EA028188B1 - Pressure gauge with an alarm device - Google Patents

Abstract

The proposed pressure gauge with an alarm device comprises a cylindrical body that houses a supporting holder with a union, a tubular Bourdon spring, an indicator dial with a transparent glass, and an alarm device including a frame that carries a transmission pinion-sector mechanism having its tie-rod on the tooth sector linked pivotally to the free end of the tubular Bourdon spring to convert its movements to circular movement of a black real pressure (Pr) telltale pointer secured on the central axle together with the pinion of the mechanism; a first and a second elongated rotatable platforms mounted on a common separate axle, the first one carrying a minimum pressure (Pmin) limiting value sensor, and the second one carrying a maximum pressure (Pmax) limiting value sensor, both sensors being made as microswitches; a green telltale pointer for setting a minimum pressure (Pmin) limiting value, mounted concentrically with the central axle of the black telltale pointer and secured on the first tubular shaft together with the pinion engaged with the upper tooth rim of the first rotatable platform; a red telltale pointer for setting a maximum pressure (Pmax) limiting value, mounted on the second tubular shaft positioned concentrically with the first tubular shaft and having a pinion engaged with the upper tooth rim of the second rotatable platform; a device for setting position of the green and red telltale pointers on the indicator dial and the pressure regulation zone (ΔP=Pmax-Pmin); a first and a second program cams mounted on the central axle of the transmission mechanism and having transfer steps and sunk and protruding profiles that interact with spring-loaded pushers of the microswitches of pressure limiting values (Pmin, Pmax) sensors through double-arm levers on respective rotatable platforms. The novel feature is that the microswitch of the maximum limiting pressure value sensor and the lever arm interacting with its pusher are disposed on the face side of the respective elongated rotatable platform, and both program cams on the central axle of the transmission pinion-sector mechanism are spatially aligned with their sunk profiles; only normally closed contacts of microswitches of both sensors are used in the circuits that turn on and off automatic control; the sunk profile in each program cam has a circumferential length (l) proportional to the trajectory of movement of the real pressure (Pr) telltale pointer over the entire measurement scale on the indicator dial, and each transfer step has a height (h) sufficient to ensure a full working stroke of the respective microswitch pusher.

Description

The invention relates to the field of instrumentation, in particular to pressure gauges having a Bourdon tubular spring, a circular or sector scale, and a signal device with limit value sensors.

A known pressure gauge with a signal device containing a cylindrical body, inside which there is a holder-base, which ends with a fitting for connecting to the medium to be measured from the outside of the body, a Bourdon tubular spring, which is connected via a rod to a gear-sector transfer mechanism that converts the movement of a free of the end of the Bourdon tubular spring in a circular motion of the index arrow of real pressure, fixed on the axis together with the tube and located above the dial m with a scale, and a protective transparent glass having a disk shape and located above the dial with a scale and a real arrow, and a signal device including a shutter mounted on a real arrow, which is made of an opaque material in the form of a thin-walled hollow half-cylinder , the lower base of which is made of a thin-walled round plate, and which is perpendicular to it, and the diameter of the hollow curtain half-cylinder is located along the midline the real arrow of the pressure indicator, and the sensor of the boundary pressure values, optronic or inductive, is located on the pointer arrow of the boundary pressure values, which is located above the curtain and mounted on an axis mounted on the extension of the bracket bracket bracket coaxial to the axis of the tube, and structurally has limitations in setting the values to angle of 180 °, and the base of the bracket is attached with two screws on the front side of the dial outside the working area of the scale [1]. This pressure gauge has the following disadvantages:

firstly, the presence of only one sensor of the pressure limit value in the signal device eliminates the possibility of creating, with an electrical contact, the necessary zone for automatically controlling the necessary pressure in the medium being measured, which greatly reduces the application efficiency (demand) of this pressure gauge;

secondly, a large number of auxiliary mechanical and electrical elements are used in the optocoupler or inductive pressure limiting pressure transducer, which complicates installation work and increases the manufacturing cost of this pressure gauge;

thirdly, the proposed design makes it necessary, when the index arrow is set to the required boundary pressure value, to remove the protective glass, which significantly increases the loss of time, worsens the service conditions, reduces the maintainability and efficiency (demand) of this pressure gauge;

fourthly, optocoupler and inductive sensors are sensitive to the voltage drop in the mains, which negatively affects the reliability of this gauge;

fifthly, the contact of the optocoupler and inductive sensor provides switching of electric circuits only with a low current load of up to 3 mA, which significantly reduces the functionality of this manometer and reduces the possibility of its use.

A pressure gauge with a signal device (with a microswitch) is known, comprising a cylindrical body, inside of which a base holder is installed, which ends with a nozzle for connecting to the medium to be measured from the external side of the body, a Bourdon tubular spring, which is connected through a rod to a tribal sector gear mechanism transforming the movement of the free end of the Bourdon tubular spring into the circular motion of the pointer of the real pressure, fixed on the axis together with the tube and bending above the dial with a dial, and a protective transparent glass having a disk shape and located above the dial with a dial and an arrow, as well as an alarm device including a micro switch mounted on a separate bracket with the possibility of its spring-loaded pusher interacting with the free end of the Bourdon tubular spring when constantly given one boundary value of pressure [2].

This design of the signal device allows you to create the necessary acting force on the spring-loaded pusher of the microswitch with the possibility of reliable operation and providing it with a switching contact in the electrical control circuit with a current load of up to 2 A.

