KR100932323B1 - Piezoelectric Generation System and Generation Method - Google Patents

Abstract

Piezoelectric generating systems and piezoelectric generating methods for use in nebulizers are disclosed. The system and method control a frequency generator to continuously generate a plurality of first electrical signals having a predetermined frequency band range (or a third electrical signal after converting the first electrical signal) transmitted to the piezoelectric generating element. Using a processing unit. The piezoelectric generating element then generates a corresponding second electrical signal (or fourth electrical signal after converting the second electrical signal) which is transmitted to the processing unit based on the first electrical signal or the third electrical signal. The first electrical signal (or third) of the optimum frequency delivered to the piezoelectric generating element based on the voltage value (or feedback frequency value) corresponding to the second electrical signal (or third electrical signal) and the frequency of the first electrical signal. The frequency generator controls the frequency generator to provide an electrical signal.

Description

Piezoelectric Generation System and Generation Method {PIEZOELECTRIC GENERATION SYSTEM AND GENERATION METHOD THEREOF}

1 is a block diagram of a conventional piezoelectric generation system.

2 is a block diagram of a piezoelectric generation system of the present invention.

3 is a graph showing the relationship between the voltage and (or feedback frequency) frequency of the piezoelectric generation system of the present invention.

4 is another graph showing the relationship between the voltage and (or feedback frequency) frequency of the piezoelectric generation system of the present invention.

5 is a flowchart of the piezoelectric generation method of the present invention.

6 is another block diagram of the piezoelectric generation system of the present invention.

7 is another flowchart of the piezoelectric generation method of the present invention.

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to piezoelectric generating systems and methods for use in nebulizers, and more particularly to the technical field using sweep frequency and electrical signal feedback.

1 is a block diagram of a conventional piezoelectric generation system. The piezoelectric generation system 1 includes a processor 10, a frequency generator 11, a signal amplifier 12 and a piezoelectric generating element 13. The processor 10 generates a predetermined control signal 101 which is communicated to the frequency generator 11. The frequency generator 11 then generates a first electrical signal 111 of a predetermined frequency which is transmitted to the signal amplifier 12. Finally, the first electrical signal 111 is processed by the signal amplifier 12 and the signal 121 is amplified. The piezoelectric generating element 13 is driven by a signal 121 to enable the nebulizer to operate normally.

However, there are some differences in the characteristics of all piezoelectric generating elements 13 applied to the nebulizer. Before the nebulizer is supplied to the market, a predetermined control signal 101 or a predetermined frequency or first electrical signal 111 needs to be predetermined. Alternatively, piezoelectric generating elements may need to be replaced or adjusted due to deterioration. The piezoelectric generating element 13 of the nebulizer can be guaranteed to operate at the optimum frequency.

In the past, such adjustments were not made in real time. In addition, no adequate protection warning or protective action is provided in case of failure of the nebulizer. Therefore, in order to overcome the above-mentioned disadvantages, the inventors of the present invention have conducted extensive research and experimentation based on years of experience in the related field, and finally piezoelectric for use in nebulizers as a method or concept that can overcome the above problems. The generation system and piezoelectric generation method were developed.

In summary, the main object of the present invention is to provide a piezoelectric generating system and a piezoelectric generating method applied to the nebulizer, thereby automatically providing an optimum operating frequency for the piezoelectric generating element of the nebulizer.

To achieve the above object, the piezoelectric generation system includes a frequency generator, a piezoelectric generating element and a processing unit, or further includes a signal amplifier or a feedback signal receiving circuit. The processing unit may control the frequency generator. Alternatively, a first electrical signal having a series of predetermined frequency band ranges is autonomously generated by the frequency generator via an external predetermined setting, whereby the first electrical signal is generated. To a piezoelectric generating element (otherwise, the first electrical signal is converted into a third electrical signal to the piezoelectric generating element by a signal simplifier). The piezoelectric generating element then generates a successive corresponding second electrical signal for the processing unit based on the first electrical signal (or third electrical signal) (otherwise, the second electrical signal is processed by the feedback signal receiving circuit. Converted to a fourth electrical signal for the unit). Thereafter, the processing unit controls the frequency generator so that the first frequency of the optimum frequency is based on the voltage value (or feedback frequency value) of the second electrical signal (or fourth electrical signal) and the frequency value corresponding to the first electrical signal. Providing an electrical signal to the piezoelectric generating element (otherwise, by the signal amplifier, the first electrical signal is converted into a third electrical signal transmitted to the piezoelectric generating element).

