CN117472107B - Control method for balance working position of piston type pressure gauge - Google Patents

Abstract

The invention provides a control method for the balance working position of a piston type pressure gauge, which is characterized in that hardware such as a displacement sensor, a controller, a standard pressure generator, an electromagnetic valve and the like are newly added on an original piston type pressure gauge, after a piston system (standard end) and a detected end reach an initial balance state, the displacement sensor below the piston system can monitor whether a piston displacement range is in an allowable working displacement range h ₀~h₁, when the piston gradually descends to be close to a height h ₀, the controller temporarily cuts off a connecting channel between the standard end and the detected end by closing the electromagnetic valve, and performs proper pressure compensation on the piston system by controlling the standard pressure generator until the standard pressure generator approaches h ₁, so that the piston displacement range is always kept in the working displacement range, and the aim of long-time constant pressure test on the pressure gauge at the detected end is fulfilled, thereby reducing manual operation.

Description

Control method for balance working position of piston type pressure gauge

Technical Field

The invention belongs to the technical field of pressure gauge measurement and control, and particularly relates to a control method for a balance working position of a piston type pressure gauge.

Background

The piston pressure gauge is a pressure measurement standard instrument based on pascal law and hydrostatic balance principle, is widely used because of its high accuracy and excellent long-term stability, and can be used for measuring and testing the measured instrument by equalizing the pressures of the standard piston and the measured instrument in an operating state, and can be used for calibrating and calibrating pressure gauges, digital pressure gauges, pressure transmitters and other pressure measurement instruments.

However, according to the design principle of the piston type pressure gauge, a micron-sized gap exists between the piston rod and the piston cylinder; under the working condition, working medium can gradually leak out of a gap of a piston system, the piston is inevitably lowered at a certain speed (the allowable lowering speed of a piston pressure gauge within 500MPa is 0.15 mm/min-1.5 mm/min according to different measuring ranges and accuracy grades), and although a certain allowable displacement range exists in the working position, if a long-term constant pressure test is carried out (namely, when two pressure values of a standard end and a detected port are kept in an equal pressure balance state for a long time), the pressure regulator is required to be continuously operated to adjust the volume of a cavity of the calibrator so as to improve the displacement of the piston system and keep the piston system in the working position, so that the whole system keeps pressure balance. The whole process needs to be monitored manually, and the height position of the piston system is continuously adjusted to be within the allowable displacement range by using the pressure regulator, and the manual pressurization causes the problem of inconvenient operation and the possibility that the piston system is easy to fall out of the working position range; meanwhile, the fact that the voltage regulator has the limit working range is considered, so that in the process of constant voltage test, the whole checking system cannot keep constant voltage after the voltage regulator reaches the limit working position is possible.

Based on the above, there is a great need to design a control method for the balance working position of the piston type pressure gauge, which reduces the manual pressure regulating workload during manual monitoring and ensures that the piston is always in the working position range when a long-term constant pressure test is performed, so that the whole system keeps pressure balance.

Disclosure of Invention

The invention provides a control method for a balance working position of a piston type pressure gauge, which is used for solving the problems that the operation is inconvenient and the piston system is easy to fall out of a working position range because manual repeated pressurization is needed in the process of keeping the pressure balance state of the whole system for a long time.

The invention discloses a control method for a balance working position of a piston type pressure gauge, wherein a displacement sensor, a controller, a standard pressure generator and an electromagnetic valve are arranged on a balance system of the piston type pressure gauge, the controller is respectively connected with the displacement sensor, the standard pressure generator and the electromagnetic valve through signals, the displacement sensor is arranged below the piston system, the output end of the standard pressure generator is connected with a hydraulic circuit, the electromagnetic valve is arranged on the hydraulic circuit between the output end of the standard pressure generator and a detected port, and when the piston system is in a balance state and the pressures of the standard port and the detected port are p, the controller can execute the following steps:

