KR20190045691A - Apparatus for caffeine detection - Google Patents

Abstract

The present invention relates to a caffeine measurement device capable of shortening the time required for measurement. According to an embodiment of the present invention, the caffeine measurement device comprises: a sample stage receiving a sample which is a part of beverage whose caffeine content is measured; a sample light output unit emitting light to the sample; a base stage storing a base material for calibrating a spectrum of light emitted from the sample by the light emitted to the sample; a base light output unit emitting light to the base material; a sample detector detecting a wavelength band corresponding to caffeine included in the sample from the spectrum of the light emitted from the sample by the light emitted to the sample; a base detector detecting the wavelength band from the spectrum of the light emitted from the base material by the light emitted to the base material; and a data processing unit calculating the content of the caffeine included in the sample based on the wavelength band corresponding to the caffeine detected by the sample detector and the wavelength band detected by the base detector.

Description

APPARATUS FOR CAFFEINE DETECTION

The present invention relates to an apparatus for measuring caffeine.

Coffee has a lot of advantages such as relieving fatigue, eliminating nephews through diuretic action, removing oxygen free radicals, tinnitus, promoting blood circulation and suppressing appetite, but consumers may be exposed to caffeine side effects by eating without accurate caffeine content information. Thus, a convenient and reliable system for consumers to determine the content of caffeine may be required. Accordingly, various types of caffeine measuring devices can be used. Here, a caffeine measuring apparatus using a spectroscope can be used.

However, in general, a caffeine measuring device using a spectrometer requires a measurement of the base spectrum to calibrate the zero point prior to measuring the spectrum of the caffeine-containing beverage (hereinafter, "sample") in constructing the data for calculating the caffeine content . Therefore, a predetermined time for measuring the base spectrum may be consumed.

In addition, a typical caffeine measuring device may inconveniently wipe the bowl containing the coffee after a single measurement.

In general, a caffeine measuring apparatus using a spectroscope may require a wavelength selector to output a light source in the form of a spectrum including a predetermined wavelength region when irradiating a light source with a sample, and then to select a specific wavelength suitable for caffeine measurement . Therefore, the cost to include a wavelength selector may be required in manufacturing a caffeine measuring apparatus using a spectroscope.

Accordingly, it is necessary to shorten the time consumed and reduce the inconvenience in order to measure the caffeine amount contained in the sample.

In addition, it is necessary to lower the unit price in manufacturing the caffeine measuring device.

Korean Patent Registration No. 10-0990841 (Oct. 25, 2010)

It is an object of the present invention to provide a caffeine measuring device in which the time consumed to measure the caffeine amount contained in the sample is shortened and the inconvenience is reduced.

Another object of the present invention is to provide an apparatus for measuring caffeine which has lowered the unit cost in manufacturing.

A caffeine measuring apparatus according to an embodiment of the present invention includes a sample stage for receiving a sample which is a part of a beverage to be measured for a caffeine content, a sample light output section for irradiating the sample with light, A base stage for receiving a base material for zero point correction of a spectrum of emitted light, a base light output section for emitting light to the base material, A base detector for detecting the wavelength band of the spectrum of the light emitted by the base material by the light emitted by the base material, and a base detector for detecting the wavelength band corresponding to the caffeine contained in the sample, The wavelength band corresponding to the caffeine and the wavelength band detected by the base detector Based on a data processing unit for calculating the amount of caffeine contained in the sample.

Wherein the sample light output section starts to irradiate the sample with light after a predetermined time from a time point at which the base light output section starts to irradiate the base material with light, and the data processing section causes the sample detector to irradiate the caffeine contained in the sample It may begin to calculate the caffeine content contained in the sample at the same time as it begins to sense the corresponding wavelength band.

The caffeine measuring apparatus includes a sample stage and a cleaning gas discharging unit provided on one side of the base stage for spraying the cleaning gas into the sample stage and the base stage, And a discharge unit for discharging the sample and the base material, which are pushed by the cleaning gas, to the outside.