It is also a second object of the present invention to provide a piezoelectric generation system and a piezoelectric generation method applied to a nebulizer capable of detecting an operating condition of the piezoelectric generating element in the nebulizer and providing a protective alarm or a protective action.

According to the object of the invention, the piezoelectric generating system comprises a frequency generator, a piezoelectric generating unit, a processing unit and a protection unit, or further includes a signal amplifier or a feedback signal receiving circuit. Based on a predetermined frequency and voltage (or feedback frequency) relationship table, the processor obtains a voltage value (or feedback frequency value) having the optimum frequency. It should be noted that this relationship table can be obtained by the designer (producer) or obtained through pre-execution of the processing unit of the sweep function. The processing unit then sends a control signal to the frequency generator. The frequency generator transmits the first electrical signal of the optimum frequency to the piezoelectric generating element by receiving the control signal (alternatively, converting the first electrical signal into a third electrical signal transmitted by the signal amplifier to the piezoelectric generating element). do). The piezoelectric generating element continuously generates a corresponding second electrical signal to be transmitted to the processing unit based on the first electrical signal (or third electrical signal) (otherwise, the second electrical signal by the feedback signal receiving circuit). Is converted into a fourth electrical signal sent to the processing unit). Finally, based on the second electrical signal (or fourth electrical signal), whether the voltage value (or feedback frequency value) of the second electrical signal (or fourth electrical signal) has an abnormal change, the processing The unit detects periodically or non-periodically or continuously. If an abnormal change occurs, the processing unit notifies the protection unit to activate a protection alert or protection action. Protective alarms or protective actions include display alarms or buzzer alarms, or turn the sprayer off or light the alarm.

Also disclosed is a piezoelectric generating method according to a piezoelectric generating system, the method comprising:

(a) The frequency generator controls the frequency generator to continuously generate a plurality of first electrical signals of a predetermined frequency band for the piezoelectric generating element. Alternatively, the first electrical signal is converted into a third electrical signal delivered by the signal amplifier to the piezoelectric generating element. It should be noted that the frequency generator can continuously and automatically generate a first electrical signal having a series of predetermined frequency band ranges through predetermined settings externally.

(b) The piezoelectric generating element then generates a plurality of corresponding second electrical signals that are delivered to the processing unit based on the first electrical signal (or third electrical signal). Alternatively, the second electrical signal is converted into a fourth electrical signal delivered by the feedback signal receiving circuit to the processing unit.

(c) thereafter, the processing unit receives the voltage value (or feedback frequency value) of the second electrical signal (or fourth electrical signal) and the second electrical signal (or fourth electrical signal) from the feedback signal receiving circuit. Obtain a frequency relation corresponding to the signal. Specifically, the relationship between the voltage value of the second electrical signal and the frequency of the first electrical signal or the relationship between the feedback frequency of the second electrical signal and the frequency of the first electrical signal is obtained.

(d) The processing unit then receives a specific control signal for controlling the frequency generator to provide a first electrical signal of an optimum frequency delivered to the piezoelectric generating element based on the voltage (or feedback frequency) and frequency relationship described above. Create Alternatively, the first electrical signal is converted by the signal amplifier to a third electrical signal which is delivered to the piezoelectric generating element for optimal work performance.

