CN218107439U - A send thick liquid device for production of textile fabric - Google Patents

Abstract

The utility model discloses a send thick liquid device for textile fabric production, including the stirring storehouse, agitator motor, spiral stirring rake, the stagnant flow valve, the terminal surface is provided with control panel before the stirring storehouse, a stirring storehouse side is provided with into thick liquid mouth, the side is provided with agitator motor on the stirring storehouse, the agitator motor lower extreme is provided with main bull stick, main bull stick lower extreme is provided with two spiral stirring rakes, stirring storehouse another side is provided with the stagnant flow valve, the stagnant flow valve opposite side is provided with out the thick liquid mouth, the stagnant flow valve includes the fixed plate, the relay, the cylinder pole, stagnant flow gate and stagnant flow block, stagnant flow gate sets up in stagnant flow block upper end, the cylinder sets up in stagnant flow gate top, the fixed plate sets up in cylinder one side, the relay sets up in the cylinder front side. The beneficial effects reside in that agitator motor control the spiral stirring is carried out positive and negative stirring, and the thick liquid can be guaranteed to the double helix stirring rake can fully stir evenly, and the flow stopping valve is opened after the thick liquid stirring is even, prevents that the thick liquid that does not stir evenly from flowing out, influences the starching quality.

Description

A send thick liquid device for production of textile fabric

Technical Field

The utility model belongs to the textile fabric production field especially relates to a send thick liquid device for textile fabric production.

Background

The textile fabric is divided into two types, namely weft knitting knitted fabric and warp knitting knitted fabric according to a weaving method, wherein the weft knitting knitted fabric is usually formed by knitting low-elasticity polyester yarns or special-shaped polyester yarns, nylon yarns, cotton yarns, wool yarns and the like serving as raw materials on various weft knitting machines by adopting a plain stitch structure, a variable plain stitch structure, a rib plain stitch structure, a double rib plain stitch structure, a jacquard weave structure, a loop structure and the like.

The textile fabric is a process of weaving yarn into yarn coils through a weaving machine to form a fabric in a mutually serially sleeved mode, sizing is needed during processing of the textile fabric, but the mixing direction in a mixing bin in a slurry feeding device for producing the existing textile fabric is single, so that the mixing effect of slurry is poor, and the sizing quality is poor.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing a send thick liquid device for production of textile fabric in order to solve above-mentioned problem.

The utility model discloses a following technical scheme realizes above-mentioned purpose:

the utility model provides a send thick liquid device for textile fabric production, includes stirring storehouse, agitator motor, spiral stirring rake, only flow valve, the terminal surface is provided with control panel before the stirring storehouse, a stirring storehouse side is provided with into thick liquid mouth, the side is provided with on the stirring storehouse agitator motor, the agitator motor lower extreme is provided with main bull stick, main bull stick lower extreme is provided with two spiral stirring rake, stirring storehouse another side is provided with only flow valve, only flow valve opposite side is provided with out the thick liquid mouth, only flow valve includes fixed plate, relay, cylinder pole, only flow brake and only flow block, only flow brake sets up only flow block upper end, the cylinder sets up only flow brake top, the fixed plate sets up cylinder one side, the relay sets up the cylinder front side.

In the structure, after the current signal is changed at regular time by the control panel, the forward rotation signal and the reverse rotation signal are input into the stirring motor through the signal transmission line to drive the stirring motor to perform forward and reverse rotation operation, the control panel controls the relay to be electrified and deenergized through the signal transmission line, the relay controls the cylinder to stretch forwards and contract to drive the flow stopping gate to descend and ascend so as to control the flow stopping valve to stop and discharge, the stirring motor transmits the rotation action to the main rotating rod through the motor shaft, the main rotating rod finally transmits the rotation action to the spiral stirring paddle to perform regular forward and reverse rotation stirring on the slurry to ensure that the slurry can be fully stirred uniformly, and after the slurry is stirred for a period of time, the relay is electrified to control the cylinder to act to drive the flow stopping gate to ascend, and the slurry is discharged from the flow stopping valve.

