KR20230088017A - Modern sundial enabling to adjust latitude longitude according to user location and correcting the equation of time according to seasonal time - Google Patents

Abstract

The present invention relates to a sundial for correcting the latitude and the longitude in a customized manner in accordance with a place where a user is located and providing equation-of-time correction, which can be easily operated. The sundial of the present invention comprises: a first hemisphere including a first needle, a first hemisphere surface, and a first solar term display unit; a second hemisphere including a second needle, a second hemisphere surface, and a second solar term display unit; a main body unit for connecting the first and second hemispheres; a compass unit located on one side of the main body unit; a latitude correction unit; and a longitude correction unit.

Description

A sundial that adjusts latitude and longitude according to the user's location and provides equational time difference correction

The present invention relates to a sundial to which a modern model is applied, and more particularly, to a modern sundial that adjusts latitude and longitude according to a location where a user is located and provides equation of time correction.

A sundial is a watch designed to tell the time using the position of the sun on the celestial sphere. The most rudimentary sundial determines the time by the position of the shadow cast by a stick standing vertically. However, since the amount of change in the shadow of a stick standing vertically on the ground does not move at a constant speed, it was difficult to draw line of sight at regular intervals.

A related sundial in Korea is Angbuilgu, a pot-shaped sundial produced in 1434 by Yi Sun-ji and others in the 16th year of King Sejong's reign. Angbuilgu could read the tip of the shadow of the celestial needle to know the time and season (date).

However, in the case of Angbuilgu, since all 24 solar terms are displayed on both sides of one hemisphere, it is not easy to know where the current solar terms are. Also, the equation of time difference, which is the difference between solar time and mean solar time, was not reflected at all, and latitude and longitude could not be corrected at all when used in regions other than Seoul or overseas other than Korea. For reference, Figures 1 and 2 show the structure of Angbuilgu, which is Korea's treasure 845a.

As one of the related conventional patent documents, Korean Patent Registration No. 10-2071980 (registered on January 23, 2020, title of invention: Sundial device and operating method correcting the equation of time {Operating method and apparatus for Sundial device to correct the equation of time}). In the patent document, "the first and second statues that are positioned so that the statues are positioned close to each other to pass sunlight in a certain solid line; the solid line sunlight passing between the first and second statues is transmitted to a light sensor A clock face that detects true solar time and calculates the equational time difference between the true solar time and standard solar time acquired through wired/wireless communication with a server and rotates according to the equational time difference; and a time difference correcting the equational time difference between the true solar time and the standard solar time A correction device; wherein the time difference correction device includes: a time correction unit that calculates the equation of time difference between the true solar time and the standard solar time; and a servo that rotates the rotating shaft connected to the clock panel according to the equation of time difference calculated by the time correction unit. Disclosed is a sundial device correcting the equation of time, further comprising a motor.

However, the corresponding sundial device includes a light sensor and a servomotor that rotates the clock face itself to correct the Equation of Time, so it is impossible to carry it or manufacture a sundial with a relatively small size, and the manufacturing cost is high. I had a lot of problems with it.

In addition, as another conventional patent document, Republic of Korea Patent Publication No. 10-2018-0025605 (published on March 9, 2018, title of invention: Fabricated model sundial and the assembly method {Fabricated model sundial and the assembly method}) can be heard According to the patent document, "The present invention relates to a prefabricated model sundial and an assembly method thereof. To understand the principle of a sundial by providing a prefabricated model sundial in which each part printed with a developed view is cut along perforated lines, then bent and joined to assemble directly. You can improve your learning efficiency by accurately understanding the seasons, seasons, and the principles of setting the hour hand, and you can feel a sense of accomplishment and fun through crafting. Disclosed is a prefabricated model sundial capable of firmly manufacturing a sundial and a method for assembling the same.

However, as described above, it only had the problems that the conventional angbuilgu had. In other words, since all 24 solar terms were displayed on both sides of one hemisphere, it was not easy to know where the current solar terms were, and when used outside of Seoul or overseas other than Korea, it was not possible to correct the latitude and longitude at all. I had a problem that I couldn't.

Republic of Korea Patent Registration No. 10-2071980 (registered on January 23, 2020, title of invention: Sundial device and operating method correcting the equation of time {Operating method and apparatus for Sundial device to correct the equation of time}) Republic of Korea Patent Publication No. 10-2018-0025605 (published on March 9, 2018, title of invention: fabricated model sundial and the assembly method {Fabricated model sundial and the assembly method})

The present invention has been created to solve the above-mentioned problems, and an object of the present invention is to disclose a sundial that adjusts latitude and longitude according to a location where a user is located and provides equation of time correction.

