JP6342266B2 - Fault diagnosis device for hydraulic pump - Google Patents

Description

  The present invention relates to a fault diagnosis device for a hydraulic pump.

  Conventionally, as a failure diagnosis device for diagnosing a failure of a hydraulic pump, a failure diagnosis device of Patent Document 1 is known. The failure diagnosis apparatus of Patent Document 1 includes an internal pressure detection unit that detects a pressure in a casing of a hydraulic pump, and a tank pressure detection unit that detects a pressure in a tank that supplies hydraulic oil to the hydraulic pump. In this failure diagnosis apparatus, the pressure difference between the pressure in the casing of the hydraulic pump detected by the internal pressure detection means and the pressure in the tank detected by the tank pressure detection means is compared with the reference pressure value, thereby comparing the hydraulic pump A fault is diagnosed.

JP 2013-160157 A

  As described above, the failure diagnosis device of Patent Document 1 diagnoses a failure of the hydraulic pump from the difference between the differential pressure obtained by subtracting the pressure in the tank from the pressure in the casing of the hydraulic pump at a predetermined rotational speed and the reference pressure value. To do. Such a failure diagnosis result depends not only on the pressure in the casing of the hydraulic pump but also on the pressure in the tank. For this reason, even if a failure does not actually occur in the hydraulic pump, for example, if a failure occurs in the tank pressure detecting means, the difference between the differential pressure and the reference pressure becomes large, and thus the hydraulic pump is erroneously There is a possibility of diagnosing that a failure has occurred. In order to suppress such a misdiagnosis, it is conceivable to diagnose a failure of the hydraulic pump based on the discharge amount of the hydraulic oil by the hydraulic pump, but in order to measure the discharge amount of the hydraulic oil, For example, it is necessary to attach a flow meter to the hydraulic pump, which increases the cost.

  The present invention has been made from the above viewpoint, and an object thereof is related to a failure diagnosis apparatus for a hydraulic pump capable of diagnosing a failure based on the degree of change in discharge amount while suppressing an increase in cost.

  The present invention relates to a failure diagnosis apparatus for a hydraulic pump that has a rotating body and discharges liquid along with the rotation of the rotating body, and the pressure of the liquid discharged from the hydraulic pump during the rotation of the rotating body A pressure detecting means for detecting a value, a rotational speed detecting means for detecting the rotational speed per unit time of the previous rotating body when the pressure value of the liquid is detected by the pressure detecting means, and discharge from the hydraulic pump Storage means for storing a model expression representing the relationship between the pressure value of the liquid to be performed, the number of rotations of the rotating body per unit time, and the unknown parameter relating to the liquid discharge amount of the hydraulic pump, and the storage unit Using the model formula stored in the table, the pressure value of the liquid detected by the pressure detection unit and the number of rotations per unit time of the rotating body detected by the rotation number detection unit Calculated by the unknown parameter calculating means for calculating the parameter, and the unknown parameter calculating means for the known parameter relating to the liquid discharge amount of the hydraulic pump calculated before the unknown parameter is calculated by the unknown parameter calculating means. Discharge amount change degree calculating means for calculating the degree of decrease of the unknown parameter.

  In the above-described hydraulic pump failure diagnosis apparatus, the pressure value of the liquid discharged from the hydraulic pump and the corresponding number of rotations per unit time of the rotating body without measuring the amount of liquid discharged from the hydraulic pump. Thus, failure diagnosis of the hydraulic pump based on the liquid discharge amount can be performed. Specifically, the relationship between the pressure value of the liquid discharged from the hydraulic pump and the rotational speed per unit time of the rotating body of the hydraulic pump is a model equation including an unknown parameter related to the liquid discharge amount of the hydraulic pump. Can be expressed as Then, the unknown parameter is calculated by substituting the pressure value detected by the pressure detection means and the rotation speed per unit time detected by the rotation speed detection means correspondingly to the model equation. Is done. Then, the degree of decrease of the unknown parameter with respect to the known parameter calculated before calculating the unknown parameter is calculated. Here, the known parameter is a parameter relating to the liquid discharge amount of the hydraulic pump calculated in the past by the same method as the unknown parameter. In the above hydraulic pump failure diagnosis apparatus, the degree of decrease of the unknown parameter with respect to the known parameter is calculated, so that the liquid at the time when the unknown parameter with respect to the discharge amount of the hydraulic pump at the time when the known parameter is calculated is calculated. The reduction degree of the discharge amount of the pressure pump becomes clear. Thus, in the above-described hydraulic pump failure diagnosis apparatus, based on the pressure value detected by the pressure detection means and the rotation speed per unit time detected by the rotation speed detection means corresponding to the pressure value, A decrease degree of the discharge amount of the pressure pump is calculated, and a failure of the hydraulic pump is diagnosed from the decrease degree. Therefore, for example, it is possible to diagnose a failure of the hydraulic pump based on the discharge amount of the hydraulic pump while suppressing an increase in cost by providing a flow meter or the like.

  It is preferable that the discharge amount change degree calculating means calculates a ratio between the unknown parameter and the known parameter as a degree of decrease of the unknown parameter with respect to the known parameter.

