HYDRAULIC UNIT AND METHOD OF CONTROLLING SPEED OF MOTOR IN HYDRAULIC UNIT

Description

TECHNICAL FIELD

[0001] The present invention relates to an oil pressure unit for driving an oil pressure pump with a motor.

BACKGROUND ART

[0002] Conventionally, in an oil pressure unit having an oil pressure pump directly connected to a motor as a drive source, a speed control (PI control) calculation is executed to calculate a current command value through comparison of a speed command value of the motor and a current rotation speed, and a current control based on the current command value is realized by an inverter. The motor controlled by the inverter is then driven so that pressure oil is discharged from the oil pressure pump (e.g., patent document 1).

[0003] Patent document 1: Japanese Laid-Open Patent Publication No. 2004-162860

DISCLOSURE OF THE INVENTION

Problems to be Solved by the Invention

[0004] In such oil pressure unit, the pressure of oil (oil pressure) becomes larger as a total amount of the oil discharged from the oil pressure pump by a drive of the oil pressure pump increases. An increase in the oil pressure leads to an increase in a load of the oil pressure pump in discharge, and causes a load torque of the motor to become larger.

[0005] Thus, in such oil pressure unit, in a case where a stepwise speed command value is provided, if a rotation speed of the motor drastically rises in response to the speed command value, the load of the oil pressure pump drastically increases and the load torque of the motor drastically becomes large. If the load torque of the motor drastically becomes large, the speed control constituted by the PI control cannot follow, and the rotation speed of the motor might lower.

[0006] A method of preventing lowering of the rotation speed of the motor includes a method of improving a response of the control by shortening a control period of the PI control by improving a processing speed of a microcomputer that performs the PI control. However, a cost of the microcomputer increases if such method is adopted. Furthermore, since the improvement of the processing speed of the microcomputer has physical limitations, lowering in the rotation speed of the motor cannot be effectively prevented with such method.

[0007] Another method includes a method using the load torque for the speed control in which the load torque is estimated from acceleration information obtained by differentiating the rotation speed of the motor. However, since the rotation speed is discrete information, a noise component increases by differentiation. Thus, there is a possibility a behavior will become unstable if the speed control is executed using the load torque.

[0008] Moreover, if a gain of the speed control is increased to improve a response to the load variation, an oscillation might occur when the stepwise speed command value is provided.

[0009] In view of the above problems, it is an object of the present invention to provide a technique capable of improving a followability of the rotation speed of the motor with respect to the variation of the load of the oil pressure pump. Means for Solving the Problems

[0010] A first aspect of an oil pressure unit according to the present invention relates to the oil pressure unit for supplying oil to an actuator by driving an oil pressure pump (16A) with a motor (15), characterized in that it comprises an inverter (14) for supplying power to the motor (15), a load sensor (17) for detecting a load of the oil pressure pump (16A), a rotation sensor (21) for detecting a rotation speed of the motor (15), a current command value calculation means (12) for calculating a current command value so that a deviation between a speed command value representing a target rotation speed of the motor (15) and a rotation speed of the motor (15) converges to zero, a correction means (18A; ... ; 18D) for correcting the current command value based on the load of the oil pressure pump (16A), and a control signal generation means (13) for outputting a control signal to the inverter (14) based on a corrected current command value.

[0011] According to a second aspect of the oil pressure unit, in the first aspect, it is characterized in that said correction means (18A; ... ;18D) corrects the current command value to raise the rotation speed of said motor (15) with an increase in the load of said oil pressure pump (16A).

[0012] According to a third aspect of the oil pressure unit, in the first or the second aspect, it is characterized in that said correction means (18A; ... ; 18D) increases the current command value with an increase in the load of said oil pressure pump (16A).

[0013] According to a fourth aspect of the oil pressure unit, in any one of the first to the third aspects, it is characterized in that said correction means (18A) acquires a correction value (Iv) using a correction coefficient (Kf) set in advance, and adds said correction value (Iv) to said current command value.

