RU2318190C2 - Fluid variable discharge generator (versions) - Google Patents

Abstract

FIELD: variable discharge generators.

SUBSTANCE: generator can be used for measurement of metrological parameters of aids for measuring arterial pressure. Generator has rotor in form of truncated cylinder, cylindrical stator with two outlet slots disposed along generator of cylinder at diametrically opposite sides. Rotor is connected with shaft of engine. Pipelines connect outlet slots of stator.

EFFECT: widened functional abilities.

5 cl, 2 dwg

Description

The invention relates to variable flow generators for determining the metrological characteristics of blood pressure measuring instruments and may find application in the instrument-making industry for metrological certification of these measuring instruments.

Known variable flow generators for determining the dynamic characteristics of flow meters (variable flow generator. Report No. B060014. All-Union Scientific and Technical Information Center. M., 1974) - [1].

A known variable flow generator, which uses the change in the area of a rectangular slot located along the generatrix of the cylindrical stator (Flow pulsator PR-1. Technical description P1-00-00 TO, 1973) - [2]. The controlled medium is fed into the internal cavity of the stator through the inlet pipe. The change in the size of the area of the slot occurs when the rotor rotates in the form of a cylinder truncated by a plane at an angle to its longitudinal axis. In this case, the flow rate through the aforementioned slot with uniform rotation of the rotor changes according to a sinusoidal law. The stream passing through the slot of variable area enters the test section in the form of a pipeline with the test flowmeter installed in it and then into the drain tank through the drain pipe. The frequency of flow pulsations is determined by the rotor speed. By changing the speed of rotation of the rotor and recording the testimony of the test flowmeter, you can determine the frequency response of the test flowmeter. This well-known generator is characterized by the difficulty of obtaining flow pulsations of the required amplitude and shape in a wide frequency range, since for this it is necessary to control the movement of a large mass of liquid, and this requires the creation of significant pressure of a controlled medium, which in some cases is practically not feasible. In addition, in generators of this design, significant pressure drops occur, which introduces additional errors in the test results, not to mention the presence of large pipeline vibrations, especially at low frequencies.

Known hydromechanical pulsator for the study of the dynamic characteristics of flowmeters according to the copyright certificate SU No. 1013764 A, G01F 25/00, published on 04.23.83 Bull. No. 15 - [3], containing a cylindrical body with input and two output windows of a rectangular shape located in mutually perpendicular planes, and with a cylindrical rotor installed in the body, which is hollow, with an odd number of windows identical to the output windows of the case, and the total size windows around the circumference is 180 °. The disadvantage of such a pulsator is the reproduction of only a sinusoidal pulsating stream.

Closest to the claimed invention is the invention according to the copyright certificate of the USSR No. 637722, G01F 25/00, Variable flow generator, publ. 12/15/78. Bull. No. 46 - [4] for determining the dynamic characteristics of flowmeters, containing a rotor in the form of a cylinder truncated by a plane at an angle to its longitudinal axis, a hollow cylindrical stator with a rectangular slot along the generatrix of the cylinder on diametrically opposite sides. The rotor is connected to the motor shaft. The internal stator cavity is connected to an inlet pipe supplying a controlled medium, and through slots it communicates with segments of two pipelines, in one of which a test flowmeter is installed. The other ends of the pipelines are connected to the outlet pipe through a throttle device (figa).

The controlled medium enters the stator cavity through the inlet pipe and passes through the slots through two pipelines and through the flow meter into the outlet pipe.

The disadvantage of this generator is the inability to reproduce the entire variety of forms of generated flow.

The technical result to which the claimed invention is directed is to expand the possibilities of obtaining a fluid flow rate with various laws of change by performing a cross-section of a rotor of various forms.