  In the above-described hydraulic pump failure diagnosis apparatus, the ratio between the unknown parameter and the known parameter is employed as an index representing the degree of decrease of the unknown parameter with respect to the known parameter. That is, in the above-described hydraulic pump failure diagnosis apparatus, the failure of the hydraulic pump is diagnosed on the basis of the change rate of the discharge amount of the liquid in the hydraulic pump, thereby enabling highly accurate diagnosis.

  The hydraulic pump failure diagnosis apparatus according to the present invention includes a temperature detection unit that detects a temperature of the liquid discharged from the hydraulic pump, and a correction that corrects the unknown parameter based on the temperature of the liquid detected by the temperature detection unit. And means.

  The discharge amount of the liquid in the hydraulic pump changes depending on the kinematic viscosity of the liquid. The kinematic viscosity changes depending on the temperature of the liquid. That is, the unknown parameter in the model formula depends on the temperature of the liquid discharged from the hydraulic pump.

  In the above-described hydraulic pump failure diagnosis apparatus, even when the temperature of the liquid at the time of calculating the unknown parameter is different from that at the time of calculating the known parameter, by correcting the unknown parameter of the model equation by the temperature, the liquid The degree of decrease in the discharge amount can be calculated accurately.

  The failure diagnosis apparatus for a hydraulic pump according to the present invention includes a determination unit that determines whether or not a decrease degree of the unknown parameter with respect to the known parameter calculated by the discharge amount change degree calculation unit exceeds a predetermined threshold value. It is preferable to further provide.

  In the above-described hydraulic pump failure diagnosis apparatus, it is determined whether or not the degree of decrease in the liquid discharge amount in the hydraulic pump exceeds a predetermined threshold value, and the presence or absence of a hydraulic pump failure is determined from the determination result. be able to.

When the pressure value of the liquid discharged from the hydraulic pump is P, the number of rotations per unit time of the rotating body is N, and the unknown parameter relating to the liquid discharge amount of the hydraulic pump is α, the model formula is , P = αN ^{1 / n} + P ₀ , and the unknown parameter calculation means calculates the number of rotations per unit time of three or more rotating bodies different from each other with respect to the model formula, Respectively, by substituting the pressure value of the liquid discharged from the hydraulic pump corresponding to the above, the α, P ₀ and n are calculated, and the model equation is approximated linearly. It is preferable to correct the value.

  In the above-described hydraulic pump failure diagnosis apparatus, the pressure detection means and the rotation speed detection means detect three or more different rotation speeds and the pressure values of the liquid corresponding to the rotation speeds, and determine the respective values. By substituting into the model formula, the unknown parameter can be calculated while approximating the model formula linearly.

  As described above, according to the present invention, there is provided a fault diagnosis device for a hydraulic pressure pump capable of diagnosing a fault based on a discharge amount while suppressing an increase in cost.

It is a schematic block diagram which shows the failure diagnostic apparatus and hydraulic circuit of the hydraulic pump which concern on this embodiment. It is a flowchart figure which shows the operation | movement procedure of the failure diagnosis apparatus of the hydraulic pump which concerns on this embodiment. It is a graph which shows the relationship between the pressure value and rotation speed in the hydraulic pump which concerns on this embodiment.

  Hereinafter, an embodiment of the present invention will be described with reference to the drawings. However, for convenience of explanation, each drawing referred to below shows a simplified main part necessary for explaining the present embodiment, out of the constituent parts of the embodiment of the present invention. Therefore, the failure diagnosis device for a hydraulic pump according to the present invention can include any component not shown in each drawing referred to in this specification.

  FIG. 1 shows a hydraulic pump failure diagnosis apparatus X1 according to this embodiment. This failure diagnosis device X1 is applied to failure diagnosis of the hydraulic pump 2 included in the hydraulic circuit Y1.

  The hydraulic circuit Y1 is mounted on a construction machine such as a hydraulic excavator, for example, and plays a role of actuating the components of the construction machine with hydraulic oil. The hydraulic circuit Y1 includes the hydraulic pump 2 that discharges hydraulic oil, a drive source 3 such as an engine that drives the hydraulic pump 2, and first to third hydraulic pipes 4a to 4c that serve as a hydraulic oil circulation path. , An oil tank 5 that stores hydraulic oil, a hydraulic cylinder 6 that expands and contracts when supplied with hydraulic oil, and a control valve 7.

  The hydraulic pump 2 has a role of discharging hydraulic oil to the hydraulic cylinder 6. Specifically, the hydraulic pump 2 is connected to the oil tank 5 via the first hydraulic pipe 4a. The hydraulic pump 2 is connected to the hydraulic cylinder 6 via the second hydraulic pipe 4b. The hydraulic pump 2 is connected to the output shaft of the drive source 3, and the drive source 3 drives the hydraulic pump 2.

  The hydraulic oil sucked into the hydraulic pump 2 from the oil tank 5 through the first hydraulic pipe 4a is discharged from the hydraulic pump 2 driven by the drive source 3 to the second hydraulic pipe 4b. Then, the hydraulic oil discharged from the hydraulic pump 2 to the second hydraulic pipe 4 b is supplied to the hydraulic cylinder 6 via the control valve 7.

