CN107505158B - Glue cutting sampling device and glue cutting sampling process - Google Patents

Abstract

The invention discloses a rubber cutting sampling device and a rubber cutting sampling process, which are used for cutting a sample piece on a rubber sheet output by an open mill and are characterized by comprising an upper roller, a lower roller and a die cutter; the upper roller and the lower roller are parallel and correspond to each other, a gap is formed between the upper roller and the lower roller, a film passes through the gap between the upper roller and the lower roller, and the die cutter is fixed on the circumferential surface of the lower roller; the two ends of the lower roller are provided with moving cylinders which can drive the lower roller to move towards or back to the film; the film output by the open mill drives the upper roller and the lower roller to rotate, and the die cutter cuts the sample on the film along with the rotation of the lower roller. The invention has the advantages and beneficial effects that: the condition of manually cutting the sample wafer is avoided, the sample wafer cutting efficiency and flatness are improved, the fatigue strength of workers is reduced, and the waste of materials is avoided; meanwhile, the risk of scalding due to carelessness of workers in the cutting and sampling process is reduced, and the safety of sample cutting work is improved.

Description

Glue cutting sampling device and glue cutting sampling process

Technical Field

The invention relates to the field of machinery, in particular to a glue cutting and sampling device and a glue cutting and sampling process.

Background

Rubber is manufactured into rubber sheets by an open mill and is output, and the conventional rubber sheet production factory usually adopts a manual cutting method to cut sample sheets, namely: the film rolled by the open mill is directly cut and sampled by the manual of an operator, the film is cut and sampled once every two minutes on average, the film is cut and sampled 240 times on average per shift, and then the film is made into a standard sample by a slicer for inspection. Because the film has residual temperature of 80-90 ℃, the labor intensity of manually cutting the sample film is high and the working condition is bad; meanwhile, the volume of the manually-cut test piece with the actual required dosage of 4-11 cm ³ for one-time detection is about 64cm ³, so that the volume of the manually-cut test piece is far larger than the actual dosage for one-time detection, and a large amount of material waste is caused.

Disclosure of Invention

In order to solve the above problems, the present invention provides a glue cutting and sampling device and a glue cutting and sampling process. According to the technical scheme, the die cutter is fixed on the circumferential surface of the lower roller, then a film passes through the space between the upper roller and the lower roller, the lower roller moves towards the film by operating the moving cylinder, the upper roller and the lower roller are driven to rotate by the film output by the open mill, the die cutter fixed on the lower roller is matched with the upper roller, and a sample piece is cut on the film;

According to the technical scheme, through the operation of automatically cutting the sample by the lower roller, the condition of manually cutting the sample is avoided, the cutting efficiency and flatness of the sample are improved, the fatigue strength of workers is reduced, the size of the sample is ensured, and the waste of materials is avoided; because the temperature of the film output by the open mill is at least 80 ℃, the technical scheme greatly reduces the risk of scalding due to carelessness of workers in the cutting and sampling process, and improves the safety of sample cutting work.

The invention relates to a rubber cutting sampling device which is used for cutting sampling pieces on a rubber sheet output by an open mill, and comprises an upper roller, a lower roller and a die cutter; the upper roller and the lower roller are parallel and correspond to each other, a gap is formed between the upper roller and the lower roller, the film passes through the gap between the upper roller and the lower roller, and the die cutter is fixed on the circumferential surface of the lower roller;

The two ends of the lower roller are provided with moving cylinders which can drive the lower roller to move towards or back to the film; the film output by the open mill drives the upper roller and the lower roller to rotate, and the die cutter cuts sample pieces on the film along with the rotation of the lower roller.

