JPS6357031A - Apparatus for continuously measuring local sweating amount - Google Patents

Abstract

(57) [Abstract] This bulletin contains application data before electronic filing, so abstract data is not recorded.

Description

DETAILED DESCRIPTION OF THE INVENTION (Field of Medical Application) The present invention relates to a device for continuously measuring local sweat amount using humidity as an index, which is useful for quantitative autonomic nerve function tests and the like.

(Prior Art) The applicant of the present invention has previously filed an application for a local sweat amount continuous measuring device using a difference vJ compensation method using humidity as an index, which is useful for quantitative autonomic nerve function tests and the like. This device for continuously measuring local sweat rate using an absenteeism compensation method is installed inside the capsule by attaching a capsule to the skin where the sweating interval is to be measured and sending a predetermined flow rate of non-dehumidified air into the device capsule from outside. A humidity sensor detects the mixed humidity of perspiration and the supply air, while another humidity sensor installed in the supply passage of the air supplied to the capsule detects the humidity of the supply air, thereby adjusting the output of each humidity sensor. The system inputs a signal, calculates the difference between the two humidity levels, and continuously determines the true amount of perspiration.

(Problems to be Solved by the Invention) However, the above-mentioned conventional local sweat semi-continuous measuring device has the following problems:
Since the method calculates the difference between the output signals of the humidity sensor inside the capsule and the humidity sensor installed in the air supply passage to determine the true sweating period, it is necessary that each senna has the same characteristics as possible. Become. That is, there was a problem in that the selection criteria for the humidity sensor had to be extremely strict.

Furthermore, since it is necessary to check changes in the characteristics of each humidity sensor during operation at very short intervals, there is a problem in that a large amount of labor is required for maintenance and inspection. Furthermore, if there is a large temperature difference between the humidity sensor mounting part in the capsule and the humidity sensor mounting part in the air supply passage, there is a problem in that the amount of perspiration cannot be accurately measured using humidity, which varies depending on the temperature, as an index.

Therefore, in the present invention, the air supplied to the capsule is dehumidified in advance to a predetermined humidity, thereby eliminating the need for a humidity sensor for detecting the humidity of the air supplied to the capsule. The technical problem is to solve the problems of the conventional continuous measurement device for local perspiration by using only one device.

(Means for solving the problem) The technical means for solving the above problem is to install a continuous local sweat measurement device with a built-in humidity detection means that detects the ambient humidity and outputs a signal corresponding to the detected humidity. At the same time, an air inflow hole for introducing dehumidified air from the outside and an air outflow hole for allowing the inflowing air to flow out at a predetermined flow rate are formed, so that when measuring the amount of perspiration from the skin surface, a capsule to be mounted; an air supply passage for supplying the dehumidified air to the capsule; an air delivery device for delivering a predetermined flow rate of air to the capsule via the air supply passage; a dehumidifying means for dehumidifying air to a predetermined humidity or lower; and a humidity output from the humidity detecting means in a state where dehumidified air is being supplied from the air sending device to the capsule via the dehumidifying means and the air supply passage. an arithmetic means for inputting a detection signal, calculating the amount of perspiration from the skin surface, and outputting a display signal for displaying the amount of perspiration in an arbitrary display format; and a display outputted from the arithmetic means. The present invention is to provide a configuration including a display means for inputting a traffic signal and displaying the ship report in an arbitrary display format.

(Function) According to the device for continuous measurement of local perspiration having the above configuration, the humidity detection means in the skin-attached capsule detects the humidity of a mixture of skin-emitted sweat and dehumidified air. The air supplied to the capsule has been dehumidified to a point where the humidity is almost zero percent, and the humidity detection signal output from the humidity detection means corresponds to the moisture emitted by sweat from the skin, so the calculation means uses the humidity detection signal to The amount of perspiration can be calculated based on the perspiration period, and the calculated amount of perspiration is displayed in an arbitrary display format by the display means.

(Example) Hereinafter, an example will be described with reference to the drawings. - Fig. 1 is a block diagram showing the configuration of one embodiment of the local perspiration continuous measurement device using humidity as an index according to the present invention; Fig. 2 is a detailed block diagram of the digital calculation circuit of the block diagram shown in Fig. 1; Figure 3 is a structural diagram of the capsule.

In FIG. 1, the capsule 2, the humidity sensor 3, and the self-propelled multivibrator 4 are the moisture (sweat) released from the skin gi1.
Configure the detection section. Further, the air supply passage 5, a dehumidifying section 6 containing silica gel, for example, and a compressor 7 constitute a dehumidified air supply section. The F/V converter 8, amplifier 9, digital performance circuit 10, and printer 11 constitute an arithmetic and data processing section.

The capsule 2 is attached in close contact with one side of the skin.

The humidity sensor 3 installed in the capsule 2 is of an electrostatic type, and a change in the volume a in response to air humidity is immediately expressed as a change in the frequency of the self-propelled multivibrator 4. After the frequency output of the free-running multivibrator 4 is converted from frequency to voltage by the F/V converter 8, it is amplified 2! It is guided by li9 and amplified. The electrical output voltage of the humidity sensor 3 in the capsule 2 attached to the skin obtained in this way is data-processed by the digital arithmetic circuit 10 and then sent to the printer 11.
Changes in perspiration amount are displayed in analog form in real time, and the total amount of perspiration, average amount of perspiration per unit time, and perspiration frequency during a certain test period are digitally printed.

