KR102034858B1 - Sugar and Acidity Content Measuring Apparatus Capable of Quantitative Induction of Specimens - Google Patents

Abstract

The present invention provides a device for measuring a sugar content and an acidity content capable of quantitatively inducing a sample so as to accurately measure the sugar content and the acidity content of a fruit, comprising: a sugar content measurement module capable of measuring the sugar content by receiving a fruit juice; a quantitative guide module for guiding the fruit juice transferred from the sugar content measurement module; a water supply valve for selectively transferring the water contained in a water tank to the quantitative guide module; and an acidity content measurement module for measuring the acidity content using a predetermined amount of fruit juice and water transferred from the quantitative guide module.

Description

Sugar and Acidity Content Measuring Apparatus Capable of Quantitative Induction of Specimens

The present invention relates to a sugar and acidity measuring device capable of quantitatively inducing a sample, and more particularly, to a sugar and acidity measurement capable of quantitatively inducing a sample to accurately measure sugar and acidity of a sample using a single device. Relates to a device.

Fruit is an alkaline food that is rich in vitamins and minerals. It is widely used because of its sweet taste from glucose, fructose, sucrose, etc. have.

However, the conventional method of sorting fruit by grade mainly determines the value and grades of the product by classifying the size or color of the fruit and the presence or absence of scratches, so that even if the grade is high, the taste of sugar and acidity is known. As a result, there are frequent cases in which the value of a good product is violated in deciding the value of a product, thereby degrading the value of the best product. Accordingly, there is a demand for a method of producing delicious fruits by measuring sugar and acidity at regular intervals in the cultivation process and determining a future cultivation method.

On the other hand, the sugar and acidity of the fruit apply different measurement principles. In other words, the sugar content is an optical method using the refraction of light, the acidity is an electrical conductivity method. Therefore, in order to measure sugar and acidity, two different measuring slots must be provided on the same machine, and each process must be treated differently before the measurement. In addition, since the existing method of measuring acidity requires the user to directly collect and dilute the quantitative fruit sample and the quantitative distilled water by hand, it is impossible to obtain the quantitative sample and the distilled water, which causes inconsistency between measured values. There is a problem.

Domestic Patent Publication No. 10-1344149

An object of the present invention for solving the problems of the prior art as described above is to provide a sugar and acidity measuring device capable of quantitative induction of the sample to accurately measure the sugar and acidity of the sample using one device.

In order to achieve the above object, the present invention provides a housing having a space portion therein and having an injection portion formed to be exposed to the outside on one side; A water tank seated on an upper portion of the housing; A support plate standing on the space part; A measuring member mounted to the support plate to measure sugar and acidity of the juice; And an output unit provided at the other side of the housing and outputting the sugar value and acidity value of the fruit juice transmitted from the measuring member to the outside, wherein the measuring member includes: a sugar measuring storage unit containing the juice injected from the injecting unit; And a sugar measurement module having a sugar measurement sensor for irradiating light in the juice direction accommodated in the sugar measurement storage unit and measuring a refractive angle of light refracted by the juice to generate a sugar signal. A quantification guide module for guiding the juice delivered from the sugar measurement module; A water supply valve selectively transferring the water contained in the water tank to the quantitative guide module; An acidity measurement unit receives a predetermined amount of juice and water from the quantitative guide module, and applies a voltage to a solution stored in the acidity unit and detects an electrical change generated according to the acidity of the juice to detect an acidity signal. An acidity measurement module having an acidity measurement sensor to generate; And a control means for receiving the sugar content to calculate a sugar value of the juice, receiving the acidity signal to calculate the acidity value of the juice, and transmitting the calculated sugar value and acidity value to the output unit. Provided is a sugar and acidity measuring device capable of quantitatively inducing a sample.

In addition, the sugar measurement storage unit is made of a transparent material, the sugar measurement sensor, the prism is located below the sugar measurement storage unit, and located on one side of the prism, the light is directed to the lower direction of the sugar measurement storage unit A light emitting unit for irradiation, and a light receiving unit positioned on the other side of the prism and receiving the light reflected by the juice contained in the sugar measuring storage unit to measure the refraction angle of the light to generate a sugar signal, characterized in that Provided is an inducible sugar and acidity measuring device.

In addition, the quantitative guide module is formed in a cylindrical shape, the first through hole, the second through hole, the third through the hole facing the first hole and the fourth through the second hole facing the second hole is formed in this order A quantitative guide body and a quantitative guide tube positioned to be rotated inside the quantitative guide body, both ends of which are positioned to communicate with the first and the third through holes, or are communicated with the second and fourth through holes. And a rotation unit for rotating the metering guide tube, wherein the sugar measurement module is connected to the first through hole, the water supply valve is connected to the second through hole, and the acidity measurement storage unit is connected to the fourth through hole. The juice is filled from the sugar measurement module to the quantitative guide tube in a state in which both ends of the quantitative guide tube are positioned to communicate with the first through hole and the third through hole. If so, the rotating part rotates the metering guide tube so that both ends of the metering guide tube is in communication with the second and fourth through hole, both ends of the metering guide tube and the second through and When the water supply valve delivers the water contained in the water tank to the quantitative guide tube in the state of being in communication with the fourth through hole, the juice filled in the quantitative guide tube and the water delivered to the quantitative guide tube are the acidity. The amount of juice delivered to the measurement storage unit and filled into the quantitative guide tube is determined by the internal volume of the quantitative guide tube, and the amount of water delivered to the quantitative guide tube is determined by the predetermined opening time of the water supply valve. Provided is a sugar and acidity measuring device capable of quantitatively inducing a sample.