  The hydraulic pump 2 includes, for example, a plurality of pistons and a rotating body 2a that holds the plurality of pistons. In the hydraulic pump 2, when the rotating body 2 a rotates in response to a drive signal from the driving source 3, each piston held by the rotating body 2 a sequentially performs a piston motion, so that the hydraulic oil is supplied from the hydraulic pump 2. Is discharged.

  The hydraulic cylinder 6 has a role which operates the structural member of a construction machine, for example. The hydraulic cylinder 6 has a piston part and a cylinder part. The hydraulic cylinder 6 is connected to the second hydraulic pipe 4b and the third hydraulic pipe 4c via a control valve 7. When hydraulic oil is supplied from the second hydraulic pipe 4b to the hydraulic cylinder 6, the hydraulic oil is sent to the oil tank 5 via the control valve 7 and the third hydraulic pipe 4c.

  Next, the configuration of the failure diagnosis apparatus X1 according to the present embodiment will be described with reference to FIG.

  The failure diagnosis apparatus X1 includes a pressure sensor 10 that detects the pressure value of the hydraulic oil, a speed sensor 20 that detects the rotational speed of the hydraulic pump 2, a temperature sensor 30 that detects the temperature of the hydraulic oil, The calculation determination unit 40 that performs various calculations from the detected values 20 and 30 and the determination unit 46 that determines a failure from the calculation result of the calculation determination unit 40 are provided.

  The pressure sensor 10 is a member corresponding to the pressure detection means according to the present invention. The pressure sensor 10 has a role of detecting the pressure value of the hydraulic oil discharged by the hydraulic pump 2. The pressure sensor 10 is connected to a portion in the vicinity of the hydraulic pump 2 in the second hydraulic pipe 4b located on the downstream side of the hydraulic pump 2, and thereby the pressure value as the discharge pressure of the hydraulic pump 2 is determined. To detect. The pressure value information of the hydraulic oil detected by the pressure sensor 10 is sent to the calculation determination unit 40.

  The speed sensor 20 has a role of detecting the rotational speed of the rotating body 2 a of the hydraulic pump 2. The speed sensor 20 is connected to, for example, a connection point between the hydraulic pump 2 and the drive source 3 that rotates the rotating body 2a of the hydraulic pump 2. The rotational speed information of the rotating body 2 a of the hydraulic pump 2 detected by the speed sensor 20 is sent to the calculation determination unit 40.

  The temperature sensor 30 is a member corresponding to the temperature detection means according to the present invention. The temperature sensor 30 has a role of detecting the temperature of the hydraulic oil discharged by the hydraulic pump 2. The temperature sensor 30 is connected to, for example, the hydraulic pump 2 and detects the temperature of the hydraulic oil that passes through the hydraulic pump 2. The temperature information of the hydraulic oil detected by the temperature sensor 30 is sent to the calculation determination unit 40. The temperature sensor 30 may be connected to the upstream side or the downstream side of the hydraulic pump 2 in the hydraulic oil circulation path, for example. Moreover, when the calculation determination part 40 does not have the correction | amendment part 44 mentioned later, the temperature sensor 30 does not need to be.

  The arithmetic determination unit 40 is a hydraulic pump based on the hydraulic oil pressure value detected by the pressure sensor 10, the rotational speed of the rotating body 2 a detected by the speed sensor 20, and the hydraulic oil temperature detected by the temperature sensor 30. It has a role of performing various calculations and determinations for diagnosing two failures. The operation determination unit 40 is constituted by, for example, a CPU, ROM, RAM, EEPROM, or the like.

  The operation determination unit 40 functionally includes a rotation speed calculation unit 41, a storage unit 42, an unknown parameter calculation unit 43, a correction unit 44, a discharge amount change degree calculation unit 45, and a determination unit 46. ing.

  The rotation speed calculation unit 41 calculates the rotation speed per unit time of the hydraulic pump 2 when the pressure sensor 10 detects the pressure value. A pressure value detection signal is sent from the pressure sensor 10 to the rotation speed calculation unit 41, and rotation speed information of the hydraulic pump 2 is sent from the speed sensor 20. The rotation speed calculation unit 41 that has received the pressure value detection signal from the pressure sensor 10 per unit time of the hydraulic pump 2 when receiving the pressure value detection signal from the rotation speed information received from the speed sensor 20. The number of rotations is calculated. The rotation speed calculation unit 41 sends information on the calculated rotation speed to the unknown parameter calculation unit 43.

  In the present embodiment, the speed sensor 20 and the rotation speed calculation unit 41 calculate the rotation speed per unit time of the hydraulic pump 2 as described above, and therefore the speed sensor 20 and the rotation speed calculation unit 41 according to the present invention. It corresponds to a rotational speed detection means.

  The storage unit 42 stores information necessary for various calculations and determinations in the unknown parameter calculation unit 43, the correction unit 44, the discharge amount change degree calculation unit 45, and the determination unit 50.

