Heat exchanger

The invention claimed is: 1. A heat exchanger comprising: a heat exchange unit ( 200 ) in which heating medium flow channels through which a heating medium flows in a space between a plurality of plates and combustion gas flow channels through which a combustion gas combusted in a burner ( 100 ) flows are alternately formed to be adjacent to each other, wherein the heat exchange unit ( 200 ) is configured with a sensible heat unit ( 200 A) configured to surround an outer side of a combustion chamber (C), configured with an area at one side of each of the plates, and configured to heat the heating medium using sensible heat of the combustion gas generated by the combustion in the burner ( 100 ); and a latent heat unit ( 200 B) configured with an area at the other side of each of the plates and configured to heat the heating medium using latent heat of water vapor contained in the combustion gas which undergoes heat exchange in the sensible heat unit ( 200 A), and a flow channel cap ( 400 ) is coupled to a rear side of the sensible heat unit ( 200 A) and configured to provide a combustion gas bypass flow channel ( 400 a ) of the combustion gas to allow a combustion gas which passes through a combustion gas flow channel formed at an upper portion of the sensible heat unit ( 200 A) to flow into a combustion gas flow channel of the latent heat unit ( 200 B). 2. The heat exchanger of claim 1 , wherein: a plurality of first combustion gas flow holes ( 203 ) are formed at the upper portion of the sensible heat unit ( 200 A) to allow the combustion gas generated in the combustion chamber (C) to flow to the combustion gas bypass flow channel ( 400 a ) formed between the sensible heat unit ( 200 A) and the flow channel cap ( 400 ), and a plurality of second combustion gas flow holes ( 204 ) are formed at a lower portion of the sensible heat unit ( 200 A) to allow the combustion gas which passes through the combustion gas bypass flow channel ( 400 a ) to flow to the combustion gas flow channel of the latent heat unit ( 200 B). 3. The heat exchanger of claim 1 , wherein: the plurality of plates are formed by stacking a plurality of unit plates each having a first plate and a second plate which are stacked, the heating medium flow channel is formed between the first plate and the second plate of the unit plate, and the combustion gas flow channel is formed between a second plate constituting a unit plate disposed at one side of adjacently stacked unit plates and a first plate of a unit plate disposed at the other side thereof. 4. The heat exchanger of claim 3 , wherein: the first plate is configured with a first plane portion ( 210 ); a first protrusion ( 220 ) protruding from one side of the first plane portion ( 210 ) to a front side and having a first opening (A 1 ) formed at a center of the first protrusion ( 220 ) to constitute the sensible heat unit ( 200 A); and a second protrusion ( 230 ) protruding forward from the other side of the first plane portion ( 210 ) to the front side and configured to form the latent heat unit ( 200 B), and the second plate is configured with a second plane portion ( 250 ); a first recess ( 260 ) recessed from one side of the second plane portion ( 250 ) to the rear side, configured to form a sensible heat unit heating medium flow channel (P 3 ) between the first protrusion ( 220 ) and the first recess ( 260 ), and having a second opening (A 2 ) corresponding to the first opening (A 1 ); and a second recess ( 270 ) recessed from the other side of the second plane portion ( 250 ) to the rear side, and configured to form a latent heat unit heating medium flow channel (P 1 ) between the second protrusion ( 230 ) and the second recess ( 270 ). 5. The heat exchanger of claim 4 , wherein, when the first plate and the second plate are stacked, the first plane portion ( 210 ) and the second plane portion ( 250 ) are in contact with each other, and the second protrusion ( 230 ) and the second recess ( 270 ) are configured to be bent in opposite directions. 6. The heat exchanger of claim 4 , wherein: a plurality of first gap maintaining portions ( 222 ) protruding toward the combustion gas flow channel are formed at the first protrusion ( 220 ), and a plurality of second gap maintaining portions ( 262 ) are formed at the first recess ( 260 ) at positions corresponding to the plurality of first gap maintaining portions ( 222 ) to protrude toward the combustion gas flow channel. 7. The heat exchanger of claim 6 , wherein a protruding end of each of the plurality of first gap maintaining portions ( 222 ) and a protruding end of each of the plurality of second gap maintaining portions ( 262 ) are formed to be in contact with each other. 8. The heat exchanger of claim 1 , wherein: each of the plates has an upright structure such that the sensible heat unit ( 200 A) is disposed at an upper portion and the latent heat unit ( 200 B) is disposed at a lower portion, and the burner ( 100 ) is assembled by being inserted into a space of the combustion chamber (C) in a horizontal direction from a front surface thereof. 9. The heat exchanger of claim 1 , wherein each of the plates constituting the sensible heat unit ( 200 A) is formed such that a width (E 1 ) of a side area facing the latent heat unit ( 200 B) is formed to be larger than that (E 2 ) of an area opposite the latent heat unit ( 200 B). 10. The heat exchanger of claim 1 , wherein: the latent heat unit ( 200 B) is configured with a heating medium inlet ( 201 ) into which the heating medium flows, and a plurality of latent heat unit heating medium flow channels (P 1 ) formed between the plurality of plates in parallel thereto and configured to communicate with the heating medium inlet ( 201 ), and the sensible heat unit ( 200 A) is configured with a heating medium outlet ( 202 ) through which the heating medium flows, and a plurality of sensible heat unit heating medium flow channels (P 3 ) formed between the plurality of plates and connected in series between the plurality of latent heat unit heating medium flow channels P 1 and the heating medium outlet ( 202 ). 11. The heat exchanger of claim 10 , wherein: a sensible heat unit combustion gas flow channel (P 4 ) is provided between the sensible heat unit heating medium flow channels (P 3 ), and a latent heat unit combustion gas flow channel (P 2 ) communicating with the sensible heat unit combustion gas flow channel (P 4 ) is provided between the latent heat unit heating medium flow channels (P 1 ). 12. The heat exchanger of claim 10 , wherein: through-holes (H 1 ) and (H 5 ) provided at one side of the latent heat unit ( 200 B) and through-holes (H 2 ) and (H 6 ) provided at the other side, which communicate with the plurality of latent heat unit heating medium flow channels (P 1 ), are diagonally formed at the latent heat unit ( 200 B) to connect the plurality of latent heat unit heating medium flow channels (P 1 ) in parallel, and through-holes (H 3 ) and (H 7 ) provided at one side of the sensible heat unit ( 200 A) and through-holes (H 4 ) and (H 8 ) provided at the other side, which communicate with the sensible heat unit heating medium flow channels (P 3 ), are diagonally formed at the sensible heat unit ( 200 A) to connect the sensible heat unit heating medium flow channels (P 3 ) in series. 13. The heat exchanger of claim 12 , wherein: a heating medium flowing into the sensible heat unit heating medium flow channel (P 3 ) through the through-holes (H 3 ) and (H 7 ) provided at the one side thereof branches off to flow towards the through-holes (H 4 ) and (H 8 ) formed at the other side in a diagonal direction;