This pressure gauge also has certain disadvantages:

firstly, the presence of only one sensor of the pressure limit value in the signal device excludes the possibility of creating, with an electrical contact, the necessary zone for automatically controlling the necessary pressure in the medium being measured, which greatly reduces the application efficiency (demand) of this pressure gauge;

secondly, the proposed design makes it necessary, when the index arrow is set to the required boundary pressure value, to remove the protective glass, which significantly increases the loss of time, worsens the service conditions, reduces the maintainability and efficiency of the use of this gauge.

A pressure gauge with a signaling device is known, comprising a cylindrical body, inside which a holder-base is installed, which ends with a nozzle for connection to a measured medium, a Bourdon tubular spring hydraulically connected to the nozzle, and a signaling device including a frame, as well as a tribal-sector gear placed on it with the possibility of articulating its thrust on the gear sector with the free end of the Bourdon tubular spring, transforming its movement into a circular engine squeezing a black pointer arrow of real pressure, fixed on the central axis together with the tribe of this mechanism; the first distant and second closest to the dial with upper and lower rims rotary platforms mounted on a common separate axis, and also located on the first of them with a minimum sensor, and on the second with a sensor of maximum boundary pressure values, each of which is made in the form of a micro switch with an acting on its pusher with an intermediate element and the possibility of using its contacts in electrical control circuits of objects; a green direction arrow to set the minimum pressure limit value, mounted on the first tubular shaft located concentrically to the central axis of the black index arrow, with a tube kinematically connected to the upper rim of the first rotary platform, and a red indicator arrow to set the maximum pressure limit value, mounted on the concentric first a second tubular shaft with a tube kinematically connected with the upper rim of the second rotary platform; the adjuster of the zone of regulation of the necessary pressure in the form of a spring-loaded rod located outside the working area of the dial with a fixed tube at its rear end to provide alternate kinematic communication with the lower crowns of the first and second rotary platforms, as well as with a slot in the front end for a screwdriver with holes made for it in the dial and protective transparent glass; the first and second, located on the axis of the transmission tribo-sector mechanism of the black index arrow, program cams with recessed and protruding profiles, transition steps and locking screws, as well as interacting with them, located on individual axes similarly on the first and second rotary platforms, respectively, the first and second levers, each of which is configured to provide contact of the roller at the free end with the recessed and protruding profiles of the corresponding program pool point, as well as the lever contact directly with the spring-loaded plunger of the microswitch of the pressure limit value sensor on the corresponding rotary platform [3].

This gauge uses microswitches with the ability to close and open their contacts with electrical control circuits with a current load of up to 5 A. And this gauge has disadvantages:

firstly, if there is a large space inside the upper part of the case, its lower part is structurally overloaded, as a result of which this pressure gauge is bulky, has relatively large dimensions (in thickness), weight and metal consumption, which significantly reduces the possibility of its use (demand );

secondly, the proposed design made it necessary to place the microswitch of the maximum pressure limit switch (Pmax) on the back of the turntable, as a result of which access to it was very complicated, and when replacing the microswitch that often comes out during operation, the protective glass must be removed, black, green, red arrows, and then restore them into place and carry out unscheduled fine-tuning, which significantly increases the loss of time on installation day work and worsens the conditions of service, significantly reduces the maintainability and effectiveness of the use of this pressure gauge;

thirdly, both program cams on the axis of the transfer tribo-sector mechanism are made with oppositely recessed recessed profiles and spatially aligned only with the left transition step of the first program cam and the right transition step of the second program cam with the possibility of providing automatic control of various objects by standard application in the circuit its inclusion of the generally accepted normally open contact of the microswitch of the sensor of the minimum boundary value d phenomena (Ртш), and in the circuit of its disconnection, the use of a normally closed contact of the sensor micro switch of the maximum pressure limit value (Pmax), while the above normally open contact is in a predominantly long closed position, and its pusher is in a loaded and recessed position, including non-working time and during storage in the warehouse of the pressure gauge, which greatly reduces elasticity and accelerates the failure of the return spring of the pusher, significantly reduces the durability of the micro switch, о reduces the reliability and performance of this pressure gauge and the effectiveness of its use (see explanatory drawing in the Appendix);

fourthly, in each program cam, the transition step is made rectilinear and with sharp protruding ends, creating jerks when interacting with rollers of two-arm levers, increasing resistance and counteracting force for the Bourdon tubular spring, as well as its hard operating mode with a significant decrease in durability, a significant a decrease in the reliability, performance and efficiency of the use of this pressure gauge (see explanatory drawing in the Appendix). A known pressure gauge with a signaling device comprising a cylindrical body, inside of which a base holder is installed, which ends with a fitting

- 2 028188 for connecting to a medium, a Bourdon tubular spring hydraulically connected to the fitting, and a signal device including a frame, as well as a tribal sector gear mounted on it with the possibility of articulating its rod on the gear sector with the free end of the tubular Bourdon springs, transforming its movement into a circular motion of the black pointer arrow of real pressure, fixed on the central axis together with the tribe of this mechanism; the first distant and second closest to the dial with upper and lower rims elongated rotary platforms mounted on a common separate axis, and also located on the first of them with a minimum sensor, and on the second with a sensor of maximum boundary pressure values, each of which is made in the form of a microswitch with an intermediate element acting on its pusher and the possibility of using its contacts in electrical control circuits of objects; a green direction arrow to set the minimum pressure limit value, mounted on the first tubular shaft located concentrically to the central axis of the black index arrow, with a tube kinematically connected to the upper rim of the first rotary platform, and a red indicator arrow to set the maximum pressure limit value, mounted on the concentric first a second tubular shaft with a tube kinematically connected with the upper rim of the second rotary platform; the adjuster of the zone of regulation of the necessary pressure in the form of a spring-loaded rod located outside the working area of the dial with a tube fixed at its rear end to provide alternate kinematic communication with the lower crowns of the first and second rotary platforms, as well as with a slot in the front end for a screwdriver with holes made for it in the dial and protective transparent glass; the first and second, located on the axis of the transmission tribo-sector mechanism of the black index arrow, program cams with recessed and protruding profiles, as well as interacting with them, located on individual axes similarly on the first and second rotary platforms, respectively, the first and second two-arm levers, each of which is made with the possibility of contacting the roller on one of its shoulders with the recessed and protruding profiles of the corresponding program cam, as well as the contact of the free end and his other shoulder through an intermediate acting element with a spring-loaded plunger of the microswitch of the sensor of the boundary pressure value on the corresponding rotary platform [4].

