FR2916233A1 - MOTOR VEHICLE ENGINE COMPRISING AN INNOVATIVE COOLING CIRCUIT - Google Patents

Abstract

The invention relates to a motor vehicle engine (10), comprising an internal cooling with, in series, a pump (15), a first water chamber (20) permitting a longitudinal circulation of a cooling liquid along the cylinders (14), a second water chamber (22), permitting transverse circulation of the cooling liquid across a cylinder head (16), a third water chamber (24) permitting the circulation of the cooling liquid along the opposite side of the cylinders (14), characterised in that the second water chamber (22) is arranged in a lower part of the cylinder head (16) and the cooling circuit comprises a fourth water chamber (28) arranged in an upper part of the cylinder head (16), supplied by the second water chamber (22) and communicating with the third water chamber (24).

Description

"Motor vehicle engine having a cooling circuit

  The invention relates to a combustion engine of a motor vehicle.

  The invention more particularly relates to a motor vehicle engine comprising at least one engine block which comprises a row of aligned cylinders and which is capped with a cylinder head, an internal cooling circuit comprises successively, from upstream to downstream, the at least one cooling pump, an inlet port, a first water chamber allowing the longitudinal circulation of a coolant along one side of the row of cylinders, a second water chamber, allowing the transverse circulation of the coolant through a portion of the cylinder head, a third water chamber permitting the longitudinal circulation of the coolant along the opposite side of the row of cylinders, and an outlet port. Many examples of thermal engines of this type are known. According to this design, the cooling of the cylinder head is ensured by a single water chamber. This design does not allow optimal cooling of the cylinder head. Another known design is to cool the cylinder head by two lower and upper independent water chambers, the upper water chamber being fed by the lower water chamber and having its own outlet port independent of the outlet port associated with a single water chamber arranged on both sides of the two sides of the row of cylinders. This design, although offering better cooling of the cylinder head generates significant head losses in the water chamber arranged on either side of both sides of the row of cylinders because of the presence of the orifice. outlet associated with the upper water chamber of the cylinder head. The invention proposes a new cooling system design of an engine, comprising a cylinder head cooled by two lower and upper water chambers, reducing the pressure drops. For this purpose, the invention proposes a heat engine of the type described above, characterized in that the second water chamber is arranged in a lower part of the cylinder head and in that the cooling circuit further comprises a fourth chamber. water which is arranged in an upper part of the cylinder head, which is fed upstream by the second water chamber, and which communicates downstream with the third water chamber. According to other features of the invention - the fourth water chamber allows the longitudinal circulation of the coolant in the upper part of the cylinder head, - the second water chamber is arranged near the combustion chambers of the engine cylinders to ensure cooling and the fourth water chamber is intended in particular to ensure the outgassing of the cooling circuit, - the fourth water chamber communicates with the third water chamber via orifices arranged at its longitudinal ends and associated ducts which pass through the second water chamber to open directly into the third water chamber; - the second water chamber is fed by the first water chamber via a series of water of longitudinally disposed orifices and feeds the third water chamber via a series of orifices arranged longitudinally, 3 - the the fourth water chamber is fed by the second water chamber through a series of orifices arranged at least transversely, the outlet orifice is arranged at a longitudinal end of the third water chamber, the outlet orifice is arranged in an intermediate part of the third water chamber; the cylinder head is made in two parts, each having separate cavities associated with each of the third and fourth water chambers; the cylinder head is made in a single part within which subdivision means delimit two separate cavities associated respectively with the third and fourth water chambers. Other features and advantages of the invention will appear on reading the detailed description which follows for the understanding of which reference will be made to the appended drawings in which: FIG. 1 is a schematic perspective view of an engine according to a first known design of the state of the art; FIG 2 is a schematic perspective view of an engine according to a second known design of the state of the art; Figure 3 is a schematic perspective view of an engine according to the invention. In the following description, like reference numerals designate like parts or having similar functions. FIG. 1 shows a first known design of a motor vehicle engine 10. In known manner, the engine 10 comprises at least one engine block 12 which comprises a row of cylinders 14 aligned and which is capped with a cylinder head 16. The engine 10 comprises an internal cooling circuit which comprises successively, from upstream to downstream as shown by the arrows of Figure 1, at least one cooling pump 15, an inlet port 18, a first water chamber 20 for the longitudinal circulation of a coolant along a side of the row of cylinders 14, io a second water chamber 22, allowing the transverse circulation of the coolant through a portion of the cylinder head 16, a third water chamber 24 for the circulation of the cooling liquid along the opposite side of the row of cylinders 14, and an outlet port 26. According to this design, the cooling of the cylinder head 16 is provided only by the second water chamber 22. This design does not allow and not optimal cooling of the cylinder head, especially around the combustion chambers (not shown) of the engine. According to a second known design which has been shown in FIG. 2, a motor 10 may comprise a yoke 16 comprising two independent lower and upper water chambers 28, the upper water chamber 28 being fed by the water chamber. 22, and having its own outlet port 30 independent of the outlet port 26 associated with a single water chamber 20 arranged on either side of both sides of the row of cylinders 14 of the engine block 12. This design, although providing a better cooling of the cylinder head 16 generates significant head losses in the water chamber arranged on both sides of the row of cylinders, in particular because of the presence of the cylinder. outlet port 30 associated with the upper water chamber 28 of the cylinder head.

