RU2681059C1 - Method of profiling the equal-performance clearance characteristics of the regulatory valve and the device for its implementation - Google Patents

Abstract

FIELD: machine building.SUBSTANCE: invention relates to mechanical engineering, in particular to regulating pipeline valves, which are designed to regulate the flow of flowing fluid, and can be used in the oil and gas industry. Method of profiling the equal-percentage throughput characteristic of the control valve includes obtaining a change in the total flow area formed by round, non-interconnected orifices of the same diameter in the wall of the separator when the plunger moves along its axis. Method is carried out using the control valve containing the control member installed in the housing with the possibility of moving the plunger along the longitudinal axis of the valve. Plunger interacts with the separator. In the walls of the separator along the longitudinal axis of the valve are located radial round openings of the same diameter, forming a total flow area. Perforation with openings of the separator is made unevenly with a decrease in the density of the openings as it approaches the outlet section of the separator and around the circumference of the separator in each section along its internal diameter. In this case, the edges of the orifices on the generator lines, which coincide with the beginning of the stroke of the plunger and correspond to the relative initial capacity of the valve, are located in one section.EFFECT: technical result consists in creating the control valve, in which due to the organization of the mutual arrangement of identical round openings, a predetermined deviation of the actual passage area of the separator from the theoretical dependence is ensured and an equal percentage transmission characteristic is realized.2 cl, 10 dwg, 1 tbl

Description

The invention relates to mechanical engineering, in particular to regulating pipeline valves, designed to regulate the flow of passing fluid, and can be used in the oil and gas industry.

In the oil and gas industry, control valves are widely used to control the flow, pressure and temperature of the fluid stream. According to the conditions of automation of technological processes in pipeline hydraulic systems, two main forms of throughput characteristics of control valves are most widely used - linear (LPH) and equal percentage (RPH). The practical implementation of this or that throughput characteristic is to change the area (profiling) of the regulated passage of the fluid flow in the regulatory body in accordance with the required throughput characteristic. At the same time, one of the problems arising in the development of control valves with a cellular regulatory body is the problem of realizing the equal percentage throughput characteristics of the control valve with minimal deviations from its theoretical dependence. Practice shows that profiling an adjustable passage in accordance with an equal percentage law is a rather laborious step in creating a regulatory body and this forces the manufacturer to use simplifying mathematical techniques, which, in the long run, often turn out to be ineffective.

A known method of implementing the throughput characteristics of the control valve, when its direct form is a structural characteristic, which is understood as the dependence of the change in the area of the passage in the stationary element of the regulatory body (separator) on the course of the movable element of the regulatory body (plunger). Some regulatory bodies, such as cell valves and slide gate valves, are characterized by almost constant flow rates. This, in turn, determines the identity of the nature of the change in the throughput and constructive characteristics of the regulatory body (Chernoshtan V.I., Blagov E.E. Features of profiling of regulatory bodies with the required throughput characteristic). A factor that aggravates the problem of ensuring an equal percentage characteristic is the impossibility of its full implementation, since two sections of the equal percentage and linear characteristics are used with a reduced value of throughput compared to the declared nominal value. The problem is solved by fitting to the required throughput with the help of a suitable curvilinear characteristic, naturally different from the required equal percentage. These characteristics are called modified. The absence of criteria for the permissible deviation of the curve from an equal percentage law raises the question of the legality of such a replacement.

Known control valve containing a regulatory body, consisting of a movable part in the form of a plunger and a fixed part in the form of a perforated glass (separator) with radial round holes made in it. In this design, the fluid flow through the valve is controlled by blocking the openings in the separator by a plunger moving inside it, which changes the total area of the openings. The maximum throughput of such a valve is determined by the dimensions of the valve and the separator. (Mokveld Valves BV Mokveld Valve Bv Catalog, Mocveld Valvs bv, PO Box 227 Mokveld Marketing, 2800 AE Gouda Holland, Nijverheidsstraat, pp. 3, 4, 8; Mokveld Website: https://mokveld.com/en / axial-control-valve Mokveld products)

However, due to the fact that the number and location of holes in each row of the separator remains constant, the area of the controlled passage in the valve when moving the plunger changes almost linearly (or close to a linear relationship). Moreover, with the indicated mutual arrangement of the holes in the separator, it is impossible to realize an equal percentage throughput characteristic for known designs that meets regulatory requirements using round holes of the same diameter.

