RU2382342C1 - Shipborne indicating pressure gage - Google Patents

Abstract

FIELD: measuring equipment.

SUBSTANCE: invention is related to instrument making, namely to indicating pressure gages. Shipborne indicating pressure gage comprises cylindrical case, where holder base is installed, ending with nozzle for connection to measured pressure on external side of case, Bourdon tubular gauge, which is connected with its free end via traction rod to pinion-sector transmission mechanism, which converts motion of free pipe end to circular motion of arrow installed on pinion axis and arranged over dial plate, besides pinion-sector mechanism comprises mechanically joined two joined parallel metal upper and lower plates, which are rigidly fixed on holder base, between which toothed sector is installed as engaged to pinion, on axis of which bush is put with axial hole, and tension flat helical spring is fixed into its slot by its internal end, and by its external end - to pinion-sector mechanism. Besides pinion-sector mechanism comprises protective limiting cup, where hole is available for passage of pinion axis, which is engaged with toothed sector and toothed inertial disk, besides axis of pinion and axis of toothed inertial disk lie in the same plane, and axis of pinion coincides with central axis of pressure gage.

EFFECT: preservation of measurements accuracy, increased vibration stability and reliability of pressure gages operation under shaking conditions.

4 cl, 4 dwg

Description

The invention relates to instrumentation, in particular to the field of creating dial gauges, thermometers and other devices, the cases of which have a cylindrical shape of various diameters with a protective glass located above the dial.

The devices are designed to operate in water vapor saturated with salts contained in sea fog, with an admixture of oil vapor, under vibration and incline conditions. Measured media can be: sea and fresh water, steam, steam-air mixture, industrial air, oil, freon grades 12, 22 and 142, kerosene, solarium, diesel fuel, gasoline, helium, nitrogen, oxygen.

As analogues, designs of devices such as manometers showing ship MTPSd-100-OM2, VTPSd-100 - OM2, MVTPSd-100-OM2 can be used [1].

Known ship pressure gauge MKU [2], containing a manometric sensitive element (hereinafter referred to as the Bourdon tube) and a tribal sector gear mechanism in the form of a rod system kinematically connected with an arrow located on its rotation axis, characterized in that in order to increase the device’s vibration resistance in he introduced an inertial disk mounted on the axis of the tribes, the center of which is located on the axis of rotation of the arrow.

A feature of this technical solution is that under the influence of the pulsating pressure of the medium being measured, the Bourdon tube makes sharp short-term oscillations of a greater or lesser amplitude (it comes into a vibration state), which are transmitted to the arrow of the device. At the same time, the disk fixed on the axis of the tribe performs a reciprocating motion. But due to inertness, the disk has a certain resistance to changing the direction of its rotation. Due to the inhibitory effect of the disk, the oscillation of the arrow decreases. In addition, the housing of the device has a device that ensures the safety of glass in the event of a burst of the Bourdon tube. There is a hole in the rear end wall of the device case, which is blocked by a circular disk integrated in the end wall. In case of bursting of the Bourdon tube by the pressure of the medium through the hole, a round disk is squeezed out and thereby protects the glass.

However, this device has a number of significant drawbacks, namely:

- in the case of shaking, the inertial disk stabilizes the position of the arrow on the dial due to its mass, but under the influence of the pulsating pressure of the medium being measured, the Bourdon tube makes sharp short-term oscillations, and due to the fact that the inertial disk has a certain mass, which causes sharp one or the other side of the actual reading of the arrow on the scale of the device;

- a flat tension spiral spring under the action of shaking is in spontaneous movement, which negatively affects the readings of the device, in addition, leads to premature wear. The tension coil spring is rigidly fixed with the inner end in the slot of the sleeve, mounted on the axis of the tribe, and the outer end in the sector gear. Since the ends of the spring are fixed rigidly, coupling reactions inevitably occur at the attachment points under the action of periodically varying loads (stresses) to which the Bourdon tube is exposed to the pulsating pressure of the medium being measured. Experiments show that parts fail at voltages lower than stresses caused by static loads [3, p. 354];

- it is characteristic that under the action of alternating loads, the spring gradually breaks down due to the fatigue of the spring material and as a result of the gradual development of cracks. Not only defects in the internal structure of the material (internal cracks, slag inclusions, etc.), but also defects in the surface treatment of the part (scratches, marks from a cutter or grinding stone) are essential for the occurrence of cracks and the development of fatigue cracks.

Studies show that failures in the vast majority of cases occur due to fatigue cracks [3, p. 354-358].

