out friction stir to the master batch for adnexed dust drops and upwards blows away through the air current on the master batch, the utility model discloses sewage is gone out the dust and need not the loaded down with trivial details operation of water waste resource and later stage stoving, the utility model discloses a structure that the liquid was annotated to the inside cavity of silica gel material ring body that the soft ring body adoption of friction stir is, so very big reduction with the collision strength of master batch, the production of the powder and the tiny granule of the part collision after having avoided the master batch collision.

Drawings

Fig. 1 is a schematic structural diagram of the present invention.

Fig. 2 is a schematic diagram of the local enlarged structure of the present invention.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

As shown in fig. 1 and 2, an anhydrous cleaning device for plastic film master batch dust comprises a tank body 1, a stirring friction mechanism 5, a blowing mechanism 4, a connecting cover plate 2 and a rotary perforated plate 3; the upper end of the tank body 1 is provided with a connecting cover plate 2; the two sides of the connecting cover plate 2 are respectively and uniformly provided with exhaust holes 21; a rotary perforated plate 3 is rotatably clamped and mounted below the inner part of the tank body 1; the rotating porous plate 3 divides the interior of the tank body 1 into an upper friction stirring cavity 11 and a lower airflow blowing cavity 12; the stirring friction mechanism 5 is arranged in the friction stirring cavity 11; the friction stir mechanism 5 comprises a driving motor 51, a rotating shaft 52, a positioning gear ring body 53, two positioning blocks 57, two rotating screws 56, two floating internal thread rings 58, two upper driven gears 54 and a friction stir soft ring body 55; the driving motor 51 is arranged in the middle of the outer side of the upper end of the connecting cover plate 2; the lower end of the driving motor 51 is connected with a rotating shaft 52; the driving motor 51 controls the rotating shaft 52 to do reciprocating positive and negative rotation movement; the lower end of the rotating shaft 52 extends into the friction stirring cavity 11 and is connected to the middle of the upper end of the rotating perforated plate 3; the positioning gear ring body 53 is arranged on the inner side of the periphery of the upper end of the friction stirring cavity 11; a gear ring surface is arranged on the inner side of the periphery of the positioning gear ring body 53; two ends of the inner side of the positioning gear ring body 53 are respectively connected with an upper driven gear 54 in a meshing way; the lower ends of the upper driven gears 54 are respectively connected with a rotating screw 56; the rotating screw rods 56 are respectively threaded through floating internal thread rings 58; the outer sides of the periphery of the floating internal thread ring 58 are respectively provided with a friction stirring soft ring body 55; the lower ends of the rotating screw rods 56 are respectively and rotationally clamped at the upper ends of the positioning blocks 57; the lower ends of the positioning blocks 57 are fixedly connected to the two sides of the upper end of the rotary perforated plate 3 through connecting short rods 572; the blowing mechanism 4 is arranged in the airflow blowing cavity 12; the blowing mechanism 4 comprises two air inlet box bodies 44, a transverse vent pipe 43, a longitudinal vent pipe 42, an induced draft fan 41 and an air supply cover 45; an air inlet box body 44 is respectively arranged at two sides in the airflow blowing cavity 12; an air inlet hole 441 is formed in the outer side wall of the air inlet box body 44; a transverse vent pipe 43 is respectively arranged on the inner sides of the gas inlet box bodies 44; the lower end of the longitudinal vent pipe 42 is connected with the inner end of the transverse vent pipe 43, and the upper end of the longitudinal vent pipe 42 is provided with an air supply cover 45; the air supply cover 45 is positioned right below the rotating perforated plate 3; and an induced draft fan 41 is arranged on the longitudinal vent pipe 42.

As shown in fig. 1 and 2, further, a rectangular positioning hole is formed at one side of the floating internal thread ring 58; a limiting rod 581 with a rectangular section is connected to the rectangular positioning hole in a penetrating manner; the lower end of the limiting rod 581 is fixedly connected to one side of the upper end of the positioning block 57. Further, a positioning rotary ring groove 571 is arranged at the upper end of the positioning block 57; the lower end of the rotating screw 56 is provided with a positioning rotating tooth 561; the rotating screw 56 is rotatably clamped in the positioning rotating ring groove 571 at the upper end of the positioning block 57 by the positioning rotating teeth 561 at the lower end. Further, the inner sides of the periphery of the lower part of the inside of the tank body 1 are provided with rotary clamping ring grooves 13; the outer sides of the periphery of the rotary perforated plate 3 are provided with rotary clamping rings 31; the rotary perforated plate 3 is rotatably clamped on the rotary clamping ring groove 13 around the lower part inside the tank body 1 through the rotary clamping ring 31 on the periphery of the rotary clamping ring. Further preferably, the friction stir soft ring body 55 is made of a silica gel material; an annular cavity 551 is arranged inside the friction stirring soft ring body 55; the annular cavity 551 is filled with a liquid.

