RU2619043C1 - Adhesive meter (versions) - Google Patents

Abstract

FIELD: measuring equipment.

SUBSTANCE: in the first embodiment, the adhesive meter consists of a base with spikes and guides, with the possibility to move a carriage thereon, to which a vertical body is rigidly connected, comprising a scraper, and a force meter, in which a dynamometer is used as the force meter, mounted on the carriage and connected to the top of the vertical body with its rod, connected to the carriage with the axle hinge. In the second embodiment, the adhesive meter consists of a base with the guides, with the possibility to move a carriage thereon, to which a vertical body is rigidly connected, and a force meter, in which a dynamometer is used as the force meter, mounted on the carriage and connected to the top of the vertical body with its rod, connected to the carriage with the axle hinge, wherein a finger is mounted in this body, connected to the scene comprising a clamp, and a chassis is set on the basis.

EFFECT: improving the accuracy of determining the adhesion value by eliminating the impact of the friction forces between the carriage and its guides on the adhesive meter values.

2 cl, 4 dwg

Description

The invention relates to devices designed to determine and control the adhesion strength of coatings of various structures, in particular protective coatings of steel pipelines.

A known adhesive meter (RF Patent No. 2239817, G01N 19/04, 10.11.2004) containing a detachment mechanism, a grip made in the form of a glass connected to the detachment mechanism, and a measuring device.

A disadvantage of the known adhesive meter is its limited functionality, due to the fact that:

1) The detachment mechanism, made in the form of a cage with a conical inner surface, can be effectively applied only to flat coatings, and it will be impossible to carry out high-quality capture of the test coating sample, for example, on a cylindrical pipe surface, by the structural elements of this adhesive meter.

2) The test coatings must have sufficient rigidity or have a relatively large thickness so that the sample cannot slip into the hole of the cage. For this reason, it is impossible to control adhesion of coatings of elastic polymer tapes and coatings based on bituminous mastics with a known adhesive meter.

3) To prepare a coating sample for testing, it is necessary to clean a large area of the coating around it, which creates certain difficulties in restoring the integrity of the insulation coating of the product after testing.

A known adhesive meter (AR-2 according to GOST R 51164-98), devoid of the noted drawbacks and used to control the adhesion of coatings of elastic polymer tapes that protect trunk pipelines from corrosion. It consists of a housing on which a clip is fixed to hold a strip of peelable coating. A force meter with two successive springs is attached to the housing, which shows the peeling force.

A disadvantage of the known adhesive meter is the low measurement accuracy due to the fact that, firstly, the design of its force meter has parts rubbing against each other, and the resulting friction forces distort the readings, and secondly, when moving the adhesive meter over the surface of the product (pipe) it is impossible maintain a stable angle of application of force to the handle.

Known adhesive meter (RF Patent for utility model No. 80575, G01N 19/04, 02/20/2010), which eliminated some of the drawbacks of the previous analogue associated with the inconvenience of operation. In particular, the clamp of the coating strip is made in the form of an eccentric, and it is also possible to fix the maximum tear-off force of the strip of the test coating with a sleeve moving on the stem with marks applied on it corresponding to different values of adhesion of the protective coating.

However, the noted drawbacks of the previous analogue - the low measurement accuracy due to the presence of friction between the parts of the load meter and the inability to withstand the direction of the applied force when moving the adhesive meter - are inherent in this well-known technical solution.

It should be noted that all three of the considered known adhesion meters have a common drawback, which lies in their limited functionality. They can be used to control adhesion only by the separation method (Method A according to GOST R 51164-98 for controlling the adhesion of protective coatings from polymer tapes), but cannot be used to control adhesion by the shear method (Method B GOST R 51164-98 of controlling adhesion of protective coatings based on bitumen mastic).

The closest to the proposed device in terms of technical nature and the achieved result is an adhesive meter (SM-1 according to GOST R 51164-98) for controlling adhesion by shearing of protective coatings based on bitumen mastics. The adhesive meter contains a base with spikes and guides with the possibility of moving a carriage along it, with which a vertical housing is rigidly connected, inside of which there is a scraper for shifting the coating sample, a force meter consisting of a calibrated spring and a displacement indicator.

The disadvantage of the closest analogue is also its limited functionality, due to its use only for controlling adhesion by shear, as well as insufficient accuracy in determining adhesion by this method. The insufficient accuracy of the readings is explained by the presence of large friction forces between the carriage and its guides due to the fact that the force acting from the side of the shear coating on the scraper creates a moment that is transmitted through the vertical casing to the carriage and increases the interaction forces of the carriage with its guides. As a result, most of the spring's elastic force is spent on overcoming these friction forces, and the rest is spent on moving the scraper. Since the indicator readings are recalculated for the full spring force of the spring, and not for the force acting on the shear coating, the adhesion value of the test coating is not determined reliably.

The authors conducted laboratory studies of a large number of adhesives of the SM-1 brand, as a result of which it was found that, due to the influence of friction, errors in determining adhesion using these devices can be 50-70%.

The task of the invention is to expand the functionality of the adhesive.

The technical result is an increase in the accuracy of determining the amount of adhesion by eliminating the influence of the frictional forces between the carriage and its guides on the indications of the adhesive meter.

The task and technical result is achieved according to the first option in that in the adhesive meter, consisting of a base with spikes and guides, with the possibility of moving a carriage along it, with which a vertical housing containing a scraper is rigidly connected, and a load meter, in contrast to the prototype as a load meter a dynamometer is used mounted on the carriage and connected by its rod to the upper part of the vertical housing connected to the carriage by an axial joint.