(e) a third electrical signal when the frequency generator receives the control signal and the first electrical signal of optimum frequency is transmitted to the piezoelectric generating element (otherwise, the first electrical signal is transmitted to the piezoelectric generating element by a signal amplifier). The piezoelectric generating element generates a second electrical signal corresponding to the first electrical signal. Alternatively, the second electrical signal is converted by the feedback signal receiving circuit into a fourth electrical signal transmitted to the processing unit.

(f) The processing unit detects a change in the voltage value (or feedback frequency value) of the second electrical signal (or fourth electrical signal) periodically or non-periodically or continuously.

(g) if the voltage value (or feedback frequency value) detected by the processing unit has an abnormal change, for the purpose of generating a protective alarm or protective action including a display alarm or a buzzer alarm or the powering off of the sprayer or lighting of the alarm; The processing unit notifies the protection unit for this purpose.

BRIEF DESCRIPTION OF THE DRAWINGS In order to facilitate understanding of the present invention, the following describes the innovative features and performances of the present invention, the technical features and the detailed description of the present invention with reference to the accompanying drawings.

Reference is made to the drawings relating to a piezoelectric generation system and a piezoelectric generation method for use in a medical nebulizer according to a preferred embodiment of the present invention, wherein like reference numerals refer to like elements.

2 is a block diagram of a piezoelectric generation system used in the nebulizer of the present invention. The piezoelectric generation system 2 includes a processor 10, a frequency generator 11, a signal amplifier 12, a piezoelectric generating element 13 and a feedback signal receiving circuit 20. The frequency generator 11 transmits the first electrical signal 201 in a different frequency range (eg, 90-100 kHz) to the piezoelectric generating element 13 or in a different frequency range (eg, 90-100 kHz). Third electrical signal 202 is transmitted via signal amplifier 12 to piezoelectric generating element 13. In general, the piezoelectric generating element 13 needs to receive the third electrical signal 202 or the first electrical signal 201 at a specific frequency (also called an operating frequency), and thus operates normally. In the present invention, when the nebulizer starts up, the processor 10 will perform a sweep frequency function. In other words, the processor 10 uses a series of control signals 204 to control the first electrical signal 201 having various frequencies provided by the frequency generator 11. After the first electrical signal is converted into a third electrical signal 202 by the signal amplifier 12, the third electrical signal 202 is transmitted to the piezoelectric generating element 13. Meanwhile, the piezoelectric generating element 13 may provide the second electrical signal 203 to the feedback signal receiving circuit 20. The feedback signal receiving circuit 20 performs rectification or filtering on the second electrical signal 203. Alternatively, a fourth electrical signal 205 is generated and passed to the processor 10 after the combination of rectification and filtering. Then, based on the first electrical signal 201 and the fourth electrical signal 205, the processor calculates the voltage value (or feedback frequency value) responded by the piezoelectric generating element 13 in various frequency ranges. It should be noted that the frequency generator 11 can control the generation of the first electrical signal 201 having a plurality of frequencies via the processor 10. Alternatively, the first electrical signal 201 having a plurality of frequencies is automatically generated by an external predetermined setting.

Reference is made to FIG. 3 where a schematic relationship graph of voltage values (or feedback frequency values) responded by the piezoelectric generating element 13 in different frequency ranges is shown. The horizontal axis represents the various frequency values given for the piezoelectric generating element 13 and the vertical axis represents the voltage value (or feedback frequency value) responded by the piezoelectric generating element 13 corresponding to the frequency value. In an embodiment, when frequency generator 11 provides a frequency range for piezoelectric generating element 13, processor 10 typically samples two 'n' squares (n is an integer) number of frequency values. Thus, a voltage value (or feedback frequency value) corresponding to n square of 2 is calculated and obtained. In general, the processor 10 has a frequency value corresponding to a minimum voltage value (shown as symbol V1 in the figure) (or a feedback frequency value shown as symbol F3 in the figure) which is the optimum operating frequency of the piezoelectric generating element 13. (Shown as symbol F1 in the figure).