The known "Pressure Gauge" [4], selected as a prototype, in which, in order to increase vibration resistance, the gear sector is connected by internal gearing with an additional gear wheel, on the axis of which an inertial element is fixed, which reduces the amplitude of oscillations of the pointing arrow by inertia. The disadvantage of this technical solution is the occurrence in the hinges of the reaction mechanism from inertial forces, which leads to accelerated destruction of the device. This circumstance limits the mass of the inertial element, which in turn reduces the effectiveness of its action.

Another disadvantage of this device is that when the device is shaken, the tension spiral spring makes spontaneous movements, the ends of which are rigidly fixed, coupling reactions inevitably occur at the attachment points under the action of periodically changing loads, which leads to the breakdown of the rigidly fixed ends of the tension spiral spring due to the same reasons as in [2]. A feature of the design of this device is that it adopted a technical solution that allows to reduce the amplitude of oscillations of the pointing arrow by using an additional gear connected by internal meshing with the gear sector, which by inertia reduce the amplitude of the oscillations of the pointing arrow. Such a constructive solution has the greatest positive effect in stationary conditions, where the device is not subject to shaking and vibration. However, under the conditions of operation of the device during shaking and vibration, the additional gear wheel acquires a delayed or advanced torque, which leads to an error in the readings of the device.

The purpose of the proposed technical solution is to preserve the accuracy of measurements, increase the vibration resistance and reliability of the pressure gauges in the conditions of shaking, as well as by reducing the influence of pulsation of the measured medium on their readings.

The technical result is achieved by the fact that the pressure gauge containing a cylindrical body, inside which there is a holder-base, ending with a fitting for connecting to the measured pressure from the outside of the body, a Bourdon tubular spring, which is connected with the free end to the transmission tribo-sector mechanism that converts the movement of the free end the tube in a circular motion of an arrow mounted on the axis of the tribe and located above the dial has a protective restrictive cup in which there are holes to pass the axis of the tribe, which is meshed with the gear sector and the gear inertial disk, and the axis of the tribe and the axis of the inertial disk lie in the same plane, and the axis of the tribe coincides with the central axis of the device, and the tension coil spring is located in the protective limit cup, where fixed by the inner end in the slot of the sleeve with an axial hole, and the sleeve is mounted on the axis of the tribe, and the external end is attached with a pin to the existing hole in the cylindrical wall of the protective limit cup, etc. whereby the cup is attached to the base holder with screws, and the dial with a central hole through which the free end of the tube passes, on the free end of which the pointer arrow is mounted, is also screwed to the base holder.

An advantage of the present invention is that a difficult technical problem is solved to maintain the measurement accuracy, to increase the vibration resistance and reliability of the pressure gauges under shaking conditions, and also by reducing the influence of the pulsation of the measured medium on their readings by using a protective limiting cup, which protects the tension coil spring during shaking and limits its spontaneous movements, reduces the likelihood of breakage of rigidly fixed ends, and the use of inertial gear di ska, which is meshed with the tribe, which is also meshed with the gear sector, and due to the opposite reciprocating rotations of the gear inertial disk and the gear sector balances their rotational inertial moments, which stabilizes the position of the pointer on the dial scale and reduces the amplitude of the oscillations of the index arrows, which increases the effectiveness of the pressure gauges.

Another advantage of the present invention is that a gear limiter of the gear sector is introduced into the design of the device within the range of indications, which is especially important in the conditions of operation of pressure gauges when shaking. The travel limiter is made in the form of a rectangular plate with ends bent down, which limit the movement of the gear sector in cases of great shaking and sharp pulsations of the medium being measured. The travel stop is attached to the top plate of the tribal sector mechanism with screws.

To protect the tribo-sector mechanism with the Bourdon tube from the effects of water vapor saturated with salts contained in sea fog and an admixture of oil vapor, the manometer is equipped with an air filter that is located inside the manometer body, in addition, the air filter serves to balance the pressures inside the device with atmospheric, which eliminates the breakage of the protective glass.

The base holder is fixed to the housing with screws, and the Bourdon tubular spring is fixed hermetically in the base holder with one end and ends with a tight free other, to which a flat protrusion is fixed, having a hole for attaching the first hinge, and there is a hole in the gear sector shank made in in the form of a groove, a second hinge for connecting the rod with its ends using the first and second hinges.