In the scheme, the device also comprises a sampling mechanism, wherein the sampling mechanism comprises a top column, a cam, a rotating shaft and a first bearing, and the lower roller comprises a roller and a supporting shaft; the axes of the rotating shaft, the supporting shaft and the roller are positioned on the same straight line;

The support shaft is connected with one end of the roller, the rotating shaft is connected with the other end of the roller through the first bearing, and the cam is positioned in the roller; one end of the rotating shaft penetrates through the first bearing to be connected with the cam, the other end of the rotating shaft extends out of the roller, and the side face of the rotating shaft is connected with the first bearing; the jacking column is perpendicular to the axial direction of the roller, one end of the jacking column is in contact with the cam, and the other end of the jacking column can extend out of the outer side surface of the roller.

In the scheme, the roller comprises an outer cylinder body, an inner cylinder body positioned in the outer cylinder body, connecting bodies with two sides connected with the outer cylinder body and the inner cylinder body respectively, and through holes penetrating through the inner parts of the connecting bodies and communicating the outer side surface of the outer cylinder body and the inner part of the inner cylinder body;

One end of the jacking column is positioned in the inner cylinder and is in contact with the cam, and the other end of the jacking column is positioned in the through hole; the outer side surface of the first bearing is fixed on the inner side surface of the inner cylinder; the outer cylinder drives the connecting body and the jacking column to rotate around the inner cylinder, the jacking column moves towards one end of the cam along the outer contour of the cam, and when the jacking column moves to the protruding part of the cam, the jacking column protrudes out of the outer cylinder from the through hole; one end of the through hole facing the outer side surface of the outer cylinder body is positioned in a space surrounded by the die cutter.

In the above scheme, the moving cylinder is perpendicular to the supporting shaft and is used for outputting pushing force or pulling force perpendicular to the axis of the supporting shaft to the supporting shaft so as to enable the lower roller to move towards or back to the film;

the moving cylinder can also be connected with the rotating shaft and is used for outputting pushing force or pulling force perpendicular to the axis of the rotating shaft to the rotating shaft so as to enable the lower roller to move towards or back to the film.

In the above scheme, one end of the through hole facing the outer cylinder body is provided with an annular protrusion, the annular protrusion is connected to the outer side surface of the outer cylinder body, and the jacking column protrudes from the annular protrusion; the annular protrusion is located in a space surrounded by the die cutter.

In the scheme, the plurality of connecting bodies are equidistantly arranged around the circumference of the inner cylinder body; and arranging a plurality of jacking columns in parallel to form a jacking column group, wherein the jacking column groups are respectively positioned in the through holes in the connecting bodies.

In the above scheme, the number of the cams is matched with the number of the jacking columns in one jacking column group, and a plurality of the cams are in one-to-one correspondence with a plurality of jacking columns in the jacking column group.

In the scheme, the die cutter is fixed on the outer side surface of the outer cylinder; the die cutting tools are arranged in a plurality, and the die cutting tools are equidistantly arranged on the outer side surface of the outer cylinder along the circumferential direction of the outer cylinder.

The glue cutting and sampling process utilizing the glue cutting and sampling device is characterized by comprising the following steps of:

s1, mounting a required die cutter on the outer side surface of an outer cylinder body, and enabling a film output by an open mill to pass through a gap between an upper roller and a lower roller;

s2, operating a moving cylinder to enable the lower roller to move towards the film;

s3, the film output by the open mill drives the upper roller and the lower roller to rotate;

s4, the lower roller drives the die cutter to rotate, so that the die cutter rotates to a film;

s5, the die cutter cuts the film and obtains a sample, and the sample is adhered in a space surrounded by the die cutter;

S6, when the outer cylinder drives the ejector post and the die cutter to rotate to the protruding part of the cam, the protruding part of the cam ejects the ejector post out of the outer surface of the outer cylinder from the through hole, and at the moment, the ejector post ejects a sample piece positioned in the die cutter and is separated from the die cutter, so that the sample piece is obtained.

In the above-mentioned aspect, in the S1, at least one die cutter may be equidistantly arranged on an outer side surface of the outer cylinder in a circumferential direction of the outer cylinder;

the die cutter can be a rubber sample die cutter for a vulcanization test, a rubber sample die cutter for a Mooney test or a die cutter for a hardness test.