[0014] According to a fifth aspect of the oil pressure unit, in any one of the first to the third aspects, it is characterized in that said correction means (18B; 18C; 18D) acquires a correction value (Iv) using a data table DT acquired in advance, and adds said correction value (Iv) to said current command value.

[0015] According to a sixth aspect of the oil pressure unit, in any one of the first to the fifth aspects, it is characterized in that said load sensor (17) is a pressure sensor (17) for detecting a pressure of oil in a discharge line (19) of said oil pressure pump (16A).

[0016] A seventh aspect of the oil pressure unit relates to a speed control method of a motor (15) in the oil pressure unit for supplying oil to an actuator by driving an oil pressure pump (16A) with the motor (15) controlled by an inverter (14) and, characterized in that it comprises the steps of a) detecting a load of said oil pressure pump (16A); b) detecting a rotation speed of said motor (15); c) calculating a current command value so that a deviation between a speed command value representing a target rotation speed of said motor (15) and a rotation speed of said motor (15) converges to zero; d) correcting the current command value based on the load of said oil pressure pump (16A); and e) outputting a control signal to said inverter (14) based on the corrected current command value.

The Effect of the Invention

[0017] According to the first aspect to the seventh aspect of the oil pressure unit of the present invention, the followability of the rotation speed of the motor with respect to the variation of the load (load oil pressure) of the oil pressure pump can be improved since the current command value is corrected based on the load of the oil pressure pump.

[0018] In particular, according to the second aspect of the oil pressure unit of the present invention, lowering in rotation speed of the motor involved in an increase of the load of the oil pressure pump can be prevented since the current command value is corrected to raise the rotation speed of the motor with an increase in the load of the oil pressure pump.

[0019] The objects, features, aspects, and advantages of the present invention will become apparent from the following detailed description and the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

[0020] 

FIG. 1 is a schematic view showing a configuration of an oil pressure unit according to an embodiment.

FIG. 2 is a schematic view showing a configuration of an oil pressure unit without a correction part.

FIG. 3 is a view showing a state of an operation when a stepwise speed command is provided in the oil pressure unit according to the embodiment.

FIG. 4 is a view showing a state of an operation when a stepwise speed command is provided in the oil pressure unit not including a correction part.

FIG. 5 is a schematic view showing an oil pressure unit including a correction part capable of acquiring a correction value using a data table.

FIG. 6 is a schematic view showing an oil pressure unit in which two oil pressure pumps are driven with one motor.

FIG. 7 is a schematic view showing an oil pressure unit in which two oil pressure pumps are connected in series.

BEST MODE FOR CARRYING OUT THE INVENTION

[0021] An embodiment of the present invention will now be described with reference to the drawings.

<Configuration>

[0022] FIG. 1 is a schematic view showing a configuration of an oil pressure unit 10A according to the embodiment of the present invention. The oil pressure unit 10A is connected to a molding machine etc., and supplies oil as working fluid to an actuator (not shown) having the oil pressure as the power source.

[0023] As shown in FIG. 1, the oil pressure unit 10A includes a controller 20, an inverter unit 14, a motor 15, an oil pressure pump 16A, a pressure sensor 17, and a pulse generator 21. In the oil pressure unit 10A having such configuration, the oil is taken in from a tank (not shown) by the oil pressure pump 16A driven by the motor 15, and the oil is discharged. The discharged oil is supplied to the actuator such as an oil pressure cylinder or an oil pressure motor through a discharge line 19.

[0024] The pressure sensor 17 serves as a load sensor for detecting the load of the oil pressure pump. The pressure sensor 17 also detects the pressure (also referred to as "present pressure" or "load oil pressure") of the oil in the discharge line 19 of the oil pressure pump.

[0025] The pulse generator 21 serves as a rotation sensor for outputting a pulse signal for detecting the rotation speed of the motor to the controller 20 (speed detection part 22).

[0026] The inverter unit 14 controls the rotation number of the motor 15 by performing switching based on a control signal from the controller 20.

[0027] The controller 20 includes a P-Q control part 11, a current command value calculation part 12, a correction part 18A, a control signal generation part 13, and a speed detection part 22. The controller 20 outputs a control signal for driving the inverter.