Known control valve containing a housing, a regulatory body having a fixed and movable, made with the possibility of axial movement along the longitudinal axis of the valve, part, while the fixed part of the regulatory body is made in the form of a glass (separator) with radial holes located in it, interacting with the movable part of the regulatory body (plunger) with the ability to overlap the passage sections of the radial holes of the separator when moving it (RF Patent No. 2529962 C1, IPC F16K 1/12, F16K 1/54, F16K 39/04, F16K 47/14, p ioritet on 04/24/2013, opub. 10.10.2014). The regulation of the fluid flow rate in this valve is ensured by changing the passage area of the separator’s circular holes when moving the plunger, which changes the area of the openings of the separator, and is characterized by a linear shape of the flow characteristic.

However, in the known valve it is impossible to realize an equal percentage throughput characteristic that meets regulatory requirements in terms of deviation of the actual values of the throughput from the calculated values, without taking into account the mutual arrangement of holes of the same diameter.

Known control valve containing a housing in which a plunger is installed, interacting with the separator with holes made in it in the form of slots with an equal percentage characteristic. Fluid flow control is performed by moving the plunger, which changes the area of open holes. In this valve, as a result of calculations on models, the valve’s flow characteristics were obtained, and then the slots were profiled to obtain a more exact match of the flow characteristics with the ideal equal percentage flow characteristics (Pasko P.I. “Study of the hydrodynamics of axisymmetric cellular control valves for pipelines of TPPs and NPPs ". Abstract of dissertation for the degree of candidate of technical sciences. Novocherkassk. 2008, p. 7, 13, 14).

The disadvantage of this design is that it is not shown in what way a more exact match with the ideal (theoretical) equal percentage characteristic was obtained, and what is the error in deviating the actual throughput characteristic from the ideal one.

Known control valve with an equal percentage flow characteristic, in the housing of which a plunger and a separator is installed, in the walls of which along the longitudinal axis there are made radial shaped slotted holes connected to holes having the shape of a truncated circle. This design provides a maximum (no more than 10%) deviation of the actual equal percentage characteristic from the theoretical one (RF Patent No. 2597798 C1, IPC F16K 47/14, F16K 1/12, priority dated September 18, 2015, published on October 10, 2014).

A disadvantage of the known valve design is the technological complexity of manufacturing profile radial slotted holes in the separator.

Known control valve containing a hollow body, inside of which there is a regulatory body with the possibility of axial movement of its moving part along the longitudinal axis of the valve, interacting with the fixed part, made in the form of a separator, in the walls of which along the longitudinal axis of the valve there are radial profile slotted and round holes, providing equal percent throughput characteristic (Mokveld. "Hamper protection valves (bypass damping valves)". Catalog, p. 1-4).

However, this valve has round and radial profile slotted holes that are not connected to each other, and the valve is additionally equipped with a control valve. The required throughput characteristic of the main control valve is provided due to the linear characteristics of the control valve in combination with profile slotted and round radial holes when moving the plunger. Thus, an equal percentage throughput characteristic of the main valve is provided. This valve, along with the complexity of the design due to the additional control valve, has the same disadvantages mentioned above in terms of ensuring the best match between the actual throughput and its theoretical dependence on that part of the plunger stroke where the round holes are located.

The closest technical solution, selected as a prototype, is a method for profiling an equal percentage throughput characteristic of a control valve, which includes obtaining the necessary dependence of the change in the total flow area formed by round, unconnected holes in the separator wall, when the plunger moves along its axis. Dependence is obtained by a set of identical holes of no more than two diameters in accordance with two sections of the required equal percentage dependence (Chernoshtan V.I., Blagov E.E. Rational profiling of cellular control valves with equal percentage throughput characteristic).

