EP3092394A1

EP3092394A1 - Fixed-head internal combustion engine with improved gas-tightness

Info

Publication number: EP3092394A1
Application number: EP15701564.5A
Authority: EP
Inventors: Marek ABRAMCZUK; Frédéric JUSTET; Pascal Tribotte
Original assignee: Renault SAS
Current assignee: Renault SAS
Priority date: 2014-01-10
Filing date: 2015-01-12
Publication date: 2016-11-16
Anticipated expiration: 2035-01-12
Also published as: FR3016404A1; EP3092394B1; BR112016015775B1; WO2015104515A1; BR112016015775A2; FR3016404B1

Abstract

The invention relates to a fixed-head internal combustion engine comprising at least one cylinder having a cylindrical chamber arranged in a housing, an applied lining (3) inserted in the cylindrical chamber, and a supporting element attached to the housing (40) whereon the liner is supported, the engine also comprising elastic means (6) forming a spring, inserted between the liner and the supporting element attached to the housing, such that the liner is supported on said supporting element attached to the housing via the elastic means forming a spring.

Description

INTERNAL COMBUSTION BORGINE MOTOR WITH AUX SEALING

IMPROVED GAS

[001] The invention relates to a blind internal combustion engine for a motor vehicle comprising an improved gas seal device.

[002] Currently, as shown in Figure 1 and in the document FR 2 972 381, a blind motor 1 to internal combustion is the assembly consisting of a cylinder head portion 2 and a cylinder block portion 7 in one. piece obtained by molding. The yoke portion 2 comprises at least one exhaust duct, said duct opening into a combustion chamber roof 26 which forms a substantially conical cavity and whose object is to improve combustion. The breech part 2 comprises at least one valve which closes the access to said exhaust duct. The cylinder head 2 also supports injection and ignition devices. [003] The cylinder block portion 7 comprises at least one vertical cylindrical chamber 8 opening at a high end in the cavity of the chamber roof 26 in the cylinder head portion 2 and opening in its lower end in a connecting rod chamber 9. The cylindrical chamber 8 is shaped to accommodate a cylindrical jacket 3. The crank chamber houses a crankshaft maintained along a horizontal axis by at least one crankshaft bearing 4 disposed transversely to the axis of the crankshaft. The crankshaft bearing 4 is fixed on the cylinder block portion 7 by fixing devices 24 located on either side of the crankshaft bearing 4. [004] The jacket 3 is a cylindrical tube-shaped piece of metal material whose outer diameter is less than or equal to a diameter of the cylindrical chamber 8, and a length is equal to or greater than a length of the cylindrical chamber 8. Once in place in the cylindrical chamber 8, the jacket 3 and the cylindrical chamber 8 define between them a water chamber 21 preferably circular of the cooling circuit located at the top and a circular air chamber 22 of the intake circuit of air, disjoined from the water chamber 21 by a prominent edge and located in the lower part. On an inner wall of the air chamber 22 has at least one hole 35, preferably drilled in an upper region of the chamber 22 d ^x air and opening into a bore of the liner 3, orifice 35 for the passage of fresh air inlet to feed the combustion chamber in the bore of said jacket 3. This orifice is substantially halfway up the jacket 3. The jacket 3 also comprises, on each prominent edge of the water chambers 21 and air, a circular groove 25 adapted to accommodate an O-ring made of elastomeric material, sealing the water chamber 21 and air 22, with the exception of the orifice 35. [005] On assembly, the jacket 3, equipped with seals

25, is nested in the cylindrical chamber 8 by the connecting rod chamber 9 low engine 1. It is held in place by a pillar 5 arranged for this purpose on the crankshaft bearing 4. The pillar 5 bears on a face 31 at the bottom end of the liner 3, during the implementation of the fixing devices 24 of the crankshaft bearing 4 on the cylinder block portion 7 of the blind motor 1. Thus, an upper end face 32 of the liner 3 is maintained pressing on an edge of the cavity of the combustion chamber roof 26 in order to achieve a gastightness around the cavity of the combustion chamber roof 26, between this cavity and the water chamber 21. In order to ensure this seal In the case of gases, the contact pressures at an interface 27 between the edge of the cavity 26 and the jacket 3 must be greater than a maximum combustion pressure with a certain safety coefficient that can prevail within the combustion chamber. The liner 3, sandwiched between the crankshaft bearing 4 and the edge of the cavity of the combustion chamber roof 26 is compressed to provide a contact pressure necessary for sealing under all operating conditions of the engine. blind motor 1. [006] Since the engine block is made of aluminum and the casing 3 cast iron, thermal expansion hot lead to a loss of tension in the assembly. In order to ensure a seal against hot gases, it is then necessary to increase the compression of the jacket 3. However, in this case, the cold contact pressures increase which may lead to a risk of plasticization in the bearing zone of the face 32 of the liner 3 with the edge of the cavity of the combustion chamber roof 26 and, as the reaction between the face 31 of the liner 3 and the pillar 5 of the crankshaft bearing 4 increases, a risk for the holding of the crankshaft bearing.