[0028] The P-Q control part 11 generates discharge pressure-discharge flow rate characteristics (P-Q characteristics) based on a set pressure and a set flow rate from a higher level system such as a molding machine. The P-Q control part 11 outputs a speed command value based on the present pressure from the pressure sensor 17 as an input.

[0029] The current command value calculation part (also referred to as "PI control part") 12 performs a proportional-integral (PI) control with the speed command value and the current speed as inputs, and outputs a current command value. More specifically, the PI control part 12 calculates the current command value so that the deviation between speed command value representing the target rotation speed of the motor 15 and the rotation speed of the motor 15 converges to zero.

[0030] The correction part 18A corrects the current command value based on the present pressure from the pressure sensor 17. The details will be hereinafter described.

[0031] The control signal generation part 13 generates a control signal for controlling the inverter part 14 based on the corrected current command value.

<Correction unit>

[0032] The correction part 18A will now be described in detail.

[0033] FIG. 2 is a schematic view showing a configuration of a general oil pressure unit 10B. The oil pressure unit 10B has the same configuration as the oil pressure unit 10A other than that the correction part 18A is not equipped.

[0034] A high response is demanded on the molding machine to which the oil pressure unit 10B is connected from the standpoint of mass production. Thus, in the oil pressure unit 10B for driving the molding machine, a stepwise speed command is provided in a short cycle.

[0035] As the total amount of the oil discharged from the oil pressure pump 16A increases, the oil pressure (load oil pressure) in the discharge line 19 of the oil pressure pump 16A becomes larger. As the load oil pressure becomes larger, the load of the oil pressure pump 16A in discharge increases. That is, the load oil pressure and the load torque of the motor 15 are more or less in a proportional relationship, where the load torque of the motor 15 becomes larger as the load oil pressure becomes larger.

[0036] Therefore, in the oil pressure unit 10B, when the stepwise speed command is provided, the rotation speed of the motor 15 drastically rises in response to the speed command value. The load oil pressure drastically increases with rise in rotation speed of the motor 15. The load torque drastically becomes larger with an increase in the load oil pressure. Thus, the speed control by the PI control cannot be followed, and the rotation speed of the motor 15 lowers.

[0037] In order to prevent the lowering in the rotation speed of the motor 15 by an increase in load torque, the generated torque of the motor 15 needs to become larger with the increase in load torque. The generated torque of the motor 15 and the motor current are in proportional relationship, and thus the motor current, that is, the current command value merely needs to become large for the generated torque of the motor 15 to become large.

[0038] In brief, the followability of the rotation speed of the motor 15 with respect to variation of the load oil pressure can be improved by changing the current command value with variation of the load oil pressure. Furthermore, the lowering in the rotation speed of the motor 15 can be prevented by increasing the current command value with the increase in load oil pressure.

[0039] In the oil pressure unit 10A according to the present embodiment, the correction part 18A for correcting the current command value based on the load oil pressure is equipped. In the correction part 18A, the correction value (current correction value) Iv is acquired using the present pressure (pressure detected value) Pd detected by the pressure sensor 17 and a correction coefficient Kf acquired in advance. The correction value Iv is added to the current command value output from the current command value calculation part 12.

[0040] According to the correction part 18A, the current command value is corrected based on the load of the oil pressure pump 16A, that is, the pressure (load oil pressure) of the oil in the discharge line 19. Therefore, the followability of the rotation speed of the motor 15 with respect to the variation of the load (load oil pressure) of the oil pressure pump 16A can be enhanced (improved).

[0041] The coefficient acquired through tests in advance is used as the correction coefficient Kf. Specifically, the correction coefficient Kf is set so that the current command value necessary for preventing lowering in the rotation speed of the motor 15 and following the speed command can be acquired in the correction part 18A. The correction coefficient Kf can also be represented as being set so that the lack of current command value necessary for preventing lowering in the rotation speed of the motor 15 and following the speed command can be acquired as the correction value.

