FR3068432A1 - ASSEMBLY COMPRISING A RECEPTACLE AND A GAS FLOW CONTROL VALVE FOR ASSEMBLY - Google Patents

Abstract

The subject of the invention is an assembly (10), in particular for a heat engine, comprising a receptacle (12) and a valve (14) for regulating the flow rate of a gas intended to be assembled with each other. assembly comprising: - a cooling duct (40) arranged and configured to carry a cooling fluid (42) for cooling the flow control valve when the control valve is assembled to the receptacle, and - at least one means for drain (50) configured to exhaust cooling fluid from the cooling duct to the outside of the receptacle during disassembly of the control valve and the receptacle.

Description

Assembly comprising a receptacle and a valve for regulating the flow of a gas intended to be assembled

The present invention relates to an assembly, in particular for a heat engine, comprising a receptacle and a valve for regulating the flow of a gas intended to be assembled with each other.

In particular, the field of the present invention is that of equipment for supplying the heat engine, in particular of a motor vehicle, for example actuators or metering valves which participate in the operation of heat engines and arranged in an air circuit of the engine. thermal. Within the meaning of the invention, the term “heat engine air circuit” designates the circuit between the intake inlet and the exhaust outlet of the heat engine. The valve can be placed in the intake circuit, the exhaust circuit, or a recirculation loop through which the exhaust gases fed back to the intake (EGR) pass.

Such a valve is therefore traversed by gases which, even if they are sometimes cooled before passing through the valve, are at very high temperatures. It is therefore necessary to cool said valve or at least one element composing it in order to ensure optimum operation. It is known in this sense to use a coolant passing through a network of cooling conduits passing through the valve.

However, in certain cases, the optimum cooling circuit or duct can lead to a risk of introducing coolant into the gas circulation duct in the event of disassembly of the valve. Such introduction of coolant into the gas circulation pipe can damage the engine and should be avoided.

There is therefore a need to improve the valve / receptacle assembly in order to avoid any risk of introducing coolant into the duct dedicated to the circulation of gases in the event of disassembly of the valve and the receptacle, for example by valve overhaul and maintenance.

Thus, the invention proposes to provide an assembly comprising a valve and a receptacle intended to be assembled with one another making it possible to remedy this problem.

-2To this end, the subject of the present invention is an assembly, in particular for a heat engine, comprising a receptacle and a valve for regulating the flow rate of a gas intended to be assembled together, the assembly comprising:

a cooling duct arranged and configured to transport a cooling fluid intended to cool the flow control valve when the control valve is assembled with the receptacle, and at least one drain means configured to discharge the cooling fluid from the cooling duct to the outside of the receptacle during disassembly of the control valve and the receptacle. Thus, such an assembly makes it possible to purge the cooling duct towards the outside of the receptacle before disassembling the valve from the receptacle thus making it possible to avoid any risk of introduction of coolant into the gas circulation duct of the valve which can cause damage to the engine.

The assembly according to the invention may also include one or more of the characteristics below, considered individually or in all technically possible combinations:

the or each draining means forms a means for fixing the control valve to the receptacle;

at least one draining means comprises at least:

• a drainage channel having one end in communication with the cooling duct and another opposite end opening onto an external wall of the receptacle, and • a shutter arranged and configured for:

close the drain channel when the control valve and the receptacle are assembled together, and open the drain channel during the disassembly of the control valve and the receptacle;

the control valve comprises a plate for fixing to the receptacle, the plate comprising at least one orifice for the passage of a drain screw and the receptacle comprises at least one bore for receiving the drain screw communicating with at least one drain channel , and the assembly includes a drain screw forming the shutter of the at least one drain means and configured to be inserted in the passage orifice of the