This pressure gauge is more compact (smaller in width), due to the use of elongated rotary platforms and elongated two-arm levers, as well as microswitches with the ability to function and provide them with switching contacts in electrical control circuits with a current load of up to 5 A.

It is the closest to the proposed invention in its technical essence and the achieved result.

However, it also has disadvantages:

firstly, with the proposed design, the microswitch of the maximum pressure limit value sensor (Pmax) and the lever arm interacting with its pusher are also located on the back of the elongated turntable, which makes access to them very difficult, and often replacing In the process of operating this microswitch, it is first of all necessary to remove the protective glass, black, green, red directional arrows again, and then restore them to their place perform fine tuning forced unscheduled, significantly increases the loss of time for assembly and adjustment work and degrades service conditions substantially reduces the maintainability and efficiency of application (demand) of the gauge;

secondly, both program cams on the axis of the transmission triboscope mechanism are also made with oppositely recessed recessed profiles and spatially aligned only with the left transition step of the first program cam and the right transition step of the second program cam with the possibility of providing automatic control of various objects by standard application in the circuit of switching on the generally accepted normally open contact of the microswitch of the sensor of the minimum boundary value pressure (Ртш), and in the circuit of its disconnection the use of a normally closed contact of the micro switch of the maximum pressure limit switch (Рах), while the above normally open contact is in a predominantly long closed position, and its pusher is in a loaded and recessed position, including during non-working hours and during storage in the warehouse of the pressure gauge, which greatly reduces elasticity and accelerates the failure of the return spring of the pusher, significantly reduces the durability of the microswitch significantly reduces the reliability and performance of this pressure gauge and the effectiveness of its use (see explanatory drawing in the Appendix);

thirdly, in each cam, the transitional stage is also made rectilinear and with sharp protruding ends, creating jerks when interacting with rollers of two-arm levers, increasing resistance and counteracting force for a Bourdon tubular spring, its rigid mode of operation with a significant decrease in durability, a significant decrease in reliability performance and efficiency of the application (demand) of this pressure gauge (see explanatory drawing

- 3 028188 in the Appendix).

The objectives of this invention are to improve maintainability and service conditions, increase the durability and switching ability of the proposed pressure gauge, increase the reliability, availability and efficiency of its use.

These problems are solved due to the fact that in the proposed pressure gauge with a signal device containing a cylindrical body, inside which there is a base holder that ends with a nozzle for connecting to the medium being measured, a Bourdon tubular spring hydraulically connected to the nozzle and a signal device including the frame itself, as well as the gear-sector gear located on it with the possibility of articulating its thrust on the gear sector with the free end of the Bourdon tubular spring, is predominantly azuyuschim moving it in a circular motion black directional arrow real pressure (Pr) is fixed on the central axis together with the pinion of the mechanism; the first distant and second closest to the dial with upper and lower rims elongated rotary platforms mounted on a common separate axis, as well as located on the first of them with a minimum sensor (Ptt), and on the second with a sensor of maximum (Pmax) boundary pressure values, each which is made in the form of a microswitch with an intermediate element acting on its pusher and the possibility of using its contacts in electrical control circuits of objects; a green direction arrow to set the minimum pressure limit value (PTT), mounted on the first tubular shaft located concentrically with the central axis of the black index arrow, with a tube kinematically connected to the upper rim of the first rotary platform, and a red indicator arrow to set the maximum pressure limit value (Pt) fixed on a concentric to the first second tubular shaft with a tube kinematically connected with the upper rim of the second rotary platform; the adjuster of the zone for regulating the necessary pressure (ДР = Рах-Ртт) in the form of a spring-loaded rod located outside the working area of the dial with a fixed tube at its rear end to provide alternate kinematic communication with the lower crowns of the first and second rotary platforms, as well as with a slot in the front end for a screwdriver with holes made for it in the dial and protective transparent glass; the first and second, located on the axis of the transmission triboscopic mechanism of the black index arrow, program cams with recessed and protruding profiles, transition steps and locking screws, as well as interacting with them, located on individual axes similarly on the first and second rotary platforms, respectively, the first and second two shoulders levers, each of which is made with the possibility of contacting the roller on one of its shoulders with recessed and protruding profiles of the corresponding software of the cam, as well as the contact of the free end of its other arm through an intermediate acting element with a spring-loaded plunger of the microswitch of the pressure limit value sensor on the corresponding rotary platform, in accordance with the invention, the micro switch of the maximum pressure limit value sensor (Pmax) and the lever arm interacting with its pusher are located on the front side of the corresponding elongated turntable with the possibility of providing free and accelerated access to him, and both software cams of the spatial located on the axis of the transfer tribo-sector mechanism are combined with their recessed profiles, as well as left and right transition steps, with the possibility of providing automatic control of the system for stable maintenance of the necessary pressure in the measured medium in a more stable and gentle operating mode of microswitches, by applying only normally closed contacts of the sensor microswitches in the switching circuit and the switching circuit of automatic control respectively, the minimum (Ptt) and maximum (Pmax) boundary pressure values, with increased current transmission and switching abilities, their predominantly long closed position and unloaded spring-loaded pushers, and in each program cam the recessed profile is made with a circumferential length (1) proportional to the trajectory of movement of the black index arrow of the real pressure (Pr) along the entire measuring scale, and each transition step is made sinusoidal with rounded and ends and height (s) sufficient to ensure the working stroke of the spring-loaded plunger of the corresponding microswitch and the possibility of providing smooth, without jerking interaction of the rollers of the two-arm levers, as well as a significant reduction in resistance and opposing force for the Bourdon tube spring.