[0042] Through the use of the correction coefficient Kf set so that the lack of the current command value can be acquired as the correction value, the rotation speed of the motor 15 can be controlled to the rotation speed given by the speed command value.

[0043] The correction value Iv acquired using the correction coefficient Kf becomes larger with rise in load oil pressure. Thus, in the correction part 18A, the current command value can be corrected so as to raise the rotation speed of the motor 15 with the increase in load oil pressure, and lowering in rotation speed of the motor 15 involved in rise of the load oil pressure is prevented.

[0044] The operation in a case where a stepwise speed command SC is provided in the oil pressure unit 10A will now be specifically described. FIG. 3 is a view showing a state of an operation when a stepwise speed command SC is provided in the oil pressure unit 10A according to the present embodiment.

[0045] As shown in FIG. 3(a), when the stepwise speed command SC is provided in the oil pressure unit 10A, the rotation speed Rs1 of the motor 15 drastically rises in response to the speed command SC. The pressure Pd1 of the oil discharged from the oil pressure pump 16A then drastically increases, and the load torque of the motor 15 becomes larger.

[0046] However, in the oil pressure unit 10A, the correction value Iv which value becomes larger with the increase in the load oil pressure Pd1 is acquired in the correction part 18A. The correction value Iv is added to the output from the current command value calculation part 12, and the corrected current command value Ic1 is acquired (see FIG. 3(b)). The current command value Ic1 becomes larger following the increase in the load oil pressure Pd1, and thus the lowering in the rotation speed Rs1 of the motor 15 by the increase in load torque is prevented. The rotation speed Rs1 of the motor 15 thus can follow the rotation speed given by the speed command SC.

[0047] There will be compared the operation in a case where the stepwise speed command SC is provided in the oil pressure unit 10A with the operation in a case where the stepwise speed command SC is provided in the oil pressure unit 10B not including the correction part 18A. FIG. 4 is a view showing a state of an operation when the stepwise speed command SC is provided in the oil pressure unit 10B.

[0048] As shown in FIG. 4(a), when the stepwise speed command SC is provided in the oil pressure unit 10B, the rotation speed Rs2 of the motor 15 lowers by influence of an increase in the load oil pressure Pd2 due to drastic rise in the rotation speed Rs2 of the motor 15.

[0049] Comparing FIG. 3(b) with FIG. 4(b), the magnitude of the current command value is different in zone BT. The difference in magnitude of the current command value indicates that the appropriate current command value necessary for following the rotation speed of the motor 15 to the speed command SC is not acquired (calculated) in the oil pressure unit 10B (FIG. 4(b)).

[0050] Therefore, when the rapid speed command like the stepwise speed command SC is provided, the rotation speed of the motor 15 cannot be followed to such speed command with only the speed control constituted by the PI control.

[0051] In the present embodiment, the correction value Iv that becomes larger with the increase in the load oil pressure Pd is acquired using the load oil pressure Pd detected by the pressure sensor 17 and the correction coefficient Kf previously acquired in the correction part 18A. The relevant correction value Iv is added to the current command value output from the current command value calculation part 12.

[0052] As described above, the current command value Ic1 can be increased following the increase in the load oil pressure Pd1 by adding the correction value Iv acquired based on the load oil pressure Pd1 to the current command value output from the current command value calculation part 12 in a feedforward manner. The lowering in the rotation speed Rs1 of the motor 15 by the increase in load torque thus can be prevented.

<Modification>

[0053] The embodiment of the present invention has been described, but the present invention is not limited to the content described above.

[0054] For instance, in the above embodiments, the correction value Iv is acquired using the correction coefficient Kf previously acquired in the correction part 18A, but is not limited thereto. FIG. 5 is a schematic view showing an oil pressure unit 10C including a correction part 18B capable of acquiring the correction value Iv using a data table DT.

[0055] Specifically, the correction value Iv may be acquired (calculated) using a data table DT showing a relationship between the load oil pressure (pressure detected value) Pd acquired in advance and the correction value Iv in the correction part 18B, as shown in FIG. 5.