The apparatus may further include a pressure control module having a supply hole in communication with the third through hole, wherein one side of the injection unit and the sugar measurement storage unit are connected to each other by a first connector, and the other side of the sugar measurement storage unit. And the first through hole are interconnected by a second connecting pipe, the third through hole and the supply hole are interconnected by a third connecting pipe, the juice supplied from the sugar measurement module to the quantitative guide tube is After filling the quantitative guide tube flows into the third connecting pipe, the pressure control module includes: a pressure control body having a supply hole formed in the lower side and an empty space therein so that juice is supplied from the third connecting pipe; A support pillar protruding upward from an inner lower surface of the pressure control body and having the supply hole positioned at a lower center thereof; And a shanghai-dong portion which is located inside the support pillar and is vertically moved by the pressure of the juice introduced into the support pillar through the supply hole, and the juice moved along the third connecting pipe is connected to the supply hole. When flowing through the support pillar, the east portion of the shanghai is moved upward by the pressure to open the supply hole, if the juice does not flow into the inside of the support, the east shanghai portion of the lower portion of the support column by gravity Located in the blocking the supply hole, the pressure control body provides a sugar and acidity measurement device capable of quantitative induction of the sample, characterized in that located above the quantitative guide body.

In addition, the inner surface of the pressure control main body further includes a support portion protruding in the direction of the support pillar, wherein the shangdong portion is configured so that it is not removed to the outside of the support pillar by the support portion Provided is an inducible sugar and acidity measuring device.

In addition, a central guide portion is formed so as to cover the inner periphery of the support pillar, the bottom surface of the central guide portion is formed to be inclined downward toward the center direction, the inclined portion is inclined so as to communicate with the supply hole. A hole is formed, and the shandong part is formed in a spherical shape but smaller than the inner diameter of the central induction part. When the shandong part is located in the inclined part, the shandong part is in an inclined shape of the inclined part. It provides a sugar and acidity measuring device capable of quantitative induction of the sample, characterized in that the guide is guided toward the center of the inclined inclined portion to block the inclined hole.

In addition, the juice flowing into the support column is discharged to the pressure control body through the space between the shanghai East and the support pillar, the drain hole is drained to drain the juice from the support pillar in the lower portion of the pressure control body Provided is a sugar and acidity measuring device capable of quantitative induction of a sample, characterized in that formed.

The acidity measurement module may further include a temperature measurement unit configured to measure a temperature of a solution accommodated in the acidity measurement storage unit, and wherein the control unit receives the acidity signal to calculate the acidity value of the juice. It provides a sugar and acidity measuring device capable of quantitative induction of the sample, characterized in that for calculating the acidity value according to the temperature of the solution received from the temperature measuring unit.

The acidity measurement module may further include a water level measurement unit mounted on an upper side of the acidity measurement storage unit to measure a level of a solution delivered to the acidity measurement storage unit, and the control unit is transferred from the water level measurement unit. When the water level of the solution of the acidity measuring unit is a predetermined water level is provided to provide a sugar and acidity measuring device capable of quantitative induction of the sample, characterized in that the water supply valve is controlled to be closed.

In addition, a drain tube is located under the acidity measurement storage unit, a drain connection tube is mounted between the lower portion of the acidity measurement storage unit and the drain tube, a washing valve is mounted on the drain connection tube, and the control means. After the acidity value is calculated, the water supply valve and the washing valve is opened, and the water contained in the water tank is guided to the acidity measuring and storage unit after passing through the quantitative guide tube and the drain pipe passing through the drain pipe. It provides a sugar and acidity measurement device capable of quantitative induction of the sample, characterized in that the control to be discharged to.

In addition, the injection unit provides a sugar and acidity measuring device capable of quantitative induction of the sample, characterized in that configured to insert a syringe containing a sample.

The present invention is configured to inject juice into the injection portion using a syringe without a separate pipette, there is an effect that can easily inject a sample such as juice.

In addition, since a predetermined amount of juice and a predetermined amount of distilled water are supplied to the acidity measurement module, the reliability of the value measured by the acidity measurement module is improved.

In addition, since the juice supplied from the glucose measuring module to the quantitative guide tube is filled in the quantitative guide tube and then moved in the direction of the third connecting tube, the amount of juice supplied to the quantitative guide tube is always quantitatively constant by the volume of the quantitative guide tube. There is a supply effect.

 In addition, since the shanghai east portion of the pressure control module is configured to block the inclined hole, the juice supplied to the third connecting pipe passing through the metering guide tube is again limited to the reverse movement to the metering guide tube.

In addition, the spherical Shanghai East portion is rolled toward the center of the induction inclination portion by the inclined shape of the induction inclination portion, accordingly, the Shanghai East portion has the effect of accurately blocking the inclined hole located in the center of the induction inclination portion.

In addition, it is possible to easily clean the various modules by using the water of the water tank or the water of the syringe without having to separate the module separately, and thus there is an effect that can quickly proceed to the subsequent measurement work.

