KR101575748B1 - System for measuring salt level and sugar content using smart phone - Google Patents

Abstract

The present invention relates to a system for measuring a salt level and a sugar level using a smartphone. An objective of the present invention is to add a salt level or a sugar level measuring function to a smartphone to allow a user to carry the same and directly measure a salt level or a sugar level. To achieve the objective, the system for measuring a salt level and a sugar level using a smartphone according to an embodiment of the present invention comprises: a salt level measurement module comprising a connector disposed on one end of a body, a measurement unit disposed on the other end of the body and provided with at least one electrode to accommodate or contact a sample and a temperature sensor, and a terminal unit disposed between the one end and the other end of the body; a bio-sensor module comprising a lead terminal detachably connected to the terminal unit in the body and an electrode unit connected to the lead terminal to contact the sample injected from the outside; and a mobile communication terminal which has a measurement application loaded therein, and receives salt level or sugar level data measured by the measurement unit or the electrode unit from the salt level measurement module or the bio-sensor module by execution of the measurement application to display the salt level or sugar level data after connected to the connector.

Description

TECHNICAL FIELD [0001] The present invention relates to a system for measuring salinity and sugar content using a smartphone,

One embodiment of the present invention relates to a salinity and sugar content measurement system using a smartphone.

Salt is the most important food to taste food. Generally, the food is measured by a person who is responsible for the kitchen work as a sensory test.

However, in modern times, both recipe and food habits are becoming diverse, and cooking technology of food is becoming larger, industrialized, or standardized. Thus, what is essential in the process of standardization of cooking technology is to represent the salinity of foods, especially soup, as an objective indicator.

The salinity meter used as a conventional salinity measuring instrument amplifies the ripple current flowing through the salinity sensor and charges the integrated condenser. The current of the integrated condenser is applied to one terminal of the comparator for a predetermined time, Compensated salinity current at the output terminal of the comparator by applying the detection current of the amplified temperature sensor and converting the output of the comparator into a digital value from the A / D converter through the buffer, and displaying the digital value on the LCD module.

However, since the conventional salinity meter is expensive and has a separately provided measuring instrument, it is inconvenient to carry, and there is a problem that it is difficult to measure the salinity easily at a restaurant or a restaurant.

Patent Registration No. 10-0752415 'Sugariness Measurement System of Fruit or Fruit Drink Using Electrochemical Biosensor' Japanese Patent Application Laid-Open No. 10-2013-0115675 'Biosensor' Patent No. 10-0555840 'Biosensor for detecting ammonia oxidation inhibitor'

One embodiment of the present invention provides a salinity and sugar content measurement system using a smart phone capable of directly measuring salinity and sugar content while carrying a user by combining a salinity and a sugar content measurement function with a smartphone.

The salinity and sugar content measuring system using a smartphone according to an embodiment of the present invention includes a connector at one end of a body and at least one electrode and a temperature sensor which are contained in or contacted with the other end of the opposite end of the one end, A salinity measurement module provided with a measurement unit and having a terminal portion between the one end and the other end of the body; A biosensor module having a lead terminal detachably connected to the terminal portion in the body and having an electrode portion connected to the lead terminal and contacting the sample injected from the outside; And a measurement application, and after the measurement application is executed, the salinity or the sugar content measured by the measurement unit or the electrode unit is received from the salinity measurement module or the biosensor module, . ≪ / RTI >

The mobile communication terminal includes a first power supply unit for supplying power to the salinity measurement module or the biosensor module when the mobile communication terminal is electrically connected to the connector or the terminal unit; A signal processing unit for signal processing salinity or sugar content data measured by the salinity measurement module or the biosensor module; A display unit for externally displaying the signal-processed salinity or sugar content data; A first memory unit for storing the salinity or sugar content data and the measurement application; A second power supply for supplying power to components other than the salinity measurement module or the biosensor module; A power control unit for sensing a state of charge of the second power supply unit and selecting an operation of the first power supply unit or the second power supply unit according to a detection result; And a first control unit mounted with a measurement application and controlling the operation of each component by execution of the measurement application.

The power control unit may operate the first power supply unit when the charging power of the second power supply unit is smaller than the operation reference voltage of the salinity measurement module or the biosensor module.

The power control unit may maintain the operation of the second power supply unit when the charging power of the second power supply unit is greater than the operation reference voltage of the salinity measurement module or the biosensor module.