[0056] An appropriate correction value Iv thus can be acquired with respect to the load pressure Pd from the pressure sensor 17 even if the load pressure and the correction value necessary for following the speed command are not in a proportional relationship.

[0057] Furthermore, the oil pressure unit 10A is driven using one oil pressure pump 16A in the above embodiment, but is not limited thereto.

[0058] Specifically, the oil pressure unit may be driven using a plurality of oil pressure pumps. FIG. 6 is a schematic view showing an oil pressure unit 10D in which two oil pressure pumps 16A, 16B are driven with one motor.

[0059] For instance, as shown in FIG. 6, information (pump drive information) indicating which oil pressure pump is being driven is output to the correction part 18C from the P-Q control part 11 according to the switching of the pump when configuring the oil pressure unit 10D with two oil pressure pumps 16A, 16B. In the correction part 18C, the data table for acquiring the correction value Iv is switched according to the pump drive information, and the correction value Iv corresponding to the driven pump is acquired.

[0060] When simultaneously driving the two oil pressure pumps 16A, 16B, the data table showing a relationship between the load oil pressure (pressure detected value) Pd and the correction value Iv in a case where the two oil pressure pumps 16A, 16B are simultaneously driven is used to acquire the correction value Iv.

[0061] The two oil pressure pumps 16A, 16B do not need be connected in parallel. FIG. 7 is a schematic view showing an oil pressure unit in which two oil pressure pumps are connected in series. As shown in FIG. 7, when the two oil pressure pumps are connected in series such that the oil discharged from one oil pressure pump 16B is taken in by the other oil pressure pump 16A, the pressure of the oil discharged form the oil pressure pump 16A on the downstream side is detected by the pressure sensor (17). The current command value is corrected based on the oil pressure discharged by the oil pressure pump 16A on the downstream side.

[0062] Although the present invention has been described in detail above, the above description is merely illustrative in all aspects and the present invention should not be limited by the description. It should be recognized that a number of modifications that are not illustrated can be contrived without deviating from the scope of the invention as defined by the appended claims.

Claims

1. An oil pressure unit for supplying oil to an actuator by driving an oil pressure pump (16A) with a motor (15), the oil pressure unit comprising.
an inverter (14) for supplying electric power to said motor (15);
a load sensor (17) for detecting a load of said oil pressure pump (16A);
a rotation sensor (21) for detecting a rotation speed of said motor (15);
a current command value calculation means (12) for calculating a current command value so that a deviation between a speed command value representing a target rotation speed of said motor (15) and a rotation speed of said motor (15) converges to zero;
a correction means (18A; ... ; 18D) for correcting said current command value based on the load of said oil pressure pump; and
a control signal generation means (13) for outputting a control signal to said inverter (14) based on a corrected current command value,
characterized in that
said correction means (18B; 18C; 18D)
increases said current command value to bring a rotation speed of said motor (15) near to said target rotation speed, with an increase in the load of said oil pressure pump (16A).

2. The oil pressure unit according to claim 1, characterized in that said correction means (18A; ... ; 18D) corrects said current command value to raise the rotation speed of said motor (15) with an increase in the load of said oil pressure pump (16A).

3. The oil pressure unit according to claim 1 or 2, characterized in that said correction means (18A; ; 18D) increases said current command value with an increase in the load of said oil pressure pump (16A).

4. The oil pressure unit according to one of the preceeding claims, characterized in that said load sensor (17) is a pressure sensor (17) for detecting a pressure of oil in a discharge line (19) of said oil pressure pump (16A).

