CN108951093B - Cutting method for cutting pearl wool board by utilizing hot oxygen flow - Google Patents

Abstract

The present invention relates to a cutting method, and more particularly, to a cutting method using a hot oxygen stream. In the prior art, the production of the pearl cotton plate is performed through a die, so that the efficiency is low, and multiple types of products need to be provided with multiple sets of dies, so that the cost is high. In order to solve the problems, the technical scheme is as follows: the method comprises the following steps: the method comprises the following steps: placing the pearl wool plate to be cut in a product placing area; step two: starting a positioning power supply, and positioning a cutting device with a cutting nozzle above a product placing area according to a preset position; step three: starting a cutting power supply, simultaneously opening hot oxygen flow, and cutting by a cutting device with a cutting nozzle according to a preset cutting path; step four: the positioning power supply and the cutting power supply are turned off, and simultaneously the hot oxygen flow is turned off, so that the cut product leaves the product placing area. The method can simultaneously cut a plurality of products, improves the efficiency, and can also set different cutting paths and cutting intervals according to different product shapes, thereby reducing the cost.

Description

Cutting method for cutting pearl wool board by utilizing hot oxygen flow

Technical Field

The invention relates to a cutting method, in particular to a cutting method for cutting a pearl wool board by utilizing hot oxygen flow.

Background

The EPE pearl wool is a novel environment-friendly packaging material, is commonly used for packaging products such as electronic appliances, instruments and meters, computers, cosmetics, sound equipment, medical appliances, wines and the like, plays a role in protecting and buffering, and is more and more widely applied to the market.

The pearl cotton produced by the prior art is in a shape of a product protected as required, different molds are manufactured, a single mold can only be used for demolding one at a time, the efficiency is low, the cost is high when a plurality of molds are manufactured, the molds are required to be maintained frequently during production by the molds, the production process is extremely inconvenient, a plurality of sets of molds are required to be arranged during production of different products, and the cost is high.

Disclosure of Invention

In order to solve the defects in the prior art, the cutting method for cutting the pearl cotton plate by using the hot oxygen flow is provided, the pearl cotton plate is cut by the hot oxygen flow, a plurality of pearl cotton plates of the same type can be simultaneously cut, the production efficiency is improved, different cutting intervals and cutting paths can be set according to different products, and the cost of a plurality of sets of dies is reduced.

The technical scheme adopted by the invention is as follows: a cutting method for cutting a pearl wool board by using hot oxygen flow comprises the following steps:

the method comprises the following steps: placing the pearl wool plate to be cut in a product placing area;

step two: starting a positioning power supply, and positioning a cutting device with a cutting nozzle above a product placing area according to a preset position;

step three: starting a cutting power supply, simultaneously opening hot oxygen flow, and cutting by a cutting device with a cutting nozzle according to a preset cutting path;

step four: the positioning power supply and the cutting power supply are turned off, and simultaneously the hot oxygen flow is turned off, so that the cut product leaves the product placing area.

Preferably, the cutting nozzle has a diameter of 5 mm.

Preferably, the temperature of the hot oxygen stream is 60-80 ℃.

Preferably, the position and the cutting path of the cutting device are set by a single chip microcomputer program and are driven by a servo motor.

Preferably, the switch of the cutting power supply and the switch for controlling the on-off of the hot oxygen flow are the same.

Preferably, the product placement area further comprises a conveyor belt through which the cut products leave the product placement area.

Preferably, the cutting device comprises a cutting nozzle dot matrix distributed with a plurality of cutting nozzles, a spacing adjusting mechanism for adjusting the spacing of the cutting nozzles, an up-down adjusting mechanism for adjusting the overall up-down movement of the cutting nozzle dot matrix and a path adjusting mechanism for adjusting the cutting path of the cutting nozzle dot matrix.

Preferably, the path adjusting mechanism comprises a square fixed slide rail, a first slide rail, a second slide rail, a first slide block and a second slide block, the first slide block can move on the first slide rail, the second slide block can move on the second slide rail, the plane moving frame is fixedly provided with a fixed block, the plane moving frame further comprises a third slide rail parallel to the second slide rail, the third slide rail penetrates through the fixed block and is fixedly connected with the first slide block, the fixed block can move on the third slide rail, the plane moving frame is provided with a through hole parallel to the first slide rail, the plane moving frame further comprises a fourth slide rail, the fourth slide rail penetrates through the through hole and is fixedly connected with the second slide block, and the plane moving frame can move on the fourth slide rail through the through hole.

