KR20180106781A - Thermometer and temperature measuing appatus having thermometer - Google Patents

Abstract

Provided is a thermometer with improved wearability while minimizing the volume. The thermometer comprises: a main body having a first body including first and second regions and a second body mounted on the first body, and extended in a first direction; a rubber cap surrounding the first region and formed to be inserted into the ear; a temperature sensor disposed in the second region, and sensing the temperature having a specific temperature sensing range with respect to the first direction; and first and second circuit boards electrically connected to the temperature sensor, and disposed in the second region in a second direction intersecting with the first direction.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a body temperature measuring instrument,

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a body temperature measuring device for detecting a body temperature by being inserted into an ear.

The devices that measure body temperature include a temperature sensor and measure the temperature by inserting it into the mouth or ear. However, these devices are kept in a state of being inserted into one part of the body for a specific time while being held by hand to acquire body temperature information. Therefore, it is made of a device that is not mounted on the body.

The body temperature rises while rising and reaches the highest in the afternoon, then falls again at night. Basal body temperature refers to the lowest body temperature in the most stable state, and recording daily basal body temperature provides useful information about women's menstruation / ovulation cycle. To measure this basal body temperature, you should take a minimum of 3 to 4 hours of sleep and then measure your body temperature in the most stable state. Since most of the thermometers need to be operated directly, it is impossible to measure during sleep. Therefore, it is necessary to minimize the movement and measure the body temperature in the awakened state. In the step of contacting the body thermometer, The position and the like of the body temperature are different from each other.

In recent years, the wearable thermometer has a bulky feel when it is worn on the ear and obstructs the water surface or blocks the ear canal, and it has a cramped feeling. .

SUMMARY OF THE INVENTION It is an object of the present invention to solve the above-described problems and other problems, and to provide a body temperature measuring instrument with improved comfort while minimizing volume.

According to an aspect of the present invention, there is provided an apparatus for measuring a body temperature according to an embodiment of the present invention includes a first body including first and second regions, a second body mounted on the first body, And a rubber cap which is formed to be able to be inserted into the ear and surrounds the first region and is disposed in the second region and has a specific sensing range based on the first direction, And a first circuit board electrically connected to the temperature sensor and disposed in the second area and disposed in a second direction intersecting with the first direction, And the rubber cap includes first and second holes for exposing the temperature sensor, wherein the first body has one end cut along the second direction, and the second body has at one end Respectively.

In one embodiment, the inner surface of the second region forming the first hole is made of an oblique surface, the inner surface of the rubber cap forming the second hole is made of an oblique surface, and the first and second oblique surfaces May be formed such that the first and second holes become larger as the distance from the temperature sensor increases, and the first and second oblique faces may have a certain angle to include the sensing range. Therefore, since the sensing region of the temperature sensor is not blocked, the temperature of the specific region of the ear formed with the eardrum can be accurately measured.

In one embodiment, the apparatus further comprises a vent hole extending from an end of the second region to a boundary of the first and second regions, the vent hole being formed by recessing an outer surface of the second region, Air can be introduced into the vent hole by the gap between the second region and the rubber cap, air and moisture can pass therethrough and the accuracy of the sensor can be consistently maintained, thereby improving the feeling of wearing.

According to the present invention, it is possible to minimize the volume of the body temperature measuring apparatus while securing the width of the circuit board by disposing the circuit board in a direction oblique to the direction in which the temperature sensor is disposed.

Accordingly, it is possible to implement the body temperature measuring device in a shape elongated in one direction, and it is possible to minimize inconvenience of taking a sleep state in a state of being worn by minimizing an area contacted to the outside of the ear such as a toe wheel.

A vent hole is formed in one region of the first body wrapped with the rubber cap so that the vent hole is formed on the outside of the main body while minimizing the chest, thereby preventing foreign matter from entering the internal electronic parts. In addition, moisture can be prevented from getting inside the ear by circulating air through the vent hole.

FIG. 1A is a view showing a body temperature measuring instrument according to an embodiment of the present invention in one direction.
FIG. 1B is a view of the storage device in which the body temperature measuring device of FIG.
1C is a conceptual diagram for explaining a state in which a body temperature measuring instrument is housed in a receiving apparatus.
FIG. 1D is a conceptual view showing a wearing state.
FIG. 2 is a view of the body temperature measuring device of FIG.
3A and 3B are conceptual diagrams for explaining the structure of the second region and the rubber cap based on the sensing range of the sensor unit.
4A is a conceptual diagram showing the arrangement of the antennas of the temperature sensor device.
4B is a conceptual diagram for explaining a wireless communication direction in a state of being inserted into an ear.
5A to 5C are conceptual diagrams for explaining a plurality of modules disposed in the first body.
5D is a conceptual diagram for explaining the arrangement structure of the first to third modules.
6 is a conceptual diagram for explaining the arrangement of the flexible circuit board.
7A to 7E are conceptual diagrams for explaining a structure for coupling and separating the second body.
8A is an exploded view for explaining components of a storage device.
8B and 8C are conceptual diagrams for explaining a hall sensor and a magnet unit for detecting that a temperature measuring device is mounted on a storage sensor.
9A and 9B are conceptual diagrams showing setting screens for setting measurement times.
9C and 9D are conceptual diagrams for explaining a control method of outputting notification information based on sensed body temperature.
10A and 10B are conceptual diagrams illustrating a control method of outputting guide information for guiding measurement.
11 is a conceptual diagram for explaining a control method for detecting an appropriate measurement start time according to an embodiment of the present invention.
FIG. 12 is a conceptual diagram for explaining an example of a body temperature change by menstrual cycle according to various states.
13A to 13C are conceptual diagrams for explaining a control method of an external device in conjunction with a body temperature measuring device according to the present invention.
14A to 14C are conceptual diagrams for explaining a control method of an external device for outputting notification information informing the driving state of the body temperature measuring device.
15A and 15B are conceptual diagrams for explaining a control method of performing body temperature sensing according to detection of acceleration.
16 is a conceptual diagram for explaining the measurement function.
17 illustrates a control method for analyzing the life state in cooperation with a wearable device.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings, wherein like or similar components are denoted by the same reference numerals, and redundant explanations thereof will be omitted. The suffix "module" and " part "for the components used in the following description are given or mixed in consideration of ease of specification, and do not have their own meaning or role. In the following description of the embodiments of the present invention, a detailed description of related arts will be omitted when it is determined that the gist of the embodiments disclosed herein may be blurred. It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory and are intended to provide further explanation of the invention as claimed. , ≪ / RTI > equivalents, and alternatives.

1A is a perspective view of a body temperature measuring apparatus of FIG. 1A taken in one direction, FIG. 1C is a sectional view of a body temperature measuring apparatus according to an embodiment of the present invention, Fig. 8 is a conceptual diagram for explaining a state accommodated in a device. Fig. FIG. 1D is a conceptual view showing a wearing state.

