JP3806908B2 - Tear evaporation meter - Google Patents

Description

  The present invention relates to a tear evaporation measuring device that measures the evaporation of tears secreted from the lacrimal glands of a subject.

  The lacrimal fluid secreted from the lacrimal gland uniformly moisturizes the surface of the eye by blinking the subject and refreshes the surface of the eye. Therefore, when the amount of lacrimal secretion decreases, a so-called dry eye state is obtained. When it is in a dry eye state, the eye is easily scratched and it is difficult to prevent the entry of fungus. The cause of the dry eye condition is, for example, that the computer screen is viewed for a long time or precise work is continued for a long time. If the symptoms of dry eye become chronic, it will interfere with work and daily life, so it is necessary to see an ophthalmologist. At the time of diagnosis, the ophthalmologist measures the evaporation amount of the subject's tears by using a tear evaporation measuring device, and determines whether or not the subject's eyes are in a dry eye state based on the evaporation amount. A conventional tear evaporation measuring device for measuring the evaporation of a subject's tears is an air whose temperature and humidity are previously adjusted to be constant from an adjustment air supply unit in a state where the eye contact is placed on the subject's eyes. It is provided in the unit by sending it to the pump, mixing it with tear fluid evaporated from the eye of the subject by sending air at a constant flow rate into the eyepiece, and sending the mixed moisture to the measurement control unit. The relative humidity sensor detects the relative humidity of the air-fuel mixture, measures the evaporation amount of the subject's tears based on the relative humidity, and indicates with a meter (see Patent Document 1).

However, the conventional tear evaporation measuring device needs to generate air in which the temperature and humidity are adjusted to be constant in advance in the adjusted air supply unit. Therefore, the adjusted air supply unit has a complicated structure, becomes large in size, and increases in cost. In addition, the adjusted air sent to the eyepiece has a constant flow rate regardless of the amount of tears evaporated by the subject, so if the amount of tears evaporated is large, the evaporated tears are mixed properly with the adjusted air. Not. Therefore, the evaporation amount of the tear fluid of the subject may not be accurately measured. In addition, it is difficult to downsize a regulated air supply unit that supplies air whose temperature and humidity have been adjusted to be constant in advance, and a measurement control unit that has a meter. Can not do it. Therefore, the amount of tears evaporated cannot be measured while the subject is in daily life or doing daily work. Therefore, the cause of the test subject's dry eye cannot be determined accurately.
U.S. Patent No. 4461303

  Accordingly, the present invention solves the problem of providing a tear evaporation measuring device that can be easily carried by a subject and that allows the subject to accurately measure the evaporation of their tears while performing daily life and daily work. It is a problem to be solved.

The above problem can be solved by the tear evaporation measuring device described in the appended claims.
According to the tear evaporation measuring apparatus according to claim 1, the natural air supply unit and the measurement unit are housed in a case that can be carried by the subject. And since an evaporating chamber is formed in the front part of both eyes of the subject without interfering with the movement, tear fluid secreted from the lacrimal gland of the subject evaporates in each evaporating chamber. In addition, when the natural air supply unit housed in the case supplies natural air to the respective evaporation chambers of the goggles unit under the control of the measurement unit, the tear fluid evaporated from the eyes of the subject and the natural air are mixed. A mixture of moisture is generated in each evaporation chamber, and the mixture is discharged from each of the evaporation chambers. In this state, the measurement unit housed in the case has the absolute humidity of the natural air based on the temperature and humidity of the natural air detected by the first sensor, and the air-fuel mixture detected by the second sensor. The flow rate of natural air supplied from the natural air supply unit to the respective evaporation chambers of the goggles unit is controlled so that the difference between the absolute humidity of the air-fuel mixture based on temperature and humidity is constant, and the natural air Based on the flow rate, the evaporation amount of the subject's tears is measured and the measurement data is recorded.
In the tear evaporation measuring device of the present invention, the flow rate of natural air supplied from the natural air supply unit to each evaporation chamber of the goggles is appropriately controlled in accordance with the evaporation amount of the subject's tears. The tears evaporated from the eyes of the subject and natural air are mixed appropriately. Thus, the tear evaporation measuring device of the present invention is carried by the subject, and the subject can accurately measure and record the tear evaporation amount while carrying out daily life or daily work.

