KR102165301B1 - Program for monitoring tatoo work - Google Patents

Abstract

The present invention relates to a program for monitoring, and more specifically, a needle cartridge connected to a handpiece of a tattoo device that moves ink into the skin for tattoo work, by grasping the position of the needle correlated with the skin in real time, It relates to a tattoo work monitoring program that can make tattoo work possible.
To this end, the present invention measures the position of the tattoo needle in a tattoo device equipped with a tattoo needle moving in a straight line to monitor the tattoo work, the initial needle position measurement of measuring the initial position (ⓝ) of the tattoo needle on a computer Step and; A maximum needle movement distance calculation step of calculating a maximum movement distance (ⓚ) of the tattoo needle; A needle insertion depth setting step of setting a depth (ⓜ) at which the tattoo needle is inserted into the skin based on the initial position (ⓝ) and the maximum movement distance (ⓚ) of the tattoo needle; It characterized in that executing; a needle monitoring step of monitoring the position information of the tattoo needle in real time during tattoo work.

Description

Tattoo work monitoring program {PROGRAM FOR MONITORING TATOO WORK}

The present invention relates to a program for monitoring, and more specifically, a needle cartridge connected to a handpiece of a tattoo device that moves ink into the skin for tattoo work, by grasping the position of the needle correlated with the skin in real time, It relates to a tattoo work monitoring program that can make tattoo work possible.

In general, a tattoo refers to injuring the skin or subcutaneous tissue and engraving letters, drawings, and patterns with pigment. The tattoo work for this is moved while piercing the tattoo pigment into the human skin with a tattoo needle to a certain depth. So that a predetermined shape is expressed on the human skin according to the intention of the operator.

At this time, when the practitioner pierces the tattoo needle to a certain depth, especially when piercing a blood vessel in the skin, bleeding occurs, and the bleeding forms a scab on the skin, and then when the scab falls off the skin, it falls like a tattoo pigment in the skin. However, there is a problem that the tattoo is not properly formed, so additional work has to be done.

In this way, if the tattoo needle is pierced beyond a certain depth of the skin, effective tattoo work cannot be performed. In order to prevent this problem in advance, the position of the needle is identified during tattoo work to enable elaborate and safe tattooing. There is a need for research to do so.

Korean Patent Publication No. 10-1781309 Korean Registered Patent Publication No. 10-1805063

The present invention was conceived to solve the problems of the prior art, and by measuring the position of a tattoo needle penetrating the skin in real time in a needle cartridge of a tattoo device that injects ink into the skin through tattoo work, the needle Its purpose is to provide a tattoo work monitoring program that allows precise and safe tattoo work to be performed by not piercing more than a certain depth of the body.

In order to achieve the above object, the present invention measures the initial position (ⓝ) of the tattoo needle on a computer in order to monitor the tattoo work by measuring the position of the tattoo needle in a tattoo device equipped with a tattoo needle moving in a straight line. Measuring the initial needle position; A maximum needle movement distance calculation step of calculating a maximum movement distance (ⓚ) of the tattoo needle; A needle insertion depth setting step of setting a depth (ⓜ) at which the tattoo needle is inserted into the skin based on the initial position (ⓝ) and the maximum movement distance (ⓚ) of the tattoo needle; A needle monitoring step of real-time monitoring of the position information of the tattoo needle during tattoo work; a needle position information storage step of storing real-time position information of the tattoo needle obtained in the needle monitoring step; The needle position information transmission step of analyzing the real-time position information of the tattoo needle stored in the needle position information storage step and transmitting it to the outside; further execute, the tattoo device is a handpiece (H), the handpiece (H) A cam (K) that is installed inside to convert the rotational movement into a linear movement, a shaft (S) having one side fixed to the cam (K) and moving straight forward in the handpiece (H), and the handpiece (H ), and a needle cartridge (C) equipped with a tattoo needle connected to the shaft (S) and connected to the shaft (S), and a position detection sensor (ⓢ) for checking the position of the tattoo needle of the needle cartridge (C), In the needle position information transmission step, the position of the tattoo needle is determined as a normal level according to Equation 1 below.
Equation 1: ⓛ ≤ ⓝ+ⓚ-ⓜ
(Ⓛ is the distance from the skin to the position sensor (ⓢ), ⓝ is the initial position of the tattoo needle, ⓚ is the maximum travel distance of the tattoo needle, and ⓜ is the set depth at which the tattoo needle is inserted into the skin)

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In particular, in the needle position information transmission step, the tattoo needle position is determined as an attention level and a warning level, respectively, according to Equations 2 and 3 below.

