Heat exchanger

The invention claimed is: 1. A heat exchanger comprising: a plurality of heating medium channels (P 1 ) formed in a space between a pair of plates facing each other and through which a heating medium flows; a plurality of combustion gas channels (P 2 ) formed at an outer side of the plurality of heating medium channels (P 1 ) and through which a combustion gas combusted in a burner flows; a plurality of heating medium dispersion portions ( 123 and 153 ) in which opened portions ( 123 ′ and 153 ′) and blocked portions ( 123 ″ and 153 ″) are formed at an inlet portion through which the heating medium flows into the plurality of heating medium channels (P 1 ) or an outlet portion through which the heating medium flows out from the plurality of heating medium channels (P 1 ); and a heat exchange part in which the plurality of heating medium channels (P 1 ) and the plurality of combustion gas channels (P 2 ) are alternately formed adjacent to each other in a space between a plurality of plates, wherein the heat exchange part is configured to surround an outer side of a combustion chamber (C) provided at a central portion of the heat exchange part, and a plurality of the heat exchange part is provided in a stacked structure; and the plurality of heating medium dispersion portions ( 123 and 153 ) are provided at a channel in which the flow direction of the heating medium is switched in the plurality of heat exchange parts. 2. The heat exchanger of claim 1 , wherein: the plurality of heating medium dispersion portions ( 123 and 153 ) are provided and spaced apart from each other along a flow direction of the heating medium; and the opened portions ( 123 ′ and 153 ′) and the blocked portions ( 123 ″ and 153 ″) are provided to intersect with each other along the flow direction of the heating medium between adjacently disposed the plurality of heating medium dispersion portions ( 123 and 153 ). 3. The heat exchanger of claim 1 , wherein the opened portions ( 123 ′ and 153 ′) and the blocked portions ( 123 ″ and 153 ″) are alternately formed at the plurality of heating medium dispersion portions ( 123 and 153 ) in a circumferential direction thereof. 4. The heat exchanger of claim 1 , wherein each of the plurality of heating medium channels (P 1 ) is formed to direct a flow of the heating medium in one direction, and the plurality of heating medium channels (P 1 ) of adjacently disposed heat exchange parts among the plurality of heat exchange parts are formed in series to direct flows of the heating medium in opposite directions. 5. The heat exchanger of claim 4 , wherein the plurality of heating medium channels (P 1 ) are formed in parallel inside each of the plurality of heat exchange parts. 6. The heat exchanger of claim 1 , wherein: the plurality of plates are formed by stacking a plurality of unit plates, wherein a first plate and a second plate are stacked in each of the plurality of unit plates; a first flat surface ( 110 ) having a first opening (A 1 ) formed at a central portion thereof, a protruding portion ( 120 ) formed to protrude from the first flat surface ( 110 ) to a front side and having sections being communicated in a circumferential direction, and a first flange ( 130 ) extending from an edge of the first flat surface ( 110 ) to a rear side are formed on the first plate; and a second flat surface ( 140 ) having a second opening (A 2 ) formed at a central portion thereof to correspond to the first opening (A 1 ) in the front-rear direction and configured to be brought into contact with the first flat surface ( 110 ), a recessed portion ( 150 ) formed to protrude from the second flat surface ( 140 ) to a rear side, having sections being communicated in a circumferential direction, and configured to form the plurality of heating medium channels (P 1 ) between the protruding portion ( 120 ) and the recessed portion ( 150 ), and a second flange ( 160 ) extending from an edge of the second flat surface ( 140 ) to the rear side and configured to be coupled to the first flange ( 130 ) of a unit plate disposed next to the second plate are formed on the second plate. 7. The heat exchanger of claim 6 , wherein: through-holes (H 1 and H 3 ) at one side and through-holes (H 2 and H 4 ) at the other side for providing a heating medium connection channel to allow the heating medium to flow in one direction between adjacently stacked heat exchange parts; first blocked portions (H 1 ′ and H 3 ′) for inducing the heating medium flowing into the plurality of heating medium channels (P 1 ) through the through-holes (H 1 and H 3 ) at the one side to flow to the through-holes (H 2 and H 4 ) at the other side via a circumference of the combustion chamber (C) in one direction; and second blocked portions (H 2 ′ and H 4 ′) for inducing the heating medium flowing into the plurality of heating medium channel (P 1 ) through the through-holes (H 2 and H 4 ) at the other side to flow to the through-holes (H 1 and H 3 ) at the one side via the circumference of the combustion chamber (C) in an opposite direction are formed at one side portion of the heat exchange part. 8. The heat exchanger of claim 7 , wherein the plurality of heating medium dispersion portions ( 123 and 153 ) are provided at each of the through-holes (H 1 and H 3 ) at the one side and the through-holes (H 2 and H 4 ) at the other side. 9. The heat exchanger of claim 6 , wherein: the protruding portion ( 120 ) is configured with a first protruding piece ( 120 a ) and a second protruding piece ( 120 b ), which are alternately disposed along a circumferential direction and have different heights in the front-rear direction; and the recessed portion ( 150 ) is configured with a first recessed piece ( 150 a ) and a second recessed piece ( 150 b ), which are alternately disposed along the circumferential direction and have different heights in the front-rear direction. 10. The heat exchanger of claim 6 , wherein: a plurality of protrusions ( 121 ) protruding toward the plurality of heating medium channels (P 1 ) are formed at the protruding portion ( 120 ); and a plurality of protrusions ( 151 ) protruding toward the plurality of heating medium channels (P 1 ) and being brought into contact with the plurality of protrusions ( 121 ) are formed at the recessed portion ( 150 ). 11. The heat exchanger of claim 6 , wherein: a plurality of protrusions ( 122 ) protruding toward the plurality of combustion gas channels (P 2 ) are formed at the protruding portion ( 120 ); and a plurality of protrusions ( 152 ) protruding toward the plurality of combustion gas channels (P 2 ) and being brought into contact with the plurality of protrusions ( 122 ) are formed at the recessed portion ( 150 ).