  According to the tear evaporation measuring apparatus according to claim 2, since the subject includes pain input means for the subject to input the degree of eye pain perceived by the subject himself / herself, the measurement unit receives the input pain This data can be recorded together with the measurement data of the tear evaporation of the subject, and the recorded data can be transmitted to an external analysis device. As a result, the correlation between the evaporation amount of the subject's tears and the degree of eye pain felt by the subject can be analyzed by an external analysis device, so that the cause of the subject's dry eye can be determined more accurately. be able to.

  According to the tear evaporation measuring apparatus according to claim 3, the measuring unit includes the temperature and humidity of the natural air detected by the first sensor and the temperature and humidity of the air-fuel mixture detected by the second sensor. Since the recorded data can be transmitted to an external analysis device in real time, the cause of the dry eye of the subject can be determined more accurately.

  According to the present invention, the amount of evaporation of the subject's tears that is carried by the subject and used as data for accurately locating the cause of the subject's dry eye while carrying out daily life and daily work is accurately measured and recorded. can do.

Next, an embodiment of the present invention will be described.
FIG. 1 is a block system diagram showing an overall configuration of a tear evaporation measuring device 1 that can be carried by a subject and that can measure the evaporation of tears while the subject performs daily life and daily work. .
The goggles 2A and 2B attached to the outer peripheral portions of the right eye E1 and the left eye E2 of the subject are integrally formed, and when a hooking band (not shown) is hooked on the subject's head, for example, the goggles The contact surfaces of 2A and 2B are attached in a sealed manner to the face of the subject. When the contact surfaces of the goggles 2A and 2B are contacted with the face of the subject, evaporation chambers 2Ca and 2Cb are formed in front of the right eye E1 and the left eye E2.

  The evaporating chambers 2Ca and 2Cb are sealed spaces for evaporating tears secreted from the subject's lacrimal glands, and a mixture of natural air, which will be described later, and evaporated lacrimal fluid are mixed with each evaporating chamber 2Ca, 2Cb. It is generated with 2Cb.

  Flexible pipes 3a, 3b, 4a, 4b are connected to the goggles 2A, 2B so as to communicate with the evaporation chambers 2Ca, 2Cb of the goggles 2A, 2B. Each flexible pipe 3a, 3b supplies natural air (room air or outside air) to the evaporation chambers 2Ca, 2Cb of the goggles 2A, 2B as will be described later. Moreover, each flexible pipe 4a, 4b guides the above-mentioned air-fuel mixture to each exhaust passage 5a, 5b provided in the case 1a made small and light so that the subject can carry it.

  When the pumps 6a and 6b provided in the case 1a of the tear evaporation measuring device 1 are rotationally driven by respective motors (not shown), the natural air is sucked to adjust the flow rate, and then the natural air is removed. The flexible pipes 3a and 3b are supplied to the evaporation chambers 2Ca and 2Cb of the goggles 2A and 2B through the pipes 8a and 8b provided on the downstream side. The motors of the pumps 6a and 6b are controlled in rotation speed according to a drive voltage output from the measurement unit 13 described later, and are sent from the pumps 6a and 6b in accordance with the motor rotation speed. The flow rate of natural air is varied.

  Natural surfaces with the flow rate adjusted as described above in a state where the contact surfaces of the goggles 2A and 2B are attached to the face of the subject and the evaporation chambers 2Ca and 2Cb are formed in front of the right eye E1 and the left eye E2, respectively. When air is supplied to the evaporation chambers 2Ca and 2Cb of the goggles 2A and 2B, the natural air is mixed with tears evaporated from the right eye E1 and the left eye E2 of the subject, and becomes a mixture of moisture. This mixed air moisture flows from the evaporation chambers 2Ca and 2Cb of the goggles 2A and 2B through the flexible pipes 4a and 4b to the exhaust passages 5a and 5b. The air-fuel mixture flowing through the exhaust passages 5a and 5b is exhausted to the atmosphere.

