RU2149370C1 - Pressure pickup - Google Patents

Abstract

FIELD: measurement technology; measurement of parameters of spatial flow of liquid and gaseous media; determination of parameters of motion of solid bodies, ships and aircraft relative to fluid media. SUBSTANCE: surface of head section of pressure pickup has additional section before peripheral pickup holes which has form of truncated cone and angle between generatrix of additional section of surface and axis of symmetry of pickup is more than angle between tangent line to generatrix of head section and axis of symmetry of pickup at points of conjugation of additional section with head section. EFFECT: facilitated manufacture of pickup; enhanced accuracy of measurements of pressure. 2 cl, 4 dwg

Description

 The invention relates to the field of measuring technology and can be used to measure the spatial flow of liquid and gaseous media or to determine the motion parameters of solids, ships, aircraft, etc. relative to fluids.

 Known six-barrel nozzles (receiver) TsAGI, which is a cylindrical tube with a hemispherical head [1], designed to measure the magnitude and direction of the velocity of the spatial flows of gas or liquid, as well as to measure the static pressure in the stream. Receiving holes are located on the head of the receiver, one of which is the central one for measuring the total pressure, and the peripheral ones, located in pairs in mutually perpendicular planes, are used to measure the pressure used to determine the angles of the flow. On the cylindrical part of the receiver are receiving holes for measuring static pressure.

 The disadvantage of the receiver, as well as of all known receivers of pressure of a spatial stream, is its low sensitivity to bevel angles and velocity head, which manifests itself in measurements in small subsonic speeds (Mach number M <0.3) by an increase in pressure measurement errors. Insufficient sensitivity to the measured parameters is associated with small pressure drops that occur on the surface of the receiver at low subsonic speeds.

 The reason that prevents obtaining the required technical result in a known technical solution is the lack of theoretical methods for the synthesis of pressure receivers that allow obtaining the required metrological characteristics of the receivers by providing a given sensitivity.

 The closest to the invention in terms of essential features is a pressure receiver, which is a rotation body having a head and a cylindrical part, while the head part contains an additional surface section, leading to an increase in the distance from the axis of symmetry of the receiver to the surface of the head part, the surface of which is made in the form section with the inflection point of the generatrix, on the surface of the head part there is a central receiving hole, and immediately after the additional section of the races peripheral inlet openings are used to measure the pressures used in determining the direction and magnitude of the liquid or gas flow rate, on the surface of the cylindrical part there are inlet openings for measuring static pressure [2] - prototype. The shape of this receiver makes it possible to ensure high sensitivity to the angles of the bevel flow and the magnitude of the pressure head and thereby obtain the required accuracy of measuring pressure of a liquid or gas.

The disadvantage of the design of the receiver is the significant technological difficulties in manufacturing an additional portion of the surface of the head part, which must have a generatrix containing an inflection point. The necessity of introducing into the design of pressure receivers sections with an inflection point of the forming surface in order to increase the sensitivity of the receivers to the bevel angles and the velocity head and to increase the accuracy of pressure measurement is the result of an analytical solution to the problem of synthesis of receivers of the optimal shape. But the concept of the inflection point of the line (generatrix) y = f (x) at the point with coordinate x ₀ is purely mathematical, because the necessary sign of the inflection point is the equality of the second derivative f '' _x (x ₀ ) = 0 to zero in it, and the sufficient sign is the change in sign of the second derivative f '' _x (x) when crossing the inflection point. The manufacture of such pressure receivers requires a laborious, technologically complex production process. Also difficult is the control of the surfaces of the manufactured receivers, taking into account the above signs of the inflection point. The complication of the technological process in the absence of effective control methods usually leads to a spread (instability) of the geometric parameters of the manufactured parts (in this case, pressure receivers), which causes an increase in the level of instrumental errors of functioning products.

 The invention is aimed at solving the synthesis problem that is optimal, in terms of sensitivity to measured parameters and accuracy of pressure measurements, of the surface of pressure receivers used in subsonic gas flows and in incompressible fluid flows, as well as to increase the manufacturability of manufacturing highly sensitive receivers and reduce the level of instrumental errors.

 The technical result consists in increasing the manufacturability of manufacturing pressure receivers of high sensitivity and in increasing the accuracy of measuring pressures in a liquid or gas stream by reducing the level of instrumental errors associated with the manufacture of receivers.

 The technical result is achieved by the fact that in the known pressure receiver, which is a rotational body having a head part and a cylindrical part, a central receiving hole and peripheral receiving holes are located on the surface of the head part for measuring pressure used to determine the direction and magnitude of the fluid flow rate or gas, and on the surface of the cylindrical part are receiving holes for measuring static pressure, while the head part contains additional an additional surface area, leading to an increase in the distance from the axis of symmetry of the receiver to the surface of the head part, and the peripheral receiving holes are located directly behind the additional section on the surface, which is a continuation of the head part, the additional section has the shape of a truncated cone, and the angle between the generatrix of the additional surface section and the axis symmetry of the receiver is greater than the angle between the tangent to the generatrix of the head part and the axis of symmetry of the receiver at the interface points of the additional plot with a head part.

