DE112014003257T5 - Preload sleeve for pneumatic actuator - Google Patents

Abstract

A pneumatic actuator (100) comprises a housing (101) and a membrane (114) which is arranged in the housing (101) in such a way that it separates an interior space (108) of the housing (101) into separate chambers (109, 110). divided. A piston (112) is disposed in the second chamber (110) and connected to the diaphragm (114) such that the movement of the piston (112) results in a change in the size of the chambers (109, 110). A spring (120) is configured to urge the piston (112) toward the first housing end (104), and a rod is connected to the piston (112). A sleeve (140, 120) is disposed on the actuator rod (34) between the housing (101) and a free end (36) of the actuator rod (34), wherein the sleeve (140, 240) is adapted to as a stop act, which limits the retraction of the actuator rod (34) in the housing (101) beyond a predetermined biasing position addition.

Description

CROSS-REFERENCE TO RELATED APPLICATIONS

This application claims the benefit of US Provisional Application No. 61 / 863,588, filed Aug. 8, 2013, entitled "Pneumatic Actuator Tension Sleeve."

Field of the invention

The present invention relates to a sleeve on the rod of a pneumatic actuator which is used to set the actuator bias for normally open waste gates on a turbocharger. The sleeve is secured to the actuator rod as soon as the appropriate position is reached and / or the specified pressure is exerted on the actuator.

BACKGROUND

There are applications in commercial diesel engines where pneumatic actuators are supplied with pressure from high pressure air tanks on the vehicle rather than from the turbocharger compressor and are controlled by a control valve to open the turbocharger wastegate. At cold starts, however, these air tanks do not have sufficient air pressure to open the wastegate. This can provide too much boost at high idle conditions, and may also remove the ability to open the wastegate to provide heat to the aftertreatment system. One solution to this problem is a normally open wastegate valve that requires pressure to be supplied to the actuator to close the wastegate valve instead of opening it. This eliminates the problems with cold starts.

SUMMARY

In some aspects, a pneumatic actuator includes a housing. The housing includes a first housing end, a second housing end opposite the first end, and an air inlet disposed in the first housing end. The pneumatic actuator includes a diaphragm disposed in the housing between the first end and the second end, the diaphragm dividing an interior of the housing into a first chamber and a second chamber. The pneumatic actuator includes a piston disposed in the second chamber and connected to the diaphragm such that movement of the piston results in a change in size of the first chamber and the second chamber, and a spring disposed in the second chamber has. The spring is configured to urge the piston toward the first housing end. The pneumatic actuator includes an actuator rod having a first rod end connected to the piston, an opposite second rod end, and a rod center portion extending through an opening formed in the second housing end. In addition, the pneumatic actuator includes a sleeve disposed on the actuator rod between the housing and the second rod end, the sleeve being configured to act as a stop that limits retraction of the actuator rod into the housing beyond a predetermined biasing position ,

The pneumatic actuator may include one or more of the following features: the actuator rod has an external thread, and the sleeve has an internal thread that engages the external thread of the actuator rod. The sleeve is fixed to the actuator rod. The position of the sleeve on the actuator rod is adjustable. The pneumatic actuator includes a mounting arm adapted to support the housing, the sleeve being disposed on the actuator rod so as to abut the mounting arm, thereby preventing the actuator rod from interfering therewith due to interference between the sleeve and the mounting arm to retract beyond the predetermined preload position into the housing.

In some aspects, a method of adjusting a bias of a pneumatic actuator for use with a normally open valve includes the steps of: applying a gas pressure to the pneumatic actuator to extend the actuator rod to a maximum outboard position; Connecting the actuator rod to the valve, wherein the valve is in the closed position; Relieving the gas pressure within the pneumatic actuator to allow the actuator rod to retract completely into a housing of the pneumatic actuator; Applying sufficient pressure to the pneumatic actuator to extend the actuator rod to a bias position corresponding to a fully open position of the valve; while the actuator rod is in the biasing position, placing a sleeve on the actuator rod such that the actuator rod is prevented from retracting past the bias position into the housing.