First sensors 10a and 10b for simultaneously detecting the temperature and humidity of the natural air are attached to the natural air supply ports of the goggles 2A and 2B, respectively. Further, second sensors 11a and 11b for simultaneously detecting the temperature and humidity of the air-fuel mixture are attached to the air-fuel mixture outlets of the goggles 2A and 2B, respectively.
The first sensors 10a and 10b and the second sensors 11a and 11b have a structure as shown in FIGS. 3 is a cross-sectional view taken along the line AA in FIG. Moreover, the unit of dimension shown in FIGS. 2 and 3 is μ meter.

According to the technical data of the sensor manufacturer, the sensor chips of the first sensor 10a, 10b and the second sensor 11a, 11b are formed on a semiconductor silicon (Si) substrate as shown in FIGS. In addition, SiO ₂ / Ta ₂ O ₅ / Pt / Ta ₂ O ₅ is formed in layers. Platinum Pt is a thin film resistor, and constitutes air heater microheaters 20a and 20b that generate heat when a current is applied. Further, lead leads 21a, 21b, and 21c are formed from a thin film resistor of platinum Pt, and bonding pads 22a, 22b, and 22c are provided at end portions of the lead leads.

  In this way, two microheaters 20a and 20b are incorporated in one sensor chip, one is a detection unit, the other is a temperature compensation unit, and the temperature compensation unit shuts off humidity and a sealed cover so that the temperature can be detected. Glass sealed. By configuring the sensor chip in this way, the temperature and humidity are quickly responded based on the temperature sensitivity difference (mV / ° C.) between the detection unit and the temperature compensation unit generated by switching the heat generation temperatures of the two micro heaters 20a and 20b. Can be detected.

  The first sensors 10a and 10b and the second sensors 11a and 11b are connected to the measurement unit 13 through lead wires 12a, 12b, 12c, and 12d. The measurement unit 13 controls the temperature and humidity of the natural air and the air-fuel mixture at high speed by controlling the heat generation temperature of the micro heaters 20a and 20b of the first sensors 10a and 10b and the second sensors 11a and 11b, respectively. Measure in response.

  The measuring unit 13 is configured to detect each natural air supplied to the two evaporation chambers 2Ca and 2Cb and each natural humidity based on each detected temperature and each detected humidity of each air-fuel mixture in the two evaporation chambers 2Ca and 2Cb. The absolute humidity of the air and the mixture is calculated, and the difference between the absolute humidity of each natural air and the mixture is calculated.

  The measurement unit 13 controls the flow rate of natural air supplied from the pumps 6a and 6b to the evaporation chambers 2Ca and 2Cb so that the difference between the absolute humidity of each natural air and the air-fuel mixture becomes constant. In this case, the measurement unit 13 controls the number of rotations of each motor by changing the drive voltage output to each motor (not shown) that drives the pumps 6a and 6b, and the pumps 6a and 6b control each evaporation chamber. While changing the flow rate of natural air supplied to 2Ca and 2Cb, the drive voltage at this time (this drive voltage corresponds to the flow rate of natural air supplied from the pumps 6a and 6b to the evaporation chambers 2Ca and 2Cb. ), The evaporation amount of tears evaporated from the right eye E1 and the left eye E2 of the subject is measured and recorded. Then, the display unit 14 displays the evaporation amount of tears evaporated from the right eye E1 and the left eye E2 of the subject in an analog or digital manner.

  The case 1a of the tear evaporation measuring device 1 is provided with a pain input unit 15 for the subject himself / herself to input the degree of pain in the subject's eyes. The pain input unit 15 touches the subject's finger on the scale 15a for inputting the degree of pain of the subject's eyes, and thereby determines the contact position as the degree of pain of the eye (pain level) felt by the subject. The pain level is detected and transmitted to the measurement unit 13 as pain level data of the subject's eyes.