Step 1: initializing, namely setting the displacement range of the working position of the piston system as h ₀~h₁, controlling the electromagnetic valve to be in an open state and controlling the standard pressure generator to be closed, wherein h ₀ is the displacement of the lowest point of the working position, and h ₁ is the displacement of the highest point of the working position;

Step 2: when the displacement sensor detects that the working position of the piston system is h ₀ +delta h, the standard pressure generator is controlled to start a control mode and close the electromagnetic valve, and delta h is a positive constant;

step 3: the standard pressure generator performs pressure output control by using a pressure p+delta p slightly larger than a p value, so that a working medium in the standard pressure generator is injected into a hydraulic circuit, a piston system is enabled to rise, and delta p is a positive constant;

Step 4: when the displacement sensor detects that the working position of the piston system is h ₁ -delta h, the standard pressure generator is controlled to close the control mode and the electromagnetic valve is controlled to be opened.

Preferably, before performing steps 1-4, the piston manometer is required to be in an equilibrium working position; firstly, a measured appliance is arranged at a detected port on a piston type pressure gauge, weights with corresponding pressure are arranged on a piston system, the piston at the standard end floats to a working position through pre-pressing of a pre-pressing pump and fine adjustment of a pressure regulating pump, the piston rotates at the speed of 20-40 r/min, and at the moment, the pressure of a verification system is p and is maintained for a period of time, and then the steps 1-4 are executed.

Preferably, Δp is 1% p to 5% p, and Δh is 1mm to 3mm.

Preferably, step 1 further comprises setting the standard pressure generator in a measurement mode to measure the pressure of the hydraulic circuit.

Preferably, the displacement sensor is a laser displacement sensor.

Preferably, the working medium supplied through the inside of the standard pressure generator is identical to the piston system medium, in particular an oil medium.

Preferably, after the standard pressure generator is turned off in step 4 in the control mode, the standard pressure generator starts the measurement mode, at which point the pressures of the piston system, standard pressure generator and port under test are maintained at p.

Preferably, the pressure control range and the measuring range of the standard pressure generator can cover the measuring range of the piston pressure meter, and the upper limit of the pressure control range and the measuring range of the standard pressure generator is more than or equal to 1.01 times of the upper limit of the measuring range of the piston pressure meter, and the accuracy grade of the piston pressure meter and the standard pressure generator is 0.05 grade or more.

Preferably, if the controller determines that the measured pressure of the standard pressure generator is greater than the preset threshold, such as greater than 1.1p, when executing steps 1-4, then immediately stopping executing steps 1-4 and exiting the process.

The control method of the balance working position of the piston type pressure gauge is a control method combining software and hardware improvement, when a long-term constant pressure test is carried out (the duration of test pressure of a tested device is as long as several hours or even tens of hours, and the reference value of the descending speed of the piston of the 0.05-level piston type pressure gauge with the upper limit of 60MPa of the measuring range is about 1mm/min, and the reference working position range is about 10mm, if the method is not used, the piston descends to the lowest point h ₀ of the working position about 10min after reaching the balance state, a pressure regulator is needed to be used for lifting the piston position, and the pressure regulation of the pressure regulator is needed to be repeatedly carried out). The displacement sensor is arranged below the piston system (standard end) with weights placed at the moment and can monitor whether the displacement range of the piston is in an allowable working displacement range h ₀~h₁ or not, when the piston gradually descends to be close to the height h ₀, the controller temporarily cuts off the standard end and the detected end by closing the electromagnetic valve, and performs proper pressure compensation on the standard end piston system by controlling the standard pressure generator until the standard end is close to h ₁, then the piston type pressure gauge can quickly recover to a normal working state, the piston displacement range is always kept in the working displacement range, the purpose of long-time constant-pressure test on the detected instrument of the detected port is achieved, and manual operation is reduced.

Drawings

In order to more clearly illustrate the invention or the technical solutions of the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described, and it is obvious that the drawings in the description below are some embodiments of the invention, and other drawings can be obtained according to these drawings without inventive effort for a person skilled in the art.