In addition, through an app that the user can easily call by recognizing a QR code provided on one side of the sundial, the user automatically checks the latitude and longitude of the current location based on GPS information or base station information of the place where the user's smartphone terminal is located, Another object of the present invention is to provide a sundial capable of determining true north direction through geomagnetic declination and easily guiding how to operate a latitude correction unit and a longitude correction unit.

A sundial according to an embodiment of the present invention is a sundial that corrects latitude and longitude according to a location where a user is located and provides equational time difference correction. a first needle capable of providing the movement of the shadow according to the movement of the sun in order to provide visual information; a concave first hemisphere on which a first visual display capable of checking visual information during a period from the winter solstice to the summer solstice is displayed on the surface using the position of the shadow of the first needle; A first hemisphere including; a first season display unit displaying seasonal seasons from the winter solstice to the summer solstice on one side of an edge surface of the first hemisphere; a second needle pointing toward the north pole and capable of providing the movement of the shadow according to the movement of the sun in order to provide visual information during the period from the summer solstice to the winter solstice; a concave second hemisphere on which a second visual display capable of checking visual information during a period from the summer solstice to the winter solstice is displayed on the surface using the position of the shadow of the second needle; A second hemisphere including; a second seasonal season display unit displaying solar terms from the summer solstice to the winter solstice on one side of an edge surface of the second hemisphere; a main body connecting the first hemisphere and the second hemisphere and providing an overall frame of the sundial; and a main body located on one side of the main body so that the first needle and the second needle face the north pole. a compass unit capable of inducing adjustment of the negative direction; a latitude correction unit configured to adjust a latitude according to a location where the user is located in a state in which the direction of the main body is directed toward the north pole; and a hardness correction unit configured to adjust the hardness according to the location where the user is located in a state in which the direction of the main body is directed toward the north pole.

In addition, on the first hemispherical surface, a first time display for knowing the standardized time of the reference position; and a segmental line display only during the period from the winter solstice to the summer solstice, wherein on the second hemisphere, a second time display capable of knowing the standardized time of the reference position; and the display of the segmental line only during the period from the summer solstice to the winter solstice.

In addition, on the first hemispherical surface, a first visual lattice display showing standard time (mean solar time); and a solar solstice (date line) display only during the period from the winter solstice to the summer solstice; a first time display including a second time grid showing standard time (mean solar time) on the second hemisphere. mark; and a second time display including; and displaying a season line (date line) only during the period from the summer solstice to the winter solstice.

In addition, the latitude and longitude of the reference position of the sundial are set to the latitude and longitude of Seoul, Korea, and the sundial corresponds to the latitude and longitude of the place where the user is located through the latitude correction unit and the longitude correction unit. It is possible to calibrate the latitude and longitude of

In addition, the latitude correction unit, in a state in which the direction of the main body is guided in the north pole direction through the compass unit, by θ, which is the difference between the latitude of Seoul, Korea and the latitude of the place where the user is located, as an axis in the east-west direction, but in the north-south direction , and the longitude correction unit, in a state in which the direction of the main body is guided in the direction of the North Pole through the compass, by Φ, which is the difference between the longitude of Seoul, Korea and the longitude of the place where the user is located, The north-south direction is the axis, but the rotation is perpendicular to the east-west direction.

In addition, an app execution unit including a QR code provided on one side of the sundial; further included, the app executed by recognizing the QR code through the user's smartphone measures the latitude and longitude of the place where the user is located and the geomagnetic deviation. and guidance for adjusting the latitude correction unit and the longitude correction unit corresponding to the latitude and longitude and determining the true north of the sundial according to the geomagnetic deviation.

In addition, the latitude correction unit is composed of a height adjustment unit for latitude correction provided at the lower south and lower north parts of the main body unit and protruding vertically, the axis being in the east-west direction, but allowing it to rotate vertically with respect to the north-south direction, and the longitude correction unit The part is preferably composed of a height adjusting part for hardness correction provided at the lower east and lower west parts of the main body part, so that the north-south direction is the axis but vertically rotated with respect to the east-west direction.

In addition, if the difference between the lower south and lower north parts of the main body is θ, which is the difference between the latitude of Seoul, Korea and the latitude of the place where the user is located, it has a height of h1, but the angle of the wedge on one side is θ for latitude correction Latitude correction is performed by supporting a wedge-shaped support below, and the latitude correction wedge satisfies the following Equation 1-1,

[Equation 1-1]

h1 = d1 sin θ

Here, d1 is the distance between the height adjusting parts of the lower south and lower north parts of the main body and is the length of the hypotenuse of the wedge for latitude correction, h1 is the height of the wedge for latitude correction,

The difference between the height control unit between the lower east side and lower west side of the main body is Φ, which is the difference between the longitude of Seoul, Korea and the longitude of the place where the user is located, and has a height of h2, but the angle of the wedge on one side is Φ. Supports the support under, and the wedge for hardness correction satisfies the following Equation 2-1,

[Equation 2-1]

h2 = d2 sin Φ

d2 is the distance between the height adjusting parts of the lower east and lower west parts of the main body and is the length of the hypotenuse of the wedge for hardness correction, h2 is the height of the wedge for hardness correction,

The latitude correction wedge and the longitude correction wedge are stacked above and below.