The caffeine measuring apparatus may further include a mesh network installed at an inlet of the discharge unit on the movement path of the sample and the base material pushed by the cleaning gas.

Wherein the caffeine measuring device further comprises a rinse solution discharging portion for rinsing the sample stage and the base stage by injecting a rinse solution into the sample stage and the base stage, The cleaning gas may be injected so that the cleaning liquid flows into the discharge portion.

The sample stage and one side of the base stage and the other side of the sample stage and the base stage may be formed to be inclined, respectively.

The effect of the caffeine measuring device according to the present invention will be described below.

According to at least one of the embodiments of the present invention, it is possible to shorten the time consumed and reduce the inconvenience in order to measure the caffeine amount contained in the sample.

Further, according to at least one of the embodiments of the present invention, the unit cost can be lowered in manufacturing the caffeine measuring device.

1 is a perspective view showing a caffeine measuring apparatus according to an embodiment of the present invention;
2 is a block diagram for explaining a caffeine measuring apparatus according to an embodiment of the present invention.
3 is a schematic view for explaining the cleaning of the caffeine measuring device according to the embodiment of the present invention
FIG. 4 is a flow chart for explaining a process of measuring a caffeine content through a caffeine measuring apparatus according to an embodiment of the present invention
5 is a block diagram illustrating and illustrating a computing environment including a computing device suitable for use in the exemplary embodiments.

Hereinafter, specific embodiments of the present invention will be described with reference to the drawings. The following detailed description is provided to provide a comprehensive understanding of the methods, apparatus, and / or systems described herein. However, this is merely an example and the present invention is not limited thereto.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following description, well-known functions or constructions are not described in detail since they would obscure the invention in unnecessary detail. The following terms are defined in consideration of the functions of the present invention, and may be changed according to the intention or custom of the user, the operator, and the like. Therefore, the definition should be based on the contents throughout this specification. The terms used in the detailed description are intended only to describe embodiments of the invention and should in no way be limiting. Unless specifically stated otherwise, the singular form of a term includes plural forms of meaning. In this description, the expressions " comprising " or " comprising " are intended to indicate certain features, numbers, steps, operations, elements, parts or combinations thereof, Should not be construed to preclude the presence or possibility of other features, numbers, steps, operations, elements, portions or combinations thereof.

In the following description, terms such as " transmission ", " transmission ", " transmission ", " reception ", and the like, of a signal or information refer not only to the direct transmission of signals or information from one component to another But also through other components. In particular, "transmitting" or "transmitting" a signal or information to an element is indicative of the final destination of the signal or information and not a direct destination. This is the same for " reception " of a signal or information. Also, in this specification, the fact that two or more pieces of data or information are " related " means that when one piece of data (or information) is acquired, at least a part of the other data (or information) can be obtained based thereon.

On the other hand, directional terms such as the top, bottom, one side, the other, and the like are used in connection with the orientation of the disclosed figures. Since the elements of the embodiments of the present invention can be positioned in various orientations, directional terms are used for illustrative purposes and not limitation.

Also, the terms first, second, etc. may be used to describe various components, but the components should not be limited by the terms. The terms may be used for the purpose of distinguishing one component from another. For example, without departing from the scope of the present invention, the first component may be referred to as a second component, and similarly, the second component may also be referred to as a first component.

FIG. 1 is a perspective view showing a caffeine measuring apparatus according to an embodiment of the present invention, and FIG. 2 is a block diagram for explaining a caffeine measuring apparatus according to an embodiment of the present invention.

1 and 2, the caffeine measuring apparatus 100 includes a sample unit 110, a light output unit 120, a detector unit 130, a data processing unit 140, a user input unit 150, and an output unit 160 < / RTI >

Specifically, the caffeine measuring apparatus 100 includes a sample portion 110 for receiving a sample, a light output portion 120 for irradiating the sample with light, a detector 130 for sensing light emitted from the sample, A data processing unit 140 for calculating a total caffeine content included in the beverage based on the total amount of the input beverage, a user input unit 150 for inputting the total amount of the beverage by the user, and an output Unit 160 may be included.