  The measurement unit 13 of the tear evaporation measuring device 1 is configured to output measurement data to an external personal computer (analysis device) or the like. Thereby, the data measured by the tear evaporation measuring device 1, that is, the evaporation amount of tears evaporated from the right eye E1 and the left eye E2 of the subject, and the two evaporation chambers 2Ca and 2Cb respectively supplied Natural air, each detected temperature and each detected humidity of the air-fuel mixture in the two evaporation chambers 2Ca and 2Cb, and the pain level data of the eye of the subject to an external personal computer etc. By using it comprehensively as diagnostic data, it is possible to analyze and diagnose the cause of dry eye of the subject.

Next, the measuring action of the tear evaporation measuring device 1 will be described.
When a retaining band (not shown) is hooked on the subject's head, for example, the contact surfaces of the goggles 2A and 2B are contacted with the face of the subject, and the front of the right eye E1 and the left eye E2 is described above. Evaporation chambers 2Ca and 2Cb are formed. Even when the goggles 2A and 2B are attached to the face of the subject, the subject can perform daily work such as personal computer operation and daily life. The case 1a of the tear evaporation measuring device 1 may be attached to the waist of the subject, placed in the pocket of the jacket, or placed on the subject's desk. At this point, preparations for measuring the evaporation amount of tears evaporated from the right eye E1 and the left eye E2 of the subject are ready.

  The evaporation chambers 2Ca and 2Cb are sealed spaces for evaporating tears secreted from the lacrimal glands of the subject, and a mixture of natural air supplied by driving the pumps 6a and 6b and evaporated tears. Humidity is generated in the respective evaporation chambers 2Ca and 2Cb. In this process, the first sensors 10 a and 10 b detect the temperature and humidity of natural air and output detection signals of the temperature and humidity to the measurement unit 13. In the process in which the air-fuel mixture passes through the flexible pipe 4a and the pipe 5a and is exhausted to the atmosphere, the second sensors 11a and 11b detect the temperature and humidity of the air-fuel mixture and detect the temperature and humidity. The signal is output to the measurement unit 13.

  The measuring unit 13 is configured to detect the natural air supplied to the two evaporation chambers 2Ca and 2Cb, and the respective natural humidity based on the detected temperatures and the detected humidity of the air-fuel mixtures in the two evaporation chambers 2Ca and 2Cb. The absolute humidity of the air and the mixture is calculated, and the difference between the absolute humidity of each natural air and the mixture is calculated.

  The measurement unit 13 controls the flow rate of natural air supplied from the pumps 6a and 6b to the evaporation chambers 2Ca and 2Cb so that the difference between the absolute humidity of each natural air and the air-fuel mixture becomes constant. In this case, the measurement unit 13 corresponds to the driving voltage output to each motor that drives the pumps 6a and 6b (this driving voltage corresponds to the flow rate of natural air supplied from the pumps 6a and 6b to the evaporation chambers 2Ca and 2Cb. By changing the flow rate of natural air supplied from the pumps 6a and 6b to the evaporation chambers 2Ca and 2Cb, and based on the driving voltage at that time. The evaporation amount of tears evaporated from the right eye E1 and the left eye E2 of the subject is measured and recorded. Then, the display unit 14 displays the evaporation amount of tears evaporated from the right eye E1 and the left eye E2 of the subject in an analog or digital manner. In this case, since the subject inputs the degree of eye pain felt at that time as a pain level on the scale 15a of the pain input unit 15, the pain input unit 15 measures the pain level as pain level data of the subject. The data is transmitted to the unit 13.