In addition, in the app, when providing guidance on the adjustment of the latitude correction unit and the longitude correction unit, the difference between the height adjustment unit between the lower south part and the lower north part of the main body is the difference between the latitude of Seoul, Korea and the place where the user is located. Corresponds to θ, which is the difference between latitudes, according to the following Equation 1-2,

[Equation 1-2]

k1 = d1 tan θ

d1 is the distance between the lower south and lower north height adjusting parts of the main body, k1 is the height difference between the lower south and lower northern height adjusting parts of the main body,

The difference between the eastern lower part and the western lower part of the body part corresponds to Φ, which is the difference between the longitude of Seoul, Korea and the longitude of the place where the user is located, according to Equation 2 below,

[Equation 2-2]

k2 = d2 tan Φ

d2 is the distance between the height adjusting parts of the lower east and lower west parts of the main body, and k2 is the height difference between the height adjusting parts of the lower east and lower west parts of the main body.

In addition, the height adjusting unit is adjustable in height through screw rotation, and a band display of a color with good visibility of the adjusted height is included on the surface of the screw so that the user can confirm that the height is adjusted to the height presented through the app. it is desirable to have

The sundial according to a preferred embodiment of the present invention,

First, latitude and longitude may be corrected according to the place where the user is located, and equational time difference correction may be provided. Through this, it is possible to correct and use the latitude and longitude even when used in an area other than Seoul or in a foreign country other than Korea.

Second, the first hemisphere includes an 'S'-shaped first visual lattice display capable of knowing the standardized time at the reference location, that is, standard time or mean solar time, for the period from the winter solstice to the summer solstice, On the second hemisphere, for the period from the summer solstice to the winter solstice, the standardized time at the reference location, that is, the standard time or the mean solar time, is included, including the second visual lattice display in the shape of an 'inverted S', In the case of , all 24 solar terms are displayed on both sides of the hemisphere, while using the constant arc of solar terms in common during the period from the winter solstice to the summer solstice and from the summer solstice to the winter solstice on one hemisphere. The difficulty of knowing where it is is eliminated, and even when a portable or relatively small-sized angbuilgu is produced, it is easy to display the seasons, and as a result, it is easy for the user to recognize the seasons.

Third, the latitude and longitude of the current location are automatically checked based on the GPS information or base station information of the place where the user's smartphone terminal is located through an app that the user can easily and automatically bring up by recognizing the QR code provided on one side of the sundial. And, the operation method of the latitude correction unit and the longitude correction unit is guided, making it easy for the user to operate, obtaining the geomagnetic declination from latitude and longitude data, and obtaining the true north direction.

1 and 2 show the structure of Angbuilgu, which is Korea's treasure 845a.
3 schematically shows a first hemisphere and a second hemisphere in a sundial according to a preferred embodiment of the present invention.
4 is a diagram schematically illustrating latitude correction in a sundial according to an exemplary embodiment of the present invention.
5 is a diagram schematically illustrating longitude correction in a sundial according to a preferred embodiment of the present invention.
6 and 7 show the first time display of the first hemisphere and the second time display of the second hemisphere in the sundial according to a preferred embodiment of the present invention.
8 is a graph showing the equation of time.
9 is a conceptual diagram of an app capable of obtaining location information and true north information.

Hereinafter, preferred embodiments according to the present invention will be described in detail with reference to the accompanying drawings. Prior to this, the terms or words used in this specification and claims should not be construed as being limited to the usual or dictionary meaning, and the inventor appropriately uses the concept of the term in order to explain his/her invention in the best way. Based on the principle that it can be defined, it should be interpreted as meaning and concept consistent with the technical spirit of the present invention.

Therefore, since the embodiments described in this specification and the configurations shown in the drawings are only one of the most preferred embodiments of the present invention and do not represent all of the technical ideas of the present invention, various alternatives may be used at the time of this application. It should be understood that there may be equivalents and variations.

3 schematically shows a first hemisphere and a second hemisphere in a sundial according to a preferred embodiment of the present invention, and FIG. 4 schematically shows latitude correction in a sundial according to a preferred embodiment of the present invention. , and FIG. 5 is a diagram schematically illustrating longitude correction in a sundial according to a preferred embodiment of the present invention.