The sample unit 110 may be formed in the main body of the caffeine measuring apparatus 100. For example, the sample portion 110 may be formed on the upper surface of the caffeine measuring device 100. The sample portion 110 may include a sample stage 112 for receiving a portion of the beverage for which the user wishes to measure the total caffeine content. That is, a portion of the beverage can be contained in the sample stage 112 as a sample. The sample stage 112 has a space for receiving a portion (i.e., a sample) of the beverage. For example, the volume of the sample stage 112 may be about 1-2 ml. The sample stage 112 may be replaceably mounted on the sample portion 110. In this case, it is possible to mount the sample stage 112 having a receiving space of various volumes according to the sample to be measured.

In addition, the sample portion 110 may include a base stage 114 for receiving a predetermined base material (e.g., water, etc.). The base stage 114 may have the same volume of space as the sample stage 112. The base stage 114 may receive a base material of the same volume as the sample contained in the sample stage 112. The base material may be a material that is measured to calibrate the zero point of the spectrum of light emitted by the sample. The base stage 114 may be replaceably mounted on the sample portion 110.

Thereafter, the caffeine amount contained in the sample corresponding to the volume of the sample stage 112 can be measured. The caffeine content can be calculated by comparing the measured caffeine dose with the volume of the sample stage.

The light output unit 120 may be provided to output light to the sample unit 110. Specifically, the light output unit 120 may include a base light output unit 122 and a sample light output unit 124. The base light output unit 122 and the sample light output unit 124 may be provided inside the caffeine measurement apparatus 100, respectively. The base light output portion 122 may be provided to irradiate light with the base material accommodated in the base stage 114.

 The sample light output section 124 can irradiate light to the sample accommodated in the sample stage 112.

Here, the base light output unit 122 and the sample light output unit 124 may emit light in a spectral form including a predetermined wavelength range including a lamp. The wavelength range of the light emitted from the base light output section 122 and the sample light output section 124 may be the same.

The light output unit 120 further includes a wavelength selector for selecting only a single light beam of a single wavelength in the spectral form so as to irradiate the sample with only a wavelength (constant monochromatic light) suitable for detecting caffeine contained in the sample .

Alternatively, the base light output section 122 and the sample light output section 124 may include a laser emitting only a single monochromatic light of a single wavelength. In this case, the optical output unit 120 does not need a wavelength selector for selecting only a single light beam of a single wavelength in the spectral light.

On the other hand, the sample light output section 124 has the same wavelength range as that of the base light output section 122 and the detector section 130, but the base light output section 122 starts to irradiate light with the base material It is possible to start irradiating the sample with light at a predetermined time difference. Accordingly, the detection of the sample detector 134 may start later than the detection of the base detector 132 in correspondence with the predetermined time. In addition, the data processing unit 140 may receive the data from the sample detector corresponding thereto and start the analysis for calculating the caffeine content. In the case of a typical caffeine measuring apparatus, the optical output section includes only one optical output device, and the detector section includes only one detector section, and the process of calculating the caffeine content can be performed only after the measurement of the substance that corrects the zero point is completed. However, in the case of the caffeine measuring apparatus 100 according to the present invention, the optical output unit 120 and the detector unit 130 are connected to the base light output unit 122, the sample light output unit 124, and the base detector 132, And the sample detector 134, so that the caffeine content can be calculated only by a predetermined time difference before the measurement of the base material is completed. Accordingly, it is possible to shorten the time consumed in measuring the caffeine amount contained in the sample.