Ansprüche

1. Öldruckeinheit zum Bereitstellen von Öl an einen Aktuator durch Antreiben einer Öldruckpumpe (16A) mit einem Motor (15), wobei die Öldruckeinheit aufweist:

einen Wechselrichter (14) zum Zuführen von elektrischem Strom zum Motor (15);

einen Kraftsensor (17) zum Erfassen einer Last der Öldruckpumpe (16A);

einen Rotationssensor (21) zum Erfassen einer Drehzahl des Motors (15);

ein Strom-Befehlswert-Berechnungsmittel (12) zur Berechnung eines Strom-Befehlswerts, so dass eine Abweichung zwischen einem Drehzahlbefehlswert, der eine Solldrehzahl des Motors (15) darstellt, und einer Drehzahl des Motors (15) gegen Null konvergiert;

ein Korrekturmittel (18A; ... ; 18D) zum Korrigieren des Strom-Befehlswerts basierend auf der Last der Öldruckpumpe; und

ein Steuersignal-Erzeugungsmittel (13) zum Ausgeben eines Steuersignals an den Wechselrichter (14) basierend auf einem korrigierten Strom-Befehlswert,

dadurch gekennzeichnet, dass

das Korrekturmittel (18B; 18C; 18D) den Strom-Befehlswert erhöht, um eine Drehzahl des Motors (15) nahe der Solldrehzahl zu bewirken bei einem Anstieg der Last der Öldruckpumpe (16A).

2. Öldruckeinheit nach Anspruch 1, dadurch gekennzeichnet, dass das Korrekturmittel (18A; ... ; 18D) den Strom-Befehlswert korrigiert, um die Drehzahl des Motors (15) mit einem Anstieg der Last der Öldruckpumpe (16A) zu erhöhen.

3. Öldruckeinheit nach Anspruch 1 oder 2, dadurch gekennzeichnet, dass das Korrekturmittel (18A; ... ; 18D) den Strom-Befehlswert mit einem Anstieg der Last der Öldruckpumpe (16A9 erhöht.

4. Öldruckeinheit nach einem der vorhergehenden Ansprüche, dadurch gekennzeichnet, dass der Lastsensor (17) ein Drucksensor (17) zum Erfassen eines Öldrucks in einer Abflussleitung (19) der Öldruckpumpe (16A) ist

Revendications

1. Source de pression d'huile pour alimenter de l'huile à un actionneur en entraînant une pompe de pression d'huile (16A) avec un moteur (15), cette source de pression d'huile comprenant :

un onduleur (14) pour alimenter de l'énergie électrique audit moteur (15) ;

un détecteur de charge (17) pour détecter une charge de ladite pompe de pression d'huile (16A) ;

un détecteur de rotation (21) pour détecter une vitesse de rotation dudit moteur (15) ;

un moyen de calcul de valeur de commande actuelle (12) pour calculer une valeur de commande actuelle de manière à ce qu'un écart entre une valeur de commande de vitesse représentant une vitesse de rotation cible dudit moteur (15) et une vitesse de rotation dudit moteur (15) converge vers zéro ;

un moyen de correction (18A ; ... ; 18D) pour corriger ladite valeur de commande actuelle en se basant sur la charge de ladite pompe de pression d'huile ; et

un moyen de génération de signal de commande (13) pour envoyer un signal de commande audit onduleur (14) basé sur une valeur de commande actuelle corrigée,

caractérisé en ce que

ledit moyen de correction (18B ; 18C ; 18D) augmente ladite valeur de commande actuelle pour amener une vitesse de rotation dudit moteur (15) à une valeur proche de ladite vitesse de rotation cible, avec une augmentation de la charge de ladite pompe de pression d'huile (16A).

2. Source de pression d'huile selon la revendication 1, caractérisée en ce que ledit moyen de correction (18A; ... ; 18D) corrige ladite valeur de commande actuelle pour augmenter la vitesse de rotation dudit moteur (15) avec une augmentation de la charge de ladite pompe de pression d'huile (16A).

3. Source de pression d'huile selon la revendication 1 ou 2, caractérisée en ce que ledit moyen de correction (18A ; ; 18D) augmente ladite valeur de commande actuelle avec une augmentation de la charge de ladite pompe de pression d'huile (16A).

4. Source de pression d'huile selon l'une quelconque des revendications précédentes, caractérisée en ce que ledit détecteur de charge (17) est un détecteur de pression (17) pour détecter une pression d'huile dans une conduite de refoulement (19) de ladite pompe de pression d'huile (16A).

Drawing