1 is a view schematically showing a sugar and acidity measuring device capable of quantitative induction of a sample according to a preferred embodiment of the present invention.
2 is a view schematically showing the inside of the housing of the sugar and acidity measurement apparatus capable of quantitative induction of a sample according to a preferred embodiment of the present invention.
3 is a view schematically illustrating a sugar measurement module of a sugar and acidity measurement device capable of quantitative induction of a sample according to a preferred embodiment of the present invention.
4 is a view schematically illustrating a quantification guide module of a sugar and acidity measuring device capable of quantitative induction of a sample according to a preferred embodiment of the present invention.
5 is a schematic cross-sectional view of a quantitative guide module of a sugar and acidity measurement device capable of quantitatively inducing sample according to a preferred embodiment of the present invention.
6 is a view schematically illustrating a pressure control module of a sugar and acidity measuring device capable of quantitatively inducing a sample according to a preferred embodiment of the present invention.
FIG. 7 is a cross-sectional view taken along line AA ′ of FIG. 6.
FIG. 8 is a view schematically illustrating a process of opening and closing a supply hole by a water level measurement unit provided in a pressure control module of a sugar and acidity measurement device capable of quantitatively inducing a sample according to a preferred embodiment of the present invention.
9 is a cross-sectional view taken along line BB ′ of FIG. 6.
FIG. 10 is a view schematically illustrating an acidity measurement module of a sugar and acidity measurement device capable of quantitatively inducing a sample according to a preferred embodiment of the present invention.
FIG. 11 is a cross-sectional view taken along line CC ′ of FIG. 10.
12 is a view schematically illustrating a control means of a sugar and acidity measuring device capable of quantitatively inducing a sample according to a preferred embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings will be described in more detail the sugar and acidity measuring device capable of quantitative induction of the sample according to a preferred embodiment of the present invention.

1 is a view schematically showing a sugar and acidity measurement device capable of quantitatively inducing a sample according to a preferred embodiment of the present invention, Figure 2 is a sugar and acidity capable of quantitative induction of a sample according to a preferred embodiment of the present invention A schematic illustration of the interior of the housing of the measuring device.

1 and 2, a sugar and acidity measuring apparatus capable of quantitatively inducing a sample according to a preferred embodiment of the present invention includes a housing 100, a water tank 150, and a measuring member 200. The housing 100 is compactly formed to be portable and an empty space part 100a is formed therein. The shape of the housing 100 may be formed in an approximately hexahedral shape, and the shape of the housing 100 is not particularly limited. The injection part 102 is formed on one side of the housing 100 to be exposed to the outside, and the output part 120 is provided on the other side of the housing 100. The injection unit 102 is configured to insert and insert a sample, that is, a conventional syringe containing juice. When the user applies pressure to the syringe, the juice inside the syringe is transferred to the sugar measurement module 210 described later through the injection unit 102 by the injection pressure. As such, the present invention is configured to inject the juice into the injection unit 102 using a syringe without a separate pipette, there is an effect that can easily inject a sample such as juice.

The output unit 120 is provided on the outside of the housing 100, and is configured as a display unit capable of displaying an image, and the sugar and acidity values of the juice are externally controlled by a control unit 270 (shown in FIG. 12) described later. It is output to, so that the general person without knowledge of sugar and acidity can easily know the sugar value and acidity value. The plate-shaped support plate 110 is installed on the space portion 100a of the housing 100, and various measurement members 200 are mounted on the support plate 110. The water tank 150 is for supplying water such as distilled water to the measuring member 200 inside the housing 100, and has a space to accommodate water therein.

The measuring member 200 includes a sugar measuring unit, a quantitative guide module 220, a water supply valve 250, a pressure control module 230, an acidity measuring module 240, and a control means 270. The sugar measurement module 210 and the acidity measurement module 240 are positioned under the support plate 110, and the quantitative guide module 220 and the pressure control module 230 are positioned above the support plate 110. At this time, the pressure control module 230 is located on the upper side of the metering guide module 220. The water supply valve 250 is located on the other side of the upper part of the metering guide module 220, and selectively transfers the water contained in the water tank 150 to the metering guide module 220.

3 is a view schematically illustrating a sugar measurement module of a sugar and acidity measurement device capable of quantitative induction of a sample according to a preferred embodiment of the present invention.

2 and 3, the sugar measurement module 210 includes a sugar measurement receiving unit 212 and a sugar measurement sensor 214. The sugar measurement storage unit 212 irradiates light in the juice direction accommodated in the sugar measurement storage unit 212 and the sugar measurement storage unit 212 accommodated with the juice injected from the injection unit 102 and is refracted by the juice. And a sugar measurement sensor 214 for measuring a refractive angle of light to generate a sugar signal. The sugar measurement storage unit 212 is mounted on the support plate 110 and is made of a transparent material so that light is easily transmitted. And the juice inlet 213a and the juice outlet 213b are formed on one side and the other side of the sugar measurement storage unit 212, respectively. The first inlet 260a is connected to the juice inlet 213a, and the juice injected into the injector 102 is sequentially moved along the first connector 260a and the juice inlet 213a, and then the sugar content is measured. It is supplied to the accommodating part 212. A second connection pipe 260b is connected to the juice outlet 213b, and the juice stored in the sugar measurement storage unit 212 is sequentially moved along the juice outlet 213b and the second connection pipe 260b. It is moved to the quantitative guide main body 222 (shown in FIG. 5) to be described later.

The glucose measuring sensor 214 is a refractive sugar meter, and measures the sugar content using the refraction of light, and is located on the side of the prism 214a and the prism 214a which are located below the sugar measuring unit 212. The light emitting unit 214b irradiates light toward the lower side of the sugar measurement storage unit 212 and the other side of the prism 214a and receives light reflected by the juice contained in the sugar measurement storage unit 212. It includes a light receiving unit 214c for measuring the refractive value of the light to generate a sugar content signal. The light emitting unit 214b may be configured of, for example, an LED emitting red light. The light emitted from the light emitting unit 214b is refracted toward the light receiving unit 214c by the juice stored in the sugar measurement storage unit 212 after passing through the prism 214a. The light receiving unit 214c measures the angle of refraction of the light refracted by the glucose measuring unit 212, generates a sugar content signal based on the measured angle of refraction, and transmits the generated sugar signal to the controller 278 (shown in FIG. 12). At this time, the higher the sugar content dissolved in the juice, the larger the angle of refraction.