-3 fixing plate and in the bore formed in the receptacle so as to close the drainage channel so as to maintain the coolant in the cooling duct when the control valve and the receptacle are assembled one to the other;

the cooling duct opens into the bore via an inlet orifice, the section of the bore between the inlet orifice and an outlet orifice formed in the external wall of the receptacle forming at least one drainage channel, and the drain screw forming the obturator, when it is inserted into the passage opening of the control valve and into the bore of the receptacle, closes the entry hole of the bore so as to maintain the fluid cooling in the cooling duct;

the bore passes through the cooling duct to an inlet orifice of the drainage channel, and the drain screw forming the obturator, when it is inserted in the passage orifice of the control valve and in the 'bore of the receptacle, closes the inlet of the drain channel so as to maintain the coolant in the cooling duct;

the or each drain screw forms a means for fixing the control valve to the receptacle;

the regulating valve comprises a plate for fixing to the receptacle, the plate comprising at least three orifices for the passage of fixing screws and the receptacle comprising at least three bores for receiving the fixing screws;

the regulating valve comprises a valve body and the receptacle comprises a receptacle body, one among the valve body and the receptacle body has an open cavity, and the other among the valve body and the receptacle body has a wall forming a cover of the open cavity when the control valve and the receptacle are assembled to each other, the cavity closed by the cover forming at least partially the cooling duct;

the cooling duct is in communication with the cooling circuit of the heat engine;

the valve is an exhaust gas recycling valve, in particular of the high pressure type;

the assembly comprises at least two draining means, each arranged and configured to remove the coolant from the duct of

-4 cooling to the outside of the receptacle during the disassembly of the control valve and the receptacle;

the bore has a tapped hole;

the assembly includes a first seal between the drain screw and the hole for the passage of the drain screw formed in the fixing plate; one of the drain screw and the opening of the drain screw has a groove intended to receive in part the first seal, preferably the groove is formed in the drain screw;

the assembly includes a second seal arranged between the fixing plate of the control valve and the receptacle;

the second seal surrounds the drain screw when the control valve and the receptacle are assembled to each other;

the fixing plate has a groove shaped to receive at least partially the second seal;

at least one of the first and second seals has an O-ring;

the first seal is formed by a thread lock formed on the drain screw;

the regulating valve is fixed to the receptacle by at least two fixing means, preferably three fixing means;

the cooling duct is arranged in the receptacle;

the gas flow control valve comprises a conduit comprising an opening allowing a flow of the gas, and a valve movable in translation in the conduit between an extreme closed position and an extreme open position;

the valve comprises a rod on which the valve is fixed and a rod control member whose translation selectively controls the opening and closing of the fluid passage conduit through the valve;

the cooling duct is arranged around the rod;

the cooling duct extends over an angular range of 360 ° around the rod;

the valve body is made of aluminum or steel;

the body of the receptacle is made of aluminum or steel;

the cooling fluid comprises water containing antifreeze, preferably glycol;

-5the receptacle is an intake distributor for the heat engine;

the receptacle is a cylinder head of the heat engine;

The receptacle can be a conduit connecting the exhaust circuit to the intake circuit of the heat engine;

the valve is a metering valve for engine intake gas.

Other characteristics and advantages of the invention will appear on reading the detailed description of embodiments given by way of nonlimiting examples and illustrated, accompanied by the following figures:

Figures 1 and 2 are schematic sectional views of an assembly according to a first embodiment of the invention. In Figure 1, the valve and the receptacle are assembled and attached to each other and the valve is cooled by a coolant.

Figure 3 is a schematic perspective view of all of Figures 1 and 2;

Figure 4 is a schematic sectional view of an assembly according to a second embodiment of the invention; and Figure 5 is a schematic sectional view of an assembly according to a third embodiment of the invention.

In the figures, similar elements are designated by identical references. In addition, the different elements are not necessarily shown to scale in order to present a view making it easier to understand the invention.

Figures 1 and 2 illustrate a first embodiment of an assembly 10 according to the invention, in particular for an internal combustion engine, comprising a receptacle 12 and a valve 14 for regulating the flow rate of a gas.

