DE102009002518A1 - high pressure pump - Google Patents

Abstract

A high-pressure pump (1), which serves in particular as a radial or inline piston pump for fuel injection systems of air-compressing, self-igniting internal combustion engines, has a pump assembly (13) and a drive shaft (6). In this case, the pump assembly (13) comprises a pump piston (16) which is guided in a cylinder bore (15) along an axis (17) of the cylinder bore (15) and which can be driven by the drive shaft (6). Further, an end face (19) of the pump piston (16) in the cylinder bore (15) defines a pump working space (20). The pump piston (16) is formed of a material having an anisotropic modulus of elasticity. As a result, at a high pressure in the pump working chamber (20), which causes an expansion of the cylinder bore (15), a radial deformation of the pump piston (16) can be achieved, which compensates for the expansion of the cylinder bore (15).

Description

State of the art

The The invention relates to a high-pressure pump, in particular a radial or inline piston pump. Specifically, the invention relates to the field fuel pumps for fuel injection systems of air-compressing, self-igniting internal combustion engines.

From the DE 10 2005 046 670 A1 a high pressure pump for a fuel injector of an internal combustion engine is known. The known high-pressure pump has a multipart pump housing, in which at least one pump element is arranged. The pump element comprises a driven by a drive shaft in a pumping motion pump piston which is slidably guided in a cylinder bore of a portion of the pump housing and defines a pump working space therein. The pump piston is supported on the drive shaft via a hollow-cylindrical ram, wherein the ram is displaceably guided in a bore of a part of the pump housing in the direction of the longitudinal axis of the pump piston. During the suction stroke of the pump piston, in which this moves radially inward, the pump chamber is filled with fuel through a fuel inlet channel with the inlet valve open, with the outlet valve is closed. During the delivery stroke of the pump piston, in which this moves radially outward, fuel is conveyed by the pump piston under high pressure through a fuel discharge channel with the exhaust valve open to a high-pressure accumulator, wherein the inlet valve is closed.

The from the DE 10 2005 046 670 A1 known high pressure pump has the disadvantage that it comes in operation due to the high pressure in the pump working space to a leak on the leadership of the pump piston. This results in deformations of the pump piston and a cylinder bore in which the pump piston is guided, which leads to a widening of the guide and thus an increasing leakage with increasing high pressure.

Disclosure of the invention

The High-pressure pump according to the invention with the features of claim 1 has the advantage that a high efficiency allows is. Specifically, the increase in leakage of fuel from the Pump work space prevented or at least reduced.

By the measures listed in the dependent claims are advantageous developments of specified in claim 1 High pressure pump possible.

Advantageous it is that the material of the pump piston, which is an anisotropic Has elastic modulus, has a transverse strain number, the not less than 0.3. This can cause a negative radial deformation, in which the pump piston is radially compressed due to the pressure load will be avoided. This can be an excessive Leakage can be prevented. A leak between the pump piston and the cylinder bore, in which the pump piston guided is, has the disadvantage that it comes to efficiency losses, the increase with increasing pressure in the pump workspace. This is also the field of application with regard to relatively high pressures limited. By reducing the leakage can on the one hand the Efficiency can be increased. On the other hand, the scope of application towards larger producible by the high pressure pump Press to be enlarged.

Advantageous it is that the material of the pump piston along the axis of Cylinder bore has a smaller modulus of elasticity as perpendicular to the axis of the cylinder bore. That's what happens with increasing pressure in the pump working space to a shortening the pump piston along the axis of the cylinder bore and to a Radial expansion, that is to a positive radial deformation, the pump piston in relation to a frontal loading of the pump piston. Furthermore, a radial admission of the occurs Pump piston by the high pressure fuel in a gap between the cylinder bore and the pump piston. This action acts on the positive radial deformation of the pump piston opposite. Depending on the design of the pump piston, the effectively resulting Radial deformation preferably about zero or greater to be zero. As a result, an optionally occurring Expansion of the cylinder bore in the area of the pump piston compensated become.

Advantageous it is that the material of the pump piston is a metallic or Partial metallic material is processed anisotropically. in this connection it is also advantageous that the material of the pump piston by at least one anisotropic rolling process and / or at least an anisotropic solidification process is processed. Thus, can targeted an anisotropic design of the material in terms on the axial extent of the pump piston and a radial expansion of the pump piston, which is perpendicular to the axial extent of the pump piston is done.

