CN220428556U - Material helps pressure structure - Google Patents

Abstract

The utility model discloses a material boosting structure, and relates to the technical field of disposable sanitary products. Including side connecting plate, ring waist virtually cut mechanism, transfer roller, material conveying mechanism, waistline take off mechanism, waistline and controller, the waistline cuts through ring waist virtually cut mechanism, forms virtual incision, material conveying mechanism's right side is provided with helps the pressure structure, helps the pressure structure to press the subassembly including supporting, supports the pressure subassembly including pressing the pipe, presses the pipe to the waistline to extrude, makes it fix in material conveying mechanism one side. According to the material boosting structure, the set of material boosting structure is added on the material conveying mechanism, when the material is broken or the machine is stopped, the boosting structure is pressed down to press the material, so that the material cannot retract, the material is prevented from retracting to a virtual cutting part, the manpower is saved, the production efficiency is improved, and meanwhile, the boosting structure is arranged on the outer side of the material conveying mechanism in an attached mode, the whole size is small, the occupied space of the machine is small, and interference with other parts is avoided.

Description

Material helps pressure structure

Technical Field

The utility model relates to the technical field of disposable sanitary products, in particular to a material boosting structure.

Background

In the production process of disposable sanitary products, particularly infant diapers, waistline is usually required to be cut virtually through a waist-surrounding virtual-cutting mechanism, conveyed through a conveying roller and a material conveying mechanism, and then pulled off and transferred through a waistline pulling-out mechanism.

Before the material reaches the waistline opening mechanism through the virtual cutting, a material conveying mechanism is arranged, the mechanism has an adsorption effect and can absorb the material, but the whole material is folded before the waistline is opened, the material conveying mechanism is not easy to absorb the elastic waistline completely, the waistline is broken from the virtual cutting part, the material is adsorbed and transferred through the waistline opening mechanism, and the material which does not reach the waistline opening mechanism is broken because the waistline rubber band is elastically retracted, so that the waistline material can return, at the moment, an operator needs to pull the waistline to attach the waistline outside the material conveying mechanism, the production efficiency is reduced, and the labor is wasted.

Disclosure of Invention

The present utility model is directed to a material boosting structure, which solves the above-mentioned problems in the prior art.

In order to achieve the above purpose, the present utility model provides the following technical solutions: the utility model provides a material helps pressure structure, includes side connecting plate, ring waist virtual cutting mechanism, transfer roller, material conveying mechanism, waistline take off mechanism, waistline and controller, and the waistline cuts through ring waist virtual cutting mechanism, forms virtual incision, material conveying mechanism's right side is provided with helps the pressure structure, helps the pressure structure including supporting the pressure subassembly, supports the pressure subassembly and includes presses the pipe, presses the pipe to the waistline to extrude, makes it fix in material conveying mechanism one side, presses the pipe to be located virtual notched top.

Preferably, the pressing assembly further comprises a side mounting plate, a vertical mounting plate and a plurality of electric telescopic rods, the left side of the vertical mounting plate is connected with a connecting block, the left side of the connecting block is fixedly provided with a fixing plate, the left side of the fixing plate is connected with a fixing shaft, the shaft body of the fixing shaft is movably connected with a movable plate, and two sides of each electric telescopic rod are respectively movably connected with the fixing plate and the movable plate through connecting shafts.

Preferably, the pressure tube is a rubber tube.

Preferably, the pressure-assisting structure further comprises a vertical adjusting assembly.

Preferably, the vertical adjusting component comprises a plurality of dovetail grooves formed in the side face of the vertical mounting plate, a plurality of dovetail blocks are fixed on the side face of the connecting block, the dovetail grooves are matched with the dovetail blocks, a screw rod is connected to the bottom of the vertical mounting plate in a rolling mode, and the screw rod is movably connected with the connecting block in a screwed mode.

Preferably, the electric telescopic rod is electrically connected with the controller.