1A to 1D, the body temperature measuring instrument 1000 has a shape that can be inserted into a human ear. The ear of the person is placed through the ear canal (EAM) and the eardrum (tm) at the end of the external ear (EE). The body temperature measuring instrument 1000 according to the present invention is disposed in the external ear canal (EAM). One area of the body temperature measuring instrument 1000 is formed to be inserted into the external ear canal (EAM). A sensor for measuring the body temperature is disposed at one end of the body temperature measuring instrument 1000. When the body temperature measuring instrument 1000 is inserted into the external ear canal EAM, the sensor is arranged to face the eardrum tm. Accordingly, the sensor can measure the body temperature emitted from the eardrum.

When the body temperature measuring instrument 1000 is separated from a user's ear, the body temperature measuring instrument 1000 is housed in the receiving apparatus 2000. The storage device 1000 includes a body part 2100, a lid part 2200 and a connection part 2210 connecting the lid part 2200 to the body part 2100. The lid part 2200 is rotatably fixed to the body part 2100 by the connection part 2210 so as to open or close the body part 2100.

The body part 2100 includes a concave shaped receiving area 2131 in which the body temperature measuring instrument 1000 is received. The body temperature measuring apparatus 1000 may be protected when performing wireless communication with an external device in a state of being seated in the storing area 2131 or when not using it. 1C, one part of the body temperature measuring device 1000 protrudes from the surface of the body part 2100 in a state of being seated in the receiving area 2131, and the cover part 2200, Are concave.

Hereinafter, the structure of the body temperature measuring instrument 1000 inserted into the user's ear to measure the body temperature will be described.

FIG. 2 is a view of the body temperature measuring device of FIG.

Referring to FIG. 2, the body temperature measuring apparatus 1000 includes a first body 1100 and a second body 1200. The first and second bodies 1100 and 1200 may be detachably coupled to each other.

The first body 1100 includes a first region 1110 and a second region 1120 protruding from the first region 1110. The outer circumference of the second region 1120 may be smaller than the outer circumference of the first region 1110. A rubber cap 1130 made of rubber is formed in the second region 1120. The rubber cap 1130 is inserted into the ear canal of the ear and can be elastically deformed and prevented from being separated from the ear by the rubber cap 1130 having a large frictional force on the surface.

The outer surface of the rubber cap 1130 may form one surface with the outer surface of the first region 1110 and the rubber cap 1130 may be detachable from the second region 1120.

The second region 1120 includes a fixing groove 1121 for fixing the rubber cap 1130 and a vent hole 1122 for allowing air to move. The fixing groove 1121 is recessed such that one region of the outer circumferential surface of the second region 1120 has a specific width. The rubber cap 1130 may further include a fixing protrusion protruding from the inner circumferential surface of the rubber cap 1130 and fitted into the fixing groove 1121. [ The rubber cap 1130 is fixed to the second region 1120. When an external force is applied to the second region 1120 and the rubber cap 1130, the fixing protrusion is elastically deformed, Gt; 1120 < / RTI >

Meanwhile, the vent hole 1122 is formed in the extending direction of the second region 1120, and one region of the second region 1120 is formed by being recessed. The vent holes 1122 are formed from the ends of the second regions 1120 to the boundary regions of the first and second regions 1110 and 1120.

One area of the vent hole 1122 is formed deeper than the fixing groove 1121. Therefore, even if the fixing protrusion is inserted into the fixing groove 1121, the air can pass through the one region of the vent hole 1122.

A space is formed between the second region 1120 and the rubber cap 1130 by the vent hole 1122. One end of the vent hole 1122 is disposed inside the ear and the other end of the vent hole 1120 is positioned inside the ear while the second region 1122 in which the rubber cap 1130 is mounted is inserted into the ear Exposed to the outside of the ear. Air can pass through the vent hole 1122 to the inside and outside of the ear.

One end of the vent hole 1122 is exposed by the end of the second region 1120 and the vent hole 1122 is formed through the gap between the first region 1110 and the rubber cap 1130. [ Air can pass through.

Therefore, since the body temperature measuring device 1000 is formed so as to communicate with the air even in the state where the ear thermometer 1000 is closed, it is possible to eliminate the bulge caused by the pressure difference.

In addition, since the vent hole of the body temperature measuring instrument 1000 of the present invention is formed on the outer surface of the first body 1110, it is not necessary to penetrate the inside of the first body 1110. Accordingly, it is possible to prevent the foreign matter or the like from being introduced into the first body 1110 through the vent hole, and it is possible to prevent the electronic parts (sensor, circuit board, etc.) disposed inside the first body 1110 Damage can be minimized.

Moisture can be prevented from being drawn by the vent hole, and a plurality of vent holes can be formed in the first body part.

3A and 3B are conceptual diagrams for explaining the structure of the second region and the rubber cap based on the sensing range of the sensor unit.

A temperature sensor 1331 for sensing the temperature is disposed at an end of the first region 1100. The temperature sensor 1331 may be implemented as a non-contact infrared sensor. The infrared sensor receives the infrared energy emitted from the body by the IR sensor and converts it into a measurable electrical signal.

The temperature sensor 1331 has a specific sensing range? 1. For example, the sensing range (FOV) (? 1) of the temperature sensor 1331 may correspond to about 100 degrees. The temperature sensor 1331 is configured to sense a temperature within a specific angle range with respect to the center.

The ends of the second region 1120 and the rubber cap 1130 surrounding the temperature sensor 1331 include first and second holes h1 and h2, respectively. The first hole h1 is formed at an end of the second region 1120, and the temperature sensor 1331 is exposed. The size of the first hole (h1) may be smaller than the end of the temperature sensor (1331). The inner surface of the second region 1120 forming the first hole h1 is composed of an oblique surface 1123. The oblique surface 1123 forms a certain angle from the temperature sensor 1331 and is formed in a direction in which the size of the first hole h1 is wider as the distance from the temperature sensor 1331 increases. The specific angle is formed to be equal to or greater than an angle corresponding to the sensing range of the temperature sensor 1331. That is, the first hole h1 is formed to include the sensing range of the temperature sensor 1331.

Meanwhile, the rubber cap 1130 includes the second hole h2 corresponding to the first hole h1. The second hole h2 is located farther from the temperature sensor 1331 than the second hole h1 and is formed to be larger than the first hole h1. The first and second holes h1 and h2 communicate with each other and the centers of the first and second holes h1 and h2 correspond to each other.

The inner surface of the rubber cap 1130 forming the second hole h2 is formed as an oblique surface 1131. The oblique surface also has a specific angle, and the second hole h2 is formed to be larger as the distance from the temperature sensor 1331 increases. The inclination of the oblique surface 1131 forming the second hole h2 may be substantially equal to the inclination of the oblique surface 1123 forming the first hole h1. Or the degree of inclination of the oblique surface of the second hole h2 may be larger.

