Heat exchanger with lateral fluid supply

The invention claimed is: 1. A heat exchanger ( 10 ) comprising an assembly of plates ( 12 ) stacked in a longitudinal stacking direction (x) to form a heat exchanger body ( 14 ) designed for the circulation of a first fluid, comprising a connection device ( 19 ) arranged at one extremity of the heat exchanger body ( 14 ) in the longitudinal stacking direction (x), wherein the connection device ( 19 ) includes an end plate ( 20 ) terminating at one end in a protrusion ( 29 ) and a cover ( 22 ) that are assembled together to jointly delimit an inlet duct ( 24 ) and an outlet duct ( 26 ), respectively, to admit the fluid into the heat exchanger body ( 14 ) and discharge the fluid from the heat exchanger body ( 14 ), wherein each one of the plates ( 12 ) comprising the assembly of plates ( 12 ) includes a first end boss ( 16 ) located at one end of the plate ( 12 ) and a second end boss ( 18 ) located at an opposite end of the plate ( 12 ) such that each one of the plates ( 12 ) defines a length extending in a vertical direction (z) from the first end boss ( 16 ) to the second end boss ( 18 ), wherein the vertical direction (z) is substantially perpendicular to the longitudinal stacking direction (x), wherein each first end boss ( 16 ) and each second end boss ( 18 ) has openings extending in parallel to the longitudinal stacking direction (x) of the plates ( 12 ), wherein the respective openings of the second end bosses ( 12 ) define circulations ducts; wherein the end plate ( 20 ) is assembled adjacent to an endmost one of the assembly of plates ( 12 ) located at the one extremity of the heat exchanger body ( 14 ) such that the end plate ( 20 ) extends along the length of the endmost one of the assembly of plates ( 12 ) from the first end boss ( 16 ) to the second end boss ( 18 ) and such that the protrusion ( 29 ) of the end plate ( 20 ) is pressed against the second end boss ( 18 ) of the endmost one of the plates ( 12 ) to close the circulation ducts defined by the respective openings of the second end boss ( 18 ), wherein the inlet duct ( 24 ) and the outlet duct ( 26 ) open out in a transversal direction (y) substantially perpendicular to the longitudinal stacking direction (x), and wherein the inlet duct ( 24 ) and the outlet duct ( 26 ) provide parallel arced flows which do not overlap each other in the longitudinal stacking direction (x). 2. The heat exchanger ( 10 ) as claimed in claim 1 , wherein the end plate ( 20 ) has a pressed part ( 30 ) including a first inlet impression ( 32 ) and a first outlet impression ( 34 ). 3. The heat exchanger ( 10 ) as claimed in claim 2 , wherein the cover ( 22 ) includes a second inlet impression ( 46 ) and a second outlet impression ( 48 ). 4. The heat exchanger ( 10 ) as claimed in claim 2 , wherein the first inlet impression ( 32 ) cooperates with a second inlet impression ( 46 ) to define the inlet duct ( 24 ) and the first outlet impression ( 34 ) cooperates with a second outlet impression ( 48 ) to define the outlet duct ( 26 ). 5. The heat exchanger ( 10 ) as claimed in claim 4 , wherein the inlet duct ( 24 ) and the outlet duct ( 26 ) each have cross sections essentially defined by the second inlet impression ( 46 ) and the second outlet impression ( 48 ) of the cover ( 22 ). 6. The heat exchanger ( 10 ) as claimed in claim 2 , wherein a depth (P 1 , P 2 ) of the first inlet impression ( 32 ) and the first outlet impression ( 34 ) are less than a depth (P 3 , P 4 ) of the second inlet impression ( 46 ) and the second outlet impression ( 48 ). 7. The heat exchanger ( 10 ) as claimed in claim 6 , wherein the depth (P 1 , P 2 ) of the first inlet impression ( 32 ) and the first inlet impression ( 34 ) is less than 1 mm. 8. The heat exchanger ( 10 ) as claimed in claim 6 , wherein the depth (P 3 , P 4 ) of the second inlet impression ( 46 ) and the second outlet impression ( 48 ) is less than 10 mm. 9. The heat exchanger ( 10 ) as claimed in claim 1 , wherein the outlet duct ( 26 ) has a first extremity ( 74 ) opening into the heat exchanger body ( 14 ) and a second extremity ( 76 ) opening outside the heat exchanger body ( 14 ), and the outlet duct ( 26 ) has a hydraulic diameter (Dh), throughout an intermediate region between the first extremity ( 74 ) and the second extremity ( 76 ) between a first hydraulic diameter value (Dh 1 ) at the first extremity ( 74 ) of the outlet duct ( 26 ) and a second hydraulic diameter value (Dh 2 ) at the second extremity ( 76 ) of the outlet duct ( 26 ). 10. The heat exchanger ( 10 ) as claimed in claim 9 , wherein the hydraulic diameter value (Dh) of the outlet duct ( 26 ) increases from the first hydraulic diameter value (Dh 1 ) at the first extremity ( 74 ) of the outlet duct ( 26 ) to the second hydraulic diameter value (Dh 2 ) at the second extremity ( 76 ) of the outlet duct ( 26 ). 11. The heat exchanger ( 10 ) as claimed in claim 10 , wherein the first hydraulic diameter value (Dh 1 ) is between 10.5 mm and 11 mm. 12. The heat exchanger ( 10 ) as claimed in claim 10 , wherein the second hydraulic diameter value (Dh 2 ) is between 15 mm and 16 mm. 13. The heat exchanger ( 10 ) as claimed in claim 1 , wherein an internal width (Ls) of the outlet duct ( 26 ), considered in an assembly plane of the end plate ( 20 ) and of the cover ( 22 ), is greater than an internal width (Le) of the inlet duct ( 24 ), considered in the assembly plane of the end plate ( 20 ) and of the cover ( 22 ). 14. The heat exchanger ( 10 ) as claimed in claim 13 , wherein the internal width (Ls) of the outlet duct ( 26 ) is between 14.5 mm and 16.8 mm. 15. The heat exchanger ( 10 ) as claimed in claim 1 , wherein a pressed reservoir ( 40 ) is placed between the end plate ( 20 ) and an adjacent plate ( 12 ) of the heat exchanger body ( 14 ), opposite the cover ( 22 ), to provide fluid communication with the inlet duct ( 24 ) and the outlet duct ( 26 ).