  The unknown parameter calculation unit 43 refers to the model formula stored in the storage unit 42 and calculates an unknown parameter in the model formula. In the storage unit 42, the pressure value of the hydraulic oil discharged from the hydraulic pump 2, the number of rotations of the rotating body 2 a of the hydraulic pump 2 per unit time, and the amount of hydraulic oil discharged from the hydraulic pump 2 are unknown. A model expression representing the relationship between parameters is stored. The unknown parameter calculation unit 43 refers to the model formula stored in the storage unit 42, and the hydraulic oil pressure value received from the pressure sensor 10 and the rotating body 2a received from the rotation number calculation unit 41 with respect to the model formula. The unknown parameter is calculated by substituting the number of revolutions per unit time.

  The correction unit 44 corrects the unknown parameter calculated by the unknown parameter calculation unit 43 based on the temperature information of the hydraulic oil received from the temperature sensor 30. The storage unit 42 stores temperature information of hydraulic oil discharged from the hydraulic pump 2 when calculating a known parameter to be described later. The correction unit 44 refers to the temperature information stored in the storage unit 42 and compares the stored temperature information with the temperature information received from the temperature sensor 30. If the temperature difference between the two is large, the unknown parameter calculated by the unknown parameter calculation unit 43 is corrected.

  The discharge amount change degree calculation unit 45 refers to the known parameter stored in the storage unit 42 and calculates the ratio between the known parameter and the unknown parameter. The storage unit 42 stores known parameters related to the discharge amount of hydraulic oil in the hydraulic pump 2. This known parameter is a parameter calculated by the same method as the unknown parameter calculation method before calculating the unknown parameter. The known parameter is calculated, for example, when the hydraulic pump 2 is shipped or when the hydraulic pump 2 is driven for the first time after shipment. Then, the discharge amount change degree calculation unit 45 calculates the ratio between the known parameter stored in the storage unit 42 and the unknown parameter calculated by the unknown parameter calculation unit 43 or the correction value of the unknown parameter. Here, since the unknown parameter and the known parameter are the same parameters relating to the discharge amount of the hydraulic oil in the hydraulic pump 2, the ratio corresponds to the change rate of the discharge amount of the hydraulic oil in the hydraulic pump 2.

  In this embodiment, the discharge amount change degree calculation unit 45 calculates the ratio between the known parameter and the unknown parameter. However, the present invention is not limited to this, and calculates the degree of decrease of the unknown parameter with respect to the known parameter. I just need it. For example, the discharge amount change degree calculation unit 45 may calculate the degree of reduction by subtracting an unknown parameter from a known parameter.

  The determination unit 46 has a role of determining whether or not the hydraulic pump 2 has failed from the discharge amount change ratio calculated by the discharge amount change degree calculation unit 45. Specifically, the determination unit 46 compares the discharge amount change ratio sent from the discharge amount change degree calculation unit 45 with a predetermined threshold value stored in the storage unit 42, and the discharge amount change ratio is a predetermined threshold value. When it is above, it is determined that the hydraulic pump 2 has a failure.

  Note that the functions corresponding to the rotation speed calculation unit 41, the storage unit 42, the unknown parameter calculation unit 43, the correction unit 44, the discharge amount change degree calculation unit 45, and the determination unit 46 may be realized by software. It may be realized by hardware. Further, the functions corresponding to the rotation speed calculation unit 41, the storage unit 42, the unknown parameter calculation unit 43, the correction unit 44, the discharge amount change degree calculation unit 45, and the determination unit 46 are realized by individual functional components. Alternatively, it may be realized by a common functional component.

  Here, the operation procedure of the failure diagnosis apparatus X1 will be described in detail with reference to FIG.

  When the drive source 3 drives the hydraulic pump 2, hydraulic oil is discharged from the hydraulic pump 2 to the second hydraulic pipe 4 b according to the rotation of the rotating body 2 a of the hydraulic pump 2. The pressure sensor 10 detects the pressure value of the hydraulic oil discharged from the hydraulic pump 2 to the second hydraulic pipe 4b. The speed sensor 20 detects the rotational speed of the rotating body 2 a of the hydraulic pump 2. The arithmetic determination unit 40 receives the pressure value information of the hydraulic oil from the pressure sensor 10 and receives the rotation speed information of the rotating body 2a from the speed sensor 20 (Op1). And the rotation speed calculation part 41 is the rotation speed per unit time of the rotary body 2a when the pressure sensor 10 detects the pressure value of hydraulic fluid from the rotation speed information of the hydraulic pump 2 which the calculation determination part 40 received. Is calculated (Op2). Thereby, the rotation speed per unit time of the rotating body 2a and the pressure value of the hydraulic oil discharged from the hydraulic pump 2 corresponding to the rotation speed are obtained.

  In the present embodiment, two or more different rotation speeds and the pressure values corresponding to the rotation speeds are obtained. At this time, the hydraulic pump 2 is in a no-load state and fixes tilting. Thus, by obtaining two or more different rotation speeds and the pressure values corresponding to the rotation speeds, the unknown parameter α can be calculated by the unknown parameter calculation unit 43 described later.

  In addition, when calculating | requiring two or more said rotation speeds which are mutually different as mentioned above, and the said pressure value corresponding to each said rotation speed, it is preferable that the temperature of the hydraulic fluid which the hydraulic pump 2 discharges is not changed as much as possible.

