RU2345340C1 - Threshold data unit of pressure - Google Patents

Abstract

FIELD: physics, measuring.

SUBSTANCE: invention can be applied in hydraulic and gas systems with overload pressures considerably exceeding working pressure. Threshold data unit of pressure contains case, immobile adjustable contacts and sensitive body interreacting through rod and spring with the mobile current-carrying contact. On rod the groove is executed. The mobile current-carrying contact is disposed on spin axis supplied with the lever, rigidly anchored on it with possibility of introduction of the lever in a groove of the rod providing transformation of progress of sensitive body in circumrotatory motion of the mobile current-carrying contact. The sensitive organ is executed in the form of piston drawn in by spring with flange and stage pusher, and the pusher step is executed on the length providing possibility of travel of the piston within admissible squeezing of its drawing in spring. In a piston body the sealing device isolating a vacuity with the mobile current-carrying contact from a working environment, and between a flange of the piston and the case - an additional sealing device is erected. The spring which is drawing in the piston, is chosen with effort, equivalent to an operation threshold. Transmission of interaction of sensitive organ with the mobile current-carrying contact is carried out through stage pusher.

EFFECT: increase of reliability of device.

1 dwg

Description

The invention relates to instrumentation, more specifically to means of control, and can be applied, for example, in systems with a hydraulic and gas medium for measuring the moment of reaching a predetermined pressure threshold.

When studying reference information and patent funds, the closest analogues of the invention were identified:

a) the pressure indicator shown in the catalog "Devices and automation means. Pressure indicators of type ID-1" M .: Informpribor, 1993, p.21. The device comprises a housing, a sensitive organ, installed on the supply side of the working medium, and a transmission link in the form of a rod that converts the translational motion of the sensitive organ into a rotary movement of the contact group armature;

b) the pressure switch, given in ed. St. SU 761859, IPC G01L 7/08, publication 1980. The device comprises a housing, fixed adjustable contacts and a sensing organ, mounted on the supply side of the working medium and interacting through the rod and spring with a movable conductive contact, made in the form of a flat spring comb, marked protruding contact plates.

The disadvantage of analogues is the inability to lock the closed state of the electrical contact after the operation of the device.

Closest to the claimed technical solution is the pressure sensor according to patent RU 2120115, IPC ⁶ G01L 7/08, 19/12, priority 20.06.96, publication 10.10.98. The device is performed with a predetermined threshold of operation and contains a housing, fixed adjustable contacts and a sensing organ installed on the supply side of the working medium and interacting through the rod and spring with a movable conductive contact. A groove is made on the stock. The movable conductive contact is placed on the axis of rotation, equipped with a lever rigidly fixed to it with the possibility of introducing the lever into the groove of the rod, which converts the translational movement of the elements of the sensitive organ into the rotational movement of the movable conductive contact. The sensitive organ is made in the form of a corrugated clapping membrane with a thin wall and large diameter. The interaction of the sensitive organ with the movable conductive contact is transmitted through the center of the membrane.

This device is selected for the prototype.

The disadvantages of the design of this measuring device include, first of all, the impossibility of its use in systems with overload pressures P _per exceeding the working pressure P _slave equivalent to its threshold. In practice, such systems are most often encountered, while overload pressures can exceed the operating value by more than an order of magnitude. This drawback is mainly due to the design of the membrane used and the large diameter over which it is sealed. The thin wall of the membrane, the geometry of its corrugations and the diameter provide the required sensitivity threshold and a predetermined threshold for the operation of the device. However, the presence of a large diameter leads to a significant magnitude of the force acting on the housing of the device at overload pressure. Due to this, the pressure of a larger P _slave , but even lower P _lane , the thin wall of the membrane may experience deflection along the corrugations not in the elastic, but in the plastic region of deformation, which leads to a violation of the geometry of the corrugations and the loss of the possibility of deflection of the membrane in the opposite direction. In places of tight sealing of the membrane, stresses can occur in excess of permissible values, because of which its destruction is possible, leading to depressurization of the cavity with the working medium and loss of operability of the system in which this device will be used.

In the known device from the impact on the membrane of the force equivalent to the pressure P _per , even before the depressurization of the membrane, the housing can also collapse, since the structural reserves of strength are quite difficult to make sufficient due to the inadmissibility of an increase in weight and dimensions. It is impossible to eliminate this drawback by increasing the thickness of the membrane, since this decreases the sensitivity threshold, and the response threshold increases and goes beyond the specified values.

In addition, devices of this type in the manufacture should, as a rule, be subjected to strength control with test pressure P _samples , the value of which can exceed P _per value with a coefficient of 1.25 to 1.5 times. A known device in the process of conducting such control may be damaged, since its membrane will either lose the possibility of deflection in the opposite direction, or it will lose its tightness, and the case may be destroyed.

Loss of ability to deflect the membrane in the opposite direction, that is, its return to its original state when the pressure of the working medium drops, leads to additional design flaws in the device selected for the prototype, which include the impossibility of its reuse.