It is also advantageous that the material of the pump piston is a glass and / or carbon fiber is carbon fiber material that is anisotropically reinforced by glass and / or carbon fibers. As a result, a targeted directional dependence of the modulus of elasticity in the axial direction and in a direction perpendicular to the axial direction can be predetermined in an advantageous manner. In addition, the size of the modulus of elasticity can be specified in the axial direction and in the radial direction.

Advantageous it is that the pump piston has an end face, that the end face of the pump piston in the cylinder bore limits the pump working space and that the pump piston designed so is that when an impact on the face of the Pump piston with a high prevailing in the pump work space Pressure an at least substantially vanishing radial deformation the pump piston at least in the portion of the material, the anisotropic modulus of elasticity occurs. in this connection it is further advantageous that the material of the pump piston, which has an anisotropic elastic modulus, a transverse strain number from a range of about 0.3 to about 0.6. hereby can advantageously at least substantially vanishing Radial deformation of the pump piston can be achieved, allowing an increase leakage with increasing pressure in the pump working space is reduced is.

Advantageous However, it is also the case that the pump piston has an end face has, that the end face of the pump piston in the Cylinder bore limits the pump working space and that the pump piston is configured so that when an impact on the end face of the pump piston with a high prevailing in the pump work space Pressure a positive radial deformation of the pump piston at least in the section of the material containing the anisotropic modulus of elasticity has occurred. It is also advantageous that the Material of the pump piston, which has an anisotropic modulus of elasticity has a transverse strain number, the larger than 0.5. This can advantageously a positive radial deformation be achieved so that the increase of leakage with increasing Pressure is further reduced or completely prevented. This may optionally an expansion of the cylinder bore in the region of the pump piston compensated in whole or in part by a positive radial expansion become.

preferred Embodiments of the invention are in the following Description with reference to the accompanying drawings, in which corresponding elements with matching reference numerals are provided, explained in more detail. It shows:

1 a high pressure pump in a schematic, axial sectional view according to an embodiment of the invention;

2 the in 1 labeled II section of the high-pressure pump of the embodiment of the invention in a schematic representation illustrating a longitudinal load;

3 the in 2 illustrated section in a schematic representation illustrating a lateral load; and

4 the in 2 shown detail in a schematic representation, which is a sum of the in 2 illustrated longitudinal load and the in 3 illustrates cross-load illustrated.

1 shows a high pressure pump 1 in a schematic, axial sectional view according to an embodiment. The high pressure pump 1 can be used in particular as a radial or inline piston pump for fuel injection systems of air-compressing, self-igniting internal combustion engines. Specifically, the high pressure pump is suitable 1 for a fuel injection system with a fuel rail that stores diesel fuel under high pressure. The high-pressure pump according to the invention 1 However, it is also suitable for other applications.

The high pressure pump 1 has a multi-part housing 2 on. In this embodiment, the housing consists 2 from the housing parts 3 . 4 . 5 , wherein the housing part 3 a basic body 3 , the housing part 4 a cylinder head 4 and the housing part 5 one on the main body 3 attached flange 5 represents.

The high pressure pump 1 has a drive shaft 6 on the one hand at a depository 7 in the housing part 2 and on the other hand at a storage location 8th in the housing part 3 is stored. Between the bearings 7 . 8th has the drive shaft 6 a cam 9 on. The cam 9 can be configured as single or multiple cam. Furthermore, the term "cam" also includes an embodiment of the cam 9 in which the drive shaft 6 an eccentric portion or the like.

The housing part 3 the high pressure pump 1 has a guide hole 12 on, in which a pump assembly 13 is arranged. The cam 9 is the pump assembly 13 assigned. Depending on the design of the high-pressure pump 1 It is also possible to provide a plurality of pump assemblies that correspond to the pump assembly 13 are designed. Such pump assemblies can also be the cam 9 be assigned and / or one or more others, the cam 9 entspre be associated with cenden cam. Depending on the configuration, a radial or in-line piston pump can thereby be realized.

