KR20030093702A - System for remotely sensing oil pump and sensing method thereof - Google Patents

Abstract

PURPOSE: A system for remotely sensing a state of a hydraulic pump is provided to directly sense a vibration of a rotating axis generated during a rotational movement of the hydraulic pump, thereby diagnosing mechanical wear and damage and delivering a text or a code message for a pump state to a remote place. CONSTITUTION: Vibration sensors(4,6) and speed sensors(5,7) are mounted on a rotating axis(2) and a hydraulic pump(3). A controller(8) receives vibration data and speed data from the vibration sensors(4,6) and the speed sensors(5,7). The controller(8) calculates pressure pulsating waves and rotations by frequency through an operator(10) while storing the data in a memory(9). A decider(11) decides whether the frequency is normal as arraying calculated results. A dialing signal generator(12) generates and outputs a dialing signal corresponding to a telephone number of a manager. When a speech path is formed through a wireless base station(14), a signal output unit(13) outputs a text or a code message informing the manager that the hydraulic pump(3) fails.

Description

System for remotely sensing oil pump and sensing method

The present invention relates to a system for remotely detecting a state of a hydraulic pump and a method for diagnosing a failure. The present invention can directly sense vibration of a rotating shaft generated during a rotational movement of a hydraulic pump to diagnose mechanical wear and breakage of the hydraulic pump as well as the state of the pump. The present invention relates to a system for remotely detecting a state of a hydraulic pump and a method for diagnosing a failure of a hydraulic pump, which can be transmitted to a remote location through a text or code message of a mobile device.

In general, hydraulic pumps are the most important machines for generating hydraulic energy in hydraulic shovels, cranes, other hydraulic machines and hydraulic devices, and it is well known that failures of these hydraulic pumps are difficult to detect easily.

In addition, since the failure occurred once in the hydraulic pump is often fatal, it is very important to diagnose the hydraulic pump and grasp the condition so that the indication of the occurrence of the failure is known in advance. It is a problem.

Conventional hydraulic pump failure diagnosis technology is to measure and analyze the operating pressure of the hydraulic pump, attempted to identify and diagnose the state of the hydraulic pump.

That is, the variable displacement inflow pump to be diagnosed has a displacement volume variable mechanism (hereinafter referred to as a swash plate) and is connected to a regulator to operate the swash plate according to its discharge pressure. A hydraulic tester is needed to diagnose the failure, and the hydraulic tester is composed of a pressure gauge for measuring the hydraulic pressure, a flow meter for measuring the flow rate, and a manual variable aperture for tightening the discharge pipe of the variable displacement hydraulic pump and increasing the discharge pressure. A variable displacement hydraulic pump is further connected with a tachometer for measuring the number of revolutions thereof.

In order to diagnose the failure of the variable displacement hydraulic pump, the pipe connected to the discharge side of the variable displacement hydraulic pump is cut off, and the piping part of the pump side is connected to the inlet of the hydraulic tester through a pipe such as a hydraulic hose. The outlet of was similarly connected to the hydraulic oil tank through a pipe such as a hydraulic hose, and then the variable speed hydraulic pump was driven by a prime mover such as an engine, and the rotation speed N of the pump was measured by a tachometer.

In this state, the variable cooking system of the tester is operated to tighten the pipe until the value of the pressure gauge (discharge pressure of the variable displacement hydraulic pump) becomes the set value Pref, and the discharge amount Q of the pump at this time is measured by a flowmeter. In this case, the discharge amount is determined by the position of the swash plate controlled by the regulator in accordance with the discharge pressure.

Next, the theoretical discharge amount Qref of the pump is calculated on the basis of the rotation speed N and the set pressure Pref, and then the theoretical discharge amount Qref is compared with the discharge amount Q previously measured, and the difference is the allowable value. The pump was determined to be in a fault state when exceeded.

As described above, in the conventional failure diagnosis apparatus, it is possible to accurately diagnose the failure. However, a part of the hydraulic piping installed at the time of performing the diagnosis must be cut off to attach a connection pipe or a hydraulic tester. It took time, and there was a possibility that foreign matters such as dust were caught in the pipes when the hydraulic pipes were cut and separated. In addition, the diagnosis itself, the variable aperture must be operated to decipher the readings of the pressure gauge and the flow meter, which requires a lot of time, and the diagnosis was cumbersome. In addition, if a mechanical device has a large number of hydraulic pumps, such as a large hydraulic shovel, and knows which hydraulic pump is failing, the conventional fault diagnosis apparatus finds which hydraulic pump has failed. It took a lot of time.