The salinity measurement module includes at least one electrode installed at the other end of the body and a second end connected to the temperature sensor. The salinity measurement module is connected to a connector installed at one end of the body, Wherein the printed circuit board includes a sample information detector including a conductivity measuring unit for measuring a conductivity value of a sample measured by the electrode and a temperature measuring unit for detecting a temperature value of the sample measured by the temperature sensor; A second memory unit for storing in advance a concentration value of sodium or a concentration value of sodium in relation to the electrical conductivity value according to the temperature value of the sample; The electrical conductivity value and the temperature value of the measured sample are compared with the sodium concentration value or the salinity concentration value with respect to the electrical conductivity value according to the temperature value stored in the second memory unit and the electrical conductivity value of the measured sample and the temperature A second control unit for calculating a concentration value of sodium and a concentration value of sodium corresponding to the value; And a signal relay unit connected between the sample information detecting unit and the control unit and converting the electrical conductivity value and the temperature value of the sample detected by the sample information detecting unit into a frequency signal and transmitting the frequency signal to the second control unit.

The salinity measuring module may further include a latching portion formed on the outer side of the body, the latching portion being formed in an "a" shape.

The second control unit may include a terminal unit, and the biosensor module may include a chip-type biosensor connected to the terminal unit through a lead terminal.

The sugar content data may include at least one of sugar content, microbial count, E. coli and blood sugar, urine component data, and acupuncture component data among at least one of food, blood, urine, One can be included.

According to another aspect of the present invention, there is provided a system for measuring salinity and sugar content using a smartphone, comprising: a communication module provided at one end of a body; at least one electrode contained in or contacting a sample at the opposite end of the one end; A salinity measurement module having a measurement unit including a sensor, and a terminal unit provided between one end and the other end of the body; A biosensor module having a lead terminal detachably connected to the terminal portion in the body and having an electrode portion connected to the lead terminal and contacting the sample injected from the outside; And a measurement application is connected to the communication module and is connected to the communication module via a local wireless communication network, and then the salinity or sugar content data measured by the measurement unit or the electrode unit is received from the salinity measurement module or the biosensor module And a mobile communication terminal for displaying the mobile communication terminal.

The salinity and sugar content measuring system using the smartphone according to an embodiment of the present invention can easily measure salinity and sugar content and can reduce manufacturing cost.

In an embodiment of the present invention, when a user desires to measure salinity and sugar content, a connector terminal of a salinity measurement module is connected to an input terminal of a portable smartphone, so that the user can directly carry out salinity and sugar content measurement .

1 is a schematic view of a salinity and sugar content measurement system using a smartphone according to an embodiment of the present invention.
FIG. 2 is a side view showing the side of the salinity measurement module and the biosensor module of FIG. 1. FIG.
FIG. 3 is a block diagram schematically showing the configuration of the salinity measurement module and the biosensor module of FIG. 1;
4 is a block diagram schematically showing the configuration of the smartphone of Fig.
5A and 5B are a perspective view and an equivalent circuit diagram showing a peripheral configuration for operation of the biosensor module and the biosensor module of FIG.
6 is a schematic view of a salinity and sugar content measurement system using a smartphone according to another embodiment of the present invention.

DETAILED DESCRIPTION OF EXEMPLARY EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings, in which those skilled in the art can readily implement the present invention.

FIG. 1 is a schematic view of a salinity and sugar content measurement system using a smartphone according to an embodiment of the present invention. FIG. 2 is a side view showing a side portion of the salinity measurement module and the biosensor module of FIG. 1, FIG. 4 is a block diagram schematically showing the configuration of the smartphone shown in FIG. 1, FIGS. 5A and 5B are views showing the configuration of the biosensor module and the biosensor module shown in FIG. A perspective view and an equivalent circuit diagram showing a peripheral configuration for operation of the biosensor module;

Referring to FIG. 1, the salinity and sugar content measurement system using a smartphone according to an embodiment of the present invention includes a salinity measurement module 10, a mobile communication terminal 20, and a biosensor module 30.

The salinity measurement module 10 includes a connector 110 at one end of the body 101 and at least one electrode 121 and a temperature sensor 122 at the other end opposite to the one end, The measurement unit 120 is provided.

The connector 110 is connected to a terminal of the mobile communication terminal 20 and enables data transmission and reception for salinity measurement with the salinity measurement module 10 and the mobile communication terminal 20. The communication protocol for the interface between the connector and the mobile communication terminal 20 may be variously used, or a protocol applied to the conventional mobile communication terminal 20 may be used.

At least one electrode 121 of the measuring unit 120 is formed at one end of the body 101. One end of the at least one electrode 121 is electrically connected to the printed circuit board 130 and the other end is contained in the sample to measure the salinity.