4 is a view schematically illustrating a quantitative guide module of a sugar and acidity measurement apparatus capable of quantitative induction of a sample according to a preferred embodiment of the present invention, Figure 5 is a view of a sample according to a preferred embodiment of the present invention Figure is a schematic cross-sectional view of the quantitative guide module of the sugar and acidity measurement device capable of quantitative induction.

2, 4 and 5, the quantitative guide module 220 is for receiving the juice delivered from the sugar measurement module 210 to deliver a predetermined amount of juice to the acidity measurement module 240. To this end, the quantitative guide module 220 is a rotary part 226 mounted on the support plate 110, a quantitative guide main body 222 mounted on the front side of the rotary part 226 located in the opposite direction of the support plate 110, and vein It includes a quantitative guide tube 224 is located rotatably inside the guide body. The rotating unit 226 is composed of a drive motor and the like is connected to the metering guide tube 224, the metering guide tube 224 is rotated by the rotation of the rotating unit 226. The quantitative guide body 222 is formed in a cylindrical shape, but along the outer circumference, the first through hole 222a, the second through hole 222b, and the third through hole 222c and the second through hole facing the first through hole 222a. A fourth through hole 222d facing 222b is sequentially formed. The metering guide tube 224 is formed to be elongated in the shape of a tube, both ends thereof are formed to extend in close contact with the inner circumference of the metering guide body 222. In addition, both ends of the metering guide tube 224 are positioned to communicate with the first through hole 222a and the third through hole 222c by the rotation of the rotating unit 226, or the second through hole 222b and the fourth through hole 222d. ) Is in communication with. And the juice outlet 213b and the first through hole (222a) are interconnected by the second connecting pipe 260b, the second through hole (222b) and the water supply valve 250 are mutually connected by the valve connecting pipe (250a) The third through hole 222c and the supply hole 232a (shown in FIG. 7) to be described later are connected to each other by the third connecting pipe 260c, and the fourth through hole 222d and the acidity measurement storage unit 242 to be described later. ) Are interconnected by a fourth connector 260d. At this time, the first, second, third, and fourth through holes 222a, 222b, 222c, and 222d respectively include the first, second, third, and fourth through holes 222a-1, 222b-1, 222c-1, and 222d-1. Can be mounted. In this case, the second connecting pipe 260b, the valve connecting pipe 250a, the third connecting pipe 260c, and the fourth connecting pipe 260d are each of the first, second, third, and fourth through holes 222a-1. , 222b-1, 222c-1, 222d-1).

And both ends of the quantitative guide tube 224 is positioned so as to communicate with the first through hole (222a) and the third through hole (222c), so that the juice is filled into the quantitative guide tube 224 in the sugar measurement module 210 When delivered, the rotating unit 226 rotates the metering guide tube 224 so that both ends of the metering guide tube 224 are in communication with the second through hole 222b and the fourth through hole 222d. At this time, the amount of juice filled with the quantitative guide tube 224 is determined by the internal volume of the quantitative guide tube 224.

Thereafter, both ends of the metering guide tube 224 are positioned to communicate with the second through hole 222b and the fourth through hole 222d, and the water supply valve 250 guides the water contained in the water tank 150. When delivered to the tube 224, the juice filled in the quantitative guide tube 224 and the water delivered to the quantitative guide tube 224 are delivered to the acidity measurement storage unit 242. At this time, the amount of water delivered to the metering guide tube 224 is determined by the opening time of the predetermined water supply valve 250.

As such, the amount of juice to be filled in the quantitative guide tube 224 and the amount of water delivered from the water tank 150 to the quantitative guide tube 224 are always constant, so that the juice of the juice transferred from the vegetation guide module to the pH measurement module 240 is constant. The amount and amount of water are also configured to be constant at all times. As such, the amount of quantitative juice and the amount of distilled water are supplied to the acidity measurement module 240, thereby improving the reliability of the value measured by the acidity measurement module 240.

On the other hand, since the amount of juice to be filled in the quantitative guide tube 224 should always be constant, the juice supplied to the quantitative guide tube 224 is filled with the quantitative guide tube 224 after passing through the quantitative guide tube 224 and the third It is supplied to one side of the connecting pipe 260c. At this time, the pressure control module 230 is provided on the other side of the third connecting pipe 260c so that the juice supplied to the third connecting pipe 260c does not move backward in the direction of the metering guide pipe 224.

FIG. 6 is a view schematically illustrating a pressure control module of a sugar and acidity measuring apparatus capable of quantitatively inducing sample according to a preferred embodiment of the present invention, and FIG. 7 is a cross-sectional view taken along line AA ′ of FIG. 6. to be.

2, 6, and 7, the pressure control module 230 may include a pressure control body 232, a support pillar 234, and an east / south part 236, and further include a central induction part 235. Can be.