Corresponding to FIG. 3, reference is made to FIG. 4, which shows another graph showing the relationship of the voltage values (or feedback frequency values) responded by the piezoelectric generating element 13 in different frequency ranges.

The horizontal axis represents the various frequency values given for the piezoelectric generating element 13 and the vertical axis represents the voltage value (or feedback frequency value) responded by the piezoelectric generating element 13 corresponding to the frequency value. In an embodiment, when frequency generator 11 provides a frequency range for piezoelectric generating element 13, processor 10 generally samples a 'n' square of two (n is an integer) frequency value, The voltage value (or feedback frequency value) corresponding to n square of 2 is calculated and obtained. In general, the processor 10 has a frequency value corresponding to a minimum voltage value (shown as symbol V2 in the figure) (or a feedback frequency value shown as symbol F4 in the figure) which is the optimum operating frequency of the piezoelectric generating element 13. (Shown as symbol F2 in the figure).

Reference is made to FIG. 5 where a flowchart of a piezoelectric generation method applied to the nebulizer of the present invention is shown. Corresponding to FIG. 2, 3, or 4, the method of the present invention comprises the following steps. In other words:

Step 50: Control the frequency generator 11 to continuously generate a plurality of first electrical signals having a predetermined frequency band range (eg, 90-100 kHz) via the processor 10, and Converting the first electrical signal into a third electrical signal which is transmitted through the signal amplifier 12 to the piezoelectric generating element. In addition, a plurality of first electrical signals 201 having a predetermined frequency range (for example, 90-100 kHz) converted into a third electrical signal 202 transmitted by the signal amplifier 12 to the piezoelectric generating element. It should be noted that the frequency generator 11 generates automatically.

Step 51: Enable the piezoelectric generating element 13 to generate a series of corresponding second electrical signals 203 based on the third electrical signal 202 and receive the second electrical signal as a feedback signal. Converting to a fourth electrical signal 205 which is transmitted to the processor 10 via the circuit 20.

Step 52: provide an optimum operating frequency for the piezoelectric generating element 13 based on the voltage value (or feedback frequency value) of the fourth electrical signal 205 and the corresponding frequency relationship (as in FIGS. 3 and 4). Enabling the processor 10 to identify and control the frequency generator 11 (generally corresponding to a minimum feedback frequency value F3 or a minimum voltage value V1 as shown in FIG. 3). Acquiring an operating frequency F1 or acquiring an operating frequency F2 corresponding to the maximum feedback frequency value F4 or the maximum voltage value V2 as shown in FIG. 4).

Reference is made to FIG. 6 where another block diagram of a piezoelectric generation system applied to the nebulizer of the present invention is shown. Verify that the frequency generator 11 generates the first electrical signal 201 and sweep frequencies that cause the third electrical signal 202 to be converted into a piezoelectric generating element 13 by the signal amplifier 12. After the processor 10 executes, it is ensured that the piezoelectric generating element 13 is operated at the optimum operating frequency. However, in order to ensure that the piezoelectric generating element is operating at the optimum frequency or when the sprayer fails or there is a need to replace the piezoelectric generating element 13, an appropriate protective alarm or protective action is necessarily provided. The processor 10 then detects whether the fourth electrical signal 205 supplied by the piezoelectric generating element through the feedback signal receiving circuit 20 has an abnormal change. For example, if the deviation between the fourth electrical signal 205 detected by the processor 10 and the previously detected fourth electrical signal 205 reaches a predetermined threshold, the processor 10 Notifies the protection device 60 to execute a protection alarm or protection action, which protection display includes a display alarm or a buzzer alarm, or includes an operation of turning off the atomizer and turning on the alarm.

Referring to Figure 7, a flow chart of the piezoelectric generation method applied to the nebulizer of the present invention is shown. Corresponding to FIGS. 6 and 3 or 4, the method includes the following steps. In other words:

Step 70: As shown in FIG. 3 or 4, the processing unit generates a control signal 204 based on the frequency and voltage relationship table.