The method may also include one or more of the following additional steps and / or features: The step of applying sufficient pressure to the pneumatic actuator to extend the actuator rod to a bias position corresponding to a fully open position of the valve includes applying a sufficient pressure to advance the actuator rod to a displacement in a range of 1 to 5 mm. The method further includes fixing the sleeve to the actuator rod. The method further includes adjusting the position of the sleeve relative to the actuator rod when the actuator rod is in the biased position. The sleeve is connected to the actuator rod via a threaded interface, and adjusting the position of the sleeve includes rotating the sleeve relative to the actuator rod. The actuator rod is prevented from retracting beyond the bias position into the housing due to interference between the sleeve and a structural portion of the pneumatic actuator. The structural portion of the pneumatic actuator is either the housing or a mounting arm that supports the housing.

In some aspects, a turbocharger includes a compressor section having a compressor wheel and a turbine section having a turbine housing surrounding the turbine wheel. The turbine wheel is connected to the compressor wheel via a shaft. The turbocharger includes a normally open wastegate valve carried on the turbine housing and a pneumatic actuator configured to actuate the wastegate valve. The pneumatic actuator includes a housing having a first housing end, a second housing end opposite the first end, and an air inlet disposed in the first housing end. The pneumatic actuator includes a diaphragm disposed in the housing between the first end and the second end, the diaphragm dividing an interior of the housing into a first chamber and a second chamber. The pneumatic actuator includes a piston disposed in the second chamber and connected to the diaphragm such that movement of the piston results in a change in size of the first chamber and the second chamber, and a spring disposed in the second chamber is. The spring is configured to urge the piston toward the first housing end. The pneumatic actuator includes an actuator rod having a first rod end connected to the piston, an opposite second rod end, and a rod center portion extending through an opening formed in the second housing end. In addition, the pneumatic actuator includes a sleeve disposed on the actuator rod between the housing and the second rod end, the sleeve being configured to act as a stop that limits retraction of the actuator rod into the housing beyond a predetermined biasing position , In some embodiments, due to interference between the sleeve and a structural portion of the pneumatic actuator, the actuator rod is prevented from retracting past the bias position into the housing.

A sleeve is provided which may be added to the actuator rod of a pneumatic actuator and secured in position to bias the actuator for normally open wastegate valve applications. The sleeve may be secured to the actuator rod by welding, a pin, or any other positive locking method. The sleeve can also be secured using a lock nut, or have a threaded sleeve or nut. The use of a threaded sleeve allows the thread of the actuator rod to support the spring load.

BRIEF DESCRIPTION OF THE DRAWINGS

1 is a partial cross-sectional view of a turbocharger comprising a wastegate in a closed position.

2 is a cross-sectional view of the wastegate of 1 in an open position.

3 is a side view of a pneumatic actuator with a sleeve arranged on the actuator rod.

4 is a cross-sectional view of the pneumatic actuator of 3 ,

5 is a side view of the pneumatic actuator with an alternative sleeve, which is arranged on the actuator rod.

DETAILED DESCRIPTION

With reference to 1 and 2 includes an exhaust gas turbocharger 1 a turbine section 2 , a compressor section 4 and a bearing housing 6 that between the compressor section 4 and the turbine section 2 is arranged and connects them. The turbine section 2 includes a turbine housing 8th that has an exhaust inlet 10 , an exhaust outlet 12 and a turbine spiral 14 defined in the fluid path between the exhaust inlet 10 and the exhaust outlet 12 is arranged. A turbine wheel 16 is in the turbine housing 8th between the turbine spiral 14 and the exhaust outlet 12 arranged. A wave 18 is with the turbine wheel 16 connected, is rotatable within the bearing housing 6 held and extends into the compressor section 4 into it. The compressor section 4 includes a compressor housing 20 that has an air intake 22 , an air outlet 24 and a compressor spiral 26 Are defined. A compressor wheel 28 is in the compressor housing 20 between the air inlet 22 and the compressor spiral 26 arranged. The compressor wheel 28 is with the wave 18 connected and is driven by this.

In operation, the turbine wheel 16 in the turbine housing rotatably driven by an incoming exhaust gas flow from the exhaust manifold of a motor (not shown). Because the wave 18 the turbine wheel 16 with the compressor wheel 28 connects, causes the rotation of the turbine wheel 16 the rotation of the compressor wheel 28 , When the compressor wheel 28 it provides pressure boosting in the engine by increasing the rate of air mass flow rate, air density and air pressure applied to the engine cylinders by a compressor air outlet connected to the engine air intake manifold 24 be delivered outflowing airflow.