FIG. 1 is a schematic diagram of a control system for a balanced operating position of a piston pressure gauge provided by the present invention;

Fig. 2 is a flow chart of the steps of the method for controlling the balance working position of the piston type pressure gauge.

Detailed Description

For the purpose of making the objects, technical solutions and advantages of the present invention more apparent, the technical solutions of the present invention will be clearly and completely described below with reference to the accompanying drawings, and it is apparent that the described embodiments are some embodiments of the present invention, not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

Based on the technical problem that the prior art is not easy to find, namely that the volume of the cavity of the piston calibrator is required to be continuously adjusted by using a pressure regulator during long-term constant pressure test, so that the displacement of a piston system is improved to push the piston system to a working position, the invention designs a control system for balancing the working position of the piston pressure gauge based on the improvement of FIG. 1.

The control system for the balance working position of the piston type pressure gauge of the invention is described below with reference to fig. 1, in the control system shown in fig. 1, a piston system with a standard piston, a pressure regulator, an oil return valve, an oil cup, a pre-pressure pump, a hydraulic circuit and a detected port all belong to the original devices on the piston type pressure gauge, the piston system is connected with the detected port through the hydraulic circuit, one end of the pressure regulator and one end of the oil return valve are connected with the hydraulic circuit, and the other end of the oil return valve is connected with the pre-pressure pump through the oil cup.

In order to automatically pressurize and ensure that the piston is always in the working position range during long-term constant pressure measurement calibration test, the invention adds hardware such as a displacement sensor, a controller, a standard pressure generator, a solenoid valve and the like in fig. 1, wherein the connection and the position relation of the components are as follows: the controller is respectively connected with the displacement sensor, the standard pressure generator and the electromagnetic valve in a signal way, and the displacement sensor is arranged below the piston system, so that the relative position of the lifting piston is monitored; the output end of the standard pressure generator is connected with the hydraulic circuit so as to perform pressure compensation on the hydraulic circuit; the solenoid valve is provided on the hydraulic circuit between the output of the standard pressure generator and the port under test, so as to actively shut off the hydraulic circuit when necessary.

After the newly-added hardware in fig. 1 is installed, the piston type pressure gauge is required to be in a balance working position, specifically, firstly, an appliance to be measured is installed at a tested port on the piston type pressure gauge, weights with corresponding pressures are installed on pistons of a piston system, the standard pistons float to the working position through pre-pressing of a pre-pressing pump and fine adjustment of a pressure regulating pump, the standard pistons rotate at the speed of (20-40) r/min, at the moment, the pressure of the whole verification system is p and is maintained for a period of time, namely, when an electromagnetic valve is in an open state and a standard pressure generator is in a measurement mode, the pressures of the piston system, the standard pressure generator and the tested port on the appliance to be measured are p and are maintained for a period of time, and the pressure value p is a pressure value displayed in the standard pressure generator measurement mode in an initial balance state.

In addition, the pressure control range and the measuring range of the standard pressure generator can cover the measuring range of the piston pressure meter, and the upper limit of the pressure control range and the measuring range of the standard pressure generator is more than or equal to 1.01 times of the upper limit of the measuring range of the piston pressure meter, and the accuracy grade of the piston pressure meter and the standard pressure generator is 0.05 grade and above.

On the basis of fig. 1, in order to keep the piston displacement range within the working displacement range all the time and achieve the purpose of performing a long-time constant pressure test on the tested instrument of the tested port, when the pressures of the piston system and the tested port are p, the controller can execute a control method for the balance working position of the piston type pressure gauge shown in fig. 2, which specifically comprises the following steps:

Step 1: initializing, setting the displacement range of the working position of the piston system as h ₀~h₁, controlling the electromagnetic valve to be in an open state and controlling the standard pressure generator to be closed, wherein h ₀ is the displacement of the lowest point of the working position, and h ₁ is the displacement of the highest point of the working position.