Step 71: A first electrical signal 201 of optimum frequency is transmitted to the piezoelectric generating element 13 via a frequency generator 11 which receives a control signal 204 from the processor 10. Alternatively, the third electrical signal 202 at the optimum frequency is transmitted via the signal amplifier 12 to the piezoelectric generating element 13.

Step 72: The piezoelectric generating element 13 generates a second electrical signal 203 which is sent to the processor 10. Alternatively, the fourth electrical signal 205 is generated by the feedback signal receiving circuit 20 and transmitted to the processor 10.

Step 73: The processor 10 continuously detects whether the second electrical signal 203 or the fourth electrical signal 205 has an abnormal change.

Step 74: If an abnormal change occurs, the protection device 60 notifies the processor 10 to cause a predetermined protection alert or protection action.

Although the present invention has been described with reference to preferred embodiments, the present invention is not limited to such description. On the contrary, the description is intended to cover various modifications and similar devices and methods, and the scope of the claims is therefore to be construed in the broadest scope so as to encompass all such modifications and similar devices and methods. something to do.

By the piezoelectric generating system and the piezoelectric generating method of the invention, the optimum operating frequency for the piezoelectric generating element of the sprayer is automatically provided, and it is also possible to detect the operating situation of the piezoelectric generating element in the sprayer and to provide a protective alarm or protective action. You can do it.

Claims (30)