The detector 130 may include a base detector 132 and a sample detector 134. The base detector 132 and the sample detector 134 may be provided inside the caffeine measurement apparatus 100. [ The base detector 132 and the sample detector 134 may be provided to sense a spectrum of light emitted from the sample irradiated with light from the base light output unit 122 and the sample light output unit 124. For example, the base detector 132 and the sample detector 134 may be disposed at an angle of 90 degrees corresponding to the base light output section 122 and the sample light output section 124, with the sample as a reference.

The base detector 132 senses a spectrum of light emitted from the base material (hereinafter, referred to as a base line) and transmits the spectrum to the data processor 140. Here, the base material may emit light using the light emitted from the base light output unit 122 as an energy source.

The sample detector 134 detects a spectrum of light emitted from the sample (hereinafter, referred to as a sample line) and transmits the spectrum to the data processing unit 140. Here, the sample can emit light using the light emitted from the sample light output unit 124 as an energy source.

In the case of a typical caffeine measuring apparatus, the optical output section includes only one optical output device, and the detector section includes only one detector section, so that the spectrum of the light emitted by the base material and the spectrum of the light emitted by the sample can not be measured at the same time .

However, in the case of the caffeine measuring apparatus 100 according to the present invention, the optical output unit 120 and the detector unit 130 are connected to the base light output unit 122, the sample light output unit 124, and the base detector 132, And sample detector 134 to measure the baseline and sample line simultaneously. Accordingly, it is possible to shorten the time consumed in measuring the caffeine amount contained in the sample.

The data processing unit 140 can receive the base line from the base detector 132 and receive the sample line from the sample detector 134. Thereafter, the data processing unit 140 may calculate a spectrum of light (hereinafter, referred to as a caffeine line) emitted by the caffeine of the sample based on the received baseline and sample line. The output of the caffeine line can be calculated by subtracting the intensity of the baseline from the intensity of the sample line.

Thereafter, the data processing unit 140 may analyze the calculated caffeine line to calculate the content of caffeine contained in the sample. The technique of calculating the content of caffeine by analyzing the spectrum of light emitted by caffeine is a well-known technique, so a detailed description thereof will be omitted.

Further, the data processing section 140 can calculate the content of caffeine contained in the sample based on the volume of the sample and the content of the caffeine contained in the sample.

Also, the data processing unit 140 may calculate the total caffeine content contained in the beverage based on the total amount of the beverage received from the user input unit 150 and the calculated caffeine content. The data processing unit 140 may include a number of application programs and data for calculating the caffeine line, calculating the caffeine content of the sample contained in the sample stage 112, calculating the caffeine content, and calculating the total caffeine content contained in the beverage. ≪ / RTI > and commands.

The user input unit 150 may receive the total amount of the beverage to know the total caffeine content from the user. When the total amount of beverage is inputted through the user input unit 150, the data processing unit 140 can calculate the total caffeine content included in the beverage corresponding to the total amount of the beverage inputted. The user input unit 150 may include a mechanical input unit (for example, a button, a dome switch, or the like located on a front or rear surface or a side surface of the caffeine measurement apparatus 100) . As an example, the touch-type input means may comprise a virtual key, a soft key or a visual key displayed on the touch screen through software processing.

The output unit 160 may display the total caffeine content calculated by the data processing unit 140 to the user. The output unit 160 may include at least one of a display 162 and a label output unit 164.

The display 162 may be disposed on the front surface of the caffeine measuring device 100. The display 162 can visually output the total caffeine content calculated in the data processing unit 140. [ Also, the display 162 may be implemented with a touch screen. In this case, it may function as a user input section.

The label printer 164 may be provided inside the caffeine measuring device 100. [ The label printer 164 can print the caffeine content calculated by the data processor 140 on a label sheet and output the label. The caffeine measuring apparatus 100 may include a predetermined gap so that the label printed and output by the label printer 164 may be discharged to the outside of the caffeine measuring apparatus 100 in correspondence with the label printer 164 provided therein have.

3 is a schematic view for explaining the cleaning of the caffeine measuring device according to an embodiment of the present invention.

