RU2377514C1 - Alarm pressure gauge - Google Patents

Abstract

FIELD: measuring technology.

SUBSTANCE: invention refers to measuring technology, particularly to alarm pressure gauges, wherein tubular spring of Burdon is flexible element sensitive to pressure of medium. The alarm pressure gauge with Burdon spring consists of the first and the second optical pairs with open radiating channels shut down with shutters, of a constant voltage source, of a unit of indicators of maximal and minimal allowed values of medium pressure and of a unit rotating shutters of optical pairs. Additionally, generators of radiation, a light diode and a photo-receiver of optical pairs, the first and the second correspondingly, are connected to a power source via current limiting resistors, while the receivers of radiation,- photo-receivers- correspondingly of the first and second optical pairs, are also connected with their outputs of power to the power source, while their electrical output is tied to a middle point of correspondingly the first and the second inertia elements, the outputs of which are connected to the first and the second controlled switches, the first outputs of which are connected to inverting outputs, while the second ones are correspondingly connected to non-inverting inputs of the first and the second voltage generators, inputs of which are connected correspondingly to the first outputs of relay winding, while the second outputs of the relay are connected to the power source via the resistors.

EFFECT: expanded operational functionality.

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Description

The invention relates to measuring technique and can be used to create a dial gauge with a node switching external voltages.

Known designs of pressure gauges with switching external voltages, for example DM 2010 Cr manometer. The disadvantage of such and similar pressure gauges described in [1] is the use of mechanical contacts, which are characterized by phenomena such as bounce, burning, as well as the low accuracy of the manometer switch in the indicators of the boundary pressure values.

The use of magnetic preloaded contacts leads to improved switching quality, but also at the same time to even greater loss of accuracy.

Known pressure gauges with limit value sensors [2, 3], which use induction or optical devices for switching external voltages.

A manometer of the A 3000 series was chosen as a prototype [3]. In this pressure gauge, to control the pressure from the lower to the upper setpoints, the movable scroll damper blocks the infrared beam directed at the phototransistor.

The amplified signal from the phototransistor activates a relay with bipolar changeover contacts and a trip occurs. Power is supplied to the relay when the arrow passes the set value from left to right and the power from the relay is removed when only the arrow moves from the corresponding set value. The manometer uses a relay with changeover contacts, which allows you to organize any version of the switching device [4], in addition, the operation of the manometer does not depend on a power outage.

However, this technical solution has several disadvantages, namely:

- When the spiral shutter passes from left to right or vice versa through the optical zone of the slit optical sensor under vibration conditions, the output signal of the slit optical sensor (hereinafter referred to as the sensor) becomes unstable, which can lead to false relay operations.

- In the event of a power failure in the device, a situation of an undefined state of the relay may occur.

The reliability of the device during power outages is not due to the design of the pressure gauge, but the uninterrupted operation of the electronic unit, which reduces the potential reliability of the device.

- Organization of the execution of the switching device by reconnecting the relay contacts to external circuits can lead to unauthorized changes in the switching circuit and errors in the manometer.

In fact, such a solution guarantees only one design of the electrical contact device and limits its versatility

- The device does not have visual observation of the switching process, which makes it difficult to control the process.

The purpose of the technical solution is to increase the reliability of the manometer, including under vibration loads, as well as expanding the functional application due to the versatility of the switching unit and the guaranteed provision of any performance. The technical result is achieved by the fact that in the signal pressure gauge containing the housing, in which the holder assembly with the Bourdon tube inside the housing and the fitting for connecting to the measured pressure from the outside of the housing are fixedly mounted, the Bourdon tube is connected with the free end via a rod with a transmission tribo-sector mechanism transforming the movement of the free end of the tube into a circular motion of an arrow mounted on the axis of the tube and located above the dial, as well as indicators of the boundary values of pressure, set located on the mechanism coaxially with the axis of rotation of the tube and set to the desired pressure values using the mechanism for their movement, installed in the center of the protective glass, hermetically mounted in the case above the dial, as well as the first and second optical gap sensors, which are installed on the indicators of the boundary pressure values , and, accordingly, the first and second radially located sensor blinds, structurally made similarly to the arrows, mounted coaxially with the help of bushings in the center of gravity on the t axis plugs and having an opaque part for controlling the sensors at the end, a leash for moving the curtains, which is fixedly mounted on the tube axis with one end of its radially located part using the attachment unit and makes a circular movement, the same as the arrow, and the second end curved at an angle moves these curtains .

