Exhaust gas latent heat recovery device

The invention claimed is: 1. A condensate economizer, comprising: a heat transfer tube disposed inside a duct through which exhaust gas flows, the heat transfer tube having a water supply inlet into which water to be heated for recovering latent heat of the exhaust gas is supplied and a water supply outlet through which the water to be heated is discharged; a water supply control part configured to control supply of the water to be heated to the water supply inlet; and a temperature sensor configured to detect an outlet temperature being a temperature of the water to be heated at the water supply outlet, wherein the water supply control part is configured to control supply of the water to be heated from the water supply inlet so that the outlet temperature is at a set temperature, wherein the heat transfer tube is disposed inside the duct so that the water supply inlet is positioned on a downstream side of the duct and the water supply outlet is positioned on an upstream side of the duct, wherein the heat transfer tube has a condensate region in which water vapor contained in the exhaust gas condenses, a dry region which is passed by the exhaust gas before reaching a condensate temperature upstream of the condensate region, and a dry-wet alteration region which is between the dry region and the condensate region, wherein the set temperature is determined so that the condensate temperature of the exhaust gas and the condensate region are formed in a specific region of a middle section of the heat transfer tube, disposed between the water supply inlet and the water supply outlet, limiting the range in which the dry-wet alternation region is formed in the heat transfer tube. 2. The condensate economizer according to claim 1 , wherein the water supply control part is configured to control a flow rate of the water to be heated supplied to the water supply inlet. 3. The condensate economizer according to claim 1 , wherein the heat transfer tube includes: linear tube sections extending linearly in a direction orthogonal to a flow passage formed by the duct; and a curved tube section coupling end portions of two of the linear tube sections with each other, wherein the middle section comprises at least one heat transfer tube module comprising a predetermined number of the linear tube sections, the predetermined number being two or more, and at least one of the curved tube section coupling the linear tube sections arranged along the flow passage, and wherein a tube coupling is disposed on each of both end portions of the heat transfer tube module. 4. The condensate economizer according to claim 1 , wherein the heat transfer tube includes: linear tube sections extending linearly in a direction orthogonal to a flow passage formed by the duct; and a curved tube section coupling end portions of two of the linear tube sections with each other, wherein the middle section includes at least one of the linear tube sections, and wherein the linear tube sections and the curved tube section are coupled by a tube coupling in the middle section. 5. The condensate economizer according to claim 1 , wherein the heat transfer tube includes: linear tube sections extending linearly in a direction orthogonal to a flow passage formed by the duct; and a curved tube section coupling end portions of two or more of the linear tube sections, wherein the latent-heat recovery device further comprises a tube sheet configured to fix end portions of the linear tube portions on each of both ends of the linear tube sections, and wherein the middle section includes at least one of the linear tube sections. 6. The condensate economizer according to claim 1 , further comprising a heating unit for pre-heating the water to be heated, wherein the water supply control part is configured to, if a temperature of the water to be heated is not higher than a predetermined temperature, supply the water to be heated which is pre-heated by the heating unit to the water supply inlet. 7. The condensate economizer according to claim 1 , wherein the duct includes: a first duct forming a bypassed passage; and a second duct forming a bypass passage bypassing the bypassed passage, wherein the latent-heat recovery device further comprises a damper for switching the bypassed passage and the bypass passage, and wherein the heat transfer tube is disposed in the bypass passage. 8. The condensate economizer according to claim 1 , wherein the water supply inlet and the water supply outlet are coupled to a header, and wherein the header and at least one of the water supply inlet or the water supply outlet is coupled to each other via a flexible tube. 9. The condensate economizer according to claim 1 , wherein the exhaust gas is exhaust gas discharged from a boiler. 10. The condensate economizer according to claim 1 , wherein the duct includes a descending section formed so as to guide the exhaust gas from above toward a bottom, and a horizontal section coupled to the downstream side of the descending section and formed so as to guide the exhaust gas in the horizontal direction, and wherein the heat transfer tube is disposed inside the descending section or the horizontal section. 11. A condensate economizer, comprising: a heat transfer tube disposed inside a duct through which exhaust gas flows, the heat transfer tube having a water supply inlet into which water to be heated for recovering latent heat of the exhaust gas is supplied and a water supply outlet through which the water to be heated is discharged; a water supply control part configured to control supply of the water to be heated to the water supply inlet; and a temperature sensor configured to detect an outlet temperature being a temperature of the water to be heated at the water supply outlet, wherein the water supply control part is configured to control supply of the water to be heated from the water supply inlet so that the outlet temperature is at a set temperature, wherein the heat transfer tube is disposed inside the duct so that the water supply inlet is positioned on a downstream side of the duct and the water supply outlet is positioned on an upstream side of the duct, wherein the set temperature is determined so that a condensate temperature of the exhaust gas is formed in a specific region of a middle section of the heat transfer tube disposed between the water supply inlet and the water supply outlet, wherein the heat transfer tube has a condensate region in which water vapor contained in the exhaust gas condenses; a dry region which is passed by the exhaust gas before reaching the condensate temperature upstream of the condensate region; and a dry-wet alteration region which is between the dry region and the condensate region, wherein the condensate region is formed in the specific region, wherein the duct includes: a first duct forming a bypassed passage; and a second duct forming a bypass passage bypassing the bypassed passage, wherein the latent-heat recovery device further comprises a damper for switching the bypassed passage and the bypass passage, wherein the heat transfer tube is disposed only in the bypass passage, and wherein a flow of the exhaust gas through the duct is configured to be switched so as to pass through either one of the bypassed passage formed in the first duct or the bypass passage formed in the second duct by the damper.