3, the caffeine measuring apparatus 100 includes a cleaning gas discharging unit 115, a cleaning liquid discharging unit 116, a mesh net 117, a discharging unit 118, and a tilt adjusting unit (not shown) As shown in FIG.

The cleaning gas discharging unit 115 may be provided adjacent to one side of the sample stage 112 and the base stage 114, respectively. The cleaning gas discharging unit 115 can jet the cleaning gas to the sample stage 112 and the base stage 114 after the measurement is finished at a predetermined pressure. The terminating end of the cleaning gas discharging portion 115 may be inclined toward the interior of the sample stage 112 and the base stage 114. The predetermined pressure may be sufficient to push the sample received in the sample stage 112, the rinsing liquid, and the base material received in the base stage 114 to the outlet 118. Here, the cleaning gas may include at least one of clean air (CDA), oxygen (O 2), and nitrogen (N 2).

The cleaning liquid discharging portion 116 may be provided adjacent to the other side of the sample stage 112 and the base stage 114, respectively. However, the position of the cleaning liquid discharging portion 116 is not limited thereto, and the cleaning liquid discharging portion 116 may be provided apart from the cleaning gas discharging portion 115 at one side of the sample stage 112 and the base stage 114 have.

The cleaning liquid discharging portion 116 discharges the cleaning liquid to the sample stage 112 after the cleaning gas discharging portion 115 pushes the sample of the sample stage 112 to the discharge portion 118 at a predetermined pressure, 112 can be cleaned. The cleaning liquid may include at least one of pure water, deionized water, and ultrapure water. Thereafter, the cleaning liquid contained in the sample stage 112 can be pushed out to the discharge portion 118 by the pressure of the cleaning gas ejected by the cleaning gas discharging portion 115, like the sample and the base material.

The mesh network 117 can be installed at the inlet of the discharge portion 118 on the sample and the sample material pushed by the cleaning gas. The mesh network may be mesh-shaped to filter out particles that may contaminate the discharge 118 as at least one of the sample, the base material, and the rinse liquid is pushed out to the discharge 118.

The discharge portion 118 may be provided on the other side of the sample stage 112 and the base stage 114, respectively. The discharge portion 118 is positioned to communicate with one end of the sample stage 112 and the base stage 114 so that the sample and base material pushed by the pressure of the cleaning gas ejected from the cleaning gas discharge portion 116 . The other end of the discharge portion 118 communicates with the outside, and may be provided to discharge the sample and the base material to the outside. The discharge portion 118 may be coated to prevent corrosion by the sample, the base material, and the cleaning liquid.

Here, the sample stage 112 and the other side of the base stage 114 (i.e., the side on which the discharge portion 118 is provided) are connected to one side of the sample stage 112 and the base stage 114 115) is provided). In this case, the sample, the base material, and the cleaning liquid can be easily pushed out to the discharge portion 118. (For example, the discharge portion 115 side) of the base stage 114 and the sample stage 112 and the other side (for example, the discharge portion 118 of the base stage 114) of the base stage 114, Side) may be formed to be inclined.

The slope control unit (not shown) controls the sample stage 112 and the sample stage 112 so that the base material, the sample, and the cleaning liquid contained in the sample stage 112 and the base stage 114 are easily discharged to the discharge unit 118, And the base stage 114 can be tilted to be inclined toward the discharge portion 118. That is, the sample stage 112 and the base stage 114 can be mounted so as to be inclined in the sample portion 110. The inclination adjusting unit (not shown) may be provided to adjust the inclination of the sample stage 112 and the base stage 114.

FIG. 4 is a flowchart illustrating a process of measuring a caffeine content through a caffeine measuring apparatus according to an embodiment of the present invention. Referring to FIG.