The invention has the beneficial effects that: the utility model provides a cutting method of cutting pearl cotton board, included the cutting nozzle dot matrix that comprises a plurality of cutting nozzles, still be equipped with the interval adjustment mechanism of adjusting the cutting nozzle interval, adjust the whole upper and lower adjustment mechanism that reciprocates of cutting nozzle dot matrix and adjust the route adjustment mechanism of cutting nozzle dot matrix cutting route, through single chip microcomputer control servo motor, adjust the interval and the height of cutting nozzle, redrive cutting nozzle cuts along appointed route, can accomplish a plurality of same specification products and the product has good uniformity in the same time, production efficiency has also been improved, this method utilizes the characteristic of pearl cotton board low-melting point, adopt the hot oxygen stream to cut it, can set up different cutting route and cutting interval according to different product shapes, need not to set up many sets of moulds, the cost is reduced.

Drawings

FIG. 1 is a schematic structural diagram of a cutting machine for cutting a pearl wool board by using a hot oxygen flow according to the present invention;

FIG. 2 is a schematic structural view of a spacing adjustment mechanism;

FIG. 3 is a schematic structural view of a lateral spacing adjustment unit;

FIG. 4 is a schematic view of the longitudinal spacing adjustment assembly;

fig. 5 is a schematic structural view of the first guide rail 3 in fig. 2;

fig. 6 is a schematic structural view of the second guide rail 7 in fig. 2;

FIG. 7 is a schematic view of the structure of the cutting nozzle 6 of FIG. 3;

FIG. 8 is a schematic view of the structure of the up-down adjustment mechanism;

fig. 9 is a schematic structural view of the ball screw 10 in fig. 8;

FIG. 10 is a schematic view of the lead screw 102 of FIG. 9;

FIG. 11 is a schematic view of the construction of the bearing assembly 101 of FIG. 9;

fig. 12 is a schematic structural view of the path adjustment mechanism.

The numbers in the figures are as follows:

a product placement area 1; a cutting device 2; a first guide rail 3; a first link 4; a second link 5; a cutting nozzle 6; a connecting groove 61; a guide block 62; an air inlet 63; an air outlet 64; the first guide groove 31; a second guide rail 7; the second guide groove 71; a connecting column 8; a planar moving frame 9; a ball screw 10; a bearing assembly 101; a screw rod 102; a fixing member 103; a rotary member 104; a polished rod portion 105; a threaded stem portion 106; a sprocket 107; a chain 11; a conveyor belt 12; a first slide rail 13; a second slide rail 14; a first slider 15; a second slider 16; a fixed block 17; a third slide rail 18; a fourth slide rail 19.

Detailed Description

The following figures further illustrate the present invention in conjunction with the description of the figures and the detailed description.

A cutting method for cutting a pearl wool board by using hot oxygen flow comprises the following steps:

the method comprises the following steps: placing a pearl wool plate to be cut in a product placing area 1;

step two: starting a positioning power supply, and positioning the cutting device 2 with the cutting nozzle 6 above the product placing area 1 according to a preset position;

step three: starting a cutting power supply, simultaneously opening hot oxygen flow, and cutting by the cutting device 2 with the cutting nozzle 6 according to a preset cutting path;

step four: the positioning power and the cutting power are turned off, and at the same time the flow of hot oxygen is turned off, the cut product leaves the product placement area 1.

In this embodiment, the switch of the cutting power supply and the switch for controlling the on-off of the hot oxygen flow are the same.

As shown in fig. 1, the cutting machine for cutting the pearl wool board by using the hot oxygen stream, the product placing area 1 further comprises a conveyor belt 12, and the cut product leaves the product placing area 1 through the conveyor belt 12.