In particular, the receptacle 12 can be an intake distributor for the heat engine or a cylinder head for the heat engine. The receptacle can also be a conduit connecting the exhaust circuit to the intake circuit of the engine. The receptacle 12 comprises a body 16 adapted to receive the control valve 14. Preferably, the body 16 of the receptacle 12 is made of aluminum. The body 16 of the receptacle comprises a cylindrical part 18 extending along a longitudinal axis X and configured to at least partially receive the valve 14 for its assembly on the receptacle 12. In addition, the receptacle 12 comprises a

-6 plate 20 extending transversely to the longitudinal axis X from the cylindrical part 18 configured to fixedly hold the valve assembled to the receptacle.

In addition, the regulating valve 14 is preferably a valve for recycling exhaust gases, in particular of the high pressure type. The valve 14 can also be a combustion engine combustion air metering valve.

More specifically, the valve 14 comprises a valve body 22 in which is formed a circulation duct, not illustrated, comprising an opening allowing a flow of fluid, for example gas. Preferably, the valve body 22 is made of aluminum and / or an aluminum alloy.

The valve 14 further comprises a shutter or shutter member (not shown) configured to close the opening of the conduit and movable between an extreme closed position and an extreme open position. Preferably, the shutter is a valve movable in translation in the circulation duct between an extreme closed position and an extreme open position so as to allow adjustment of the gas flow rate through the valve.

In addition, the valve 14 comprises a rod or shaft 24 on which the valve is fixed and a member for controlling the movement of the rod. The control member is preferably rotary so that the opening and closing of the gas circulation duct by the valve is selectively controlled by the rotation of the control member causing the translation of the rod for example.

The valve body 22 comprises a cylindrical section 26 extending along the longitudinal axis X housing the valve mechanism and in particular the rod 24 supporting the shutter.

The regulating valve 14 and the receptacle 12 are configured to be fixedly assembled with each other.

To this end, the cylindrical part 18 of the body 16 of the receptacle 12 is configured to at least partially receive the cylindrical section 26 of the valve 14 during assembly of the valve and of the receptacle by sliding the cylindrical section 26 of the valve in the cylindrical part 18 of the body of the receptacle along the longitudinal axis X.

In addition, the valve body 22 comprises a fixing plate 28 extending transversely to the longitudinal axis from the cylindrical section 26. The control valve 14 is fixed to the receptacle 12 by at least two fixing means, preferably three fixing means, for example fixing screws.

As is more visible in FIG. 3, the plate 28 comprises at least three orifices 32 for the passage of fixing screws, preferably regularly spaced. In addition, the receptacle 12 comprises at least three bores for receiving the fixing screws. More specifically, the receptacle 12 has as many bores as there are holes 32 for fixing screws to fix the valve 14 to the receptacle 12.

According to the invention, the assembly 10 further comprises a cooling duct 40 arranged and configured to transport a cooling fluid 42 intended to cool the flow control valve 14 when the control valve is assembled to the receptacle 12. For example , the cooling fluid 42 comprises water with added antifreeze, preferably glycol.

In addition, the cooling duct 40 is preferably in communication with a cooling circuit of the heat engine.

Preferably, the cooling duct 40 is produced at least partially in the body 16 of the receptacle 12. The cooling duct 40 can also be produced at least partially in the valve body 22 capable of being heated during operation of the heat engine.

Advantageously, the cooling duct 40 is arranged around the rod 24 and preferably extends over an angular range of 360 ° around the rod 24 supporting the valve in order to effectively cool the valve body 22 capable of being heated by operation of the heat engine.

In particular, the cooling duct 40 can advantageously include a cavity 44 delimited by the cylindrical body 18 and the plate 20 of the receptacle 12.

According to the embodiment illustrated in Figures 1 and 2, the cavity 44 is formed by the assembly of a first open cavity 46 arranged in the valve body 22 and a second open cavity 48 arranged in the body 16 of the receptacle 12.

