JP2013154291A - Ultrasonic cleaning apparatus and method for controlling power thereof - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an ultrasonic cleaning apparatus which can allow reliability of power management to be enhanced much more.SOLUTION: The ultrasonic cleaning apparatus includes an object 11 to be cleaned, a cleaning liquid 12, an ultrasonic vibrator 13, an oscillator 14, a power source unit 16 and a power meter 15. The oscillator 14 has: an oscillation unit 17; a control unit 18 for controlling so that the first power oscillated by the oscillation unit 17 becomes a preset power value and outputting the controlled power to the ultrasonic vibrator 13; a detection unit 19 for detecting the second power outputted from the control unit 18 to the ultrasonic vibrator 13; and a calculation unit 20. The calculation unit 20 has such a function that the a first detected power value is corrected by using a correction value α to derive a first corrected power value, the measured power value measured by the power meter 15 is corrected by using a correction value β to derive a second corrected power value, and the correction value α is corrected so that the first corrected power value becomes the second corrected power value, when the first corrected power value is deviated from the second corrected power value by a fixed value or more, to obtain a corrected correction value α' and the revised correction value α' is recorded in a record unit 21.

Description

  The present invention relates to an ultrasonic cleaning apparatus that performs ultrasonic cleaning on an object to be cleaned, a power control method thereof, and the like.

  A conventional ultrasonic cleaning apparatus includes an ultrasonic vibrator, an oscillator, and a power supply unit that apply ultrasonic waves to a cleaning liquid for cleaning an object to be cleaned. The oscillator includes an oscillation unit, a detection unit, and a calculation unit. Yes. An oscillator is electrically connected to the ultrasonic vibrator, and a power supply unit is electrically connected to the oscillator. The electric power oscillated by this oscillating unit is output to the ultrasonic transducer. The output power is detected by the detection unit, and whether the detected power value deviates from the set power value (that is, a power value suitable as power applied to the ultrasonic transducer) is compared by the calculation unit. The When the power value output to the ultrasonic transducer is different from the set power value, the power controlled to be the set power value is output to the ultrasonic transducer (see, for example, Patent Document 1).

  In order to set the power actually applied to the ultrasonic transducer to the set power value, it is necessary to accurately detect the power applied to the ultrasonic transducer by the detection unit. The detector is adjusted by a power calibrator when the ultrasonic cleaning apparatus is manufactured in a factory or the like, so that the power value can be accurately detected.

  As described above, in the conventional ultrasonic cleaning apparatus, the power value applied to the ultrasonic transducer is detected by the detection unit, the power value is compared with the set power value, and the power value applied to the ultrasonic transducer is compared. Is controlled to become the set power value. As a result, even if the power applied to the ultrasonic transducer changes depending on the environmental conditions (for example, the temperature, quality, type, and type of the object to be cleaned), the power value can be adjusted to the set power value. As a result, a decrease in the efficiency of ultrasonic cleaning can be suppressed.

  However, since the detection unit inside the oscillator is not provided with a device configured as a power meter, power management by the detection unit is simplified. In addition, when the ultrasonic vibrator is replaced in the ultrasonic cleaning apparatus, the power value detected by the detection unit may deviate from an accurate value.

JP 2000-49619 A

  An object of one embodiment of the present invention is to provide an ultrasonic cleaning apparatus and a power control method thereof that can further improve the reliability of power management.

  One embodiment of the present invention includes a cleaning liquid that cleans an object to be cleaned, an ultrasonic vibrator that applies ultrasonic waves to the cleaning liquid, an oscillator that is electrically connected to the ultrasonic vibrator, and the ultrasonic vibrator. A power meter for measuring the applied power, and the oscillator controls the ultrasonic vibration by controlling the oscillation unit and the first power oscillated by the oscillation unit to be a set power value. A control unit that outputs to the child, a detection unit that detects the second power output to the ultrasonic transducer by the control unit, and a recording unit that records the first correction value and the second correction value. And a calculation unit electrically connected to each of the detection unit, the control unit, the recording unit, and the wattmeter, wherein the calculation unit is a first detected power value detected by the detection unit. Deriving a first corrected power value obtained by correcting the value with the first correction value Deriving a second corrected power value obtained by correcting the measured power value measured by the wattmeter with the second correction value, and comparing the second corrected power value with the first corrected power value; When the first correction power value deviates from the second correction power value by a certain value or more, the first correction value is set so that the first correction power value becomes the second correction power value. The ultrasonic cleaning apparatus has a function of recording the first correction correction value in which the correction is made in the recording unit.

  One aspect of the present invention is an ultrasonic cleaning apparatus having a first ultrasonic cleaning apparatus, a second ultrasonic cleaning apparatus, and a wattmeter, wherein the first ultrasonic cleaning apparatus includes a first object to be cleaned. A first cleaning liquid for cleaning an object, a first ultrasonic vibrator for applying ultrasonic waves to the first cleaning liquid, a first oscillator electrically connected to the first ultrasonic vibrator, The second ultrasonic cleaning apparatus includes: a second cleaning liquid that cleans a second object to be cleaned; a second ultrasonic vibrator that applies ultrasonic waves to the second cleaning liquid; A second oscillator electrically connected to two ultrasonic transducers, wherein the wattmeter is applied to the first ultrasonic transducer or the second ultrasonic oscillation. The first ultrasonic transducer and the second ultrasonic transducer are for measuring the power applied to the child, and the first ultrasonic transducer and the second ultrasonic transducer are the first switch. The first oscillator and the second oscillator are electrically connected to the power meter via a second switch, and the first oscillator and the second oscillator are electrically connected to the power meter via the first switch. The oscillator controls the first oscillating unit and the first power oscillated by the first oscillating unit to a first set power value and outputs the first power to the first ultrasonic transducer. 1 control part, 1st detection part which detects the 2nd electric power output to the 1st ultrasonic transducer by the 1st control part, 1st correction value and 2nd correction A first recording unit that records a value; and the first detection unit, the first control unit, the first recording unit, and the wattmeter, each of which is electrically connected to the wattmeter. A first arithmetic unit electrically connected via a switch of the first, the first arithmetic unit, the first arithmetic unit. A first corrected power value obtained by correcting the first detected power value detected by the unit with the first correction value is derived, and the first measured power value measured by the power meter is calculated as the second correction value. A second corrected power value corrected by the value is derived, the second corrected power value is compared with the first corrected power value, and the first corrected power value is constant from the second corrected power value. A function of recording, in the recording unit, a first correction correction value obtained by correcting the first correction value so that the first correction power value is equal to the second correction power value when the value exceeds a predetermined value And the second oscillator controls the second oscillator and the third power oscillated by the second oscillator to be a second set power value. A second control unit for outputting to the ultrasonic transducer; and the second ultrasonic vibration by the second control unit. A second detector for detecting the fourth power output to the child; a second recording unit for recording the third correction value and the fourth correction value; the second detector; And a second arithmetic unit electrically connected to each of the two control units, the second recording unit, and the wattmeter, and electrically connected to the wattmeter via the second switch. The second calculation unit derives a fourth correction power value obtained by correcting the third detection power value detected by the second detection unit with the third correction value, and the power meter A fifth corrected power value obtained by correcting the measured second measured power value by the fourth correction value is derived, and the fifth corrected power value is compared with the fourth corrected power value, If the correction power value of 4 is more than a predetermined value from the fifth correction power value, the fourth correction power value is An ultrasonic cleaning apparatus characterized by having a function of recording the second modified correction value obtained by correcting the third correction value so that the fifth correction power value in the recording unit.