Equation 2: ⓛ ≤ ⓝ+ⓚ-ⓟ

Equation 3: ⓛ ＜ ⓝ+ⓚ-ⓟ

(Ⓛ is the distance from the skin to the position sensor (ⓢ), ⓝ is the initial position of the tattoo needle, ⓚ is the maximum travel distance of the tattoo needle, ⓜ is the set depth at which the tattoo needle is inserted into the skin, ⓟ is the tattoo Is the limited depth at which the needle is inserted into the skin)

In addition, the tattoo device further includes an LED module that emits light corresponding to the position of the tattoo needle, and when the position of the tattoo needle is determined to be a warning level in the step of transmitting the needle position information, the LED module emits light, and the step of storing the needle position information Is characterized in that real-time tattoo needle location information is stored in a separate monitoring server, and in the needle location information transmission step, data obtained by analyzing real-time location information of the stored tattoo needle is transmitted to a tattoo device user terminal.

Since the tattoo operation monitoring program according to the present invention as described above can prevent the situation where the operator pierces the tattoo needle beyond a certain depth of the skin by notifying the operator by grasping the position change of the needle through a sensor in real time during tattoo operation, It can be a great help in getting a detailed and stable tattoo on the skin.

1 is a flow chart showing an embodiment of a tattoo operation monitoring method according to the present invention.
Figure 2 is a diagram schematically showing the principle of measuring the position of the tattoo needle of the tattoo device through the present invention.

The terms or words used in this specification and claims should not be construed as being limited to their usual or dictionary meanings, and the inventor may appropriately define the concept of terms in order to describe his own invention in the best way. It should be interpreted as a meaning and concept consistent with the technical idea of the present invention based on the principle that there is.

Accordingly, the embodiments described in the present specification and the configurations shown in the drawings are only the most preferred embodiments of the present invention, and do not represent all the technical ideas of the present invention, so that they can be replaced at the time of application It should be understood that there may be various equivalents and variations.

Hereinafter, a tattoo operation monitoring program according to the present invention will be described with reference to the drawings.

1 is a flow chart showing an embodiment of a tattoo work monitoring method according to the present invention, Figure 2 is a diagram schematically showing the principle of measuring the position of the tattoo needle of the tattoo device through the present invention.

The present invention is a program stored in a computer-readable recording medium in order to monitor tattoo work by measuring the position of the tattoo needle in a tattoo device equipped with a tattoo needle that moves in a straight line, the initial needle position measuring step in the computer, It includes the step of calculating the maximum needle travel distance, the step of setting the needle insertion depth, and the step of monitoring the needle.

More specifically, the present invention provides an initial needle position measurement step of measuring the initial position (ⓝ) of the tattoo needle, a needle maximum travel distance calculation step of calculating the maximum travel distance (ⓚ) of the tattoo needle, and the initial position of the tattoo needle. And a needle insertion depth setting step of setting a depth (ⓜ) at which the tattoo needle is inserted into the skin based on the maximum moving distance, and a needle monitoring step of monitoring position information of the tattoo needle in real time during tattoo work.

Looking at an example of the structure of the tattoo device used in the present invention, a handpiece (H) held by a practitioner for tattoo work, and a handpiece (H) are installed inside the upper side so that the rotational motion can be converted into a straight motion. Includes a cam (K), a shaft (S) that is fixed to the cam (K) on one side and moves straight in the handpiece, and a tattoo needle detachably installed on the handpiece (H) and connected to the shaft (S). It is configured to include a needle cartridge (C) and a position sensor (ⓢ) for checking the position of the tattoo needle of the needle cartridge (C).

First, in the initial needle position measurement step, the initial position (ⓝ) of the tattoo needle is checked, and basic information related to the formula for calculating the tattoo needle movement distance described in detail below is checked. The tattoo needle length itself is determined in advance. As it is interlocked with the cam (K) and shaft (S), by indirectly checking the position change of the cam (K) and shaft (S) through a conventionally known sensing technology or by checking the direct position change of the tattoo needle. The initial position (ⓝ) of the tattoo needle can be derived.

In the step of calculating the maximum needle travel distance, the maximum travel distance (ⓚ) of the tattoo needle in proportion to the movement distance of the cam (K) and the shaft (S) is calculated, and the maximum travel distance (ⓚ) of the tattoo needle is the tattoo needle It is used as data to measure the real-time movement distance of the tattoo needle along with the initial position of (ⓝ).

The needle insertion depth setting step is to set the depth of the tattoo needle inserted into the skin to a normal level for tattooing in consideration of different skin thickness for each person, and the initial position (ⓝ) and the maximum travel distance (ⓚ) of the tattoo needle are After confirmation, the depth at which the tattoo needle is inserted into the skin is set according to the skin thickness that may vary from person to person.