The pressure control body 232 is mounted to the support plate 110 is located above the quantitative guide body 222. The pressure control main body 232 has an empty space formed therein, and a supply hole 232a is formed at the lower side such that the juice is supplied from the third connection pipe 260c. The support column 234 protrudes upward from the inner bottom surface of the pressure control body 232, but the supply hole 232a is positioned at the lower center. The induction inclination part 235a is formed to cover the inner circumference of the support pillar 234, and the induction inclination part 235a is formed to be inclined downward toward the center direction of the center guide part 235. The inclined hole 235a-1 is formed at the center of the inclined slope 235a so as to communicate with the supply hole 232a. The shanghai eastern part 236 is formed in a spherical shape, such as metal ball and is located inside the inclined portion 235a. The shanghai eastern part 236 is formed to be smaller than the inner diameter of the central induction part 235. In addition, the east-east Shanghai 236 is vertically moved in the inclined portion 235a by the pressure of the juice flowing through the supply hole 232a and the inclined hole 235a-1 into the inclined portion 235a.

FIG. 8 is a view schematically illustrating a process of opening and closing a supply hole by a water level measurement unit provided in a pressure control module of a sugar and acidity measurement device capable of quantitatively inducing a sample according to a preferred embodiment of the present invention.

6 to 8, the fruit juice moving along the third connecting pipe 260c is supplied to the central induction part 235 through the supply hole 232a and the inclined hole 235a-1, and the east part 236 of Shanghai. Upward pressure is applied. Then, the east portion 236 is moved upward by the pressure to open the supply hole 232a and the inclined hole 235a-1.

In this case, the pressure control body 232 further includes a support part 238 protruding in the direction of the support pillar 234 on the inner bottom of the pressure control main body 232, the shanghai East part 236 is external to the support pillar 234 by the support part 238. It is configured not to be removed.

On the other hand, if the juice is no longer introduced into the central guide portion 235, the upward pressure is canceled, so the east-east Shanghai 236 is located in the lower portion of the central guide portion 235 by gravity to supply holes 232a and inclined holes Block (235a-1). At this time, since the induction inclination portion 235a is provided below the central guide portion 235, the spherical Shanghai East portion 236 is in the center direction of the induction inclination portion 235a by the inclined shape of the induction inclination portion 235a. Rolling to, the east east 236 has the effect of blocking the inclined hole 235a-1 located in the center of the inclined slope 235a accurately.

In addition, since the shanghai East 236 is configured to block the inclined hole (235a-1), the juice supplied through the metering guide tube 224 to the third connecting pipe (260c) back to the metering guide tube 224 The reverse movement is limited.

FIG. 9 is a cross-sectional view taken along line BB ′ of FIG. 6.

2, 6 to 9, the juice flowing into the support pillar 234 flows out to the pressure control body 232 through the space between the shanghai East 236 and the support pillar 234. At this time, a drain hole 232b is formed at one side of the supply hole 232a at the lower portion of the pressure control body 232, and the juice flowing out of the support column 234 is connected to the pressure control body 232 through the drain hole 232b. Is drained outside. For this purpose, a first drain connection pipe 262a is installed in the drain hole 232b, and a drain pipe 264 is installed below the first drain connection pipe 262a, and the juice is drained through the drain hole 232b. The first drain connection pipe 262a and the drain pipe 264 are discharged to the outside of the housing 100.

FIG. 10 is a view schematically illustrating a acidity measurement module of a sugar and acidity measurement device capable of quantitatively inducing sample according to a preferred embodiment of the present invention, and FIG. 11 is a cross-sectional view taken along line CC ′ of FIG. 10. to be.

2, 10, and 11, the acidity measurement module 240 is mounted on the support plate 110 and is housed in the acidity measurement storage unit 242 and the acidity measurement storage unit 242 having a space formed therein. A pH measurement sensor 244 is applied to generate a pH signal by applying a voltage to the prepared solution and detecting an electrical change generated according to the acidity of the juice.

And in the state filled with the juice in the quantitative guide tube 224 of the quantitative guide module 220, the rotary unit 226 rotates the quantitative guide tube 224 so that both ends of the quantitative guide tube 224 are second through holes ( 222b) and the fourth through hole 222d, the water supply valve 250 is opened so that the water contained in the water tank 150 flows to the metering guide tube 224. Then, the water contained in the water tank 150 is delivered to the pH measurement storage unit 242 together with the juice of the quantitative guide tube 224. Thereafter, the electrode portion 244a of the acidity measuring sensor 244 applies a predetermined voltage, for example, 200 mV, to a solution contained in the acidity measuring storage 242, that is, water and fruit juice. In addition, the current sensor 244b of the acidity sensor 244 detects an electric change amount, ie, an electromotive force change, of the hydrolyzed fruit juice to generate an acidity signal, and transmits the generated acidity signal to the controller 278. . The controller 278 calculates the acidity value of the juice by substituting an electromotive force change into the acidity measurement algorithm.

In addition to this, the acidity measurement module 240 may further include a temperature measuring unit 246 and a water level measuring unit 248. The temperature measuring unit 246 measures the temperature of the solution accommodated in the acidity measurement storage unit 242 and transmits the temperature to the control unit 278 which will be described later. The water level measurement unit 248 is mounted on the upper side of the acidity measurement storage unit 242 to measure the level of the solution supplied to the acidity measurement storage unit 242 and transmits it to the controller 278 which will be described later.

On the other hand, a second drain connecting pipe 262b connected to the drain pipe 264 is mounted on the upper portion of the acidity measuring storage part 242, and after the solution is filled in the acidity measuring storage part 242, the acidity is continuously maintained. When the solution is supplied to the measurement storage unit, the remaining solution is drained to the drain pipe 264 through the second drain connection pipe 262b.

In addition, the drain pipe 264 is positioned below the acidity measurement storage unit 242 spaced downward, and the third drain connection pipe 262c between the lower portion of the acidity measurement storage unit 242 and the drain pipe 264. ) Can be mounted. In addition, the washing valve 252 may be mounted to the third drain connection pipe 262c, and the washing valve 252 may be opened or closed by the control of the controller 278 described later.