  Next, the unknown parameter calculation unit 43 calculates the unknown parameter of the model formula using the model formula stored in the storage unit 42.

  Specifically, first, the relationship between the pressure value of the hydraulic oil discharged from the hydraulic pump 2 and the number of revolutions per unit time of the rotating body 2a of the hydraulic pump 2 can be expressed by the following mathematical formula.

ここで、上記の数式におけるｑは、回転体２ａの１回転あたりに液圧ポンプ２から吐出される作動油の流量である。Ｎは、回転体２ａの単位時間あたりの回転数である。Ｃは、流出係数であって、作動油の動粘度に関する関数である。作動油の動粘度は、当該作動油の温度に応じて変化する。Ａは、作動油が通過する面積に関する係数である。なお、本実施形態では、係数Ａは常に一定の値となる。Ｐは、液圧ポンプ２から吐出される作動油の圧力値である。Ｐ_０は、作動油の循環路のうち圧力センサ１０が接続される部位よりも下流側に位置する所定の部位における圧力値の推定値である。ｎは、例えば液圧ポンプ２の機種ごとに複数の実験データをとることによって予め求められる既知の値である。ｎの値は、例えば０．５〜１．０に設定される。なお、回転数Ｎの１／ｎ乗と圧力値Ｐとの関係が線形となるようにｎの値を補正してもよい。この場合、Ｏｐ１およびＯｐ２において、互いに異なる３つ以上の回転数と当該各回転数に対応する圧力値とを求める必要がある。

Here, q in the above formula is the flow rate of the hydraulic oil discharged from the hydraulic pump 2 per rotation of the rotating body 2a. N is the number of rotations per unit time of the rotating body 2a. C is an outflow coefficient, which is a function relating to the kinematic viscosity of the hydraulic oil. The kinematic viscosity of the hydraulic oil changes according to the temperature of the hydraulic oil. A is a coefficient relating to the area through which the hydraulic oil passes. In this embodiment, the coefficient A is always a constant value. P is a pressure value of the hydraulic oil discharged from the hydraulic pump 2. P ₀ is an estimated value of the pressure value at a predetermined part located downstream of the part where the pressure sensor 10 is connected in the hydraulic oil circulation path. For example, n is a known value obtained in advance by taking a plurality of experimental data for each model of the hydraulic pump 2. The value of n is set to 0.5 to 1.0, for example. Note that the value of n may be corrected so that the relationship between the rotational speed N to the 1 / nth power and the pressure value P is linear. In this case, at Op1 and Op2, it is necessary to obtain three or more different rotation speeds and pressure values corresponding to the rotation speeds.

Here, when the above mathematical formula is modified, the relationship between the pressure value P and the rotational speed N is expressed by the following model formula (X) having a slope α ^{1 / n} and an intercept being a linear function of P _0. .

記憶部４２は、上記のモデル式（Ｘ）を記憶している。このモデル式（Ｘ）におけるαは、未知パラメータ算出部４３により算出される未知パラメータである。未知パラメータ算出部４３は、記憶部４２に記憶された上記のモデル式（Ｘ）を参照し、当該モデル式（Ｘ）の圧力値Ｐに圧力センサ１０から受け付けた圧力値を代入するとともに、回転数Ｎに回転数算出部４１により算出された回転数を代入することにより、未知パラメータαおよびＰ_０を算出する。なお、圧力値Ｐおよび回転数Ｎは、圧力センサ１０および速度センサ２０において検出される瞬時の値でなくともよい。例えば、圧力値Ｐは、各回転数Ｎにおける所定期間内に圧力センサ１０が検出した圧力値の平均値であってもよい。圧力値Ｐとして前記平均値を採用すると、外乱あるいはノイズの影響を低減することができ、これにより未知パラメータαおよびＰ_０を正確に算出することができる。

The storage unit 42 stores the model formula (X). Α in the model formula (X) is an unknown parameter calculated by the unknown parameter calculation unit 43. The unknown parameter calculation unit 43 refers to the model equation (X) stored in the storage unit 42, substitutes the pressure value received from the pressure sensor 10 for the pressure value P of the model equation (X), and rotates The unknown parameters α and P ₀ are calculated by substituting the number of rotations calculated by the number-of-rotations calculation unit 41 into the number N. Note that the pressure value P and the rotational speed N do not have to be instantaneous values detected by the pressure sensor 10 and the speed sensor 20. For example, the pressure value P may be an average value of the pressure values detected by the pressure sensor 10 within a predetermined period at each rotation speed N. When the average value is adopted as the pressure value P, the influence of disturbance or noise can be reduced, and thereby the unknown parameters α and P ₀ can be accurately calculated.

  The temperature sensor 30 detects the temperature of the hydraulic oil that passes through the hydraulic pump 2. For example, when the rotating body 2a is rotated for N seconds at a rotation speed of N times per unit time and the pressure sensor 10 detects a plurality of pressure values during the rotation, the temperature sensor 30 is Obtain the average temperature of the detected hydraulic oil. And the average value of the said temperature is calculated | required for every rotation speed of the rotary body 2a, and the value which further averaged this can be made into the net temperature of hydraulic fluid.