The advantage of the proposed technical solution is that the second curtain is located on an axis above the first so that the vertical distance between the curtains is equal to the height of the sensor, in addition, a flat spiral spring is installed between the curtains so that its center coincides with the axis of the tribe, one end of the spring is fixed on the sleeve of the first curtain, and the second on the opposite opaque part of the end of the second curtain, creating the moment of oncoming movement of the curtains, while there is a gap between the axis of the tube and the axial holes of the bushes, and which interlocks the connection between the tribe and the bushings, and the length from the center to the opaque part of the first curtain is greater than the length of the same part of the second curtain by the width of the sensor, the curtain lead is installed in the corner zone between the first and second curtains so that its attachment point is located on the axis of the tribe below the first curtain its radially located part has a size less than the distance from the axis to the opaque part of the curtain, and the vertical one is sufficient for contacting both curtains, while the first and second sensors are fixedly mounted on the pointer If the limit values are set in such a way that when the curtain enters the sensor slit, they prevent further movement of the curtain and the middle of the sensor slit coincides in height with the opaque part of the curtain, the radiation shapers, LED and photodetector, the first and second gap sensors are also connected to the power source by the power leads, and their output electrical terminals are connected, respectively, to the inputs of the first and second inertial elements, the outputs of which are connected to the midpoint of the first and second controlled switches, first the conclusions of which are connected to the inverting inputs, and the second, respectively, to the non-inverting inputs of the first and second voltage conditioners, the outputs of which are connected, respectively, to the first terminals of the relay windings, and the second conclusions of the relay windings are connected through the resistors to the power source.

To visually observe the switching between the outputs of the voltage conditioners and the power source, the first and second signaling circuits are included, consisting of series-connected signal LEDs and resistors, and these LEDs are mounted on the upper surface of the protective glass. The invention is illustrated by the description of the signal pressure gauge, as well as the electrical circuit (figure 1) and the drawings (figure 2-7) of the inventive signal pressure gauge.

Figure 1 shows the electrical circuit of the signal pressure gauge, which indicates: 1 - a constant voltage source (AC voltage to DC converter); 2 and 3 - the first and second slotted optocouplers (hereinafter referred to as sensors) with open radiating channels; 4 and 5 - the first and second curtains; radiation shapers - LED 6 and a photodetector 7 of gap sensors, respectively, of the first 2 and second 3 are connected to a power source 1 through current-limiting resistors 8 and 9, and radiation receivers - photodetectors 7, of a first 2 and second 3 gap sensors, are also connected by power leads to the power source 1, and their output electrical terminals are connected to the inputs 10, respectively, of the first 11 and second 12 inertial elements, the conclusions 13 and 14 of which are connected to the midpoints a and b of the first 15 and second 16 control switches of switches, the first terminals of which are connected to the inverting inputs 17 and 18, and the second, respectively, to the non-inverting inputs 19 and 20 of the first 21 and second 22 voltage generators, the outputs of which are connected respectively to the first terminals of the relay windings 23, and the second relay terminals are connected through resistors 24 to the specified power source 1.

To control external electrical circuits, the contacts 25 (closed - open) of the relay 23 are connected to the elements 26, 27.

To visually observe the switching between the outputs of the voltage drivers 21 and 22 and the power source 1, the first and second signaling circuits are included, consisting of series-connected signal LEDs VD and resistors R, and these LEDs are fixed on the inner surface of the protective glass 19 (in Fig. 2, conditionally shown).

Introduction to the electrical circuit of controlled switches 15 and 16 allows you to organize 4 combinations of the initial state of the relay 23, corresponding to the requirements of regulatory documents for such devices.

When the blinds 4 and 5 enter or exit into the optical zones of the slit sensors 2 and 3 (Figs. 3, 4) before the steady-state process of their fixation, the output signal may become unstable due to vibration.

Introduction to the electrical circuit (figure 1) inertial elements 11 and 12 will weaken or completely eliminate this disadvantage.

The operation of the circuit is not violated during power failures due to the fact that the mechanical design of the pressure gauge reliably ensures the position of the curtains and prevents the occurrence of an undefined state.

Figure 2 shows a longitudinal section of a signal pressure gauge (hereinafter - pressure gauge).

