KR20070115495A - Urinary flow rate measuring method and system for thereof - Google Patents

Abstract

A method for measuring a urinary flow rate and a system thereof are provided to obtain an effective and efficient urinary flow signal by not using a special funnel used to prevent an impact noise. A method for measuring a urinary flow rate includes the steps of: transmitting pressure of urine(113) accumulated in a container(100) to an outside of a pressure sensor(116) through a pressure transmission pipe(115); generating an electric signal as a voltage signal corresponding to a capacity signal in the pressure sensor; amplifying the electric signal through a bridge amplifier in the pressure sensor; changing the amplified analog signal into a digital signal; and deriving the urinary flow signal by a mathematical differentiation after changing the transmitted water pressure signal into a volume signal by interfacing the digital signal with an analyzing device.

Description

Urinary flow rate measuring method and system for using pressure gauge

1 is a conceptual diagram of a conventional urine flow inspection method

Figure 2 is a urine flow test result graph of normal people by the conventional method

Figure 3 is a graph of the results of test measurements by the conventional method

4 is a conceptual diagram of the urine flow test method according to the present invention

5 is a schematic diagram for carrying out the method according to the invention.

6 is a graph of test measurement results according to the present invention

<Description of the symbols for the main parts of the drawings>

10, 100: container 12: weight sensor 13, 113: urine

115: pressure transfer pipe 116: pressure sensor

The present invention relates to a method and apparatus for measuring urine flow, and more particularly, to a method and apparatus for measuring urine flow using a pressure gauge.

Urination in men passes through the urethra, which is surrounded by the prostate under the bladder

Is done. In other words, the prostate gland is the only organ that only males have, which is a chestnut-shaped soft tissue about 20g below the bladder, and the glandular organs surrounding the urethra. It is one of the representative chronic diseases in the elderly society, which affects about 50% to 80% of men, especially men over 50. When such an enlarged prostate gland occurs, the urethra surrounded by the prostate gland is compressed, resulting in urination abnormalities, as well as sexual dysfunction.

The method of determining whether there is an abnormality of the prostate gland, that is, whether there is an enlarged prostate, uses a uro-flowmetry method that continuously measures a urinary flow rate signal indicating urine volume per unit time during urination. This is an essential biometric test for the diagnosis of enlarged prostate.

Conventional urine flow test method as described above is based on the measurement of the weight of the urine (weight), as shown schematically in Figure 1, accumulating urine 13 in a container 10 of constant diameter as shown in FIG. 10) It is a method for measuring the change in weight (weight) during the urination process by placing a weight sensor 12, which is a load cell (load-cell) element that is mounted below to measure the weight. In this method, the weight w measured by the weight sensor 12 is proportional to the volume v of urine contained in the container 10. That is, the weight of urine represented by the weight sensor 12 is w, the volume of urine contained in the container 10 is v, the cross-sectional area of the container is A, the density of urine is ρ, and the container 10 H is the height of the urine,

Weight (W) = ρgAh, where the product of the cross-sectional area (A) of the container and the height (h) of the urine is the volume of urine (v),

W = ρgAh = ρgv.

Since the density (ρ) of urine is almost equal to water, it is regarded as 1 and g is constant as a gravity constant, so the equation

W = ρgAh = ρgv∝v.

Therefore, by measuring the change in the urine weight accumulated during the urination process can be seen the change in the urine volume. However, in order to determine whether there is an abnormality in the prostate gland, the actual biological variable to be calculated is a urine flow signal. That is, since the urine flow is defined as the rate of change of the volume of time, the urine flow signal is calculated by differentiating a weight signal proportional to the volume with respect to time.

Figure 2 shows a graph of an example of the urine flow test by the conventional method as described above.

In other words, Figure 2 shows an example of the results of the conventional urine test showing the volume signal obtained by measuring the urine weight of a normal person, differential urine signal and all the diagnostic parameters obtained from the analysis (urination disorder and urinary incontinence. Disability and Urinary Incontinence Society, Sculpture, P.331, 2003).

As described above, the conventional urinary flow test method and apparatus adopts continuously measuring a change in weight by using a weight sensor while receiving urine in a container, and testing the volume signal based on the urine flow signal and the differential urine flow signal.

 However, in the above-described conventional apparatus and method, when urine 13 accumulates in the container 10 during urination, the urine stem (dotted line: see FIG. 1) directly touches the bottom surface of the container 10 to the weight of the urine. In addition, the bottom surface of the container 10 is further impacted by the momentum of the urine stem (mass shock rate), and thus the impact amount is transmitted to the weight sensor 12 as well as the weight of the urine. Since it is transmitted to the weight sensor 12 unspecifically according to the amount and speed of the urine stem acts as a measurement noise, there is a problem that leads to a decrease in reliability when calculating the differential process and diagnostic parameters to obtain urine flow.