As shown in fig. 1, the cutting machine for cutting the pearl wool plate by adopting the hot oxygen flow comprises a cutting nozzle lattice distributed with a plurality of cutting nozzles 6, a space adjusting mechanism for adjusting the space between the cutting nozzles 6, an up-down adjusting mechanism for adjusting the whole up-down movement of the cutting nozzle lattice and a path adjusting mechanism for adjusting the cutting path of the cutting nozzle lattice. The precise positioning of the cutting nozzle is realized by arranging the spacing adjusting mechanism for adjusting the spacing of the cutting nozzle, the up-and-down adjusting mechanism for adjusting the overall up-and-down movement of the cutting nozzle lattice and the path adjusting mechanism for adjusting the cutting path of the cutting nozzle lattice.

The spacing adjustment mechanism shown in fig. 2-6 comprises a plurality of transverse spacing adjustment units, each transverse spacing adjustment unit comprises a connecting rod telescoping mechanism and two first guide rails 3, each connecting rod telescoping mechanism comprises a plurality of first connecting rods 4 and second connecting rods 5 which are sequentially connected through a rotating shaft, the first connecting rods 4 and the second connecting rods 5 are the same in length, a connecting groove 61 is formed in the upper portion of each cutting nozzle 6, the two free ends of each connecting rod telescoping mechanism and the hinged ends of the first connecting rods 4 and the second connecting rods 5 on the same side are hinged to the connecting groove 61 of each cutting nozzle 6, the first guide rails 3 are provided with first guide grooves 31 corresponding to the corresponding positions, and the cutting nozzles 6 are provided with two guide blocks 62 capable of moving in the first guide grooves 31.

In this embodiment, the distance adjusting mechanism further includes two second guide rails 7, second guide grooves 71 corresponding to the second guide rails 7 in opposite positions are formed on the second guide rails 7, and a longitudinal distance adjusting assembly capable of adjusting the front-back vertical movement of the first guide rail 3 in the second guide grooves 71 is further included.

In this embodiment, there are two longitudinal distance adjusting assemblies, which are respectively located at two ends of the first guide rail 3. Vertical interval adjustment assembly includes connecting rod telescopic machanism and a plurality of spliced pole 8, connecting rod telescopic machanism includes first connecting rod 4 and the second connecting rod 5 that a plurality of connected gradually through the pivot, first connecting rod 4 is the same with the length of second connecting rod 5, spliced pole 8 one end with 3 fixed connection of two first guide rails, the other end with connecting rod telescopic machanism is articulated.

In this embodiment, still including taking first connecting plate and two second connecting plates, first connecting plate and second connecting plate all have the guide way, horizontal interval adjustment assembly's connecting rod telescopic machanism's upper portion hinged end with the guide way of first connecting plate is connected and can move in the guide way, vertical interval adjustment assembly's connecting rod telescopic machanism's upper portion hinged end with the guide way of second connecting plate is connected and can move in the guide way, still includes a fixed plate, the fixed plate with the equal fixed connection of first connecting plate and two second connecting plates, still includes the mechanism that adjustable fixed plate reciprocated, the mechanism that adjustable fixed plate reciprocated includes ball screw, ball screw's one end and fixed plate fixed connection, ball screw is driven by servo motor.

Referring to fig. 7, fig. 7 shows a cutting nozzle 6, the upper portion of the cutting nozzle 6 is provided with a connecting groove 61, two guide blocks 62 capable of moving in the first guide groove 31, an air inlet 63 and an air outlet 64, and the air inlet 63 and the air outlet 64 are communicated with each other. In the embodiment, the air flow introduced by the cutting nozzle 6 is hot oxygen flow with the temperature of 60-80 ℃, the diameter of the cutting nozzle 6 is 5mm, and the pearl cotton plate is vertically cut by controlling the high-pressure hot oxygen flow at the linear speed of 10mm/s through the single chip microcomputer.

The transverse spacing adjusting units are provided with ten transverse spacing adjusting units, each transverse spacing adjusting unit comprises five cutting nozzles which jointly form a 5-10 cutting nozzle lattice, the distances among the cutting nozzles are jointly adjusted through connecting rod telescopic mechanisms of the transverse spacing adjusting assembly and the longitudinal spacing adjusting assembly, the connecting rod telescopic mechanisms move on the tracks and are driven by servo motors, and the servo motors are controlled by a single chip microcomputer to be switched on and off.

The cutting nozzle lattice of 5 x 10 is only one preferable scheme of the invention, and the number of the cutting nozzles can be increased or reduced according to the actual production requirement, and the protection scope of the invention is also considered.