The invention has the advantages and beneficial effects that: according to the glue cutting sampling device and the glue cutting sampling process, through the operation of automatically cutting the sample by the lower roller, the condition of manually cutting the sample is avoided, the cutting efficiency and flatness of the sample are improved, the fatigue strength of workers is reduced, the size of the sample is ensured, and the waste of materials is avoided; because the temperature of the film output by the open mill is at least 80 ℃, the technical scheme greatly reduces the risk of scalding due to carelessness of workers in the cutting and sampling process, and improves the safety of sample cutting work.

Drawings

In order to more clearly illustrate the embodiments of the invention or the technical solutions of the prior art, the drawings which are used in the description of the embodiments or the prior art will be briefly described, it being obvious that the drawings in the description below are only some embodiments of the invention, and that other drawings can be obtained according to these drawings without inventive faculty for a person skilled in the art.

FIG. 1 is a schematic diagram of a device for sampling cut adhesive according to the present invention;

FIG. 2 is a schematic diagram of a lower roller structure of a cutting and sampling device according to the present invention;

FIG. 3 is a schematic side view of a lower roller of the adhesive cutting and sampling device;

FIG. 4 is a schematic view of the structure of the portion B-B in FIG. 3;

FIG. 5 is a schematic view of the structure of the portion C-C in FIG. 3;

FIG. 6 is a diagram showing the structure or position relationship between the device for cutting and sampling S1 and a film in the process of cutting and sampling according to the present invention;

FIG. 7 is a diagram showing the structure or position relationship between the cutting and sampling device and the film in S2 and S3 of the cutting and sampling process according to the present invention;

FIG. 8 is a diagram showing the structure or position relationship between the device and the film in S4 of the process of cutting and sampling according to the present invention;

FIG. 9 is a diagram showing the structure or position relationship between the device and the film and the sample in S5 of the process of cutting and sampling according to the present invention;

FIG. 10 is a diagram showing the structure or position relationship between the device and the film and the sample in S51 of the process of cutting and sampling according to the present invention;

FIG. 11 is a diagram showing the structure or position relationship between the device and the film and the sample in S6 of the invention.

In the figure: 1. upper roller 2, lower roller 3, die cutter 5, film

6. Sample sheet 7, sampling mechanism 21, roller 22, and support shaft

211. Outer cylinder 212, inner cylinder 213, connector 214, through hole

215. Annular projection 71, post 72, cam

73. Rotating shaft 74, first bearing 75, second bearing

Detailed Description

The following describes the embodiments of the present invention further with reference to the drawings and examples. The following examples are only for more clearly illustrating the technical aspects of the present invention, and are not intended to limit the scope of the present invention.

As shown in fig. 1 to 5, the invention is a cutting and sampling device for cutting a sample piece 6 on a film 5 output by an open mill, comprising an upper roller 1, a lower roller 2 and a die cutter 3; the upper roller 1 and the lower roller 2 are parallel and correspond to each other, a gap is formed between the upper roller 1 and the lower roller 2, a film 5 passes through the gap between the upper roller 1 and the lower roller 2, and a die cutter 3 is fixed on the circumferential surface of the lower roller 2;

The two ends of the lower roller 2 are provided with moving air cylinders (not shown in the figure), and the moving air cylinders (not shown in the figure) can drive the lower roller 2 to move towards or back to the film 5; the film 5 output by the open mill drives the upper roller 1 and the lower roller 2 to rotate, and the die cutter 3 cuts the sample piece 6 on the film 5 along with the rotation of the lower roller 2.