The first open cavity 46 is formed by a groove formed in the cylindrical section 26 of the valve 14. More specifically, the first open cavity 46 opens onto the second cavity 48 formed in the receptacle 12, preferably over its entire normal cross-section. to the direction of the depth of the groove of the first cavity which is radial to the longitudinal axis X. Such a first open cavity 46 can in particular be produced by molding. The internal surface of the domed cavity increases the heat exchange surface

-8with the cylindrical section 26 of the valve body 22 capable of being heated during operation.

The second open cavity 48 is formed by a groove formed in the plate 20 of the body of the receptacle 12 so that the directions of the depth of the grooves of the first and second cavities are opposite.

Thus, when the valve 14 and the receptacle 12 are fixed to each other, the cavity 44 resulting from the assembly of the first and second open cavities 46, 48 is closed and adapted to receive the coolant 42 such that 'illustrated in figure 1.

In addition, the assembly comprises at least one draining means 50 configured to evacuate the cooling fluid 42 from the cooling duct 40, in particular from the cavity 44, towards the outside of the receptacle 12 during the disassembly of the control valve. 14 and receptacle 12.

Preferably, the assembly comprises at least two draining means for discharging the cooling fluid from the cooling duct towards the outside of the receptacle during disassembly. The emptying means are preferably regularly spaced angularly around the rod.

A draining means will now be detailed with reference to FIGS. 1 and 2. Such a draining means 50 comprises a draining channel 52 and a shutter 54 of the draining channel.

The drain channel 52 has one end 56 in communication with the cooling duct 40 and another opposite end 58 opening onto an outer wall 60 of the receptacle 12.

According to the embodiment illustrated in Figures 1 and 2, the drain channel 52 is in communication with the cooling cavity 40 through a through hole 62 formed in the second cavity 48 of the receptacle 12 in order to allow the cooling fluid 42 to flow according to the arrow marked F in the drainage channel 52 towards the external wall 60 of the receptacle 12 before the disassembly of the valve and of the receptacle, that is to say before sliding the cylindrical section 26 of the valve of the cylindrical part 18 of the body of the receptacle along the longitudinal axis X.

The shutter 54 of the drain channel 52 is arranged and configured to close the drain channel 52 when the control valve and the receptacle are assembled together. Thus, in the example illustrated, the shutter makes it possible to obstruct the orifice 62 formed in the second cavity and therefore to close the

-9 cavity 44 receiving the coolant 42 when the heat engine is in operation and capable of heating the valve as illustrated in FIG. 1.

In addition, the shutter 54 of the drain channel 52 is arranged and configured to open the drain channel 52 during the disassembly of the control valve and the receptacle as illustrated in FIG. 2.

Advantageously and as illustrated in the figures, the shutter 54 includes a drain screw 70. In addition, the plate 28 of the valve 14 includes a passage orifice 72 of the drain screw 70 and the plate 20 of the receptacle 12 comprises a bore 74 for receiving the drain screw 70 communicating with the drain channel 52. In the example illustrated in FIGS. 1 and 2, the drain channel is formed by a portion of the bore 74 for receiving the drain screw 70 formed in the receptacle.

Preferably, bore 74 has a tapped hole.

The drain screw 70 forming the shutter 54 of the drain means 50 is configured to be inserted in the passage orifice 72 of the fixing plate and in the bore 74 formed in the receptacle so as to close the drain channel 52 so as to maintain the cooling fluid 42 in the cooling duct 40 when the control valve and the receptacle are assembled to one another and in particular when the engine and the valve are in operation.

Advantageously, each draining means forms a means for fixing the control valve to the receptacle, in particular each draining screw is a screw for fixing the valve to the receptacle. In other words, the drain channel is formed by a portion of the receiving bore of a fixing screw formed in the receptacle.

Thus, it is not possible to disassemble the valve from the receptacle as long as a drain screw is still present. Disassembly of the receptacle valve requires disassembly of the circuit drain screws. The cooling circuit is therefore empty when the valve is extracted from the receptacle. The risk of coolant intrusion into the gas circulation duct is eliminated.

