CN217844619U - High wear-resisting water thorn machine dewatering mechanism for non-woven fabrics - Google Patents

Abstract

The utility model provides a high wear-resisting water thorn machine dewatering mechanism for non-woven fabrics, including the water thorn machine main part, be provided with the dehydration subassembly in the water thorn machine main part, the dehydration subassembly includes the backup pad, the extrusion groove has been seted up to the inside of backup pad, the inside sliding connection in extrusion groove has the transmission piece, fixed mounting has the roller that absorbs water on the transmission piece, the utility model provides a high wear-resisting water thorn machine dewatering mechanism for non-woven fabrics, it removes to drive harmless cloth through the driving piece for harmless cloth, when the roller that absorbs water for harmless cloth is being passed through, is extruded harmless cloth by the roller that absorbs water, and then can make the rivers in the harmless cloth go out to absorbed by the roller that absorbs water, and when the roller that absorbs water is rotatory, can make the roller that absorbs water of extrusion piece pairing rotation extrude, and then can make the inside water of roller that absorbs water flow downwards along the extrusion piece, make can accomplish the dehydration to the non-woven fabrics, avoided current dewatering mechanism to make the backward flow of water easily, make the dehydration effect to the non-woven fabrics not good.

Description

High wear-resisting water thorn machine dewatering mechanism for non-woven fabrics

Technical Field

The utility model relates to a water thorn machine dehydration technology field especially relates to a high wear-resisting water thorn machine dewatering mechanism for non-woven fabrics.

Background

The spunlace method is also called as a jet-flow net method, a hydraulic entangling method, a water-jet cloth forming method and the like, is a unique and novel processing technology in a non-woven cloth consolidation process, and utilizes high-speed and high-pressure water flow to impact a fiber net to promote fibers to be entangled and cohered with each other so as to achieve the purpose of reinforcing the fiber net.

The fiber web formed by winding through the spunlace method contains too much water, and the quality of the fiber web is influenced by the too much water, so that a dehydration process needs to be added after the fiber web is formed by the spunlace method.

Therefore, it is necessary to provide a dewatering mechanism for a spunlace machine for a high abrasion resistance spunlace nonwoven fabric to solve the above technical problems.

SUMMERY OF THE UTILITY MODEL

The utility model provides a high wear-resisting water thorn machine dewatering mechanism for non-woven fabrics has solved the problem that causes the water reflux easily after the dehydration of current dewatering structure.

For solving the technical problem, the utility model provides a high wear-resisting water thorn machine dewatering mechanism for non-woven fabrics, including water thorn machine main part, be provided with the dehydration subassembly in the water thorn machine main part, the dehydration subassembly includes the backup pad, the extrusion groove has been seted up to the inside of backup pad, the inside sliding connection in extrusion groove has the transmission piece, fixed mounting has the roller that absorbs water on the transmission piece, the top fixed mounting of backup pad has the rotation motor, the output fixed mounting who rotates the motor has the actuating lever, fixed mounting has the stopper in the water thorn machine main part, the fixed slot has been seted up to the inside of stopper, the inside fixed mounting of fixed slot has the promotion spring, the one end fixed mounting that promotes the spring has the promotion piece, the one end fixed mounting that promotes the piece has the extrusion piece.

Preferably, the support plate is fixedly installed on the main body of the spunlace machine, and the extrusion groove and the transmission block are both square.

Preferably, the number of the support plates is two, the two support plates are symmetrically distributed on two sides of the main body of the spunlace machine, and the structures of the two support plates are the same.

Preferably, the transmission blocks are arranged in a plurality, and the transmission blocks are symmetrically distributed on two sides of the extrusion groove.

Preferably, the suction roll is located between the two support plates, one end of the driving rod penetrates through the tops of the support plates and extends to the inside of the pressing groove, and the driving rod is rotatably connected with the support plates.

Preferably, the driving rod adopts positive and negative threaded rod to the driving rod is located the inside of transmission piece, the driving rod with transmission piece threaded connection.

Preferably, the squeezing blocks are triangular, the squeezing blocks are located below the water suction roller, the surfaces of the squeezing blocks are in contact with the water suction roller, and the surfaces of the pushing blocks are in sliding connection with the inner surface of the fixing groove.