 In FIG. 1 shows a general view of a pressure receiver.

= R/L (где L - длина приемника давлений), представлена кривой 2, при его продольном обтекании. В области головной части приемник содержит дополнительный участок поверхности - 3, приводящий к увеличению расстояния от оси симметрии приемника до поверхности головной части, образующая которого содержит точку перегиба. График 4 соответствует изменению коэффициента угловой чувствительности

приемника в зависимости от значения безразмерной продольной координаты

=X/L. График 5 показывает распределение коэффициента давления C_p по поверхности приемника.In FIG. 2 shows a graph - 1 distribution of the dimensionless tangential component V _{τ of the} velocity of a liquid or gas over the surface of a pressure receiver, the generatrix of which has a radius

= R / L (where L is the length of the pressure receiver), is represented by curve 2, with its longitudinal flow. In the region of the head part, the receiver contains an additional surface area - 3, leading to an increase in the distance from the axis of symmetry of the receiver to the surface of the head part, the generatrix of which contains an inflection point. Graph 4 corresponds to the change in the coefficient of angular sensitivity

receiver, depending on the value of the dimensionless longitudinal coordinate

= X / L. Graph 5 shows the distribution of the pressure coefficient C _p over the surface of the receiver.

. График 5 соответствует распределению коэффициента давления C_p по поверхности приемника.In FIG. Figure 3 shows a graph - 1 of the distribution of the dimensionless tangential component of the velocity V _{τ of a} liquid or gas over the surface of a pressure receiver, the generatrix of which is represented by curve 2, during its longitudinal flow. In the region of the head part, the receiver contains an additional surface area - 3, leading to an increase in the distance from the axis of symmetry of the receiver to the surface of the head part, having the shape of a truncated cone. Graph 4 corresponds to the change in the coefficient of angular sensitivity S of the receiver depending on the longitudinal coordinate

. Graph 5 corresponds to the distribution of the pressure coefficient C _p over the surface of the receiver.

аналога - график 2 и заявляемого приемника давлений, изображенного на фиг. 1, - график 1. Здесь P_i, P_j - давления в двух приемных отверстиях, расположенных на головной части приемников симметрично относительно продольной оси,

- скоростной напор в невозмущенном потоке; ν_∞ - скорость невозмущенного потока.In FIG. 4 for the Mach number M = 0.2 shows the angular characteristics

analogue - graph 2 and the inventive pressure receiver, shown in FIG. 1, - graph 1. Here P _i , P _j are the pressures in two receiving holes located on the head of the receivers symmetrically with respect to the longitudinal axis,

- velocity head in an undisturbed flow; ν _∞ is the velocity of the unperturbed flow.

 The graphs in FIG. 2, 3 were obtained using a computer numerical calculation of the flow of pressure receivers past an incompressible fluid [3]. In the case of a stream of gas flowing around the bodies, the results obtained can be used up to Mach numbers M = 0.4, when the compressibility of the gas can still be neglected.

 In FIG. 1 shows the inventive pressure receiver, which is a body of revolution, the generatrix of which is represented by curve 1, with a head part - 2, on which an additional surface section - 3 is located, leading to an increase in the distance from the axis of symmetry of the receiver to the surface of the head part, having the shape of a truncated cone, immediately beyond which on the surface, which is a continuation of the head part, is point 4, at the location of which inlet holes 5-8 are placed in pairs in mutually perpendicular planes, intended nnye for measuring the bevel angle and the magnitude of the flow velocity at the head of the receiver is a central hole 9 for measuring the total pressure on the cylindrical portion for measuring static pressure sensing ports 10 are arranged.

где индексы y давлений P соответствуют номерам приемных отверстий заявляемого устройства (фиг. 1). Здесь вместо отверстия 6 могут быть использованы отверстия 5, 7 или 8.The operation of the inventive pressure receiver is completely similar to the work of the prototype. Assume that the flow around the receiver is longitudinal and the magnitude of the spatial flow velocity is determined. Usually, the following dependence is used to find the velocity value (see [4], p. 123), which is called the velocity characteristic:

where the indices y of the pressures P correspond to the numbers of the receiving holes of the inventive device (Fig. 1). Here, instead of hole 6, holes 5, 7 or 8 can be used.

Нетрудно видеть, что при постоянстве скоростного напора q_∞ и увеличении разности давлений между центральным и периферийными приемными отверстиями чувствительность приемника к величине скоростного напора будет возрастать.Then, as follows from FIG. 3, when the receiver flows around the receiver with a liquid or gas stream in the region of the head part where there is an additional surface section having the shape of a truncated cone, the stream accelerates, which is illustrated by graph 1 for the dimensionless tangential component of the fluid velocity V _τ , which increases and reaches at points the location of the receiving holes 5-8 of its maximum value. An increase in V _τ in accordance with the Bernoulli equation is accompanied by a decrease in the pressures acting in the inlet openings (see graph 5 in Fig. 3), which leads to an increase in the pressure difference (differential) between the central inlet 9 and peripheral 5-8. This effect causes an increase in the sensitivity coefficient S _{q of the} inventive receiver to the value of the pressure head in comparison with the receiver without an additional section. In the case of a linear velocity characteristic, we obtain

It is easy to see that with a constant pressure head q _∞ and an increase in the pressure difference between the central and peripheral receiving holes, the sensitivity of the receiver to the value of the speed head will increase.

