Material measuring device, material measuring system and material measuring method

The invention claimed is: 1 . A particle material measuring device comprising: a piezoelectric substrate including a sensing region; and first to n-th electrode modules provided on one surface of the piezoelectric substrate, wherein each of the first to n-th electrode modules includes first and second comb electrodes that are a comb-shaped electrode pair opposing each other based on the sensing region, and the piezoelectric substrate is formed of a piezoelectric material that is excited by the first to n-th electrode modules to generate a surface acoustic wave (where n is a natural number greater than 1), wherein the first to n-th electrode modules are radially arranged around the sensing region. 2 . The particle material measuring device of claim 1 , wherein a gap between the first and second comb electrodes of any one of the first to n-th electrode modules is greater or smaller than a gap between the first and second comb electrodes of another of the first to n-th electrode modules so that the first to n-th electrode modules generate a surface acoustic wave having multiple resonance frequencies. 3 . The particle material measuring device of claim 1 , wherein each of the first to n-th electrode modules includes first and second reflective portions, and the first and second reflective portions are disposed behind the first and second comb electrodes based on the sensing region, reflect the surface acoustic wave in a direction parallel to a traveling direction of a surface acoustic wave excited by the first and second comb electrodes, and are formed of a plurality of diffraction gratings. 4 . The particle material measuring device of claim 1 , further comprising: at least one heating unit including a heating wire heating a measurement object. 5 . The particle material measuring device of claim 4 , wherein the heating unit is provided on one surface of the piezoelectric substrate and includes at least one heater module formed of at least one heating wire that is repeatedly formed in a zigzag shape to generate heat. 6 . The particle material measuring device of claim 5 , wherein the heater module has a structure in which a width of the zigzag shape increases in a direction away from the sensing region. 7 . The particle material measuring device of claim 5 , wherein the heater module includes at least one thermistor element. 8 . The particle material measuring device of claim 1 , further comprising: at least one cooling unit provided on at least one of one surface and the other surface of the piezoelectric substrate and including a thermoelectric element cooling a measurement object. 9 . A particle material measuring system comprising: the particle material measuring device comprising a piezoelectric substrate including a sensing region and first to n-th electrode modules provided on one surface of the piezoelectric substrate, wherein each of the first to n-th electrode modules includes first and second comb electrodes that are a comb-shaped electrode pair opposing each other based on the sensing region, and the piezoelectric substrate is formed of a piezoelectric material that is excited by the first to n-th electrode modules to generate a surface acoustic wave (where n is a natural number greater than 1); a power supply module supplying power to at least one of the first to n-th electrode modules; and a signal processing module receiving a signal from at least one of the first to n-th electrode modules and calculating physical properties of a measurement object provided in the sensing region, wherein the piezoelectric substrate is excited by the first to n-th electrode modules to generate a surface acoustic wave having multiple resonance frequencies. 10 . The particle material measuring system of claim 9 , wherein the power supply module is connected to at least one of each of the first and second comb electrodes and the signal processing module to apply a direct current (DC) or alternating current (AC) voltage. 11 . The particle material measuring system of claim 9 , further comprising: a heating unit including a heating wire heating the measurement object, wherein the power supply module supplies power to the heating unit. 12 . The particle material measuring system of claim 11 , wherein the signal processing module directly varies a temperature of the heating unit or indirectly varies a temperature of the heating unit by controlling power supplied to the heating unit by the power supply module, and calculates physical properties of the measurement object according to the changed temperature. 13 . The particle material measuring system of claim 12 , wherein the signal processing module measures a frequency of a surface acoustic wave generated by the piezoelectric substrate based on a signal received from at least one of the first to n-th electrode modules, and directly or indirectly controls a temperature of the heating unit to control a frequency of the surface acoustic wave. 14 . A particle material measuring method using the system of claim 11 , wherein the signal processing module includes: (a) controlling the power supply module connected to the heating unit so that the heating unit reaches a predetermined temperature; (b) controlling the power supply module so that power is applied to at least one of the first to n-th electrode modules; (c) receiving a sensing signal from at least one of the first to n-th electrode modules; and (d) calculating physical properties of a measurement object provided in the sensing region based on the sensing signal. 15 . The particle material measuring method of claim 14 , further comprising, between (b) and (c), (e) measuring a frequency of a surface acoustic wave having multiple resonance frequencies generated by the piezoelectric substrate excited by the first to n-th electrode modules; and (f) controlling the heating unit to vary the frequency of the surface acoustic wave. 16 . The particle material measuring method of claim 15 , wherein in (f), when the frequency of the surface acoustic wave measured in (e) is lower than a command frequency, the temperature of the heating unit is controlled to increase, and when the frequency of the surface acoustic wave is higher than the command frequency, the temperature of the heating unit is controlled to decrease.