[007] An object of the invention is to provide an internal combustion blind motor having improved gas tightness while avoiding the above disadvantages.

[008] For this purpose, it is provided, according to the invention, a blind engine with internal combustion comprising at least one cylinder comprising a cylindrical chamber, an attached sleeve fitted into the cylindrical chamber and crankshaft bearings on which the liner is supported, the motor further comprising resilient spring means interposed between the liner and the crankshaft bearing so that the liner is supported on the crankshaft bearing via spring elastic means. [009] Thus, the resilient means forming a spring make it possible to absorb the thermal expansions of the elements in contact, source expansions of the variations between the cold contact pressures and the hot contact pressures, thus reducing the risks of failure of the bearing. crankshaft, on the one hand, and, on the other hand, plasticizing the bearing zone of the upper face of the jacket.

[010] Advantageously, but optionally, the blind internal combustion engine according to the invention comprises at least one of the following additional technical characteristics:

the resilient spring means are attached to the crankshaft bearing;

the elastic spring means have a low stiffness;

the resilient spring means comprise a leaf spring;

the resilient spring means comprise soft pads;

the soft pads are made of polyether ether ketone or polyamide-imide; and,

the resilient spring means comprise a "Belleville" type washer. [011] It is also provided, according to the invention, a motor vehicle having a blind engine with internal combustion having at least one of the above characteristics.

[012] Other features and advantages of the invention will become apparent from the following description of two embodiments of the invention. In the accompanying drawings:

- Figure 1 is a sectional view of a blind engine internal combustion according to the state of the art;

FIG. 2 is a three-dimensional view of a sleeve / bearing assembly embodying a first embodiment of the elastic spring means of a blind motor according to the invention;

Figure 3 is a three-dimensional view of the first embodiment of spring elastic means;

FIG. 4 is a three-dimensional view of a second embodiment of spring elastic means mounted on a bearing of a blind motor according to the invention; and,

Figure 5 is a three-dimensional view of a sleeve / bearing assembly implementing the second embodiment of the elastic spring means of a blind motor according to the invention.

[013] We will now describe in detail two embodiments of the invention with reference to Figures 2 and 3, and Figures 4 and 5 respectively. Only spring elastic means are concerned by the description which follows, and their assembly between the sleeve 3 and the crankshaft bearing 40,400. Note that the assemblies thus formed are installed in a blind internal combustion engine similar to that 1 which has been described in the preamble with reference to FIG. 1. [014] According to a first embodiment of the blind internal combustion engine according to FIG. In the invention, spring elastic means are here in the form of a leaf spring 6. This leaf spring 6 is elongated parallelepiped here with a small thickness compared to the other two dimensions. The leaf spring 6 has, over a length, a shape of hump with a boss 61 and two median ends 63, 64 each comprising a substantially oblong receiving opening 62. Said opening may be, as shown in Figure 3, in the shape of a "U". The leaf spring 6 is mounted on a crankshaft bearing 40 which comprises for this purpose a pair of pillars 41 located on either side, preferably symmetrically to a vertical axis passing through and perpendicular to an axis of rotation. a crankshaft in the crankshaft bearing 40. The pillars 41 project vertically from an upper face of the crankshaft bearing 40 towards the underside 31 of the jacket 3. The pillars 41 are integral with the crankshaft 40. crankshaft bearing 40. At an upper free end, the pillars 41 each comprise a pin 42 which, during assembly, is received in the receiving openings 62 of the leaf spring 6.

[015] The liner 3 has at its lower end 31 a lug 33 extending radially projecting from an outer side wall of the liner 3. During assembly, the lug 33 bears on a top of the bump 61 of the spring blade 6. Thus the leaf spring 6 is found mounted in series between the liner 3 and the crankshaft bearing 40. In operation of the internal combustion engine blind according to the invention and equipped with the leaf spring 6, the latter is deformed elastically when thermal expansion of the jacket 3, the cylinder head part 2 and the crankshaft bearing 4.

