RU2743288C1 - Circulation valve - Google Patents

Abstract

FIELD: oil and gas industry.SUBSTANCE: invention relates to a device for drilling oil and gas wells, namely, circulation valves. The device contains a housing, two circulation ports with seals fixed in the housing, a spring that presses the piston, activation and deactivation balls, a sub with a device for catching balls, a sleeve fixed inside the housing by circulation ports, a piston with radial holes and a central channel. Inside the piston there is a seat having an internal sealing diameter for a tight fit of the activation ball, which is less than the diameter of the activation ball by 0.01...1%. Downstream of the drilling fluid relative to the sealing diameter, the seat has internal protrusions to hold the activation ball, the total area of the internal protrusions of the seat in the cross section is 1...15% of the cross-sectional area of the activation ball, the activation ball has a hardness of 95 Shore A to 90 Shore D. The seals of the circulation ports on the piston side are hard-mounted in the inner grooves of the sleeve on both sides relative to the circulation ports. The piston support and centering rings are installed in the inner grooves of the sleeve. The sleeve is made of corrosion-resistant material.EFFECT: invention extends the service life and improves operation reliability, improves wellbore cleaning, provides ability to restore the drilling fluid parameters and to replace process fluids.2 cl, 4 dwg

Description

The invention relates to a device for drilling oil and gas wells, namely, circulation valves (or circulation subs) of a drill string, allowing multiple switching of the flow of a fluid - drilling mud from the inner space of the drill string to the annular space. The main purpose of the circulating valves is to deliver clogging materials to the site of lost circulation in the well, bypassing the elements of the bottom of the drill string assembly, through which it is prohibited to pump the bridging agents, without lifting and disassembling the drill pipe string. Circulating valves (sub) have an inactivated state when the side circulation ports are closed and the drilling fluid flows in full through the central channel of the device to the elements of the bottom of the drill string, and an activated state when the central channel is closed, the side circulation ports are open and the drilling fluid is fully open passes through the circulation ports into the annulus.

Known circulation valve of the drill string according to US patent No. 7347288 (publ. 01.06.2006), containing a housing with circulation ports, a piston with radial holes and a central channel with the ability to move along the axis of the housing, a saddle located in the central channel of the piston, a spring that presses the piston , a ball trap for catching balls downstream of the drilling fluid flow, the valve includes dumped activation balls and deactivation balls, on the lower side and on the upper side relative to the circulation ports in the body there are two internal grooves in which four seals are installed, the activation ball is made deformable ...

The circulation valve is activated by dropping an activation ball into the drill string, which moves and self-aligns into the piston seat by the flow of flushing fluid, closing the central channel, the piston moves downstream under fluid pressure and opens the circulation ports.

The circulation ports of the activated circulation valve are closed by a spring when the circulation is stopped, for example, when the pumped fluid is changed, preventing backflow of the drilling fluid from the annular space into the drill string.

The circulation valve is deactivated by dropping two metal deactivation balls into the drill string, which move to the ports and close them by the flow of drilling fluid, the pressure inside the drill string rises, the activation ball is deformed under fluid pressure and is pushed through the piston seat into the ball catcher, the deactivation balls also move into ball trap. The piston is spring loaded to its original position, closing the ports. The ball trap is designed to accommodate a certain number of balls.

The disadvantage of this circulation valve is that the activation ball is deformable and the deactivation of the circulation valve is based on the mechanism for pushing the activation ball through the seat. The main types of deformable materials used in this type of technology are rubber and plastic with a hardness of 70 Shore A to 100 Shore. Experts from LLC Gidrobur-service have experimentally determined that the use of deformable activation balls provides a deactivation pressure (pressure for pushing the activation ball through the saddle) in the range from 50 to 150 atm. At this deactivation pressure range, spontaneous deactivation (pushing the activation ball through the seat) of the previously activated circulation valve very often occurs during pumping of a viscous clogging material, because pushing pressure of viscous material can reach values up to 320 atm. at the mouth. The main risk of spontaneous deactivation of the circulation valve is to slurry the elements of the bottom of the drill string (telemetry system, engine, bit) with clogging material, after which the drilling process will be impossible. The use of deformable activation balls does not ensure the reliability of the process of delivering the clogging viscous material to the zones of absorption of the drilling fluid into the annulus, i.e. does not provide reliable target operation of the device.