3 to 5, the sundial according to a preferred embodiment of the present invention includes a first hemisphere, a second hemisphere, a body part, a compass part (not shown), a latitude corrector and a longitude corrector. , It is a sundial that corrects the latitude and longitude according to the user's location and provides equational time difference correction.

Here, the first hemisphere includes a first needle, a first hemisphere surface, and a first season display unit. The first needle points toward the north pole (meaning true north, not magnetic north), and is responsible for the movement of the sun in order to provide standard time information only during the period from the winter solstice to the summer solstice (the ecliptic ascending section). Therefore, it is a configuration that can provide movement of the shadow. The first acupuncture needle and the second acupuncture needle described later play a role similar to that of the English chimney of Angbuilgu. Of course, it has the characteristics of the present invention.

The first hemisphere is a concave hemisphere on which a first time display is displayed on the surface to check standard time time information only during the period from the winter solstice to the summer solstice by using the position of the shadow of the first hand. The first hemisphere includes a first seasonal season display unit displaying solar terms from the winter solstice to the summer solstice on one side of an edge surface of the first hemisphere. The first solar terms display unit can display the 12 solar terms or 13 solar terms from the winter solstice to the summer solstice in Chinese characters among the existing 24 solar terms, or write Korean or solar or lunar dates together.

In addition, the second hemisphere includes a second needle, a second hemisphere surface, and a second season display unit. The second needle is oriented toward the North Pole (true north), and is configured to provide the movement of the shadow according to the movement of the sun in order to provide time information in standard time only during the period from the summer solstice to the winter solstice (the strong bridge section of the ecliptic). The second hemisphere is a concave hemisphere on which a second time display is displayed on the surface to check standard time time information only during the period from the summer solstice to the winter solstice using the position of the shadow of the second hand. The second hemisphere includes a second seasonal season display unit displaying solar terms from the summer solstice to the winter solstice on one side of an edge surface of the second hemisphere. The second solar terms display unit can display the 12 solar terms or 13 solar terms from the summer solstice to the winter solstice in Chinese characters among the existing 24 solar terms, or it is possible to write Korean or solar or lunar dates together.

Realistically, in the conventional angbuilgu, the 24 solar terms were written on both sides of the hemispheric surface, so in the small sized angbuilgu, the letters became smaller and smaller, so there was a problem that it was difficult to identify with the naked eye of the user, and the connection between the 24 solar terms was not easily recognized. However, as in the present invention, by dividing the first hemisphere and the second hemisphere, the first hemisphere has 12 or 13 solar terms only during the period from the winter solstice to the summer solstice (Winter Solstice, Sohan, Daehan, Ipchun, Excellent, Gyeongchip, In the second hemisphere, 12 or 13 solar terms only during the period from the summer solstice to the winter solstice (Haji, Soseo, Daeseo, Ipchu, Cheoseo, Baekro) are displayed. , Autumn equinox, Hanro, Sanggang, Ipdong, Novel, Daeseol, (winter solstice)) can be displayed to improve the user's visibility.

In general, the 24 solar terms are made to distinguish the seasons according to the position of the sun on the ecliptic. Specifically, Ipchun is February 3, 4 or 5 in the Gregorian calendar, rain is February 18 or 19 in the Gregorian calendar, Gyeongchip is March 5 or 6 in the Gregorian calendar, and vernal equinox is March 20 or 21 in the Gregorian calendar Sun, Cheongmyeong is April 4 or 5 in the Gregorian calendar, Gowu is April 20 or 21 in the Gregorian calendar, Ip is May 5 or 6 in the Gregorian calendar, and Soman is May 20, 21 or 22 in the Gregorian calendar. Sun and Mangjong are on June 5 or 6 in the Gregorian calendar, summer solstice is on June 21 or 22 in the Gregorian calendar, small is on July 7 or 8 in the Gregorian calendar, large is on July 22 or 23 in the Gregorian calendar, and Ipchu is on the Gregorian calendar. August 7th or 8th, Chuseo August 23rd or 24th Gregorian calendar, Egret September 7th or 8th Gregorian calendar, Autumnal equinox September 22nd, 23rd or 24th Gregorian calendar, Hanro October 8th Gregorian calendar or 9th, Sanggang on October 23 or 24 of the Gregorian calendar, Idong on November 7 or 8 of the Gregorian calendar, Novel on November 22 or 23 of the Gregorian calendar, Daeseol on December 7 or 8 of the Gregorian calendar, Winter solstice Since December 21st or 22nd of the Gregorian calendar, January 5th or 6th of the Gregorian calendar, and January 20th or 21st of the Gregorian calendar, it is possible to write these dates of the Gregorian calendar together with the seasons.