Accordingly, 1984 Patent Application No. 1984-0004488 (Hydraulic Pump Fault Diagnosis Device) was proposed.

This is the subject of fault diagnosis, and the variable displacement hydraulic pump operated by the operation lever has a displacement volume variable mechanism (hereinafter referred to as swash plate), such as swash plate, bevel shaft,

The swash plate is driven by a regulator, that is, a swash plate driving device according to the input signal, and the position of the swash plate, that is, the displacement amount is detected by the displacement meter,

The displacement meter outputs a displacement signal according to the detected swash plate displacement amount, and the operation lever outputs an operation signal according to the manipulated amount.

The displacement signal of the displacement meter and the operation signal of the operation lever are input to a control device for driving control of the swash plate according to the operation of the operation lever. Thus, the swash plate was driven.

As such, when the swash plate is operated by the operating lever and the output signal of the displacement meter for detecting the displacement of the swash plate is equal to the output signal of the operating lever, the control device outputs a stop signal to the swash plate driving device.

However, the failure diagnosis apparatus of the conventional hydraulic pump as described above attempts to grasp the properties of the rigid parts constituting the hydraulic pump as an indirect state amount through the fluid, and the accuracy and reliability of the failure diagnosis of the hydraulic pump are closely related to the observer's experience and control. There is a drawback that depends heavily on.

Therefore, the present invention has been devised to solve the problems described above, by directly sensing the vibration of the rotating shaft generated during the rotational movement of the hydraulic pump can not only diagnose the mechanical wear and breakage of the hydraulic pump but also pump It is an object of the present invention to provide a remote state detection system and a failure diagnosis method of a hydraulic pump that can transmit the state of a mobile device to a remote place through a text or code message.

Remote state detection system and failure diagnosis method of the hydraulic pump according to the present invention for achieving the above object to diagnose the state of the hydraulic pump from the speed and vibration data obtained while operating the hydraulic pump,

Calculate the pressure pulsating wave and rotation of the hydraulic pump by frequency, and if the additional occurrence or distorted frequency appears among them, many data indicate that most of the causes are due to wear, which is damage inside the pump.

The analysis technique based on the above data is used to determine the degree of wear and damage of internal parts such as spools and gears without disassembling the pump.

When the hydraulic pump rotates, in the case of the variable hydraulic pump, the flow rate and the hydraulic pressure are generated by the reciprocating motion of the spool, and in the case of the gear pump, the flow rate and the hydraulic pressure are generated by the rotational movement of the gear,

While generating a fine pulsation pressure wave according to the movement of the spool and the rotation of the gear, the vibration is generated on the rotating shaft,

When the vibration and pulsation pressure, which is a value obtained by multiplying the number of rotations and the number of spools and the number of gears, are made at a constant cycle, it is determined that the hydraulic pump operates at a constant rotation.

Since the pulsation pressure is fine, the frequency is calculated while measuring the vibration to more accurately perform the diagnosis of the hydraulic pump,

If a large number of frequencies other than the vibration frequency range caused by the vibration and pulsation pressure are present, it is possible to diagnose that the gears of the multiple spools or gears are damaged. Prevention and action can be taken in advance to prevent damage due to malfunctions.

1 is a schematic diagram showing a system equipped with a vibration sensor and a speed sensor in the vibration shaft and the hydraulic pump of the present invention.

Figure 2 is a waveform diagram of a state analyzed by the vibration program and the vibration waveform and frequency by the vibration sensor and the speed sensor of the present invention.

Figure 3 is a flowchart showing a process of determining the damage of the pump by analyzing the frequency in the controller of the present invention.

Explanation of symbols on the main parts of the drawings

2: rotating shaft 3: hydraulic pump

4, 6: vibration sensor 5, 7: speed sensor

8 controller 9 memory

10: calculating unit 11: discriminating unit

12: dialing signal generation unit 13: signal output unit

Hereinafter, with reference to the accompanying drawings, the present invention will be described in detail.