The temperature sensor 122 provided in the measuring unit 120 is formed at one end of the body 101. One end of the temperature sensor 122 is electrically connected to the printed circuit board 130, and the other end is exposed to the outside to directly contact the sample to measure the temperature value of the sample.

The sensing signal sensed by the measuring unit 120 is transmitted to the mobile communication terminal 20 through the connector 110.

One end of the body 101 is connected to a connector 110 provided at one end of the body 101 and at least one electrode 121 and a temperature sensor 122 provided at the other end of the body 101 And a printed circuit board 130 to which the other side is connected.

In addition, the body 101 has a hollow shape, and an engaging portion 102 formed in a shape of "a" According to the present invention, the engagement portion 102 is formed on the outer surface of the body 101 so that the user can be fixed to the engagement means (not shown) such as clothes or a bag, .

In the upper end of the body 101, a grip portion 103 formed in a disk shape is formed to facilitate the user's grip. Further, a connector 110 is mounted on the upper end of the grip portion 103. At this time, the connector 110 may be slidably installed in the grip portion 103 of the body 101 or may be fixedly installed. However, the present invention does not limit the manner in which the connector 110 is installed. Although not shown, a battery may be installed inside the gripper 103. At this time, the battery may be built by a battery cap (not shown) which surrounds the battery. The battery is connected to the printed circuit board 130 to supply power. For this purpose, a secondary battery that can be charged by connection with the mobile communication terminal 20 is preferably used.

The printed circuit board 130 includes a sample information detecting unit 150, a second memory unit 141, a second control unit 143, and a signal relay unit 151. The printed circuit board 130 includes a terminal 143a for electrically connecting the second controller 143 and the biosensor module 30. [

The sample information detector 150 detects the electrical conductivity of the sample measured by the electrode 121 and the temperature of the sample measured by the temperature sensor 122. The sample information detector 150 includes a conductivity measuring unit 152 for measuring the electrical conductivity of the sample measured by the electrode 121 and a temperature measuring unit 152 for measuring the temperature of the sample measured by the temperature sensor 122. [ (153). Therefore, the sample information detecting unit 150 receives the electrical conductivity value of the sample from the electrode 121 under the control of the second controller 143, and the temperature measuring unit 153 detects the temperature of the sample, And transmits the temperature value of the sample to the second controller 143, which will be described later.

The second memory unit 141 stores in advance the sodium concentration value or the salt concentration value in accordance with the electrical conductivity value according to the temperature value of the sample. The second memory unit 141 stores a concentration value of sodium or a concentration value of salt with respect to the electrical conductivity value according to the temperature value of the sample in a predetermined method (for example, a digit or a letter according to each size) . The second memory unit 141 stores a calculation program for calculating the sugar content data of the sample (i.e., sugar content, microbial count, E. coli, blood sugar, urine component, needle component, etc.).

The second controller 143 controls the electrical conductivity value and the temperature value of the sample measured by the measuring unit 120 based on the concentration value of sodium or the salt value of the sample with respect to the electrical conductivity value according to the temperature value stored in the second memory unit 141 And the concentration value of sodium and the concentration value of salinity corresponding to the electric conductivity value and the temperature value of the measured sample are calculated. Also, the second control unit 143 calculates the sugar content data of the sample calculated by the electrode unit by the stored calculation program.

For example, the second control unit 143 calculates the sodium concentration value. First, the chemical formula of sodium chloride (NaCl) contained in the aqueous solution is 58.44. In the aqueous solution, Na ⁺ and Cl ^- exist in the aqueous solution do. At this time, the abundance in the aqueous solution was Na ⁺ of 22.99, and Cl ^- And 35.45, NaCl aqueous solution in a Na ⁺ and Cl ^- is the ratio of the Na ⁺ and 39.34%, Cl ^-, accounting for 60.66%. For example, the concentration of Cl ^- in 0.6% Na ⁺ in 1% NaCl is about 0.4%. In practice, the amount of sodium (Na ⁺ ) in this aqueous solution is calculated by the formula (0.3934 g = 0.3934 sodium (Na ⁺ ) ratio x 100 g (volume) x 0.01 salt water NaCl) concentration) to 393.4 mg.

The signal relay unit 151 is connected between the sample information detection unit 150 and the second control unit 143 and converts the electrical conductivity value and the temperature value of the sample detected by the sample information detection unit 150 into a frequency signal To the second controller 143. A power management unit 142 is connected between the connector 110 and the second controller 143 to manage the power supplied from the mobile communication terminal 20. An external pulse interrupt 144 for transmitting the frequency signal supplied from the signal relay 151 to the second controller 123 is connected between the controller 143 and the signal relay 151.