Another disadvantage of this circulation valve is that the inner grooves for sealing the circulation ports are formed in the body. The circulating valve body is made of high-strength chromium-molybdenum steel (40XH2MA, 38XH3MFA, 40XH, 40XGMA, AISI 4330, AISI 4140, etc.) used for elements of the drill string, which is prone to corrosion. Corrosion of the metal in the grooves of the body breaks the tightness of the seal in contact with the elastic seal during operation for 300 ... 400 hours with a resource for this type of equipment more than 2000 hours of operation. In addition, the grooves on both sides of the body ports are located at a distance of 300 to 800 mm from the end face of the part, which technologically complicates their high-quality manufacturing in accordance with the requirements for the accuracy of the diametral dimensions, the beating of the grooves relative to the sliding surface of the part to be sealed and the roughness of the sealed surface in the grooves applied to the elements of seals in general mechanical engineering. Taking into account the above, corrosion and low quality of manufacturing of the internal grooves of the body leads to a breach of the tightness of the ports of the body with a relatively short operating time for the circulation valve, reducing its resource and reliability during operation. Depressurization of the circulation valve ports makes further drilling impossible.

Another disadvantage of this circulation valve is that four elastic seals are installed in the internal grooves of the body to seal the circulation ports - two seals on each side of the ports when only one is sufficient. Each of the elastic seals creates a resistance to piston movement equal to 20 ... 25 kgf, and, accordingly, a total of four seals create a resistance of 80 ... 100 kgf. Considering that at the end of its stroke the spring has a force of 140 kgf (for small sizes of circulation valves), four seals create resistance up to 72% of the spring force. The residual spring force is not enough to reliably deactivate the circulation valve (when the circulation ports are closed) when the piston resists the hydrodynamic force acting on it when the piston moves up against the flow of drilling fluid. Thus, the increased number of elastic seals reduces the likelihood of a successful deactivation operation and a reliable tight seal of the circulation valve ports. Depressurization of the circulation valve ports makes further drilling impossible.

Closest to the claimed invention is a drill string circulation valve according to RU patent No. 2681774 (publ. 02.26.2018), containing a housing with circulation ports, a sleeve fixedly installed in the body, a piston with radial holes and a central channel with the ability to move along the sleeve axis, a spring that presses the piston, the liner has external stationary seals to ensure the tightness of the ports, the piston has external movable seals to ensure the tightness of the ports, a device for catching balls downstream of the drilling fluid, installed in a sub attached below the body, the circulation valve includes resettable activation balls and deactivation balls. The activation ball is designed to deform and pass through the piston seat. This circulating valve is selected as a prototype.

The activation and deactivation of the circulation valve is carried out in the same way as described above.

The disadvantage of this circulation valve is that the activation ball is deformable and the deactivation of the circulation valve is based on the mechanism for pushing the activation ball through the seat. As described above, the use of deformable activation balls does not ensure the reliability of the process of delivering the clogging viscous material to the zones of absorption of the drilling fluid into the annular space due to the high probability of spontaneous deactivation (pushing the activation ball through the seat) of the circulation valve, i.e. does not provide reliable target operation of the device.

Another disadvantage of this circulation valve is that external movable seals are made on the piston, which in the non-activated state of the circulation valve are located on both sides of the circulation ports and seal the ports, in the activated state both seals move downward relative to the ports. In the activated state, a clogging material is pumped through the ports of the circulation valve, which in most cases contains nut shells, chalk and wood chips, which is pressed under high pressure into the gap between the sleeve and the piston open above the upper piston seal and then, during the deactivation operation, creates due to increased friction resistance to the upward movement of the piston. The force of the spring is insufficient for the piston to hermetically seal the circulation ports. And also the upper seal of the piston, when the piston moves upward, must clear the annular space between the piston and the liner from the pressed-in bridging material, while solid particles of the bridging agent are very likely to damage the movable upper seal of the piston, which leads to the loss of tightness of the circulation valve. Thus, the external movable piston seals do not provide reliable target operation of the device.

The proposed invention solves the problem of increasing well drilling performance while increasing the reliability of the device.

The technical result of the invention is to increase the resource and reliability of the operation of the circulation valve when drilling wells due to the use of the activation ball cutting mechanism and the seals of the circulation ports along the piston, which makes it possible to pump all types of clogging and insulating materials into the absorption zones of the drilling fluid; improve wellbore cleaning by increasing the flow rate of drilling fluid (in particular, when drilling horizontal wells and wells with extended reach); restore the parameters of drilling fluids; as well as replacement of process fluids during well development / completion and workover.