  Since the measurement unit 13 of the tear evaporation measuring device 1 is configured to output measurement data to an external personal computer (analysis device) or the like, the data measured by the tear evaporation measuring device 1 is used. That is, the amount of tears evaporated from each of the right eye E1 and the left eye E2 of the subject, the natural air supplied to the two evaporation chambers 2Ca and 2Cb, and the respective evaporation chambers 2Ca and 2Cb Cause of dry eye by transmitting each detected temperature and each detected humidity of air-fuel mixture and the above-mentioned subject's eye pain level data to an external personal computer, etc., and allowing the personal computer to analyze the dry eye in detail Can be determined.

  As described above, the tear evaporation measuring device 1 has the main components housed in a small and light case 1a, so that the subject measures the evaporation of his / her tears while carrying out daily life and daily work. can do. Further, the flow rate of natural air supplied from the pumps 6a and 6b to the evaporation chambers 2Ca and 2Cb is appropriately controlled in accordance with the evaporation amount of the subject's tears, and thus evaporates from the eyes E1 and E2 of the subject. Tears and natural air are mixed properly. Thereby, since the evaporation amount of tears evaporated from the eyes E1 and E2 of the subject can be accurately measured, the cause of the dry eye of the subject can be accurately identified.

  The configuration of the tear evaporation measuring device 1 shown in FIG. 1 is an example. For example, the first sensors 10a and 10b and the second sensors 11a and 11b described above are small and high-speed responsive sensors. If it is, it will not be restricted to the thing as shown in FIG. 2, FIG. Further, the mounting position of each sensor is not limited to the goggles.

  Moreover, when the goggle part is formed so as to be in contact with one eye of the subject, the evaporation amount of tears evaporated from one eye can be measured.

It is the block system figure which showed the whole structure of the tear-liquid evaporation measuring device. It is a top view of the sensor chip of a sensor. It is AA arrow sectional drawing of FIG.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Tears evaporation measuring device 1a Case 2A, 2B Goggles 2Ca, 2Cb Evaporation chamber 3a, 3b Flexible tube 4a, 4b Flexible tube 5a, 5b Pipe 6a, 6b Pump 8a, 8b Pipe 10a, 10b First sensor 11a, 11b Second sensor 13 Measuring unit 14 Display unit 15 Pain input unit

Claims (3)

  The evaporation chamber is formed in the front part of both eyes of the subject without interfering with the view and movement of the subject while attached to the subject's head, and tear fluid secreted from the subject's lacrimal gland evaporates in each of the evaporation chambers Natural air that discharges from each of the evaporating chambers a mixed air-and-humid mixture in which the natural air having a variable flow rate supplied to the respective evaporating chambers of the goggles and the tear fluid evaporated from the eyes of the subject is mixed Discharged from the supply section, the first sensor of the air bridge structure based on a semiconductor that detects the temperature and humidity of the natural air supplied to the evaporation chamber of the goggles section, and the evaporation chamber of the goggles section A second sensor having an air bridge structure based on a semiconductor that detects the temperature and humidity of the air-fuel mixture, and the temperature and humidity of the natural air detected by the first sensor However, from the natural air supply unit to the goggle unit, the difference between the absolute humidity of the air and the absolute humidity of the mixed gas / humidity based on the temperature and humidity of the mixed gas / humidity detected by the second sensor is constant. And a measurement unit for controlling the flow rate of the natural air supplied to each of the evaporation chambers and measuring the evaporation amount of the subject's tears based on the flow rate of the natural air and recording the measurement data, By storing the natural air supply unit and the measurement unit in a case that can be carried by the subject, the subject can measure and record the evaporation amount of tears while performing daily life and daily work. Tear evaporation meter.   The subject is provided with pain input means for the subject to input the degree of eye pain perceived by the subject, and the measurement unit records the inputted pain degree data together with the tear evaporation data of the subject. 2. The tear evaporation measuring apparatus according to claim 1, wherein the recorded data can be transmitted to an external analysis device.   The measurement unit records the temperature and humidity of the natural air detected by the first sensor and the temperature and humidity of the air-fuel mixture detected by the second sensor in real time and records the recorded data. 3. The tear evaporation measuring apparatus according to claim 1, wherein the tear evaporation measuring apparatus is configured to be transmitted to an external analysis device.

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