12 is a view schematically illustrating a control means of a sugar and acidity measuring device capable of quantitatively inducing a sample according to a preferred embodiment of the present invention.

1 to 12, the control unit 270 includes an input unit 271, a light source driver 272, a power driver 273, a rotation driver 274, a water supply driver 275, and a water supply valve driver 276. It includes a washing valve driving unit 277 and the control unit 278.

The input unit 271 is provided at the outside of the housing 100 and may be located at one side of the output unit 120. The input unit 271 receives various signals from a user and transfers them to the controller 278. The light source driver 272 receives the control signal from the controller 278 and emits the light emitting unit 214b of the glucose measuring sensor 214. The power driver 273 receives the control signal from the controller 278 to drive the electrode unit 244a of the acidity measurement sensor 244. The rotary driver 274 receives the control signal from the controller 278 and drives the rotary unit 226 to rotate forward or reverse. The water supply valve driver 276 receives a control signal from the controller 278 to drive the water supply valve 250 to be opened or closed. The washing valve driver 277 receives the control signal from the controller 278 to drive the washing valve 252 to be opened or closed.

The control unit 278 receives the sugar content signal from the light receiving unit 214c to calculate the sugar value of the juice, receives the acidity signal from the current sensor 244b, calculates the acidity value of the juice, and calculates the sugar value of the juice and The pH value is transmitted to the output unit 120. In addition, when the controller 278 receives the acidity signal and calculates the acidity value of the juice, the controller 278 calculates the acidity value according to the temperature of the solution received from the temperature measuring unit 246. In addition, the controller 278 controls the water supply valve 250 to be closed when the water level of the acidity measurement unit 242 transmitted from the water level measurement unit 248 corresponds to a preset water level. After the controller 278 calculates the pH value, the water supply valve 250 and the washing valve 252 are opened so that the water contained in the water tank 150 passes through the quantitative guide tube 224 and the acidity measurement storage unit 242. After being guided to) and passes through the third drain connection pipe 262c to control the discharge to the drain pipe (264).

Hereinafter, the operation of the sugar and acidity measuring device capable of quantitative induction of a sample according to a preferred embodiment of the present invention will be described.

First, in order to measure the sugar content of the juice, the user puts the juice in the syringe and then inserts the syringe into the injection portion 102. Thereafter, when the pressure is applied to the syringe, the juice of the syringe passes through the first connection pipe 260a through the injection unit 102 and is received in the sugar measurement storage unit 212 of the sugar measurement module 210. Thereafter, when a user inputs a sugar measurement control signal to the controller 278 using the input unit 271, the controller 278 controls the light source driver 272 so that the light emitter 214b transmits light to the sugar measurement storage unit. To light at 212. Then, the light receiving unit 214c measures the angle of refraction of the light refracted by the glucose measuring unit 212, generates a sugar signal based on the measured angle of refraction, and transmits the generated sugar signal to the controller 278. The control unit 278 receives the sugar content signal, calculates the sugar value of the fruit juice, and outputs the calculated sugar value to the outside through the output unit 120.

Then, to measure the acidity of the juice, after measuring the sugar content of the juice, the user continues to pressurize the syringe. Then, the juice guided to the sugar measurement storage unit 212 passes through the second connecting tube 260b and the quantitative guide tube 224 in order, and then moves in the direction of the third connecting tube 260c. At this time, both ends of the metering guide tube 224 is positioned to communicate with the first through hole 222a and the third through hole 222c. And the quantitative guide tube 224 is filled with juice. Thereafter, when the user inputs the rotation control signal such that the rotation unit 226 rotates forward through the input unit 271, the rotation control signal is transmitted to the control unit 278, and the control unit 278 controls the rotation driving unit 274. The rotating unit 226 is controlled to rotate. Then, both ends of the metering guide tube 224 are rotated to communicate with the second through hole 222b and the fourth through hole 222d, and in this state, the controller 278 controls the water supply valve driver 276 to supply a water supply valve ( 250 controls to transfer the water contained in the water tank 150 to the metering guide tube (224). Then, the juice filled in the quantitative guide tube 224 and the water delivered to the quantitative guide tube 224 are delivered to the acidity measurement storage unit 242. Thereafter, the controller 278 controls the power driver 273 to allow the electrode 244a to apply a predetermined voltage to the solution contained in the acidity measurement storage 242, that is, water and juice. Thereafter, the current detecting unit 244b generates an acidity signal by detecting an electrical change amount, ie, an electromotive force change, with respect to the acid of the hydrolyzed fruit juice, and the generated acidity signal is transmitted to the controller 278. Subsequently, the temperature measuring unit 246 measures the temperature of the solution accommodated in the acidity measurement storage unit 242 and transmits the temperature to the control unit 278. The controller 278 substitutes the electromotive force change and the temperature of the solution into the acidity measurement algorithm to calculate the acidity value of the juice, and outputs the acidity value to the outside through the output unit 120. In this process, the water level measurement unit 248 measures the level of the solution supplied to the acidity measurement storage unit 242 and transmits it to the control unit 278, the control unit 278 is the acidity measurement delivered from the water level measurement unit 248 When the water level of the storage unit 242 corresponds to the preset water level, the water supply valve driver 276 controls to close the water supply valve 250.

Subsequently, in order to proceed with the washing operation of the acidity measurement module 240, after measuring the acidity of the juice, the user inputs the washing control signal to the controller 278 through the input unit 271. Then, the control unit 278 controls the water supply valve driver 276 and the washing valve driver 277 to open the water supply valve 250 and the washing valve 252. Then, the water contained in the water tank 150 is guided through the metering guide tube 224 to the pH measurement storage unit 242 and then discharged to the drain tube 264 through the third drain connecting pipe 262c. 224 and the acidity measurement storage unit 242 are washed.

