KR20130003205A - Method and apparatus for measuring hydraulic pressure using vibration of gererator in self-generating videt - Google Patents

Abstract

PURPOSE: An apparatus and a method for measuring water pressure using the vibration of a power generator is provided to measure the pressure of raw water by simply attaching a vibration conversion module to the case of the power generator. CONSTITUTION: An apparatus for measuring water pressure using the vibration of a power generator(120) comprises a charging unit, a vibration conversion module(121), a signal conversion module(131), and a water pressure measuring module(132). The vibration conversion module converts the vibration of the power generator into output signals. The signal conversion module converts the output signals into square wave signals. The water pressure measuring module calculates the pressure of raw water from the number of edges per unit time. The power generator is fixed by a first support(120b) and first elastic material(120c). The vibration conversion module is fixed by a second support(121a), and attached to the case of the power generator by a second elastic material. [Reference numerals] (121) Vibration conversion module; (131) Signal conversion module

Description

METHOD AND APPARATUS FOR MEASURING HYDRAULIC PRESSURE USING VIBRATION OF GERERATOR IN SELF-GENERATING VIDET}

The present invention relates to a bidet, and more particularly to a method and apparatus for measuring the water pressure of the raw water in the bidet to perform self-generation by the introduced raw water.

In general, a bidet is a device for cleaning the anus and / or female part of the human body and is also called a hot water washing device or a local washing device.

The bidet includes a mechanical bidet that sprays water by directly operating a lever, and various operations provided to the bidet by pressing a button of a specific function, for example, a bidet function, a cleaning function, a nozzle cleaning function, and a drying function. There is an electronic bidet that does this automatically.

However, the mechanical bidet does not have a separate external power source, so the user has to adjust all the operations, and the electronic bidet can be operated only when an external power source is connected. Not available in.

In order to solve the difficulty of connecting the electric bidet of the electronic bidet, it is possible to consider a method of using various functions of the bidet using a battery, but in this case, it is inconvenient to replace the battery from time to time.

In order to solve this problem, a self-powered bidet for providing electricity by performing power generation using water pressure of raw water supplied from a water tap has been proposed. Since the power generation amount of the generator depends on the pressure of the raw water, it is necessary to measure the pressure of the raw water.

The present invention has been made to solve the above problems, there is a technical problem to provide a method and apparatus for measuring water pressure using generator vibration in a self-powered bidet capable of measuring the water pressure of raw water from the vibration of the generator.

The first technical aspect of the present invention for solving the above problems of the present invention,

In the water pressure measuring device of the self-powered bidet including a generator for generating power by the introduced raw water, and a charging unit for charging the electricity generated by the generator,

A vibration conversion module for detecting vibration of the generator and converting the vibration into an electrical output signal;

A signal conversion module for converting the converted electrical output signal into a square wave signal; And

It provides a hydraulic pressure measurement apparatus using a generator vibration comprising a hydraulic pressure measurement module for obtaining the hydraulic pressure of the raw water from the number of edges per unit time of the converted square wave signal.

According to an embodiment of the present invention, the vibration conversion module,

The apparatus may further include an amplification module for amplifying the converted electrical output signal or a filter module for low pass filtering the amplified output signal.

According to an embodiment of the invention, the hydraulic pressure measuring module,

A first module detecting an edge of the converted square wave signal;

A second module for obtaining a frequency of the generator based on the number of edges detected per unit time; And

On the basis of the obtained frequency of the generator, it may include a hydraulic pressure measuring module for obtaining the water pressure of the introduced raw water.

In addition, according to an embodiment of the present invention, the generator,

It is fixed by the first support member via the first elastic material,

The vibration conversion module may be fixed by a second support member and attached to an enclosure of the generator via a second elastic material.

The second technical aspect of the present invention for solving the problems of the present invention,

In the hydraulic pressure measurement method of a self-powered bidet comprising a generator for generating power by the introduced raw water, and a charging unit for charging the electricity generated by the generator,

Sensing vibration of the generator through a vibration conversion module and converting the vibration into an electrical output signal;

Converting the converted electrical output signal into a square wave signal; And

It provides a hydraulic pressure measurement method using a generator vibration comprising the step of obtaining the hydraulic pressure of the raw water from the number of edges per unit time of the converted square wave signal.