  One aspect of the present invention is an ultrasonic cleaning apparatus power control method, wherein the ultrasonic cleaning apparatus includes: a cleaning liquid that cleans an object to be cleaned; an ultrasonic vibrator that applies ultrasonic waves to the cleaning liquid; and the ultrasonic vibration. An oscillator electrically connected to a child, and a wattmeter electrically connected to the oscillator and the ultrasonic transducer, wherein the oscillator is electrically connected to the oscillator and the oscillator Control unit, a detection unit electrically connected to the control unit, a calculation unit electrically connected to each of the detection unit and the control unit, and a record electrically connected to the calculation unit The power control method controls the control unit so that the first power oscillated by the oscillating unit becomes a set power value and outputs the set power value to the ultrasonic transducer. The second power output to the sonic transducer is detected by the detection unit. And correcting the first detected power value detected by the detecting unit with the first correction value recorded in the recording unit to derive the first corrected power value by the calculating unit, and the ultrasonic vibration The second power output to the child is measured by the wattmeter, and the first measured power value measured by the wattmeter is corrected by the second correction value recorded in the recording unit. A correction power value is derived by the calculation unit, the second correction power value is compared with the first correction power value by the calculation unit, and the first correction power value is calculated from the second correction power value. When it is outside a certain value, the first correction correction value obtained by correcting the first correction value so that the first correction power value becomes the second correction power value is recorded in the recording unit. Of ultrasonic cleaning equipment characterized by It is the force control method.

  According to one aspect of the present invention, it is possible to provide an ultrasonic cleaning apparatus and a power control method thereof that can further improve the reliability of power management.

It is the schematic which shows the structure of the ultrasonic cleaning apparatus which concerns on 1 aspect of this invention. It is the schematic for demonstrating the electric power control method of the ultrasonic cleaning apparatus which concerns on 1 aspect of this invention. It is the schematic which shows the structure of the ultrasonic cleaning apparatus which concerns on 1 aspect of this invention.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. However, the present invention is not limited to the following description, and it will be easily understood by those skilled in the art that modes and details can be variously changed without departing from the spirit and scope of the present invention. Therefore, the present invention should not be construed as being limited to the description of the embodiments below.

(First embodiment)
FIG. 1 is a schematic diagram illustrating a configuration of an ultrasonic cleaning apparatus according to an aspect of the present invention.
The ultrasonic cleaning apparatus includes a cleaning liquid 12 that cleans an object to be cleaned 11, a cleaning tank 10 in which the cleaning liquid 12 is placed, an ultrasonic vibrator (load) 13 that applies ultrasonic waves to the cleaning liquid 12, and this ultrasonic vibration. An oscillator 14 electrically connected to the child 13, a power supply unit 16 electrically connected to the oscillator 14, a wattmeter 15 for measuring the power applied to the ultrasonic transducer 13, and the wattmeter 15 has a power supply 9 electrically connected to 15. The object to be cleaned 11 may be a semiconductor wafer, a compact disk, a glass substrate, a flat panel display, a thin disk, or a substrate.

  The wattmeter 15 is preferably calibrated, and more preferably calibrated within the past year, for example. Moreover, the wattmeter 15 is good to be able to be easily attached and detached from the ultrasonic cleaning apparatus.

  The analog output terminal of the wattmeter 15 is electrically connected to the analog input terminal of the oscillator 14. The oscillator 14 includes an oscillation unit 17, a control unit 18, a detection unit 19, a calculation unit 20, and a recording unit 21. The wattmeter 15 is electrically connected to the calculation unit 20.

  The calculation unit 20 is electrically connected to the control unit 18, the detection unit 19, and the recording unit 21. The detection unit 19 is electrically connected to the control unit 18, and the control unit 18 is electrically connected to the oscillation unit 17.

  The oscillation signal (first power) oscillated by the oscillation unit 17 is supplied to the control unit 18, and is controlled by the control unit 18 so that the first power becomes the set power value. 2) is output to the ultrasonic transducer 13. The set power value here means a power value suitable as the power applied to the ultrasonic transducer 13, and this suitable power value depends on the temperature, quality, type and amount of the individual ultrasonic transducer, cleaning liquid. Varies depending on the type of cleaning item.

  The detection unit 19 detects the second power output to the ultrasonic transducer 13 by the control unit 18. The signal A corresponding to the detected first detected power value is input from the detection unit 19 to the calculation unit 20.

The computing unit 20 corrects the first detected power value detected by the detecting unit 19 with the correction value α, and derives the first corrected power value. The first correction power value is derived by calculation (product) of the signal A and the correction value α, and corresponds to the power value actually output to the ultrasonic transducer 13.
The correction value α is a value that is adjusted by the power calibrator when the ultrasonic cleaning apparatus is manufactured in a factory or the like, so that an accurate power value can be calculated inside the oscillator, and is recorded in the recording unit 21.

  The arithmetic unit 20 compares the first corrected power value with the set power value, and when obtaining a comparison result that the first corrected power value deviates from the set power value by a certain value or more, controls the comparison result. To the unit 18. The constant value may include 0.