  To overcome these disadvantages, as illustrated in Figure 3, the invention provides a motor 10 substantially having the basic characteristics of the first known design of the state of the art, and characterized in that the second chamber of water 22 is arranged in a lower part of the cylinder head 16 and in that the cooling circuit further comprises a fourth water chamber 28 which is arranged in an upper part of the cylinder head 16, which is supplied upstream by the second chamber 22 of water, and which communicates downstream directly with the third water chamber 24. Advantageously, as shown by the arrows of Figure 3, unlike the second water chamber 22, the fourth chamber water 28 allows the longitudinal circulation of the coolant in the upper part of the cylinder head 16. The cooling of the cylinder head 16 is thus organized according to specific needs. The lower part of the cylinder head 16 is arranged close to the combustion chambers of the cylinders 14 of the engine and is cooled by a transverse circulation in the second water chamber 22, which makes it possible to ensure optimal cooling of the combustion chambers. , while the upper part of the cylinder head 16 is cooled by a longitudinal circulation, which makes it possible to ensure optimum degassing of the cooling circuit. Furthermore, the fourth water chamber 28 communicates with the third water chamber via orifices 31 arranged at its longitudinal ends 32 and associated ducts 34 which pass through the second water chamber 22 to open directly. in the third water chamber 24. In the preferred embodiment of the invention, the second water chamber 22 is fed by the first water chamber 20 via a series of orifices 36 6. disposed longitudinally and in that it feeds the third water chamber 24 through a series of orifices 38 arranged longitudinally. Furthermore, the fourth water chamber 28 is fed by the second water chamber 22 via a series of orifices 40 arranged at least transversely. Several arrangements are possible for the arrangement of the outlet orifice 26. This can be arranged at a longitudinal end of the third water chamber 24, as shown in FIG. 3, or alternatively (not shown) be arranged in an intermediate part of the third water chamber 24. In order to produce the second and fourth water chambers 22, 28, the cylinder head 16 can be made in two parts, with distinct cavities associated with each of the third and fourth chambers. As a variant, the cylinder head 16 may be made of a single part within which subdivision means delimit two distinct cavities associated with the third and fourth water chambers 22, 28 respectively. The invention thus makes it possible to substantially improve the cooling of a motor vehicle engine 10.

Claims (10)

  Motor vehicle engine (10) comprising at least one engine block (12) having a row of cylinders (14) aligned and which is capped with a cylinder head (16), an internal cooling circuit comprises successively, d downstream, at least one cooling pump (15), an inlet (18), a first water chamber (20) for longitudinal circulation of a coolant along a side of the row of cylinders (14), a second water chamber (22), allowing the transverse circulation of the coolant through a portion of the cylinder head (16), a third water chamber (24) allowing the longitudinal circulation of the coolant along the opposite side of the row of cylinders (14), and an outlet orifice (26), characterized in that the second water chamber (22) is arranged in a lower part of the cylinder head (16) and that the cooling circuit comprises in addition a fourth water chamber (28) which is arranged in an upper part of the cylinder head (16), which is supplied upstream by the second water chamber (22), and which communicates downstream directly with the third water chamber (24).   2. Engine (10) of a motor vehicle according to the preceding claim, characterized in that the fourth water chamber (24) allows the longitudinal circulation of the cooling liquid in the upper part of the cylinder head (16).   3. Vehicle engine (10) according to one of the preceding claims, characterized in that the second water chamber (22) is arranged close to the combustion chambers of the engine cylinders to ensure cooling and in that 30 the fourth water chamber (24) is intended in particular to ensure the degassing of the cooling circuit.   4. Engine (10) of a motor vehicle according to one of claims 2 or 3, characterized in that the fourth 8 water chamber (28) communicates with the third water chamber (22) via orifices (31) arranged at its longitudinal ends (32) and associated ducts (34) which pass through the second water chamber (22) to open directly into the third water chamber (24).   Motor vehicle engine (10) according to one of the preceding claims, characterized in that the second water chamber (22) is fed by the first water chamber (20) via a series of port (36) arranged longitudinally and that it feeds the third water chamber (24) through a series of orifices (38) arranged longitudinally.   Motor vehicle engine (10) according to one of the preceding claims, characterized in that the fourth water chamber (28) is fed by the second water chamber (22) via a series of orifices (40) arranged at least transversely.   Motor vehicle engine (10) according to one of the preceding claims, characterized in that the outlet opening (26) is arranged at a longitudinal end of the third water chamber (24).   8. motor vehicle engine (10) according to any one of claims 1 to 6, characterized in that the outlet orifice (26) is arranged in an intermediate portion of the third water chamber (24).   9. motor vehicle (10) according to any one of the preceding claims, characterized in that the yoke (16) is made in two parts, separate cavities are associated with each of the third and fourth 30 water chambers ( 22, 28).   10. Engine (10) of a motor vehicle according to any one of claims 1 to 8, characterized in that the yoke is made in a single part within which 9 subdivision means delimit two separate cavities respectively associated with third and fourth water chambers (22, 24) .5