To achieve the specified technical result, the circulation valve of the drill string contains a body, two circulation ports with flow holes fixed in the body, a sleeve rigidly fixed inside the body by circulation ports, a piston with radial holes and a central channel, inside which a saddle is located, seals for circulation ports, a spring, a pressure piston, activation and deactivation balls, a sub with a device for catching balls, while the seat has an inner sealing diameter for a tight fit of the activation ball, which is 0.01 ... 1% less than the diameter of the activation ball, downstream of the drilling fluid flow relative to the sealing diameter, the saddle has internal protrusions for holding the activation ball, the total area of the internal protrusions of the saddle in the cross-section is 1 ... 15% of the cross-sectional area of the activation ball, the activation ball has a hardness of 95 ShoreA to 90 ShoreD, the sleeve is made of n Stainless material, the seals of the circulation ports on the piston side are fixedly installed in the inner grooves of the liner on both sides of the ports, the support-centering rings of the piston are installed in the inner grooves of the liner.

Distinctive features of the proposed circulation valve of the drill string from the above known, the closest to it, is that the seat has an inner sealing diameter for a tight fit of the activation ball, which is less than the diameter of the activation ball by 0.01 ... 1%, downstream of the drilling mud relative to the sealing diameter, the seat has internal projections to hold the activation ball, the total area of the internal projections of the seat in the cross section is 1 ... 15% of the cross-sectional area of the activation ball, the activation ball has a hardness of 95 Shore A to 90 Shore D, the sleeve is made of stainless material , the seals of the circulation ports on the side of the piston are fixedly installed in the inner grooves of the liner on both sides of the ports, the support-centering rings of the piston are installed in the inner grooves of the liner.

Due to the presence of these features, the proposed design increases the resource and reliability of the circulation valve when using drilling fluids, including abrasive and clogging materials, increases the technical and economic indicators of drilling and prevents complications and accidents during drilling due to the reliable retention of the activation ball in the seat in the activated state during pumping bridging material through the device, reliable and tight closing of the circulation ports during deactivation, ensuring the tightness of the circulation ports.

The accompanying figures illustrate the essence of the invention.

FIG. 1 shows the arrangement of the circulation valve;

FIG. 2 shows the valve assembly of the circulation valve.

FIG. 3 shows a cross-section of the circulation valve seat.

FIG. 4 shows the principle of the circulation valve.

The circulation valve (figure 1) contains a housing 1 with two circulation ports 2, inside which a sleeve 3 is installed, an axially movable piston 4 with radial holes 5 and a central channel 6, a seat 7 installed in the central channel of the piston 4, a spring 8, pressing the piston 4 up, seals 9 of circulation ports on the piston side in the inner grooves 10 of the sleeve and the support-centering rings 11 of the piston in the inner grooves 12 of the sleeve, a sub with a device for catching balls 13 (Fig. 13). The delivery set with a circulation valve includes 14 activation balls and 15 deactivation balls.

The seat 7 is made of steel 95X18 with high hardness, due to which it is less susceptible to hydroabrasive wear, mechanical wear and corrosion when passing through the circulation valve of the drilling mud with a mass content of abrasive (sand) up to 3%.

The activation ball 14 is made with a hardness of 95 Shore A to 90 Shore D and when it is installed in the seat 7 on the sealing diameter D, the diameter of which is 0.01 ... 1% less than the diameter of the activation ball, the tightness of the overlap of the central channel 6 in the piston is ensured for intended use circulation valve.

Stable device deactivation pressure 150… 200 atm. provided by a mechanism for cutting off the activation ball with a hardness of 95 ShoreA to 90 ShoreD by the internal projections of the seat 7 (see Fig. 3), the total area of which in the cross section is 1 ... 15% of the cross-sectional area of the activation ball. The main characteristics of the geometry of the internal projections of the seat 7 are their width s and inner diameter d (figure 2).