In the prototype, the components of the sensitive organ, including the places of the hermetic seal of the membrane along the contour, are not actually protected from the external environment from the side of the conductive contacts, since the cavity in which these contacts are placed is most often leaky. Therefore, the actual pressure of the environment will influence the thresholds of sensitivity and response of the device. In addition, prolonged exposure to an external environment, which can be aggressive, on a thin-walled membrane and its tight seal can lead to an additional change in the sensitivity and response thresholds. In such cases, this will lead to an additional decrease in the reliability of its operation.

As noted above, a significant difference between the prototype and analogues is the presence of a locked state of electrical contact after the operation of the device. This quality should be attributed to the advantages of the prototype. This quality is preserved in the design of the proposed device.

The objective of the present invention is to increase the reliability of the device with the ability to control the strength of the test pressure and reuse, as well as maintaining the response threshold and reducing its dependence on the ambient pressure.

When using the invention, the following technical result is achieved:

a) increase the level of reliability of operation of the device;

b) providing the ability to control the strength of the test pressure;

c) reducing the influence of environmental pressure on the threshold and ensuring the safety of this threshold within the warranty period of storage and operation;

d) ensuring the possibility of reuse.

The solution of this problem and the achievement of the technical result is ensured by the fact that in the known device comprising a housing, fixed adjustable contacts, a sensitive organ installed on the supply side of the working medium and interacting through the rod and spring with a movable conductive contact, a groove is made on the rod, a movable conductive contact placed on the axis of rotation, equipped with a lever rigidly fixed to it with the possibility of introducing the lever into the groove of the rod, providing translational translation of the motion of the sensitive organ into the rotational motion of the conductive contact, according to the invention, the sensitive organ is made in the form of a spring-loaded piston with a flange and a step pusher, a sealing element is installed in the piston body that isolates the cavity with a movable conductive contact from the working medium, between the piston flange and the housing an additional sealing element, while the spring pressing the piston is selected with a force equivalent to the threshold, the transmission The action of the sensitive organ with the movable conductive contact is carried out through a step pusher, and the pusher step is made over a length that allows the piston to move within the allowable compression of its pressing spring.

The implementation of the sensitive body in the form of a spring-loaded piston with a flange and a step pusher reduces the possibility of such environmental influences that could lead to damage to its elements, or to changes in the sensitivity and response thresholds. This contributes to the possibility of increasing parametric reliability and maintaining it at a high level.

The working area of the piston without impairing the operability of the device can be made ten times smaller than the working area of the corrugated popping membrane, which leads to a proportional decrease in the force acting on the device body at overload pressure. This contributes to the possibility of increasing the strength reliability and maintaining it at a high level.

In addition, the dependence of the response threshold on the actual value of the ambient pressure will be proportionally reduced. This contributes to the possibility of increasing parametric reliability and maintaining it at a high level.

The installation in the piston body of a sealing element isolating the cavity with a movable conductive contact from the working medium eliminates the impact of the working medium on the elements of the sensitive organ and thereby reduces the likelihood of changes in the sensitivity and response thresholds. This contributes to the possibility of increasing parametric reliability and maintaining it at a high level.

The installation between the piston flange and the housing of an additional sealing element, insulating the channel in which the piston is located, from a cavity with a movable conductive contact, eliminates the influence of the external environment on the first sealing element. Therefore, the likelihood of damage to the elements of the sensitive organ or changes in the response threshold from the effects of the external environment within the warranty period for storage and use in this device is reduced. This contributes to the possibility of increasing parametric reliability and maintaining it at a high level.

The choice of a spring that compresses the piston with a force equivalent to the response threshold provides the possibility of increasing both the strength and parametric reliability of the work and maintaining it at a high level. This is due to the fact that in this device the spring is placed on the side of the cavity with a movable conductive contact and is insensitive to the pressure and the degree of aggressiveness of the external environment acting on it from this side. The working medium does not have the possibility of contact with the spring.

The transmission of the interaction of the sensitive organ with the movable conductive contact through a step pusher together with the spring pressing the piston eliminates the possibility of non-return of the sensitive organ to its original state after a pressure drop in the working medium. This provides the proposed device with the ability to control test pressure in the manufacture and reuse as intended.

Performing a pusher step along a length that allows the piston to move within the allowable compression of its compression spring reduces the likelihood of damage to the elements of the sensitive organ, as well as lowering its sensitivity threshold or changing the response threshold when testing pressure is used during the manufacturing process of the device and its repeated use destination.

A structural diagram of the proposed device is shown in the drawing, while for the convenience of reading illustrative material, individual parts are depicted conventionally.

The device comprises a housing 1, fixed adjustable contacts 2, a sensitive body made in the form of a piston 3, a rod 4, a spring 5, a movable conductive contact 6, a lever 7, a torsion spring 8, an axis of rotation 9, an electrical connector 10. A piston 3 is installed in the channel of the housing 1 on the supply side of the working medium, and on the opposite side is pressed by the spring 11. A flange 12 is made on the piston 3, and a pusher 13 is installed behind the piston. A sealing element 14 is installed in the piston 3 body, and an additional seal is installed between the flange 12 and the body of the housing 1 ermetiziruyuschy element 15. The housing body 1 is formed on the end face A. The plunger 13 is formed with a step end face B.