If the exhaust pressure is high, there may be more exhaust pressure than is needed to provide the desired pressure boost. One solution to this problem is to exhaust gas at high exhaust pressure conditions from the turbine wheel 16 to guide away, so that the exhaust gas, which is the turbine wheel 16 achieved, the amount required is to provide an optimal pressure gain. A normally open wastegate valve 30 is used to exhaust gases from the turbine wheel 16 to lead away. The diversion of exhaust gases controls the speed of the turbine wheel, which in turn controls the speed of the compressor wheel 28 controls. By controlling the speed of the compressor wheel 28 is the wastegate valve 30 able to withstand the maximum boost pressure passing through the exhaust gas turbocharger 1 supplied to the engine is to be regulated. In the illustrated embodiment, the wastegate valve is 30 a flap-type valve configured to extend through an angle α between a closed position in which a valve face 30a against the turbine housing 8th ( 1 ), and an open position in which the valve face 30a from the turbine housing 8th spaced and angled relative thereto ( 2 ), pans.

The wastegate valve 30 is on the turbine housing 8th upstream of the turbine wheel 16 arranged and is controlled by a pneumatic actuator 100 pressed the turbo charger 1 used as a source of pressurized fluid. For example, in some embodiments, compressed air from high pressure air tanks on the vehicle, such as those used to supply the brakes, to the actuator 100 delivered.

With reference to 3 and 4 has the pneumatic actuator 100 the housing 101 on, the first housing end 104 , a second housing end 106 that's the first end 104 opposite, and a side wall 102 includes, extending between the first housing end 104 and the second housing end 106 extends. An interior 108 of the housing 101 will be within the first case end 104 , the second housing end 106 and the side wall 102 Are defined.

The pneumatic actuator 100 includes a flexible, gas-permeable membrane 114 in the case 101 arranged in such a way that a seal between the membrane 114 and the side wall 102 is formed, and the interior into two separate chambers 109 . 110 is divided. In particular, a first chamber 109 between the first housing end 104 and the membrane 114 defined, and a second chamber 110 between the second housing end 106 and the membrane 114 ,

A piston 112 sits in the second chamber 110 , The piston 112 is generally cup-shaped (eg, U-shaped in cross-section) and includes a closed end that communicates with a central portion of the membrane 114 connected is. The piston 112 is about a spring 120 that is between the piston 112 and the second housing end 106 extends to the first housing end 104 pushed. The piston 112 is with the wastegate valve 30 through an actuator rod 34 connected, resulting from the second housing end 106 through a bushing 122 extends.

The housing 101 includes the inlet 126 for pressurized fluid in the first end 104 of which is formed and through which the first chamber 109 Compressed air from the compressor section 4 over the line 32 receives. Thus, the first chamber 109 In operation, an overpressure defined to be a higher pressure than the atmospheric pressure. The second chamber 110 is essentially subject to atmospheric pressure. The compressed air in the first chamber 109 acts on the piston 112 , and when the pressure is sufficient, the air pushes the piston 112 against the force of the spring 120 to the second housing end 106 out. Due to its connection with the wastegate valve 30 over the actuator rod 34 leads the movement of the piston 112 to the second housing end 106 towards advancing the actuator rod 34 out of the case 101 out, and to move the wastegate valve 30 from an open position to a closed position. Rule in the first chamber 109 insufficient pressure, the piston becomes 112 due to the elastic properties of the spring 120 to the first housing end 104 withdrawn. While the piston 112 to the first housing end 104 moved, drives the actuator rod 34 at least partly in the case 101 one and the wastegate valve 30 moves from a closed position to an open position.

In typical normally closed wastegate applications, one becomes Preload position of the pneumatic actuator 100 by the position of the actuator rod 34 relative to the housing 101 Definitely when using the wastegate valve 30 connected in the closed position. That is, the interface of wastegate and turbine housing serves to the pneumatic actuator 100 during installation and the displacement path (eg the advancement) of the actuator rod 34 during operation.