, где R - радиус ротора; x, y - координаты точек направляющей кривой при нахождении начала координат в точке пересечения оси ротора с линией сопряжения секущих поверхностей. Съемный ротор выполнен в виде цилиндра, усеченного двумя линейчатыми поверхностями, одна из которых выпуклая, а другая вогнутая. Сечение съемного ротора представляет собой линейчатую поверхность, ограниченную направляющей кривой согласно уравнению

, где R - радиус ротора; x, y - координаты точек направляющей кривой при нахождении начала координат в точке пересечения оси ротора с линией сопряжения секущих поверхностей. Сечение съемного ротора представляет собой линейчатую поверхность, ограниченную направляющей кривой согласно уравнению

, где R - радиус ротора, x, y - координаты точек направляющей кривой при нахождении начала координат в точке пересечения оси ротора с линией сопряжения секущих поверхностей.The technical result is achieved in that in a variable fluid flow generator containing a rotor in the form of a truncated cylinder, connected to the motor shaft, a cylindrical stator with two output slots along the cylinder generatrix on diametrically opposite sides associated with the pipelines, the new is that the cross-section of the removable rotor represents a ruled surface bounded by a guide curve according to the equation

where R is the radius of the rotor; x, y - coordinates of the points of the guide curve when finding the origin at the intersection of the rotor axis with the interface line of the secant surfaces. The removable rotor is made in the form of a cylinder truncated by two ruled surfaces, one of which is convex and the other is concave. The cross-section of the removable rotor is a ruled surface bounded by a guide curve according to the equation

where R is the radius of the rotor; x, y - the coordinates of the points of the guide curve when finding the origin at the point of intersection of the rotor axis with the interface line of the secant surfaces. The cross-section of the removable rotor is a ruled surface bounded by a guide curve according to the equation

, where R is the radius of the rotor, x, y are the coordinates of the points of the guide curve when finding the origin at the intersection of the axis of the rotor with the interface line of the secant surfaces.

The invention is illustrated in figure 1, 2, where:

figure 1 - alternating flow generator;

figb, c, d are examples of a truncated rotor.

1 - rotor; 2 - stator; 3 - case; 4 - inlet pipeline; 5 - the right pipeline; 6 - the left pipeline; 7 - engine; 8 - slots of the stator; 9 - coupling.

In the stator 2 in the form of a hollow cylinder with slots 8 located along the generatrix of the cylinder on diametrically opposite sides, the rotor 1 is located in the form of a truncated cylinder. The rotor 1 is connected to the motor shaft 7 by a coupling 9. The internal cavity of the stator 2 is connected to the inlet pipe 4 supplying a controlled medium, and through slots 8 is connected to the pipelines 5 and 6. The stator 2 is fixed to the housing 3, in which the rotor shaft 1 is mounted in the bearings To replace the rotor 1 with a different cross-section, it is disconnected from the motor shaft 7 by the coupling 9, and then the stator 2 is also disconnected.

The controlled fluid through the inlet pipe 4 enters the cavity of the stator 2 and passes through the slots 8 through pipelines 5 and 6. Depending on the angular position of the rotor, the flow rate of the medium through the slots can be either the same or different. In this case, the flow rate is determined by the area of the slot, which is not currently blocked by the rotor.

(фиг.2б), где R - радиус ротора 1; x, y - координаты точек направляющей кривой при нахождении начала координат в точке пересечения оси ротора с линией сопряжения секущих поверхностей. Съемный ротор 1 выполнен в виде цилиндра, усеченного двумя линейчатыми поверхностями, одна из которых выпуклая, а другая вогнутая (фиг.2в). Сечение съемного ротора 1 представляет собой линейчатую поверхность, ограниченную направляющей кривой согласно уравнению

, где R - радиус ротора 1; x, y - координаты точек направляющей кривой при нахождении начала координат в точке пересечения оси ротора с линией сопряжения секущих поверхностей. Сечение съемного ротора 1 представляет собой линейчатую поверхность, ограниченную направляющей кривой согласно уравнению

