Inverter device having shunt resistor and printed board with conductive pattern component joining shunt resistor and terminal

What is claimed is: 1. An inverter device that uses an inverter to convert direct-current voltage supplied from a rectifying component to alternating-current voltage and applies the alternating-current voltage to an inductive load, the inverter device comprising: a shunt resistor provided on a direct-current link interconnecting the rectifying component and the inverter; a first terminal passing current to the shunt resistor; a second terminal to which the current from the shunt resistor flows; and a printed board with a conductive pattern formed thereon, the conductive pattern including a first conductive pattern component that joins the shunt resistor and the first terminal to each other, and a second conductive pattern component that joins the shunt resistor and the second terminal to each other, the first conductive pattern component, as seen from a position facing the shunt resistor from the first terminal, including a first central region connecting a right-side end and a left-side end of the shunt resistor to a right-side end and a left-side end of the first terminal, a first right-side protruding region jutting out on a right side from the first central region and extending between the right side end of the shunt resistor and the right side end of the first terminal, and a first left-side protruding region jutting out on a left side from the first central region and extending between the left side end of the shunt resistor and the left side end of the first terminal, the first right-side protruding region and the first left-side protruding region being different in shape and area, and a ratio of an area of the first left-side protruding region to an area of the first right-side protruding region being a first range of 0.6 to 1.6. 2. The inverter device according to claim 1 , wherein the second conductive pattern component, as seen from a position facing the second terminal from the shunt resistor, includes a second central region connecting the right-side end and the left-side end of the shunt resistor to a right-side end and a left-side end of the second terminal, a second right-side protruding region jutting out on the right side from the second central region, and a second left-side protruding region jutting out on the left side from the second central region, and a ratio of an area of the second left-side protruding region to an area of the second right-side protruding region being in a second range of 0.6 to 1.6. 3. The inverter device according to claim 1 , wherein at least one of the first conductive pattern component and the second conductive pattern component includes a cutout defining an area that corrects a direction of the current flowing to the shunt resistor. 4. An inverter device that uses an inverter to convert direct-current voltage supplied from a rectifying component to alternating-current voltage and applies the alternating-current voltage to an inductive load, the inverter device comprising: a shunt resistor provided on a direct-current link interconnecting the rectifying component and the inverter; a first terminal passing current to the shunt resistor; a second terminal to which the current from the shunt resistor flows; and a printed board with a conductive pattern formed thereon, the conductive pattern including a first conductive pattern component that joins the shunt resistor and the first terminal to each other, and a second conductive pattern component that joins the shunt resistor and the second terminal to each other, the first conductive pattern component, as seen from a position facing the shunt resistor from the first terminal, including a first central region connecting a right-side end and a left-side end of the shunt resistor to a right-side end and a left-side end of the first terminal, a first right-side protruding, region jutting out on a right side from the first central region, and a first left-side protruding region jutting out on a left side from the s central region, a ratio of an area of the first left-side protruding region to an area of the first right-side protruding region being a first range of 0.6 to 1.6, the first conductive pattern component further including a cutout defining an area that corrects a direction of the current flowing to the shunt resistor, and when an area of the first right-side protruding region and an area of the first left-side protruding region are different, and when a protruding distance of the first right-side protruding region using the right-side end of the shunt resistor as a reference and a protruding distance of the first left-side protruding region using the left-side end of the shunt resistor as a reference are different, the cutout being provided in whichever of the first right-side protruding region and the first left-side protruding region having a larger area and a larger protruding distance. 5. An inverter device that uses an inverter to convert direct-current voltage supplied from a rectifying component to alternating-current voltage and applies the alternating-current voltage to an inductive load, the inverter device comprising: a shunt resistor provided on a direct-current link interconnecting the rectifying component and the inverter; a first terminal passing current to the shunt resistor; a second terminal to which the current from the shunt resistor flows; and a printed board with a conductive pattern famed thereon, the conductive pattern including a first conductive pattern component that joins the shunt resistor and the first terminal to each other, and a second conductive pattern component that joins the shunt resistor and the second terminal to each other, the first conductive pattern component, as seen from a position facing the shunt resistor from the first terminal, including a first central region connecting a right-side end and a left-side end of the shunt resistor to a right-side end and a left-side end of the first terminal, a first right-side protruding region jutting out on a right side from the first central region, and a first left-side protruding region jutting out on a left side from the first central region, a ratio of an area of the first left-side protruding region to an area of the first right-side protruding region being a first range of 0.6 to 1.6, the second conductive pattern component, as seen from a position facing the second terminal from the shunt resistor, including a second central region connecting the right-side end and the left-side end of the shunt resistor to a right-side end and a left-side end of the second terminal, a second right-side protruding region jutting out on the right side from the second central region, and a second left-side protruding region jutting out on the left side from the second central region, a ratio of an area of the second left-side protruding region to an area of the second right-side protruding region being in a second range of 0.6 to 1.6, the second conductive pattern component including a cutout defining an area that corrects a direction of the current flowing from the shunt resistor, and when the area of the second right-side protruding region and the area of the second left-side protruding region are different, and when a protruding distance of the second right-side protruding region using the right-side end of the shunt resistor as a reference and a protruding distance of the second left-side protruding region using the left-side end of the shunt resistor as a reference are different, the cutout being provided in whichever of the second right-side protruding region and the second left-side protruding region having a larger area and a larger protruding distance. 6. The inverter device according to claim 1 , wherein the shunt resistor includes a gro