Next, the arithmetic control method of the digital arithmetic circuit 10 shown in FIG. 1 will be explained with reference to FIG.

A microprocessor (CPU) 20, such as Z80, is used as the core of the digital arithmetic circuit 10, and 8255, for example, are used for the human output buffer circuits 22 and 26 to configure the system.

The analog signal outputted from the amplifier 9 is changed into a digital value by an A/D converter 21, and is converted into a digital value by a human output balance circuit 22 into a random access memory RAM 2.
Recorded in 5. Then, based on the data recorded in the RAM 25 after the inspection is completed, each calculated value is calculated using an arithmetic program written in the programmable read-only memory P-ROM 24. The calculated value is sent to the printer interface 27 through the human output buffer circuit 26,
Finally, the printer 11 digitally prints the total n value. It should be noted that by using a multi-channel type A/D converter 21 and connecting a plurality of the amplifiers 9, it is possible to reduce the temperature of the human body. ! It is possible to measure sweating in several locations at the same time.

Next, the humidity/moisture (sweat) detection section shown in FIG. 1 will be explained with reference to FIG. 3. The capsule 2, the humidity sensor 3, and the self-propelled multivibrator 4 constitute a sensor for detecting moisture (sweat) dissipated from the skin, and the dehumidified air inflow hole 31, air outflow hole 32 formed in the capsule 2, and the air The supply passage 5 constitutes an air circuit section. Moisture (sweat) released from the skin 1 fills the capsule 2. However, since the capsule 1 is filled with moisture (sweat) due to insensible sweating, a certain amount of moisture is always kept in the air outflow by the dehumidified air flowing in through the air inflow hole 31 from the air supply passage 5. hole 3
From 2 onwards, it is exposed to the outside air. and moisture due to stimulation (sweat)
The frequency of the self-propelled multivibrator 4 changes because the humidity sensor 3 senses the change and outputs it as a change in each electrostatic charge.

This is input as a signal to the F/V converter 8 through the electric wire 33.

(Effect of the invention) As is clear from the above explanation, according to the present invention, the skin D
While blowing a small amount of dehumidified air into a small capsule made of bamboo, the amount of local perspiration can be continuously measured with high precision and easily based on the electrical output signal of a humidity sensor installed inside the capsule. In addition, since only one humidity sensor is used, there is no measurement error caused by the difference in characteristics between the two humidity sensors, unlike in conventional continuous local sweat measurement devices using a differential compensation method, and there is no need for maintenance. This has the effect of making inspection easier, and since there is only one humidity measurement point, there is the effect that the sweat period can be measured with almost no influence from the outside temperature.

The present invention can be applied not only to clinical medicine, physical fitness, and sports medicine as an autonomic nerve function testing device, but also to the field of daily necessities, such as measuring the effect on moisture evaporation of cosmetics, etc., and measuring moisture movement in clothing as a means of testing daily necessities. It is also possible to utilize this technology, and it has great social significance.

[Brief explanation of drawings]

FIG. 1 is a block diagram showing the configuration of one embodiment of the local sweat amount continuous measurement device of the present invention, FIG. 2 is an explanatory diagram of the configuration of the digital arithmetic circuit section of the block diagram shown in FIG. It is a structural diagram. 1...Skin 2...Capsule 3...Humidity sensor 4...Self-propelled multivibrator 5...Air supply passage 7...Compressor 8...F/V converter 9...Amplification Ding 10...Digital arithmetic circuit 11...Printer

Claims (2)

[Claims] (1) A humidity detection means for detecting the ambient humidity and outputting a signal corresponding to the detected humidity is provided, and an air inflow hole is provided for allowing dehumidified air from outside to flow in, and the incoming air is caused to flow out at a predetermined flow rate. a capsule that is formed with an air outflow hole and is attached to the skin surface when measuring the amount of perspiration from the skin surface; an air supply passage that supplies the dehumidified air to the capsule; and an air supply passage that supplies the dehumidified air to the capsule; an air delivery device that sends out air to be supplied to the capsule; a dehumidifying means that dehumidifies the air delivered from the air delivery device to a predetermined humidity or less; inputting the humidity detection signal output from the humidity detection means while dehumidified air is being supplied to the capsule via the capsule, calculating the amount of sweat from the skin surface, and displaying the amount of sweat in an arbitrary display format. Local sweating characterized by comprising: a calculation means for outputting a display signal for causing sweating; and a display means for inputting the display signal output from the calculation means and displaying the amount of perspiration in an arbitrary display form. Continuous quantity measuring device. (2) The display means is a printer, and the printer displays the sweat amount as an analog value corresponding to the measurement time, and also displays the total sweating interval, average sweating amount per unit time, sweating frequency, etc. within a certain test time. 2. The continuous local sweat measurement device according to claim 1, wherein the device displays a digital value at the end of the test.