The seals 9 of the circulation ports on the piston side (Fig. 3) are fixedly installed in the inner grooves 10 of the liner 3 on both sides relative to the circulation ports 2, due to which, during the deactivation of the circulation valve when the piston 4 moves up, the seals 9 do not clean the annular gap between the piston 4 and sleeve 3 from the bridging material, without additionally sealing it in the gap, without reducing the efficiency of the spring 8 and without creating resistance to the movement of the piston 4 upward for reliable tight closing of the circulation ports.

Also, support-centering rings 11 of the piston are installed in the inner grooves 12 of the liner 3, centering the piston 4 relative to the seals 9 and relative to the liner 3 to ensure an equal annular gap around the entire circumference between the piston 4 and the liner 3 in any position of the piston 4 (activated and unactivated). This ensures reliable operation of the seals 9 in an abrasive environment and when the bridging material enters the gap between the sleeve 3 and the piston 4, and also excludes the skewing and jamming of the piston 4 when the circulation valve is deactivated during its movement upward in the inner diameter of the sleeve 3 not cleaned from the bridging material.

The circulating valve is installed in the bottom hole assembly (hereinafter BHA) above the telemetry system and is designed to switch the flow of flushing fluid from the inner space of the drill string to the annular one at its installation site through the circulation ports of the casing. The circulating valve has two modes of operation: activated and non-activated (figure 4).

In the non-activated mode of operation, the circulation ports of the casing are closed, and the entire volume of pumped drilling fluid passes through the circulation valve from the mud pumps to the bit.

In the activated state, the circulation ports of the casing are open, communicating the annular space with the drill string, the central hole is closed, the drill string is disconnected from the BHA elements located below the sub, the entire volume of pumped drilling fluid passes through the circulation ports of the casing into the annular annular space.

Its activation allows you to solve the following tasks:

- injection of all types of clogging and insulating materials into the absorption zones of the drilling fluid;

- improvement of wellbore cleaning by increasing the flow rate of drilling fluid (in particular, when drilling horizontal wells and wells with extended reach);

- restoration of parameters of drilling fluids;

- replacement of process fluids during well development / completion and workover.

FIG. 4 shows the principle of the circulation valve.

When the circulating valve in the BHA is in an unactivated state, the entire volume of drilling fluid flows through the circulating valve. To activate the circulation valve, an activation ball 14 is thrown (Fig. 5, a). The activation ball is installed by the flow of drilling fluid into the seat 7 of the piston 4, closing the central hole 6 of the piston 4. Under the action of the pressure of the drilling fluid, the piston 4 moves downward, opening the circulation ports 2 for the passage of the drilling fluid into the annulus. The circulating valve is activated, the entire volume of the drilling fluid through the circulation ports goes from the drill string to the annulus (Fig. 5, b). To deactivate the circulation valve in order to resume the circulation of the drilling fluid inside the drill string, two metal deactivation balls 15 are thrown (Fig. 5, c). Two metal deactivation balls 15 are installed by the flow of drilling fluid into the circulation ports 2, completely blocking the flow (Fig. 5, d). The pressure of the drilling fluid increases, the activation ball 14 under the action of pressure is cut off by the projections of the seat 7 and passes through the seat 7 of the piston 4, opening the central hole 6 of the piston, and is captured in a sub with a device for catching balls 13 (Fig. 5, e). The piston 4, under the action of the spring 8, closes the ports 2 and pushes the metal deactivation balls 15 out of the ports (Fig. 5, e). The deactivation balls are also trapped in the sub with ball trap 13. The entire volume of the drilling fluid passes through the circulation valve. A circulation valve with a ball trap retains the balls that have passed through it.

Experts of LLC Gidrobur-service have experimentally selected the outer diameter of the activation ball and the inner sealing diameter of the seat for a tight fit of the ball into the seat on a test bench. It has been determined that if there is a gap between the sealing diameter of the seat and the activation ball when it is seated in the seat (i.e. the inner sealing diameter of the seat is larger than the diameter of the activation ball), then the tightness of the central channel of the circulation valve is not provided, and part of the liquid passes through the central hole of the piston ... It has been established that if the seat has an inner sealing diameter less than the diameter of the activation ball by 0.01 ... 1%, then the ball is sealed into the seat. An increase in the interference fit in the seat of the activation ball in the seat (the seat has an inner sealing diameter less than the diameter of the activation ball, more than 1%) is impractical from a design point of view, because does not give an additional positive effect, but on the contrary, it can lead to premature destruction of the ball.