However, in this method, in order to ensure the required equal percentage dependence of the change in throughput on the stroke of the plunger, they resort to fitting the profiled bore through forced placement of the required area, even if this leads to a departure from the required shape of the adjustment characteristic, that is, to its distortion, resulting in the deviation of the actual equal percentage throughput characteristic from the theoretical one occurs.

The closest in technical essence to the proposed valve design is a control valve containing a regulatory body installed in the housing with the ability to move its movable part in the form of a plunger along the longitudinal axis of the valve, interacting with its fixed part in the form of a separator, in the walls of which are located along the longitudinal axis of the valve radial round holes of the same diameter, forming the total bore, while the perforation of the separator holes is made uneven, with a decrease in the density of the holes as they approach the output section of the separator (RF Patent No. 165850 F16K 1/12, F16K 48/08, F16K 39/04, priority dated September 16, 2015, published on November 10, 2016).

However, in this design there is no data on the number of holes and a decrease in their density as they approach the separator and the outlet pipe, which does not allow obtaining data on the allowable deviation of the theoretical profile of the passage section from the actual one. That is, in fact, the law of the change in the cross section is undefined, which ensures the receipt of a given equal percentage throughput characteristic and the correspondence of the change in the cross section to the required equal percentage throughput characteristic.

The technical result, to which the claimed invention is directed, consists in creating a valve regulating body in which, by arranging the mutual arrangement of identical round holes, a predetermined deviation of the separator actual passage area from the theoretical dependence is provided and an equal percentage valve throughput is realized.

The technical result achieved is achieved by the fact that in the method of profiling an equal percentage throughput characteristic of the control valve, which includes obtaining a change in the total flow area formed by round, unconnected holes of the same diameter in the separator wall, when moving the plunger along its axis, according to the invention, the distance is preliminarily calculated between the centers of the round holes located in sections on the generators of the inner diameter of the separator, within the conditions th stroke of the plunger according to the formula:

h _s = S + d,

the centers of the holes, the edges of which coincide with the beginning of the conditional stroke of the plunger on the generators, are located between the centers of the holes on the adjacent generators, the edges of the last holes of which are aligned with the end of the conditional stroke of the plunger, then the integer number of round holes on each generator is calculated by the formula:

,

,

and determine the maximum number of generators in any section of the separator according to the formula:

,

,

then calculate the whole number of holes within the conditional stroke of the plunger, placed in each section along the separator, according to the formula

,

,

and the change in the total bore of the separator F _Σ within the conditional stroke of the plunger is calculated from the solution of the system of equations:

F _Σ = F _n + F ₀

F ₀ = N ₀ ⋅ F

Then, the deviation of the actual passage area of the separator from the theoretical dependence is estimated to create an equal percentage throughput characteristic by the formula:

,

,

where h _s is the distance between the centers of the circular holes located on the generators of the inner diameter of the separator, m;

S is the distance along the generatrix of the inner diameter between adjacent holes, m;

d is the diameter of the round holes in the bore of the separator, m;

n is an integer number of holes along the generatrix of the inner diameter of the separator, pcs .;

h _y = n⋅h _s + d - conditional (maximum) stroke of the plunger, m;

h _s is the distance between the centers of the round holes along the generatrix of the inner diameter of the separator, m;

N _max - the maximum number of generators in any section of the separator, pcs .;

π = 3.14 - mathematical constant equal to the ratio of the circumference of a circle to its diameter;

Y is the chord distance of the inner diameter between adjacent holes in the cross section of the separator, m;

D is the inner diameter of the separator, m;

N _i - the number of round holes with a diameter of d in each design section of the separator, pcs;

i - serial number of the current calculated section, i varies from 0 to m = 2⋅n-1 - the total number of calculated sections;