Compared with the prior art, the utility model provides a high wear-resisting water thorn machine dewatering mechanism for non-woven fabrics has following beneficial effect:

the utility model provides a high wear-resisting water thorn machine dewatering mechanism for non-woven fabrics, it removes to drive harmless cloth through the driving piece, make harmless cloth when the roller absorbs water, extrude harmless cloth by the roller that absorbs water, and then can make the rivers in the harmless cloth go out, and absorb by the roller that absorbs water, and when the roller that absorbs water is rotatory, can make the roller that absorbs water of extrusion piece pairing rotation extrude, and then can make the inside water of roller that absorbs water flow downwards along the extrusion piece, make and to accomplish the dehydration to the non-woven fabrics, avoided current dewatering mechanism to make the backward flow of water easily, make the dehydration effect to the non-woven fabrics not good.

Drawings

FIG. 1 is a schematic structural view of a preferred embodiment of a dewatering mechanism of a spunlace machine for highly abrasion-resistant spunlace nonwoven fabric provided by the present invention;

FIG. 2 is a perspective view of the stop block shown in FIG. 1;

fig. 3 is a sectional view of the stopper shown in fig. 2.

Reference numbers in the figures: 1. the water jet machine comprises a water jet machine main body 2, a dewatering component 21, a supporting plate 22, an extrusion groove 23, a transmission block 24, a water suction roller 25, a rotating motor 26, a driving rod 27, a limiting block 28, a fixing groove 29, a pushing spring 210, a pushing block 211 and an extrusion block.

Detailed Description

The present invention will be further described with reference to the accompanying drawings and embodiments.

Referring to fig. 1, fig. 2 and fig. 3, fig. 1 is a schematic structural diagram of a dewatering mechanism of a spunlace machine for high abrasion resistance spunlace nonwoven fabric according to a preferred embodiment of the present invention; FIG. 2 is a perspective view of the stop block shown in FIG. 1; fig. 3 is a sectional view of the stopper shown in fig. 2. The utility model provides a high wear-resisting water thorn machine dewatering mechanism for water thorn non-woven fabrics, includes water thorn machine main part 1, be provided with dehydration subassembly 2 on the water thorn machine main part 1, dehydration subassembly 2 includes backup pad 21, extrusion groove 22 has been seted up to the inside of backup pad 21, the inside sliding connection of extrusion groove 22 has driving block 23, fixed mounting has water absorbing roller 24 on the driving block 23, the top fixed mounting of backup pad 21 has rotation motor 25, the output fixed mounting who rotates motor 25 has actuating lever 26, fixed mounting has stopper 27 on water thorn machine main part 1, fixed slot 28 has been seted up to the inside of stopper 27, the inside fixed mounting of fixed slot 28 has promotion spring 29, the one end fixed mounting that promotes spring 29 has promotion piece 210, the one end fixed mounting that promotes piece 210 has extrusion piece 211.

An external power supply supplies power to the rotating motor 25, and a control switch is arranged between the external power supply and the rotating motor 25.

A collection tank for collecting water is provided at one side of the pressing block 211.

The support plate 21 is fixedly installed on the main body 1 of the spunlace machine, and the extrusion groove 22 and the transmission block 23 are both square.

The pressing groove 22 limits the transmission block 23 so that the transmission block 23 can only slide up and down.

The number of the support plates 21 is two, the two support plates 21 are symmetrically distributed on two sides of the main body 1 of the spunlace machine, and the structures of the two support plates 21 are the same.

The transmission blocks 23 are arranged in a plurality, and the transmission blocks 23 are symmetrically distributed on two sides of the extrusion groove 22.

The plurality of drive blocks 23 are configured to support two suction rolls 24.

The suction roll 24 is located between the two support plates 21, one end of the driving rod 26 penetrates the top of the support plates 21 and extends to the inside of the pressing groove 22, and the driving rod 26 is rotatably connected with the support plates 21.

The two suction rolls 24 can only be provided with suction elements on the surface of the bottom suction roll 24, so that the water taken out can only be absorbed by the bottom suction roll 24.

The driving rod 26 adopts a positive and negative threaded rod, the driving rod 26 is positioned inside the transmission block 23, and the driving rod 26 is in threaded connection with the transmission block 23.

The positive and negative threaded rod can drive the two transmission blocks 23 to approach each other or move away from each other when rotating.

The squeezing blocks 211 are triangular, the squeezing blocks 211 are positioned below the water suction roller 24, the surfaces of the squeezing blocks 211 are in contact with the water suction roller 24, and the surfaces of the pushing blocks 210 are in sliding connection with the inner surfaces of the fixing grooves 28.

The triangular pressing blocks 211 can press the water suction roll 24, and after pressing, water is made to flow down along the pressing blocks 211.