For reference, prior to setting the depth (ⓜ) at which the tattoo needle is inserted into the skin in the needle insertion depth setting step, each individual penetrates the tattoo needle into the skin little by little and checks the skin thickness at which the tattoo needle can be pierced at a normal level. The process can follow.

The needle monitoring step is a process of real-time monitoring of the location information of the tattoo needle according to the initial position (ⓝ) of the tattoo needle, the maximum travel distance (ⓚ), and the set depth (ⓜ) at which the tattoo needle is inserted into the skin during tattoo work, The presence or absence of an abnormality in the cam (K), shaft (S), and needle cartridge (C) can be inferred simply by monitoring the location information of the tattoo needle alone.

In addition, the present invention provides a needle position information storage step for storing real-time position information of the tattoo needle acquired in the needle monitoring step, and a needle position for analyzing and transmitting the real-time position information of the tattoo needle stored in the needle position information storage step. It may include an information transmission step.

In the needle location information storage step, real-time tattoo needle location information can be stored as a database in a recording medium such as a memory or a hard disk, or a separate monitoring server, and the tattoo needle location information stored in this way is basically While it is confirmed as data for precise location analysis, follow-up processes such as correcting the tattoo needle position or artificially suggesting the desired tattoo needle position through analysis methods such as machine learning and data mining based on these past and present data. You might be able to get this done.

In the needle location information transmission step, the data obtained by analyzing real-time location information of the tattoo needle stored through the needle location information storage step is transmitted to an external terminal such as a tattoo device user terminal or to a specific server, whereby the tattoo operator correctly damages the skin. You can make it possible to check yourself if you are doing tattoo work without it.

In particular, in the needle position information transmission step, the tattoo needle position may be determined as a normal level, an attention level, or a warning level, respectively, according to Table 1 and Equations 1 to 3 below, and a detailed description thereof is as follows.

Classification Justice Remark Ⓝ Initial position of tattoo needles Constant, given Ⓚ Tattoo needle travel distance Constant, given Ⓛ Distance from skin to location sensor (ⓢ) Variable, sensor value Ⓜ Set depth at which tattoo needles are inserted into the skin Variable, user configurable Ⓟ Limited depth at which tattoo needles are inserted into the skin Variable, user configurable

<If the position of the tattoo needle is judged to be the normal level>

-The distance from the skin to the position sensor (ⓢ) is less than the sum of the initial position (ⓝ) of the tattoo needle and the maximum travel distance (ⓚ) of the tattoo needle minus the set depth (ⓜ) at which the tattoo needle is inserted into the skin. Is equal to

Equation 1: ⓛ ≤ ⓝ+ⓚ-ⓜ

-Referring to FIG. 2, the level at which the tattoo needle penetrates between the skin surface and the set depth (ⓜ) at which the tattoo needle is inserted into the skin is determined as a normal level.

<When judging the position of the tattoo needle as the level of attention>

-The distance from the skin to the position sensor (ⓢ) is less than the sum of the initial position (ⓝ) of the tattoo needle and the maximum travel distance (ⓚ) of the tattoo needle, minus the limit depth (ⓟ) at which the tattoo needle is inserted into the skin. Is equal to or equal to, and the limiting depth (ⓟ) at which the tattoo needle is inserted into the skin is greater than the set depth (ⓜ) at which the tattoo needle is inserted into the skin

Equation 2: ⓛ ≤ ⓝ+ⓚ-ⓟ

-Referring to FIG. 2, the level of penetration of the tattoo needle to the limited depth (ⓟ) at which the tattoo needle is inserted into the skin beyond the skin surface and the set depth (ⓜ) at which the tattoo needle is inserted into the skin is judged as a caution level.

<When judging the position of the tattoo needle as a warning level>

-The distance from the skin to the position sensor (ⓢ) is less than the sum of the initial position (ⓝ) of the tattoo needle and the maximum travel distance (ⓚ) of the tattoo needle, minus the limit depth (ⓟ) at which the tattoo needle is inserted into the skin. The depth limit (ⓟ) at which the tattoo needle is inserted into the skin is larger than the set depth (ⓜ) at which the tattoo needle is inserted into the skin.

Equation 3: ⓛ ＜ ⓝ+ⓚ-ⓟ

-Referring to FIG. 2, the level of penetration through the skin surface, the set depth at which the tattoo needle is inserted into the skin (ⓜ), and the limited depth (ⓟ) at which the tattoo needle is inserted into the skin is judged as a warning level.

