RU58709U1 - DEVICE FOR DETERMINING Friction Coefficient of Friction - Google Patents

Abstract

The utility model is aimed at expanding the functionality of the device by selecting the composition of the liquid bath, which eliminates sticking pipe columns. The specified technical result is achieved in that the device for determining the coefficient of friction of the filter cake, containing the supporting surface with a hinge mounted to rotate around its axis by one side of the platform attached to it, a bed for the filter cake and means for measuring the angle with a graduated scale, has an open the vessel, the bottom of which is made in the form of a supporting surface, the bed is made in the form of a recess on the part of the platform located inside the vessel, on the counter-floor located outside the vessel The groove side of the platform has a groove with a roller placed inside it, made with the possibility of movement along its cylindrical surface of the thread with a load attached to one of its ends, allowing movement of a sample of material attached to the other end of the thread on the surface of the filter cake; on the graduated scale fixed to the side wall of the vessel, the means for measuring the angle are made at equal angular distances from each other, holes designed to fasten the platform on a graduated scale using a pin passing through a through hole made in the platform body into one of the holes of the graduated scale. 1 nz P. f-ly, 1 ill.

Description

The utility model relates to devices for determining the coefficient of friction of the filter cake and may find application in the oil and gas industry.

The closest in technical essence to the proposed utility model is a device for determining the coefficient of friction of the filter cake, containing a supporting surface with a hinge mounted to rotate around its axis by one side of the platform attached to it, a bed for the filter cake and means for measuring the angle with a graduated scale (see USSR Author's Certificate No. 794438, class G 01 N 19/02, 1981).

The disadvantages of the known device are its low functionality, since it does not allow you to choose the composition of the liquid bath, which eliminates the sticking of the pipe columns.

The technical result, which is aimed at the proposed utility model, is to expand the functionality of the device by selecting the composition of the liquid bath, which eliminates the sticking of the pipe columns.

The specified technical result is achieved due to the fact that the device for determining the coefficient of friction of the filter cake, containing a supporting surface with a hinge mounted to rotate around its axis by one side of the platform attached to it, a bed for the filter cake and means for measuring the angle with a graduated scale, has an open vessel, the bottom of which is made in the form of a supporting surface, the bed is made in the form of a recess on the part of the platform located inside the vessel, on the outside of the vessel on the opposite side of the platform there is a groove with a roller placed inside it, made to move along its cylindrical surface of the thread with a load attached to one of its ends, providing movement of a sample of material attached to the other end of the thread on the surface of the filter cake; on a graduated scale fixed to the side wall of the vessel, the means for measuring the angle are made at equal angular distances to each other

other holes intended for mounting the platform on a graduated scale using a pin passing through a through hole made in the platform body into one of the holes of the graduated scale.

The proposed device is designed to select the composition of the liquid bath in order to eliminate sticking of the pipe columns (the model corresponds to the type of sticking when pipe peeling is determined by their friction coefficient on the filter cake and the zenith angle of the inclined wellbore).

The essence of this utility model is illustrated by the figure, which shows a structural diagram of a device for determining the coefficient of friction of the filter cake.

The positions in the figure indicate the sample 1 of the material, the filter cake 2, the bed 3 for the filter cake 2, made in the platform 4, an open vessel 5 into which the test composition of the liquid bath 6 is poured. Also shown in the figure are pin 7, load 8, thread 9, the guide roller 10, the means 11 for measuring the angle with a graduated scale 12. The figure shows the holes 13 made in the graduated scale 12, and the hinge 14. The bottom of the open vessel 5 is the supporting surface 15. The platform 4 is attached on one side to that mounted on the supporting surface 15 of the hinge 14 and rotates around its axis. The bed 3 is made in the form of a recess on the part of the platform 4 located inside the vessel 5. On the opposite side of the platform 4 outside the vessel 5 there is a groove (not shown in the figure) with a guide roller 10 placed inside it with a thread 9 passing along its cylindrical surface, to one the end of which is attached a load 8, made with the possibility of changing its weight. The other end of the thread 9 is attached to the sample 1 of the material. As a sample 1 of the material, a metal plate made of material of pipe columns is used. In the operating position of the device, the load 8 hangs vertically and during operation of the device provides movement along the surface of the filter cake 2 of sample 1 of the material. The means 11 for measuring the angle fixed on the side wall of the open vessel 5 is configured to establish an anti-aircraft angle. In the case of this device, the zenith angle is formed by the plane of the platform 4 and the plane perpendicular to the bottom (supporting surface 15) of the open vessel 5. On a graduated scale 12 at equal angular distances from each other are made

holes 13 for fixing the platform 4 on the graduated scale 12 using a pin 7 passing through a through hole (not shown in the figure) made in the body of the platform 4 into one of the holes 13 on the graduated scale 12.

The principle of operation of this device for determining the coefficient of friction of the filter cake 2 located in the liquid bath 6 is as follows. The filter cake 2 is applied to the surface of the bed 3, made in the form of a recess in the platform 4, and fills its entire volume. A sample of material 1 is placed on top of the filter cake 2. As a sample 1 of the material, as a rule, a metal plate is used, to which the thread 9 is attached at one end. Next, the platform 4 with the help of a pin 7 passing through a through hole made in the body of the platform 4 into one of the holes 13 on a graduated scale 12 is installed at a given zenith angle α and is fixed by fastening elements (not shown in the figure) in this position. At the other end of the thread 9, thrown through the guide roller 10, a vertically hanging load 8 (representing a cup with weights located on it) is suspended. After that, the metal plate (material sample 1) on the filter cake 2 is left alone for a predetermined period of time t ₁ . Next, the vessel 5 is completely filled with the test composition of the liquid bath 6 and left alone for physico-chemical effects on the filter cake 2 for a second predetermined period of time t ₂ . Gradually changing the mass of the load 8 (loading the cup with weights), determine the force required for moving the metal plate. The smaller the straining force, the more effective the composition of the liquid bath is to eliminate sticking pipe columns. The effectiveness of the effects of the liquid bath on the filter cake was evaluated using the coefficient of friction. As you know, the friction force is determined by two groups of factors - both dependent on the normal load and independent of it. Using various calculation models, we can obtain the dependence of the friction force on the load, roughness, mechanical properties, etc.