- относительное приращение суммарной площади круглых отверстий проходного сечения сепаратора для соседних расчетных сечений, для i

1;

- the relative increment of the total area of the circular holes of the separator through passage for adjacent design sections, for i

one;

- относительная пропускная способность клапана в текущем расчетном сечении;

- relative valve capacity in the current design section;

F ₀ - the relative value of the initial valve throughput;

- отношение текущего хода плунжера к условному ходу плунжера в каждом расчетном сечении;

- the ratio of the current stroke of the plunger to the conditional stroke of the plunger in each design section;

x _i - the current value of the plunger stroke, m;

F _Σ is the total bore of the separator within the conditional stroke of the plunger, m ² ;

F _n - the total area of round identical holes within the conditional stroke of the plunger, m ² ;

F ₀ - the total area of round holes corresponding to the relative initial throughput outside the conditional stroke of the plunger, m ² ;

- площадь проходного сечения круглых отверстий, м²;

- the area of the bore of round holes, m ² ;

N ₀ - the number of holes outside the conditional stroke of the plunger, corresponding to the relative initial throughput;

- относительная площадь проходного сечения.

- the relative area of the bore.

The calculation of the distance h _s = S + d between the centers of the holes located on the generatrix for the diameter of the circular hole d and the minimum distance between the holes S specified as the initial data allows determining the number of round holes to an integer

в пределах условного хода плунжера h_y.

within the conditional stroke of the plunger h _y .

The choice of the diameter of the round hole is determined by the need to obtain the required valve capacity. An increase in the diameter of the round hole and a decrease in the distance between the holes S leads to an increase in the total bore due to more efficient use of the side surface of the separator. Changing the distance between round holes in the range from 0 to d and placing the centers of the holes in the sections forming the inner diameter of the separator within the conditional stroke of the plunger ensures continuity of change in the total bore of the separator in accordance with an equal percentage law. Moreover, the choice of the minimum distance between the holes is determined by the requirements for the strength of the separator and improve the manufacturability of the manufacture of closely spaced round holes.

Calculation of the maximum number of generators

in any section of the separator for given values of the inner diameter of the separator D and the chord distance between the centers of the holes in the same section Y, it is necessary for the rational use of the side surface of the separator in order to create the required flow section. On each generatrix, n round holes are provided that are offset from each other by h _s / 2, i.e. between the centers of the holes of each generatrix. An increase in Y leads to a decrease in the cross-section of the separator and, accordingly, to a decrease in the throughput of the valve regulator. At the same time, the choice of S, Y values that affect the minimum distance between adjacent holes in any direction allows us to provide the necessary conditions for the strength of the separator and improve the manufacturability of manufacturing closely spaced round holes.

для проектируемого регулирующего органа вычисляют целое количество круглых отверстий, размещаемое последовательно в каждом расчетном сечении.Based on the maximum number of generators according to the formula

for the designed regulatory body, an integer number of round holes is calculated, placed sequentially in each design section.

Moreover, the centers of the holes, the edges of which coincide with the beginning of the conditional stroke of the plunger on the generators, are located between the centers of the holes on the adjacent generators, the edges of the last holes of which are aligned with the end of the conditional stroke of the plunger. In this way, an equal percentage throughput characteristic is obtained with the estimated value, the deviation of the actual passage section from its theoretical value due to rounding of the number of holes to integer numbers, the use of holes of only one diameter, and also taking into account their mutual arrangement.

Based on the solution of the system of equations:

F _Σ = F _n + F ₀

F ₀ = N ₀ ⋅ F

calculate the total flow cross-section F _Σ necessary for the design of the valve regulator within the conditional plunger stroke, the total area of round holes corresponding to the relative initial throughput F ₀ , the total area of identical round holes within the conditional plunger stroke F _n and the number of holes corresponding to the accepted the value of the initial throughput N ₀ . The obtained data on the change in the total bore of the separator are used to assess the compliance of its actual bore with the theoretical value.