 3 is a graph of a test measurement result using the conventional method as described above, and a graph of a result of performing an experiment of obtaining a volume signal by pouring 800 mL of water instead of urine in a urination state and measuring a weight, and measuring the signal overall It can be seen that noise exists. In order to prevent this impact effect, a funnel is usually used to minimize the amount of impact by allowing urine to descend down the wall of the container. In this case, the funnel is designed and manufactured separately to precisely collect and collect the container. This is followed by cumbersome problems such as plugging in and using it.

 In addition, load-cell, a sensor element used in conventional weighing, is extremely expensive, with a minimum price of about 70,000 won for domestic products, and high-quality products with high measurement precision are expensive enough to cost 1,000,000 won, thus greatly reducing the production cost of the measuring device. It is a major cause of the rise and has economic problems.

 Therefore, the present invention is to solve the problems of the prior art as described above, the object of the present invention is to measure the water pressure with a general-purpose low-cost pressure sensor instead of measuring the weight with a conventional high-priced load cell shock by obtaining a volume signal The present invention provides a method and apparatus for measuring urine flow using a pressure gauge, which can prevent noise and of course, eliminate the use of a funnel.

In order to achieve the object of the present invention as described above, the present invention, in the urine flow measuring method, the pressure of the amount of urine accumulated in the container is transmitted to the external pressure sensor through the pressure transfer tube, the water pressure delivered to the pressure sensor Generates an electrical signal, a voltage signal corresponding to a volumetric signal, by a pressure sensor, amplifies the generated electrical signal through a bridge amplifier, converts the amplified analog signal into a digital signal, and interfaces with an analysis device for analysis. The present invention provides a urine flow measuring method using a pressure gauge, which converts a hydraulic pressure signal into a volume signal and differentially calculates a urine flow signal. The analysis apparatus in the above may use a computer or a dedicated analysis apparatus.

In addition, since the pressure sensor in the form of a conventional fitness stone bridge (Wheatstone bridge) consisting of four resistance elements, a general purpose, for example, the general purpose multi-purpose disclosed in the Republic of Korea Utility Model Registration No. 404559 registered in the name of the applicant A bridge amplifier can be used or a dedicated bridge amplifier circuit can be connected. The interface with the analyzer uses an RS-232C serial communication port or a device capable of interfacing.

 The present invention also provides a vessel in which urine accumulates, a pressure transfer tube inserted into the vessel and connected to an external pressure sensor, and for extracting and amplifying the pressure signal. An amplifier, a converter for converting an amplified analog signal into a digital signal, and an analysis device and an interface with the converted digital signal provide a current measurement system composed of an analysis device.

The analyzer may be a dedicated analyzer or computer, and the interface may be an RS-232C serial communication port.

 Hereinafter, the present invention will be described in more detail with reference to preferred embodiments.

 According to the present invention, when urine is accumulated in the container 100 having a constant cross-sectional area A as shown in FIG. 4, the water pressure P generated at the bottom surface of the container 100 is proportional to the height h of the accumulated urine. So that

 Hydraulic pressure (P) = ρgh,

 Here, the cross-sectional area (A) is equally multiplied by the denominator and numerator

             ρgAh

P = ρgh = ───

               A

Here, as described above, the height (h) of urine times the cross-sectional area (A) of the container becomes the volume (V) of urine.

             ρgAh ρg

 P = ρgh = ─── = ── · V,

              A A

Since ρ is the density of urine and is almost equal to water as described above, it can be regarded as 1 and g becomes constant as a gravity constant.

        g

 P = ρ ─ V ∝ V is established,

        A

The pressure P becomes proportional to the volume V.

Therefore, as long as the cross-sectional area (A) of the container 100 to be used is constant, the water pressure (P) at the bottom surface is proportional to the volume (V) of the urine 113 accumulated as well as the weight (W). Instead, by measuring the pressure (P) signal it is possible to perform the urine flow measurement test by calculating the urine flow signal in a simpler manner than the conventional method.

That is, as shown in Figure 5 when the pressure transfer tube 115, which is a thin tube as shown in the bottom surface of the container 100, the pressure (P) of the bottom surface of the Pascal (Pascal) According to the principle, the pressure P according to the amount of urine 113 is transmitted to the external pressure sensor 116 through the pressure transfer tube 115, and the pressure sensor 116 functions to convert water pressure into voltage. Therefore, the voltage signal corresponding to the volumetric signal can be obtained.