The sensing range of the temperature sensor 1331 is not blocked by the first and second holes h1 and h2. Accordingly, the function of the temperature sensor 1331 can be improved.

FIG. 4A is a conceptual diagram showing the arrangement of antennas of the temperature sensor device, and FIG. 4B is a conceptual diagram for explaining a wireless communication direction in a state of being inserted into the ear.

Referring to FIG. 4A, an antenna unit 1313 is formed in a first region 1110 of the first body 1100. Is formed in the first module (1310) among a plurality of modules disposed inside the first region (1100). The antenna unit 1313 is formed on one surface of the first module 1310 facing the second body 1200. The battery unit 1340 is disposed on the surface of the first module 1310 and the battery unit 1340 and the antenna unit 1313 are covered by the second body 1200.

The antenna unit 1313 may be formed of a metal pattern surrounding the battery unit 1340. The shape of the antenna unit 1313 is not limited to that shown in the drawings. The direction d shown in Fig. 4A is the radiation direction of the antenna portion 1313. Fig.

Referring to FIGS. 2 and 4B, when the second region 1120 is inserted into the ear, one region of the first region 1100 is exposed to the outside. Particularly, the antenna portion 1313 disposed at the end of the first region 1100 is not inserted into the ear. Therefore, the antenna unit 1313 can perform wireless communication without being affected by the ear.

4B, the antenna portion 1313 is formed in a region that is distant from the auricle in a state where the second region 1120 is inserted into the ear. Accordingly, since the antenna unit 1313 radiates to the front of the ear, the wireless communication performance of the antenna unit 1313 may not affect the temperature sensor unit even when the temperature sensor unit is mounted on the ear.

5A to 5C are conceptual diagrams for explaining a plurality of modules disposed in the first body.

5A, the temperature sensor device 1000 includes a first body 1100, a first body 1200, and a rubber cap 1130 mounted on the first body 110, 1320 and 1330 mounted on the body 1100 and a battery unit 1340. The first module 1310 includes a first module 1320,

The second region 1120 extends from the one end 1100 'of the first region 1100 along the first direction D1. The first region 1100 extends along the first direction D1. However, the other end 1100 of the first region 1100 is formed along the first direction D2 intersecting the first direction D1. The ends of the one end portion 1100 'and the other end portion 1100 are formed in directions intersecting with each other. The second body 1200 is mounted on the other end 1100 of the first region 1100 in a third direction D3 intersecting the first and second directions D1 and D2. That is, distances from the other end 1100 to the second region 112 are different from each other.

The first to third modules 1310, 1320 and 1330 are sequentially mounted on the first region 1110 and the second region 1120.

The first module 1310 is mounted in the first region 1110 of the first body 1100 adjacent to the second body 1200. The outermost face of the first module 1310 corresponds to the other end 1100 of the first region 1100 cut in the second direction D2. And the other end 1100 of the first region 1100 is covered by the first module 1310.

First and second circuit boards 1314 and 1316 are disposed on a first surface of the first module 1310. The first and second circuit boards 1314 and 1316 are arranged so that at least one area is overlapped with each other. A storage area for storing the battery unit 1340 is formed on the second surface of the first module 1310. A side wall portion is protruded to form the accommodating region. The side wall part may include a spiral structure for fixing the second body 1200.

The battery unit 1340 and the temperature sensor 1331 are electrically connected by the first and second circuit boards 1314 and 1316.

The second module 1320 is mounted on the first surface of the first module 1310 and surrounds the peripheral areas of the first and second circuit boards 1314 and 1316. That is, the first and second circuit boards 1314 and 1316 are protected by the first module 1310.

5B, the second module 1320 is disposed between the side wall portion 1321 and the side wall portion 1321 corresponding to the inner surface of the first region 1110, And a supporting portion 1322 for supporting between the two circuit boards 1314 and 1316. The supporting portion 1322 includes an opening region 1322a for electrically connecting the first and second circuit boards 1314 and 1316, .

The side wall portion 1321 is formed to correspond to the inner surface of the first region 1110, and the width and the degree of bending of the side surface can be varied. The third module 1330 is mounted on one end of the second module 1320 and the first module 1310 is mounted on the other end of the second module 1320.

The first module 1310 includes first and second fixed hook portions 1333 and 1334 extending from the sensor supporting portion 1332 and the sensor supporting portion 1332 facing each other in the first direction D1 .

The first module 1310 is disposed inside the second region 1120 extending in the first direction D1 and supports the temperature sensor 1331. [ One end of the first module 1310 is formed of a supporting surface 1332a for supporting the temperature sensor 1331.

The first and second fixed hook portions 1333 and 1334 have different lengths and have a hook structure in which the end portion can be fitted into the groove. The hook structures of the first and second fixed hook portions 1333 and 1334 are opposite to each other.

First and second fixing grooves 1321a and 1321b are formed on the inner surface of the second module 1321 so that the hook structures of the first and second large and large portions 1333 and 1334 are fitted. The first and second fixing grooves 1321a and 1321b may be disposed adjacent to the first circuit board 1314. [ Accordingly, when the first and second large and large portions 1333 and 1334 are inserted into the first and second fixing grooves 1321a and 1321b, the first and second large and high information 1333 and 1334 The first circuit board 1314 is supported to prevent the first circuit board 1314 from moving. The first and second fixing grooves 1321a and 1321b are formed to face each other.

The first fixing hook portion 1333 having a relatively short length is first inserted into the first fixing groove 1321a and the second fixing hook portion 1334 is inserted into the second fixing groove 1321b.

The lengths of the first and second fixed hook portions 1333 and 1334 are different from each other. The length of the second fixing hook 1334 may be longer than the length of the first fixing hook 1333. Accordingly, the sensor supporting portion 1332 is inclined with respect to the first circuit board 1314 (and the other end 1110 of the first region 1110). Specifically, when the first and second large rear portions 1333 and 1334 are fixed to the first and second fixing grooves 1321a and 1321b, the lengths of the first and second rear large portions 1333 and 1334 The side where the first large rear portion 1333 is formed tilts further downward due to the difference. Accordingly, the sensor support 1332 can be arranged in the first direction D1.

Referring to FIG. 5C, a method of assembling the first to third modules and the first and second bodies will be described.

The temperature sensor 1331 is inserted into the first body 1100. The temperature sensor 1331 is seated at the end of the second region 1120 of the first body 1100. The second and third modules 1320 and 1330 coupled to the first body 1100 as shown in FIG. 5B are arranged in the second region 1120 in a state where the temperature sensor 1331 is disposed. . The second and third modules 1320 and 1330 are inserted such that the sensor support 1332 supports the temperature sensor 1331. The first and second circuit boards 1314 and 1316 are mounted on the second module.