The working principle of the technical scheme is as follows: by fixing the die cutter 3 on the circumferential surface of the lower roller 2 and then passing the film 5 between the upper roller 1 and the lower roller 2, operating a moving cylinder (not shown in the figure) to move the lower roller 2 toward the film 5, the film 5 output from the mill will drive the upper roller 1 and the lower roller 2 to rotate, the die cutter 3 fixed on the lower roller 2 will cooperate with the upper roller 1 to cut the sample piece 6 on the film 5;

According to the technical scheme, through the operation of automatically cutting the sample wafer 6 by the lower roller 2, the condition of manually cutting the sample wafer 6 is avoided, the cutting efficiency and flatness of the sample wafer 6 are improved, and the fatigue strength of workers is reduced; the worker can arrange the die cutters on the lower roller with a certain fixed size, so that the size of the sample wafer 6 is ensured, and the waste of materials is avoided; because the temperature of the film 5 output by the open mill is at least 80 ℃, the technical scheme greatly reduces the risk of scalding due to carelessness of workers in the cutting and sampling process, and improves the working safety of the cutting sample 6.

Further, the device also comprises a sampling mechanism 7, wherein the sampling mechanism 7 comprises a top column 71, a cam 72, a rotating shaft 73 and a first bearing 74, and the lower roller 2 comprises a roller 21 and a supporting shaft; the rotation shaft 73, the support shaft 22 and the axis of the roller 21 are positioned on the same straight line;

The support shaft is connected with one end of the roller 21, the rotating shaft 73 is connected with the other end of the roller 21 through the first bearing 74, and the cam 72 is positioned in the roller 21; one end of a rotating shaft 73 passes through a first bearing 74 to be connected with the cam 72, the other end of the rotating shaft 73 extends out of the roller 21, and the side surface of the rotating shaft 73 is connected with the first bearing 74; the top post 71 is perpendicular to the axial direction of the drum 21, one end of the top post 71 is in contact with the cam 72, and the other end of the top post 71 may protrude from the outer side surface of the drum 21.

Specifically, the roller 21 includes an outer cylinder 211, an inner cylinder 212 located inside the outer cylinder 211, a connecting body 213 having both sides connected to the outer cylinder 211 and the inner cylinder 212, respectively, and a through hole 214 penetrating inside the connecting body 213 and communicating the outer surface of the outer cylinder 211 and the inside of the inner cylinder 212;

One end of the top post 71 is positioned inside the inner cylinder 212 and contacts the cam 72, and the other end of the top post 71 is positioned inside the through hole 214; the outer side surface of the first bearing 74 is fixed on the inner side surface of the inner cylinder 212; 211 the outer cylinder body drives the connecting body 213 and the prop 71 to rotate around the inner cylinder body 212, the prop 71 moves along the outer contour of the cam 72 towards one end of the cam 72, and when the prop 71 moves to the protruding part of the cam 72, the prop 71 protrudes from the inside of the through hole 214 to the outside of the outer cylinder body 211; one end of the through hole 214 facing the outer side surface of the outer cylinder 211 is located in a space surrounded by the die cutter 3;

the sampling mechanism 7 further includes a second bearing 75, and the support shaft 22 is connected to the inner cylinder 212 of the roller 21 through the second bearing 75.

Further, a moving cylinder (not shown) is connected to the support shaft perpendicularly to the support shaft for outputting a pushing force or a pulling force perpendicular to the axis of the support shaft to the support shaft 22 to move the lower roll 2 toward or away from the film 5;

a moving cylinder (not shown) may also be coupled to the rotating shaft 73 for outputting a pushing or pulling force to the rotating shaft 73 perpendicular to the axis of the rotating shaft 73 to move the lower roll 2 toward or away from the film 5.

Preferably, the end of the through hole 214 facing the outer cylinder 211 has an annular protrusion connected to the outer side surface of the outer cylinder 211, and the post 71 protrudes from the annular protrusion 215; the annular projection is located in the space surrounded by the die cutter 3.

Preferably, several connectors 213 are equally spaced around the circumference of the inner cylinder 212; the plurality of posts 71 are arranged in parallel to each other to form a group of posts 71, and the plurality of posts 71 are respectively positioned in the through holes 214 in the plurality of connecting bodies 213.