The second memory unit 141, the power management unit 142, the second control unit 143 and the external pulse interrupt 144 may be implemented as a separate central processing unit 140 in the form of a printed circuit board, The signal relay unit 151, the conductivity measuring unit 152, and the temperature measuring unit 153 may be implemented as separate printed circuit boards 150.

When the connector 110 is connected to the mobile communication terminal 20, power is supplied from the mobile communication terminal 20 to the printed circuit board 130 . Then, in response to the control of the second controller 143, the external pulse interrupt 144 is waited for. When the sample contacts the electrodes 121, an electrical signal formed between the electrodes 121 and 121, that is, a signal corresponding to a change in the electrical conductivity value is transmitted through the connection connector 154 to the conductivity measuring unit 152 . Then, the electrical conductivity value is transmitted to the external pulse interrupt 144 and the second control unit 143 via the signal relay unit 151 that converts the electrical conductivity value into a frequency according to the change of the conductivity value of the sample in the conductivity measuring unit 152 do. After reading the electrical conductivity of the sample, the temperature value of the temperature sensor 122 is transmitted to the external pulse interrupt 144 and the second controller 143 via the connector 154 via the temperature measuring unit 153 . The signal relay unit 151 divides the signal read by the conductivity measuring unit 152 and the signal read by the temperature measuring unit 153 into a signal of the external pulse interrupt 154 into a conductivity signal and a temperature signal, And transmits it to the controller 143. The second controller 143 then transmits it to the mobile communication terminal 20 through the connector 110. [

The mobile communication terminal 20 is connected to the connector 110 of the salinity measuring module 10 and then is connected to the measuring unit 10 or the biosensor module 30 by the measurement application, Or salinity or sugar content data measured by the electrode unit 120 or the electrode unit. The terminal of the mobile communication terminal 20 is connected to the connector 110 of the salinity measuring module 10 in a lower border area. The terminal may have a number of pins corresponding to the connector 110 for data communication or power supply. For example, the terminal may have a number of other pins such as 8-pin, 30-pin, and the like, and the number of the pins may be different according to the manufacturer, so that it can be designed according to the type of the mobile communication terminal 20.

2, the mobile communication terminal 20 having the salinity or sugar content measurement function according to the present invention may be a smart phone, but is not limited thereto, and may be a PDC (Personal Digital Cellular) phone, (Personal Handyphone System) phone, a CDMA-2000 (1X, 3X) phone, a WCDMA (Wideband CDMA) phone, a dual band / dual mode phone, a GSM PDAs (Personal Digital Assistants), Hand-Held PCs (Hand-Held PCs), and the like, which may include communication functions such as a standard for mobile phone, MBS (Mobile Broadband System) phone, DMB (Digital Multimedia Broadcasting) , A portable terminal such as a notebook computer, a laptop computer, a WiBro terminal, an MP3 player, an MD player, and an International Mobile Telecommunication-2000 (IMT-2000) terminal providing an international roaming service and an extended mobile communication service A handheld-based wireless communication device may be used.

The mobile communication terminal 20 includes a first power supply unit 210, a signal processing unit 220, a display unit 230, a first memory unit 240, a second power supply unit 250, a power control unit 260, And a first controller 270.

The first power supply unit 210 supplies power to the salinity measurement module 10 or the biosensor module 30 when the first power supply unit 210 is electrically connected to the connector 110. In the case of the salinity measurement module 10 or the biosensor module 30, a power supply voltage for measuring salinity or sugar content is required and is different from the power output specification of the conventional mobile communication terminal 20, The salinity measurement module 10 or the biosensor module 30 may be provided with a separate power supply unit (i.e., battery) for supplying power to the biosensor module 30, as in the first power supply unit 210.

The signal processing unit 220 processes the salinity or sugar content data measured by the salinity measurement module 10 or the biosensor module 30. For example, the signal processing unit 220 converts the salinity data measured by the salinity measurement module 10 into a digital signal or various electrical signals so that the salinity data can be displayed through the display unit 230.

The display unit 230 is a device for externally displaying signal-processed salinity or sugar content data, and a display module provided in the mobile communication terminal 20 can be used. In general, the display unit 230 may be a liquid crystal display, a thin film transistor-liquid crystal display, an organic light-emitting diode, a flexible display, A three-dimensional display (3D display), or the like. In the present embodiment, salinity or sugar content data is generated and displayed as letters, numbers, symbols, and graphs using the display unit 230, and a message regarding the presence or absence of saltiness or sugar content data is also output through the display unit 140 .