The designation of the positions of the pressure gauge in figure 2 is not identical to the positions in figure 1 and should be read independently.

Figure 3 shows a fragment of the position of the curtains to overlap; figure 4 - overlap of the optical channels in the gap sensors.

Figure 5-7 shows the functional arrangement of the blinds relative to slot sensors.

The pressure gauge contains a housing 1, in which a fitting 2 is installed, which is part of the holder 3, the Bourdon tube 4, the tribal sector mechanism 5, the tube 6, on the axis of which an arrow 7 is mounted, which rotates by an angle on the dial 8, corresponding to the pressure; the lever 9 for turning the arrows of the pointers 10 and 11 of the maximum and minimum acceptable values of the pressure of the medium, the holder 12 for attaching the dial 8; slotted optical sensors 13 and 14; respectively, the first and second curtains 15 and 16; spiral spring 17, a leash of blinds 18.

For visual observation, switching between the outputs of the first 21 and second 22 voltage conditioners and the power source 1, the first and second, respectively 28 and 29 signaling circuits from the series-connected signal LEDs VD and resistors R (Fig. 1) are turned on, and these signal LEDs are mounted on the inner surface of the protective glass 19 (conventionally not shown).

The pressure gauge device operates as follows (figure 2).

A pressure gauge comprising a housing 1, in which a fitting 2 is installed, which is part of a holder 3 fixed fixed in the housing 1, is installed in the threaded hole of the object and pressure is applied. Under the action of pressure, the Bourdon tube 4 transmits the movement to the tribo-sector mechanism 5, the tube 6, on the axis of which an arrow 7 is installed, which rotates through an angle on the dial 8, corresponding to the pressure. Using the rotation mechanism of the lever 9 to turn the arrows of the pointers 10 and 11, the boundary pressure values are set to the desired position.

The mount of the dial 8 is located on the holder 12 in the non-working zone of the dial 8.

Slit, first 13 and second 14 optical sensors are installed on the indicators of the boundary values 10 and 11, and they are installed so that the first and second shutters, respectively 15 and 16, stop at a pressure of less or more boundary values, blocking the optical channel of the sensors, because rests against the wall (figure 4).

Figure 3 shows the curtains to the overlap of the optical channel, and figure 4 - overlap of the optical channel curtains.

The spiral spring 17 (figure 2) is placed between the shutters 15 and 16 so that its center coincides with the axis of the tribe 6, one end of which is fixed to the non-working end of the first shutter 15, and the second to the sleeve of the second shutter 16, which creates a rotational moment of the shutter aimed at their rapprochement.

The shutter bushes 15 and 16 freely rotate on the axis of the tribe 6, because between the axis of the sleeve and the axis of the tribe 6 there is a gap.

The first curtain 15 (Fig. 4) is located in the optical zone of the first sensor 13 and abuts against its wall and is fixed from the moment created by the coil spring 17, and therefore does not respond to vibration loads.

The leash 18 of the shutters 15 and 16, located between the first 15 and the second 16 shutters, keeps the second 16 shutter from moving to the first 15, caused by the action of the coil spring 17.

The operation of the pressure gauge at zero pressure is illustrated in figure 5.

In this case, the position of the optical sensors 13 and 14 corresponds to some established boundary minimum and maximum values, indicated respectively by A and B.

The leash 18 of the shutters 15 and 16 is opposite the mark “O”. Under the action of the force created by the spring 17, the first curtain 15 is fixed inside the first optical sensor 13, abutting against its wall (figure 4). The second curtain 16, being also under the action of the force of the spring 17, is held by a leash 18 (Fig. 5). The direction of the forces acting on the curtains 15 and 16 is shown by arrows.

The operation of the pressure gauge at a working pressure between position A and B is illustrated in Fig.6. When applying a pressure exceeding the value of A, the leash 18, making a movement to position C corresponding to a given pressure, approaches the first curtain 15 and leads it out of the optical zone of the first sensor 13. At the same time, the second curtain 16 continues to be held by the leash 18 and moves with it .

In the working pressure zone, limited by the boundary value indicators, the shutters 15 and 16 are located next to each other and are separated by a leash 18 between them (Fig. 6).