Preferably, the control panel with the stirring storehouse passes through welding fastening connection, agitator motor with control panel passes through signal transmission line connection transmission signal, agitator motor with the stirring storehouse passes through bolt fastening connection.

Preferably, the slurry inlet and the stirring bin are integrally formed, a motor shaft of the stirring motor is fastened and coaxially connected with the main rotating rod through a bolt, and the main rotating rod is fastened and coaxially connected with the spiral stirring paddle through a bolt.

Preferably, the flow stopping block is fixedly connected with the stirring bin by welding, the fixed plate is fixed with the cylinder by a bolt, the relay is fixedly connected with the fixed plate by a bolt, the flow stopping gate is fixedly connected with the cylinder rod by a bolt, the flow stopping gate is slidably connected with the flow stopping block, and the slurry outlet is fixedly and coaxially connected with the flow stopping block by welding.

Has the advantages that: stirring motor control the spiral stirring is carried out positive and negative stirring, and double helix stirring rake can guarantee that the thick liquid can the intensive mixing, and the flow stopping valve is opened after the thick liquid stirring, prevents that the thick liquid that does not stir evenly from flowing, influences the starching quality.

Drawings

FIG. 1 is a spatial perspective view of a slurry feeding device for textile fabric production according to the present invention;

FIG. 2 is a front view of a slurry feeding device for textile fabric production according to the present invention;

FIG. 3 is a left side view of a slurry feeding device for textile fabric production according to the present invention;

FIG. 4 isbase:Sub>A sectional view A-A of FIG. 3 ofbase:Sub>A slurry feeding apparatus for textile fabric production according to the present invention;

fig. 5 is an enlarged view of part I in fig. 1 of a pulp feeding device for textile fabric production according to the present invention.

Description of reference numerals:

1. a stirring bin; 2. a control panel; 3. a pulp inlet; 4. a stirring motor; 5. a main rotating rod; 6. a helical stirring paddle; 7. a flow stop valve; 701. a fixing plate; 702. a cylinder; 703. a cylinder rod; 704. a relay; 705. a flow stopping gate; 706. a flow stopping block; 8. and a pulp outlet.

Detailed Description

The present invention will be further explained with reference to the accompanying drawings:

as shown in fig. 1-5, a slurry feeding device for textile fabric production includes a stirring bin 1, a stirring motor 4, a spiral stirring paddle 6, and a stop valve 7, a control panel 2 is disposed on a front end surface of the stirring bin 1, the control panel 2 is responsible for controlling forward and reverse rotation of the stirring motor 4 and power on and power off of a relay 704, a slurry inlet 3 is disposed on one side surface of the stirring bin 1, the stirring motor 4 is disposed on an upper side surface of the stirring bin 1, a main rotating rod 5 is disposed at a lower end of the stirring motor 4, the stirring motor 4 is responsible for driving the main rotating rod 5 to rotate, two spiral stirring paddles 6 are disposed at a lower end of the main rotating rod 5, the main rotating rod 5 is responsible for driving the spiral stirring paddles 6 to rotate, a stop valve 7 is disposed on another side surface of the stirring bin 1, a slurry outlet 8 is disposed on another side surface of the stop valve 7, the stop valve 7 includes a fixing plate 701, a relay 704, a cylinder 702, a stop valve 703, a stop valve 705 and a stop valve 706, the relay 704 is disposed above the cylinder 702, the cylinder 705 and the cylinder 701, and the stop valve 702 are disposed on one side of the cylinder 701, and the cylinder 701, thereby controlling slurry to descend.

In the structure, after the current signal is changed at regular time by the control panel 2, the forward rotation signal and the reverse rotation signal are input into the stirring motor 4 through the signal transmission line, the stirring motor 4 is driven to operate in forward and reverse rotation, the control panel 2 controls the relay 704 to be powered on and powered off through the signal transmission line, the relay 704 is extended and contracted through the air pipe control cylinder 702 to drive the flow stop gate 705 to descend and ascend, so that the flow stop and the discharge of the flow stop valve 7 are controlled, the stirring motor 4 transmits the rotation action to the main rotating rod 5 through the motor shaft, the main rotating rod 5 finally transmits the rotation action to the spiral stirring paddle 6, the slurry is stirred in forward and reverse rotation at regular time, the slurry can be fully and uniformly stirred, after the slurry is stirred for a period of time, the relay 704 is powered on to control the cylinder 702 to drive the flow stop gate 705 to ascend, and the flow stop gate 7 discharges the slurry.