Based on the above data and comparison of the claimed object with analogues and prototype, it can be seen that the proposed technical solutions meet the criterion of inventive step and are new, and their industrial applicability is confirmed by the detailed description below of the constructive implementation of the proposed manometer and the principle of its operation.

In FIG. 1 shows a General view of the proposed pressure gauge with a signal device; in FIG. 2 is the same, view A in FIG. one; in FIG. 3 is the same, section BB in FIG. 2;

in FIG. 4 - structural design of the signal device;

in FIG. 5 - placement of tubular shafts of green and red arrows on the axis of the black arrows, the breakout In

- 4 028188 in FIG. 4;

in FIG. 6 - interaction of the roller of the two shoulders of the lever with the recessed profile of the software cam and its second free shoulder with an intermediate acting element of the microswitch of the pressure limit value sensor;

in FIG. 7 is a diagram of the positional arrangement of the rollers of both two shoulders of the levers on the recessed profiles of the respective program cams before starting to align ahead of the black index arrow of the real pressure (Pg) with the green pointer arrow of the minimum boundary pressure value (Pts);

in FIG. 8 is a kinematic diagram of the proposed pressure gauge.

The proposed pressure gauge with a signal device comprises a cylindrical body 1, inside which a holder-base 2 is installed, which ends with a nozzle 3 for connecting to the medium 4, a Bourdon tube spring 5, hydraulically connected to the nozzle 3, and a signal device 6, including a frame 7 , as well as the tribo-sector gear mechanism 8 mounted on it with the possibility of articulating its thrust 9 on the gear sector 10 with the free end of the Bourdon tube spring 5, transforming its movement into cr black pulling movement of the arrow 11, the actual pressure (Pr) is fixed to the central axis 12 together with the pinion 13 of the mechanism; the first 14 is distant and the second 15 closest to the dial 16 with upper and lower rims are elongated rotary platforms mounted on a common separate axis 17, and also located on the first of them with a minimum sensor 18 (Ptsh), and on the second with a maximum sensor 19 (Pts) boundary pressure values, each of which is made in the form of a microswitch 20 with an intermediate element 22 acting on its pusher 21 and the possibility of using its contacts in electrical control circuits of objects; a green pointer arrow 23 for setting the minimum pressure limit value (Pct), mounted on a concentric central axis 12 of the black pointer arrow 11 of the first tubular shaft 24 with a tube 25 kinematically connected with the upper crown of the first rotary platform 14, and a red pointer arrow 26 for installation the maximum boundary value of pressure (Pmax), mounted on a concentric to the first 24 second second tubular shaft 27 with a tube 28, kinematically connected with the upper rim of the second rotary th platform 15; the adjuster 29 of the zone of regulation of the necessary pressure (DR = Rtakh-Rtsh) in the form of a spring-loaded rod 30 located outside the working zone of the dial 16 with a fixed tube 31 at its rear end to provide alternate kinematic communication with the lower crowns of the first 14 and second 15 rotary platforms, and also with a slot 32 in the front end for a screwdriver (not shown) with holes 33 made for it in the dial 16 and 34 of the protective transparent glass 35; the first 36 and second 37, located on the axis 38 of the transmission tribo-sector mechanism 8 of the black index arrow 11, program cams with recessed 39 and protruding 40 profiles, transitional steps 41 and locking screws 42, as well as interacting with them, located on individual axes 43 , 44 similarly on the first 14 and second 15 elongated turntables, respectively the first 45 and second 46 two-arm levers, each of which is made with the possibility of contact of the roller 47 on one of its shoulders with recessed 39 and protruding 40 profiles of the corresponding software cam 36 (37), as well as the contact of the free end of its other shoulder through an intermediate acting element 22 with a spring-loaded pusher 21 of the microswitch 20 of the pressure sensor 18 (19) of the pressure limit value on the corresponding rotary platform 14.15 (Figs. 1-7) . This pressure gauge is quite compact and in it the microswitch 20 of the gauge 19 of the maximum pressure limit value (Pmax) and the lever arm 46 interacting with its spring-loaded pusher 21 are located not on the back, but on the front side of the elongated turntable 15, so that it was possible to provide free and accelerated access to it, do not remove the black 11, green 23 and red 26 directional arrows, as well as dial 16, which can significantly reduce the time spent on installation and commissioning, improve service conditions to increase maintainability and efficiency of use (demand) of this pressure gauge (Fig. 3, 4).