The degree of correspondence of the obtained dependence of the change in the flow cross section to the required equal percentage throughput characteristic within the conditional stroke of the plunger is estimated as a percentage of the expression

.

.

By setting the values of d, S, h _y , Y, D, δF _i that vary during the design of the valve regulator, the necessary data are obtained for the manufacture of the valve regulator with the required equal percentage characteristic.

The technical result in the present invention is achieved by the fact that, in a control valve with an equal percentage flow characteristic, containing a regulating body installed in the housing with the ability to move its movable part in the form of a plunger along the clan’s longitudinal axis, interacting with its fixed part in the form of a separator, in the walls of which radial round holes of the same diameter are located along the longitudinal axis of the valve, forming a total bore, and perforation with openings se the arator is made unevenly, with a decrease in the density of the holes as it approaches the output section of the separator, characterized in that the uneven perforation of the separator with holes is made around the circumference in each section along the generatrices along its inner diameter, while the edges of the holes on the generators coincide with the beginning of the conditional stroke the plunger and the corresponding relative initial valve capacity are located in one section.

The arrangement of round holes in each section of the separator is not uniform in its inner diameter, as the calculations showed, but with the necessary number of them, it does not affect the shape of the throughput characteristic and allows to simplify the manufacturing technology of the separator due to more rational placement of holes.

The combination of the edges of the holes located on the generators, with the beginning of the conditional stroke of the plunger and the location of the edges corresponding to the relative initial throughput of the valve in the same section, allows for a continuous change in the flow area within the conditional stroke of the plunger, corresponding to an equal percentage characteristic with an error of not more than 10% relative theoretical dependence. Moreover, the magnitude of the error in this case is determined only by the accuracy of coincidence of the real total passage area with the theoretical one. The permissible deviation in accordance with (Single-seat, two-seat and valve control valves. General specifications. GOST 12893-2005, page 5, paragraph 3.1.69 and page 8, paragraph 6.5.1.) Is from 15 to 28.6% depending on the stroke of the plunger. A larger tolerance value corresponds to the start of the plunger stroke when the valve is opened.

Of practical interest for the same valve is the case in which a separator providing a linear throughput characteristic is replaced with a separator providing an equal percentage throughput characteristic.

It should be noted that for separators having the same hole sizes, the maximum value of the throughput with an equal percentage characteristic will always be less than the maximum throughput with a linear characteristic (Chernoshtan V.I., Blagov E.E. Rational profiling of cellular control valves with an equal percentage bandwidth characteristic).

The valve capacity according to (Gurevich DF “Calculation and design of pipe fittings: Calculation of pipe fittings”. Ed. 5th. M., Ed. LCI, 2008, p. 454.) is equal to:

,

,

where K _vi is the current value of throughput, m ³ / h;

- текущее значение суммарной площади круглых отверстий в сепараторе, м²;

- the current value of the total area of round holes in the separator, m ² ;

ρ = 1000 kg / m ³ , the density of the fluid (water);

ζ is the coefficient of hydraulic resistance.

The mathematical expression for an equal percentage throughput characteristic has the form

,

,

- текущее значение относительной пропускной способности;Where

- current value of relative throughput;

K _vi - the current value of throughput, m ³ / h;

K _vy - throughput value corresponding to the conditional stroke of the plunger, m ³ / h;

Ф ₀ - initial throughput values in accordance with (Single-seat, two-seat and cellular control valves. General specifications. GOST 12893-2005, page 5, clause 3.1.69 and page 8, clause 6.5.1.).

Assuming that the coefficient of hydraulic resistance ζ during flow in the separator holes is weakly dependent on the shape and area of the radial round holes of diameter d, the valve capacity will be practically proportional to the total passage area of the radial round holes of diameter d.