For normally open wastegate applications, another procedure is needed to use the pneumatic actuator 100 with the wastegate open and the displacement path (eg, the advancement) of the actuator rod 34 during operation. To ensure consistent performance and consistent actuator bias and to avoid damage to the actuator, the biasing process must be adjustable.

To a bias of the pneumatic actuator 100 of the wastegate valve 30 to provide, includes the pneumatic actuator 100 a sleeve 140 on the actuator rod 34 , The sleeve 140 is a hollow cylinder, and an inner surface of the sleeve 140 includes a thread adapted to engage a corresponding thread on an outer surface of the actuator rod 34 is provided. Thus, an axial position of the sleeve 140 along a longitudinal axis of the actuator rod 34 by turning the sleeve 140 relative to the actuator rod 34 be set. The sleeve 140 is designed to serve as a stop, the retraction of the actuator rod 34 in the case 101 Limited beyond a predetermined bias position. Especially if the actuator rod 34 in a desired preload position, the position of the sleeve 140 along the actuator rod 34 set until a first end 142 the sleeve 140 against a structural portion of the pneumatic actuator 100 such as a bracket 150 , is present. If the pneumatic actuator 100 on the turbocharger 1 over the attachment arm 150 is mounted, as shown for example in the illustrated embodiment, the position of the sleeve 140 along the actuator rod 34 set until a first end 142 the sleeve 140 against a surface 150a of the attachment arm 150 is applied. In some embodiments, a locknut will be used 146 used to the sleeve 140 in the desired position relative to the actuator rod 34 to keep.

With reference to 5 becomes an alternative sleeve 240 used to the pneumatic actuator 100 pretension. Like the in 2 and 3 illustrated sleeve 140 is also the alternative sleeve 240 a hollow cylinder adapted to serve as a stop which retracts the actuator rod 34 in the case 101 Limited beyond a predetermined bias position. The alternative sleeve 240 however, has no thread on the inner surface thereof, and has an inner diameter formed to have a minimum clearance relative to an outer diameter of the actuator rod 34 show that also can be threadless. When in operation, the actuator rod 34 is in a desired preload position, the position of the sleeve 240 along the actuator rod 34 set until a first end 142 the sleeve 140 against a structural portion of the pneumatic actuator 100 is applied, and then the sleeve 240 on the actuator rod 34 fixed, for example by welding or any other form-fitting method. In this embodiment, further adjustments can not easily be made when the initial bias has been adjusted.

A method for adjusting the bias of the pneumatic actuator 100 for use with a normally open wastegate valve 30 includes the following steps. First, a gas pressure is applied to the first chamber 109 of the housing 101 created by applying compressed air through the fluid inlet 126 provided. A sufficient gas pressure is applied to the actuator rod 34 in a maximum external (eg advanced) position extend. In this position becomes a free end 36 the actuator rod 34 with the closed wastegate valve 30 for example via a linkage 38 connected. These steps become the wastegate valve 30 adjusted so that it is closed when the actuator rod is in a maximum extended position.

After the wastegate valve 30 is adjusted so that it is closed when the actuator rod 34 is in a maximum extended position, the position of the actuator rod 34 determines the open position (eg, the bias position) of the wastegate valve 30 equivalent. For this purpose, the gas pressure within the first chamber 109 of the pneumatic actuator 100 Relieves the actuator rod 34 to allow all the way into the case 101 retract. Then a sufficient gas pressure on the first chamber 109 of the housing 101 exercised to the actuator rod 34 in a bias position corresponding to a fully open position of the wastegate valve 30 extend. For example, based on the spring constant k of the spring 120 the pressure within the first chamber 109 be adjusted so that he has a slight advance of the actuator rod 34 achieved relative to their completely retracted position. In some embodiments, the pressure sufficient to provide advancement in a range of 1 mm to 5 mm, or in a range of 2 mm to 3 mm, may provide sufficient bias to the wastegate valve 30 to hold in the desired open position. While the actuator rod 34 is in the desired (preload) position, the sleeve is 140 . 240 on the actuator rod 34 placed in such a way that the actuator rod is prevented from retracting beyond the bias position into the housing. In particular, the sleeve 140 . 240 so on the actuator rod 34 placed that first end 142 the sleeve 140 . 240 against a structural portion of the pneumatic actuator 100 is applied. This will cause the actuator rod 34 due to the interference between the sleeve 140 . 240 and the structural portion of the pneumatic actuator 100 prevented from beyond the bias position into the housing 101 retract.