Preferably, the number of cams 72 matches the number of posts 71 in one group of posts 71, and the number of cams 72 corresponds one-to-one with the number of posts 71 in the group of posts 71.

Preferably, the die cutter 3 is fixed on the outer side surface of the outer cylinder 211; the die cutters 3 are arranged on the outer side surface of the outer cylinder 211 at equal intervals along the circumferential direction of the outer cylinder 211; by utilizing a plurality of die cutters 3, a plurality of sample wafers 6 can be cut on the film 5 at the same time, so that the working efficiency of the sample wafer 6 cutting work is improved.

As shown in fig. 6-11, a glue cutting and sampling process, using the glue cutting and sampling device, includes the following steps:

S1, mounting a required die cutter 3 on the outer side surface of an outer cylinder 211, and enabling a film 5 output by an open mill to pass through a gap between an upper roller 1 and a lower roller 2;

S2, operating a moving cylinder (not shown in the figure) to move the lower roller 2 towards the film 5;

s3, a film 5 output by the open mill drives the upper roller 1 and the lower roller 2 to rotate;

s4, the lower roller 2 drives the die cutter 3 to rotate, so that the die cutter 3 rotates to the film 5;

S5, the die cutter 3 cuts the film 5 and obtains a sample 6, and the sample 6 is adhered in a space surrounded by the die cutter 3;

S6, when the outer cylinder 211 drives the ejector post 71 and the die cutter 3 to rotate to the protruding part of the cam 72, the protruding part of the cam 72 ejects the ejector post 71 out of the outer side surface of the outer cylinder 211 from the through hole 214, and at the moment, the ejector post 71 ejects and separates the sample 6 in the die cutter 3 from the die cutter 3 to obtain the sample 6; the operation of obtaining the sample wafer 6 is facilitated for the worker, and the condition that the worker is scalded in the process of obtaining the sample wafer 6 is avoided.

Preferably, in S1, at least one die cutter 3 may be equidistantly arranged on the outer side surface of the outer cylinder 211 in the circumferential direction of the outer cylinder 211;

the die cutter 3 may be a rubber sample die cutter for vulcanization test, a rubber sample die cutter for mooney test or a die cutter for hardness test.

Preferably, S5 further comprises the steps of:

S51, the film 5 continuously drives the upper roller 1 and the lower roller 2 to rotate, and drives the die cutter 3 and the sample 6 adhered in the space surrounded by the die cutter 3 to rotate, so that the die cutter 3 and the sample 6 are separated from the film 5.

Specifically, when the worker does not need to collect the sample 6, the moving cylinder is operated to move the lower roller 2 away from the film 5, so that the lower roller 2 is separated from the film 5.

The foregoing description of the preferred embodiments of the invention is not intended to be limiting, but rather is intended to cover all modifications, equivalents, alternatives, and improvements that fall within the spirit and scope of the invention.

Claims (4)

1. The utility model provides a cut gluey sampling device for cut out sample piece on the film of mill output, its characterized in that includes upper roller, lower roller and mould cutter; the upper roller and the lower roller are parallel and correspond to each other, a gap is formed between the upper roller and the lower roller, the film passes through the gap between the upper roller and the lower roller, and the die cutter is fixed on the circumferential surface of the lower roller;

The two ends of the lower roller are provided with moving cylinders which can drive the lower roller to move towards or back to the film; the film output by the open mill drives the upper roller and the lower roller to rotate, the die cutter cuts a sample on the film along with the rotation of the lower roller, and the open mill further comprises a sampling mechanism, wherein the sampling mechanism comprises a jacking column, a cam, a rotating shaft and a first bearing, and the lower roller comprises a roller and a supporting shaft; the axes of the rotating shaft, the supporting shaft and the roller are positioned on the same straight line;