  The operation determination unit 40 receives the temperature information of the hydraulic oil from the temperature sensor 30 (Op4). And the correction | amendment part 44 determines whether the temperature of hydraulic fluid exists in the predetermined | prescribed range from the said temperature information which the calculation determination part 40 received (Op5).

Here, the unknown parameter α is a parameter represented by the discharge amount q of the hydraulic oil, the coefficient A, and the outflow coefficient C. In a later-described discharge amount change degree calculation unit 45, the unknown parameter α _i calculated by the unknown parameter calculation unit 43 at a certain point in time and the known parameter α ₀ calculated by the same method before the unknown parameter α _i is calculated. From this ratio, the discharge amount change ratio of the hydraulic oil discharged from the hydraulic pump 2 is obtained. Here, the outflow coefficient C in the unknown parameter α is a function relating to the kinematic viscosity of the hydraulic oil, and the kinematic viscosity changes depending on the temperature of the hydraulic oil. Therefore, when the difference between the temperature T _i of the hydraulic oil at the time when the unknown parameter α _i is calculated and the temperature T ₀ of the hydraulic oil at the time when the known parameter α ₀ is calculated is large, the outflow coefficient C _i and the outflow coefficient the difference between the C ₀ increases. For this reason, if the ratio between the unknown parameter α _i and the known parameter α ₀ is calculated by approximating C _i = C ₀ , the ratio does not correctly represent the hydraulic oil discharge amount change ratio.

Therefore, in this embodiment, the correction unit 44, the absolute of the difference between the temperature T ₀ of the hydraulic oil at the time of the temperature T _i and the known parameters alpha ₀ of the hydraulic oil at the time of the unknown parameter alpha _i is calculated is calculated When the value is equal to or smaller than the predetermined value (YES at Op5), it approximates to C _i = C ₀ . On the other hand, the correction unit 44, the absolute value of the predetermined value of the difference between the temperature T ₀ of the hydraulic oil at the time of the temperature T _i and the known parameters alpha ₀ of the hydraulic oil at the time of the unknown parameter alpha _i is calculated is calculated If it exceeds (NO at Op5), the unknown parameter α is corrected (Op7). This correction method is as follows.

  The relationship between the outflow coefficient C and the kinematic viscosity ν of the hydraulic oil is expressed by, for example, the following mathematical formula (Y).

なお、上記の数式（Ｙ）におけるａおよびｂは、事前に算出された実験データから求まる既知の値である。

Note that a and b in the above formula (Y) are known values obtained from experimental data calculated in advance.

  Further, the relationship between the kinematic viscosity ν of the hydraulic oil and the temperature T of the hydraulic oil is expressed, for example, by the following mathematical formula (Z) known as Walter's empirical formula.

なお、上記の数式（Ｚ）におけるＢおよびＤは、作動油によって決まる定数である。なお、定数Ｂおよび定数Ｄは、実験データから事前に算出してもよい。

In addition, B and D in said numerical formula (Z) are constants determined by hydraulic fluid. The constant B and the constant D may be calculated in advance from experimental data.

When the correction unit 44 determines NO in Op5, the kinematic viscosity ν ₀ is calculated by substituting the temperature T ₀ of the hydraulic oil at the time when the known parameter α ₀ is calculated into the formula (Z), The outflow coefficient C ₀ is calculated by substituting the kinematic viscosity ν ₀ into the formula (Y). Both the known parameter α ₀ and the temperature T ₀ are stored in the storage unit 42. Note that this storage unit 42, the discharge coefficient C ₀ may be stored directly. Moreover, to calculate the kinematic viscosity [nu _0i by substituting the temperature T _i of the hydraulic oil at the time of the unknown parameter alpha _i is calculated in formula (Z), substituting the kinematic viscosity [nu _i in Equation (Y) Thus, the outflow coefficient C _i is calculated. The unknown parameter α is corrected from the outflow coefficient C _i calculated in this way (Op7).

Next, the discharge amount change degree calculation unit 45 calculates the unknown parameter α _i calculated by the unknown parameter calculation unit 43 and the known parameter α ₀ calculated by the same method before the unknown parameter α _i is calculated. From the ratio, the hydraulic oil discharge rate change ratio in the hydraulic pump 2 is calculated (Op6).

Specifically, the ratio J between the discharge amount q _i of the hydraulic pump 2 at the time when the unknown parameter α _i is calculated and the discharge amount q ₀ of the hydraulic pump 2 at the time when the known parameter α ₀ is calculated is: It is expressed by the following mathematical formula.

上式では、吐出量ｑ_ｉの係数となる断面積Ａが吐出量ｑ_０の係数となる断面積Ａによって除されている。このため、比率Ｊは、断面積Ａを算出せずとも求めることができる。

In the above equation, the cross-sectional area A that is the coefficient of the discharge amount q _i is divided by the cross-sectional area A that is the coefficient of the discharge amount q ₀ . For this reason, the ratio J can be obtained without calculating the cross-sectional area A.

Here, when it is determined YES in Op5 and the unknown parameter α _i is not corrected, it is approximated as C _i = C ₀ . Accordingly, the ratio J between the discharge amount q _i and the discharge amount q ₀ is expressed by the following mathematical formula.