Subsequently, in order to proceed with the washing operation of the pressure control module 230, when the user inputs the rotation control signal such that the rotation unit 226 is reversely rotated through the input unit 271, the rotation control signal is transmitted to the controller 278. The controller 278 controls the rotation driving unit 274 to control the rotation unit 226 to reverse rotation. Then both ends of the quantitative guide tube 224 is rotated so as to communicate with the first through hole 222a and the third through hole 222c, in this state, inserting and inserting a syringe containing water such as distilled water into the inlet 102 After the pressure is applied to the syringe, the water of the syringe passes through the injection unit 102, the first connection tube 260a, the glucose measurement storage unit 212, the second connection tube 260b, the quantitative guide tube 224, The drain pipe 264 is finally drained through the third connecting pipe 260c, the pressure control body 232, and the first drain connecting pipe 262a.

As such, the present invention can easily clean various modules such as the sugar measurement module 210 and the acidity measurement module 240 by using the water of the water tank 150 or the water of the syringe without having to separate the module. Therefore, there is an effect that can quickly proceed to the subsequent sugar measurement and acidity measurement.

Although the present invention has been described in detail in the above embodiments, it is obvious that the present invention is not limited thereto, and it is obvious to those skilled in the art that various changes and modifications can be made within the technical scope of the present invention. If the technical scope falls within the scope of the claims, the technical spirit should also be regarded as belonging to the present invention.

100: housing 100a: space part
102: injection portion 110: support plate
120: output unit 150: water tank
200: measuring member
210: sugar measurement module
212: sugar measurement storage 213a: juice inlet
213b: juice extractor 214: sugar measurement sensor
214a: prism 214b: light emitting portion
214c: light receiver
220: quantitative guide module
222: quantitative guide body 222a: first through-hole
222b: second throughhole 222c: third throughhole
222d: fourth through hole 222a-1: first through hole inserting portion
222b-1: second through hole inserting portion 222c-1: third through hole inserting portion
222d-1: fourth through hole inserting portion 224: quantitative guide tube
226: rotating part
230: pressure control module
232: pressure control body 232a: supply hole
232b: drain hole 234: support pillar
235: central guide part 235a: guided slope part
235a-1: Inclined Hall 236: East Shanghai
238: support
240: acidity measurement module
242: acidity measurement unit 244: acidity measurement sensor
244a: electrode portion 244b: current sensing portion
246: temperature measuring unit 248: water level measuring unit
250: water supply valve
250a: valve connector
252: washing valve 260a: first connecting pipe
260b: 2nd connector 260c: 3rd connector
260d: fourth connector 262a: first drain connector
262b: second drain connector 262c: third drain connector
264: drain pipe
270 control means
271: input unit 272: light source driving unit
273: power drive unit 274: rotary drive unit
275: water supply drive unit 276: water supply valve drive unit
277: washing valve driving unit 278: control unit

Claims (11)