The first module 1310 is inserted into the third module 1330 inserted in the first region 1110 of the first body 1100. [ The battery module 1340 is inserted into the storage area of the first module 1310. The battery module 1340 may be detached from the first module 1310.

The second body 1200 is fixed to the first body 1100 so as to cover the battery unit 1340. Referring to FIG. 5A, the second body 1200 includes a fixing protrusion 1210 inserted and fixed in one area of the first body 1100. The fixing protrusion 1210 is movably fixed to the first body 1100 so that the fixing protrusion 1210 is fixed even when the second body 1200 is separated from the first body 1100. Accordingly, since the second body 1200 is connected to the first body 1100, it is possible to prevent the second body 1200 from being lost.

5D is a conceptual diagram for explaining the arrangement structure of the first to third modules.

The first body 1100 and the second body 1200 extend in one direction (first direction D1) and are arranged in the second region 1120 of the first body 1100 in the first direction The temperature sensor 1331 is disposed in the first direction D1 and has a sensing range of a specific angle with respect to the first direction D1.

The first and second circuit boards 1314 and 1316 are arranged in the first direction 1110 of the first body 1100 in a second direction D2 that intersects the first direction D1 . The first and second circuit boards 1314 and 1316 may be disposed in the second direction D2 in a space defined by the first and second bodies 1100 and 1200 so as to secure a maximum width. Accordingly, it is possible to dispose the circuit board having the largest width while being disposed in the inner spaces of the first and second bodies 1100 and 1200.

The first and second bodies 1100 and 1200, which constitute the external appearance of the temperature measuring apparatus according to the present invention, have a shape extending along one direction, one of which is inserted into the ear canal and the other of which covers the outside of the ear, There is no structure to fit. That is, the area of contact with or supported by the outer structure of the ear is minimized when the volume of the uninserted area is minimized and worn on the ear (particularly when wearing and sleeping). Thus, the feeling of fit is improved.

In addition, by arranging the circuit board obliquely with respect to the one direction, securing the area of the circuit board, it is possible to secure the stability of the driving of the temperature sensor and implement additional functions.

The temperature sensors can be disposed in a direction adjacent to the eardrum using the first and second large and long portions having different lengths with reference to the obliquely arranged circuit board. Accordingly, the body temperature of the area adjacent to the eardrum can be accurately measured, and the circuit board can be obliquely arranged to realize a structure extending in one direction, so that comfort can be improved when the eardrum is mounted on the ear.

Referring to FIG. 1D again, since the region where the eardrum tm is disposed is included in the sensing range of the temperature sensor of the body temperature measuring instrument 1000 inserted in the ear canal EAm, accurate measurement is possible, It is possible to prevent errors in measurement of body temperature due to movement or measurement posture.

6 is a conceptual diagram for explaining the arrangement of the flexible circuit board.

The temperature sensor 1311 is electrically connected to the first circuit board 1314 by a flexible circuit board 1315. The sensor supporting portion 1332 and the temperature sensor 1311 are arranged in the first direction D1 and the first circuit board 1314 is arranged in the second direction D2.

Referring to FIG. 5B and FIG. 6 together, a region of the first circuit board 1314 adjacent to the relatively short first fixed hook 1333 is disposed adjacent to the temperature sensor 1311. One end of the flexible circuit board 1315 is connected to the temperature sensor 1311 and the other end of the flexible circuit board 1315 is connected to the one area of the first circuit board 1314. That is, Is connected to one region of the first circuit board 1314 adjacent to the first fixed hook portion 1333. The first circuit board 1314 may include a terminal portion 1314a disposed in the one area and connected to the flexible circuit board 1315. [

The flexible circuit board 1315 connected to the one area of the first circuit board 1314 is bent by an angle? 2 between the first and second directions D1 and D2. Therefore, the degree of bending of the flexible circuit board 1315 can be minimized.

7A to 7E are conceptual diagrams for explaining a structure for coupling and separating the second body.

Referring to FIG. 7A, the second body 1200 is separated from the first body 1100 by rotation of the second body 1200 with respect to the first body 1100. The second body 1200 includes a nail groove 1201 which forms a space with respect to the first body 1100. In this case, the user can separate the second body 1200 from the first body 1100 using the nail groove 1201. [

However, the second body according to one embodiment may not include the nail groove 1201.

Referring to FIGS. 7B and 7C, the first module 1310 includes a side wall portion 1317 for forming a receiving region for receiving the battery portion 1340. The side wall part 1317 is formed to surround the battery part 1340. The outer surface of the side wall portion 1317 is formed with a thread. The second body part 1200 includes an inner area 1202 surrounding the side wall part 1317 and accommodating the battery part 1340. A screw thread 1210 corresponding to the thread of the side wall portion 1317 is formed on the inner surface of the second body portion 1200 forming the inner region 1202. [

The side wall portion 1317 and the second body portion 1200 may be fixed by rotation. The side wall part 1317 includes a guide groove 1317a formed along the outer circumference of the side wall part 1317 and a fixing groove 1317b extending in the other direction from the end of the guide groove 1317a. Meanwhile, the second body part 1200 includes a protrusion 1211 protruding from the inner surface of the inner area 1202. The protrusion 1211 moves along the guide groove 1317a so that the first and second body parts 1100 and 1200 rotate relative to each other. The protrusion 1211 moves along the guide groove 1317a and is seated in the fixing groove 1317b so that the first and second body parts 1100 and 1200 are fixed.

The second body part 1200 may be separated from the first body part 1100 by rotating about the first body part 1100 as shown in FIG. When the second body part 1100 is separated from the first body part 1100, the battery part 1340 is exposed. The battery unit 1340 is booty-separated from the first body unit 1100 and may be a removable battery.

7E, the second body part 1200 includes a locking protrusion 1203, and the first body part 1100 includes a locking groove part 1318 formed to catch the locking protrusion 1203 . The latching groove portion 1318 includes first and second grooves 1318a and 1318b. The engaging protrusion 1203 moves along the first groove 1318a while the second body part 1200 is fitted in the first body part 1100. [

The second groove 1318a is formed to extend from the end of the first groove 1318a. The first and second grooves 1318a and 1318b are formed in directions intersecting with each other. The locking protrusion 1203 fitted in the first groove 1318a is fitted into the second groove 1318b by the rotation of the second body part 1200. [ The second body part 1200 is not separated from the first body part 1100 when the second body part 1200 is fitted in the second groove 1318b.

Accordingly, the second body part 1200 is fitted in the direction in which the first groove 1318a is formed, and rotates in a specific direction (counterclockwise) so that the engagement protrusion 1203 is inserted into the second groove 1318b And is fixed to the first body part 1100 due to the fitting.