The first memory unit 240 is a device for storing salinity or sugar content data and a measurement application. The first memory unit 240 may store a program for processing and control of the first control unit 270, and may temporarily store input or output data. For example. The first memory unit 240 may be a flash memory type, a hard disk type, a multimedia card micro type, a card type memory (for example, an SD or XD memory Or the like), RAM, ROM, or the like.

The second power supply unit 250 may include components other than the salinity measurement module 10 or the biosensor module 30 such as the signal processing unit 220, the display unit 230, the first memory unit 240, The control unit 260 and the first control unit 270). The second power supply unit 250 is a device that supplies power according to the conventional specifications in a normal case where the connector 110 of the salinity measurement module 10 is not coupled to the terminal of the mobile communication terminal 20. [

The power control unit 260 is a device that detects the state of charge of the second power supply unit 250 and can select the operation of the first power supply unit 210 or the second power supply unit 250 according to the detection result. That is, the power control unit 260 may operate the first power supply unit 210 when the charging power of the second power supply unit 250 is lower than the operation reference voltage of the salinity measurement module 10. The power control unit 260 may maintain the operation of the second power supply unit 250 when the charging power of the second power supply unit 250 is greater than the operation reference voltage of the salinity measurement module 10. [ The power control unit 260 may be designed to receive power from the battery of the second power supply unit 250 when the power of the dedicated battery of the first power supply unit 210 is exhausted.

The first control unit 270 includes a measurement application and executes the salinity measurement application. The first control unit 270 controls the operation of each component (i.e., the first power supply unit 210, the signal processing unit 220, the display unit 230, The first power supply unit 240, the second power supply unit 250, and the power supply control unit 260).

For example, the first control unit 270 receives the electrical conductivity value and the temperature value from the measurement unit 120 of the salinity measurement module 10 and compares the electrical conductivity value and the temperature value with the data of the first memory unit 240 Analyze. At this time, the first memory unit 240 transmits the data (the reference value of conductivity according to temperature and the reference value stored in calibration) requested by the first controller 270 to the first controller 270. If the operation is selected by the user's operation on the display unit 230 of the mobile communication terminal 20 as the salt measurement mode, the first controller 270 calculates the salinity measurement value by the display unit 230 ) Output. In addition, when the operation is selected as the sodium measurement mode by the user's operation, the first control unit 270 sends the sodium measurement value to the output of the display unit 230 through calculation. In addition, when the operation is selected as the temperature display mode by the user's operation, the first controller 270 sends the temperature value to the output of the display unit 230. Then, the display unit 230 stores or updates the result sent from the first control unit 270 after the mathematical operation is performed on the first memory unit 240, and displays the result on the screen.

The biosensor module 30 is installed in the body 101 to be connected to the second controller 143 of the salinity measuring module 10 and measures the sugar content data of the sample injected from the outside. A signal for converting the sugar content data of the sample detected by the electrode unit 32 into a frequency signal and transmitting it to the second control unit 143 between the biosensor module 30 and the second control unit 143 A relay means can be formed. The biosensor module includes a lead terminal 31 detachably connected to the terminal portion 143a in the body 101 and an electrode portion 32 connected to the lead terminal 31 and contacting the sample injected from the outside Respectively. The biosensor module 30 may include a chip type biosensor connected to the terminal portion 143a of the second controller 143 through a lead terminal 31. [

Here, the sample may be at least one of food, blood, urine, and sediment. In addition, the sugar content data may include at least one of sugar content of a sample, at least one of microbial bacteria, E. coli, and blood sugar, urine component data, and needle component data.

The biosensor module 30 includes a lead terminal 31 contacting the terminal portion 143a of the second control portion 143 and two lead terminals 31 connected to the lead terminal 31 through a lead wire. An insulating substrate 310 on which an electrode section 32 composed of an electrode and one reference electrode is printed and two exposed grooves (not shown) in which an electrode section 32 printed on the insulating substrate 310 is exposed An insulating layer 320 formed to simultaneously insulate the lead wire printed on the insulating substrate 310 and two enzyme reaction layers formed in the exposed electrode portion 32 for reaction with sugar in the sample A spacer 330 having two sample injection ports 34 and 35 having a predetermined height forming a space into which the sample can be injected into the enzyme reaction layer and an air outlet 36 A cover 350 formed on the air exhaust layer 340, It comprise. The enzyme reaction layer describes the case where the present biosensor module measures sugar content and can be used as a space for reacting with each sample when measuring microbial bacteria, Escherichia coli or blood glucose. On the other hand, techniques for measuring sugar content, microbial bacteria, E. coli, blood glucose, etc. of a sample using a biosensor are already well known in the art, so a detailed description thereof will be omitted herein.