Amonton's law was adopted as the initial dependence for calculating the coefficient of friction of the sample 1 of the material on the filter cake 2 (see Kheifets IB, On the coefficient of friction of the rubber element of the packer on the walls of wells, NTS, series

“Drilling”, No. 10, 1971, pp. 26-28), according to which the coefficient of friction μ is the ratio of the friction force F to reaction N, which occurs when a load is applied, pressing one body to another and directed normal to the contact surface:

In the case of the proposed device, the coefficient of friction of the sample 1 of the material on the filter cake 2 is determined from the following expression:

where μ is the coefficient of friction of sample 1 of the material on the filter cake 2;

Q - straining force, N;

G is the weight of sample 1 material, N;

α - zenith angle, deg.

The use of this device will be examined using examples of its use, where a metal plate weighing 0.1678 N was taken as a sample of material 1. A filter cake made of bentonite clay powder was used as a filter cake 2. As liquid baths to eliminate the sticking of pipe columns, for example, tap water and a 5% aqueous solution of sodium bisulfate (NaHSO ₄ ) were used.

Example 1. Determination of the coefficient of friction of a metal plate on a clay peel in a water bath.

Clay peel was prepared from bentonite clay powder as follows. The desiccator was filled with tap water in an amount of 1250 g. With constant stirring of water for 20 minutes, 400 g of bentonite clay powder was gradually added and the mixture was kept for three days under normal conditions. The prepared clay paste having a density ρ = 1285 kg / m ^{3 was} manually applied flush with a spatula in the form of a clay cake (filter cake 2) on a bed 3 of a platform 4. A metal plate was placed on top of the clay cake (sample 1 of the material from which the pipe column) with a thread attached to it 9. Platform 4 was installed at a given zenith angle α equal to 65 ° and its position was fixed using pin 7. After that, the assembled structure was left alone for a given period of time t ₁ = 5 minutes. After expiration

a predetermined period of time t ₁ vessel 5 was filled with water and left alone for the physico-chemical effect of the water bath on the clay crust for another predetermined period of time t ₂ = 10 minutes. At the other end of the thread 9, thrown through the guide roller 10, hung a cup, which is a vertically hanging load 8. After a predetermined period of time t ₂ , gradually loading the cup with weights, we determined the force required to break the metal plate. In this case, the force required for stragging the plate at a zenith angle of 65 ° was Q = 0.1255 N. The coefficient of friction of the metal plate on the clay crust according to formula (2) was:

Example 2. Determination of the coefficient of friction of a metal plate on a clay peel in a liquid bath based on a 5% aqueous solution of NaHSO ₄ .

Previously prepared clay paste (see example 1), having a density ρ = 1285 kg / m ³ , was manually applied flush with a spatula in the form of a clay crust on a bed of 3 platforms 4. A metal plate with a thread attached to it was placed on top of a clay crust 9 Platform 4 was installed at a given zenith angle α equal to 65 ° and fixed its position using pin 7. After that, the assembled structure was left alone for a given period of time t ₁ = 5 minutes. After a predetermined period of time t _{1, the} vessel 5 was filled with a 5% aqueous solution of sodium bisulfate and left alone for another predetermined period of time t ₂ = 10 minutes. At the other end of the thread 9, thrown through the guide roller 10, hung a cup, which is a vertically hanging load 8. After a predetermined period of time t ₂ , gradually loading the cup with weights, we determined the force required to break the metal plate. In this case, the force required for stragging the plate at an anti-aircraft angle of 65 ° was Q = 0.106 N. The coefficient of friction of the metal plate on the clay crust according to formula (2) had the value

As can be seen from the above examples, a liquid bath based on a 5% aqueous solution of sodium bisulfate has a more significant physico-chemical effect on the clay crust compared to water.

The proposed device for determining the coefficient of friction will expand the functionality of the device by selecting the composition of the liquid bath, which eliminates sticking pipe columns.

The use of this device will significantly accelerate and reduce the cost of creating new formulations of liquid baths to eliminate sticking pipe columns during well construction.

Claims (1)

A device for determining the coefficient of friction of the filter cake, comprising a supporting surface with a hinge mounted for rotation about its axis by one side of the platform, a bed for the filter cake and means for measuring an angle with a graduated scale, characterized in that it has an open vessel, the bottom of which is made in the form of a supporting surface, on the opposite side of the platform located outside the vessel, a groove with a roller placed inside it phenomena along its lateral surface of the thread with a load attached to one of its ends; the bed is made in the form of a recess on the part of the platform located inside the vessel, the angle measuring means fixed on the side wall of the vessel is configured to establish an zenith angle formed by the plane of the platform and the plane perpendicular to the bottom of the vessel, and on a graduated scale at equal angular distances relative to each other holes designed to fix the position of the platform relative to the bottom of the vessel using a pin passing through a through hole made in the body of the plate molds in one of the holes of the graduated scale.