Compared with the prior art, the utility model has the beneficial effects that:

according to the material boosting structure, the material boosting structure is additionally arranged on the material conveying mechanism, when the material is broken or the machine is stopped, the boosting structure is pressed down to press the material, so that the material cannot retract, the material is prevented from retracting to the virtual cutting part, the manpower is saved, and the production efficiency is improved

Meanwhile, the auxiliary pressing mechanism is arranged outside the material conveying mechanism, is small in whole, occupies small whole space of the machine, and avoids interference with other parts.

Drawings

FIG. 1 is a schematic diagram of the overall structure of the present utility model;

FIG. 2 is an enlarged view of portion A of FIG. 1;

fig. 3 is a detailed view of the boosting structure of the present utility model.

In the figure: 1. a side connection plate; 2. a waist-encircling virtual cutting mechanism; 3. a conveying roller; 4. a material conveying mechanism; 5. a waistline pulling mechanism; 6. waistline; 601. a virtual incision; 701. a side mounting plate; 703. a connecting block; 704. a fixing plate; 705. a fixed shaft; 706. a movable plate; 707. pressing a pipe; 708. an electric telescopic rod; 801. dovetail blocks; 802. and a screw rod.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

The mechanism is specially used for producing paper diapers, relates to processing of waistlines, and can be known that in the waistline production of paper diapers, the waistlines are usually required to be cut virtually through a waist-encircling virtual cutting mechanism, conveyed through a conveying roller and a material conveying mechanism, and then are peeled off and transferred through a waistline peeling mechanism.

Before the material reaches the waistline opening mechanism through the virtual cutting, a material conveying mechanism is arranged, the mechanism has an adsorption effect and can absorb the material, but the whole material is folded before the waistline is opened, the material conveying mechanism is not easy to absorb the elastic waistline completely, the waistline is broken from the virtual cutting part and is adsorbed and transferred through the waistline opening mechanism, and the material which does not reach the waistline opening mechanism is broken because of being pulled, the waistline material can return due to elastic retraction of waistline rubber bands, and an operator needs to pull the waistline to be attached to the outer side of the material conveying mechanism.

As shown in fig. 1-3, the present utility model provides a technical solution: the utility model provides a material helps pressure structure, including side connecting plate 1, ring waist virtual cutting mechanism 2, transfer roller 3, material conveying mechanism 4, waistline take-off mechanism 5, waistline 6 and controller, material conveying mechanism 4 and waistline take-off mechanism 5 all have the function of adsorbing the ring waist, ring waist virtual cutting mechanism 2, transfer roller 3, material conveying mechanism 4, waistline take-off mechanism 5 are prior art, and unnecessary description in this scheme, as shown in fig. 1, waistline 6 (hereinafter collectively referred to as the material) cuts through ring waist virtual cutting mechanism 2, forms virtual incision 601.

A pressing-assisting structure is provided on the right side of the material conveying mechanism 4, wherein the pressing-assisting structure comprises a pressing assembly comprising a pressing tube 707, the pressing tube 707 presses the waist circumference 6 to be fixed on the side of the material conveying mechanism 4, and the pressing tube 707 is located at the top of the virtual cut 601, in this case, in order to increase the friction between the pressing tube 707 and the material, thereby limiting the material on the side of the material conveying mechanism 4, in a specific embodiment the pressing tube 707 is preferably a rubber tube.

In order to move the pressing tube 707, as shown in fig. 3, the pressing assembly further includes a side mounting plate 701, a vertical mounting plate and a plurality of electric telescopic rods 708, the side mounting plate 701 is fixed to the side of the side mounting plate 701 by screws, the vertical mounting plate is vertically fixed to the side of the side mounting plate 701, a connection block 703 is connected to the left side of the vertical mounting plate, a fixing plate 704 is fixed to the left side of the connection block 703, a fixing shaft 705 is connected to the left side of the fixing plate 704, a movable plate 706 is movably connected to a shaft body of the fixing shaft 705, and two sides of the electric telescopic rods 708 are movably connected to the fixing plate 704 and the movable plate 706 by connection shafts respectively.

In order to improve the rotation stability of the movable plate 706, in this embodiment, two electric telescopic rods 708 are symmetrically disposed on two sides of the movable plate 706, and the electric telescopic rods 708 are electrically connected to the controller.