  The control unit 18 performs control using the above comparison result so that the power value of the oscillation signal oscillated by the oscillation unit 17 becomes the set voltage value, and outputs the result to the ultrasonic transducer 13. Thereby, the power value of the signal supplied to the ultrasonic transducer 13 can be made closer to the set power value.

The ultrasonic cleaning apparatus of FIG. 1 has a function of further bringing the power value of the signal supplied to the ultrasonic transducer 13 closer to the set power value.
The wattmeter 15 measures the second power output to the ultrasonic transducer 13 by the control unit 18. A signal B (voltage) corresponding to the measured power value thus measured is input from the wattmeter 15 to the computing unit 20.

  The computing unit 20 corrects the measured power value measured by the wattmeter 15 with the correction value β, and derives the second corrected power value. This second correction power value is derived by the calculation (product) of the signal B and the correction value β, and corresponds to the power value actually output to the ultrasonic transducer 13. However, since the power meter 15 is more reliable in power measurement than the detection unit 19, the power value measured by the power meter 15 is more accurate than the power value detected by the detection unit 19. The correction value β is recorded in the recording unit 21.

  The calculation unit 20 compares the second correction power value with the first correction power value obtained by the detection unit 19 and the calculation unit 20, and the first correction power value is greater than or equal to a certain value from the second correction power value. If it is not, the correction correction value α ′ obtained by correcting the correction value α so that the first correction power value becomes the second correction power value is recorded in the recording unit. The correction correction value α ′ is a correction value that is more accurate than the correction value α. The correction correction value α ′ is obtained by correcting the correction value α so that, for example, the first correction power value and the second correction power value are equal. The constant value may include 0.

  The computing unit 20 corrects the first detected power value detected by the detecting unit 19 with the correction value α, and derives the first corrected power value. It is derived by the calculation (product) of the signal A and the correction value α, and corresponds to the power value actually output to the ultrasonic transducer 13.

  The calculation unit 20 detects the second power output to the ultrasonic transducer 13 by the control unit 18 using the detection unit 19, and a signal A corresponding to the detected second detection power value is output from the detection unit 19. A third correction power value is derived by calculation (product) of the input signal A and the correction correction value α ′, which is input to the calculation unit 20, and the third correction power value is compared with the set power value. When a comparison result is obtained that the third correction power value deviates from the set power value by a certain value or more, this comparison result is output to the control unit 18. The constant value may include 0.

  The control unit 18 performs control using the above comparison result so that the power value of the oscillation signal oscillated by the oscillation unit 17 becomes the set voltage value, and outputs the result to the ultrasonic transducer 13. Thereby, the power value of the signal supplied to the ultrasonic transducer 13 can be made closer to the set power value.

  The operation of deriving the correction correction value α ′ using the wattmeter 15 as described above is preferably performed automatically, and is preferably performed every predetermined period. By making the predetermined period extremely short, it is possible to approach the set power value more accurately in almost real time. Further, by using a calibrated calibrator as the wattmeter 15, it is possible to output the ultrasonic transducer 13 with a more accurate power value.

  Further, when the ultrasonic transducer 13 is replaced in the ultrasonic cleaning apparatus, even if the power value detected by the detection unit 19 deviates from an accurate value, the correction correction value is obtained using the wattmeter 15 as described above. By deriving α ′ and recording the correction correction value α ′ in the recording unit 21, the power value detected by the detecting unit 19 can be made a more accurate value.

Next, the power control method of the ultrasonic cleaning apparatus will be described in detail with reference to FIG. This power control is performed in the following order (1) to (10).
(1) The first power oscillated by the oscillating unit 17 is controlled by the control unit 18 so that the first power is set to the set power value, and is output to the ultrasonic transducer 13.
(2) The second electric power controlled by the control unit 18 and output to the ultrasonic transducer 13 is detected by the detection unit 19.
(3) The first corrected power value is obtained by correcting the signal A corresponding to the first detected power value detected by the detecting unit 19 with the correction value α recorded in the recording unit 21 as shown in the following equation (a). PA is derived by the arithmetic unit 20.
(A) PA = A × α
(4) The second electric power controlled by the control unit 18 and output to the ultrasonic transducer 13 is measured by the wattmeter 15.
(5) The second power output to the ultrasonic transducer 13 is measured by the wattmeter 15 to obtain a first measured power value, and a signal B corresponding to the first measured power value is sent to the computing unit 20. The second correction power value PB is derived by the calculation unit 20 by correcting the signal B as input by the correction value β recorded in the recording unit 21 according to the following equation (b).
(B) PB = B × β
(6) The second correction power value PB is compared with the first correction power value PA by the arithmetic unit 20, and when the first correction power value PA deviates from the second correction power value PB by a certain value or more. As shown in the following equation (c), the correction correction value α ′ obtained by automatically correcting the correction value α so that the first correction power value PA becomes the second correction power value PB is automatically recorded in the recording unit 21. . The constant value may include 0.
(C) Automatic adjustment algorithm PB = PA = A × α ′

(7) After the correction correction value α ′ is recorded in the recording unit 21, the control unit 18 controls the third power oscillated by the oscillating unit 17 to be a set power value and outputs the set power value to the ultrasonic transducer 13. To do.
(8) The fourth power output from the control unit 18 to the ultrasonic transducer 13 is detected by the detection unit 19, and the second detected power value detected by the detection unit 19 is corrected by the correction correction value α ′. Thus, the third correction power value is derived by the calculation unit 20.
(9) When the calculation unit 20 compares the third corrected power value with the set power value, and obtains a comparison result that the third corrected power value deviates from the set power value by a certain value or more, this comparison result Is output to the 18 control unit.
(10) The control unit 18 performs control using the above comparison result so that the fifth power oscillated by the oscillation unit 17 becomes the set power value, and outputs the result to the ultrasonic transducer 13. The constant value may include 0.

(Second Embodiment)
FIG. 2 is a schematic diagram for explaining the power control method of the ultrasonic cleaning apparatus according to one aspect of the present invention.
The ultrasonic cleaning device includes first to third ultrasonic cleaning devices 31 to 33 and a wattmeter 15.

  The first ultrasonic cleaning device 31 includes a first cleaning liquid 12a for cleaning the first object to be cleaned (object 1 to be cleaned) 11a, and a first ultrasonic vibrator that applies ultrasonic waves to the first cleaning liquid 12a. (Load 1) 13a and a first oscillator (oscillator 1) 14a electrically connected to the first ultrasonic transducer 13a. The first oscillator 14a has the same configuration as the oscillator 14 shown in FIG.