Referring to FIG. 4, the process of measuring the total caffeine content through the caffeine measuring device includes a step S110 of receiving a sample in a sample stage of a sample part, a step S120 of irradiating the absorbed light to a sample accommodated therein, (S142) of calculating the caffeine content of the sample through the emitted emitted light, measuring the total amount of the beverage for which the user wants to know the total caffeine content, to the caffeine measuring device (S144) of calculating the total caffeine content based on the calculated caffeine content and the total amount of the input beverage, and informing the user of the total caffeine content contained in the beverage (S160) .

In the step S110 of accepting the sample in the sample stage of the sample part, the user can accommodate a part of the beverage to know the total caffeine content in the sample stage as a sample necessary for the measurement. The volume of the space in which the sample stage accommodates the sample may be constant. Wherein the volume of the sample stage that receives a portion of the beverage as a sample may be about 1-2 ml. If the user provides a beverage that is larger than the volume of the space in the sample stage, the excess volume of beverage can flow down the sample stage. Thereafter, the caffeine amount contained in the sample corresponding to the volume of the sample stage can be measured. The caffeine content can be calculated by comparing the measured caffeine dose with the volume of the sample stage.

In the step of irradiating the absorbed light with the absorbed light (S120), the absorbed light may be irradiated to the sample, and the base material may be provided together to irradiate the absorbed light with the base material. Where the base material may be a material provided to zero to determine the spectrum of caffeine released by the sample (hereinafter, referred to as the caffeine line). Wherein the absorbed light irradiated with the sample and the base material may be light emitted from the lamp and the laser. If the absorbed light is light generated from the lamp, light of a wavelength suitable for detecting caffeine in the spectral form of light generated from the lamp may be selected. after

In step S130, the emitted light may be detected in the form of a spectrum (hereinafter, referred to as a sample line). At the same time, a spectral emission light (hereinafter, referred to as a baseline) in which the base material irradiated with the absorbed light emits light can be detected. Thereafter, the sensed baseline and sample lines can be used as data for calculating the caffeine content.

In the step of calculating the caffeine content of the sample through the emitted emitted light, a spectrum of light emitted by the caffeine of the sample based on the sensed base line and the sample line (hereinafter referred to as a caffeine line) is calculated . Thereafter, the calculated caffeine line can be analyzed to calculate the content of caffeine contained in the sample. In addition, the content of caffeine contained in the sample can be contrasted with the amount of sample contained in the sample stage, and as a result, the content of caffeine can be calculated.

Before the data of the baseline and the sample line in the step of irradiating the sample with absorbing light (S120) or the step of calculating the caffeine content (S142) obtains the data value with respect to the whole wavelength interval, Once you get started, you can calculate the cafe inline using the data values that are immediately obtained, without waiting for the baseline and sample line measurements to finish. In addition, the caffeine content can be calculated at the same time by analyzing the caffeine line.

The step (S150) of inputting the total amount of the beverage for which the user wants to know the total caffeine content to the caffeine measuring device may be implemented by an input means included in the apparatus. For example, the user can touch the virtual key displayed on the touch screen provided in the device to input the total amount of the beverage.

In step S144 of calculating the total caffeine content based on the calculated caffeine content and the total amount of the input beverage, the total caffeine content contained in the beverage can be calculated based on the total amount of the input beverage and the calculated caffeine content .

In step S160, in which the user is informed of the total caffeine content contained in the beverage, the calculated total caffeine content can be visually output. In addition, the calculated total caffeine content can be printed on paper.

5 is a block diagram illustrating and illustrating a computing environment 10 that includes a computing device suitable for use in the exemplary embodiments. In the illustrated embodiment, each of the components may have different functions and capabilities than those described below, and may include additional components in addition to those described below.

The illustrated computing environment 10 includes a computing device 12. In one embodiment, the computing device 12 may be a caffeine measurement device.

The computing device 12 includes at least one processor 14, a computer readable storage medium 16, The processor 14 may cause the computing device 12 to operate in accordance with the exemplary embodiment discussed above. For example, processor 14 may execute one or more programs stored on computer readable storage medium 16. The one or more programs may include one or more computer-executable instructions, which when executed by the processor 14 cause the computing device 12 to perform operations in accordance with the illustrative embodiment .