Step 2: when the displacement sensor detects that the working position of the piston system is h ₀ +Δh (at this time, the relative distance between the piston system and the displacement sensor is close to h ₀, and the normal number Δh may be preferably 1 mm), which indicates that the piston has fallen to the vicinity of the lower limit of the working position, the standard pressure generator is controlled to start the control mode and close the electromagnetic valve.

Step 3: the standard pressure generator is pressure-output-controlled with a pressure p + deltap slightly greater than the p-value (if a threshold p + deltap=1.01 p is set, deltap=0.01 p), and since the pressure of the standard pressure generator is greater than the pressure p of the hydraulic circuit, the working medium inside the standard pressure generator is injected into the hydraulic circuit at this time, so that the piston position rises.

Step 4: when the displacement sensor detects that the working position of the piston system is h ₁ -delta h (when the distance between the piston system and the displacement sensor is close to h ₁, such as h ₁ -1 mm), the standard pressure generator is controlled to close the control mode and the electromagnetic valve is controlled to open.

Therefore, the controller can cyclically execute the operation steps from the step 1 to the step 4 by monitoring the working position of the piston system, so that the standard piston can always keep in a normal working state, the purpose of long-time constant pressure test on the tested device is achieved, and the manual operation quantity can be greatly reduced.

Further, in the setting of step 1, the standard pressure generator may be set in a measurement mode to measure the pressure of the hydraulic circuit, where the pressures of the standard piston, the standard pressure generator and the measured tool are all measured to be p. In addition, the operating position displacement range h ₀~h₁ is related to both the relative mounting position of the displacement sensor and the normal range of motion of the piston, which can be measured in advance according to experiments.

Further, the displacement sensor may preferably be a high-precision contactless laser displacement sensor to ensure accuracy of the relative distance measurement.

In step 3, the working medium supplemented in the standard pressure generator is the same as the medium in the oil cup, preferably oil medium such as transformer oil or di (2-ethylhexyl) sebacate, and the purpose of supplementing pressure is achieved by injecting the working medium into the hydraulic circuit. In order to prevent overshoot due to rapid rise of the piston position during pressure compensation, Δp should not be excessively large, and the standard pressure generator output pressure may preferably be a pressure value of 1.01p to 1.05p, that is, Δp is 1% p to 5% p.

Further, in step 4, after the standard pressure generator is turned off in the control mode, the measurement mode may be started, and the pressures of the standard piston, the standard pressure generator, and the measured tool continue to be maintained at p.

Furthermore, in step 1, the pressure control range and the measuring range of the standard pressure generator can cover the measuring range of the piston type pressure gauge, and the upper limit of the pressure control range and the measuring range of the standard pressure generator is more than or equal to 1.01 times of the upper limit of the measuring range of the piston type pressure gauge, so that the standard pressure generator is ensured to have basic pressure control and measuring capability. The accuracy class of the piston manometer and the standard pressure generator is 0.05 level and above, thereby ensuring the accuracy of the whole measuring and controlling system.

Further, if the measured pressure of the standard pressure generator is greater than a certain threshold δ when executing steps 1-4, that is, if the pressure is not within the range of (p±δ), it means that the system is not under the constant pressure measurement condition (may exit the constant pressure test, or may indicate that the measurement is abnormal or disturbed), and at this time, the execution of steps 1-4 is immediately stopped and the program is exited, so that the erroneous pressurization is avoided, and the reference value of δ may be set to 0.1p.

In several embodiments provided in the present invention, each of the functional units in steps 1-4 may be integrated into one controller processing unit, or each unit may exist alone physically, or two or more units may be integrated into one unit. The integrated units may be implemented in hardware or in hardware plus software functional units. The integrated units implemented in the form of software functional units described above may be stored in a computer readable storage medium. The software functional unit is stored in a storage medium, and includes several instructions for causing a computer device (which may be a personal computer, a server, or a network device, etc.) or a processor (processor) to perform part of the steps of the methods according to the embodiments of the present invention. And the aforementioned storage medium includes: a U-disk, a removable hard disk, a read-only memory (ROM), a random access memory (Random Access Memory, RAM), a magnetic disk, or an optical disk, or other various media capable of storing program codes.