The sealing element 14 isolates from the working medium a cavity in which stationary adjustable contacts 2, a spring 5, a movable conductive contact 6, a lever 7, a torsion spring 8 and a rotation axis 9 are placed. This thereby excludes the possibility of the working medium affecting the sensitive organ of the device.

In the initial state of the device, an additional sealing element 15 isolates the channel in which the piston 3 is mounted from the cavity in which the fixed adjustable contacts 2 are placed. This eliminates the possibility of the external environment in which the device is located on the sealing element 14.

The device operates as follows.

After installation of the device in the system for which it is intended, when the working medium pressure P values less _slave piston 3 retains its original state.

In the case of increasing pressure of the working medium, the piston 3 with the flange 12, overcoming the resistance of the spring 11, is shifted relative to the initial position. In this case, the piston 3 is temporarily decompressed by an additional sealing element 15, but due to the sealing element 14, the working medium remains isolated from the cavity in which the fixed adjustable contacts are placed 2. The tightness of the system in which the device is installed is not broken.

With a further increase in the pressure of the working medium to the value P, the _slave piston 3, overcoming the increasing resistance of the spring 11, moves a greater distance. The pusher 13 makes contact with the rod 4, which moves synchronously with the piston 3. By selecting the spring 11 with a force equivalent to the threshold, the rod 4 moves until the lever 7 enters its groove, due to which the movable contact 6 acquires the ability to turn.

The interaction of the pusher 13 with the rod 4 converts the translational movement of the piston 3 into the rotational movement of the movable conductive contact 6. Due to the torsion spring 8, the movable contact 6 after rotation around its axis 9 is located between the plates of the fixed contacts 2, which allows you to maintain reliable electrical contact. The locking mechanism, consisting of a lever 7 and a rod 4 with a groove, provides a closed (open) state of the fixed contacts 2. This is achieved after the rod 4 is moved and the lever 7 enters the groove of the rod 4, due to which its position is reliably maintained, since the movable contact 6 remains tightened by the force of the torsion spring 8 and it is not possible to return back.

With further movement of the piston 3, the end face B of the pusher 13 comes into contact with the end face A of the housing 1 and the piston stops, thereby limiting the amount of compression of the spring 11. In the process of increasing the pressure in the range from practically the value of P _slave to the value of P _per, all the force by which the piston 3 loaded, perceived by the end face A of the housing 1, thereby eliminating the possibility of damage to the elements of the sensitive organ of the device.

After the pressure in the system drops, the spring 11 returns the piston 3 to its original state, while the additional sealing element 15 is pressed by the flange 12 to the body of the housing 1 and isolates the channel in which the piston 3 is installed from the cavity in which the stationary adjustable contacts 2 are placed. again excluded the possibility of exposure to the external environment in which the device is located on the sealing element 14.

It should be noted that the device provides the ability to control the strength of the test pressure during its manufacture. When performing this control at the moment of reaching the value of P _{slave, the} process of operation of the device occurs in the same way as described above. Loss of performance or a decrease in any performance characteristics when testing the device with test pressure does not occur. Due to this, the pressure sensor can be used repeatedly. This device also achieves a reduction in the effect of environmental pressure on the response threshold and ensures the safety of this threshold within the warranty period for storage and operation. The reliability of the device reaches a level of at least P = 0.9995 with a confidence probability of P = 0.9.

The operability of the device and its reliability were confirmed experimentally on a prototype when triggered under different temperature conditions up to 500 times. At the same time, in the prototype, the power part of the housing 1 (from the supply side of the working medium and at the location of the end face A), the piston 3 with the flange 12 and the step pusher 13 with the end face B were made of steel, the spring 11 was made of steel wire with a diameter of 1 to 2 mm and with a protective coating, the sealing element 14 is made of rubber compound, and the sealing element 15 is made of fluoroplastic film. The working diameter of the piston 3 was 8 mm. The distance from the rod 4 to the stepped pusher 13 was chosen equal to 0.8 mm, and the gap between the ends A and B was 1.8 mm.

Practical results obtained when the prototype of the device is triggered, show that in the case of design according to the invention, this device fully meets the requirements for achieving a technical result.

Claims (1)

A threshold pressure sensor comprising a housing, fixed adjustable contacts, a sensing organ mounted on the supply side of the working medium and interacting through the rod and spring with a movable conductive contact, a groove is made on the rod, and a movable conductive contact is placed on a rotation axis equipped with a lever rigidly fixed on it with the possibility of introducing a lever into the groove of the rod, providing the conversion of the translational motion of the sensitive organ into the rotational motion of the movable conductive its contact, characterized in that the sensitive body is made in the form of a piston pressed by a spring with a flange and a step pusher, a sealing element is installed in the piston body, isolating the cavity with a movable conductive contact from the working medium, an additional sealing element is installed between the piston flange and the housing, while the spring pressing the piston is selected with a force equivalent to the threshold, the interaction of the sensitive organ with the movable conductive contact is transmitted through without a step pusher, and the step of the pusher is made on a length that allows the piston to move within the allowable compression of its pressing spring.