As piezoelectric generation systems applicable to nebulizers: A frequency generator for continuously generating a plurality of first electrical signals having different frequencies in a predetermined frequency band range based on the plurality of control signals; A piezoelectric generating element for generating a plurality of corresponding second electrical signals based on the respective first electrical signals; A feedback signal receiving circuit for receiving a second electrical signal transmitted by the piezoelectric generating element; And A processing unit for receiving a second electrical signal from the feedback signal receiving circuit, wherein the frequency generator is controlled so that the relationship between the voltage value of the second electrical signal and the frequency of the first electrical signal or the feedback frequency of the second electrical signal And a processing unit for providing a piezoelectric generating element with a first electrical signal of an optimum frequency based on a relationship with a frequency of the first electrical signal, and selectively generating a control signal, The number of frequencies of the first electrical signal is n squared of two, the frequency of the first electrical signal is selected from a predetermined band range, and corresponds to a voltage value or a feedback frequency value of the second electrical signal, respectively, where n is Piezoelectric generation system that is an integer. The piezoelectric generation system of claim 1, wherein said frequency generator delivers a first electrical signal to said piezoelectric generating element. delete delete The piezoelectric generation system of claim 1, wherein the optimum frequency corresponds to a maximum or minimum voltage value of the feedback frequency value. The piezoelectric generation system of claim 1, further comprising a protection unit coupled with the processing unit. 7. The protection unit according to claim 6, wherein the protection unit determines whether a protection alarm or activation of a protection action is required when the processing unit detects a feedback frequency value or a voltage value of the second electrical signal generated by the piezoelectric generating element. To determine the piezoelectric generation system. 8. The piezoelectric generation system according to claim 7, wherein the protection alarm or protection action is a display alarm or a buzzer alarm, or is for turning off the atomizer or turning on the alarm. As piezoelectric generation systems applicable to nebulizers: A frequency generator for receiving a control signal to transmit a first electrical signal; A piezoelectric generating element for generating a corresponding second electrical signal based on the first electrical signal; A feedback signal receiving circuit for receiving a second electrical signal transmitted by the piezoelectric generating element; And A processing unit for receiving a second electrical signal from the feedback signal receiving circuit, the control unit generating a control signal based on a relationship table that records the relationship between the frequency or voltage value of the second electrical signal and the frequency of the first electrical signal; A processing unit for detecting whether a feedback frequency or voltage value of the second electrical signal has an abnormal change; The relationship table is obtained from the processing unit pre-executing the sweep frequency function, and records a feedback frequency or voltage value corresponding to two n-square frequencies of the first electrical signal and these frequencies of the first electrical signal; and n are integers. 10. The piezoelectric generation system of claim 9, wherein said frequency generator delivers a first electrical signal to a piezoelectric generating element through a signal amplifier. delete delete 10. The piezoelectric generation system of claim 9, wherein said first electrical signal having an optimal frequency corresponds to a maximum or minimum voltage value of a feedback frequency value. 10. The piezoelectric generation system of claim 9, further comprising a protection unit coupled with the processing unit. The protection unit of claim 14, wherein the protection unit is further configured to activate the protection alert or the protective action based on whether the feedback frequency value or the voltage value of the second electrical signal detected by the processing unit has an abnormal change. Piezoelectric generation system to determine whether it is necessary. 16. The piezoelectric generation system of claim 15, wherein said protective alarm or protective action is a display alarm or a buzzer alarm, or is for turning off the atomizer or turning on the alarm. Piezoelectric generation methods applicable to nebulizers include: Pre-determining or controlling the frequency generator via a processing unit to continuously generate a plurality of first electrical signals with piezoelectric generating elements having different frequencies within a predetermined frequency band range; Causing the piezoelectric generating element to generate a plurality of corresponding second electrical signals based on the first electrical signals; Transmitting the second electrical signal to the processing unit via a feedback signal receiving circuit; And Optimal for piezoelectric generating elements in the first electrical signal based on the relationship between the voltage value of the second electrical signal and the frequency of the first electrical signal or the relationship between the feedback frequency of the second electrical signal and the frequency of the first electrical signal. Causing the processing unit to control a frequency generator to provide a frequency; Wherein the predetermined frequency band range is pre-divided by an n-squared frequency value of two, corresponding to a feedback frequency or voltage value of a second electrical signal, respectively, wherein n is an integer. 18. The method of claim 17, wherein the first electrical signal is further delivered by a signal amplifier to the piezoelectric generating element. 18. The method of claim 17, wherein the second electrical signal is further delivered to the processing unit by a feedback signal receiving circuit. delete 18. The method of claim 17, wherein the first electrical signal at an optimal frequency corresponds to a feedback frequency of a second electrical signal or a maximum or minimum voltage value. 18. The method of claim 17, further comprising determining whether a protection alert or activation of a protective action is required when the processing unit detects a feedback frequency value or a voltage value generated by the piezoelectric generating element. . 23. The method of claim 22, wherein the protective alarm or protective action is a display alarm or a buzzer alarm, or to turn off the atomizer or to light an alarm. Piezoelectric generation methods applicable to nebulizers include: Receiving a control signal through a frequency generator and transmitting a first electrical signal; Delivering a first electrical signal to a piezoelectric generating element to generate a corresponding second electrical signal based on the first electrical signal; Transmitting the second electrical signal to a processing unit via a feedback signal receiving circuit; And The control signal is transmitted from the processing unit based on a relationship table that records the relationship between the frequency or voltage value of the second electrical signal and the frequency of the first electrical signal, and the feedback frequency value or voltage value of the second electrical signal is Detecting whether there is an abnormal change; The relation table is obtained by the processing unit pre-executing the sweep frequency function, and the piezoelectric generation recording a feedback frequency or a corresponding voltage value associated with a second n-square frequency of the first electrical signal and a second electrical signal. Way. 25. The method of claim 24, wherein said first electrical signal is delivered to a piezoelectric generating element by a signal amplifier. delete delete 25. The method of claim 24, wherein the first electrical signal at an optimal frequency corresponds to a feedback frequency value or a maximum or minimum voltage value associated with the second electrical signal. 25. The method of claim 24, wherein determining whether a protection alert or activation of a protective action is necessary based on whether the feedback frequency value or voltage value of the second electrical signal detected by the processing unit has an abnormal change. Piezoelectric generation method further comprising. 30. The method of claim 29, wherein the protective alarm or protective action is a display alarm or a buzzer alarm, or to power off the sprayer or to light an alarm.

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