SU1696720A1 - Pressure indicator for mine hydraulic support - Google Patents

Abstract

The invention relates to mining and is intended to measure pressure. The purpose of the invention is to improve accuracy, measurement. The indicator includes a housing 1, a plunger pair 2 and 3. A compensating spring 4, indicators 5 and 6 of the current and maximum pressure with a scale of 7 in the form of transverse scratches. The transverse risks are applied at an angle to each other and to the longitudinal axis of the indicator, so that in any longitudinal section of the indicator the distance between the risks is the same, but in different sections these distances differ. The tilt angle of the scratch increases from the outer end of the pointer to its inner part. Each pointer contains an additional longitudinal measuring risk conducted through all transverse risks from the point of intersection of the last of them with the end surface of the housing 1 at a pressure in the indicator equal to the maximum measured on a scale. . Each risk in its area covers a possible range of variation in the length of the spring 4 for the accepted accuracy of its manufacture. The pressure is fixed at a longitudinal measuring risk of 8 by the number of transverse scratches crossing it. 2 Il. (Ls

Description

The invention relates to mining, in particular to plunger pressure gauges for measuring pressure in hydraulic supports of shaft supports.

The aim of the invention is to improve the measurement accuracy.

FIG. Figure 1 shows the pressure indicator for hydraulic shaft supports, longitudinal section; in fig. 2 depicts

the indicator is rotated 90 ° with respect to FIG. 1 and the position of the indication of the maximum pressure at risk.

The pressure indicator includes a housing 1, a plunger pair 2 and 3, a compensating spring 4, indicators 5 and 6 of the current and maximum pressure, respectively. On the pressure gauges there is a scale of 7 with lateral risks longitudinal measurements.

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permissible risks 8 and additional longitudinal measuring risks 9. Indicators on a scale cross-section can be

HALF-ROUND OR RECTANGULAR U. The Shank 6 can be kept from an arbitrary downward movement by ring 10.

All transverse p; (. To and are on the scale at an angle to each other and to the longitudinal axis of the indicator. The slope of the scratches to the longitudinal axis increases in the direction from the outer end of the pointer to its internal part, and the traces of all scratches on the plane intersect at one point - pop o pE, With such a run, the distances between any neighboring via them, as well as between the first and the pointer ends, are the same along the indicator axis, and in any other extension of the scale section parallel to the indicator axis, risk gap and will be equal, but for different sections these distances will be different. The price, the division of the scale in any of these sections is the same and depends not on the distance between the risks, but on their number and measurement range. The slope of the risks is necessary to compensate for inaccuracy manufacture of the spring 4. If the real load characteristic of the spring corresponds to the nameplate (exactly corresponds to the drawing), then the pressure on the indicator is read by the longitudinal measuring risk, carried out along the scale through the midpoints. At the same time, the distance between the centers of neighboring scratches is equal to the deformation of the spring when the pressure in the indicator changes by an amount equal to the scale division value. If the real spring characteristic does not correspond to the calculated one, then measuring risks 8 and 9 are carried out on indicators and and 6 in a place for which the difference between the risks corresponds to the eigenvalue of the spring, i.e. real change in its length with pressure.

Thus, the angle of incline of the scratches and the length of the portion of the scale limited by them is determined by the specified accuracy of the spring manufacture. Moreover, it is even possible to reduce the requirements for the accuracy of manufacturing springs to ± 15% or more (in actual designs of indicators, the deviation from the characteristics of the springs; ± 10% is allowed). This will lead to an increase in the angle of contact of the transverse scratches, but will not reduce the accuracy of the indication, since the measuring risk is held at the place of the scale corresponding to the actual load characteristic of the spring. 3s decline account

spring requirements will reduce culling.

The pressure indicator works as follows.

Under the action of the pressure of the working fluid, the plunger 3 moves the pointer 5 of the current pressure, which moves out of the housing 1 by a certain amount in accordance with the pressure on the hydraulic system. The value of pressure is xixed at measuring risk 8 by the number of transverse risks crossing it and in accordance with the yen scale division. The maximum pressure value during the observation period is similarly fixed at the measuring risk 9 of the pointer 6 of the maximum pressure, which is kept from an arbitrary displacement of the pulp mill when the pressure decreases, for example by ring 10,

0 The method of manufacture of the proposed pressure indicator is as follows.

The details of the indicator are made. On each pressure gauge, transient risks are applied at an angle to each other and to the longitudinal axis of the gauge. The transverse risks are applied so that their centers are on the axis of symmetry of the indicator. The distance between any neighboring ones for this

The axis and the distance between the first risk and the pointer pointer are the same and equal to the calculated change in the length of the spring under pressure, corresponding to the price of the pressure of the scale. The tilt angles of the scratches are such that

5 each of them limits on the indicator a section equal in length to the range of deviation of the length of the spring from its nominal loading characteristic for a given given pressure value. Thus, each risk in its section covers a possible range of variation in the length of the spring for the accepted accuracy of its manufacture.

After the parts are made and the transverse slips are applied, the indicator mount is assembled and checked. When testing the indicator, the tightness of the plunger pair is checked and the measuring longitudinal risks 8 and 9 are applied to the indicators.

In order to determine the location of the application of risks, a calibrated (controlled by the pressure gauge) pressure equal to the maximum measured on the scale of the individual boats is applied to the indicator. Both indicators exit the enclosure.

5 by an amount corresponding to this pressure and the deformation of the spring installed in the indicator. The point of intersection of the last pointers of the indicators with the end surface of the indicator housing is marked, then from these points on each indicator is carried out

longitudinal risk measurement, crossing the entire scale parallel to the axis of the indicator. Measuring risk leads B to conformity with the actual load characteristic of the spring and the distance between the transverse risks at the point of their intersection with the longitudinal risk.

The proposed indicator and method of its manufacture allow an increase in the accuracy of the pressure measurement, reduce the requirements for the manufacture of springs and reduce the scrap.

Claims (1)

Claims An indicator of pressure for mine hydraulic supports, comprising a housing associated with a plunger pair capable of moving the plunger into the housing cavity, a pointer of a current pressure preloaded by a compensating spring and mounted with a holding element and a maximum pressure indicator that are fitted with a scale with transverse risks, characterized in that, in order to improve measurement accuracy, the risks are angled to each other. to the other and to the longitudinal axis of the indicator, with the restriction of each of them on the indicator of the scale section equal to the length of the range of the deviation of the spring length from its nominal loading characteristic for the given pressure value, and with increasing the slope of the marks in the direction from the outer end of the indicator to the internal , while in the sections of the pointer parallel to the axis, the distance between adjacent risks is the same, and each pointer is made with an additional longitudinal measuring line drawn through all the transverse ie the risk of the point of intersection of the last of them with the end the surface of the body when the pressure in the indicator is equal to the maximum measured on a scale. ten evil