 The introduction of the condition that the angle between the generatrix of the additional surface area of the claimed receiver and the axis of symmetry of the receiver is greater than the angle between the tangent to the generatrix of the head part and the axis of symmetry of the receiver at the points of conjugation of the additional section with the head part is necessary because it uniquely determines the additional (in comparison with the initial shape of the receiver) increasing the distance from the axis of the receiver to the surface of the head part, which is the main condition for ensuring a high sensitivity the accuracy and accuracy of measuring the parameters of the motion of objects relative to fluids.

а выражение для коэффициента угловой чувствительности -

Увеличение перепада давлений |P_i-P_j| между приемными отверстиями, расположенными непосредственно за дополнительным участком поверхности за счет более быстрого изменения давления в зависимости от угла скоса потока, приводит к увеличению коэффициента угловой чувствительности заявляемого приемника.Consider measuring the direction of flow of gas or liquid using the inventive pressure receiver. Usually, four inlet openings are used to measure the direction of the spatial flow, arranged in pairs in mutually perpendicular planes, forming pressure differences separately between two inlet openings located symmetrically with respect to the longitudinal axis of the receiver. To obtain angular characteristics independent of the Mach number, the pressure measured at the central inlet is additionally used. In the general case, the angular characteristic (without using a central receiving hole) can be represented as

and the expression for the coefficient of angular sensitivity is

The increase in pressure drop | P _i -P _j | between the receiving holes located directly behind the additional surface area due to a more rapid change in pressure depending on the angle of the bevel of the flow, leads to an increase in the coefficient of angular sensitivity of the inventive receiver.

 In FIG. 4 presents the angular characteristics of the analogue - graph 2 and the inventive receiver - graph 1, obtained for the Mach number M = 0.2. Moreover, an additional surface section having the shape of a truncated cone was introduced into the design of the inventive receiver, leading to an increase in the distance from the axis of the receiver to the surface of the head by 7%, which leads to an increase in the angular sensitivity coefficient by 1.5 times. An additional increase in the radius of the generatrix of the surface at the injection site of the section having the shape of a truncated cone will lead to a further increase in the coefficient of angular sensitivity.

 For the inventive receiver, it was believed that the additional section leads to the exact same increase in the distance from the axis of the receiver to the surface of the head part as in the prototype. From a comparison of the graphs for the angular sensitivity coefficients S of the prototype and the inventive receiver (graph 4 of Fig. 2 and graph 4 of Fig. 3) it follows that instead of an additional section, the surface of which is made in the form of a section with an inflection point of the generatrix, a section having the shape of a truncated cone , practically does not change the form of the graph for S. Moreover, the maximum value of S for the prototype coincides with the maximum value of S for the claimed receiver.

 Thus, the use of an additional section in the form of a truncated cone, instead of the theory recommended additional section, the surface of which is made in the form of a section with an inflection point generatrix, does not impair the accuracy characteristics of the claimed receiver. But this increases the manufacturability of manufacturing pressure receivers of high sensitivity, because the generatrix of the conical surface of the additional section is a straight line segment. Significantly increases the reliability of the methods of controlling the surfaces of manufactured receivers and, as a result of this, increases the accuracy of measuring pressures in a liquid or gas stream by reducing the level of instrumental errors associated with the manufacture of receivers.

Sources of information
1. Bedrzhitsky E. L., Egorshev A.V. and others. Aerodynamic and strength tests of aircraft. - M.: Mechanical Engineering, 1992, p. 159.

 2. Patent for the invention N 2124709. Pressure receiver. / Ledyaev V.V. Patent holder of the Perm State Technical University. Publ. 01/10/99, Bull. N 1.

 3. Maslov L.A., Levshina Z.G. A program for calculating the distribution of pressure and a turbulent boundary layer on a body of revolution at an angle of attack. TsAGI Report N 9270, 1976.

 4. Petunin A. N. Methods and techniques for measuring gas flow parameters (pressure and velocity heads). - M.: Mechanical Engineering, 1972, p. 123.

Claims (2)

 1. The pressure receiver, which is a rotation body having a head part and a cylindrical part, has a central receiving hole and peripheral receiving holes on the surface of the head for measuring pressure used to determine the direction and magnitude of the flow rate of a liquid or gas, and on the surface in the cylindrical part there are receiving holes for measuring static pressure, while the head part contains an additional surface area, leading to an increased the distance from the axis of symmetry of the receiver to the surface of the head part, and the peripheral receiving holes are located directly behind the additional section on the surface, which is a continuation of the head part, characterized in that the additional section has the shape of a truncated cone.  2. The pressure receiver according to claim 1, characterized in that the angle between the generatrix of the additional surface section and the axis of symmetry of the receiver is greater than the angle between the tangent to the generatrix of the head part and the axis of symmetry of the receiver at the interface points of the additional section with the head part.

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