The support shaft is connected with one end of the roller, the rotating shaft is connected with the other end of the roller through the first bearing, and the cam is positioned in the roller; one end of the rotating shaft penetrates through the first bearing to be connected with the cam, the other end of the rotating shaft extends out of the roller, and the side face of the rotating shaft is connected with the first bearing; the jacking column is perpendicular to the axial direction of the roller, one end of the jacking column is in contact with the cam, and the other end of the jacking column can extend out of the outer side surface of the roller;

The roller comprises an outer cylinder body, an inner cylinder body positioned in the outer cylinder body, connecting bodies with two sides connected with the outer cylinder body and the inner cylinder body respectively, and through holes penetrating through the inside of the connecting bodies and communicating the outer side surface of the outer cylinder body and the inside of the inner cylinder body;

One end of the jacking column is positioned in the inner cylinder and is in contact with the cam, and the other end of the jacking column is positioned in the through hole; the outer side surface of the first bearing is fixed on the inner side surface of the inner cylinder; the outer cylinder drives the connecting body and the jacking column to rotate around the inner cylinder, the jacking column moves towards one end of the cam along the outer contour of the cam, and when the jacking column moves to the protruding part of the cam, the jacking column protrudes out of the outer cylinder from the through hole; one end of the through hole facing the outer side surface of the outer cylinder body is positioned in a space surrounded by the die cutter;

the end of the through hole facing the outer cylinder body is provided with an annular protrusion, the annular protrusion is connected to the outer side surface of the outer cylinder body, and the jacking column protrudes from the annular protrusion; the annular protrusion is positioned in a space surrounded by the die cutter;

the plurality of connecting bodies are equidistantly arranged around the circumference of the inner cylinder body; arranging a plurality of jacking columns in parallel to form a jacking column group, wherein the jacking column groups are respectively positioned in through holes in the connecting bodies;

the number of the cams is matched with the number of the jacking columns in one jacking column group, a plurality of the cams are in one-to-one correspondence with a plurality of jacking columns in the jacking column group, and the die cutting rule is fixed on the outer side surface of the outer cylinder body; the die cutting tools are arranged in a plurality, and the die cutting tools are equidistantly arranged on the outer side surface of the outer cylinder along the circumferential direction of the outer cylinder.

2. The apparatus according to claim 1, wherein the moving cylinder is connected to the support shaft perpendicularly, and is configured to output a pushing force or a pulling force perpendicular to an axis of the support shaft to the support shaft, so that the lower roller moves toward or away from the film;

the moving cylinder can also be connected with the rotating shaft and is used for outputting pushing force or pulling force perpendicular to the axis of the rotating shaft to the rotating shaft so as to enable the lower roller to move towards or back to the film.

3. A glue cutting and sampling process, using a glue cutting and sampling device according to any one of claims 1-2, comprising the steps of:

s1, mounting a required die cutter on the outer side surface of an outer cylinder body, and enabling a film output by an open mill to pass through a gap between an upper roller and a lower roller;

s2, operating a moving cylinder to enable the lower roller to move towards the film;

s3, the film output by the open mill drives the upper roller and the lower roller to rotate;

s4, the lower roller drives the die cutter to rotate, so that the die cutter rotates to a film;

s5, the die cutter cuts the film and obtains a sample, and the sample is adhered in a space surrounded by the die cutter;

S6, when the outer cylinder drives the ejector post and the die cutter to rotate to the protruding part of the cam, the protruding part of the cam ejects the ejector post out of the outer surface of the outer cylinder from the through hole, and at the moment, the ejector post ejects a sample piece positioned in the die cutter and is separated from the die cutter, so that the sample piece is obtained.

4. A glue cutting and sampling process according to claim 3, wherein in said S1, at least one die cutter is equidistantly disposed on the outer side surface of said outer cylinder in the circumferential direction of said outer cylinder;

the die cutter can be a rubber sample die cutter for a vulcanization test, a rubber sample die cutter for a Mooney test or a die cutter for a hardness test.