  The second ultrasonic cleaning device 32 includes a second cleaning liquid 12b for cleaning the second object to be cleaned (object to be cleaned 2) 11b, and a second ultrasonic vibrator for applying an ultrasonic wave to the second cleaning liquid 12b. (Load 2) 13b and a second oscillator (oscillator 2) 14b electrically connected to the second ultrasonic transducer 13b. The second oscillator 14b has a configuration similar to that of the oscillator 14 shown in FIG.

  The third ultrasonic cleaning device 33 includes a third cleaning liquid 12c for cleaning the third object to be cleaned (object 3 to be cleaned) 11c, and a third ultrasonic vibrator for applying ultrasonic waves to the third cleaning liquid 12c. (Load 3) 13c and a third oscillator (oscillator 3) 14c electrically connected to the third ultrasonic transducer 13c. The third oscillator 14c has the same configuration as the oscillator 14 shown in FIG.

  The wattmeter 15 has the same configuration as that of the wattmeter 15 shown in FIG. 1, and the electrical connection with the first ultrasonic transducer 13a and the first oscillator 14a is the same as in FIG. The electrical connection between the second ultrasonic transducer 13b and the second oscillator 14b and the wattmeter 15 is also the same as in FIG. 1, and the third ultrasonic transducer 13c and the third oscillator 14c The electrical connection of the wattmeter 15 is the same as in FIG.

  There is only one wattmeter 15 for the first to third ultrasonic cleaning apparatuses 31 to 33, and the wattmeter 15 can be easily attached and detached from each of the first to third ultrasonic cleaning apparatuses 31 to 33. It can be done.

Next, a power control method for the above ultrasonic cleaning apparatus will be described. This power control is performed in the following order (1) to (14).
(1) The first ultrasonic transducer 13a and the first oscillator 14a are electrically connected to the wattmeter 15, and the first power is set to the first by the same method as the oscillator 14 shown in FIG. The electric power value is controlled by the control unit 18 and output to the first ultrasonic transducer 13a.
(2) The second power output to the first ultrasonic transducer 13a is detected by the detector 19 in the same manner as the oscillator 14 shown in FIG. 1, and the detected first detected power value is recorded. The first correction power value is derived by the calculation unit 20 by correcting with the correction value α recorded in the unit 21.
(3) The second power output to the first ultrasonic transducer 13a is measured by the wattmeter 15 by the same method as the oscillator 14 shown in FIG. 1, and the measured first measured power value is recorded. The second correction power value is derived by the calculation unit 20 by correcting with the correction value β recorded in the unit 21.
(4) The second correction power value is compared with the first correction power value by the arithmetic unit 20 by the same method as that of the oscillator 14 shown in FIG. 1, and the first correction power value is calculated from the second correction power value. If it is outside the predetermined value, the corrected correction value α ′ obtained by correcting the first correction value so that the first correction power value becomes the second correction power value is recorded in the recording unit 21.

(5) The wattmeter 15 is removed from the first ultrasonic cleaning device 31, and the wattmeter 15 is electrically connected to the second ultrasonic transducer 13b and the second oscillator 14b of the second ultrasonic cleaning device 32, respectively. Connect to.
(6) By the same method as the oscillator 14 shown in FIG. 1, the second ultrasonic vibration is controlled by the control unit 18 so that the third power oscillated by the oscillation unit 17 becomes the second set power value. Output to the child 13b.
(7) The fourth power output to the second ultrasonic transducer 13b is detected by the detection unit 19 in the same manner as the oscillator 14 shown in FIG. 1, and the detected second detected power value is recorded. The third correction power value is derived by the calculation unit 20 by correcting with the correction value α recorded in the unit 21.
(8) The fourth power output to the second ultrasonic transducer 13b is measured by the wattmeter 15 by the same method as the oscillator 14 shown in FIG. 1, and the measured second measured power value is recorded. The fourth correction power value is derived by the calculation unit 20 by correcting with the correction value β recorded in the unit 21.
(9) The fourth correction power value is compared with the third correction power value by the arithmetic unit 20 by the same method as that of the oscillator 14 shown in FIG. 1, and the third correction power value is calculated from the fourth correction power value. When it is outside the predetermined value, the corrected correction value α ′ obtained by correcting the third correction value so that the third correction power value becomes the fourth correction power value is recorded in the recording unit 21.

(10) The wattmeter 15 is removed from the second ultrasonic cleaning device 32, and the wattmeter 15 is electrically connected to the third ultrasonic transducer 13c and the third oscillator 14c of the third ultrasonic cleaning device 33, respectively. Connect to.
(11) By the same method as the oscillator 14 shown in FIG. 1, the third ultrasonic vibration is controlled by the control unit 18 so that the fifth power oscillated by the oscillation unit 17 becomes the third set power value. Output to the child 13c.
(12) The sixth power output to the third ultrasonic transducer 13c is detected by the detector 19 in the same manner as the oscillator 14 shown in FIG. 1, and the detected third detected power value is recorded. The fifth correction power value is derived by the calculation unit 20 by correcting with the correction value α recorded in the unit 21.
(13) The sixth power output to the third ultrasonic transducer 13c is measured by the wattmeter 15 by the same method as the oscillator 14 shown in FIG. 1, and the measured third measured power value is recorded. The sixth correction power value is derived by the calculation unit 20 by correcting with the correction value β recorded in the unit 21.
(14) The sixth correction power value is compared with the fifth correction power value by the arithmetic unit 20 by the same method as that of the oscillator 14 shown in FIG. 1, and the fifth correction power value is calculated from the sixth correction power value. When it is outside the predetermined value, the corrected correction value α ′ obtained by correcting the fifth correction value so that the fifth correction power value becomes the sixth correction power value is recorded in the recording unit 21.

  According to this embodiment, the same effect as that of the first embodiment can be obtained.

  Further, according to the present embodiment, the power control of each of the first to third ultrasonic cleaning devices 31 to 33 can be performed by one wattmeter 15 by the work of replacing one wattmeter 15. As a result, the power control of the first to third ultrasonic cleaning devices 31 to 33 can be automatically adjusted based on the same standard.