上式では、吐出量ｑ_ｉの流出係数Ｃ_ｉと近似される流出係数Ｃ_０が吐出量ｑ_０の流出係数Ｃ_０によって除されている。このため、比率Ｊは、流出係数Ｃを算出せずとも求めることができる。

In the above equation, the discharge coefficient C ₀ is divided by the discharge coefficient C ₀ of the discharge amount q ₀ which is approximated to discharge coefficient C _i of discharge quantity q _i. Therefore, the ratio J can be obtained without calculating the outflow coefficient C.

Thus, the ratio J between the discharge amount q _i and the discharge amount q ₀ is expressed by the n-th power of the ratio between the unknown parameter α _i and the known parameter α ₀ . The discharge amount change degree calculation unit 45 calculates the ratio J between the discharge amount q _i and the discharge amount q ₀ by substituting the unknown parameter α _i and the known parameter α ₀ into the above formula. Thereby, the discharge amount change ratio of the hydraulic oil in the hydraulic pump 2 is calculated.

Incidentally, if the answer is NO in Op5, the ratio of the formula (Y) and Equation discharge coefficient calculated by (Z) _{C 0} and the discharge coefficient _{C i} of each discharge quantity _{q i} and the discharge amount _{q 0} The ratio J is calculated by substituting into the above equation for J.

  Next, the determination unit 46 determines whether or not the discharge amount change ratio is equal to or more than the threshold stored in the determination unit 46 based on the discharge amount change ratio calculated by the discharge amount change degree calculation unit 45. (Op8).

  When the determination unit 46 determines that the discharge amount change ratio is equal to or greater than the threshold (YES at Op8), the determination unit 46 determines that the hydraulic pump 2 has a failure (Op9), and determines the determination result. For example, it is displayed on a liquid crystal monitor. If the determination unit 46 determines that the discharge rate change ratio is not equal to or greater than the threshold (NO at Op8), the determination unit 46 determines that there is no failure in the hydraulic pump 2 (Op10), and the determination result. Is displayed on a liquid crystal monitor, for example. The user refers to, for example, the determination result displayed on the liquid crystal monitor or the like, and determines whether or not the hydraulic pump 2 has failed.

Note that the determination unit 46 may not be provided. For example, as illustrated in FIG. 3, the graph L ₀ indicating the model equation (X) at the time when the known parameter α ₀ is calculated and the model at the time when the unknown parameter α _i is calculated. wherein the graph L _i indicating the (X) may be displayed on the LCD monitor or the like. In this case, the user determines whether or not there is a failure in the hydraulic pump 2 by confirming the slope of the graph L _i with respect to the graph L ₀ . Further, by obtaining the ratio J between the discharge amount q _i and the discharge amount q ₀ every predetermined period, the time series change of the ratio J may be displayed on the liquid crystal monitor or the like, for example. In this case, the user determines whether or not the hydraulic pump 2 has failed by checking the time series change of the ratio J.

  The various calculations described above may be performed in a remote place away from the construction machine on which the hydraulic circuit Y1 is mounted, for example. Specifically, various data detected by the pressure sensor 10, the speed sensor 20, and the temperature sensor 30 are sent to a remote place, and the user calculates the ratio J in the remote place, so that the user can obtain the hydraulic pump 2 Whether or not there is a failure may be determined.

  In this way, the failure diagnosis of the hydraulic pump 2 by the failure diagnosis device X1 is completed.

  As described above, in the failure diagnosis apparatus X1, the pressure value of the liquid discharged from the hydraulic pump 2 and the corresponding unit time of the rotating body 2a can be measured without measuring the amount of hydraulic oil discharged from the hydraulic pump 2. , The failure diagnosis of the hydraulic pump 2 can be performed based on the liquid discharge amount. Specifically, in the failure diagnosis apparatus X1, the hydraulic pump 2 is based on the pressure value detected by the pressure sensor 10 and the rotation speed per unit time calculated by the rotation speed calculation unit 41 corresponding to the pressure value. The degree of decrease in the hydraulic oil discharge amount is calculated, and a failure of the hydraulic pump 2 is diagnosed from the degree of decrease. Therefore, for example, it is possible to diagnose a failure of the hydraulic pump 2 based on the discharge amount of the hydraulic pump 2 while suppressing an increase in cost by providing a flow meter or the like.

Further, in the fault diagnosis apparatus X1, as an index indicating the degree of decrease of the unknown parameters alpha _i to known parameters alpha _0, it adopts the ratio of the unknown parameter alpha _i and the known parameter alpha _0. That is, in the failure diagnosis device X1, the failure of the hydraulic pump 2 is diagnosed based on the change rate of the discharge amount of the liquid in the hydraulic pump 2, and a highly accurate diagnosis is possible.