Specifically, when the waistline pulling mechanism 5 adsorbs and breaks the material, the controller controls the electric telescopic rod 708 to start, and when the electric telescopic rod 708 stretches, the movable plate 706 of the belt rotates anticlockwise around the fixed shaft 705 until the pressing pipe 707 is pressed with the material, at this time, the pressing pipe 707 is located right above the virtual incision 601, the material of the waistline pulling mechanism 5 moves, and the waistline 6 is pulled from the virtual incision 601.

In a specific embodiment of this embodiment, as shown in fig. 3, to implement adjustment of the distance between the pressing tube 707 and the top of the virtual cutout 601, the pressing assisting structure further includes a vertical adjustment assembly.

In order to ensure smooth implementation of the scheme, it is required to know that the vertical adjusting component comprises two dovetail grooves formed on the side surface of the vertical mounting plate, two dovetail blocks 801 are fixed on the side surface of the connecting block 703 or integrally formed, the dovetail grooves are matched with the dovetail blocks 801, a screw rod 802 is connected to the bottom of the vertical mounting plate in a rolling way, the screw rod 802 is movably connected with the connecting block 703 in a screwed manner, and a knob is fixed at the top end of the screw rod 802.

Specifically, when the distance between the pressing pipe 707 and the top of the virtual notch 601 is adjusted, the screw rod 802 is driven to rotate through the rotating knob, and the dovetail block 801 is limited by the dovetail groove, so that the connecting block 703 can move up and down, the position adjustment of the pressing pipe 707 is realized, and finally, when the pressing pipe 707 is used for limiting a material, the position adjustment of the pressing pipe 707 on the top of the virtual notch 601 is realized, the position adjustment of the mechanism is convenient, the breaking of the material is convenient, and the material is effectively prevented from being absorbed by the material conveying mechanism 4 and the waistline pulling mechanism 5 due to elastic retraction of waistline rubber strings.

Although embodiments of the present utility model have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made hereto without departing from the spirit and scope of the utility model as defined by the appended embodiments and equivalents thereof.

Claims (6)

1. The utility model provides a material helps pressure structure, includes side connecting plate (1), ring waist virtually cuts mechanism (2), transfer roller (3), material conveying mechanism (4), waistline and takes off opening mechanism (5), waistline (6) and controller, and waistline (6) cut through ring waist virtually cuts mechanism (2), forms virtual incision (601), its characterized in that: the right side of material conveying mechanism (4) is provided with helping the pressure structure, and helping the pressure structure and including supporting the pressure subassembly, support and press the subassembly and include pressing pipe (707), press pipe (707) to waistline (6) extrusion, make it fix in material conveying mechanism (4) one side, press pipe (707) to be located the top of virtual incision (601).

2. A material compression assist structure as in claim 1, wherein: the pressing assembly further comprises a side mounting plate (701), a vertical mounting plate and a plurality of electric telescopic rods (708), wherein the left side of the vertical mounting plate is connected with a connecting block (703), the left side of the connecting block (703) is fixedly provided with a fixing plate (704), the left side of the fixing plate (704) is connected with a fixing shaft (705), the shaft body of the fixing shaft (705) is movably connected with a movable plate (706), and two sides of each electric telescopic rod (708) are respectively movably connected with the fixing plate (704) and the movable plate (706) through connecting shafts.

3. A material compression assist structure as in claim 1, wherein: the pressing pipe (707) is a rubber pipe.

4. A material compression assist structure as claimed in claim 2, wherein: the boosting structure further comprises a vertical adjusting assembly.

5. A material compression assist structure as defined in claim 4, wherein: the vertical adjusting assembly comprises a plurality of dovetail grooves formed in the side face of the vertical mounting plate, a plurality of dovetail blocks (801) are fixed on the side face of the connecting block (703), the dovetail grooves are matched with the dovetail blocks (801), a screw rod (802) is connected to the bottom of the vertical mounting plate in a rolling mode, and the screw rod (802) is movably connected with the connecting block (703) in a screwed mode.

6. A material compression assist structure as claimed in claim 2, wherein: the electric telescopic rod (708) is electrically connected with the controller.