A housing having an injection portion formed to have a space therein and exposed to the outside on one side;
A water tank seated on an upper portion of the housing;
A support plate standing on the space part;
A measuring member mounted to the support plate to measure sugar and acidity of the juice; And
It is provided on the other side of the housing and includes an output unit for outputting the sugar value and acidity value of the juice received from the measuring member to the outside,
The measuring member is:
It has a glucose measuring sensor for storing the sugar injected from the injecting unit, and a sugar measuring sensor for generating a sugar signal by irradiating light in the juice direction accommodated in the sugar measuring unit and measuring the refraction angle of the light refracted in the juice Sugar measurement module;
A quantification guide module for guiding the juice delivered from the sugar measurement module;
A water supply valve selectively transferring the water contained in the water tank to the quantitative guide module;
The acidity measurement storage unit receives a predetermined amount of juice and water from the quantitative guide module, and applies a voltage to a solution stored in the acidity measurement storage unit, and detects an electrical change generated according to the acidity of the juice to detect a pH signal. An acidity measurement module having an acidity measurement sensor to generate; And
And a control means for receiving the sugar content to calculate a sugar value of the juice, receiving the acidity signal to calculate the acidity value of the juice, and transmitting the calculated sugar value and acidity value to the output unit,
The quantitative guide module is formed in a cylindrical shape, the quantitative guide is formed along the outer periphery, the first through hole, the second through hole, the third through the hole facing the first through hole and the fourth through the hole facing the second through hole A main body, a quantitative guide tube positioned to rotate inside the quantitative guide main body, and both ends of which are positioned to communicate with the first and third through holes, or with the second and fourth through holes; Includes a rotating part for rotating the metering guide tube, wherein the sugar measurement module is connected to the first through hole, the water supply valve is connected to the second through hole, the acidity measurement receiving unit is connected to the fourth through hole,
When both ends of the quantitative guide tube are positioned to communicate with the first and the third through holes, when the juice is filled from the sugar measurement module to the quantitative guide tube, the rotating unit may provide the quantitative guide tube. Rotating so that both ends of the metering guide tube is in communication with the second and fourth holes,
When both ends of the metering guide tube is positioned to communicate with the second and fourth holes, when the water supply valve delivers the water contained in the water tank to the metering guide tube, it is filled in the metering guide tube. Fruit juice and water delivered to the quantitative guide tube is delivered to the acidity measuring unit,
The amount of juice filled into the metering guide tube is determined by the internal volume of the metering guide tube,
The amount of water delivered to the metering guide tube is determined by the predetermined opening time of the water supply valve,
Further comprising a pressure control module having a supply hole in communication with the third through hole,
One side of the injection unit and the sugar measurement storage unit are interconnected by a first connection pipe, the other side of the sugar measurement storage unit and the first through hole are interconnected by a second connection pipe, and the third through hole The supply holes are interconnected by a third connecting pipe, the juice supplied from the sugar measurement module to the quantitative guide tube is filled into the quantitative guide tube and then flows into the third connecting tube,
The pressure control module is:
A pressure control body in which the supply hole is formed at a lower side and an empty space is formed therein so that the juice is supplied from the third connecting pipe;
A support pillar protruding upward from an inner lower surface of the pressure control body and having the supply hole positioned at a lower center thereof; And
Located in the interior of the support pillar and includes a Shanghai East portion which is vertically moved by the pressure of the juice flowing into the support pillar through the supply hole,
When the juice moving along the third connecting pipe is introduced into the support pillar through the supply hole, the shanghai east portion is moved upward by the pressure to open the supply hole,
When the juice does not flow into the support pillar, the shanghai east portion is located under the support pillar by gravity to block the supply hole,
The pressure control body is a sugar and acidity measurement device capable of quantitative induction of the sample, characterized in that located above the quantitative guide body.
The method of claim 1,
The sugar measurement storage unit is made of a transparent material,
The sugar measuring sensor may include a prism positioned under the sugar measuring storage unit, a light emitting unit positioned at one side of the prism and irradiating light toward the lower side of the sugar measuring storage unit, and positioned at the other side of the prism. And a light receiving unit receiving light reflected by the juice contained in the sugar measuring storage unit and measuring a refractive angle of the light to generate a sugar signal.
delete delete The method of claim 1,
It further comprises a support portion protruding in the direction of the support pillar on the inner lower surface of the pressure control body, wherein the shanghai East portion is configured so that it is not removed to the outside of the support pillar by the support portion Possible sugar and acidity measuring devices.
The method of claim 5,
A central induction part is formed to cover the inner circumference of the support pillar, and the induction inclination part is formed so that the bottom of the central induction part is inclined downward toward the center direction.
An inclined hole is formed in the center of the inclined slope so as to communicate with the supply hole.
The shanghai east portion is formed in a spherical shape but smaller than the inner diameter of the central guide portion,
When the shanghai east portion is located in the induction slope portion, the shanghai east portion is guided toward the center of the induction slope portion by the inclined shape of the induction slope portion and is positioned to block the inclined hole. Available sugar and acidity measuring device.
The method of claim 5,
The juice flowing into the support column flows out to the pressure control body through the space between the shanghai eastern part and the support column,
The lower portion of the pressure control body is a sugar and acidity measurement device capable of quantitative induction of the sample, characterized in that the drain hole is formed so as to drain the juice flowing out of the support pillar.
The method of claim 1,
The acidity measurement module further includes a temperature measurement unit for measuring the temperature of the solution accommodated in the acidity measurement storage unit,
The control means, when receiving the acidity signal to calculate the acidity value of the juice, calculates the acidity value according to the temperature of the solution received from the temperature measuring unit sugar and acidity capable of quantitative induction of the sample Measuring device.
The method of claim 1,
The acidity measurement module further includes a water level measurement unit mounted on an upper side of the acidity measurement storage unit and measuring a level of a solution delivered to the acidity measurement storage unit.
The control means, the sugar and acidity measurement capable of quantitative induction of the sample, characterized in that the water supply valve is controlled to close if the water level of the solution of the acidity measurement unit delivered from the water level measuring unit corresponds to a predetermined level Device.
The method of claim 1,
The drain pipe is located under the acidity measurement storage,
A drain connection pipe is mounted between the lower portion of the acidity measurement storage and the drain pipe,
The drain valve is equipped with a washing valve,
The control means calculates the acidity value, opens the water supply valve and the washing valve, and the water contained in the water tank is guided to the acidity measurement storage part through the quantitative guide tube and then to the drain connection tube. Sugar and acidity measurement device capable of quantitative induction of the sample, characterized in that the control to be discharged to the drain pipe.
A housing having an injection portion formed to have a space therein and exposed to the outside on one side;
A water tank seated on an upper portion of the housing;
A support plate standing on the space part;
A measuring member mounted to the support plate to measure sugar and acidity of the juice; And
It is provided on the other side of the housing and includes an output unit for outputting the sugar value and acidity value of the juice received from the measuring member to the outside,
The measuring member is:
It has a glucose measuring sensor for storing the sugar injected from the injecting unit, and a sugar measuring sensor for generating a sugar signal by irradiating light in the juice direction accommodated in the sugar measuring unit and measuring the refraction angle of the light refracted in the juice Sugar measurement module;
A quantification guide module for guiding the juice delivered from the sugar measurement module;
A water supply valve selectively transferring the water contained in the water tank to the quantitative guide module;
An acidity measurement unit receives a predetermined amount of juice and water from the quantitative guide module, and applies a voltage to a solution stored in the acidity unit and detects an electrical change generated according to the acidity of the juice to detect an acidity signal. An acidity measurement module having an acidity measurement sensor to generate; And
And a control means for receiving the sugar content to calculate a sugar value of the juice, receiving the acidity signal to calculate the acidity value of the juice, and transmitting the calculated sugar value and acidity value to the output unit,
The injection unit is a sugar and acidity measuring device capable of quantitative induction of the sample, characterized in that configured to insert a syringe containing a sample.

Images