Thus, in order to maintain the accuracy of measurements, increase the vibration resistance and reliability of the pressure gauges under shaking conditions, and also by reducing the influence of pulsations of the measured medium on their readings, the tribo-sector mechanism contains a protective limiting cup in which there is an opening for the passage of the axis of the tribe which is meshed with the gear sector and the gear inertial disk, and the axis of the tribe and the axis of the gear inertia disk lie in the same plane, and the axis of the tribe coincides with the central axis of the man meter, and the located spiral tension flat spring in the protective restrictive cup, in which it is fixed with the inner end in the slot of the sleeve with an axial hole, and the sleeve is mounted on the axis of the tube, and the external end is attached with a pin to the existing hole in the cylindrical wall of the protective limit cup, which protects the tension flat coil spring during shaking and limits its spontaneous vibrations, reduces the likelihood of breakage of rigidly fixed ends, in addition, installed in t Due to their opposite reciprocating rotations, their rotational inertial moments balance the position of the pointer arrow on the dial scale and practically eliminate the oscillation amplitude due to the sector-specific mechanism of the inertial toothed disk meshed with the tribe, which is also meshed with the toothed sector. the arrow, in addition, the stroke of the gear sector is limited within the range of readings by the newly introduced stroke limiter made in the idea of a rectangular plate with downward bent ends, between which the gear sector performs reciprocating rotations, in addition, in order to protect the tribo-sector mechanism with the Bourdon tube from exposure to water vapor saturated with salts contained in sea fog mixed with oil vapor, pressure gauge equipped with an air filter, which also serves to balance the pressure inside the manometer with atmospheric, which eliminates the breakage of the protective glass, therefore, the new design of the ship manometer fulfills the purpose of the task left - it maintains the accuracy of measurements, increases the vibration resistance and reliability of the pressure gauges in the conditions of shaking, by reducing the influence of pulsation of the measured medium on their readings.

Comparison of the claimed technical solution with the prototype made it possible to establish its compliance with the criterion of "novelty." In the study of other known technical solutions in this technical field that distinguish the claimed invention from the prototype, were not identified, and therefore they provide a technical solution that meets the criterion of "significant differences".

A drawing explaining the essence of the invention is shown in figure 1 - from the front side; figure 2 is a longitudinal section in which 1 is a cylindrical body of the device in which the holder-base 2 is fixed with a sealing gasket 3 using screws 4 (figure 2) and a fitting 5 for connecting to the measured pressure from the outside of the housing 1, and the tubular spring of Bourdon 6 is fixed hermetically in the base holder 2 at one end and ends with a tight free other, to which a flat protrusion 7 is rigidly fixed, having a hole 8 for attaching the first hinge 9, and there is a hole 12 in the shank of the gear sector 11 in the form of a groove for the second hinge 13 for connecting the rod 14 to its ends using the first 9 and second 13 hinges, the length of the rod 14 being adjusted using the shoulder 15, in which there is a longitudinal groove 16 for moving the shoulder 15 up or down, which is attached to the rod 14 with screws 17, in addition, and on the base holder 2 is rigidly attached tribo-sector mechanism A, which contains mechanically interconnected two parallel, upper 18 and lower 19, metal plates, and on the upper plate 18 of mechanism A strengthened and with the help of screws 20, a protective restrictive cup 21, in which a tension spiral spring 22 is installed, which is fixed by the inner end 23 in the slot of the sleeve 24, mounted on the axis of the tribe 25, and the outer end 26 is attached with a pin 27 to the existing hole in the cylindrical wall 28 protective restrictive cup 21, and the dial 29 with a Central hole through which passes the free end of the tube 25, on the free end of which is mounted the pointer arrow 30, is also fastened with screws 20 to the base holder 2, in addition, between at the upper 18 and lower 19 parallel metal plates of the tribal sector mechanism A, an inertial gear disk 31 is mounted on the axis B, which is meshed with the tube 25, which is also engaged with the gear sector 11, in addition, the design of the device has a stroke limiter 32 ( figure 1, figure 3) of the gear sector 11 within the range of the scale of the dial 29, and the stop 32 is made in the form of a rectangular plate with the ends 33 bent down, which limit the progress of the gear sector 11, and the stop 32 is attached to the top plate 18 of the tribal sector mechanism A with screws 20, in addition, the device has a damping device 34 (Fig. 1, Fig. 4) for damping pulsating pressure, in addition, an air filter 35 is installed inside the cylindrical housing 1 of the manometer, which serves to balancing the pressure inside the manometer with atmospheric, which eliminates the breakage of the protective glass 36, which is attached to the cylindrical body 1 of the manometer with sealing gaskets 38 and 39 using the shell 40, which is mounted on the housing 1 with three screws 41, on one of which seal 42 is installed with a control screw 43. The outside of barrel 1 in a quadrangular wall 44 at the corners there are openings 45 for mounting the pressure gauge at the place of application.

The pressure gauge operates as follows.

The work of the pressure gauge is based on balancing the measured pressure by the forces of elastic deformation of the gauge tubular spring of Bourdon 6 (figure 1).

The measured pressure is fed through the nozzle 5 into the inner cavity of the tubular spring of Bourdon 6, one end of which is rigidly fixed in the holder-base 2, and the other is free.

When applying pressure, the movement of the free end of the tubular spring of Bourdon 6 using the rod 14, the tribal sector mechanism A is converted into rotational movement of the indicating arrow 30. The readout of the readings is made on the dial 29.