Figure 1 shows a system equipped with a vibration sensor and a speed sensor on the vibration shaft and the hydraulic pump, Figure 2 shows a state of analyzing the vibration waveform and frequency by the vibration sensor and the speed sensor through a simulation program, Figure 3 Figure 2 shows the process of determining the damage of the pump by analyzing the frequency in the controller of the present invention,

To generate a rotational force in the drive source (1) receiving power such as electric energy from the outside,

To generate hydraulic energy by the rotational force in the hydraulic pump (3) receiving the rotational force through the rotating shaft (2) coupled to the drive source (1),

Mounting the vibration sensor (4) (6) and the speed sensor (5) (7) to the rotary shaft (2) and the hydraulic pump (3), respectively,

The controller 8, which receives the vibration data and the speed data from the vibration sensors 4 and 6 and the speed sensor 5 and 7, compares the frequency to determine whether the hydraulic pump has failed.

The controller 8 stores the hydraulic pump 3 through the calculation unit 10 while storing the data obtained from the vibration sensors 4, 6 and the speed sensors 5, 7 in the internal memory 9. To calculate the pressure pulse wave and rotation from

By performing the frequency analysis (DET: Discrete Fourier Transform) in the discriminating unit 11 by arranging the result values of the above operation, whether the frequency calculated by the normality of the frequency is caused by the damage of the hydraulic pump 3 or not. To judge,

As a result of the determination, if the frequency is caused by damage, the dialing signal generation unit 12 generates and outputs a dialing signal corresponding to the telephone number of the administrator inputted into the memory 9,

When a call path is formed through the radio base station 14 by the dialing signal, the signal output unit 13 is configured to output a letter or code indicating that the hydraulic pump 3 is in a faulty state.

The remote sensing state of the hydraulic pump of the present invention configured as described above is capable of directly sensing the vibration of the rotating shaft generated during the rotational movement of the hydraulic pump to diagnose mechanical wear and breakage of the hydraulic pump, and then send the state of the pump to the remote site. ,

The drive source 1 that receives power such as electric energy from the outside generates a rotational force to rotate the rotating shaft 2.

The hydraulic energy is generated by the rotational force in the hydraulic pump 3 receiving the rotational force through the rotating shaft 2 coupled to the drive source 1.

Since the vibration shafts 4 and 6 are mounted on the rotary shaft 2 and the hydraulic pump 3, the vibration data is transmitted to the controller 8, and the speed data is transmitted through the speed sensors 5 and 7. To be transmitted to the controller (8) to compare the frequency to determine whether the hydraulic pump failure.

That is, the vibration data of the rotary shaft 2 by the vibration sensor 4, the vibration data of the hydraulic pump 3 by the vibration sensor 6, the speed data of the rotary shaft 2 by the speed sensor 5 and When the speed data of the hydraulic pump 3 by the speed sensor 7 is received by the controller 8 (step 21), it is temporarily stored in the internal memory 9 (step 22).

In this state, the controller 8 performs the calculation of the pulsating wave and the rotation by the frequency and the vibration from the rotating shaft 2 through the calculating section 10 (step 23) while the vibration from the hydraulic pump 3 and An operation for calculating the pressure pulsating wave and the rotation by the frequency for each frequency is performed (step 24).

The controller 8 compares the frequency from the hydraulic pump 3 on the basis of the frequency from the rotating shaft 2 in the discriminating unit 11 while arranging the result values of the calculation (step 25). Then, it is determined whether or not the frequency from the hydraulic pump 3 is caused by the damage of the hydraulic pump 3 by whether or not the state is normal (step 26).

The method for determining whether the hydraulic pump 3 is broken or damaged by the controller 8 can look at the frequency of the vibration data and the speed frequency of the hydraulic pump 3 as shown in FIG. After confirming that there is a distorted part of the waveform at the frequency, it can be seen that it appears in two frequency bands. Therefore, the frequency of one of the two frequency bands can be analyzed as the frequency of the broken part due to the damage of the hydraulic pump.

When the controller 8 determines that the frequency is due to damage of the hydraulic pump 3 (step 27), the control signal is output to the dialing signal generator 12 and inputted to the memory 9. A dialing signal corresponding to the manager's telephone number is generated and output (step 28).

When the call path is formed by the dialing signal (step 29), the signal output unit 13 outputs a character or code indicating that the hydraulic pump 3 is in a failure state to the manager's wireless telephone (step 30).