In addition, in the case of the present invention to measure the water pressure (P) instead of the weight (W) when the urine 113 accumulates only a small amount of the inlet of the pressure transmission tube 115 is locked after the height of the urine accumulated (h) Only the pressure proportional to) is transmitted and the impact amount to the bottom is not transmitted to the pressure transfer tube 115, so that impact noise as in the prior art does not occur. Therefore, the smaller the diameter of the pressure transfer tube 115 is, the better it is, but it can be used to manufacture about 0.5 ~ 2mm.

In the above pressure sensor 116 is a type of Wheatstone bridge (Wheatstone bridge) consisting of four resistance elements can be used a conventional pressure sensor, in particular the "general purpose multi-purpose bridge amplifier" registered by the applicant of the Republic of Korea Utility Model Registration No. 404559 By using or using a dedicated bridge amplifier circuit, the pressure signal is extracted and amplified, and then analog-to-digital conversion is performed to interface with a computer (PC).

In the above, the interface with the computer uses the RS-232C serial communication port. In the computer, the hydraulic pressure signal is converted into a volume signal, the differential signal is calculated, the urine signal is calculated, and the overall diagnostic parameters are calculated. Normal analysis will be performed.

The circuits and analytical methods applied to the signal accumulation configuration above are all general-purpose techniques.

A graph measured by the method of the present invention as described above is shown in FIG. 6. That is, FIG. 6 is a graph of test measurement results while pouring 800 mL of water, which is the same condition as the test measurement of FIG. 3, in a urination state, and is a pressure (P) measurement rather than a weight (W) measurement in FIG. 3. The test measurement is performed through the present invention, which is a method of obtaining a volume signal.

As can be seen in FIG. 6, when compared to the volume signal at the time of weighing under the same conditions (see FIG. 3), it can be seen that the volume signal at the time of the pressure measurement according to the present invention is a very clean signal with almost no noise, which is water pressure. Measuring by means that the impact noise can be eliminated, it is possible to measure the signal quality better than the measurement by weight, which means that it is possible to perform the urine test with high reliability ultimately.

In addition, the load cell used to obtain the graph of FIG. 3 used the lowest cost 70,000 won (BCL-2L, CAS Corp., USA), and the pressure sensor (MPX-10DP, Freescale, USA) used to obtain the graph of FIG. ) Can be purchased at 10,000 won, it can be seen that the method and system of the present invention is much more economical than the conventional ones.

As described above, according to the present invention, even in the case of using a low-cost pressure sensor without using the conventional expensive weight sensor, it is possible to perform the urine flow measurement without the conventional measurement noise, as well as the impact noise in the case of conventional weight measurement. By not using a separate funnel to prevent the use of a more economical, effective and efficient urine signal can be obtained, it is possible to provide a urine flow measuring method and apparatus that can be efficiently used for measuring the presence of prostate enlargement in men.

Although described above with reference to a preferred embodiment of the present invention, those skilled in the art will be variously modified and modified within the scope of the invention without departing from the spirit and scope of the invention described in the claims below. It will be appreciated that it can be changed.

Claims (8)

A urinary flow measuring method for diagnosing prostatic hyperplasia, the pressure of urine volume accumulated in a container is transmitted to an external pressure sensor through a pressure delivery tube, and the pressure sensor transmits the electric pressure, which is a voltage signal corresponding to a volumetric signal. The generated electric signal is amplified by the bridge amplifier, and then the amplified analog signal is converted into a digital signal and interfaced with the analysis device. Urinary flow measuring method characterized in that. The method of claim 1, wherein the pressure transmission pipe has a diameter of 0.1 to 2 mm, and the pressure sensor is in the form of a Wheatstone bridge composed of four resistance elements. The method of claim 1, wherein the interface with the analyzer uses an RS-232C serial communication port. The method of claim 1, wherein the analysis device is a computer or a dedicated analysis device. A system for carrying out the urine flow measuring method according to any one of claims 1 to 4, comprising: a vessel in which urine accumulates, a pressure transfer tube inserted into the vessel and connected to an external pressure sensor, and extracting the pressure signal A current flow measurement system comprising an amplifier for amplifying, a converter for converting the amplified analog signal into a digital signal and an analysis device interfaced with the converter. 6. The urine flow measurement system according to claim 5, wherein the pressure transfer pipe has a diameter of 0.5 to 2 mm and the pressure sensor is connected to a bridge amplifier circuit consisting of four resistance elements. 6. The airflow measurement system according to claim 5, wherein the interface is an RS-232C serial communication port. The urine flow measurement system according to claim 5, wherein the analysis device is a computer or a dedicated analysis device.

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