Under the action of shaking and pulsating pressure of the medium being measured, the manometric sensitive element 6 performs sharp oscillations of a greater or lesser amplitude (comes into a vibration state), which are transmitted to the pointer arrow 30 of the device. At the same time, the protective restrictive cup limits the spontaneous vibrations of the tension coil spring, in addition, the inertial gear disk 31 mounted on the axis B is meshed with the tube 25, which is also meshed with the gear sector 11, which counterbalance the reciprocating movements their rotational inertial moments, which stabilizes the position of the pointer arrow 30 on the dial scale and virtually eliminates the fluctuations of the pointer arrow 30, in addition, the limiter 32 strokes of the gear sector 11 limits the progress of the gear sector 11 within the range of the instrument when measuring the pressure of the medium to be measured, while maintaining the accuracy of the measurements, increases the vibration resistance and reliability of the pressure gauges under the conditions of jolting and pulsations of the measured medium, in addition, air is installed inside the body 1 of the pressure gauge filter 35 protects the tribo-sector mechanism A with a Bourdon tube 6 from exposure to water vapor saturated with salts contained in sea fog, mixed with oil vapors, and also serves um for balancing the pressure inside the device with atmospheric, which eliminates the breakage of the protective glass 36.

Information sources

1. Nomenclature catalog of products of OJSC Manotom, www. manotom-tmz.ru; manometers showing ship MP - 100 КР, ВП - 100 КР, MVP - 100 КР in the operation manual 5ШО.283.429 РЭ, and also technical conditions - TU 4212-055-00225590-2007, Tomsk, 2007.

2. Ship pressure gauges MKU, technical specifications TU 25-05.1454-79, Moscow, 1979

3. P.A. Stepin. Resistance of materials, 424 p., M., 1968

4. "Pressure gauge", as No. 300790 is a prototype.

Claims (4)

1. A manometer showing a ship containing a cylindrical body, inside of which there is a holder-base, ending with a fitting for connecting to the measured pressure from the outside of the body, a Bourdon tubular spring, which is connected through a rod to a transfer tribo-sector mechanism that converts the movement of the free end tubes in a circular motion of an arrow mounted on the axis of the tribe and located above the dial, and the tribal-sector mechanism contains mechanically connected there are two parallel metal, upper and lower plates, which are rigidly fixed to the base holder, between which the gear sector is mounted in engagement with a tube, on the axis of which a sleeve with an axial hole is inserted, into the slot of which a tension flat spiral spring is fixed, and external to the tribo-sector mechanism, characterized in that, in order to preserve the accuracy of measurements, increase the vibration resistance and reliability of the pressure gauges under shaking conditions, as well as by reducing the impact pulsations of the measured medium to their readings, the tribo-sector mechanism contains a protective restrictive cup in which there is an opening for the passage of the axis of the tribe, which is meshed with the gear sector and the gear inertial disk, and the axis of the tribe and the axis of the gear inertia disk lie in the same plane , and the axis of the tube coincides with the central axis of the pressure gauge, and the tension flat spiral spring located in the protective limit cup is fixed with its inner end in the slot of the sleeve with an axial hole, The sleeve is mounted on the axis of the tribe, and the external end is attached with a pin to the existing hole in the cylindrical wall of the protective limit cup, which is attached to the base holder with screws, and the dial with the central hole through which the free end of the tribe passes to the free end which the index arrow is mounted on, is also screwed to the base holder. 2. The pressure gauge according to claim 1, characterized in that the protective limiting cup protects the tension coil spring during shaking and limits its spontaneous vibrations, reduces the likelihood of breakage of the rigidly fixed ends, in addition, a toothed inertial disk located in the tribal sector mechanism located in meshing with the tribe, which is also meshing with the gear sector, due to their opposite reciprocating rotations balances their rotational inertial moments, which stabilize the position of the pointer on the dial scale and virtually eliminate the amplitude of the oscillations of the pointer, which increases the efficiency of the pressure gauge. 3. The pressure gauge according to claim 1 or 2, characterized in that the stroke of the gear sector is limited within the range of indications by a newly introduced stroke limiter made in the form of a rectangular plate with ends bent downwards, between which the gear sector makes reciprocating movements, and the limiter the course is attached to the upper plate of the tribo-sector mechanism with screws. 4. The pressure gauge according to claim 1, characterized in that, in order to protect the tribo-sector mechanism with the Bourdon tube from the effects of water vapor saturated with salts contained in sea fog mixed with oil vapor, the pressure gauge is equipped with an air filter that is located inside the housing In addition, the air filter serves to balance the pressure inside the manometer with atmospheric, which eliminates the breakage of the protective glass.

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