In addition, it is preferable to further include a compass unit capable of inducing adjustment of the direction of the body unit so that the first needle and the second needle face the north pole (true north). The sundial can be installed according to true north by obtaining the geomagnetic deviation (referring to the geomagnetic declination because the geomagnetic deviation occurs in an angle) from the current location through the app connected with the QR code and applying it to the compass of this sundial. If there is no compass part in the body part, since a separate compass is required, it is preferable to include the compass part for user convenience.

It is formed on one side of the body part, especially on the needle surface of the first needle or the second needle so that it is easy to adjust the direction of the first needle and the second needle, and the first needle and the second needle are measured by considering the geomagnetic deviation while looking at the compass part. It is most preferable to make it possible to adjust the . Although two compass parts may be included on the surface of the first and second needle needles, adjustment in the true north direction of the body part is possible even if they are included in either one.

For reference, FIG. 9 is a conceptual diagram of an app capable of obtaining location information and true north information. The related app executed by recognizing the QR code through the user's smartphone provides the latitude and longitude of the place where the user is located and the geomagnetic deviation to determine the true north of the sundial according to the geomagnetic deviation, and at the same time provides the latitude and longitude Correspondingly, latitude correction and longitude correction are provided.

In addition, the latitude correction unit is configured to adjust the latitude according to the location where the user is located in a state in which the above-described direction of the main body is guided in the direction of the North Pole (true north) through the compass, and the longitude correction unit, In a state where the direction of the main body is guided in the direction of the north pole (true north) through the compass, the longitude can be corrected according to the location where the user is located. An embodiment for this will be described later in detail below.

In addition, on the above-described first hemisphere, a plurality of 'S'-shaped first visual grids displaying standardized time at a reference location, that is, standard time or mean solar time; and a first time display including; and displaying a season line (date line) only during the period from the winter solstice to the summer solstice.

In addition, on the above-described second hemisphere surface, a plurality of inverted 'S'-shaped second visual grids displaying standardized time at the reference position, that is, standard time or mean solar time; and a second time display including; and displaying a season line (date line) only during the period from the summer solstice to the winter solstice.

For reference, FIGS. 6 and 7 show a first time display in a first hemisphere and a second time display in a second hemisphere in a sundial according to a preferred embodiment of the present invention. As shown in FIGS. 6 and 7, a first visual grid display and a second visual grid displaying standard time or mean solar time, which are standardized times at reference locations, using the ends of the shadows of the first and second needles. There is a visual grid display. For example, it is possible to display 1 hour in 6 grids on a hemispherical surface in a 10-minute unit. The standardized time at the reference location may be previously set as standard time according to the latitude and longitude of Seoul, Korea, or set as mean solar time in advance according to the latitude and longitude of Seoul, Korea.

On such a lattice display, that is, on the first time lattice display, a first equation of time difference correction display (first S-curve in FIG. 6 ), and a second equational time difference correction mark (the second S-curve in FIG. 7) for correcting the solar time only during the period from the summer solstice to the winter solstice to standard time or average solar time on the second visual grid display. do. When the first S-curve and the second S-curve are put together, an 8-shaped curve is displayed.

Here, the equation of time is the difference between solar time and mean solar time, and the eccentricity of the elliptical orbit (the distance from the sun and the speed of revolution are different each time because the earth rotates in an elliptical orbit. Because of this, the angle at which it orbits during the same time is slightly different. It is known that the value is caused by the tilt of the earth's axis (up to ±3%) and the axis of rotation (the plane of Earth's orbit and its axis of rotation are not perpendicular, but are tilted by about 66.5 degrees). In other words, the change in the length of the solar day due to the eccentricity of the elliptical orbit and the inclination of the pole axis determines the change in the equation of time. If the solar day is longer than 24 hours, the noon time is delayed, and if it is short, it is early.

<Table> Seoul (126° 58′58″ east longitude) standard (Korea standard time) meridian time and equation time difference

When the solar time is noon, the sun is in the middle of the day, and the mean solar time at the standard meridian is the local standard time. Therefore, the equation of time is obtained by subtracting the time at which the sun is at its highest altitude on the standard meridian from 12 o'clock on the hour. If the time is earlier than noon, the equation of time is a (+) sign, and if it is later than noon, it is a (-) sign.

8 is a graph showing the equation of time, and the horizontal axis means the number of days that have elapsed since January 1, and as can be seen from FIG. It can be seen that it peaks at the earliest. The equation of time shows periodic changes, and after one year, the cumulative change from day to day is offset and the change returns to zero. Of course, in the long run, the equation of time may change due to changes in the earth's eccentricity, movement of the apogee and apogee, and change in the tilt of the axis of rotation.