The vertical adjustment mechanism as shown in fig. 8-11, further comprises a plane moving frame 9, the vertical adjustment mechanism comprises a ball screw 10, the ball screw 10 comprises a bearing assembly 101 and a screw 102, the bearing assembly 101 comprises a fixing member 103 and a rotating member 104 which are coaxial, the fixing member 103 is fixed on the plane moving frame 9, the rotating member 104 can rotate along a central axis plane relative to the fixing member 103, the screw 102 comprises a polished rod part 105 and a threaded rod part 106, the polished rod part 105 is fixedly connected with the cutting nozzle lattice, and the threaded rod part 106 is connected with the plane moving frame 9 and the rotating member 104 through threads.

The ball screw 10 is three and distributed in a triangular shape, the chain wheel 107 is arranged on the upper portion of the rotating part 104, the chain 11 is further included, and the chain 11 is meshed with the three chain wheels 107 and is sequentially connected to form a closed transmission system. The ball screw is adopted to convert the rotary motion into the linear motion of the screw rod, so that the up-and-down adjustment of the cutting device is realized, the ball screw is driven by a chain, the transmission ratio is accurate and reliable, and the synchronous control can be realized

A path adjusting mechanism as shown in fig. 12, which is connected to the plane moving frame 9, and adjusts the movement of the plane moving frame 9 in the horizontal plane, the path adjusting device comprises a fixed slide rail which is square and comprises two first slide rails 13 and two second slide rails 14, a first slide block 15 which can move on the first slide rails 13 and a second slide block 16 which can move on the second slide rails 14, the plane moving frame 9 is fixedly provided with a fixed block 17 and also comprises a third slide rail 18 parallel to the second slide rail 14, the third slide rail 18 passes through the fixed block 17 and is fixedly connected with the first slide block 15, the fixed block 17 can move on the third slide rail 18, the plane moving frame 9 is provided with a through hole parallel to the first slide rail 13 and also comprises a fourth slide rail 19, the fourth slide rail 19 passes through the through hole and is fixedly connected with the second slide block 16, and the plane moving frame 9 can move on the fourth slide rail 19 through the through hole.

The path adjusting mechanism further comprises two mutually independent chain transmission assemblies, the movement of the movable frame on the third slide rail 13 and the fourth slide rail 14 is adjusted respectively, each chain transmission assembly comprises a chain and a chain wheel with the same three specifications, the chain wheels are distributed in a triangular shape, the chain is sequentially meshed with the chain wheels and connected with the chain wheels, and two free ends of the chain are fixedly connected with the first slide block 15 or the second slide block 16.

The chain transmission in the invention is driven by the servo motor, the servo motor has the advantages of high precision and high stability, and the signal voltage is zero without autorotation phenomenon, so that the accurate positioning of the cutting mechanism can be realized.

The product placing area 1 comprises a conveyor belt 12, and a pearl cotton plate with cutting is moved to a designated area through the conveyor belt and then cut by a cutting device.

The invention is realized by the following steps: the pearl cotton board that will wait to cut passes through the conveyer belt and conveys to the cutting region, according to the shape specification of required product, sets for the singlechip procedure, and singlechip control servo motor adjusts the interval between the cutting nozzle and the cutting nozzle apart from the distance to the pearl cotton board, and the cutting path that the cutting nozzle was set for according to the singlechip afterwards, under servo motor's drive, cuts the pearl cotton board, and the product that once cutting can obtain a plurality of the same specifications, and production efficiency is high. Through single chip microcomputer control, drive servo motor adjusts cutting nozzle's interval and height, drives cutting nozzle again and cuts along appointed route, can accomplish a plurality of same specification products and product in the same time and have good uniformity, has also improved production efficiency to, adopt the indirect control connecting rod telescopic machanism of singlechip to remove on the track and the transmission of chain, development cost is lower

The above description is only an embodiment of the present invention, and not intended to limit the scope of the present invention, and all equivalent structures made by using the contents of the specification and the drawings of the present invention or directly or indirectly applied to other related technical fields are included in the scope of the present invention.