The biosensor module 30 configured as described above is connected to the second controller 143 through the operational amplifiers AMP1 and AMP2 used as a current-to-voltage converter, the switches SW1 through SW3 and the A / D converter 33, And is connected to the communication terminal 20.

A DC voltage source is connected to the non-inverting terminal (+) of each of the operational amplifiers AMP1 and AMP2 and one side of the first switch SW1 and the third switch SW3 is connected to the inverting terminal (-). The other side of the switches SW1 and SW3 may be connected to the first working electrode 32b of the biosensor module coupled to the second control unit and the lead terminal 31 connected to the second working electrode 32c. The operational amplifiers AMP1 and AMP2 supply power to the working electrodes 32b and 32c and detect the amount of current flowing through each of the working electrodes in accordance with the power supply and output the voltage as a voltage value.

The reference electrode 32a of the biosensor module 30 coupled to the second controller 143 is grounded via the second switch SW2. The switches SW1 to SW3 are switches that are switched on / off under the control of the second controller 143, and are used for interrupting the current path of the circuit.

The A / D converter 33 converts analog voltage values output from the operational amplifiers AMP1 and AMP2 into digital data.

The second controller 143 controls the sugar content measurement operation of the biosensor module 30. For example, the second control unit 143 controls the switches SW1 to SW3 to supply power to the first and second working electrodes 32b and 32c to check whether the electrode of the sample has reached the electrode, The back switches SW1 to SW3 are controlled to supply power to the first and second working electrodes 32b and 32c to read the concentration value corresponding to the detected voltage value to calculate an average value, Is compared with the respective concentration values, whether or not an error has occurred is transmitted to the mobile communication terminal 20 for display or an average value is displayed. The control program data for this purpose may be stored in the second memory unit 141 or the second controller 143. In addition, the second memory unit 141 or the second controller 143 stores a table in which density values corresponding to the voltage values detected from the first and second working electrodes 32b and 32c are mapped.

Referring to FIG. 6, the salinity and sugar content measurement system using a smartphone according to another embodiment of the present invention includes a communication module 110 'at one end, at least one electrode contained in or contacting the sample at the other end, A salinity measuring module 10 'having a measuring part 120' including a sensor and having a terminal part between one end and the other end of the body 101 ' A biosensor module having a lead terminal detachably connected to the lead terminal and having an electrode part connected to the lead terminal and contacting the specimen injected from the outside, a measurement application, and a communication module 110 'and a short- The salinity or sugar content data measured by the measurement unit 120 'or the electrode unit from the salinity measurement module 10' or the biosensor module is transmitted And a mobile communication terminal 20 'for displaying the mobile communication terminal 20'. At this time, any one of WIFI, Zigbee, Bluetooth, and NFC (Near Field Communication) may be used for the short-range wireless communication network, but the present invention is not limited thereto.

On the other hand, the bodies 101 and 101 'of the salinity measurement module 10 and 10' are made of a polypropylene resin composition having excellent impact resistance.

The polypropylene resin composition comprises 0.01 to 0.5 parts by weight of an antioxidant and 0.01 to 0.5 parts by weight of a catalyst neutralizing agent based on 100 parts by weight of the polypropylene resin.

The polypropylene resin includes two or more ethylene-propylene random copolymers having different ethylene contents.

It is preferable that the polypropylene resin has a melt index of 1 to 10 g / 10 min (230 캜, 2.16 kg load). If the melt index is less than 1 g / 10 min, And if it exceeds 10 g / 10 min, the bubble stability and thickness uniformity are lowered, which is not suitable for use in the final product, which is not preferable.

Wherein the polypropylene resin comprises 30 to 70 parts by weight of a first ethylene-propylene random copolymer having a relatively low ethylene content and 30 to 70 parts by weight of a second ethylene-propylene random copolymer having a relatively high ethylene content -Propylene random copolymer. When the amount is less than 30 parts by weight, transparency is deteriorated. When the amount is more than 70 parts by weight, heat resistance is deteriorated.