9 is a conceptual diagram of an app capable of obtaining location information and true north information. When the app is executed on a user's smartphone terminal, the latitude and longitude of the current location are automatically calculated based on GPS information or base station information of the place where the user is located. It obtains the geomagnetic deviation of the place where the user is located by automatically accessing the website that provides the geomagnetic model again, and displays the latitude, longitude, and geomagnetic deviation obtained in this way on the screen of the app. In addition, these apps display these information together with a true north direction line on the compass, like a compass app that indicates magnetic north, that is, display the earth model and compass model on the app screen, but on the app screen, the latitude from the current location, Longitude, true north, magnetic north, and geomagnetic deviation are all displayed together, so that app users can increase the convenience of matching the sundial to true north. For example, if only the magnetic north of the compass part of the sundial is set, the sundial is adjusted to the true north direction, so that the app displays the direction of the magnetic north as well as the true north direction.

The Equation corrected display in the present invention has the basis of FIG. 8 as it is, but in order to secure user convenience and visibility even for a small sundial, the first Equation of time difference is corrected only for the period from the winter solstice to the summer solstice as shown in FIG. 6 A plurality of 'S'-shaped curves that are standard time or mean solar time, and a plurality of inverse 'S'-shaped curves that are standard time or mean solar time corrected for the second differential time difference for only the period from the summer solstice to the winter solstice, as shown in FIG. It is divided into ruler curves and displayed on the first hemisphere and the second hemisphere, respectively.

In addition, for the method of using or reading the standard time or mean solar time corrected for the first equation of time difference and the standard time or mean solar time corrected for the second equation of time difference, when the app or web described later is operated, automatically a smartphone or smart terminal It is also possible to provide a reading method or an explanation of the equation of time difference correction while displaying it in . In addition, the app can provide information about the season, good food and activities for that season, climate change, health care, and related history.

Meanwhile, the latitude and longitude of the reference position of the sundial of the present invention described above are set to the latitude and longitude of Seoul, Korea, and correspond to the latitude and longitude of the place where the user is located through the latitude correction unit and the longitude correction unit. Thus, it is possible to correct the latitude and longitude of the sundial.

In addition, the latitude correction unit, in a state in which the direction of the main body is guided in the north pole direction (true north direction) through the compass unit, by θ, which is the difference between the latitude of Seoul, Korea and the latitude of the place where the user is located, in the east-west direction The difference between the longitude of Seoul, Korea and the longitude of the place where the user is located, in a state in which the direction of the main body is guided to the North Pole through the compass. As much as Φ, the north-south direction is the axis, but it is allowed to rotate perpendicularly to the east-west direction.

At this time, an app execution unit (not shown) including a QR code provided on one side of the sundial may be further included. When a user shoots a QR code with a smartphone or smart terminal (iPad, etc.) and runs an app or web, the latitude and longitude information and geomagnetic deviation information of the smart terminal are automatically called from the app or web. come. In this case, if necessary, a consent process allowing access to the user's personal information may have to be preceded in the app or web. It is usually possible to give comprehensive consent to future information access only once.

In this way, the app executed by recognizing the QR code through the user's smartphone provides the user with the latitude and longitude of the place where the user is located, and in response to the latitude and longitude of the place where the user is located, the latitude correction unit and Guidance can be provided kindly and in detail on how to adjust the longitude correction unit and determine the true north of the sundial according to the geomagnetic deviation. If you follow the instructions in the app, you can correct the latitude and longitude by the difference between the latitude and longitude of Seoul, South Korea, which is the standard.

Specifically, as an embodiment of the latitude corrector and the longitude corrector, the latitude corrector adjusts the height for latitude correction provided in the lower south and lower north parts of the main body so as to rotate vertically in the north-south direction while using the east-west direction as an axis. It is composed of a portion, the hardness correction unit, but the north-south direction as an axis, but can be composed of a height adjustment for hardness correction provided in the lower east and lower west of the main body portion so that it can be rotated vertically with respect to the east-west direction.

For example, the height adjustment unit for latitude correction can be adjusted in height by installing a plurality of wedge-shaped supports having different specifications, or by screw rotation (nails, etc.), and the user It is desirable to display the adjusted height on the surface of the screw in a color band with good visibility so that it can be confirmed that the height is adjusted to the height suggested through the app.