FIG. 8A is an exploded view for explaining the components of the storage device, and FIGS. 8B and 8C are conceptual diagrams for explaining a hall sensor and a magnet portion for detecting that a temperature measuring device is mounted on the storage sensor.

8A, the storage device 2000 includes a connection portion 2210 connecting the body portion 2100, the lid portion 2200, and the lid portion 2200 to the body portion 2100 .

The body 2100 includes a first body 2110 forming an outer space 2111 and a second body 2120 mounted to the inner space 2111 and a body temperature measuring device 1000 And includes a third main body 2130 including a receiving area 2131 for receiving the first main body 2130. The main body 2130 is inserted into the second main body 2120.

A magnet portion 2140 is disposed inside the first body 2110. In addition, a spring 2112 for connecting the connection portion 2210 and a fixing portion 2113 to which the spring is fixed may be disposed inside the first body 2110.

The second body 2120 includes an opening 2121 which is received in the first body 2110 and through which the spring 2112 can pass. The spring 2112 passes through the opening 2121 and is fixed to the connection portion 2210.

On the other hand, a region separated from the region where the opening 2121 is formed is formed with a recessed portion. The magnet portion 2140 is covered by one region where the recess portion is formed. And the third body 2130 is disposed in the recess portion. The main body 2130 includes a receiving area 2131 for receiving the body temperature measuring instrument 1000 and the receiving area 2131 includes a recessed shape for enclosing an area of the body temperature measuring instrument 1000 ≪ / RTI > The storage area 2131 is formed in an area overlapping with the magnet part 2140.

Referring to FIG. 8C, when the body temperature measuring apparatus 1000 is placed in the storing area 2131, the body temperature measuring apparatus 1000 is disposed adjacent to the magnet unit 2140.

The body temperature measuring apparatus 1000 further includes a hall sensor 1350 disposed on the first circuit board 1314 (or the second circuit board 1316). The hall sensor 1350 senses a magnetic change. The body temperature measuring apparatus 1000 can determine whether the body temperature measuring apparatus 1000 is placed on the receiving apparatus 2000 based on the magnetic change sensed by the hall sensor 1350. In this case, the second region 1120 of the first body 1100 is adjacent to the magnet portion 2140 such that the Hall sensor 1350 is adjacent to the magnet portion 2140, Can be accommodated in the accommodating area 2131 while being inserted.

For example, when the body temperature measuring apparatus 1000 is housed in the storage unit 2000, that is, when the magnet unit 2140 is detected as being adjacent to the hall sensor 1350 according to a change in magnetism , The power of the body temperature measuring instrument 1000 can be turned off. On the contrary, when the hall sensor 1350 does not detect a magnetic change, the body temperature measuring apparatus 1000 can be turned on.

In this case, the body temperature measuring apparatus 1000 may not include a switch or the like for controlling the power supply, so that the volume of the body temperature measuring apparatus 1000 can be minimized.

When the battery pack 200 is not used, the power is turned off and the life of the battery can be increased.

The body temperature measuring instrument 1000 may transmit the body temperature information to an external device when it is sensed that a change in magneticity of the hall sensor 1350 is sensed and stored in the storage device 2000. In this case, when the body temperature measuring device 1000 is inserted into the user's ear, limitation of the wireless communication can minimize the body effect due to the communication.

Further, although not shown in the drawings, the storage device 2000 may further include a dehumidifying agent accommodated in the inner space. The dehumidifying agent may be a silica gel which absorbs moisture. The dehumidifying agent can be reused by heating it in a microwave oven. The storage device 2000 may further include a cleaning tool for removing foreign matters such as ear wax of the body temperature measuring instrument 1000.

9A and 9B are conceptual diagrams showing setting screens for setting measurement times.

The body temperature measuring apparatus 1000 according to the embodiment of the present invention is interlocked with an external device (for example, a mobile terminal 100). The antenna unit 1313 performs a measurement function in conjunction with the external device 100 or transmits the measured data to the external device 100. [ Meanwhile, the body temperature measuring apparatus 1000 may further include a memory for storing the measured data.

The body temperature measuring apparatus 1000 is controlled to start measurement at a time set by the external device 100 and to measure the body temperature at a predetermined cycle. The body temperature measuring apparatus 1000 can measure the temperature several times in the sleep state corresponding to the 3-4 sleep stages of the non-REM sleep state, which is the most stable sleep state. The external device 100 may form body temperature data as an average value of body temperature information measured during the specific time.

The body temperature measuring instrument 1000 receives a control command to start body temperature measurement at a time set by the external device 100. [ The control of the body temperature measurement can be set by the user.

The day when the basal body temperature is the lowest in the menstrual cycle is determined as the day of ovulation. In addition, if the basal body temperature is maintained at a high temperature for 18 days or more after the ovulation day, it is considered that there is a possibility of pregnancy. If the temperature is not maintained, the menstruation is considered to have started. Here, the basal body temperature corresponds to the lowest body temperature that appears in the most stable state everyday. It is low from the evening, the day is the lowest, and then increases again.

Referring to FIG. 9A, the measurement time of the body temperature measuring apparatus 1000 may be set according to a sunrise time according to a user's location. The external device 100 may detect the location of the user (i.e., the location of the external device 100) by a location information sensing unit (e.g., GPS).

The display unit 151 of the external device 100 outputs a first setting screen 510 for setting the measurement time. The first setting screen 510 may be output when the application for executing the body temperature measurement function is executed for the first time, when the measurement start time is not set.

The first setting screen 510 includes the sunrise information 511 according to the location information of the external device 100 and the information 510a about the measurement start time calculated according to the sunrise information. The measurement start time may be set to two hours before the sunrise time. Therefore, the temperature can be measured in the most stable non-REM sleep 3-4 steps 2 hours before the user wake-up time.

Referring to FIG. 9B, the first setting screen 510 includes pre-stored alarm time information 512 and information 510b about a measurement start time calculated based on the alarm time information.

If there is alarm time information stored by the user, the control unit of the external device 100 can set the measurement start time 2 hours before the alarm time.

Although not shown in the drawing, the measurement start time can be set based on the touch input applied to the first setting screen 510. Or change the residential area information or change the alarm time. In addition, the measurement start time can be input using the first setting screen 510. FIG. In this case, the display unit 151 may output guide information that the measurement start time is preferably 3 hours to 4 hours after sleeping or 2 hours before the wake-up.

In addition, the controller of the external device may execute the positioning application or the alarm time setting application on the first setting screen 510. [

Accordingly, even if the user does not set the measurement start time separately, the user can predict the sleeping time of the user according to the necessary information and recommend the measurement start time.

9C and 9D are conceptual diagrams for explaining a control method of outputting notification information based on sensed body temperature.

