RU2601610C2 - Differential pressure sensor with support on tension section - Google Patents

Abstract

FIELD: measuring equipment.

SUBSTANCE: invention relates to measurement equipment, namely, to pressure sensors. Proposed differential pressure sensor with support on tension section with self-centering system contains external and internal bases, on which external and internal rollers or rotation sprockets, respectively, are fixed, connected by successively closed cable, chain or belt, wherein inner base is made with possibility of applying to it first pressure force, additionally rollers are introduced, through which springs provide cable tension, chain or belt, additionally roller is introduced, to which second pressure force is supplied via union and bellows, applied to cable, to chain or belt, wherein differential pressure sensor is made with possibility to convert internal base displacement into gear wheel rotational movement, connected to pointer.

EFFECT: technical result is increased accuracy of pressure measurements.

1 cl, 3 dwg

Description

A known differential pressure sensor using a universal self-centering system. The internal base is used as a measuring body, which is affected by two measured pressures. Measured pressures act on the internal base in mutually opposite directions through bellows or membranes. In the absence of pressure, the inner base returns to its original position. The self-centering system has internal and external bases on which internal rollers or sprockets are fixed. The number of rollers on each base is at least three. The rollers of the outer base are outside the volume V in which the rollers of the inner base are. The rollers of the external and internal bases are sequentially interconnected by a closed cable, chain or belt. When the cable or belt is displaced along its perimeter, the direction of rotation of the rollers or sprockets of the inner base is opposite to the direction of rotation of the rollers or sprockets of the outer base. One of the properties of a universal self-centering system is that the load P acting on the inner base is divided between the rollers of the outer base. The inner base always returns to its original position when there is no load P. This positioning is independent of temperature and the magnitude of the force of the tension springs (DE202012008307U1, DE102012016380A1).

 The disadvantage of this sensor is that the angle of 180 degrees between the measured forces can change, which will lead to measurement errors.

 The aim of the invention is to eliminate the dependence of measurement accuracy on the angle between the measured pressure forces.

 This goal is achieved by the fact that the second measured pressure force is applied to the section of the chain, belt or cable through a roller or sprocket, which is enclosed between a pair of rollers or sprockets of the same base, and this pair of rollers is a replacement for one roller, which took place in a conventional universal self-centering system. Exposure to a portion of a cable, chain or belt between rollers or sprockets does not alter the properties of a universal, self-centering system.

 In a specific embodiment, the differential pressure sensor has a housing 2, which is used as the external base of a universal self-centering system. The inner base 1 is connected to the bellows B2, to which the measured pressure P2 is supplied through the fitting W2. The inner base 1 has 3 r rollers. Instead of the usual three rollers that took place in a conventional universal system, 6 rollers R1, R2, R3, R4, R5, R6 are mounted on axes A. On the axle A. The cable sections between the rollers R1-R2, R3-R4 are used to tension the cable through the rollers tension N1, N2. The cable section between the rollers R5-R6 is used to apply the force of the second measured pressure P1 supplied through the fitting W1 and the bellows B1 to the roller D. The springs F1, F2 serve to tension the cable S through the tension rollers N1, N2. Displacement of the internal base, which will be proportional to the pressure difference P2-P1. In the absence of P2, pressure P1 does not cause displacement of the base 1, but only increases the tension of the cable. The displacement of the inner base 1 together with the gear rack Z2 is converted into the rotational movement of the gear wheel Z1 connected to the arrow Z3. Instead of a mechanical displacement transducer, any type of transformation can be applied, for example, capacitive inductive, magnetic, electrostatic, electromagnetic, and strain resistance.

The figure 1 presents a cross section of the pressure difference sensor.

The figure 2 presents a General view of the sensor.

The figure 3 presents an enlarged view of the elements of the differential pressure sensor.

Claims (1)

Differential pressure sensor based on a tension section with a self-centering system, containing external and internal bases, on which external and internal rollers or sprockets, respectively, are connected, connected in series by a closed cable, chain or belt, while the internal base is made with the possibility of applying force to it the first pressure, additionally introduced rollers through which the springs provide tension to the cable, chain or belt, an additionally introduced roller, to which the force of the second pressure through the fitting and the bellows applied to the cable, chain or belt, while the differential pressure sensor is configured to convert the displacement of the inner base into the rotational movement of the gear connected to the arrow.

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