According to an embodiment of the present invention, the vibration conversion module,

The apparatus may further include an amplification module for amplifying the converted electrical output signal or a filter module for low pass filtering the amplified output signal.

According to an embodiment of the invention, the hydraulic pressure measuring module,

A first module detecting an edge of the converted square wave signal;

A second module for obtaining a frequency of the generator based on the number of edges detected per unit time; And

On the basis of the obtained frequency of the generator, it may include a hydraulic pressure measuring module for obtaining the water pressure of the introduced raw water.

In addition, according to an embodiment of the present invention, the generator,

It is fixed by the first support member via the first elastic material,

The vibration conversion module may be fixed by a second support member and attached to an enclosure of the generator via a second elastic material.

According to one embodiment of the present invention, by simply attaching a vibration conversion module such as a piezoelectric element to an enclosure of a generator, there is a technical effect of measuring the hydraulic pressure of raw water from vibration of the generator.

1 is an overall block diagram of a self-powered bidet in accordance with one embodiment of the present invention.
2 is a view showing an elastic material for fixing the generator and the generator according to an embodiment of the present invention.
3 is a flowchart illustrating a hydraulic pressure measurement apparatus using generator vibration according to an embodiment of the present invention.
4 is a flowchart illustrating a water pressure measuring method using generator vibration according to an embodiment of the present invention.

Hereinafter, various embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, embodiments of the present invention may be modified in various other forms, and the scope of the present invention is not limited to the embodiments described below. The embodiments of the present invention are provided to more fully explain the present invention to those skilled in the art. Accordingly, it should be noted that the shapes, sizes, etc. of the components shown in the drawings may be exaggerated for clarity.

1 is an overall block diagram of a self-powered bidet in accordance with one embodiment of the present invention.

First, a self-powered bidet 180 according to an embodiment of the present invention will be described with reference to FIG. 1.

As shown in FIG. 1, the self-powered bidet 180 includes a generator 120 for generating power by the raw water inlet 110 through which raw water is introduced, the raw water introduced into the raw water inlet 110, and a generator. The charging unit 130 for storing the electricity generated by the 120, the nozzle unit 150 configured to spray the raw water introduced into the raw water inlet 110, and the raw water passed through the generator 120 nozzle unit And a nozzle flow path unit 140 provided between the generator 120 and the nozzle unit 150 to supply to the 150, and a control unit for controlling the opening and closing of the flow path of the nozzle flow path unit 140 so that the generator 120 is driven. (C) may be further included. In addition, although not shown in Figure 1, the self-powered bidet 180 to which the method according to the present invention is applicable is provided with a separate reservoir tank (not shown), a reservoir tank and a generator for storing raw water through the generator 120. It may further include a tank flow path portion (not shown) provided between.

The raw water inlet 110 receives raw water from a raw water supply unit 101 installed outside the bidet housing 180, such as a water pipe or a pipe connected thereto, and has a connection port for connecting to the water pipe.

Raw water introduced from the raw water inlet 110 is introduced into the generator 120 to generate power. As an example, the generator 120 used in the present invention is provided with an impeller (aberration) (not shown) to generate the rotation of the impeller when the raw water flows into the generator 120, thereby generating power. In addition, the charging unit 130 is electrically connected to the generator 120 to store the electricity generated in the generator 120, the electricity charged in the charging unit 130 is the use of the bidet, that is, nozzle drive unit 160 or various valves ( It is used for driving the 143, 144, and 147, operation of a sensor, and the like. As such, the configuration of the generator 120 to generate power by the flow of the fluid is known in various forms, so a detailed description thereof will be omitted.