In addition, both program cams 36, 37 located on the axis 38 of the transfer tribo-sector mechanism 8 are spatially aligned with their recessed profiles 39, as well as the left and right transition steps 41, with the possibility of providing automatic control of the system for stable maintenance of the required pressure in the medium being measured in more stable and gentle operation of microswitches, by applying only normally closed contacts 48.49 mic in the switching circuit and the switching circuit of this automatic control switch 20 sensors 18, 19, respectively, the minimum (Ptsh) and maximum (Pts) boundary pressure values, with increased current transmission and switching capabilities, as well as their predominantly long closed position and unloaded spring-loaded pushers 21, which makes it possible to significantly increase the operability and efficiency of use (demand) of the proposed pressure gauge (Fig. 7, 8).

To ensure automatic control of the system for stable maintenance of the required pressure in the medium 4, two switching circuits are used: the first for starting the preparatory

- 5 028188 preliminary cycle with the use of a standard normally open contact, for example, the START button, in the relay power circuit, and the second to start a steady duty cycle using, in contrast to the first circuit, a non-standard normally closed contact, for example 48 microswitch 20 of the sensor 18 the minimum boundary value of pressure (Рш1и) in the starter power supply circuit, which guarantees the gentle operation of the proposed pressure gauge.

And also two trip circuits are used with the use of standard normally closed contacts, for example, in the first - STOP buttons, and in the second - 49 microswitches 20 of the sensor 19 of the maximum pressure limit value (Pmax).

Moreover, the elongated rotary platforms 14, 15 made it possible to place microswitches 20 with increased current transmission capacity in the upper free zone of the housing 1, so that their contacts could be used in power circuits directly of electromechanisms and devices with high current load without additional use of intermediate electrical elements ( relay, etc.) and wiring materials (wires, etc.), which significantly expands the functionality of the proposed pressure gauge and increases the efficiency ktivnost its application (demand).

Moreover, in each program cam 36, 37, the recessed profile 39 is made with a circumferential length (1) proportional to the trajectory of movement of the black index arrow 11 of real pressure (Pr) along the entire measuring scale 50, and each transition step 41 is sinusoidal with rounded ends and heights (i) sufficient to ensure the working stroke of the spring-loaded plunger 21 of the corresponding microswitch with the possibility of smooth, without jerking interaction of the rollers 47 of the two-arm levers 45, 46, and also essential th resistance decrease and counteracts the spring force to the Bourdon tube, which guarantees a steady gentle s operation and increasing the durability, and improved reliability, efficiency and effectiveness of (demand) of the proposed gauge (FIGS. 6, 7).

The required pressure control zone (DR = Ptm-Ptm-Pt1p), indicated by the location on the dial 16 of the green pointer 23 of the minimum (Ptm) and red pointer 26 of the maximum (Ptm) boundary pressure values, as well as the positional position in the initial position on the recessed profiles 39 software the cams 36, 37 of the rollers 47 of the two shoulders of the levers 45, 46, respectively, of the above arrows, makes it possible to create a pause sufficient to ensure a stable position of normally closed contacts in advance 48, 49 microswitches 20 sensors 18, 19 pressure limits (Ptm, Pt) after they open and close without bounce, excessive sparking and burning, which significantly increases the switching capabilities of these microswitches, additionally guarantees them sparing operation and increased durability, increasing reliability , health and effectiveness of the application (demand) of the proposed pressure gauge (Fig. 7, 8).

The kinematic scheme consists of the following separate kinematically interconnected groups of mechanisms of the proposed pressure gauge: the first rotary platform 14 kinematically connected with the green pointer arrow 23 of the minimum boundary pressure value (PTT) and the adjuster 29 of the corresponding pressure; the second rotary platform 15, kinematically connected with the red pointer arrow 26 of the maximum boundary pressure value (Pmax) and periodically with the same common setpoint 29 of the corresponding pressure; tribo-sector mechanism 8, kinematically connected with a Bourdon tube spring 5, black pointer arrow 11 of real pressure (Pr) and program cams 36.37; a two-arm lever 45 on the turntable 14, kinematically connected with the pusher of the micro-switch 20 of the sensor 18 of the minimum boundary pressure value (Ptt) jointly located on this platform through the free shoulder of this lever, and also with the program cam 36 through the roller 47 on its other arm, positioned in the initial position on the recessed profile 39 of this cam, corresponding to the set position of the green pointer 23 on the dial 16; a two-arm lever 46 on the turntable 15, kinematically connected with the microswitch 20 of the maximum pressure limit sensor 19 (Pmax) jointly located on this platform through the free arm of this arm, and also with the program cam 37 through the roller 47 on the other arm of the same arm located positionally in the initial position on the recessed profile 39 of this cam, corresponding to the specified position of the red pointer arrow 26 on the dial 16; at the same time, all these groups together represent a tracking system for the movement of the black index arrow 11 of the real pressure (Pr) and for fixing its combination alternately with the green 23 and red 26 of the index arrows of the boundary pressure values, respectively, of the minimum (Pm) and maximum (Pm) control zone ( AR = Rtakh-RTt) with the use of normally closed contacts 48, 49 microswitches 20, respectively, sensors 18.19 for automatic control of various objects and technological processes, including stable maintaining the necessary pressure in the medium 4, and in a stable gentle operation of these microswitches and the Bourdon tube spring 5

- 6 028188 (Fig. 8). The proposed pressure gauge works as follows.

After connecting the nozzle 3 to the medium 4 to be measured in the pressure gauge, immediately on the dial 16 it is necessary to set, in accordance with the regulation zone of the required pressure (ДР = Ршах-Ртш), the green arrow 23 on the reading in the measuring scale 50, corresponding to the minimum boundary value of pressure (Ртш), and the red index arrow 26 - to the indication in the measuring scale 50, corresponding to the maximum boundary value of pressure (Рах).