The computer-readable storage medium 16 is configured to store computer-executable instructions or program code, program data, and / or other suitable forms of information. The program 20 stored in the computer-readable storage medium 16 includes a set of instructions executable by the processor 14. In one embodiment, the computer-readable storage medium 16 may be any type of storage medium such as a memory (volatile memory such as random access memory, non-volatile memory, or any suitable combination thereof), one or more magnetic disk storage devices, Memory devices, or any other form of storage medium that can be accessed by the computing device 12 and store the desired information, or any suitable combination thereof.

Communication bus 18 interconnects various other components of computing device 12, including processor 14, computer readable storage medium 16.

The computing device 12 may also include one or more input / output interfaces 22 and one or more network communication interfaces 26 that provide an interface for one or more input / output devices 24. The input / output interface 22 and the network communication interface 26 are connected to the communication bus 18. The input / output device 24 may be connected to other components of the computing device 12 via the input / output interface 22. The exemplary input and output device 24 may be any type of device, such as a pointing device (such as a mouse or trackpad), a keyboard, a touch input device (such as a touch pad or touch screen), a voice or sound input device, An input device, and / or an output device such as a display device, a printer, a speaker, and / or a network card. The exemplary input and output device 24 may be included within the computing device 12 as a component of the computing device 12 and may be coupled to the computing device 12 as a separate device distinct from the computing device 12 It is possible.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, . Therefore, the scope of the present invention should not be limited to the above-described embodiments, but should be determined by equivalents to the appended claims, as well as the appended claims.

100: Caffeine measuring device
110:
112: Sample stage
114: base stage
120: Optical output section
122: Base light output section
124: sample light output section
130: Detector part
132: Base detector
134: Sample detector
140:
150: User input
160: Output section
162: Display
164: Label printer

Claims (6)

A sample stage for containing a sample that is part of the beverage for which the caffeine content is to be measured;
A sample light output unit for irradiating the sample with light;
A base stage for receiving a base material for zero point correction of a spectrum of light emitted by the sample by the light irradiated to the sample;
A base light output unit for emitting light to the base material;
A sample detector for detecting a wavelength band corresponding to caffeine included in the sample among the spectrum of light emitted by the sample by the light irradiated to the sample;
A base detector for detecting the wavelength band of the spectrum of light emitted by the base material by the light irradiated by the base material; And
And a data processor for calculating a caffeine content included in the sample based on the wavelength band corresponding to the caffeine sensed by the sample detector and the wavelength band sensed by the base detector.
The method according to claim 1,
The sample light output unit includes:
The base light output unit starts to irradiate light to the sample after a predetermined time from a time point at which the base material starts to irradiate light to the base material,
Wherein the data processing unit comprises:
Wherein the sample detector begins to detect the caffeine content contained in the sample while at the same time starting to sense the wavelength band corresponding to the caffeine contained in the sample.
The method according to claim 1,
The caffeine measuring device comprises:
A cleaning gas discharge unit provided at one side of the sample stage and the base stage, respectively, for spraying a cleaning gas into the sample stage and the base stage; And
Further comprising a sample stage and a discharge portion provided on the other side of the base stage for discharging the sample and the base material pushed by the cleaning gas to the outside.
The method of claim 3,
The caffeine measuring device comprises:
Further comprising a mesh net installed at an inlet of the discharge section on a path of movement of the sample and the base material pushed by the cleaning gas.
The method of claim 3,
The caffeine measuring device comprises:
Further comprising a rinse solution discharging portion for rinsing the sample stage and the base stage by injecting a rinse solution into the sample stage and the base stage,
Wherein the cleaning gas ejecting portion ejects the cleaning gas such that the cleaning liquid contained in the sample stage and the base stage flows into the discharge portion.
The method of claim 3,
Wherein the sample stage and one side of the base stage and the other side of the sample stage and the base stage are each formed to be inclined.

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