The cylinder head 4 has an approach 14 on. The approach 14 extends into the guide bore 12 , The approach 14 has a cylinder bore 15 on, in which a pump piston 16 along an axis 17 the cylinder bore 15 slidably guided. The pump piston 16 can do this along the axis 17 in the cylinder bore 15 to be moved back and forth, as indicated by the double arrow 18 is illustrated. The piston 16 has an end face 19 on having a pump work space 20 in the cylinder bore 15 limited. In the pump workroom 20 leads a fuel channel 21 in which an inlet valve 22 is arranged. With a suction stroke of the pump piston 16 flows over the inlet valve 22 Fuel from the fuel channel 21 into the pump workroom 20 , There is also a fuel channel 23 provided in which an exhaust valve 24 is arranged. With a delivery stroke of the pump piston 16 becomes high pressure fuel from the pump working space 20 via the outlet valve 24 in the fuel channel 23 promoted. The fuel channel 23 For example, it is connected to a fuel rail. As a result, high-pressure fuel can be supplied to such a fuel distributor strip.

The pump assembly 13 has a role 25 on that in a roller shoe 26 is stored. The roller shoe 26 is in a substantially hollow cylindrical tappet body 27 used. Furthermore, the plunger body 27 with a disk-shaped driving element 28 connected to the pump piston 16 above a covenant 29 embraces. This is the pump piston 16 about his covenant 29 in contact with the roller shoe 26 held. Here is a plunger spring 30 provided on the ram body 27 and the entrainment element 28 acts and thus the ram body 27 together with the pump piston 16 in the direction of the role 25 acted upon by a certain spring force. This causes the pump piston 16 with his covenant 29 , the roller shoe 26 , the role 25 and a tread 31 of the cam 9 each against each other, and this mutual contact even at high speeds of the high-pressure pump 1 is guaranteed.

In operation of the high pressure pump 1 is due to a rotation of the drive shaft 6 with the cam 9 around a rotation axis 32 the drive shaft 6 a reciprocating motion of the pump piston 16 achieved, so that the promotion of high-pressure fuel to a fuel rail or the like via the fuel channel 23 he follows. During the delivery stroke is thus in the pump workspace 20 high pressure fuel.

The generation of high pressure in the pump workspace 20 takes place during operation thus by means of the moving pump piston 16 in the cylinder bore 15 is very tight. Between the cylinder bore 15 and an outside 35 of the pump piston 16 there is a certain lead gap. The guide gap between the cylinder jacket outside 35 of the pump piston 16 and the cylinder bore 15 is chosen so that on the one hand sufficient ease of the pump piston 16 is guaranteed and on the other hand, a leakage over the guide gap is as small as possible. By this given very narrow leadership low pressure leakage is specified. However, there is a problem that, due to the widely varying pressure in the pump working space 20 a pressure-induced widening of the guide gap starting from the pump working space 20 along the cylinder bore 15 can occur. This can on the one hand by acting on the guide gap of the approach 14 of the cylinder head 4 in the area of the cylinder bore 15 be widened. On the other hand, the pump piston 16 on its outside 35 be applied and compressed accordingly. The pumps piston 16 the high pressure pump 1 of the embodiment is formed of a material having an anisotropic elastic modulus. As a result, leakage over the guide gap can be reduced. Specifically, one may be with increasing pressure in the pump workspace 20 possible increase in the amount of leakage prevented or at least reduced. As a result, especially at very high pressures in the pump working space 20 an excessively large leakage can be prevented. By one at very high pressures in the pump workspace 20 Occurring leakage creates a significant loss of energy, which can thus be reduced or prevented. This allows a high efficiency of the high pressure pump 1 be guaranteed even at high pressures to be generated.

The embodiment of the pump piston 16 the high pressure pump 1 of the embodiment is described below with reference to the 2 to 4 described in further detail.

2 shows the in 1 with II designated section of the pump piston 16 the high pressure pump 1 of the embodiment in a schematic representation, wherein a radial deformation U _RL is illustrated due to a longitudinal load. In the pump workroom 20 There is a pressure P on the face 19 of the pump piston 16 acts. Along the axis 17 of the pump piston 16 This causes a shortening of the pump piston 16 that is a change in length 36 , on. The pump piston 16 is cylindrical in this embodiment. The pump piston 16 indicates here in the initial state, ie without Pressurization on the face 19 , a radius R on. The pump piston 16 is formed of a material having an anisotropic modulus of elasticity. Here is along the axis 17 given a relatively small elasticity, while in the radial direction, that is perpendicular to the axis 17 , a relatively large elasticity is given. The modulus of elasticity is therefore along the axis 17 relatively small and relatively large in the radial direction. In addition, the material of the pump piston 16 a transverse strain number v which is not smaller than 0.3. The ratio of a longitudinal strain to a transverse strain is thus greater than or equal to 0.3. For example, an anisotropically machined steel may have a transverse strain of 0.3.