To do this, a screwdriver (not shown) is passed through the hole 34 in the protective glass 35 and its end part is placed in the slot 32 at the front end of the spring-loaded rod 29 and rotate it left or right when setting the maximum pressure limit value (Pmax), and when installing of the minimum boundary value of pressure (Ртш), it is first necessary to first recess the spring-loaded rod 29 before its tribe 30 comes into interaction with the lower crown of the platform 14, and then rotate it.

First, with the help of a spring-loaded rod 29 and a tribe 30 on it, interacting with the lower gear ring of the platform 14, it is rotated around the axis 17 with a two-arm lever 45 and a sensor 18 of the minimum boundary pressure value (Pct), and the upper gear ring on the platform 14 simultaneously with the help of the tribe 25 and the tubular shaft 24, rotates on the dial 16 the green pointer 23 corresponding to the above indication by a certain angle with the possibility of outstripping the black pointer arrow 11 with an increase in real pressure (Pr), while the two-arm lever 45 synchronously rotates by the same angle and its roller 47 is positioned on the recessed profile 39 of the program cam 36 with the possibility of also anticipating its interaction with the protruding profile 40.

Then, using a spring-loaded rod 29 and a tribe 30 on it, interacting with the lower gear ring of the platform 15, it is rotated around the axis 17 with a two-arm lever 46 and a maximum pressure limit sensor 19 (Pmax), and the upper gear ring on the platform 14 is simultaneously with the help of the tribe 28 and the tubular shaft 27 performs a similar rotation of the red index arrow 26 at a certain angle, with the possibility of lagging its interaction with the black index arrow 11 with an increase in real pressure (Pr), at This two-arm lever 46 synchronously rotates the same angle and its roller 47 is positionally positioned on the recessed profile 39 of the software cam 37 with the possibility of its delayed interaction with the protruding profile 40.

Since the black pointer arrow 11 is predominantly (during working and non-working hours, as well as during storage of the pressure gauge in the warehouse) located below the zone for regulating the required pressure (DR = Ptakh-Ptsh), then in this situation the rollers 47 of the two-arm levers 45, 46 in the area of recessed profiles 39 program cams 36, 37, spring-loaded pushers 21 microswitches 20 sensors 18, 19 boundary values of the minimum (Ptsh) and maximum (Pts) pressure in the initial extended upper unloaded position, and their normal but closed contacts 48,49 in the initial closed position that guarantees them steady gentle mode of operation and a significant increase in the durability, increased reliability, availability and efficacy (demand) of the proposed gauge.

Moreover, the zone of pressure control on the scale 50 for the medium 4 to be measured can be set different, depending on production and technological need, but not equal to zero or a little more, because in this situation, the green 23 and red 26 are the directional arrows on the dial 16 will be aligned, and the rollers 47 of the two-arm levers 45, 46 located on the recessed profiles 39 of the cams 36, 37 will also be positionally aligned, thereby eliminating the possibility of creating a pause sufficient to ensure good temporary stable position of normally closed contacts 48, 49 microswitches 20 sensors 18, 19 boundary values (Pt1n, Ptakh) pressure in the process of opening and closing, so these contacts will be in a state of continuous strong bounce, excessive sparking and burning, leading to indispensable failure of the pressure gauge.

If on the scale 50 the black pointer arrow 11 of the real pressure (Рг) in the medium 4 is below the control zone (ДР = Рах-Ртш), and the rollers 47 of the two-arm levers 45, 46 will be positionally in interaction with the recessed profiles 39 of the program cams 36 37 with unloaded and extended spring-loaded pushers 21 microswitches 20 sensors 18, 19 pressure limits (Ptsh, Ptakh), normally closed contacts 48, 49 microswitches of these sensors will be in the initial closed position in the switching circuit and the open circuit li ne and ready to provide automatic control system stably maintain the required pressure in the measured medium 4, but it is necessary to launch the said system.

To do this, click on the Start button of the system, after which its normally open contact closes and the relay turns on, in which the first (self-blocking) normally open contact of this relay closes, connected in parallel to the normally open contact of the button, and the second same contact in the circuit readiness for automatic control, therefore immediately, since normally closed contacts 48,49 of microswitches 20 of sensors 18, 19 are closed, the starter is switched on, in which its first is closed similarly (self-locking a normally open contact connected in parallel to the normally closed contact 48 of the microswitch 20 of the sensor 18 in the automatic control circuit with a large current load of up to 10 A, and the other three normally open contacts closed in the power circuits of the electric motor, which, together with the rest of the electrical equipment, are closed against overload and short circuit by means of a circuit breaker.

After that, the electric motor puts the pump into working condition and with its help pumping and pressure increase in the medium being measured 4 are carried out.

As a result of the increase in pressure in the measured medium 4, the bourdon tube spring 5 gradually begins to unbend, and its free end by means of the thrust 9 rotates the gear sector 10 of the transfer tribo-sector mechanism 8, its axis 38 and program cams 36.37 fixed to this axis, while the gear sector 10 of this mechanism, in turn, synchronously rotates the tribe 13, the axis 12 and the black index arrow 11 in proportion to the increase in real pressure (Pr), overcoming the force of the return coil spring 51 for this arrow.