The body temperature measuring apparatus 1000 according to the present invention transmits and receives measured body temperature information while performing wireless communication with the external apparatus 100. [ The external device 100 forms body temperature data using the received body temperature information, and forms guide information according to a change in body temperature.

For example, the control unit of the external device 100 outputs the first notification information 611 when the body temperature suddenly drops. The first notification information 611 may include analysis result information indicating that the menstruation is expected to start. The analysis result information can predict the ovulation when the low body temperature is measured, the start of the menstruation when the body temperature suddenly drops after the body temperature rises, and the information that predicts the pregnancy when the body temperature is maintained at the high temperature state. The first notification information 611 may be text or an image.

Alternatively, the external device 100 may output the first notification information 611 including information indicating measured body temperature data.

The control unit executes the application related to the basic body temperature based on the touch input applied to the first notification information 611 and controls the display unit 151 to output the first result screen 520 of the application. The first result screen 520 may include a graph 521 indicating a change in body temperature, and a description unit 522 describing a change in body temperature.

Referring to FIG. 9D, the controller may output the second notification information 712 when the change in the body temperature is out of the normal range or when the body temperature itself is out of the range of the normal body temperature. The second announcement information 712 may be a pop-up window.

Also, while the second announcement information 712 is being output, the external device 100 may output vibration or output specific auditory data. Accordingly, when an abnormality occurs in the user's body, the user can confirm it through the notification and take action.

Alternatively, the control unit may output the guide information for recommending the visit if the change in the body temperature is out of the normal range and the cycle of the basic body temperature is not clear, through the second notification information 712. Although not shown in the figure, when the touch input is applied to the second notification information 712, the application is executed and additional analysis information can be output on the execution screen.

10A and 10B are conceptual diagrams illustrating a control method of outputting guide information for guiding measurement.

Referring to FIG. 10A, the control unit controls the display unit to output third announcement information 612 including guide information recommending basic body temperature measurement before going to bed. The third notification information 612 may be output together with information on an event that occurred and driving information of the external device 100.

The controller executes the application when the touch input is applied to the third notification information 612 and controls the display unit to output a setting screen 532 for measuring the body temperature. The setting screen 532 may include an icon 531 for changing the setting of the basic body temperature measurement for each day of the week.

Referring to FIG. 10B, the controller senses that the body temperature measuring apparatus 1000 is separated from the user's ear when the body temperature information detected during a specific time is out of a temperature range corresponding to the body temperature. In this case, the display unit 151 outputs fourth notification information 712 indicating that the body temperature measuring apparatus is disconnected from the ear. The fourth notification information 712 may be a pop-up window. Also, the external device 100 can output vibration or output audible data.

In addition, the controller may control the display unit to output guide information for guiding accurate wearing of abnormal body temperature information according to a certain criterion.

Meanwhile, the body temperature measuring apparatus 1000 can transmit information on the remaining amount of the battery to the external device 100. When the remaining amount of the battery is less than the reference remaining amount, The display unit can be controlled to output the guide information.

In addition, even if the measurement is irregular or the accurate measurement continues, the result information on the measurement can be output on the display unit. Accordingly, the user can measure the body temperature more accurately based on the guide information, and can more accurately perform measurement later by feedback on the measured information.

11 is a conceptual diagram for explaining a control method for detecting an appropriate measurement start time according to an embodiment of the present invention.

Referring to FIG. 11, the display unit 530 displays a measurement time detection screen 530. The detection screen 530 includes guide information 533 and a measurement period setting image 534. The body temperature measuring apparatus 1000 measures a change in body temperature for a predetermined period of time and recommends that the external apparatus 100 sets a measurement start time around a time at which the lowest basal body temperature appears. Thus, the user can set the measurement start time for more accurate measurement.

The control unit outputs a result image 535 based on the collected body temperature information. The resultant image includes recommended measurement time information for measuring a change in body temperature for a set specific period and a time indicated by the lowest basal body temperature.

According to the present invention, the user is set to measure for two hours before waking up, and is set to measure every predetermined period of about ten minutes. The average sleep cycle is 90 minutes, and the most stable non-REM levels 3 to 4 of these are approximately 25 minutes. Therefore, if the body temperature is measured at intervals of 10 minutes, the body temperature can be measured in the non-REM 3-4 step, which is the most stable sleeping phase even if the sleep cycle becomes irregular according to the user's condition.

12 is a conceptual diagram for explaining an example of a body temperature change according to various states.

According to the present invention, the body temperature measuring device 1000 transmits body temperature information to the external device 100. [ For example, the body temperature measuring apparatus 1000 transmits information when the body temperature measuring apparatus 1000 is housed in the receiving apparatus 2000, transmits information when the body temperature measuring apparatus 1000 is positioned adjacent to the external apparatus 100, The body temperature information can be transmitted to the external device 100 in real time. The external device 100 can form body temperature data using the received body temperature information and calculate result information according to the body temperature data.

Figure 12 (a) shows a graph of the general basal body temperature during the menstrual cycle. The low temperature and the high temperature are repeated, and when the low temperature is over, the lowest temperature is recorded and the temperature is increased. In this case, it is possible to output the notification information from the previous month-based next month ovulation prediction day and the day before the start of menstruation prediction two days before.

Fig. 12 (b) is a graph showing a change in body temperature when a rise in body temperature takes a long time after the low temperature. If the body temperature has not increased for a long time after the low temperature, the external device can output guide information recommending utilization of the ovulation test for more accurate confirmation of the ovulation date before the body temperature rises next month based on the previous month.

In the case of (c) of Fig. 12, the body temperature sensing graph in which the high temperature is unstable is shown. In this case, the external device 100 can output guide information for guiding the condition adjustment.

12 (d) corresponds to the case where the low-temperature period is long and the high-temperature period is short. It is judged to be a rare menstrual state when the entire cold cycle becomes longer than 60 days due to the longevity. In this case, the external device (`00) recommends the use of the ovulation test before the rise of body temperature next month based on the previous month, and can output guide information recommending the visit of the hospital.

In the case of (e) of FIG. 12, a graph showing a change in body temperature is measured in a skewed manner. In this case, the external device (`00) recommends utilization of the ovulation test before the rise of body temperature next month based on the previous month, and can output guide information for confirming ovulation mucus and ovulation cyst.

In the case of (f) in FIG. 12, this corresponds to a body temperature measurement graph in which the distinction between a low temperature and a high temperature is impossible. In this case, the external device 100 determines that the variation of the entire basic body temperature for a period of 2 months or more is not a change in the predetermined temperature (0.2 degrees) .

The control unit of the external device may be configured such that when the basal body temperature does not fall below the characteristic temperature (0.2 degrees) even after 2-3 days from the start of menstruation, and when the high temperature period continues for 20 days or more after the ovulation date And outputs the recommended guide information. If the distinction between the low temperature and the high temperature is impossible, the child outputs guide information recommending visit to the hospital.