Although the pneumatic actuator 100 with pressurized air from the compressor section 4 of the turbocharger 1 is supplied, is the pneumatic actuator 100 not limited to this configuration. For example, the pneumatic actuator 100 be supplied with pressurized air from other sources, such as high-pressure air tanks on the vehicle, and controlled by a control valve.

The structural section of the pneumatic actuator 100 is not on the mounting arm 150 limited and may, depending on the specific application other elements of the pneumatic actuator 100 include. For example, the structural portion may alternatively be the second housing end 106 , a screen element 107 , etc.

Although the turbocharger 1 with a wastegate valve 30 is illustrated by the flap type, is the turbocharger 1 not limited to this type of wastegate valve. For example, the wastegate valve 30 alternatively a poppet valve, a rotary valve or another suitable valve.

The invention has been described purely by way of illustration; It should be clear that the terminology used is purely descriptive and not meant to be limiting. In light of the above teachings, various modifications and variations of the present invention are possible. Therefore, it should be understood that within the scope of the following claims, the invention may be practiced otherwise than as specifically described.

Claims (14)

Pneumatic actuator ( 100 ), comprising: a housing ( 101 ), which has a first housing end ( 104 ), a second housing end ( 106 ), which is the first end ( 104 ) and an air intake ( 126 ) which is in the first housing end ( 104 ), a membrane ( 114 ) in the housing ( 101 ) between the first end ( 104 ) and the second end, wherein the membrane ( 114 ) an interior ( 108 ) of the housing ( 101 ) into a first chamber ( 109 ) and a second chamber ( 110 ) divided; a piston ( 112 ) in the second chamber ( 110 ) and so with the membrane ( 114 ) that the movement of the piston ( 112 ) to a change in the size of the first chamber ( 109 ) and the second chamber ( 110 ) leads; a feather ( 120 ) in the second chamber ( 110 ) is arranged, wherein the spring ( 120 ) is adapted to the piston ( 112 ) to the first housing end ( 104 ) to urge; an actuator rod ( 34 ) with a first rod end ( 33 ), with the piston ( 112 ), an opposite second rod end ( 36 ), and a hub portion extending through a in the second housing end ( 106 ) formed opening extends; and a sleeve ( 140 . 120 ) attached to the actuator rod ( 34 ) between the housing ( 101 ) and the second rod end ( 36 ) is arranged, wherein the sleeve ( 140 . 240 ) is designed to act as a stop, the retraction of the actuator rod ( 34 ) in the housing ( 101 ) is limited beyond a predetermined bias position. Pneumatic actuator ( 100 ) according to claim 1, wherein the actuator rod ( 34 ) has an external thread, and the sleeve ( 140 ) has an internal thread with the external thread of the actuator rod ( 34 ) is engaged. Pneumatic actuator ( 100 ) according to claim 1, wherein the sleeve ( 240 ) on the actuator rod ( 34 ) is fixed. Pneumatic actuator ( 100 ) according to claim 1, wherein the position of the sleeve ( 140 ) on the actuator rod ( 34 ) is adjustable. Pneumatic actuator ( 100 ) according to claim 1, comprising a fastening arm ( 150 ), which is adapted to the housing ( 101 ), the sleeve ( 140 . 240 ) on the actuator rod ( 34 ) is arranged so that it on the mounting arm ( 150 ), whereby the actuator rod ( 34 ) due to the interference between the sleeve ( 140 . 240 ) and the fastening arm ( 150 ) is prevented from going beyond the predetermined biasing position into the housing (FIG. 101 ) retract. Method for adjusting a preload of a pneumatic actuator ( 100 ) for use with a normally open valve, comprising the following steps: applying a gas pressure to the pneumatic actuator ( 100 ) to the actuator rod ( 34 ) extend into a maximum external position; Connecting the actuator rod ( 34 ) with the valve ( 30 ), whereby the valve ( 30 ) in the closed position; Relieving the gas pressure within the pneumatic actuator ( 100 ) to the actuator rod ( 34 ) in a housing ( 101 ) of the pneumatic actuator ( 100 ) to be retracted; Applying sufficient pressure to the pneumatic actuator ( 100 ) to the actuator rod ( 34 ) in a bias position corresponding to a fully open position of the valve ( 30 ) to drive out; while the actuator rod ( 34 ) in the bias position, placing a sleeve ( 140 . 