It is also possible to adopt and provide the latitude and longitude of the region most similar to the place where the user is located, in a state where the latitude and longitude of major cities in Korea are organized in advance in a server or database linked to the app or web. Alternatively, the latitude and longitude can be corrected by adjusting the height so that the main latitude and longitude of Korea can be adjusted by 0.5 degree or 1 degree, and the color is different for each height, so that the corresponding color appears. Through this, user convenience can be improved when latitude correction and longitude correction are performed through a display having good visibility to the user. It is also possible to provide a color indicator with good visibility in the same color on the app so that the user can intuitively recognize it.

In addition, in the app, when providing guidance on the adjustment of the latitude corrector and the longitude corrector, (1) wedge type and (2) two types of latitude correction and longitude correction through adjusting the vertically protruding screw It is possible to guide by type.

First, looking at the wedge type, the difference between the height control unit between the lower southern part and the lower northern part of the main body is θ, which is the difference between the latitude of Seoul, Korea and the latitude of the place where the user is located. A wedge that satisfies the following Equation 1-1 will support That is, a wedge-shaped support for latitude correction having a height of h1 and an angle of one wedge of θ is supported below.

[Equation 1-1]

h1 = d1 sin θ

Here, d1 is the distance between the lower south and lower north height control units of the main body and is the length of the hypotenuse of the wedge for latitude correction, and h1 is the height of the wedge for latitude correction.

In addition, when the difference between the height control unit between the lower east side and the lower west side of the main body is Φ, which is the difference between the longitude of Seoul, Korea and the longitude of the place where the user is located, receive a wedge for hardness correction that satisfies the following Equation 2-1 will hit That is, a wedge-shaped support for hardness correction having a height of h2 and an angle of one wedge of Φ is supported below.

[Equation 2-1]

h2 = d2 sin Φ

d2 is the distance between the lower east and lower west height adjusting parts of the main body and is the length of the oblique side of the wedge for hardness correction, and h2 is the height of the wedge for hardness correction.

Latitude and longitude are corrected together by stacking the wedges for latitude correction and the wedges for longitude correction on top and bottom of each other.

Next, latitude correction and longitude correction through the adjustment of the vertically protruding screw will be described.

In the app, when providing guidance on the adjustment of the latitude corrector and the longitude corrector, the difference between the height adjuster between the lower south and lower north of the main body is between the latitude of Seoul, Korea and the latitude of the place where the user is located. Corresponds to the difference θ, but adjusts according to Equation 1-2 below.

[Equation 1-2]

k1 = d1 tan θ

Here, d1 is the distance between the height adjusting parts of the lower south part and the lower part of the north part of the body part, and k1 is the height difference between the height adjusting part of the lower part of the south part and the lower part of the north part of the main body part. is the length of the protruding screw.

In addition, the difference between the eastern lower part and the western lower part of the main body corresponds to Φ, which is the difference between the longitude of Seoul, Korea and the longitude of the place where the user is located, and is adjusted according to Equation 2-2 below.

[Equation 2-2]

k2 = d2 tan Φ

d2 is the distance between the height adjusting parts of the lower eastern part and the lower western part of the body part, and k2 is the height difference between the height adjusting part of the lower part of the eastern part and the lower western part of the main body part. is the length of the screw

As described above, such height adjustment is guided so that even beginners can easily follow for user convenience through an app or the web.

As described above, although the present invention has been described by the limited embodiments and drawings, the present invention is not limited thereto, and the technical spirit of the present invention and the following by those skilled in the art to which the present invention belongs Of course, various modifications and variations are possible within the scope of equivalents of the claims to be set forth.

Claims (9)