On the other hand, the raw water passed through the generator 120 is supplied to the nozzle unit 150 through the nozzle passage 140. At this time, the nozzle passage 140 may be provided with a variety of valves 143, 144, 147 to supply or block the raw water to the nozzle unit 150, the specific configuration is not limited to the example shown in FIG.

In addition, the nozzle unit 150 may be made of only the injection nozzle 151 for cleaning the anus and / or the female part of the human body, but to clean the outer surface of the injection nozzle 151 (particularly, the upper surface of the injection nozzle) It may be configured to include a washing nozzle 152 for spraying the raw water to the upper surface side of the injection nozzle (151).

At this time, as shown in Figure 1, the nozzle flow path 140 is a spray nozzle passage 146 for supplying raw water to the injection nozzle 151 and a washing nozzle passage for supplying raw water to the washing nozzle 152 ( 148). The injection nozzle flow path 146 is provided with a first on-off valve 143 for opening and closing the injection nozzle flow path 146, the flow control valve to adjust the flow rate of the raw water passing through the first on-off valve 143 ( 144 may be installed. In addition, a second opening / closing valve 147 may be installed in the washing nozzle passage 148 to open and close the washing nozzle passage 148.

At this time, the first on-off valve 143 and the second on-off valve 147 is preferably composed of a latch valve that is turned on / off (ON / OFF) by an electrical signal in order to minimize power consumption. Since the configuration of the latch valve is known in various forms and structures, a detailed description thereof will be omitted.

In addition, the flow control valve 144 may also be configured as a latch valve capable of adjusting the flow rate by being turned on / off by an electrical signal. As shown in FIG. 1, the flow regulating valve 144 includes a body 144a having one inflow path into which raw water is introduced and a plurality of outlet paths 145a and 145b that are selectively opened to control the flow rate. A plurality of water outlets 144b into which the plurality of water outlet passages 145a and 145b are combined may be provided.

On the other hand, the nozzle passage 140 is a manual valve for forcibly blocking the passage in the case of adjusting the opening and closing amount of the valve to adjust the inflow of raw water, or when an abnormality occurs in the components constituting the passage, or the parts need to be replaced ( 142 may be installed, the manual valve 142 is normally kept open.

In addition, the injection nozzle 151 may be provided with a bidet nozzle and a cleaning nozzle, that is, two nozzles that perform respective functions to perform a bidet function and a cleaning function, but is not limited thereto. Do.

In addition, the nozzle unit 150 may include a nozzle driving unit 160 for moving the injection nozzle 151 in the front-rear direction. In this case, the nozzle driving unit 160 may achieve a reduction in power consumption as compared to the case of using a stepping motor by using a DC motor.

Specifically, the efficiency of DC motor is 75% ~ 80%, but the stepping motor has to use current with multiple phases for precise position control, so current usage efficiency is 50 ~ 60%, which is 25 ~ 30% lower than the above DC motor. Level. Therefore, when using a DC motor as an embodiment of the present invention has an excellent effect in terms of power consumption compared to the case of using a stepping motor is suitable for a self-powered bidet. As the DC motor, a brush DC motor or a brushless DC motor may be used.

In addition, the movement of the injection nozzle 151 by the driving of the nozzle driver 160 may be controlled by using a variable resistor associated with a DC motor. Since a technique for controlling the amount of rotation of the DC motor by the variable resistor is known, a detailed description thereof will be omitted.

On the other hand, when only one injection nozzle 151 is provided in the nozzle unit 150, cleaning is performed through one injection nozzle 151 by controlling the driving of the nozzle driver 160 so that the moving distance of the injection nozzle 151 is different. Functions and bidet functions can be implemented. As such, when only one injection nozzle 151 is provided, the nozzle unit 150 is simpler in configuration than the two injection nozzles 151 and only one injection nozzle 151 is moved. There is an advantage that control of 160 is easy. That is, when two injection nozzles 151 are provided, a complicated gear structure is required to move only one injection nozzle 151 as one nozzle driving unit (motor) 160, but one injection nozzle 151 is required. If only) is used, the structure for driving the injection nozzle 151 is simple, which facilitates the control of the nozzle driver 160. In addition, as described above, when the DC motor is used as the nozzle driving unit 160 and the moving distance of the injection nozzle 151 (that is, the amount of rotation of the DC motor) is controlled by a variable resistor, a stepping motor is used. Reduction of power consumption can be achieved.