The utility model discloses an operation principle as follows: the driving motor 51 controls the rotation shaft 52 to do reciprocating and forward and backward rotation, the lower end of the rotation shaft 52 drives the rotation perforated plate 3 to do forward and backward rotation, so the rotation perforated plate 3 drives the positioning blocks 57 on the two sides of the upper end to do forward and backward rotation, and further the positioning blocks 57 drive the rotation screw 56 to do reciprocating rotation in a large range, and further drives the floating internal thread ring 58 and the friction stirring soft ring body 55 to do forward and backward rotation in a large range, and after the rotation screw 56 rotates, the upper driven gear 54 is driven to roll on the gear ring surface on the inner side of the periphery of the positioning gear ring body 53, so the upper driven gear 54 drives the rotation screw 56 to do reciprocating and self-rotation, and after the rotation screw 56 rotates, the floating internal thread ring 58 is driven to do reciprocating motion up and down, so the friction stirring soft ring body 55 is, and the two soft friction stirring rings 55 float up and down synchronously, so that the two soft friction stirring rings 55 reciprocate up and down to form a spiral motion track.

The utility model discloses a reciprocal spiral motion orbit that is carries out friction stir to the master batch about two soft ring bodies 55 of friction stir for adnexed dust drops and upwards blows away through the air current on the master batch, the utility model discloses sewage is gone out the dust and need not the loaded down with trivial details operation of water waste resource and later stage stoving, the utility model discloses a structure of liquid is annotated to the inside cavity of silica gel material ring body that the soft ring body 55 of friction stir adoption was, so very big reduction with the collision strength of master batch, the production of the powder and the tiny granule of the part collision after having avoided the master batch collision.

The above description is only a preferred embodiment of the present invention, and should not be taken as limiting the invention, and any modifications, equivalent replacements, improvements, etc. made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (5)

1. An anhydrous cleaning device for plastic film master batch dust is characterized by comprising a tank body, a stirring friction mechanism, a blowing mechanism, a connecting cover plate and a rotating perforated plate; the upper end of the tank body is provided with a connecting cover plate; exhaust holes are uniformly formed in the two sides of the connecting cover plate respectively; a rotary perforated plate is rotatably clamped and mounted below the inner part of the tank body; the rotating perforated plate divides the interior of the tank body into an upper friction stirring cavity and a lower airflow blowing cavity; the stirring friction mechanism is arranged in the friction stirring cavity; the friction stir mechanism comprises a driving motor, a rotating shaft, a positioning gear ring body, two positioning blocks, two rotating screws, two floating internal thread rings, two upper driven gears and a friction stir soft ring body; the driving motor is arranged in the middle of the outer side of the upper end of the connecting cover plate; the lower end of the driving motor is connected with the rotating shaft; the driving motor controls the rotating shaft to do reciprocating forward and reverse rotation movement; the lower end of the rotating shaft extends into the friction stirring cavity and is connected to the middle of the upper end of the rotating porous plate; the positioning gear ring body is arranged on the inner side of the periphery of the upper end of the friction stirring cavity; a gear ring surface is arranged on the inner side of the periphery of the positioning gear ring body; two ends of the inner side of the positioning gear ring body are respectively connected with an upper driven gear in a meshing way; the lower ends of the upper driven gears are respectively connected with a rotating screw; the rotating screw rods are respectively in threaded connection with floating internal thread rings in a penetrating manner; the outer sides of the periphery of the floating internal thread ring are respectively provided with a friction stirring soft ring body; the lower ends of the rotating screw rods are respectively and rotationally clamped at the upper ends of the positioning blocks; the lower end of the positioning block is fixedly connected to two sides of the upper end of the rotary perforated plate through connecting short rods; the blowing mechanism is arranged in the airflow blowing cavity; the air blowing mechanism comprises two air inlet box bodies, a transverse vent pipe, a longitudinal vent pipe, an induced draft fan and an air supply cover; two sides in the airflow blowing cavity are respectively provided with an air inlet box body; the outer side wall of the gas inlet box body is provided with a gas inlet hole; the inner sides of the gas inlet box bodies are respectively provided with a transverse vent pipe; the lower end of the longitudinal vent pipe is connected with the inner end of the transverse vent pipe, and the upper end of the longitudinal vent pipe is provided with an air supply cover; the air supply cover is positioned right below the rotating porous plate; and an induced draft fan is arranged on the longitudinal vent pipe.

2. The waterless plastic film master batch dust cleaning device of claim 1, wherein one side of the floating internal thread ring is provided with a rectangular positioning hole; a limiting rod with a rectangular section is connected to the rectangular positioning hole in a penetrating manner; the lower end of the limiting rod is fixedly connected to one side of the upper end of the positioning block.

3. The waterless plastic film master batch dust cleaning device of claim 1, wherein the upper end of the positioning block is provided with a positioning rotary ring groove; the lower end of the rotating screw is provided with a positioning rotating tooth; the rotary screw rod is rotatably clamped in the positioning rotary ring groove at the upper end of the positioning block through the positioning rotary teeth at the lower end.

4. The waterless plastic film master batch dust cleaning device of claim 1, wherein a rotary clamping ring groove is formed in the inner side of the periphery below the inner part of the tank body; the outer sides of the periphery of the rotating perforated plate are provided with rotating clamping rings; the rotary perforated plate is rotatably clamped on the rotary clamping ring groove around the lower part inside the tank body through the rotary clamping ring on the periphery of the rotary perforated plate.

5. The waterless plastic film master batch dust cleaning device of claim 1, wherein the friction stir soft ring body is made of a silica gel material; an annular cavity is arranged inside the friction stirring soft ring body; liquid is injected into the annular cavity.

Images