A sundial that corrects latitude and longitude according to a location where a user is located and provides equational time difference correction,
A first needle that faces the North Pole and can provide the movement of the shadow according to the movement of the sun in order to provide visual information during the period from the winter solstice to the summer solstice; a concave first hemisphere on which a first visual display capable of checking visual information during a period from the winter solstice to the summer solstice is displayed on the surface using the position of the shadow of the first needle; A first hemisphere including a first seasonal season display unit displaying solar terms from the winter solstice to the summer solstice on one side or both sides of an edge surface of the first hemisphere;
a second needle pointing toward the north pole and capable of providing the movement of the shadow according to the movement of the sun in order to provide visual information during the period from the summer solstice to the winter solstice; a concave second hemisphere on which a second visual display capable of checking visual information during a period from the summer solstice to the winter solstice is displayed on the surface using the position of the shadow of the second needle; A second hemisphere including a second seasonal season display unit displaying solar terms from the summer solstice to the winter solstice on one side or both sides of an edge surface of the second hemisphere;
a main body connecting the first hemisphere and the second hemisphere and providing an entire frame of the sundial;
a compass unit located on one side of the main body unit and capable of inducing adjustment of the direction of the main body unit so that the first needle and the second needle face the North Pole;
a latitude correction unit configured to adjust a latitude according to a location where the user is located in a state in which the direction of the main body is directed toward the north pole; and
In a state in which the direction of the main body is guided in the direction of the North Pole, a hardness correction unit configured to correct the hardness according to the place where the user is located; including,
sundial.
According to claim 1,
On the first hemispherical surface, a first time display capable of knowing the standardized time of the reference position; and displaying the incisor line only during the period from the winter solstice to the summer solstice;
On the second hemispherical surface, a second time display capable of knowing the standardized time of the reference position; Characterized in that it includes,
sundial.
According to claim 2,
The latitude and longitude of the reference position of the sundial are set to the latitude and longitude of Seoul, Korea,
Through the latitude correction unit and the longitude correction unit, it is possible to correct the latitude and longitude of the sundial in correspondence with the latitude and longitude of the place where the user is located.
sundial.
According to claim 3,
The latitude correction unit, in a state in which the direction of the main body is guided in the direction of the North Pole through the compass, the east-west direction is the axis by θ, which is the difference between the latitude of Seoul, Korea and the latitude of the place where the user is located, but with respect to the north-south direction to rotate vertically,
The longitude correction unit, in a state in which the direction of the main body is guided to the north pole through the compass, the north-south direction is the axis as much as Φ, which is the difference between the longitude of Seoul, Korea and the longitude of the place where the user is located, but with respect to the east-west direction Characterized in that it can be rotated vertically,
sundial.
According to claim 4,
An app execution unit including a QR code provided on one side of the sundial; further comprising,
The app executed by QR code recognition through the user's smartphone provides the latitude and longitude and geomagnetic deviation of the place where the user is located, and the latitude correction unit and the longitude correction unit correspond to the latitude and longitude. Characterized in that it provides guidance on adjustment and determining the true north of the sundial according to the geomagnetic deviation,
sundial.
According to claim 5,
The latitude correction unit is composed of a height adjustment unit for latitude correction that protrudes vertically provided in the lower south and lower north parts of the main body, which has an axis in the east-west direction but can rotate vertically with respect to the north-south direction,
Characterized in that the hardness correction unit is composed of a height adjustment unit for hardness correction provided at the lower east and lower west parts of the main body, which rotates vertically with respect to the north-south direction but vertically with respect to the east-west direction.
sundial.
According to claim 6,
If the difference between the lower south and lower north parts of the main body is θ, which is the difference between the latitude of Seoul, Korea and the latitude of the place where the user is located,
Latitude correction is performed by supporting a wedge-shaped base for latitude correction having a height of h1 but having an angle of θ on one side of the wedge, and the latitude correction wedge satisfies the following Equation 1-1,
[Equation 1-1]
h1 = d1 sin θ
Here, d1 is the distance between the height adjusting parts of the lower south and lower north parts of the main body and is the length of the hypotenuse of the wedge for latitude correction, h1 is the height of the wedge for latitude correction,
When the difference between the height adjusting part between the lower east part and the lower part of the west part of the body part is Φ, which is the difference between the longitude of Seoul, Korea and the longitude of the place where the user is located,
A wedge-shaped support for hardness correction having a height of h2 and an angle of one wedge of Φ is supported below, and the wedge for hardness correction satisfies the following Equation 2-1,
[Equation 2-1]
h2 = d2 sin Φ
d2 is the distance between the height adjusting parts of the lower east and lower west parts of the main body and is the length of the hypotenuse of the wedge for hardness correction, h2 is the height of the wedge for hardness correction,
Characterized in that the latitude correction wedge and the longitudinal correction wedge are laminated above and below,
sundial.
According to claim 6,
In the app, when providing guidance on the adjustment of the latitude correction unit and the longitude correction unit,
The difference between the lower southern part and the lower northern part of the body part corresponds to θ, which is the difference between the latitude of Seoul, Korea and the latitude of the place where the user is located, according to the following Equation 1-2,
[Equation 1-2]
k1 = d1 tan θ
d1 is the distance between the lower south and lower north height adjusting parts of the main body, k1 is the height difference between the lower south and lower northern height adjusting parts of the main body,
The difference between the eastern lower part and the western lower part of the body part corresponds to Φ, which is the difference between the longitude of Seoul, Korea and the longitude of the place where the user is located, according to the following Equation 2-2,
[Equation 2-2]
k2 = d2 tan Φ
d2 is the distance between the height adjustment parts of the lower east and lower west parts of the main body, and k2 is the height difference between the height adjustment parts of the lower east and lower west parts of the main body,
sundial.
According to claim 8,
The height adjusting unit is capable of adjusting the height through screw rotation, and the user can confirm that the height is adjusted to the height presented through the app. characterized by,
sundial.

Images