13A to 13C are conceptual diagrams for explaining a control method of an external device in conjunction with a body temperature measuring device according to the present invention.

Referring to FIG. 13A, the display unit 151 of the external device 100 outputs a first execution screen 541 when a specific application is executed. The first execution screen 541 may display the basic body temperature measured before the present day of the day as a number and may include information on the rise / fall of the basic body temperature of the day yesterday. It may also include guide information on physiology, pregnancy, and ovulation. Here, the basal body temperature is set to the lowest body temperature measured 12 times at intervals of 10 minutes for 2 hours from 2 hours before the wake-up time.

The first execution screen 541 includes a graph 541a showing a variation amount of the basic body temperature by date and driving information 541b of the body temperature measuring apparatus 1000.

When a specific touch input is applied to the first execution screen 541, a second execution screen 542 is outputted. The second execution screen 542 includes history information of the measured body temperature. The control unit forms the menstrual cycle pattern data based on the measured body temperature information, and the second execution screen 542 includes a graph 542a according to the pattern data. The graph 542a represents a change in body temperature, and includes information about the menstrual period, ovulation date, and fertility period.

In addition, the second execution screen 542 includes a basic body temperature data list 542b recorded for each date.

Referring to FIG. 13B, the display unit 151 outputs a third execution screen 543 including a calendar screen. The calendar screen 543 records the measured basal body temperature and includes data (physiological status, sex, ovulation inducing agent and injection, cold medicine, antibiotic use, notes, etc.) stored by the user.

Accordingly, the user can grasp the data based on the basic body temperature results as well as the basic body temperature at a glance through the calendar screen.

The third execution screen 543 may be switched to the fourth execution screen 544 based on the touch input of the specific method applied on the third execution screen 543. [ The fourth execution screen 544 corresponds to a control screen for controlling body temperature measurement.

According to the present embodiment, the body temperature of a person other than the set user can be measured and recorded. In this case, the current body temperature can be measured in real time using the body temperature measuring instrument 1000, rather than the basic body temperature. When a touch input is applied to the fourth execution screen 454, body temperature measurement of the body temperature measuring instrument 1000 is performed by a control signal.

Also, unlike the measurement of the basal body temperature about 2 hours before the wake-up, it is possible to measure the body temperature for a predetermined time and set the notification to be received when the temperature exceeds the specific temperature range. Although not specifically shown in the figure, the measured body temperature information can be transmitted to the external device 100 in real time. The external device 100 can output an alarm when the received body temperature information satisfies a specific condition and the body temperature is out of a predetermined range of a predetermined body temperature.

The external device 100 may output the list of measured data to the fifth execution screen 545. The fifth execution screen 545 may selectively include data directly measured by the user's choice or data measured overnight.

13C shows a display unit 151 for outputting a screen for setting a body temperature measurement start time. The screen for setting can display the measurement time for each day of the week, and when one day of the week is selected, a sixth execution screen 546 for changing the time is output.

14A to 14C are conceptual diagrams for explaining a control method of an external device for outputting notification information informing the driving state of the body temperature measuring device.

The body temperature measuring instrument 1000 according to the present embodiment can transmit body temperature information and / or driving state information sensed by the external device 100 in real time.

If the external device 100 does not receive the body temperature information within the normal range after the predetermined temperature measurement start time, the external device 100 detects the abnormal state of the measurement and outputs the first warning image 548a. The first warning image 548a may be text or an image for confirming the position of the clinical thermometer, and may output vibration or sound.

Referring to FIG. 14B, the body temperature measuring instrument 1000 transmits the body temperature information to the external device 100 when the body temperature measuring instrument 1000 is accommodated in the accommodating apparatus 2000. The external device 100 outputs a second warning image 548b when the body temperature information is not received. The second warning image 548b may include information that the pairing is not possible.

In this case, the memory included in the body temperature measuring apparatus 1000 may temporarily store information. Accordingly, when the pairing state corresponds to the normal range, all stored information can be transmitted to the external device.

Referring to FIG. 14C, the external device 100 may output a third warning image 548c indicating that the battery of the body temperature measuring device 1000 is insufficient. The external device 100 may output the third warning image 548c when the received body temperature information is irregular. Alternatively, the body temperature measuring apparatus 1000 may transmit information on a battery shortage to the external device 100 as a radio signal.

The control method according to the embodiment can be activated and deactivated according to the setting of the user.

15A and 15B are conceptual diagrams for explaining a control method of performing body temperature sensing according to detection of acceleration.

Referring to FIG. 15A, the body temperature measuring apparatus 1000 activates a temperature sensor (S12) when separation from the storing apparatus 2000 is sensed (S11). If a change in the acceleration is not detected based on the sensing unit included in the wearable device (S13), the temperature is sensed at a specific period (S14).

That is, it is assumed that there is no motion in which the acceleration change is not detected and the measured temperature value corresponds to the body temperature range is the sleep state. According to the present embodiment, the temperature measurement can be started based on whether or not it is motion.

15B, sunrise time information based on the location information of the user (the external device 100) is acquired (S21), and the wearable device activates the sensor (acceleration sensor) based on the sunrise time information . For example, the sensing unit is activated two hours before the sunrise.

The change of the acceleration is sensed (S23). If there is no change in the acceleration, the temperature can be measured at a specific period (S24).

According to the present embodiment, the body temperature information can be collected by more accurately grasping the case of being judged as the sleeping state.

16 is a conceptual diagram for explaining the measurement function.

Referring to FIG. 16, the body temperature measuring apparatus 1000 can sense a body temperature in real time. When the body temperature measuring instrument 1000 is detached from the storage unit 2000, the power of the body temperature measuring instrument 1000 is turned ON.

It is possible to control the body temperature measuring apparatus 1000 to measure the body temperature in real time through the external device 100. The body temperature measuring instrument 1000 transmits the sensed body temperature information to the external device 100. Accordingly, the display unit 151 of the external device 100 can output the received body temperature information.

FIG. 17 illustrates a control method for analyzing the sleep state in cooperation with a wearable device.

The wearable device according to the present embodiment may correspond to any one of a watch type terminal, a ring type terminal and a glass type terminal worn on a wrist, a finger and a head. The wearable device includes a sensing unit which is worn in one area of the user's body and senses the movement of the user's body. The sensing unit may include an acceleration sensor, a gyro sensor, or the like. According to the present embodiment, the sleep state can be accurately analyzed through the body temperature information sensed by the body temperature measuring device and the motion information sensed by the wearable device.