On the other hand, when high-pressure raw water directly flows into the generator 120, a considerable noise is generated due to the rapid rotation of the impeller, so that the noise generated by the self-power generation is minimized in the high-pressure region, but the power generation nozzle can be secured. In order to prevent the damage of the components installed in the unit 140 from occurring, it is necessary to properly reduce the raw water pressure. For this purpose, it is preferable to install a pressure reducing valve 115 for reducing the raw water pressure to a predetermined level or less between the raw water inlet 110 and the generator 120.

As such, since the self-powered bidet 100 illustrated in FIG. 1 performs power generation of the generator 120 while discharging raw water through the nozzle unit 150, the self-powered bidet 100 may be installed in a toilet without a water storage tank. . In particular, when the bidet is used to perform power generation using raw water discharged through the spray nozzle 152 or raw water sprayed through the spray nozzle 151, the power generation capacity is not sufficient or the voltage of the charging unit 130 In this case, a sufficient amount of raw water is discharged through the nozzle unit 150, for example, the washing nozzle 152 for a sufficient time (for example, 1 to 2 minutes per minute of raw water is discharged). Development is possible.

In addition, in the case of having a storage tank (not shown), as well as power generation using the raw water discharged through the washing nozzle 152 for washing raw water or nozzles sprayed through the spray nozzle 151 when the bidet is used, the storage tank ( Since power generation using raw water supplied to 230 is performed, power generation of sufficient capacity is possible. In addition, when the voltage of the charging module included in the rotation speed limiter 130 is low, power generation is performed through a large amount of raw water forcibly discharged through the nozzle unit 150, for example, the washing nozzle 152. There are many ways to generate electricity and to make up for the lack of electricity.

2 is a view showing a generator and an elastic material for fixing the generator according to an embodiment of the present invention, Figure 3 is a flow chart illustrating a hydraulic pressure measurement device using a generator vibration according to an embodiment of the present invention.

Hereinafter, a hydraulic pressure measuring apparatus using generator vibration according to an embodiment of the present invention will be described in detail.

Referring to FIG. 2, a first elastic material 120a such as rubber may be attached to the generator 120, and a hole H may be formed in the first elastic material 120a. The generator 120 having such a configuration may be fixed to the inside of the bidet body through the first member member 120b of FIG. 3, and vibrates in various directions such as up, down, left, and right in proportion to the water pressure of the raw water. According to one embodiment of the present invention, the vibration of the generator according to the hydraulic pressure of the raw water is to indirectly measure the hydraulic pressure of the raw water through a vibration conversion module such as a piezoelectric element.

The generator 120 generates power by the introduced raw water. The generator 200 is provided with an impeller (aberration) (not shown) when the raw water flows into the generator 120, the rotation of the impeller may occur and thereby generate power. The generated power is stored in the charging unit 130 (see FIG. 1). As such, the configuration of the generator 120 to generate power by the flow of fluid is known in various forms, so a detailed description thereof will be omitted.

On the other hand, Figure 3 is a hydraulic pressure measuring device using a generator vibration according to an embodiment of the present invention.

2 to 3, the hydraulic pressure measuring device is a vibration conversion module 121 and the vibration conversion module 121 attached to the generator 120 via an elastic material such as vibration transfer rubber in the enclosure of the generator 120. It may include a module 130 for obtaining the water pressure of the raw water from the signal transmitted from).

In particular, the first support member 120b penetrating the groove H formed in the first elastic material 120a is fixed to the inside of the bidet body 180 so that the generator 120 may be fixed and the first elastic member The material 120a is made of a material having elasticity such as rubber, and the generator 120 vibrates in various directions of up, down, left, and right by hydraulic pressure of raw water.

