Heat exchanger

The invention claimed is: 1. A heat exchanger comprising: a burner configured to burn a mixture of air and fuel; and a heat exchange unit configured to exchange heat between combustion gas generated by combustion of the burner and a heating medium, wherein the heat exchange unit is formed by a plurality of stacked unit plates, wherein the heat exchange unit comprises a sensible-heat exchange unit and a latent-heat exchange unit, the sensible-heat exchange unit and the latent-heat exchange unit being integrally formed by the plurality of stacked unit plates and arranged around a periphery of the burner in a coaxial structure such that the sensible-heat exchange unit is part of the stacked unit plates and is located at an inner region of each of the plurality of stacked unit plates, and the latent-heat exchange unit is part of the stacked unit plates and is integrally formed with the sensible-heat exchange unit at an outer region of each of the plurality of stacked unit plates, wherein a first heating medium passage and a first combustion gas passage are separately and alternately formed adjacent to each other through the entirety of the stacked unit plates of the sensible-heat exchange unit, a second heating medium passage and a second combustion gas passage are separately and alternately formed adjacent to each other through the entirety of the stacked unit plates of the latent-heat exchange unit, and a combustion gas discharge passage is formed at an edge of each of the plurality of unit plates to discharge combustion gas that has passed through the first combustion gas passage and the second combustion gas passage, wherein, in the plurality of stacked unit plates, a flow direction of the heating medium passing through the first heating medium passage of a first unit plate of the plurality of stacked unit plates and a flow direction of the heating medium passing through the first heating medium passage of a second unit plate adjacent to the first unit plate of the plurality of stacked unit plates are opposite to each other, and wherein each respective flow direction extends entirely from an inlet to an outlet of the respective heating medium passage. 2. The heat exchanger of claim 1 , wherein each of the plurality of unit plates is formed with a first plate and a second plate which are longitudinally stacked, wherein the first plate includes: a first plane portion in which a first through hole is formed at a central part thereof; a first flange portion formed to extend from an edge of the first plane portion to an upper side thereof and bent to an outward side thereof; and a protruding portion of the first heating medium passage and a protruding portion of the second heating medium passage that are spaced apart from each other at a region between the edge of the first plane portion and the first through hole, wherein the protruding portion of the first heating medium passage and the protruding portion of the second heating medium passage have an upwardly convex shape, and wherein the second plate includes: a second plane portion in which a second through hole of a shape matching that of the first through hole is formed at a central part of the second plane portion and having an upper surface in contact with a bottom surface of the first plane portion; a second flange portion that extends from an edge of the second plane portion to a lower side thereof and bent to an outward side; and a depressed portion of the first heating medium passage and a depressed portion of the second heating medium passage that are spaced apart from each other at a region between the edge of the second plane portion and the second through hole and having a downwardly concave shape, wherein the first heating medium passage is formed between the protruding portion of the first heating medium passage and the depressed portion of the first heating medium passage, and the second heating medium passage is formed between the protruding portion of the second heating medium passage and the depressed portion of the second heating medium passage. 3. The heat exchanger of claim 2 , wherein the first flange portion is higher than a protruding height of each of the protruding portion of the first heating medium passage and the protruding portion of the second heating medium passage, the second flange portion is deeper than a depressed depth of each of the depressed portion of the first heating medium passage and the depressed portion of the second heating medium passage, and the plurality of unit plates are arranged side by side. 4. The heat exchanger of claim 3 , wherein a plurality of first gap maintaining protruding portions protrude at the same height as that of the first flange portion at the protruding portion of the first heating medium passage, a plurality of second gap maintaining protruding portions protrude at the same height as that of the first flange portion at the protruding portion of the second heating medium passage, a plurality of first gap maintaining depressed portions are depressed at the same depth as that of the second flange portion at the depressed portion of the first heating medium passage, and a plurality of second gap maintaining depressed portions are depressed at the same depth as that of the second flange portion at the depressed portion of the second heating medium passage. 5. The heat exchanger of claim 3 , wherein a first combustion gas outlet is formed at the edge of the first plane portion to provide the combustion gas discharge passage, and a second combustion gas outlet is formed at a position on the edge of the second plane portion, wherein the position longitudinally aligns with the first combustion gas outlet. 6. The heat exchanger of claim 3 , wherein a turbulent flow portion is formed at the protruding portion of the first heating medium passage, the depressed portion of the first heating medium passage, the protruding portion of the second heating medium passage, and the depressed portion of the second heating medium passage. 7. The heat exchanger of claim 4 , wherein the protruding portion of the first heating medium passage is arranged along a circumferential direction of the first plate, the depressed portion of the first heating medium passage is arranged along a circumferential direction of the second plate, and a through hole is formed at the first gap maintaining protruding portion and the first gap maintaining depressed portion, wherein the through hole is located to reverse a direction of the first heating medium passage in the unit plate being located at the upper side against that of the first heating medium passage in the unit plate being located at the lower side. 8. The heat exchanger of claim 4 , wherein a through hole is formed at the first gap maintaining protruding portion and the first gap maintaining depressed portion so as to connect a first heating medium passage of a first unit plate located at an upper side of the stacked unit plates to a first heating medium passage of a second unit plate located at a lower side of the stacked unit plates, wherein the through hole is located so as to reverse a direction of the first heating medium passage in the first unit plate located at the upper side against that of the first heating medium passage of the second unit plate located at the lower side. 9. The heat exchanger of claim 8 , wherein a heating medium, which flowed in through a through hole formed at one side of a first plate configuring the first unit plate located at the upper side, flows in one direction along the first heating medium passage of the first unit plate, and then passes through a through hole formed at a second plate located at an opposite side against the first plate and a through hole for