The invention is illustrated by drawings, where:

in FIG. 1 - shows a General view of the control valve with an equal percentage flow characteristic, a longitudinal section in a perspective view;

in FIG. 2 - shows separately a separator, a longitudinal section in a perspective view;

in FIG. 3 - shows a drawing of a separator, a longitudinal section, section A-A corresponds to the calculated section 12, section BB corresponds to the calculated section 11 of table 1;

in FIG. 4 shows a section AA of the separator in FIG. 3, the value of Y corresponds to the chord between the generators along the inner diameter of the separator, increased;

in FIG. 5 shows a section BB of the separator in FIG. 3, the value of D corresponds to the inner diameter of the separator, increased;

in FIG. 6 is a view B of the separator of FIG. 3, the values of d, h _S and S correspond to the diameter of the same round holes, the step between the same round holes and the minimum thickness of the jumper between the same round holes along the generatrix of the inner diameter of the separator, respectively, increased;

in FIG. 7 - calculated theoretical values of the relative throughput of the valve in the current calculated cross section F _i , numerically equal to the relative total passage area (dashed line) and the relative actual passage area F _i (solid line);

in FIG. 8 - the deviation δF _i (in percent) of the actual passage area of the separator F _i from the theoretical dependence of F _i for creating an equal percentage throughput characteristic at Ф ₀ = 0.04;

in FIG. 9 - shows the calculated values of the actual relative throughput of the control valve for various relative strokes h _i , the plunger (points) and the theoretical equal percentage characteristic for this valve Ф _i at Ф ₀ = 0.04 (solid line);

in FIG. 10 - shows the deviation (in percent) of the calculated values of the relative throughput from the theoretical values of the dependence Ф _i within the conditional stroke h _i , of the plunger for the value of the relative throughput Ф ₀ = 0,04.

The control valve (Fig. 1) with an equal percentage throughput characteristic comprises a housing 1 in which a regulatory body is mounted with the possibility of axial movement of its movable part, made in the form of a plunger 2, along the longitudinal axis of the valve. The plunger 2 interacts with the fixed part, made in the form of a separator 3. In the separator 3 along the longitudinal axis of the valve are made radial round holes 4 of the same diameter d, forming the total flow area F _n , and holes 5 with the diameter d, forming the total flow area F ₀ , in quantities in accordance with table 1 (Fig. 1, 2). The perforation of the holes 4 of the separator 3 is made unevenly, with a decrease in the density of the holes as they approach the output section of the separator 3. Each generatrix has the same number of sections in which the centers of identical round holes are located along the inner diameter of the separator 3, as shown in table 1. The edges of the first the holes 4 on the generators coincide with the initial cross-section of the stroke of the plunger 2. The edges of the holes 5 corresponding to the relative initial throughput of the valve are located in the same section Before starting the stroke of the plunger 2. The centers of the first holes 4 on adjacent generators are located at a distance equal to the sum of half the diameter and half the distance between the holes. The number of holes 4 in each subsequent section of the separator is located unevenly around the circumference of the separator 3.

The geometric characteristics used are shown in FIG. 3-5.

The calculated values of the relative total passage area for the number of round holes N _i and N ₀ (dashed line) and the relative actual passage area (solid line) depending on the relative stroke of the plunger are shown in FIG. 7.

The deviation (degree of conformity) δF _{i of the} relative actual area of the passage separator from the theoretical dependence in the range of variation of the relative stroke of the plunger for Φ ₀ = 0.04, is shown in FIG. 8.

The calculated values of the actual relative throughput Ф _{i of the} control valve at various relative strokes h _{i of the} plunger (points) and the theoretical equal percentage characteristic for this valve Ф _i at Ф ₀ = 0.04 (solid line) are shown in FIG. 9.

In FIG. 10 shows the deviation of the calculated values of the relative throughput from the theoretical values of the dependence Ф _i within the conditional stroke h _{i of the} plunger for the value of the relative throughput Ф ₀ = 0.04.

The control valve operates as follows.