As the tattoo needle position level information based on the calculated data of Equations 1 to 3 as described can be transmitted to the tattoo device user terminal, it is possible to prevent a situation in which a practitioner pierces the tattoo needle beyond a certain depth of the skin, and It can make it possible to stably get a tattoo on the skin.

On the other hand, when the position of the tattoo needle is determined as a normal level, a caution level, or a warning level in the needle location information transmission step, in particular, when the tattoo needle location is determined as a warning level, the tattoo needle penetrates the skin at a warning level by the operator. In order to easily check a situation, the tattoo device used in the present invention may further include an LED module that emits light in response to the position of the tattoo needle.

Therefore, when the tattoo needle pierces the skin at a warning level when the operator performs a tattoo work, the LED module emits light, so that the operator can be notified of this situation immediately.

Of course, by allowing the LED module to emit a color corresponding to each of the normal level, attention level, and warning level in the tattoo needle position, the operator can easily identify the tattoo needle position for each level, and a visual LED module is used. In addition to the method, the position of the tattoo needle in relation to the skin could be identified by an audible method that generates different sounds for each level through a speaker.

In the description of the present invention with reference to the accompanying drawings above, a specific shape and direction have been described, but the present invention can be variously modified and changed by those skilled in the art, and such modifications and changes are included in the scope of the present invention. Should be interpreted as.

Claims (10)

An initial needle position measuring step of measuring the initial position (ⓝ) of the tattoo needle on a computer in order to monitor the tattoo work by measuring the position of the tattoo needle in a tattoo device equipped with a tattoo needle moving straight forward; A maximum needle movement distance calculation step of calculating a maximum movement distance (ⓚ) of the tattoo needle; A needle insertion depth setting step of setting a depth (ⓜ) at which the tattoo needle is inserted into the skin based on the initial position (ⓝ) and the maximum movement distance (ⓚ) of the tattoo needle; Performing a needle monitoring step of real-time monitoring of the location information of the tattoo needle during tattoo work;
A needle position information storage step of storing real-time position information of the tattoo needle acquired in the needle monitoring step;
The needle position information transmission step of analyzing the real-time position information of the tattoo needle stored in the needle position information storage step and transmitting it to the outside; is further executed,
The tattoo device includes a hand piece (H), a cam (K) installed in the hand piece (H) to convert a rotational movement into a straight movement, and one side is fixed to the cam (K) and the handpiece (H ), a needle cartridge (C) provided with a shaft (S) moving in a straight line, a tattoo needle detachably installed on the handpiece (H) and connected to the shaft (S), and the needle cartridge (C) It includes a location sensor (ⓢ) to check the position of the tattoo needle,
In the needle position information transmission step, a tattoo work monitoring program stored in a computer-readable recording medium, characterized in that the position of the tattoo needle is determined to be a normal level according to Equation 1 below.
Equation 1: ⓛ ≤ ⓝ+ⓚ-ⓜ
(Ⓛ is the distance from the skin to the position sensor (ⓢ), ⓝ is the initial position of the tattoo needle, ⓚ is the maximum travel distance of the tattoo needle, and ⓜ is the set depth at which the tattoo needle is inserted into the skin)
delete delete delete delete The method according to claim 1,
In the needle position information transmission step, a tattoo work monitoring program, characterized in that the position of the tattoo needle is determined as a caution level according to Equation 2 below.
Equation 2: ⓛ ≤ ⓝ+ⓚ-ⓟ
(Ⓛ is the distance from the skin to the position sensor (ⓢ), ⓝ is the initial position of the tattoo needle, ⓚ is the maximum travel distance of the tattoo needle, and ⓟ is the limited depth at which the tattoo needle is inserted into the skin)
The method according to claim 1,
In the needle position information transmission step, a tattoo work monitoring program, characterized in that the position of the tattoo needle is determined as a warning level according to Equation 3 below.
Equation 3: ⓛ ＜ ⓝ+ⓚ-ⓟ
(Ⓛ is the distance from the skin to the position sensor (ⓢ), ⓝ is the initial position of the tattoo needle, ⓚ is the maximum travel distance of the tattoo needle, and ⓟ is the limited depth at which the tattoo needle is inserted into the skin)
The method of claim 7,
The tattoo device further comprises an LED module that emits light corresponding to the position of the tattoo needle,
When the position of the tattoo needle is determined to be a warning level in the needle position information transmission step, the LED module emits light.
The method according to claim 1,
In the needle location information storage step, tattoo work monitoring program, characterized in that the real-time tattoo needle location information is stored in a separate monitoring server.
The method according to claim 1,
In the needle location information transmission step, a tattoo work monitoring program, characterized in that the data obtained by analyzing the stored real-time location information of the tattoo needle are transmitted to a tattoo device user terminal.

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