In addition, the vibration conversion module 121 may also be fixed to the inside of the bidet body 180 by the second support member 121a, the vibration conversion module 121 and the generator 120 is a second elastic such as rubber The material 121 may be connected via a medium. Through such a configuration, the vibration of the generator 120 may be transmitted to the vibration conversion module 121. The vibration conversion module 121 may be, for example, a piezoelectric element using a piezoelectric effect, and may convert the vibration of the generator 120 into an electrical output signal and transmit the converted signal to the signal conversion module 131. Here, the electrical output signal may be a waveform similar to a sine wave. On the other hand, the electrical output signal may be a very fine signal, it may include an amplification module (not shown) for amplifying such a fine signal. The apparatus may further include a filter module (not shown) to remove noise by low pass filtering the amplified output signal.

Meanwhile, the module 130 may be embodied as a signal conversion module 131 and a hydraulic pressure measurement module 132. The signal conversion module 131 may convert an electric output signal received from the vibration conversion module 121 into a square wave signal. Can be converted to The converted square wave signal may be transmitted to the hydraulic pressure measurement module 132.

Finally, the hydraulic pressure measurement module 132 may include a first module 132a, a second module 132b, and a third module 132c. In detail, the first module 132a may detect the number of edges per unit time of the square wave signal received from the signal conversion module 131. The detected number of edges per unit time may be passed to the second module 132b. Thereafter, the second module 132b may obtain the frequency of the generator 120 based on the number of edges per unit time received from the first module 132a. The number of edges per unit time and the frequency of the generator 120 may be stored in advance in the form of a lookup table. The obtained frequency of the generator 120 may be transmitted to the third module 132c. Meanwhile, the third module 132c may measure the water pressure of the raw water based on the frequency of the generator 120 received from the second module 132b. Similarly, the frequency of the generator 120 and the water pressure of the raw water may be stored in advance in the form of a lookup table.

Although described above, the frequency of the generator 120 is obtained from the number of edges per unit time, and the water pressure of the raw water is calculated from the obtained frequency of the generator 120. However, this is merely an example. You can also get the pressure of the raw water directly. In this case, it is necessary to store the pressure of the raw water corresponding to the number of edges per unit time in the form of a lookup table in advance.

As described above, according to the embodiment of the present invention, by simply attaching a vibration conversion module such as a piezoelectric element to the generator enclosure, there is a technical effect of measuring the hydraulic pressure of raw water from the vibration of the generator.

4 is a flowchart illustrating a water pressure measuring method using generator vibration according to an embodiment of the present invention.

Referring to FIG. 4, power generation by the generator 120 is first performed by the introduced raw water, and vibration is generated in the generator 120 by the hydraulic pressure of the raw water. The vibration is transmitted to the vibration conversion module 121, and is converted into an electrical output signal by the vibration conversion module 121 (S400). The converted electrical output signal may be transmitted to the signal conversion module 131.

Thereafter, the signal conversion module 131 may convert the electrical output signal received from the vibration conversion module 121 into a square wave signal (S401). The converted square wave signal may be transmitted to the hydraulic pressure measurement module 132.

Finally, the hydraulic pressure measurement module 132 may calculate the hydraulic pressure of the raw water from the frequency of the converted square wave signal (S402). In detail, the first module 132a may detect the number of edges per unit time of the square wave signal received from the signal conversion module 131. The detected number of edges per unit time may be passed to the second module 132b. Thereafter, the second module 132b may obtain the frequency of the generator 120 based on the number of edges per unit time received from the first module 132a. The number of edges per unit time and the frequency of the generator 120 may be stored in advance in the form of a lookup table. The obtained frequency of the generator 120 may be transmitted to the third module 132c. Meanwhile, the third module 132c may measure the water pressure of the raw water based on the frequency of the generator 120 received from the second module 132b. Similarly, the frequency of the generator 120 and the water pressure of the raw water may be stored in advance in the form of a lookup table.

As described above, one may find the raw water pressure directly from the number of edges per unit time. In this case, it will be necessary to store in advance the hydraulic pressure of the raw water corresponding to the number of edges per unit time in the form of a lookup table.