When moving the plunger 2 along the longitudinal axis of the valve inside the separator 3 installed in the housing 1, from the beginning of the radial round holes 4 to their ends and vice versa, there is an increase or decrease in the total passage area of the radial round holes 4 and 5 in accordance with the equal percentage throughput characteristic. When moving the plunger 2 in the forward or reverse directions, the deviation of the calculated actual throughput characteristics from the theoretical dependence does not exceed ± 10%, (Fig. 10). The indicated movement of the plunger 2 within its stroke h _y allows the valve to control the flow or differential pressure of the fluid.

Implementation of the proposed method in the development of the design of the regulatory body with a given inner diameter of the separator includes obtaining a change in the total bore, formed by round, unconnected holes 4 and 5 of the same diameter in the wall of the separator 3, when moving the plunger 2 along its axis. Pre-calculate the distance between the centers of the round holes 4 on the generators according to the formula

h _s = S + d.

The centers of the holes 4 on the generators, the edges of which coincide with the beginning of the conditional stroke of the plunger 2, are placed between the holes 4 on the adjacent generators, the edges of the last holes 4 of which coincide with the end of the conditional stroke of the plunger 2. Then calculate the maximum integer number of round holes n corresponding to the number design cross sections 2⋅n, the same for each generatrix, based on the specified diameter d and the minimum thickness of the jumper S (Fig. 1, 6)

,

,

Then determine the maximum number of generators corresponding to the integer number of centers of the holes 4 in any section of the separator 3

,

,

and calculate the integer number of holes 4, placed in sections along the generatrix of the separator 3, by the formula

,

,

then calculate the values of F _Σ , F _Q , F _n , N ₀ , taking the specified in accordance with the recommendations (Chernoshtan V.I., Blagov E.E. Rational profiling of cellular control valves with an equal percentage throughput characteristic) Ф ₀ = 0.01- 0.04, and calculate the change in the total flow area of the separator F _Σ from the solution of the system of equations:

F _Σ = F _n + F ₀

F ₀ = N ₀ ⋅ F

Then, the deviation of the actual total passage area of the separator from the theoretical dependence is estimated to create an equal percentage throughput characteristic (assessment of the correspondence of the change in the total passage section from the theoretical dependence within the conditional stroke of the plunger) by the formula:

.

.

As an example of a specific embodiment of the proposed embodiment of the design of the regulatory body, the control valve DN 300 is taken. An embodiment of the manufacture of the fixed part of the regulatory body, consisting of the same diameter holes, is shown in FIG. 12.

The number of identical round holes is shown in table 1 within the nominal stroke for given values:

d = 0.008 m

S - not less than 0.0045 m,

h _y = 0,077 m

h _s = 0.012545 m,

Y - not less than 0.022 m,

D = 0.1951 m

δF - no more than 10%

The deviation δF _{i of the} calculated relative values of the actual total passage area of the separator 3 from the theoretical dependence within the conditional stroke of the plunger 2 depending on the relative stroke h _i to create an equal percentage throughput characteristic at Ф ₀ = 0.04 is shown in FIG. 8.

The values of the relative capacity of the control valve Ф _i for Ф ₀ = 0.04 for different plunger strokes (points) obtained on the basis of a numerical solution of the hydrodynamic equations and calculated in this case the maximum K _vy and the minimum values K _{v0 of the} throughput and theoretical (solid line, Φ _i = ƒ (/ h _i )), for a given valve are shown in FIG. 9

The value of Ф ₀ was taken equal to the maximum value in accordance with (Mokveld. "Shock protection valves (bypass damping valves). Catalog, p. 1-4), namely Ф ₀ = 0.04.

Referring to FIG. 10 the deviations of the relative throughput depending on the relative stroke of the plunger h _i when Ф ₀ = 0.04 are calculated by the formula:

.

.

As can be seen from the graph, the given error values do not exceed their permissible values for an equal percentage characteristic in accordance with (Mokveld. “Shock protection valves (bypass damping valves).” Catalog, p. 1-4), namely:

.

.