When the black index arrow 11 on the scale 50 of the dial 16 reaches the reading coinciding with the green pointer arrow 23 of the preset minimum pressure limit value (Pct), synchronously, the transition cam 41 moves up from the recessed 39 to the recessed 40 profile of the roller 47 on the end of one shoulder of the lever 45 and lowering the other shoulder, which through the acting intermediate element 22 immerses the spring-loaded pusher 21 of the microswitch 20 of the sensor 18 of the minimum boundary pressure value (Rshsh), the normally closed contact 48 of the microswitch advance instantaneously forcedly opened without arcing, because it is connected to another previously closed normally open contact actuator, the pump continues pumping and increase the pressure in the measured medium 4.

In the course of the increase in real pressure (Рг), the black pointer arrow 11 continues to turn clockwise and when the reading on the scale 50, which coincides with the reading of the red pointer arrow 26, sets the required maximum pressure limit value (Pmax), the transition along the transition stage is delayed 41 of the program cam 37 from the recessed 39 to the protruding profile 40 of the roller 47 at the end of one shoulder of the lever 46 and lowering the end of its second shoulder, which is through the acting intermediate element 22 heats the spring-loaded plunger 21 of the microswitch 20 of the sensor 19 of the maximum pressure limit value (Pmax), while the normally closed contact 49 of this microswitch is forced to instantly open without strong sparking in the system shutdown circuit, as a result of which the starter and electric motor are disconnected, and the pump stops pumping and increasing the pressure in the measured medium 4.

Since the transition steps 41 are made with rounded ends, the rollers 47 of the two-arm levers 45,46 move smoothly without jerking, as well as with a significant decrease in resistance and opposing force for the Bourdon tubular spring, which guarantees it a stable gentle operation and increased durability, and also a significant increase in the reliability, availability and efficiency of the application (demand) of the proposed pressure gauge.

If a real pressure (Pr) decreases in the medium 4 being measured, then immediately under the action of the return spring 51, the black pointer arrow 11 starts to turn in the opposite direction, and the software cams 36, 37 also synchronously rotate, while in the process of moving them first the roller 47 of the two shoulders of the lever 46 smoothly advances along the transition stage 41 from the protruding 40 onto the recessed 39 profile of the program cam 37, releasing the spring-loaded pusher 21 microswitch 20 of the maximum limit sensor 19 pressure value (Pmax), completely removing the load from it and returning to the initial extended upper position, as well as returning normally closed contact 49 of this microswitch completely to its original closed position without sparking, preparing the starter for re-starting.

Then, in the direction of travel, the roller 47 of the two shoulders of the lever 45 with delay retreats smoothly along the transition stage 41 from the protruding 40 to the recessed 39 profile of the program cam 36, releasing the spring-loaded plunger 21 of the microswitch 20 of the sensor 18 of the minimum pressure limit value (Pct), removing the load from it and returning to the initial extended upper position, and also instantly returning to the initial closed position without strong sparking, the normally closed contact 48 of this microswitch, which is immediately similar to the above to the newborn, gives a command to restart the Starter, which, similarly to the above, immediately self-locks the specified contact 48, and also turns on the Electric Motor and Pump.

This without rattling, strong sparking and burning normally closed contacts 48, 49 of the microswitches 20 of the above sensors 18, 19, significantly increases their switching ability and durability, which additionally guarantees them a sparing mode of operation, increased reliability, performance and efficiency of the application (demand) of the proposed pressure gauge .

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Then everything repeats, automatically ensuring stable maintenance of the required pressure in the measured medium 4 in a given adjustable zone (LR = Ptm-Pt1i), while the most critical actuators, the Bourdon tubular spring and microswitches, work in a fairly stable gentle mode, which guarantees them significant increased durability, a significant increase in reliability, availability, efficiency, application (demand) of the proposed pressure gauge.

Based on the foregoing, it can be seen that the proposed pressure gauge compares favorably with known similar pressure gauges, since it is more compact, convenient in maintenance, repair and commissioning, has large current transmission and switching capabilities, a fairly stable gentle operation, increased durability, reliability and performance, therefore can be widely used not only for simple use, but also for the automatic control of various objects and technological processes in all industries x industry.

Information sources.

1. Patent for the invention of KI 2390739 C1, MKI O01 7/04, 02.27.2009

2. Patent for the invention of OV 2276453 A, MKI O01 7/04, 03/23/1996

3. Catalog of the German company SH1VKOS, subsection 08 (Measuring instruments with built-in microswitches), Internet site \\ l \ l \ / mu_gosk.be.

4. Eurasian application for invention No. 201500006/26, MKI 6011. 07/04, 10.30.2015.

Appendix to the sources of information [3, 4]

Note. For the convenience of comparing the design and spatial location of the software cams in the analogue [3] and prototype [4], the reference designations on them are made similarly in the claimed object: 14 - the first and 15 - the second platform, rotatable on the axis 17; 18 a sensor of the minimum boundary value of pressure (Ptt) on the platform 14, and 19 - a sensor of the maximum boundary value of pressure (Ptm) on the platform 15; 20 - microswitch with a spring-loaded plunger 21 and an intermediate element 22 acting on it for each sensor 18, 19; 36-first and 37-second program cams located on the axis 38 of the tribo-sector mechanism; 39 - recessed and 40 - protruding profiles on the first program cam 36, as well as oppositely located 39 - recessed and 40 - protruding profiles on the second program cam 37; spatially aligned left on the first cam 36 and right on the second cam 37 transitional steps 41, which are rectilinear with sharp ends, as well as the rest on these cams not combined similar steps 41; 42 - locking screws on the fists 36, 37 for fixing them on the axis 38 in the required position; 43, 44 - individual axes on the platforms 14, 15 for two-arm levers 45, 46, respectively, in which the roller 47 on one shoulder of the lever 45 is kinematically connected mainly with the protruding profile 40 of the cam 36, and its second free shoulder acts through the intermediate element 22 on the spring-loaded the pusher 21 of the microswitch 20 of the sensor 18 of the minimum pressure limit value (PTT), leaving it in the recessed loaded position, and the normally open contact 48 of this microswitch in the forced closed position is mainly for a long time (during working and non-working hours, as well as during storage of the pressure gauge in the warehouse) in the automatic control switching circuit with accelerated loss of spring return elasticity on this pusher, and the roller 47 on one shoulder of the lever 46 is kinematically connected mainly with the recessed profile 39 of the cam 37, and its second free shoulder acts through an intermediate element 22 on the spring-loaded plunger 21 of the microswitch 20 of the sensor 19 of the maximum pressure limit value (Pmax), leaving it in the extended unloaded position, but The closed contact 49 of this microswitch in the initial closed position is predominantly long (during working and non-working hours, as well as when the pressure gauge is stored in the warehouse) in the automatic control disconnection circuit with a longer preservation of the elasticity of the return spring of this pusher.