The utility model provides a high wear-resisting water thorn machine dewatering mechanism for non-woven fabrics's theory of operation as follows:

when needs are to the non-woven fabrics dehydration, through placing the non-woven fabrics between two transmission blocks 23, then thickness according to the non-woven fabrics, the control rotates the output of motor 25 rotatory, it is rotatory that the output of rotating motor 25 rotates to drive actuating lever 26, actuating lever 26 is rotatory to make two transmission blocks 23 be close to each other or keep away from each other, make can control the distance between two transmission blocks 23 as required, then drive the non-woven fabrics by pulling the piece and remove, make the non-woven fabrics when through water absorption roller 24, receive water absorption roller 24's extrusion, make water in the non-woven fabrics absorb water by water absorption roller 24 by the extrusion, when water absorption roller 24 is rotatory, can make extrusion piece 211 extrusion water absorption roller 24, and then can make the water on the water absorption roller 24 flow downwards along extrusion piece 211.

Compared with the prior art, the utility model provides a high wear-resisting water thorn machine dewatering mechanism for non-woven fabrics has following beneficial effect:

drive harmless cloth through the driving piece and remove, make harmless cloth when through suction roll 24, extrude harmless cloth by suction roll 24, and then can make the rivers in the harmless cloth flow, and absorbed by suction roll 24, and when suction roll 24 is rotatory, can make the absorbent roll 24 of extrusion piece 211 pairing rotation extrude, and then can make the inside water of suction roll 24 flow downwards along extrusion piece 211, make can accomplish the dehydration to the non-woven fabrics, avoided current dewatering mechanism to make the backward flow of water easily, make the dehydration effect to the non-woven fabrics not good.

The foregoing shows and describes the basic principles and principal features of the invention, together with the advantages thereof. 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 (7)

1. The utility model provides a high wear-resisting water thorn machine dehydration mechanism for non-woven fabrics, includes water thorn machine main part (1), its characterized in that, be provided with dehydration subassembly (2) on water thorn machine main part (1), dehydration subassembly (2) are including backup pad (21), extrusion groove (22) have been seted up to the inside of backup pad (21), the inside sliding connection in extrusion groove (22) has drive block (23), fixed mounting has water absorption roller (24) on drive block (23), the top fixed mounting of backup pad (21) has rotation motor (25), the output fixed mounting who rotates motor (25) has actuating lever (26), fixed mounting has stopper (27) on water thorn machine main part (1), fixed slot (28) have been seted up to the inside of stopper (27), the inside fixed mounting of fixed slot (28) has push spring (29), the one end fixed mounting that pushes away piece (210) of push spring (29), the one end fixed mounting that pushes away piece (210) has extrusion piece (211).

2. A hydroentangling machine dewatering mechanism for highly abrasion resistant hydroentangled nonwoven fabrics according to claim 1, characterized in that the support plate (21) is fixedly mounted on the hydroentangling machine body (1), and the pressing groove (22) and the driving block (23) are both square.

3. A hydroentangling machine dewatering mechanism for highly abrasion resistant spunlace nonwoven fabric according to claim 1, characterized in that there are two support plates (21), the two support plates (21) are symmetrically distributed on both sides of the hydroentangling machine body (1), and the structures on the two support plates (21) are the same.

4. A dewatering mechanism for a high abrasion resistant hydroentangled nonwoven fabric according to claim 1, characterized in that a plurality of said driving blocks (23) are provided, said plurality of driving blocks (23) being symmetrically distributed on both sides of said pressing channel (22).

5. A hydroentangling machine dewatering mechanism for highly abrasion resistant spunlace nonwoven fabric according to claim 1, characterized in that the water suction roll (24) is located between the two support plates (21), one end of the driving rod (26) extends through the top of the support plates (21) and into the interior of the pressing channel (22), and the driving rod (26) is rotatably connected to the support plates (21).

6. A dewatering mechanism for a high abrasion resistant hydroentangled nonwoven fabric according to claim 1, characterized in that the driving rod (26) is a positive and negative threaded rod and the driving rod (26) is located inside the driving block (23), the driving rod (26) being in threaded connection with the driving block (23).

7. A hydroentangling machine dewatering mechanism for highly abrasion resistant spunlace nonwoven fabric according to claim 1, characterized in that the pressing blocks (211) are triangular and the pressing blocks (211) are located below the water suction roll (24), the surface of the pressing blocks (211) is in contact with the water suction roll (24) and the surface of the pushing blocks (210) is in sliding connection with the inner surface of the fixing groove (28).

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