Claims (4)

1. A cutting method for cutting a pearl wool board by using hot oxygen flow is characterized by comprising the following steps:

the method comprises the following steps: placing a pearl wool plate to be cut in a product placing area (1);

step two: starting a positioning power supply, and positioning a cutting device (2) with a cutting nozzle (6) above the product placing area (1) according to a preset position; the position and the cutting path of the cutting device (2) are set through a single chip microcomputer program and are driven by a servo motor; the cutting device (2) comprises a cutting nozzle dot matrix distributed with a plurality of cutting nozzles (6), a spacing adjusting mechanism for adjusting the spacing of the cutting nozzles (6), an up-down adjusting mechanism for adjusting the whole up-down movement of the cutting nozzle dot matrix and a path adjusting mechanism for adjusting the cutting path of the cutting nozzle dot matrix;

the spacing adjusting mechanism comprises a plurality of transverse spacing adjusting units, each transverse spacing adjusting unit comprises a connecting rod telescoping mechanism and two first guide rails (3), each connecting rod telescoping mechanism comprises a plurality of first connecting rods (4) and second connecting rods (5) which are sequentially connected through a rotating shaft, the lengths of the first connecting rods (4) and the second connecting rods (5) are the same, a connecting groove (61) is formed in the upper part of the cutting nozzle (6), and the two free ends of each connecting rod telescoping mechanism and the hinged ends of the first connecting rods (4) and the second connecting rods (5) on the same side are hinged with the connecting groove (61) of the cutting nozzle (6); the distance adjusting mechanism further comprises two second guide rails (7), wherein second guide grooves (71) corresponding to the second guide rails (7) in opposite positions are formed in the second guide rails (7), and the distance adjusting mechanism further comprises a longitudinal distance adjusting assembly capable of adjusting the first guide rails (3) to vertically move back and forth in the second guide grooves (71);

the up-down adjusting mechanism further comprises a plane moving frame (9), the up-down adjusting mechanism comprises a ball screw (10), the ball screw (10) comprises a bearing assembly (101) and a screw rod (102), the bearing assembly (101) comprises a fixing piece (103) and a rotating piece (104) which are coaxial, the fixing piece (103) is fixed on the plane moving frame (9), the rotating piece (104) can rotate along a central shaft plane relative to the fixing piece (103), the screw rod (102) comprises a polished rod part (105) and a threaded rod part (106), the polished rod part (105) is fixedly connected with a cutting nozzle lattice, and the threaded rod part (106) is connected with the plane moving frame (9) and the rotating piece (104) through threads;

the path adjusting mechanism is connected with the plane moving frame (9) and can adjust the movement of the plane moving frame (9) on the horizontal plane, the path adjusting mechanism comprises a square fixed slide rail, two first slide rails (13) and two second slide rails (14), a first slide block (15) capable of moving on the first slide rails (13) and a second slide block (16) capable of moving on the second slide rails (14), a fixed block (17) is fixedly arranged on the plane moving frame, the path adjusting mechanism also comprises a third slide rail (18) parallel to the second slide rails (14), the third slide rail (18) penetrates through the fixed block (17) and is fixedly connected with the first slide block (15), the fixed block (17) can move on the third slide rail (18), a through hole parallel to the first slide rails (13) is formed in the plane moving frame, and a fourth slide rail (19) is further included, the fourth sliding rail (19) penetrates through the through hole and is fixedly connected with the second sliding block (16), and the plane moving frame can move on the fourth sliding rail (19) through the through hole;

step three: starting a cutting power supply, and simultaneously opening a hot oxygen flow, wherein the temperature of the hot oxygen flow is 60-80 ℃, and the cutting device (2) with a cutting nozzle (6) realizes cutting according to a preset cutting path;

step four: the positioning power supply and the cutting power supply are turned off, and simultaneously the hot oxygen flow is turned off, and the cut product leaves the product placing area (1).

2. The cutting method of pearl wool board using hot oxygen stream as claimed in claim 1, wherein: the diameter of the cutting nozzle (6) is 5 mm.

3. The cutting method of pearl wool board using hot oxygen stream as claimed in claim 1, wherein: the switch of the cutting power supply and the switch for controlling the on-off of the hot oxygen flow are the same.

4. The cutting method of pearl wool board using hot oxygen stream as claimed in any one of claims 1 to 3, wherein: the product placement area (1) further comprises a conveyor belt (12), through which conveyor belt (12) the cut products leave the product placement area (1).

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