The operation of the pressure gauge at a working pressure exceeding position B is illustrated in Fig. 7. When applying a pressure exceeding the values of A and B, the leash 18, making movements to the D position corresponding to the given pressure, leads the second curtain 16 into the optical zone of the second sensor 14, the curtain 16 abuts against the wall of the sensor 14 (Fig. 4) and at the same time the gauge force 4 and coil spring 17 is fixed in this position. Vibration is neutralized by the fixed position of the curtain.

Since the first sensor 13 is located above the second curtain 16, the second curtain 16 carried by the lead 18 passes under the first sensor 13 and is fixed by the lead 18 in position D.

Thus, the design of the pressure gauge increases the reliability of control of the state of the optical sensors and prevents the influence of vibration loads on the quality of switching, and also allows you to organize any version of the switching device and visually observe the process of switching.

Information sources

1. Pressure gauges MD2010, MD5010 and others in the book of the author Muleva Yu.V. "Manometers": Production and technical manual, 280 pp., Moscow: MPEI, 2003

2. MANOTHERM Beierfeld GmbH Am Gewerbepark 9. D-08340 Beierfeld Phone: (0 37 74) 58 - 0. Fax: (0 37 74) 58 - 545 manotherm.com. manotherm@t-online.de

3. Contact pressure sensors / manometers Photohelic®, Series A3000, LLC OLIL www.olil / ru El. Email dwver@jlil.ru

4. GOST2405-88.

Claims (1)

A signal pressure gauge comprising a housing in which the holder assembly is fixedly mounted with a Bourdon tube inside the housing and a fitting for connecting to the measured pressure from the outside of the housing, the Bourdon tube with its free end connected by a rod with a transfer tribo-sector mechanism that converts the movement of the free end of the tube into circular movement of the arrow mounted on the axis of the tribe and located above the dial, as well as indicators of the boundary values of the pressures installed on the mechanism coaxially with the axis of rotation of three barrels and pressure values set to the desired readings using the mechanism of their movement, mounted in the center of the protective glass, hermetically mounted in the case above the dial, as well as the first and second optical slot sensors, which are installed on the indicators of the boundary pressure values and, accordingly, the first and second radially located sensor blinds, structurally made similar to the arrow, mounted coaxially with the help of bushes in the center of gravity on the axis of the tribe and having a non-transparent part for controlling slotted sensors at the end, a leash for moving the curtains, which at one end of its radially located part is fixedly mounted on the axis of the tribe using the attachment unit and performs a circular movement, the same as the arrow, and the second end bent at an angle moves these curtains, characterized in that the second curtain is located on an axis above the first, so that the vertical distance between the curtains is equal to the height of the slit sensor, a flat spiral spring is installed between the curtains so that its center coincides it with the axis of the tribe, one end is fixed to the sleeve of the first curtain, and the other end is on the opposite non-transparent part of the end of the second curtain, creating the moment of oncoming movement of the curtains, while there is a gap between the axis of the tribe and the axial holes of the bushings, which prevents the tribes from engaging with the bushings, and the length from the center to the non-transparent part of the first curtain, more than the length of the similar part of the second curtain to the width of the sensor, the lead of the curtains is installed in the corner zone between the first and second curtains so that its attachment point is located on the axis of the trib of the first curtain, its radially located part is smaller than the distance from the axis to the opaque part of the curtain, and the vertical one is sufficient for contacting both curtains, while the first and second gap sensors are fixedly mounted on the boundary value indicators so that when the curtain enters the slit of the optical sensor prevents further movement of the curtain and the middle of the slit of the sensor coincides in height with the opaque part of the curtain, radiation shapers, LED and photodetector of gap sensors, first of the second and second, are connected to the power source through current-limiting resistors, and the radiation receivers are photodetectors, respectively, of the first and second gap sensors, the power leads are also connected to the power source, and their output electrical terminals are connected, respectively, to the conclusions of the first and second inertial elements, the conclusions of which are connected to the midpoints of the first and second controlled switches, the first conclusions of which are connected to inverting inputs, and the second, respectively, to non-inverting inputs the first and second voltage conditioners, the outputs of which are connected, respectively, to the first terminals of the relay windings, and the second terminals of the relay windings are connected through resistors to the power source, while the first and second signaling circuits are included to visually observe the switching between the voltage former outputs and the power source, consisting of series-connected signal LEDs and resistors, and these LEDs are mounted on the inner surface of the protective glass.

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