The drawing shows the location of the rollers 47 of the two shoulders of the levers 45, 46 on the cams 36, 37 respectively according to the placement on the dial 16 of the black arrow 11 of the real pressure (Pr) in the pre-launch position for the switching process, i.e. before the beginning of its leading combination with the green arrow 23 of the minimum boundary value of pressure (PTT) and synchronous with leading movement

- 9 028188 of the roller 47 of the two shoulders of the lever 45 from the protruding 40 to the recessed 39 profile of the cam 36 through the corresponding transition stage 41, accompanied by sharp jerks at its sharp ends and opening of the normally closed normally open contact 48 of the sensor 18, as well as with the subsequent placement of the arrow 11 in the finish positions for the switching process, i.e. after it, with the delay of combining with the red arrow 26 the maximum pressure limit value (Pmax) and synchronous with the delay of the movement of the roller 47 of the two shoulders lever 46 from the recessed 39 to the protruding 40 profile of the cam 37 through the corresponding transition stage 41, similarly with sharp jerking at its sharp ends and opening normally closed contact 49 of the sensor 19, stopping the injection of pressure into the medium, and the resumption of injection will begin after the return of the arrow 11 and the rollers 47 of the two shoulders levers 45, 46 to the pre-start position of the switching process.

Claims (1)

CLAIM A pressure gauge with a signal device, comprising a cylindrical body, inside which a holder-base is installed, which ends with a nozzle for connecting to the medium to be measured, a Bourdon tubular spring hydraulically connected to the nozzle, and a signal device that includes a frame, as well as a transfer tribock -sector mechanism with the possibility of articulating its thrust on the gear sector with the free end of the Bourdon tubular spring, transforming its movement into a circular motion of black the tangent arrow of real pressure (Pr), fixed on the central axis together with the tribe of this mechanism; the first distant and second closest to the dial with upper and lower rims elongated rotary platforms mounted on a common separate axis, as well as located on the first of them with a minimum sensor (Ptsh), and on the second with a sensor of maximum (Pmax) boundary pressure values, each which is made in the form of a microswitch with an intermediate element acting on its pusher and the possibility of using its contacts in electrical control circuits of objects; a green direction arrow to set the minimum pressure limit value (Ртш), mounted on the first tubular shaft located concentrically with the central axis of the black index arrow, with a tribe kinematically connected to the upper rim of the first rotary platform, and a red direction arrow to set the maximum pressure limit value (Pt) fixed on a concentric to the first second tubular shaft with a tube kinematically connected with the upper rim of the second rotary platform; the adjuster of the zone for regulating the required pressure (AR = Rtakh-RTt) in the form of a spring-loaded rod located outside the working zone of the dial with a fixed tube at its rear end to provide alternate kinematic communication with the lower crowns of the first and second rotary platforms, as well as with a slot in the front end for a screwdriver with holes made for it in the dial and protective transparent glass; the first and second, program cams with recessed and protruding profiles, transition steps and locking screws, located on the axis of the transmission tribo-sector mechanism of the black index arrow, as well as interacting with them, located on individual axes similarly on the first and second rotary platforms, respectively, the first and second two shoulders levers, each of which is made with the possibility of contacting the roller on one of its shoulders with recessed and protruding profiles of the corresponding software about the cam, as well as the contact of the free end of its other shoulder through an intermediate acting element with a spring-loaded plunger of the micro switch of the pressure limit value sensor on the corresponding rotary platform, characterized in that the micro switch of the maximum pressure limit value sensor (Pmax) and the lever arm interacting with its pusher are located on the front side of the corresponding elongated turntable with the possibility of providing free and accelerated access to them, and located both program cams located on the axis of the transfer tribo-sector mechanism are spatially aligned with their recessed profiles, as well as the left and right transition steps, with the ability to provide automatic control of the system for stable maintenance of the required pressure in the measured medium in a more stable and gentle operating mode of microswitches, by applying on and off circuits of automatic control of only normally closed contacts of microswitches of sensors the minimum (Pct) and maximum (Pm) boundary pressure values, with increased current transmission and switching capabilities, mainly their long closed position and unloaded spring-loaded plungers, and in each program cam, the recessed profile is made with a circumferential length (1) proportional to the path moving the black pointer arrow of real pressure (Pr) along the entire measuring scale, and each transition step is sinusoidal with rounded ends and in cell (L) sufficient for performing the working stroke the spring-loaded pusher corresponding microswitch and provide a smooth, jerk-free interaction rollers double-arm levers, and also a significant decrease of the resistance force and the counteracting spring for the Bourdon tube.