Combustible gas detection device

The invention claimed is: 1. A combustible gas detection device comprising: a heat generation resistor disposed in an object atmosphere where its resistance changes with its own temperature; an energization control section which controls the switching of an energization state of the heat generation resistor every time a predetermined time period elapses such that the heat generation resistor alternately has resistances corresponding to two predetermined temperatures set in advance; a temperature measurement resistor disposed on a substrate having the heat generation resistor disposed thereon where its resistance changes with an environmental temperature which is the temperature of the object atmosphere; a gas concentration computation section which calculates a concentration of a combustible gas contained in the object atmosphere by using a voltage generated across the heat generation resistor which is detected when electricity is supplied to the heat generation resistor by the energization control section, and using the environmental temperature based on a voltage change which occurs as a result of a change in the resistance of the temperature measurement resistor, wherein the period of time has a length determined in advance such that a change in the environmental temperature which occurs when the energization control section switches the energization state of the heat generation resistor falls within a range of 0.5° C. 2. The combustible gas detection device according to claim 1 , wherein the two predetermined temperatures are preset to be a first predetermined temperature and a second predetermined temperature, the second predetermined temperature is lower than the first set temperature, the first and second predetermined temperatures are preset in advance such that the difference between the first and second predetermined temperatures becomes 50° C. or greater; and the gas concentration computation section determines the voltage across the heat generation resistor detected at the first predetermined temperature as a high-temperature-time voltage, determines the voltage across the heat generation resistor detected at the second predetermined temperature as a low-temperature-time voltage, calculates a humidity of the object atmosphere based on a ratio between the high-temperature-time voltage and the low-temperature-time voltage, and corrects the concentration of the combustible gas by using the humidity. 3. The combustible gas detection device according to claim 2 , further comprising: an average calculation section which detects at least one of environmental temperatures obtained based on the resistance of the temperature measurement resistor, said environmental temperatures being measured in two successive periods among the predetermined time periods controlled by the energization control section and calculates an average of a plurality of the environmental temperatures detected in the two successive periods, wherein the gas concentration computation section uses the average of the environmental temperatures calculated by the average calculation section for computing the concentration of the combustible gas contained in the object atmosphere. 4. The combustible gas detection device according to claim 2 , wherein the length of the predetermined time period is set to fall within a range of 25 msec to 1 sec. 5. The combustible gas detection device according to claim 2 , wherein the substrate has a rectangular shape as viewed from above; and when the substrate is viewed from above, the heat generation resistor is disposed on the substrate at a location closer to the center thereof as compared with the temperature measurement resistor that is formed in a region which extends along at least adjacent two sides of four sides which form a peripheral edge of the substrate. 6. The combustible gas detection device according to claim 1 , further comprising: an average calculation section which detects at least one of environmental temperatures obtained based on the resistance of the temperature measurement resistor, said environmental temperatures being measured in two successive periods among the predetermined time periods controlled by the energization control section and calculates an average of a plurality of the environmental temperatures detected in the two successive periods, wherein the gas concentration computation section uses the average of the environmental temperatures calculated by the average calculation section for computing the concentration of the combustible gas contained in the object atmosphere. 7. The combustible gas detection device according to claim 6 , wherein the length of the predetermined time period is set to fall within a range of 25 msec to 1 sec. 8. The combustible gas detection device according to claim 6 , wherein the substrate has a rectangular shape as viewed from above; and when the substrate is viewed from above, the heat generation resistor is disposed on the substrate at a location closer to the center thereof as compared with the temperature measurement resistor that is formed in a region which extends along at least adjacent two sides of four sides which form a peripheral edge of the substrate. 9. The combustible gas detection device according to claim 1 , wherein the length of the predetermined time period is set to fall within a range of 25 msec to 1 sec. 10. The combustible gas detection device according to claim 9 , wherein the substrate has a rectangular shape as viewed from above; and when the substrate is viewed from above, the heat generation resistor is disposed on the substrate at a location closer to the center thereof as compared with the temperature measurement resistor that is formed in a region which extends along at least adjacent two sides of four sides which form a peripheral edge of the substrate. 11. The combustible gas detection device according to claim 1 , wherein the substrate has a rectangular shape as viewed from above; and when the substrate is viewed from above, the heat generation resistor is disposed on the substrate at a location closer to the center thereof as compared with the temperature measurement resistor that is formed in a region which extends along at least adjacent two sides of four sides which form a peripheral edge of the substrate. 12. The combustible gas detection device according to claim 11 , wherein the temperature measurement resistor is disposed in a region which extends along three sides of the peripheral edge of the substrate. 13. The combustible gas detection device according to claim 12 , wherein a first electrode group including two electrodes connected to opposite ends of the heat generation resistor and a second electrode group including two electrodes connected to opposite ends of the temperature measurement resistor, are disposed in a region which extends along one side of the peripheral edge of the substrate.