[016] Now, with reference to FIGS. 4 and 5, we will describe a second embodiment of the blind internal combustion engine according to the invention, the spring-forming elastic means are here, in the form of studs 420 reported. in orifices arranged for this purpose at a free end 411 of a pillar 410 of a crankshaft bearing 400. Once reported, the pads 420 extend projecting from the free end 411 of the pillar 410.

[017] The pillar 410 extends projecting vertically from an upper face of the crankshaft bearing 400 towards the lower face 31 of the liner 3, and to the right of an axis of rotation of a crankshaft in the bearing of crankshaft 400. In addition, the pillar 410 is integral with the crankshaft bearing 400. [018] The studs 420 are, here, two in number, positioned symmetrically with a mean plane of the perpendicular crankshaft bearing 400 to the axis of rotation of the crankshaft. Such an arrangement makes it possible to interface the crankshaft bearing 400 with two adjacent jackets 3 of the blind internal combustion engine according to the invention, each stud 420 being dedicated to one of the adjacent jackets 3.

[019] As for the previous embodiment, the liner 3 has at its lower face 31 end of an ear 33 extending protruding centrifugally from a radially outer side wall of the liner 3. The lug 33 has a bearing face 330. During an assembly, the ear 33 has its face support 330 which comes into contact with a free end of one of the pads 420. Thus the pad 420 is found connected in series between the liner 3 and the crankshaft bearing 400. In operation of the blind engine with internal combustion according to the invention. invention thus equipped with the pad 420, the latter is deformed in an elastic manner during the thermal expansions of the jacket 3, the cylinder head part 2 and the crankshaft bearing 4.

[020] The pads 420 are here cylindrical in shape of revolution. However, they may have other forms of polygonal section or not. On the other hand, the pads 420 are made of a thermoplastic material such as polyether-ether-ketone (PEEK) or polyamide-imide (PAI).

[021] In an alternative embodiment, the elastic spring means comprise a Belleville type washer.

[022] In another embodiment, the elastic means forming a spring comprise helical springs.

[023] In general, the resilient spring means have a very low stiffness in order to compensate for the thermal expansion while hot limiting the increase of the forces in the assembly of the various elements in the blind engine to internal combustion according to the invention. The stiffness of said elastic means is preferentially less than 2000N / mm for a unit capacity of less than 500cm3.

[024] According to another embodiment not shown, the resilient spring means are supported on a bearing element which may be a plate, fixed to the housing, in the connecting rod chamber, near the outlet of the cylindrical chamber . [025] Such a blind internal combustion engine according to the invention is installed in a powertrain of a motor vehicle.

[026] Of course, it is possible to bring to the invention many modifications without departing from the scope thereof.

Claims

claims

1. Blind internal combustion engine (1) comprising at least one cylinder (7) comprising a cylindrical chamber (8) arranged in a housing, an insert (3) attached fitted into the cylindrical chamber, and a support element fixed to the casing (4; 40; 400) on which the liner is supported, characterized in that the motor further comprises resilient spring means (6; 420) interposed between the liner and the support member attached to the casing; so that the liner is supported on said support element fixed to the housing via the elastic means forming a spring.

2. Motor according to claim 1, characterized in that the elastic means forming a spring are fixed on the support member fixed to the housing.

3. Motor according to claim 1 or 2, characterized in that the motor comprises at least one crankshaft bearing fixed to the housing and forming the support element fixed to the housing.

4. Motor according to any one of claims 1 to 3, characterized in that the elastic spring means have a very low stiffness.

5. Motor according to one of claims 1 to 4, characterized in that the resilient spring means comprise a leaf spring (6).

6. Motor according to one of claims 1 to 4, characterized in that the resilient spring means comprise flexible pads (420).

7. Motor according to claim 6, characterized in that the soft pads are made of polyether-ether-ketone or polyamide-imide.

8. Motor according to one of claims 1 to 4, characterized in that the resilient spring means comprise a washer type "Belleville".

9. Motor according to one of claims 1 to 4, characterized in that the elastic spring means comprise helical springs.

10. Motor vehicle comprising a heat engine, characterized in that the heat engine is a blind motor according to one of claims 1 to 9.