(фиг.2г), где R - радиус ротора 1; x, y - координаты точек направляющей кривой при нахождении начала координат в точке пересечения оси ротора с линией сопряжения секущих поверхностей.To obtain various characteristics of the forms of the variable flow, the cross section of the rotor 1 is changed. Figure 2 shows examples of a truncated rotor 1. The cross section of the removable rotor 1 is a ruled surface bounded by a guide curve according to the equation

(figb), where R is the radius of the rotor 1; x, y - the coordinates of the points of the guide curve when finding the origin at the point of intersection of the rotor axis with the interface line of the secant surfaces. The removable rotor 1 is made in the form of a cylinder truncated by two ruled surfaces, one of which is convex and the other is concave (Fig.2c). The cross-section of the removable rotor 1 is a ruled surface bounded by a guide curve according to the equation

where R is the radius of the rotor 1; x, y - the coordinates of the points of the guide curve when finding the origin at the point of intersection of the rotor axis with the interface line of the secant surfaces. The cross-section of the removable rotor 1 is a ruled surface bounded by a guide curve according to the equation

(Fig.2d), where R is the radius of the rotor 1; x, y - the coordinates of the points of the guide curve when finding the origin at the point of intersection of the rotor axis with the interface line of the secant surfaces.

The duration of the period is determined by the speed of rotation of the rotor 1. The mass of liquid in the output pipelines 5 or 6 is small, and therefore the frequency range of the generator expands towards high frequencies. Due to the fact that the total area of the conditional passage of the slots during operation of the generator remains constant, a pressure drop in the inlet pipe does not occur, which minimizes distortions in the shape and amplitude of flow fluctuations and improves the operating characteristics of the generator.

The variable fluid flow generator operates as follows.

When you turn on the engine 7, the rotor 1 comes into rotation. The controlled medium through the inlet pipe 4 enters the cavity of the stator 2 and through alternately overlapping slots 8 passes through the right 5 and / or left 6 pipelines. Moreover, if the area of one slot 8 increases, then the area of the other slot decreases and vice versa. Therefore, the flow rate through the slots 8 changes in antiphase with respect to each other.

Choosing the required cross section of the rotor 1, change the shape of the variable generated flow. To replace the rotor 1, first disconnect the coupling 9 from the shaft of the engine 7, and then disconnect the housing 3.

Thus, a variable fluid flow generator is proposed, in which the expansion of the possibilities of obtaining a fluid flow with various laws of change is carried out by performing the cross-section of the rotor of various shapes, while the solution of the generator is simple in execution, simple and reliable in operation.

Claims (4)

1. A variable fluid flow generator containing a rotor in the form of a truncated cylinder, connected to the motor shaft, a cylindrical stator with two output slots along the cylinder generatrix on diametrically opposite sides connected with pipelines, characterized in that the cross-section of the removable rotor is a ruled surface limited guide curve according to the equation

, where R is the radius of the rotor; x, y - the coordinates of the points of the guide curve when finding the origin at the point of intersection of the rotor axis with the interface line of the secant surfaces. 2. A variable fluid flow generator containing a rotor in the form of a truncated cylinder connected to the motor shaft, a cylindrical stator with two output slots of a rectangular shape along the generatrix of the cylinder on diametrically opposite sides connected with pipelines, characterized in that the removable rotor is made in the form of a cylinder, truncated by two ruled surfaces, one of which is convex and the other is concave. 3. The variable fluid flow generator according to claim 2, characterized in that the cross-section of the removable rotor is a ruled surface bounded by a guide curve according to the equation

, where R is the radius of the rotor; x, y - the coordinates of the points of the guide curve when finding the origin at the point of intersection of the rotor axis with the interface line of the secant surfaces. 4. A variable fluid flow generator containing a rotor in the form of a truncated cylinder connected to the motor shaft, a cylindrical stator with two output slots along the cylinder generatrix on diametrically opposite sides connected with pipelines, characterized in that the cross-section of the removable rotor is a ruled surface limited guide curve according to the equation

, where R is the radius of the rotor; x, y - the coordinates of the points of the guide curve when finding the origin at the point of intersection of the rotor axis with the interface line of the secant surfaces.

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