Finally, it should be noted that: the above embodiments are only for illustrating the technical solution of the present invention, and are not limiting; although the invention has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that: the technical scheme described in the foregoing embodiments can be modified or some technical features thereof can be replaced by equivalents; such modifications and substitutions do not depart from the spirit and scope of the technical solutions of the embodiments of the present invention.

Claims (8)

1. The control method for the balance working position of the piston type pressure gauge is characterized in that a balance system of the piston type pressure gauge is provided with a displacement sensor, a controller, a standard pressure generator and an electromagnetic valve, the controller is respectively connected with the displacement sensor, the standard pressure generator and the electromagnetic valve in a signal mode, the displacement sensor is arranged below the piston system, the output end of the standard pressure generator is connected with a hydraulic circuit, the electromagnetic valve is arranged on the hydraulic circuit between the output end of the standard pressure generator and a detected port, and when pressures at the piston system and the detected port are p, the controller can execute the following steps:

Step 1: initializing, namely setting the displacement range of the working position of the piston system as h ₀~h₁, controlling the electromagnetic valve to be in an open state and controlling the standard pressure generator to be closed, wherein h ₀ is the displacement of the lowest point of the working position, and h ₁ is the displacement of the highest point of the working position;

Step 2: when the displacement sensor detects that the working position of the piston system is h ₀ +delta h, the standard pressure generator is controlled to start a control mode and the electromagnetic valve is closed, wherein delta h is 1 mm-3 mm;

Step 3: the standard pressure generator performs pressure output control by using a pressure p+delta p slightly larger than a p value, so that a working medium in the standard pressure generator is injected into a hydraulic circuit, a piston system is enabled to rise, and delta p is a positive constant; the delta p is 1-5% p;

Step 4: when the displacement sensor detects that the working position of the piston system is h ₁ -delta h, the standard pressure generator is controlled to close the control mode and the electromagnetic valve is controlled to be opened.

2. The method for controlling the balance working position of a piston pressure gauge according to claim 1, wherein the piston pressure gauge is required to be in the balance working position before performing steps 1-4; firstly, a measured appliance is arranged at a detected port on a piston type pressure gauge, a weight with corresponding pressure is arranged on a piston system, the piston system floats to a working position through pre-pressing of a pre-pressing pump and fine adjustment of a pressure regulating pump, the piston system rotates at the speed of (20-40) r/min, the pressure of the whole checking system is kept to be p, and after the pressure is maintained for a period of time, the step 1-4 is executed.

3. The method of controlling the balance operating position of a piston pressure gauge according to claim 2, further comprising, in step 1, setting a standard pressure generator in a measurement mode to measure the pressure of the hydraulic circuit.

4. The method for controlling the balance operating position of a piston pressure gauge according to claim 2, wherein the displacement sensor is a laser displacement sensor.

5. Method according to claim 2, characterized in that the working medium replenished inside the standard pressure generator is in particular an oil medium and is identical to the medium in the oil cup.

6. The method of controlling the equilibrium operating position of a piston pressure gauge according to claim 2 wherein the normal pressure generator starts the measurement mode immediately after the normal pressure generator is turned off in step 4, and the pressures of the piston system, the normal pressure generator and the port under test are maintained at p.

7. The method according to claim 1, wherein the pressure control range and the measurement range of the standard pressure generator can cover the measurement range of the piston pressure generator, and the upper limit of the pressure control range and the measurement range of the standard pressure generator is not less than 1.01 times the upper limit of the measurement range of the piston pressure generator, and the accuracy class of the piston pressure generator and the standard pressure generator is 0.05 level or more.

8. The method according to claim 3 or 6, wherein if the controller determines that the measured pressure of the standard pressure generator is greater than the preset threshold value when performing steps 1-4, the controller immediately stops performing steps 1-4 and exits the routine.