Dismounting a first drain screw opens the cooling circuit. Disassembling a second screw creates an air intake which facilitates emptying the circuit.

Advantageously, the assembly 10 further comprises a first seal 90 between the drain screw 70 and the orifice 72 for passage of the screw.

-10 drain in the fixing plate making it possible to seal the fixing of the drain screw 70 on the fixing plate 28 to avoid possible leaks of the coolant 42.

For this purpose, one of the drain screw 70 and the orifice 72 for passage of the drain screw has a groove 92 intended to receive at least partially the first seal 90. Preferably, the groove 92 is formed in the drain screw 70 as illustrated in FIG. 1.

The first seal 90 can be an O-ring or be formed by a thread lock provided on the drain screw 70.

In addition, the assembly 10 advantageously comprises a second seal 94 arranged between the fixing plate 28 of the control valve and the plate 20 of the receptacle 12 ensuring the tightness of the fixing of the fixing plate of the valve. on the receptacle body to prevent leakage of coolant. The fixing plate 28 has a groove 96 shaped to receive at least partially the second seal. Of course, the groove 96 shaped to receive at least partially the second seal can be formed in the plate 20. In addition, the second seal 94 surrounds the drain screw 70 when the control valve and the receptacle are assembled to each other.

For example, the second seal 94 has an O-ring.

The assembly 10 may also advantageously include a third seal 98 arranged between the fixing plate 28 of the regulating valve and the plate 20 of the receptacle 12 ensuring the tightness of the fixing of the fixing plate of the valve on the receptacle body to prevent leakage of coolant. The fixing plate 28 or the plate 20 has a groove 100 shaped to receive at least partially the third seal.

In addition, the assembly 10 may also advantageously comprise a fourth seal 102 arranged between the cylindrical section 26 of the valve 14 and the cylindrical part 18 of the body of the receptacle 12. One of the advantageously comprises a fourth seal sealing 102 arranged between the cylindrical section 26 of the valve 14 and the cylindrical part 18 of the body of the receptacle 12 may have a groove 104 shaped to receive at least partially the fourth seal 102.

The seals 90, 94, 98 and 102 make it possible to seal the assembly 10 when the valve is cooled, avoiding possible leaks of the coolant 42.

A second embodiment is illustrated in Figure 4 and differs from the first embodiment shown in Figures 1 and 2 in that the cooling duct 140 of the assembly 110 comprises an open cavity 144 formed in the cylindrical section 126 of the valve 114.

In addition, the body 116 of the receptacle 112 has a wall 146 forming a cover of the open cavity 144 when the control valve and the receptacle are assembled to one another. The cavity closed 144 by the cover 146 forms at least partially the cooling duct.

In addition, the cooling duct 140 opens into the bore 174 for receiving the drain screw through an inlet orifice 156 either directly or via a cooling channel 148 as illustrated in FIG. 4. For example the cooling channel 148 is formed in the plate 120 of the receptacle 112.

The section of the bore 174 between the inlet orifice 156 and an outlet orifice 158 formed in the outer wall 160 of the receptacle forms the drain channel 152. The drain screw forming the shutter, when it is inserted into the passage orifice 172 of the control valve and into the bore 174 of the receptacle, closes the inlet orifice 156 of the bore so as to maintain the coolant in the cooling duct.

A third embodiment, illustrated in Figure 5, differs from the first embodiment shown in Figures 1 and 2 in that the bore 274 for receiving the drain screw 270 formed in the body 216 of the receptacle 212 passes through the cooling duct 240 up to an inlet orifice 262 of the drainage channel 252.

Disassembly of the drain screw 270 thus creates two separate openings in the cooling circuit, which facilitates the entry of air into the circuit and therefore its drainage.

The drain channel 252 and the bore 274 are coaxial. The drain channel has a smaller diameter than that of the receiving bore of the drain screw.