  In the present embodiment, one aspect of the present invention is applied to the power control method of the ultrasonic cleaning apparatus having the first to third ultrasonic cleaning apparatuses 31 to 33, but two or four or more One embodiment of the present invention can also be applied to a power control method for an ultrasonic cleaning apparatus having the ultrasonic cleaning apparatus.

  Moreover, it is preferable to calibrate the wattmeter 15 before performing the above power control, and for example, it is preferable to calibrate the wattmeter 15 within the past year.

(Third embodiment)
FIG. 3 is a schematic diagram illustrating a configuration of an ultrasonic cleaning apparatus according to an aspect of the present invention.
The ultrasonic cleaning device includes first to third ultrasonic cleaning devices 31 to 33 and an automatic switching wattmeter 34. The automatic switching wattmeter 34 includes a wattmeter 15, a first switch 35, and a second switch 36. The wattmeter 15 has the same configuration as the wattmeter 15 shown in FIG.

  Each of the first to third ultrasonic cleaning apparatuses 31 to 33 has the same configuration as each of the first to third ultrasonic cleaning apparatuses 31 to 33 shown in FIG. That is, the first to third objects to be cleaned 11a to 11c, the first to third cleaning liquids 12a to 12c, the first to third ultrasonic transducers 13a to 13c, and the first to third oscillators 14a to 14c. Is the same as that shown in FIG.

  The wattmeter 15 is a power applied to the first ultrasonic transducer (load 1) 13a, a power applied to the second ultrasonic transducer (load 2) 13b, or a third ultrasonic vibration. The child (load 3) 13c is measured.

  The first to third ultrasonic transducers 13 a to 13 c are electrically connected to the wattmeter 15 via the first switch 35. The first to third oscillators (oscillator 1, oscillator 2, oscillator 3) 14 a to 14 c are electrically connected to the wattmeter 15 via the second switch 36.

  The calculation unit 20 of the first oscillator 14a is electrically connected to the detection unit 19, the control unit 18, and the recording unit 21 of the first oscillator 14a, and is electrically connected to the wattmeter 15 via the second switch 36. Connected.

  The computing unit 20 of the first oscillator 14 a derives a first corrected power value obtained by correcting the first detected power value detected by the detecting unit 19 with the correction value α, and the first corrected power value measured by the wattmeter 15 is derived. A second corrected power value obtained by correcting the measured power value of the first corrected power value by the correction value β is derived, the second corrected power value is compared with the first corrected power value, and the first corrected power value is the second corrected power value. When the value deviates from a certain value by a certain value or more, the recording unit 21 has a function of recording a corrected correction value α ′ obtained by correcting the correction value α so that the first correction power value becomes the second correction power value.

The signal A corresponding to the first detected power value detected by the detection unit 19 of the first oscillator 14a is input to the calculation unit 20, and the first correction power value is calculated from the signal A and the correction value α. Derived by (product).
Further, the signal B corresponding to the first measured power value measured by the wattmeter 15 is input to the calculation unit 20, and the second corrected power value is derived by the calculation (product) of the signal B and the correction value β. The
The corrected correction value α ′ is obtained by correcting the correction value α so that the first correction power value and the second correction power value are equal.

  The calculation unit 20 of the second oscillator 14b is electrically connected to the detection unit 19, the control unit 18, and the recording unit 21 of the second oscillator 14b, and is electrically connected to the wattmeter 15 via the second switch 36. Connected.

  The computing unit 20 of the second oscillator 14 b derives a fourth corrected power value obtained by correcting the third detected power value detected by the detecting unit 19 with the correction value α, and the second corrected power value measured by the wattmeter 15 is derived. A fifth corrected power value obtained by correcting the measured power value of the second corrected power value by the correction value β is derived, the fifth corrected power value is compared with the fourth corrected power value, and the fourth corrected power value is the fifth corrected power value. When the value deviates from a certain value by more than a certain value, the recording unit 21 has a function of recording the corrected correction value α ′ obtained by correcting the correction value α so that the fourth correction power value becomes the fifth correction power value.

The signal A corresponding to the third detected power value detected by the detection unit 19 of the second oscillator 14b is input to the calculation unit 20, and the fourth correction power value is calculated from the signal A and the correction value α. Derived by (product).
Further, the signal B corresponding to the second measured power value measured by the wattmeter 15 is input to the calculation unit 20, and the fifth corrected power value is derived by the calculation (product) of the signal B and the correction value β. The
The corrected correction value α ′ is obtained by correcting the correction value α so that the fourth correction power value and the fifth correction power value are equal.

  The arithmetic unit 20 of the third oscillator 14c is electrically connected to the detection unit 19, the control unit 18, and the recording unit 21 of the third oscillator 14c, and is electrically connected to the wattmeter 15 via the second switch 36. Connected.

  The computing unit 20 of the third oscillator 14 c derives a seventh corrected power value obtained by correcting the fifth detected power value detected by the detecting unit 19 with the correction value α, and the third corrected power value measured by the wattmeter 15 is derived. An eighth corrected power value obtained by correcting the measured power value of the first corrected power value by the correction value β is derived, the eighth corrected power value is compared with the seventh corrected power value, and the seventh corrected power value is the eighth corrected power value. When the value deviates from a certain value by a certain value or more, the recording unit 21 has a function of recording the corrected correction value α ′ obtained by correcting the correction value α so that the seventh correction power value becomes the eighth correction power value.

The signal A corresponding to the fifth detected power value detected by the detection unit 19 of the third oscillator 14c is input to the calculation unit 20, and the seventh correction power value is calculated from the signal A and the correction value α. Derived by (product).
Further, the signal B corresponding to the third measured power value measured by the wattmeter 15 is input to the calculation unit 20, and the eighth corrected power value is derived by the calculation (product) of the signal B and the correction value β. The
The corrected correction value α ′ is obtained by correcting the correction value α so that the seventh correction power value and the eighth correction power value are equal.

  The calculation unit 20 of the first oscillator 14a derives a third correction power value obtained by correcting the second detection power value detected by the detection unit 19 of the first oscillator 14a with the correction correction value α ′. 3 is compared with the first set power value, and when the first comparison result that the third corrected power value deviates from the first set power value by a certain value or more is obtained, The comparison result is output to the control unit 18. A signal A corresponding to the second detected power value detected by the detection unit 19 of the first oscillator 14a is input to the calculation unit 20, and the third correction power value is the signal A and the corrected correction value α ′. It is derived by the operation (product) of

  The control unit 18 of the first oscillator 14a performs control using the first comparison result so that the first power oscillated by the oscillation unit 17 of the first oscillator 14a becomes the first set voltage value. Output to the first ultrasonic transducer 13a.