Further, in the failure diagnosis apparatus X1, it is not necessary to calculate the outflow coefficient C and the cross-sectional area A when calculating the ratio J between the discharge quantity q _i and the discharge quantity q _0, and thus the outflow coefficient C and the cross-sectional area A are calculated. It can suppress that the calculation precision of the ratio J deteriorates by the influence of an estimation error. Specifically, the discharge amount q is a parameter obtained by multiplying the unknown parameter α by the outflow coefficient C and the cross-sectional area A, and when calculating the ratio J by dividing the discharge amount q ₀ from the discharge amount q _i , Since the outflow coefficient C and the cross-sectional area A are reduced, it is not necessary to calculate the outflow coefficient C and the cross-sectional area A in order to calculate the ratio J. As described above, the failure diagnosis apparatus X1 employs the ratio J as an index representing the degree of decrease in the unknown parameter α _i with respect to the known parameter α _0, thereby calculating the hydraulic pump without calculating the outflow coefficient C and the cross-sectional area A. 2 discharge amount change can be captured.

  Further, the failure diagnosis apparatus X1 detects two or more relationships between the rotational speed N of the hydraulic pump 2 and the pressure value P of the hydraulic oil discharged from the hydraulic pump 2 at the rotational speed N, and the rotational speed N Since the change rate J of the discharge amount q is estimated from the slope of the expression indicating the relationship between the pressure sensor 10 and the pressure value P, even if some offset is applied due to the change over time of the pressure sensor 10, it is not affected.

Further, in the failure diagnosis apparatus X1, even when the temperature T _i of the hydraulic oil at the time of calculating the unknown parameter α _i is different from the temperature T ₀ of the hydraulic oil at the time of calculating the known parameter α ₀ , the temperature T _i By correcting the unknown parameter α _i based on the above, the discharge rate change ratio of the hydraulic oil in the hydraulic pump 2 can be accurately calculated.

  Furthermore, in the failure diagnosis apparatus X1, the determination unit 46 determines whether the hydraulic oil discharge amount change ratio in the hydraulic pump 2 exceeds a predetermined threshold value, so that the hydraulic pump failure can be determined from the determination result. The presence or absence can be determined.

  In addition, although this embodiment demonstrated the example which diagnoses the failure of the hydraulic pump 2 which discharges hydraulic fluid with the failure diagnosis apparatus X1, it is not restricted to this. The failure diagnosis device X1 can also diagnose failure of a hydraulic pump that discharges a liquid such as warm water in addition to the hydraulic oil.

X1 Hydraulic pump failure diagnosis device 2 Hydraulic pump 2a Rotating body 10 Pressure sensor (pressure detection means)
20 Speed sensor 30 Temperature sensor (temperature detection means)
40 calculation unit 41 rotation speed calculation unit 42 storage unit (storage unit)
43 Unknown parameter calculation unit (unknown parameter calculation means)
44 Correction part (correction means)
45 Discharge amount change degree calculation unit (discharge amount change degree calculating means)
50 determination unit (determination means)

Claims (5)

A fault diagnosis device for a hydraulic pump that has a rotating body and discharges liquid along with the rotation of the rotating body,
Pressure detecting means for detecting the pressure value of the liquid discharged from the hydraulic pump during rotation of the rotating body;
A rotational speed detection means for detecting the rotational speed per unit time of the rotating body before the pressure value of the liquid is detected by the pressure detection means;
A memory for storing a model expression representing the relationship between the pressure value of the liquid discharged from the hydraulic pump, the number of rotations of the rotating body per unit time, and the unknown parameter relating to the liquid discharge amount of the hydraulic pump. Means,
Using the model formula stored in the storage unit, the unknown parameter from the pressure value of the liquid detected by the pressure detection unit and the rotation number per unit time of the rotating body detected by the rotation number detection unit An unknown parameter calculating means for calculating
Discharge for calculating the degree of decrease of the unknown parameter calculated by the unknown parameter calculation unit with respect to the known parameter related to the liquid discharge amount of the hydraulic pump calculated before the unknown parameter is calculated by the unknown parameter calculation unit A fault diagnosis device for a hydraulic pump, comprising: a degree-of-change calculation means.   The hydraulic pump failure diagnosis apparatus according to claim 1, wherein the discharge amount change degree calculation unit calculates a ratio between the unknown parameter and the known parameter as a degree of decrease of the already-known parameter with respect to the known parameter. Temperature detecting means for detecting the temperature of the liquid discharged from the hydraulic pump;
The hydraulic pump failure diagnosis apparatus according to claim 1, further comprising a correction unit that corrects the unknown parameter according to a temperature of the liquid detected by the temperature detection unit.   The determination unit according to claim 1, further comprising: a determination unit that determines whether or not a decrease degree of the already-known parameter with respect to the known parameter calculated by the discharge amount change degree calculation unit exceeds a predetermined threshold value. The fault diagnosis device for the hydraulic pump according to the item. When the pressure value of the liquid discharged from the hydraulic pump is P, the rotation number of the rotating body per unit time is N, and the unknown parameter related to the liquid discharge amount of the hydraulic pump is α,
The model formula is represented by P = αN ^{1 / n} + P ₀ ,
The unknown parameter calculation means includes a rotation number per unit time of three or more rotating bodies different from each other with respect to the model formula, and a pressure of the liquid discharged from the hydraulic pump corresponding to each rotation number 5. The α, P _0, and n are calculated by substituting the values respectively, and the value of the n is corrected so that the model equation is approximated linearly. The fault diagnosis device for the hydraulic pump according to the item.

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