The drain screw 270 forming the shutter, when it is inserted in the passage orifice 272 of the control valve and in the bore 274 of the

-12 receptacle, closes the inlet 262 of the drain channel 252 so as to maintain the coolant in the cooling duct.

The invention has been described in the context of an assembly comprising a metering valve 5 for combustion engine intake gas. Of course, other applications of the assembly according to the invention are also possible without departing from the scope of the invention.

Claims (12)

1. Assembly (10; 110; 210), in particular for a heat engine, comprising a receptacle (12; 112; 212) and a valve (14; 114; 214) regulating the flow rate of a gas intended to be assembled one with the other, the set comprising: a cooling duct (40; 140; 240) arranged and configured to transport a cooling fluid (42) intended to cool the flow control valve when the control valve is assembled to the receptacle, and at least one draining means ( 50) configured to discharge the coolant from the cooling duct to the outside of the receptacle during the disassembly of the control valve and the receptacle. 2. The assembly of claim 1, wherein the or each drain means (50) forms a means for fixing the control valve to the receptacle. 3. An assembly according to claim 1 or 2, in which at least one draining means (50) comprises at least: a drain channel (52; 152; 252) having one end in communication with the cooling duct (40; 140; 240) and another opposite end opening onto an external wall of the receptacle (12; 112; 212), and a shutter (54) arranged and configured for: • close the drain channel when the control valve and the receptacle are assembled together, and • open the drain channel during disassembly of the control valve and the receptacle. 4. The assembly as claimed in claim 3, in which: the control valve (14) comprises a fixing plate (28) to the receptacle, the plate comprising at least one orifice for passage (72) of a drain screw (70) and the receptacle (12) comprises at least one bore receiving (74) the drain screw communicating with at least one drain channel, and The assembly (10) comprises a drain screw (70) forming the shutter (54) of the at least one drain means and configured to be inserted in the orifice for passage of the fixing plate and in the bore formed in the receptacle so as to close the drain channel so as to maintain the coolant in the cooling duct when the control valve and the receptacle are assembled to each other. 5. The assembly as claimed in claim 4, in which: the cooling duct (140) opens into the bore (174) through an inlet port (156), the section of the bore between the inlet port and an outlet port (158) formed in the wall outer (160) of the receptacle (112) forming at least one drain channel (152), and the drain screw forming the shutter, when it is inserted in the passage opening of the control valve and in the receptacle bore, closes the inlet port (156) of the bore (174) so as to maintain the cooling fluid in the cooling duct. 6. The assembly as claimed in claim 4, in which: the bore (274) passes through the cooling duct (240) to an inlet orifice (262) of the drain channel (252), and the drain screw (270) forming the shutter, when it is inserted in the opening of the regulating valve and in the bore of the receptacle, closes the inlet of the drain channel so as to maintain the coolant in the cooling duct. 7. Assembly according to any one of claims 4 to 6, in which the or each drain screw (70) forms a means for fixing the control valve to the receptacle. 8. Assembly according to any one of the preceding claims, in which the control valve (14) comprises a fixing plate (28) to the receptacle, the plate (28) comprising at least three orifices for fixing fixing screws and the receptacle comprising at least three bores for receiving the fixing screws. 9. Assembly according to any one of the preceding claims, in which: the control valve (14) comprises a valve body (22) and the receptacle (12) comprises a receptacle body (16), one of the valve body and the receptacle body has an open cavity, and 5 - the other, among the valve body and the receptacle body, has a wall forming a cover of the open cavity when the control valve and the receptacle are assembled together, the cavity closed by the cover forming at less partially the cooling duct. 10. Assembly according to any one of the preceding claims, in which the cooling duct (40; 140; 240) is in communication with the cooling circuit of the heat engine. 11. Assembly according to any one of the preceding claims, in which 15 the valve (14; 114; 214) is an exhaust gas recycling valve, in particular of the high pressure type.