Here, the sleep state can be distinguished as a deep sleep state, a light sleep state, and a state (awake). It is important to distinguish between the N3 / N4 state and the REM sleep state, which have substantially the same degree of motion during the sleep phase, in determining the depth of the sleep surface. However, the use of the wearable device based on the acceleration sensor alone can not distinguish between the REM sleep stage and the non-REM 3/4 stage because it determines the sleep stage only by the movement. In addition, although there is motion in the skip state, it can not distinguish the state only by the motion information of the sensing part. Therefore, more accurate sleep analysis can be performed by analyzing the movement information of the wearable device and the body temperature of the body temperature measuring apparatus 1000 together.

Therefore, if the body temperature is irregular and motion is not detected, it is judged to be a REM sleep state. If the body temperature is stable while the motion is not detected, the state is discriminated as N3 / N4 state. . The REM sleep state is mainly a dreaming stage, in which the cerebrum is actively active and there is no movement of the body, but the movement of the eyeball is active. The N1 state is a transient state between complete sleep and awake, and the N2 state causes the amplitude and frequency of the brain waves to decrease and gradually enter a deep sleep state. The N3 / N4 state corresponds to the deep sleep state and corresponds to the deepest sleep phase.

Referring to FIG. 17, it is determined whether movement has been measured by the wearable device (S31). If motion is detected, it is determined whether the body temperature is regular or whether the body temperature is stable (S35). If the movement is detected and the body temperature is regular and stable, it is classified into the N3 / N4 level of the non-REM sleep state (S36). If the body temperature is not regular and stable, the REM sleep state is classified.

When the wearable device detects movement, it is classified as Awake (S33). However, if it is determined that the movement is sensitive to minute movement (degree of backwardness) according to a specific criterion, it can be classified into the N1 / N2 level of the non-REM sleep surface.

As a result, body temperature sensing and motion detection can be used to more accurately identify sleep stages.

The present invention described above can be embodied as computer-readable codes on a medium on which a program is recorded. The computer readable medium includes all kinds of recording devices in which data that can be read by a computer system is stored. Examples of the computer readable medium include a hard disk drive (HDD), a solid state disk (SSD), a silicon disk drive (SDD), a ROM, a RAM, a CD-ROM, a magnetic tape, a floppy disk, , And may also be implemented in the form of a carrier wave (e.g., transmission over the Internet). Also, the computer may include a control unit 180 of the terminal. Accordingly, the above description should not be construed in a limiting sense in all respects and should be considered illustrative. The scope of the present invention should be determined by rational interpretation of the appended claims, and all changes within the scope of equivalents of the present invention are included in the scope of the present invention.

Claims (20)

A body having a first body including first and second regions and a second body mounted on the first body, the body extending in a first direction;
A rubber cap surrounding the first region and formed to be insertable into the ear;
A temperature sensor disposed in the second region and sensing a temperature having a specific sensing range based on the first direction;
And first and second circuit boards electrically connected to the temperature sensor and disposed in the second region and disposed in a second direction intersecting the first direction,
Wherein the first body and the rubber cap include first and second holes for exposing the temperature sensor,
Wherein the first body has one end cut along the second direction, and the second body is mounted to the one end. The method according to claim 1,
And a flexible circuit board connecting the temperature sensor and the circuit board,
Wherein the flexible circuit board includes a bending area and one end of the flexible circuit board is connected to one area of the temperature sensor closest to the circuit board. The method according to claim 1,
The inner surface of the second region forming the first hole is formed of an oblique surface,
The inner surface of the rubber cap forming the second hole is made of an oblique surface,
Wherein the first and second oblique faces are formed such that the first and second holes become larger as the distance from the temperature sensor increases, and the first and second oblique faces have a certain angle so as to include the sensing range Thermometer. The method according to claim 1,
Wherein the second region includes a fixing groove formed along the inner peripheral surface,
And the rubber cap includes a fixing protrusion corresponding to the fixing groove on an inner surface thereof to fix the rubber cap to the second area. 5. The method of claim 4,
And a vent hole extending from an end of the second region to a boundary of the first and second regions, the vent hole being formed by recessing an outer surface of the second region,
And air is introduced into the vent hole by the gap between the first and second regions and the rubber cap. The instrument according to claim 5, wherein one region of the vent hole in which the fixing groove is formed is formed deeper than a depth of the fixing groove. The method according to claim 1,
A first module coupled to the first body and disposed at the one end of the first direction;
A second module coupled to the first module and seating the first and second circuit boards;
And a third module coupled to the second module and supporting the temperature sensor in the first direction. 8. The method of claim 7,
And a side wall part formed on one surface of the first module so as to surround the battery part,
The side wall portion including a thread,
The second body includes an inner surface formed to surround the side wall portion and having a thread,
Wherein the first body and the second body are formed to be separated by rotation. 8. The method of claim 7,
Wherein the first body includes first and second grooves formed in directions intersecting with each other,
And the second body includes a coupling protrusion that moves along the first groove and is fixed to the second groove. 8. The method of claim 7,
Wherein the second module includes a side wall part formed to surround the first and second circuit boards and a support part protruding from the side wall part and supporting between the first and second circuit boards. . 11. The method of claim 10,
And the outer surface of the side wall portion corresponds to one region of the outer surface of the first region. 11. The method of claim 10,
Wherein the third module includes a sensor support for supporting the temperature sensor and first and second fixed hooks extending from the sensor support and mounted to the second module,
Wherein the first and second fixed hook portions have different lengths. 13. The method of claim 12,
Wherein each end of the first and second fixed hook portions includes a hook structure projecting in a direction away from each other,
Wherein the inner surface of the side wall portion of the second module corresponds to each other and includes first and second fixing grooves into which the hook structures of the first and second fixing hook portions are inserted. 14. The method of claim 13,
Wherein the first and second fixing grooves are formed adjacent to the first circuit board, respectively. 8. The method of claim 7,
Further comprising an antenna unit disposed on one side of the first module and transmitting and receiving a radio signal. 16. The method of claim 15,
Performs wireless communication with an external device through the antenna unit,
Wherein the antenna unit transmits the measured body temperature information to the external device. The method according to claim 1,
The second body extends from the other end of the first body along the first direction,
And the outer periphery of the second body is formed to be smaller than the outer periphery of the first body. A body temperature measuring instrument including a temperature sensor and having a hall sensor; And
And a storage device for storing the body temperature measuring device,
The storage device,
A first body having an outer appearance and having an inner space;
A third body disposed in the inner space, the third body including a second body and a housing area in which the body temperature measuring instrument is housed in a concave shape; And
And a magnet portion disposed in one region of the first main body. 19. The method of claim 18,
Wherein the body temperature measuring device senses a magnetic change by the hall sensor, and when the magnetic change is not sensed, the temperature sensor is activated. 19. The method of claim 18,
The body temperature measuring instrument includes an antenna unit,
Wherein the body temperature measuring device transmits body temperature information measured through the antenna to an external device when a magnetic change is detected by the hall sensor.

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