As described above, according to the embodiment of the present invention, by simply attaching a vibration conversion module such as a piezoelectric element to the generator enclosure, there is a technical effect of measuring the hydraulic pressure of raw water from the vibration of the generator.

The best embodiments have been disclosed in the drawings and specification above. Although specific terms have been employed herein, they are used for purposes of illustration only and are not intended to limit the scope of the invention as defined in the claims or the claims. Therefore, those skilled in the art will understand that various modifications and equivalent other embodiments are possible from this. Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims.

180 ... Self-powered bidet 101 ... Raw water supply
110 ... Raw water inlet 115 ... Pressure reducing valve
120 ... generator 120a ... first elastic material
120b .. First support member 120c .. First elastic material
121 ... vibration conversion module 121a .. second supporting member
130 ... Module 131 ... Signal Conversion Module
132 ... Hydraulic module 132a .. 1st module
132b .. Second Module 132c .. Third Module
140 ... nozzle flow path 141 ... nozzle flow path
141a ... Mixing valve 142 ... Manual valve
143 ... 1st valve 144 ... flow control valve
145a .. First Euro 145b ... Second Euro
146 ... injection nozzle flow path 147 ... second on-off valve
148 ... nozzle for cleaning 150 ... nozzle
151 ... Nozzle 152 ... Cleaning nozzle
160 ... nozzle drive
C ... control unit S .... Detection sensor

Claims (10)

In the water pressure measuring device of the self-powered bidet including a generator for generating power by the introduced raw water, and a charging unit for charging the electricity generated by the generator,
A vibration conversion module for detecting vibration of the generator and converting the vibration into an electrical output signal;
A signal conversion module for converting the converted electrical output signal into a square wave signal; And
And a hydraulic pressure measurement module for calculating the hydraulic pressure of the raw water from the number of edges per unit time of the converted square wave signal. The method of claim 1,
The generator is fixed by a first support member via a first elastic material,
The vibration conversion module is fixed by a second support member, the hydraulic pressure measuring device using a generator vibration in a self-powered bidet attached to the enclosure of the generator via a second elastic material. The method of claim 1,
The vibration conversion module,
Hydraulic apparatus using a generator vibration further comprises an amplification module for amplifying the converted electrical output signal. The method of claim 3,
The vibration conversion module,
And a filter module for low-pass filtering the amplified output signal. The method of claim 1,
The hydraulic pressure measurement module,
A first module detecting an edge of the converted square wave signal;
A second module for obtaining a frequency of the generator based on the number of edges detected per unit time; And
A hydraulic pressure measurement apparatus using a generator vibration comprising a hydraulic pressure measurement module for calculating the hydraulic pressure of the introduced raw water based on the frequency of the generator. In the hydraulic pressure measurement method of a self-powered bidet comprising a generator for generating power by the introduced raw water, and a charging unit for charging the electricity generated by the generator,
Sensing vibration of the generator through a vibration conversion module and converting the vibration into an electrical output signal;
Converting the converted electrical output signal into a square wave signal; And
Obtaining the hydraulic pressure of the raw water from the number of edges per unit time of the converted square wave signal. The method according to claim 6,
The generator is fixed by a first support member via a first elastic material,
The vibration conversion module is fixed by a second support member, the hydraulic pressure measurement method using a generator vibration in a self-powered bidet attached to the enclosure of the generator via a second elastic material. The method according to claim 6,
Converting to the electrical output signal,
A hydraulic pressure measurement method using a generator vibration further comprising the step of amplifying the converted electrical output signal. 9. The method of claim 8,
Converting to the electrical output signal,
And low pass filtering the amplified output signal. The method according to claim 6,
Obtaining the water pressure of the raw water,
Detecting an edge of the converted square wave signal;
Obtaining a frequency of the generator based on the number of edges detected per unit time; And
Based on the predicted frequency of the generator, the hydraulic pressure measurement method using the generator vibration comprising the step of obtaining the water pressure of the introduced raw water.

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