It is preferable that the first ethylene-propylene random copolymer has an ethylene content of 0.5 to 4 wt% and the second ethylene-propylene random copolymer has an ethylene content of 5 to 15 wt%. When the content of ethylene is less than 0.5 wt% If the content exceeds 15% by weight, heat resistance of the final film deteriorates, which is not preferable.

The antioxidant preferably contains 0.01 to 0.5 parts by weight based on 100 parts by weight of the polypropylene resin. When the amount of the antioxidant is less than 0.01 part by weight, it is difficult to ensure the heat stability during sterilization of the film. When the amount of the antioxidant exceeds 0.5 parts by weight, It may become a problem in economical efficiency.

More specifically, as the antioxidant, conventionally known antioxidants can be used, specifically, tetrakis (methylene (3,5-di-t-butyl-4-hydroxy) hydrosilylate), and 1,3 , Phenol-based antioxidants such as 5-trimethyl-tris (3,5-di-t-butyl-4-hydroxybenzene) and the like, and phosphites such as tris (2,4- Based antioxidant and at least one selected from the group consisting of antioxidants.

The amount of the catalyst neutralizing agent is preferably 0.01 to 0.5 part by weight based on 100 parts by weight of the polypropylene resin. When the amount of the catalyst neutralizing agent is less than 0.01 part by weight, the amount of the catalyst neutralizing agent is too small to remain in the polymer. It is undesirable because it is difficult to neutralize in the case of remaining, and when it exceeds 0.5 part by weight, it may be eluted into the film surface, which is not preferable.

More specifically, the catalyst neutralizing agent can be conventionally used in a known catalyst, and specifically, it is preferable to use calcium stearate or synthetic hydrotalcite.

As described above, the salinity and sugar content measuring system using the smartphone according to the present invention is only one embodiment, and the present invention is not limited to the above embodiments, It will be understood by those of ordinary skill in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention.

10, 10 ': salinity measurement module 20, 20': mobile communication terminal
30, 30 ': Biosensor module 31: Lead terminal
32: electrode unit 33: A / D converter
34, 35: Sample inlet 101, 101 ': Body
102: latching portion 110: connector
110 ': communication module 120, 120': measuring part
121: electrode 122: temperature sensor
130, 130 ': printed circuit board 140: central processing unit
141: second memory unit 142: power management unit
143: second control section 143a:
150: sample information detection unit 151: signal relay unit
152: Conductivity measuring unit 153: Temperature measuring unit
154: connection connector 210: first power supply
220: signal processing unit 230:
240: first memory unit 250: second power supply unit
260: power supply control unit 270:
310: insulating substrate 320: insulating layer
330: spacer 340: air discharge layer
350: cover

Claims (9)