  The calculation unit 20 of the second oscillator 14b derives a sixth correction power value obtained by correcting the fourth detection power value detected by the detection unit 19 of the second oscillator 14b with the correction correction value α ′. 6 is compared with the second set power value, and when the second comparison result that the sixth corrected power value deviates from the second set power value by a certain value or more is obtained, The comparison result is output to the control unit 18. The signal A corresponding to the fourth detected power value detected by the detection unit 19 of the second oscillator 14b is input to the calculation unit 20, and the sixth correction power value is the signal A and the corrected correction value α ′. It is derived by the operation (product) of

  The control unit 18 of the second oscillator 14b performs control using the second comparison result so that the third power oscillated by the oscillation unit 17 of the second oscillator 14b becomes the second set voltage value. Output to the second ultrasonic transducer 13b.

  The arithmetic unit 20 of the third oscillator 14c derives a ninth correction power value obtained by correcting the sixth detection power value detected by the detection unit 19 of the third oscillator 14c with the correction correction value α ′. If the third correction power value is compared with the third set power value, and the third comparison result that the ninth correction power value deviates from the third set power value by a certain value or more is obtained, The comparison result is output to the control unit 18. The signal A corresponding to the sixth detected power value detected by the detection unit 19 of the third oscillator 14c is input to the calculation unit 20, and the ninth correction power value is the signal A and the corrected correction value α ′. It is derived by the operation (product) of

  The control unit 18 of the third oscillator 14c performs control while using the third comparison result so that the third power oscillated by the oscillation unit 17 of the third oscillator 14c becomes the third set voltage value. Output to the third ultrasonic transducer 13c.

  Next, the power control method of the ultrasonic cleaning apparatus will be described, but only portions different from the power control method performed in the order of (1) to (14) of the second embodiment will be described.

(1) First and second switches 35 and 36 are connected to electrically connect the first ultrasonic transducer 13a and the first oscillator 14a of the first ultrasonic cleaning device 31 to the wattmeter 15 respectively. Switch. In other words, the first ultrasonic transducer 13a and the wattmeter 15 are electrically connected by the first switch 35, and the wattmeter 15 and the first oscillator 14a are electrically connected by the second switch 36. .
(5) First and second switches 35 and 36 are connected to electrically connect the second ultrasonic transducer 13b and the second oscillator 14b of the second ultrasonic cleaning device 32 to the wattmeter 15 respectively. Switch. In other words, the second ultrasonic transducer 13b and the wattmeter 15 are electrically connected by the first switch 35, and the wattmeter 15 and the second oscillator 14b are electrically connected by the second switch 36. .
(10) The first and second switches 35 and 36 are connected so that the wattmeter 15 is electrically connected to the third ultrasonic transducer 13c and the third oscillator 14c of the third ultrasonic cleaning device 33, respectively. Switch. In other words, the first ultrasonic transducer 13c and the wattmeter 15 are electrically connected by the first switch 35, and the wattmeter 15 and the third oscillator 14c are electrically connected by the second switch 36. .

  According to this embodiment, the same effect as that of the second embodiment can be obtained.

  In the present embodiment, the connection with the wattmeter 15 can be automatically switched in the order of the first ultrasonic cleaning device 31 to the third ultrasonic cleaning device 33.

  In the present embodiment, one aspect of the present invention is applied to the ultrasonic cleaning apparatus having the first to third ultrasonic cleaning apparatuses 31 to 33. However, two or four or more ultrasonic cleaning apparatuses are used. It is also possible to apply one embodiment of the present invention to an ultrasonic cleaning apparatus having

  Moreover, it is preferable to calibrate the wattmeter 15 before performing the above power control, and for example, it is preferable to calibrate the wattmeter 15 within the past year.

DESCRIPTION OF SYMBOLS 9 ... Power supply 10 ... Cleaning tank 11 ... To-be-processed object 11a ... 1st to-be-processed object (to-be-processed object 1)
11b ... second object to be processed (object to be processed 2)
11c 3rd to-be-processed object (processed object 3)
12 ... Cleaning fluid 12a ... 1st cleaning fluid 12b ... 2nd cleaning fluid 12c ... 3rd cleaning fluid 13 ... Load (ultrasonic transducer)
13a: Load 1 (first ultrasonic transducer)
13b ... Load 2 (second ultrasonic transducer)
13c: Load 3 (third ultrasonic transducer)
14: Oscillator 14a: Oscillator 1 (first oscillator)
14b ... oscillator 2 (second oscillator)
14c: Oscillator 3 (third oscillator)
DESCRIPTION OF SYMBOLS 15 ... Wattmeter 16 ... Power supply part 17 ... Oscillation part 18 ... Control part 19 ... Detection part 20 ... Calculation part 21 ... Recording part 31 ... 1st ultrasonic cleaning apparatus 32 ... 2nd ultrasonic cleaning apparatus 33 ... 3rd Ultrasonic cleaning device 34 ... automatic switching wattmeter 35 ... first switch 36 ... second switch

Claims (12)