The task and technical result is achieved according to the second option in that in the adhesive meter, consisting of a base with guides, with the possibility of moving along them a carriage with which the vertical body is rigidly connected, and a force meter, in contrast to the prototype, a dynamometer mounted on the carriage and connected by its rod to the upper part of the vertical housing connected to the carriage by an axial hinge, while a finger is connected to the housing connected to the link containing the clamp, and on the main Vania set chassis.

The essence of the device is illustrated by drawings, which depict:

In FIG. 1 is a front view of the adhesive meter according to the 1st embodiment;

In FIG. 2 shows a top view of the adhesive meter according to the 1st embodiment;

In FIG. 3 shows a left side view of the adhesive meter according to the 1st embodiment;

In FIG. 4 shows an adhesive meter according to the 2nd embodiment;

According to the first embodiment, the adhesive meter consists of a base 1 (Fig. 1), on which a stop 2 (Fig. 2) and two heels 3 are fixed, holding two cylindrical guides 4, which are capable of moving a carriage 5 along them, on the upper plane of which a dynamometer is installed 6. Screw 7 is designed to move the carriage along the guides. The carriage 5 is pivotally connected to the housing 8, which is a kind of rocker. The dynamometer rod 6 is pivotally attached to the upper arm of this rocker arm, and the scraper 9 located in the housing, the edge of which is brought to the test cover sample, is pivotally attached to the rocker arm. The screw 10 is designed to move the scraper 9 relative to the housing 8, which allows you to change the length of the lower arm of the beam depending on the thickness of the test coating. To set the required length of the lower shoulder, a scale is applied to the housing 8, one division of which is 2 mm If the head of the index screw 11 (Fig. 3) connected to the scraper 9 is opposite the central division of the scale (extended risk), then this means that the arms of the rocker are equal. In this case, when moving the carriage 5 with the screw 7, the readings of the dynamometer 6 will exactly correspond to the force acting on the lower edge of the scraper 9 from the side of the test coating, and the influence of the friction forces arising from the movement of the carriage 5 on the surfaces of its contact with the guides 4, on the readings dynamometer 6 is completely excluded, which is the main factor in increasing the accuracy of measuring the value of adhesion. Four studs 12 are screwed into the base 1 to install and hold the adhesive on the product (pipe) during testing. The casing 13 (Fig. 3) serves to protect the device from external mechanical influences.

In the second embodiment, the adhesive meter consists of a base 1 (Fig. 4) with guides 4 along which the carriage 5 can be moved with a dynamometer 6 mounted on it. The carriage 5 is pivotally connected to the vertical housing 8. The rod of the dynamometer 6 is also pivotally attached to the top of the vertical housing 8 A finger 14 is inserted into the housing 8, connected to the link 15, ending with a clamp 16, which serves to secure the notched strip of the tested protective coating. In this embodiment, the vertical casing 8 is also a beam, the lower shoulder of which is the finger 14. As a result, when the arms of the rocker arm are equal, the readings of the dynamometer 6 will be equal to the force acting on the finger 14 from the side of the wings 15, and which, in turn, will correspond exactly to the force peeling strips of the test protective coating. The strip of the tested protective coating can be peeled off by moving the adhesive meter over the surface of the product (pipe), for which it is equipped with a chassis 17 installed on the base 1. The influence of friction forces on the dynamometer readings is also excluded in the considered version, in addition, due to the rather long backstage 15, the angle of application of force to the finger 14 remains practically unchanged, which stabilizes the readings of the dynamometer 6. Thus, the accuracy of measuring the adhesion value is improved.

The device operates as follows.

When controlling the adhesion of protective coatings based on bitumen mastics (method B GOST R 51164-98), the adhesive meter according to the first embodiment is installed on the protective coating of the product so that the edge of the scraper 9 (Fig. 1) is strictly against the prepared sample of the test coating. Screw 10 scraper 9 rises. By pressing on the casing 13 of the adhesive meter, the maximum penetration of the spikes 12 (Fig. 3) into the protective coating is achieved. Then the scraper 9 with the help of the screw 10 is lowered to the base of this coating. By rotating the screw 7, the edge of the scraper 9 smoothly leads to the sample of the test coating, and at a constant speed it is shifted. At the same time, the readings of dynamometer 6 are recorded (Fig. 2).

When controlling the adhesion of protective coatings from polymer tapes (method A according to GOST R 51164-98), the adhesive meter according to the second embodiment is installed on a product (pipe) with a protective coating. In the clamp 16 (Fig. 4), the notched strip of the test coating is fixed (not shown in Fig. 4), and when the adhesive meter equipped with the chassis 17 is moved through the product (tube), the notched strip is peeled off with a measurement using a dynamometer 6 of a steady peeling force.

It should be noted that the adhesive meter according to the first embodiment is easily transformed into an adhesive meter according to the second embodiment by simple replacement of component parts, which makes it universal in application for controlling the adhesion of various protective materials.

Thus, the claimed invention, having all the full functionality, allows to increase the accuracy of determination and control of the adhesive strength of protective coatings.

Claims (2)

1. An adhesive meter consisting of a base with spikes and guides, with the possibility of moving a carriage along it, with which a vertical housing containing a scraper is rigidly connected, and a force meter, characterized in that a dynamometer mounted on the carriage and connected with its rod to the upper part of the vertical housing connected to the carriage by an axial hinge. 2. An adhesive meter consisting of a base with guides, with the possibility of moving a carriage along it, with which the vertical body is rigidly connected, and a force meter, characterized in that a dynamometer mounted on the carriage and connected by its rod to the upper part of the vertical case is used as a force meter, connected to the carriage by an axial hinge, while a finger is installed in the housing, connected to a link, containing a clip, and a chassis is installed on the base.

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