Preferably, the control panel 2 is fixedly connected with the stirring bin 1 by welding, the stirring motor 4 is connected with the control panel 2 by a signal transmission line to transmit signals, the stirring motor 4 is fixedly connected with the stirring bin 1 by bolts, the slurry inlet 3 is integrally formed with the stirring bin 1, a motor shaft of the stirring motor 4 is fixedly connected with the main rotating rod 5 by bolts and coaxially connected, the main rotating rod 5 is fixedly connected with the spiral stirring paddle 6 by bolts and coaxially connected, the flow stopping block 706 is fixedly connected with the stirring bin 1 by welding, the fixing plate 701 is fixed with the cylinder 702 by bolts, the relay 704 is fixedly connected with the fixing plate 701 by bolts, the flow stopping gate is fixedly connected with the cylinder rod 703 by bolts, the flow stopping gate 705 is slidably connected with the flow stopping block 706, and the slurry outlet 8 is fixedly connected with the flow stopping block 706 by welding.

The foregoing illustrates and describes the general principles, features and advantages of the present invention. It will be understood by those skilled in the art that the present invention is not limited to the above embodiments, and that the foregoing embodiments and descriptions are provided only to illustrate the principles of the present invention without departing from the spirit and scope of the present invention. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims (4)

1. The utility model provides a send thick liquid device for production of textile fabric which characterized in that: the stirring device comprises a stirring bin (1), a stirring motor (4), spiral stirring paddles (6) and a flow stopping valve (7), wherein a control panel (2) is arranged on the front end face of the stirring bin (1), a slurry inlet (3) is formed in one side face of the stirring bin (1), the stirring motor (4) is arranged on the side face of the stirring bin (1), a main rotating rod (5) is arranged at the lower end of the stirring motor (4), two spiral stirring paddles (6) are arranged at the lower end of the main rotating rod (5), the flow stopping valve (7) is arranged on the other side face of the stirring bin (1), a slurry outlet (8) is formed in the other side face of the flow stopping valve (7), the flow stopping valve (7) comprises a fixing plate (701), a relay (704), a cylinder (702), a cylinder rod (703), a flow stopping gate (705) and a flow stopping block (706), the flow stopping gate (705) is arranged on the upper end of the flow stopping block (706), the cylinder (702) is arranged on one side of the cylinder (704), and the side of the cylinder (702) is arranged on the front side of the cylinder.

2. A slurry feeding device for textile fabric production according to claim 1, characterized in that: control panel (2) with stirring storehouse (1) is through welding fastening connection, agitator motor (4) with control panel (2) are through signal transmission line connection transmission signal, agitator motor (4) with stirring storehouse (1) is through bolt fastening connection.

3. A slurry feed apparatus for textile cloth production according to claim 1, wherein: advance thick liquid mouth (3) with stirring storehouse (1) integrated into one piece, the motor shaft of agitator motor (4) pass through the bolt with main bull stick (5) fastening and coaxial coupling, main bull stick (5) with spiral stirring rake (6) pass through bolt fastening and coaxial coupling.

4. A slurry feed apparatus for textile cloth production according to claim 1, wherein: the flow stopping block (706) is fixedly connected with the stirring bin (1) through welding, the fixing plate (701) is fixed with the air cylinder (702) through bolts, the relay (704) is fixedly connected with the fixing plate (701) through bolts, the flow stopping gate (705) is fixedly connected with the air cylinder rod (703) through bolts, the flow stopping gate (705) is connected with the flow stopping block (706) in a sliding mode, and the slurry outlet (8) is fixedly and coaxially connected with the flow stopping block (706) through welding.

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