A cleaning solution for cleaning an object to be cleaned;
An ultrasonic vibrator for applying ultrasonic waves to the cleaning liquid;
An oscillator electrically connected to the ultrasonic transducer;
A wattmeter for measuring the power applied to the ultrasonic transducer;
Comprising
The oscillator is
An oscillation unit;
A control unit that controls the first power oscillated by the oscillation unit to be a set power value and outputs the set power value to the ultrasonic transducer;
A detection unit for detecting second power output to the ultrasonic transducer by the control unit;
A recording unit for recording the first correction value and the second correction value;
A calculation unit electrically connected to each of the detection unit, the control unit, the recording unit, and the wattmeter,
The calculation unit derives a first correction power value obtained by correcting the first detection power value detected by the detection unit with the first correction value, and the measurement power value measured by the power meter is A second correction power value corrected by the second correction value is derived, the second correction power value is compared with the first correction power value, and the first correction power value is the second correction power value. When the power value deviates from a certain value by more than a certain value, the first correction correction value obtained by correcting the first correction value so that the first correction power value becomes the second correction power value is stored in the recording unit. An ultrasonic cleaning apparatus having a function of recording in In claim 1,
The calculation unit derives a third correction power value obtained by correcting the second detection power value detected by the detection unit with the first correction correction value, and uses the third correction power value as the set power. When the comparison result that the third correction power value is deviated from the set power value by a certain value or more is obtained in comparison with the value, the function has the function of outputting the comparison result to the control unit,
The control unit controls the first electric power oscillated by the oscillating unit so as to have the set voltage value, and outputs the ultrasonic power to the ultrasonic transducer. Sonic cleaning device. In claim 2,
A first signal corresponding to the first detection power value detected by the detection unit is input to the calculation unit, and the first correction power value is the first signal and the first correction value. Derived from the operation of
A second signal corresponding to the measured power value measured by the power meter is input to the calculation unit, and the second correction power value is calculated by calculating the second signal and the second correction value. Derived,
The first correction correction value is a correction of the first correction value so that the first correction power value and the second correction power value are equal.
A third signal corresponding to the second detection power value detected by the detection unit is input to the calculation unit, and the third correction power value is the third signal and the first correction correction. An ultrasonic cleaning apparatus derived by calculating a value. An ultrasonic cleaning device having a first ultrasonic cleaning device, a second ultrasonic cleaning device, and a power meter,
The first ultrasonic cleaning device includes:
A first cleaning liquid for cleaning the first object to be cleaned;
A first ultrasonic transducer for applying ultrasonic waves to the first cleaning liquid;
A first oscillator electrically connected to the first ultrasonic transducer,
The second ultrasonic cleaning device includes:
A second cleaning liquid for cleaning the second object to be cleaned;
A second ultrasonic transducer for applying ultrasonic waves to the second cleaning liquid;
A second oscillator electrically connected to the second ultrasonic transducer,
The wattmeter measures the power applied to the first ultrasonic transducer or the power applied to the second ultrasonic transducer,
The first ultrasonic transducer and the second ultrasonic transducer are electrically connected to the wattmeter via a first switch;
The first oscillator and the second oscillator are electrically connected to the wattmeter via a second switch;
The first oscillator includes:
A first oscillation unit;
A first control unit that controls the first power oscillated by the first oscillation unit to be a first set power value and outputs the first power to the first ultrasonic transducer;
A first detection unit for detecting a second power output to the first ultrasonic transducer by the first control unit;
A first recording unit for recording the first correction value and the second correction value;
A first calculation electrically connected to each of the first detection unit, the first control unit, and the first recording unit, and electrically connected to the power meter via the second switch. And
The first calculation unit derives a first correction power value obtained by correcting the first detection power value detected by the first detection unit with the first correction value, and is measured by the wattmeter. A second corrected power value obtained by correcting the first measured power value by the second correction value is derived, the second corrected power value is compared with the first corrected power value, and the first corrected power value is compared with the first corrected power value. When the correction power value is out of the second correction power value by a certain value or more, the first correction value is corrected so that the first correction power value becomes the second correction power value. Having a function of recording one correction correction value in the first recording unit;
The second oscillator is
A second oscillation unit;
A second control unit that controls the third power oscillated by the second oscillation unit to be a second set power value and outputs the second power to the second ultrasonic transducer;
A second detection unit for detecting a fourth power output to the second ultrasonic transducer by the second control unit;
A second recording unit for recording the third correction value and the fourth correction value;
A second calculation electrically connected to each of the second detection unit, the second control unit, and the second recording unit, and electrically connected to the wattmeter via the second switch. And
The second calculation unit derives a fourth correction power value obtained by correcting the third detection power value detected by the second detection unit with the third correction value, and is measured by the wattmeter. A fifth corrected power value obtained by correcting the second measured power value with the fourth correction value is derived, the fifth corrected power value is compared with the fourth corrected power value, and the fourth corrected power value is compared with the fourth corrected power value. When the corrected power value deviates from the fifth corrected power value by a certain value or more, the third corrected value is corrected so that the fourth corrected power value becomes the fifth corrected power value. An ultrasonic cleaning apparatus having a function of recording a correction correction value of 2 in the second recording unit. In claim 4,
The first calculation unit derives a third correction power value obtained by correcting the second detection power value detected by the first detection unit with the first correction correction value, and the third correction power value is derived. When the power value is compared with the first set power value, and the first comparison result that the third corrected power value deviates from the first set power value by a certain value or more is obtained, the first Having the function of outputting the comparison result to the first control unit,
The first control unit performs control using the first comparison result so that the first power oscillated by the first oscillation unit becomes the first set voltage value. Output to 1 ultrasonic transducer,
The second calculation unit derives a sixth correction power value obtained by correcting the fourth detection power value detected by the second detection unit with the second correction correction value, and the sixth correction power value is derived. When the power value is compared with the second set power value, and the second comparison result that the sixth correction power value deviates from the second set power value by a certain value or more is obtained, the second And a function of outputting the comparison result of the second control unit to the second control unit,
The second control unit performs control using the second comparison result so that the third power oscillated by the second oscillation unit becomes the second set voltage value. An ultrasonic cleaning apparatus that outputs to an ultrasonic transducer of No. 2. In claim 5,
A first signal corresponding to the first detection power value detected by the first detection unit is input to the first calculation unit, and the first correction power value is the same as the first signal. Derived by calculating the first correction value;
A second signal corresponding to the first measured power value measured by the wattmeter is input to the first computing unit, and the second corrected power value is the second signal and the second signal. Derived by calculating the correction value of
The first correction correction value is a correction of the first correction value so that the first correction power value and the second correction power value are equal.