240 ) on the actuator rod ( 34 ) in such a way that the actuator rod ( 34 ) is prevented from passing beyond the bias position into the housing ( 101 ) retract. The method of claim 6, wherein the step of applying sufficient pressure to the pneumatic actuator (10) 100 ) to the actuator rod ( 34 ) in a bias position corresponding to a fully open position of the valve ( 30 ), applying a sufficient pressure to the actuator rod ( 34 ) to advance to a shift in a range of 1 to 5 mm. The method of claim 6, further comprising fixing the sleeve (10). 240 ) on the actuator rod ( 34 ). The method of claim 6, further comprising adjusting the position of the sleeve (10). 140 ) relative to the actuator rod ( 34 ), when the actuator rod ( 34 ) is in the bias position. The method of claim 9, wherein the sleeve ( 140 ) with the actuator rod ( 34 ) is connected via a threaded interface, and adjusting the position of the sleeve ( 140 ) turning the sleeve ( 140 ) relative to the actuator rod ( 34 ). Method according to claim 6, wherein the actuator rod ( 34 ) due to the interference between the sleeve ( 140 . 240 ) and the structural section of the pneumatic actuator ( 100 ) is prevented from passing beyond the bias position into the housing ( 101 ) retract. The method of claim 11, wherein the structural portion of the pneumatic actuator ( 100 ) either the housing ( 101 ) or a fastening arm ( 150 ), which is the housing ( 101 ) wearing. Turbocharger ( 1 ), comprising: a compressor section ( 4 ) with a compressor wheel ( 28 ), a turbine section ( 2 ) with a turbine housing ( 8th ), which is a turbine wheel ( 16 ), wherein the turbine wheel ( 16 ) with the compressor wheel ( 28 ) over a wave ( 18 ), a normally open wastegate valve ( 30 ), of the turbine housing ( 8th ) and a pneumatic actuator ( 100 ) which is adapted to the wastegate valve ( 30 ), wherein the pneumatic actuator ( 100 ) comprises: a housing ( 101 ), which has a first housing end ( 104 ), a second housing end ( 106 ), which is the first end ( 104 ) and an air intake ( 126 ) which is in the first housing end ( 104 ), a membrane ( 114 ) in the housing ( 101 ) between the first end ( 104 ) and the second end, wherein the membrane ( 114 ) an interior ( 108 ) of the housing ( 101 ) into a first chamber ( 109 ) and a second chamber ( 110 ) divided; a piston ( 112 ) in the second chamber ( 110 ) and so with the membrane ( 114 ) that the movement of the piston ( 112 ) to a change in the size of the first chamber ( 109 ) and the second chamber ( 110 ) leads; a feather ( 120 ) in the second chamber ( 110 ) is arranged, wherein the spring ( 120 ) is adapted to the piston ( 112 ) to the first housing end ( 104 ) to urge; an actuator rod ( 34 ) with a first rod end ( 33 ), with the piston ( 112 ), an opposite second rod end ( 36 ), and a rod center portion extending through one in the second housing end ( 106 ) formed opening extends; and a sleeve ( 140 . 120 ) attached to the actuator rod ( 34 ) between the housing ( 101 ) and the second rod end ( 36 ) is arranged, wherein the sleeve ( 140 . 240 ) is designed to act as a stop, the retraction of the actuator rod ( 34 ) in the housing ( 101 ) is limited beyond a predetermined bias position. Turbocharger ( 1 ) according to claim 13, wherein the actuator rod ( 34 ) due to the interference between the sleeve ( 140 . 240 ) and a structural portion of the pneumatic actuator ( 100 ) is prevented from passing beyond the bias position into the housing ( 101 ) retract.

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