So, at the beginning of the characteristic, according to (Chernoshtan V.I., Blagov E.E. Rational profiling of cellular control valves with an equal percentage throughput characteristic), a maximum error of ± 28.6% is allowed, and at the end of the characteristic ± 15%, while the actual the error does not exceed ± 9%.

Thus, the use of the proposed technical solution allows you to create a control valve, the perforator of which is carried out only by the same round holes that form the inner diameter forming the maximum (no more than 10%) deviation of the actual equal percentage throughput characteristic from the theoretical one and simplify its manufacturing technology.

Claims (39)

1. A method of profiling an equal percentage throughput characteristic of a control valve, including obtaining a change in the total flow area formed by round, unconnected holes of the same diameter in the separator wall, when the plunger moves along its axis, characterized in that the distance between the centers of the round holes is preliminarily calculated located in sections on the generators of the inner diameter of the separator, within the nominal stroke of the plunger according to the formula h _s = S + d, the centers of the holes, the edges of which coincide with the beginning of the conditional stroke of the plunger on the generators, are located between the centers of the holes on the adjacent generators, the edges of the last holes of which are aligned with the end of the conditional stroke of the plunger, then the integer number of round holes on each generatrix is calculated by the formula

and determine the maximum number of generators in any section of the separator according to the formula

then calculate the whole number of holes within the conditional stroke of the plunger, placed in each section along the separator, according to the formula

and the change in the total bore of the separator F _∑ within the conditional stroke of the plunger is determined by solving the system of equations F _∑ = F _n + F ₀

F ₀ = N ₀ ⋅ F, Then, the deviation of the actual passage area of the separator from the theoretical dependence is estimated to create an equal percentage throughput characteristic according to the formula

where h _s is the distance between the centers of the circular holes located on the generators of the inner diameter of the separator, m; S is the distance along the generatrix of the inner diameter between adjacent holes, m; d is the diameter of the round holes in the bore of the separator, m; n is an integer number of holes along the generatrix of the inner diameter of the separator, pcs .; h _y = n⋅h _s + d - conditional (maximum) stroke of the plunger, m; h _s is the distance between the centers of the round holes along the generatrix of the inner diameter of the separator, m; N _max - the maximum number of generators in any section of the separator, pcs .; π = 3.14 - mathematical constant equal to the ratio of the circumference of a circle to its diameter; Y is the chord distance of the inner diameter between adjacent holes in the cross section of the separator, m; D is the inner diameter of the separator, m; N _i - the number of round holes with a diameter of d in each design section of the separator, pcs; i - serial number of the current calculated section, i varies from 0 to m = 2⋅n-1 - the total number of calculated sections;

- the relative increment of the total area of the round holes of the separator through passage for adjacent design sections, for

;

- relative valve capacity in the current design section; F ₀ - the relative value of the initial valve throughput;

- the ratio of the current stroke of the plunger to the conditional stroke of the plunger in each design section; x _i - the current value of the plunger stroke, m; F _∑ - the total bore of the separator within the nominal stroke of the plunger, m ² ; F _n - the total area of round identical holes within the conditional stroke of the plunger, m ² ; F ₀ - the total area of round holes corresponding to the relative initial throughput outside the conditional stroke of the plunger, m ² ;

- the area of the bore of round holes, m ² ; N ₀ - the number of holes outside the conditional stroke of the plunger, corresponding to the relative initial throughput;

- the relative area of the bore. 2. A control valve with an equal percentage flow characteristic, comprising a regulating body installed in the housing with the possibility of moving its movable part in the form of a plunger along the longitudinal axis of the valve, interacting with its stationary part in the form of a separator, in the walls of which along the longitudinal axis of the valve there are radial round holes of the same diameters forming the total bore, while the perforation of the separator holes is made unevenly with a decrease in the density of the holes by e approaching the outlet cross section of the separator, characterized in that the uneven perforation of the separator with holes is made around the circumference in each section along the generatrices along its inner diameter, while the edges of the holes on the generators coinciding with the start of the conditional stroke of the plunger and corresponding to the relative initial valve throughput, located in one section.

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