On the other hand, when the hydraulic pump 3 operates in a constant rotation, the vibration and pulsation pressure are also made at regular intervals, and the pulsation pressure and vibration at this time are the value of the supply rotational speed multiplied by the number of spools or the number of gears.

By the way, since the general pulsating pressure is fine, it is possible to determine the diagnosis of the hydraulic pump 3 more accurately by measuring the vibration and calculating the frequency.

And for variable hydraulic pumps:

Normal vibration frequency (f normal) = pump rotation speed (rpm) / 60 * number of spools

Also for gear hydraulic pumps:

Normal vibration frequency (f normal) = pump rotation speed (rpm) / 60 * gear gear number

Since the vibration frequency range for the variable hydraulic pump and the gear hydraulic pump can be calculated according to the equation, when a spool or gear gear is worn or damaged, another frequency outside the above normal vibration frequency (f normal) range can be calculated. If several different frequencies occur, it is possible to infer and diagnose that multiple spools or gear teeth are damaged.

Therefore, according to the present condition remote sensing system and fault diagnosis method of the hydraulic pump of the present invention, the vibration frequency analysis results of the vibration frequency of the actuator together with the vibration frequency of the rotor in order to prevent a mistake in the rotational variation of the driver as a result of the vibration frequency analysis It is possible to detect the damage and abrasion of components that cause malfunction and deterioration of hydraulic pump by increasing the reliability of diagnosis by distinguishing whether it is caused by abrasion or damage of the pump or rotational change. Of course, it is possible to determine the degree of wear or damage of the hydraulic pump early by a simple method, so that a countermeasure can be taken in advance before a fatal failure of the hydraulic pump occurs, and the estimated time of the fatal malfunction can be estimated. It can be.

Claims (3)

In the hydraulic pump state remote sensing system for generating hydraulic energy from the hydraulic pump (3) receiving the rotational force through the rotating shaft (2) in the drive source (1), Vibration sensors (4) and (6) and speed sensors (5) and (7) are respectively mounted on the rotary shaft (2) and the hydraulic pump (3), The controller 8, which receives the vibration data and the speed data from the vibration sensors 4, 6, and speed sensors 5, 7, stores pressure in the memory 9 through the operation unit 10. To compute the wave and rotation by frequency, The discriminating unit 11 determines whether the frequency is normal by frequency analysis while enumerating the result values of the above operation, Based on the determination result, the dialing signal generation unit 12 generates and outputs a dialing signal corresponding to the manager's telephone number. When the communication path is formed through the radio base station 14 by the dialing signal, the hydraulic pump state remote sensing system to output a letter or code indicating that the hydraulic pump (3) in the failure state. Vibration data of the rotary shaft 2 by the vibration sensor 4, vibration data of the hydraulic pump 3 by the vibration sensor 6, speed data of the rotary shaft 2 by the speed sensor 5 and the speed sensor 7 Receiving speed data of the hydraulic pump 3 by the controller 8 and temporarily storing the speed data in the internal memory 9; Performing calculation to calculate the pulsating wave and rotation by frequency and vibrations from the rotation shaft 2 and the hydraulic pumps 3 through the calculating unit 10 in the controller 8; The controller 8 performs the frequency analysis of comparing the frequency from the hydraulic pump 3 on the basis of the frequency from the rotating shaft 2 through the discriminating unit 11 while arranging the calculation result values. Determining whether or not the hydraulic pump 3 is damaged by whether or not the frequency from the pump 3 is normal; When the controller 8 determines that the frequency is due to damage of the hydraulic pump 3, the controller 8 outputs a control signal to the dialing signal generator 12 to generate a dialing signal corresponding to the inputted telephone number of the manager. And outputting When the communication path is formed by the dialing signal of the hydraulic pressure characterized in that it is carried out by the step of outputting a letter or code in the signal output unit 13 indicating that the hydraulic pump 3 is in a failure state to a wireless telephone of the manager How to diagnose pump failure. According to claim 2, wherein the hydraulic pump is a swash plate-type hydraulic pump or gear hydraulic pump and senses the rotation and vibration of the drive shaft of the drive source frequency band, bearing frequency band, pump spool for the remaining frequency of controlling the rotation frequency Fault diagnosis method of hydraulic pump which is divided into frequency band of gear gear and gear gear to compare frequency band for each.