Sensing device

What is claimed is: 1. A sensing device that senses a substance to be sensed in a sample solution by using a piezoelectric sensor having a common piezoelectric piece on which a piezoelectric resonator is formed by providing two pairs of excitation electrodes arranged in an X direction to form a first oscillation area and a second oscillation area, in which an absorption layer absorbing the substance to be sensed in the sample solution is formed on the first oscillation area of the excitation electrodes on one surface side of the piezoelectric piece, and the absorption layer is not formed on the second oscillation area on said one surface side, the sensing device comprising: a channel forming member being contacted on said one surface side of the piezoelectric sensor, having an opposing surface opposing said one surface side having the first oscillation area and the second oscillation area via a gap, and forming a reaction channel which is a height of 0.3 mm or less on an area facing said one surface side; a liquid supply port being provided on one end side in a Y direction orthogonal to the X direction in the reaction channel and supplying the sample solution to the reaction channel; a liquid discharge port being provided on another end side in the Y direction in the reaction channel and discharging the sample solution from the reaction channel; and a groove part formed by stretching out along a flow direction of a liquid flow in the reaction channel on the opposing surface to control a liquid flow that suppresses a concentration of liquid flow caused because the first oscillation area has a hydrophilic property and the second oscillation area has a hydrophobic property due to the presence/absence of the absorption layer, wherein the first oscillation area and the second oscillation area are provided to sense, when the piezoelectric sensor is oscillated by oscillator circuits, the substance to be sensed based on oscillation frequencies of these oscillation areas. 2. The sensing device according to claim 1 , wherein said groove part has a first groove portion extending from said liquid discharge port side toward the first oscillation area, and a second groove portion extending from said liquid discharge port side toward the second oscillation area, in which end portions on the sides of the oscillation areas of the first groove portion and the second groove portion are respectively positioned not to overlap with the first oscillation area and the second oscillation area. 3. The sensing device according to claim 2 , wherein the first groove portion and the second groove portion are formed to have a distance therebetween gradually increasing toward the sides of the oscillation areas from said liquid discharge port, when seen from above. 4. The sensing device according to claim 3 , wherein: the first groove portion is on a side of a line connecting said liquid supply port and said liquid discharge port, from an edge of the reaction channel extending from said liquid discharge port to the first oscillation area side; and the second groove portion is on a side of a line, from an edge of the reaction channel extending from said liquid discharge port to the second oscillation area side. 5. A sensing device that senses a substance to be sensed in a sample solution by using a piezoelectric sensor having a common piezoelectric piece on which a piezoelectric resonator is formed by providing two pairs of excitation electrodes arranged in an X direction to form a first oscillation area and a second oscillation area, in which an absorption layer absorbing the substance to be sensed in the sample solution is formed on the first oscillation area of the excitation electrodes on one surface side of the piezoelectric piece, and the absorption layer is not formed on the second oscillation area on said one surface side, the sensing device comprising: a channel forming member being contacted on said one surface side of the piezoelectric sensor, having an opposing surface opposing said one surface side having the first oscillation area and the second oscillation area via a gap, and forming a reaction channel on an area facing said one surface side; a liquid supply port being provided on one end side in a Y direction orthogonal to the X direction in the reaction channel and supplying the sample solution to the reaction channel; a liquid discharge port being provided on another end side in the Y direction in the reaction channel and discharging the sample solution from the reaction channel; and a groove part formed on the opposing surface to control a liquid flow that suppresses a concentration of liquid flow caused because the first oscillation area has a hydrophilic property and the second oscillation area has a hydrophobic property due to the presence/absence of the absorption layer; wherein the first oscillation area and the second oscillation area are provided to sense, when the piezoelectric sensor is oscillated by oscillator circuits, the substance to be sensed based on oscillation frequencies of these oscillation areas; and wherein said groove part has a first groove portion extending from said liquid discharge port side toward the first oscillation area, and a second groove portion extending from said liquid discharge port side toward the second oscillation area, in which end portions on the sides of the oscillation areas of the first groove portion and the second groove portion are respectively positioned not to overlap with the first oscillation area and the second oscillation area. 6. The sensing device according to claim 5 , wherein the first groove portion and the second groove portion are formed to have a distance therebetween gradually increasing toward the sides of the oscillation areas from said liquid discharge port, when seen from above. 7. The sensing device according to claim 6 , wherein: the first groove portion is on a side of a line connecting said liquid supply port and said liquid discharge port, from an edge of the reaction channel extending from said liquid discharge port to the first oscillation area side; and the second groove portion is on a side of a line, from an edge of the reaction channel extending from said liquid discharge port to the second oscillation area side.