A measuring unit 120 including at least one electrode 121 and a temperature sensor 122 which is contained in or contacts with the sample is provided at one end of the body 101 and at the other end opposite to the one end thereof A salinity measuring module having a terminal portion 143a disposed between one end and the other end of the body 101 and a hook portion 102 formed on an outer surface of the body 101, 10);
And a lead terminal 31 connected to the lead terminal 31 so as to be detachably connected to the terminal portion 143a inside the body 101. The lead terminal 31 is connected to the lead terminal 31, A biosensor module (30) having an electrode part (32) to be brought into contact with the electrode part (30); And
Measurement application is mounted and connected to the connector 110 and then the measurement application is executed from the salinity measurement module 10 or the biosensor module 30 by the measurement part 120 or the electrode part 32 And a mobile communication terminal (20) for receiving and displaying measured salinity or sugar content data,
The connector 110 is provided at the upper end of the grip portion 103 and is moved in a sliding manner in the grip portion 103 or in a fixed state in the grip portion 103. [ A battery and a battery cap surrounding the battery are provided in the grip portion 103,
The mobile communication terminal (20)
A first power supply unit 210 for supplying power to the salinity measurement module 10 or the biosensor module 30 when electrically connected to the connector 110 or the terminal unit 143a;
A signal processing unit 220 for signal processing salinity or sugar content data measured by the salinity measurement module 10 or the biosensor module 30;
A display unit 230 for externally displaying the signal-processed salinity or sugar content data;
A first memory unit 240 for storing the salinity or sugar content data and the measurement application;
When power is supplied to components other than the salinity measurement module 10 or the biosensor module 30 and the connector 110 of the salinity measurement module 10 is not coupled to the terminal of the mobile communication terminal 20 A second power supply unit 250 for supplying power to the first power supply unit 250;
The first power supply unit 210 or the second power supply unit 250 may be operated according to a result of sensing the state of charge of the second power supply unit 250, The first power supply unit 210 is operated when the charging power of the second power supply unit 250 is lower than the operation reference voltage of the salinity measurement module 10 or the biosensor module 30, 250) is greater than the operation reference voltage of the salinity measurement module (10) or the biosensor module (30), the operation of the second power supply unit (250) is maintained, and the operation of the first power supply unit A power control unit 260 receiving power from the battery of the second power supply unit 250 when the dedicated battery is exhausted; And
And a first control unit (270) which controls the operation of each component by executing the measurement application,
The first controller 270 receives the electrical conductivity value and the temperature value from the measurement unit 120 of the salinity measurement module 10 and compares the electrical conductivity value and the temperature value with the data of the first memory unit 240 The first memory unit 240 transmits the data requested by the first controller 270 to the first controller 270 and the reference value stored at the time of calibration to the mobile communication terminal 20 The operation of the first control unit 270 is performed by the user's operation on the display unit 230 of the display unit 230. The first control unit 270 transmits the measured salt value to the output of the display unit 230 through calculation, When the operation is selected by the user's operation in the sodium measurement mode, the first control unit 270 transmits the sodium measurement value to the output of the display unit 230 through operation, The first control unit 270 sends the temperature value to the output of the display unit 230 and the display unit 230 outputs the resultant value after the mathematical operation is calculated from the first control unit 270 to the first After being stored or updated in the memory unit 240, is displayed on the screen,
The salinity measurement module (10)
At least one electrode 121 installed at the other end of the body 101 and a temperature sensor 120 installed at the other end of the body 101 and connected to the connector 110 installed at one end of the body 101, And a printed circuit board (130) to which the other side is connected to the sensor (122)
The printed circuit board (130)
A conductivity measuring unit 152 for measuring the electrical conductivity of the sample measured by the electrode 121 and a temperature measuring unit 153 for detecting the temperature of the sample measured by the temperature sensor 122, The conductivity measurement unit 152 receives the electrical conductivity value of the sample from the electrode 121 under the control of the second control unit 143 and the temperature measurement unit 153 receives the electrical conductivity value of the sample from the temperature sensor 122 A sample information detection unit 150 for receiving the value and transmitting the value to the second control unit 143;
The concentration value of sodium or the concentration value of salinity relative to the electrical conductivity value according to the temperature value of the sample is stored in advance and the concentration value of sodium or the concentration value of salinity relative to the electrical conductivity value according to the temperature value of the sample is calculated in a predetermined manner A second memory unit 141 for storing a calculation program for calculating the sugar content data of the sample;
The electrical conductivity and the temperature of the measured sample are compared with the concentration value of sodium or the concentration of sodium relative to the electrical conductivity value according to the temperature value stored in the second memory unit 141, A second controller 143 for calculating the sodium concentration value and the salt concentration value corresponding to the value and the temperature value and calculating the sugar content data of the sample calculated by the electrode unit 32 by the stored calculation program; And
The second controller 143 is connected between the sample information detector 150 and the controller 143 and converts the electrical conductivity value and the temperature value of the sample detected by the sample information detector 150 into frequency signals, And a signal relay unit (151)
The second control unit 143 includes a terminal unit 143a,
The biosensor module 30 includes a chip type biosensor connected to the terminal portion 143a through a lead terminal 31,
The body 101 of the salinity measurement module 10 is made of a polypropylene resin composition having excellent impact resistance,
Wherein the polypropylene resin composition contains 0.01 to 0.5 parts by weight of an antioxidant and 0.01 to 0.5 parts by weight of a catalyst neutralizing agent based on 100 parts by weight of the polypropylene resin,
Wherein the polypropylene resin comprises two or more kinds of ethylene-propylene random copolymers having different ethylene contents,
The polypropylene resin has a melt index of 1 to 10 g / 10 min (230 DEG C, 2.16 kg load)
Wherein the polypropylene resin comprises 30 to 70 parts by weight of a first ethylene-propylene random copolymer having a relatively low ethylene content and 30 to 70 parts by weight of a second ethylene-propylene random copolymer having a relatively high ethylene content - propylene random copolymer,
Wherein the first ethylene-propylene random copolymer has an ethylene content of 0.5 to 4% by weight and the second ethylene-propylene random copolymer has an ethylene content of 5 to 15% by weight. system. delete delete delete delete delete delete The method according to claim 1,
The sample may be at least one of food, blood, urine, and sediment,
Wherein the sugar content data includes at least one of sugar content of a sample, at least one of microbial bacteria, E. coli, and blood sugar, urine component data, and acupuncture component data. . delete

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