Experts of LLC Gidrobur-service experimentally selected the outer diameter, the hardness of the activation ball and the total area of the inner ridges of the saddle in the cross-section to ensure shearing and passing the ball through the saddle at a drilling mud pressure of 150 ... 200 atm. The hardness of the material of the activation balls from 95 Shore A to 90 Shore D. was selected experimentally on a test bench. It has been experimentally established that in this range of hardness the requirement for the pushing pressure of the activation ball through the seat in the range of 150… 200 atm is provided. In the case of using activation balls with a lower hardness (up to 95 Shore A), the deactivation pressure was 50 ... 120 atm., Which does not correspond to the operational characteristics of the device. Activation balls with a hardness of more than 90 Shore D were not manufactured and, accordingly, were not tested on bench equipment as part of a circulation valve, because there are very few materials on the plastics market in this hardness range (90 ... 100 Shore D).

Experimentally at LLC Gidrobur-service on a test bench, it was found that for circulation valves of standard sizes 106 and 120 mm, a cut-off pressure of the activation ball of 150 ... 200 atm. Is provided, when the total area of the internal projections of the saddle in the cross section is 1 ... 5% of the area cross-section of the activation ball, and for a circulation valve with a standard size of 170 mm - when the total area of the inner projections of the seat in the cross-section is 6 ... 15% of the cross-sectional area of the activation ball. The specified range of overlapping area of two elements (ball and seat protrusions) allows setting (adjusting) the required deactivation pressure of the circulation sub at the factory: the minimum overlap corresponds to a deactivation pressure of 150 atm., The maximum overlap corresponds to a deactivation pressure of 200 atm.

In LLC Gidrobur-service, according to the results of pilot tests of circulation valves, the material of the seat and sleeve was selected, which meets the requirements for physical, mechanical and tribological properties, requirements for corrosion resistance. The selected material is corrosion-resistant steel 95X18.

Based on the results of pilot testing of circulation valves, LLC Gidrobur-service confirmed the effectiveness of using fixed seals of circulation ports on the piston side and support-centering rings of the piston in the inner grooves of the liner. All prototypes of circulation valves after operation in wells were installed on the bench equipment of Gidrobur-Service LLC and successfully passed tests to check their tightness and operability.

In the course of pilot testing of circulation valves in the presence of an engineer from Gidrobur-service LLC at the drilling site and technical support from the authors, it was revealed that with a drilling mud density of more than 1200 kg / m ³ and a limited flow of drilling mud for technological reasons, up to 12 liters / sec to the circulation valve of standard size 120 mm it is not possible to deliver the activation ball inside the drill string to activate the circulation valve. The materials of the used activation balls have a density of up to 1200 kg / m ³ and at a density lower than the density of the drilling fluid tend to float to the surface. For such conditions, when the probability of the activation ball floating up is high, the authors have developed a weighted activation ball, which at the time of writing the application for the invention is at the stage of bench tests.

The proposed design of the circulating valve increases the service life and reliability of the operation of the circulating valve when drilling wells due to the use of the mechanism for cutting the activation ball and seals of the circulating ports along the piston fixedly installed in a stainless sleeve, increases the technical and economic indicators of drilling and prevents complications and accidents of the drilling tool.

Claims (2)

1. A circulation valve containing a body, two circulation ports fixed in the body, a sleeve fixed inside the body by circulation ports, a piston with radial holes and a central channel, inside which a seat is located, seals of circulation ports, a spring that presses the piston, activation and deactivation balls , a sub with a device for catching balls, characterized in that the seat has an inner sealing diameter for a tight fit of the activation ball, which is 0.01 ... 1% less than the diameter of the activation ball, downstream of the drilling fluid flow relative to the sealing diameter, the seat has internal protrusions to hold the activation ball, the total area of the inner projections of the seat in the cross-section is 1 ... 15% of the cross-sectional area of the activation ball, the activation ball has a hardness of 95 Shore A to 90 Shore D, the seals of the circulation ports on the piston side are fixedly installed in the inner tubes on both sides of the liner with respect to the circulation ports, and support-centering rings of the piston are installed in the inner grooves of the liner, while the liner is made of corrosion-resistant material. 2. A circulation valve according to claim 1, characterized in that the activation ball is made composite with an outer shell made of material of hardness from 95 ShoreA to 90 ShoreD and with an inner element installed in the shell made of a material with a density greater than that of the shell.

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