A third signal corresponding to the second detection power value detected by the first detection unit is input to the first calculation unit, and the third correction power value is the same as the third signal. Derived by calculating the first correction correction value;
A fourth signal corresponding to the third detection power value detected by the second detection unit is input to the second calculation unit, and the fourth correction power value is the same as the fourth signal. Derived by calculating the third correction value;
A fifth signal corresponding to the second measured power value measured by the wattmeter is input to the second computing unit, and the fifth corrected power value is calculated using the fifth signal and the fourth signal. Derived by calculating the correction value of
The second correction correction value is a correction of the third correction value so that the fourth correction power value and the fifth correction power value are equal.
A sixth signal corresponding to the fourth detection power value detected by the second detection unit is input to the second calculation unit, and the sixth correction power value is the same as the sixth signal. The ultrasonic cleaning apparatus, which is derived by calculation of the second correction correction value. In any one of Claims 1 thru | or 6,
The ultrasonic cleaning apparatus according to claim 1, wherein the power meter is calibrated. In the power control method of the ultrasonic cleaning device,
The ultrasonic cleaning apparatus is
A cleaning solution for cleaning an object to be cleaned;
An ultrasonic vibrator for applying ultrasonic waves to the cleaning liquid;
An oscillator electrically connected to the ultrasonic transducer;
A wattmeter electrically connected to the oscillator and the ultrasonic transducer,
The oscillator is
An oscillation unit;
A control unit electrically connected to the oscillation unit;
A detection unit electrically connected to the control unit;
A calculation unit electrically connected to each of the detection unit and the control unit;
A recording unit electrically connected to the arithmetic unit,
The power control method includes:
The first power oscillated by the oscillating unit is controlled by the control unit so that the first power becomes a set power value, and is output to the ultrasonic transducer,
The second power output to the ultrasonic transducer is detected by the detection unit,
A first correction power value is derived by the calculation unit by correcting the first detection power value detected by the detection unit by the first correction value recorded in the recording unit,
The second power output to the ultrasonic transducer is measured by the wattmeter,
Deriving a second corrected power value by the calculation unit by correcting the first measured power value measured by the wattmeter with the second correction value recorded in the recording unit;
The second correction power value is compared with the first correction power value by the arithmetic unit, and when the first correction power value deviates from the second correction power value by a certain value or more, The power of the ultrasonic cleaning apparatus, wherein the first correction correction value obtained by correcting the first correction value so that the correction power value of 1 becomes the second correction power value is recorded in the recording unit. Control method. In claim 8,
After recording the first correction correction value in the recording unit,
The third power oscillated by the oscillating unit is controlled by the control unit so that the third power becomes the set power value, and output to the ultrasonic transducer,
Detecting the fourth power output to the ultrasonic transducer by the detection unit;
Deriving a third correction power value by the calculation unit by correcting the second detection power value detected by the detection unit with the first correction correction value;
When the calculation unit compares the third corrected power value with the set power value, and obtains a comparison result that the third corrected power value deviates from the set power value by a certain value or more, the comparison result Is output to the control unit,
Ultrasonic cleaning characterized in that the control unit uses the comparison result so that the fifth power oscillated by the oscillation unit becomes the set power value, and outputs the result to the ultrasonic transducer. Device power control method. In the power control method of the ultrasonic cleaning device,
The ultrasonic cleaning device includes a first ultrasonic cleaning device, a second ultrasonic cleaning device, and a wattmeter,
The first ultrasonic cleaning device includes:
A first cleaning liquid for cleaning the first object to be cleaned;
A first ultrasonic transducer for applying ultrasonic waves to the first cleaning liquid;
A first oscillator electrically connected to the first ultrasonic transducer,
The first oscillator includes:
A first oscillation unit;
A first control unit electrically connected to the first oscillation unit;
A first detector electrically connected to the first controller;
A first calculation unit electrically connected to each of the first detection unit and the first control unit;
A first recording unit electrically connected to the first calculation unit,
The second ultrasonic cleaning device includes:
A second cleaning liquid for cleaning the second object to be cleaned;
A second ultrasonic transducer for applying ultrasonic waves to the second cleaning liquid;
A second oscillator electrically connected to the second ultrasonic transducer,
The second oscillator is
A second oscillation unit;
A second control unit electrically connected to the second oscillation unit;
A second detector electrically connected to the second controller;
A second calculation unit electrically connected to each of the second detection unit and the second control unit;
A second recording unit electrically connected to the second calculation unit,
The power control method includes:
Electrically connecting the wattmeter and each of the first ultrasonic transducer and the first oscillator;
The first power oscillated by the first oscillating unit is controlled by the first control unit so that the first set power value becomes a first set power value, and is output to the first ultrasonic transducer,
The second power output to the first ultrasonic transducer is detected by the first detector;
By correcting the first detected power value detected by the first detection unit with the first correction value recorded in the first recording unit, the first correction power value is obtained by the first calculation unit. Derived,
Measuring the second power output to the first ultrasonic transducer with the power meter;
Deriving a second corrected power value by the first calculation unit by correcting the first measured power value measured by the wattmeter with the second correction value recorded in the first recording unit;
When the first correction power value is compared with the first correction power value by the first calculation unit, and the first correction power value deviates from the second correction power value by a certain value or more. , Recording the first correction correction value obtained by correcting the first correction value so that the first correction power value becomes the second correction power value in the first recording unit,
Electrically connecting the wattmeter and each of the second ultrasonic transducer and the second oscillator;
The third power oscillated by the second oscillating unit is controlled by the second control unit so that the third electric power becomes a second set power value, and is output to the second ultrasonic transducer,
The fourth power output to the second ultrasonic transducer is detected by the second detection unit,
By correcting the second detection power value detected by the second detection unit with the third correction value recorded in the second recording unit, a third correction power value is obtained by the second calculation unit. Derived,
Measuring the fourth power output to the second ultrasonic transducer with the power meter;
A second corrected power value is derived by the second computing unit by correcting the second measured power value measured by the wattmeter by the fourth correction value recorded in the second recording unit;
When the second correction power value is compared with the third correction power value by the second calculation unit, and the third correction power value deviates from the fourth correction power value by a certain value or more. The second correction correction value obtained by correcting the third correction value so that the third correction power value becomes the fourth correction power value is recorded in the second recording unit. A power control method for an ultrasonic cleaning apparatus. In claim 10,
The electrical connection between the first ultrasonic transducer and the first oscillator and the wattmeter is achieved by electrically connecting the first ultrasonic transducer and the wattmeter by a first switch. And electrically connecting the wattmeter and the first oscillator by a second switch,
The electrical connection between the second ultrasonic transducer and the second oscillator and the wattmeter is achieved by electrically connecting the second ultrasonic transducer and the wattmeter by the first switch. A power control method for an ultrasonic cleaning apparatus, wherein the power meter and the second oscillator are electrically connected by the second switch. In any one of Claims 8 thru | or 11,
A power control method for an ultrasonic cleaning apparatus, wherein the power meter is calibrated before performing the power control.

Images