The radial deformation U _RL due to the longitudinal load results from the product of the transverse strain number v, the radius R of the pump piston 16 and the quotient of the pressure P and the elastic modulus in the longitudinal direction E _L : U RL = v · R · P / E L , (1)

This radial deformation U _RL due to the longitudinal load causes a certain expansion of the pump piston 16 along its axis 17 as it is in the 2 by a broken line 37 is illustrated. It should be noted that in the 2 only the radial deformation U _RL is illustrated due to the longitudinal load, which does not occur in isolation in practice. For the radial deformation U _RL due to the longitudinal load is still a radial deformation U _RQ due to a transverse load, which in the following with reference to 3 is illustrated.

3 shows the in 2 illustrated pump piston 16 in a partial, schematic representation, wherein the radial deformation U _RQ due to transverse load of the pump piston 16 is illustrated. In the 3 becomes the impingement of the pump piston 16 on its outside 35 idealized without the impingement on his face 19 shown. On the outside 35 becomes the pump piston 16 along the axis 17 by the pressure in the guide gap between the pump piston 16 and the cylinder bore 15 applied. In the area of the face 19 this pressure is equal to the pressure P in the pump working space 20 , In one direction 38 along the guide gap, the pressure in the guide gap decreases continuously. This is in the 3 by different lengths of arrows pointing to the outside 35 of the pump piston 16 show, illustrated. The pressure in the guide gap causes the pump piston 16 radially compressed, so that the radial deformation U _RQ occurs in the 3 by a broken line 39 is illustrated. For simplicity, it can be assumed in the zeroth approximation that the pressure in the guide gap in a to the end face 19 adjacent section 40 of the pump piston 16 equal to the pressure P in the pump working space 20 is. The radial deformation U _RQ in the section 40 then results as a product of a difference with a minuend equal to the transverse strain number v and a subtrahend equal to the number 1 is, the pressure P in the pump working space 20 and a quotient with a dividend equal to the radius R of the pump piston 16 is and a divisor which is equal to the elasticity in the transverse direction E _Q. The radius R is here the radius R of the pump piston 16 in the initial state. This results in: U RQ = (v - 1) · P · R / E Q , (2)

4 shows the in 2 shown section of the pump piston 16 in a schematic representation for explaining the embodiment, wherein the sum of the basis of the 2 illustrated radial deformation U _RL on the basis of longitudinal load and the basis 3 illustrated radial deformation U _{RQ is shown} due to lateral load. While in the 2 and 3 Thus, the isolated effects are shown, for the design of the pump piston 16 serve is in the 4 illustrates the combined effect occurring in practice. The radial deformation U results from the sum of the radial deformation U _RL due to longitudinal loading and the radial deformation U _RQ due to transverse loading: U = U RL + U RQ , (3)

This also occurs a shortening of the pump piston 16 that is a change in length 36 , on. For the radial deformation U due to longitudinal and transverse loading, formulas (1) and (2) thus result in: U = P · R · (v / E L + (v - 1) / E Q ). (4)

By expanding the formula (4) with a quotient whose dividend and divisor are equal to the elasticity in the longitudinal direction E _L and therefore equal to 1, the result is: U = P · R · (v · E Q + v · E L - E L ) / (E L · e Q ). (5)

From the formula (4) or the formula (5), it is found that the radial deformation U is positive and large when the elasticity in the longitudinal direction E _L becomes small, when the transverse strain number v becomes large and when the elasticity in the transverse direction E _Q becomes large , Thus, by an embodiment of the pump piston 16 given predetermined variation of the modulus of elasticity, the desired radial deformation U can be specified.

A special case arises when the Elastizi Modulus in the longitudinal direction E _{L is} equal to the modulus of elasticity in the transverse direction E _Q. Then: U = P * R * (2 * v-1) / E, (6) where E denotes the modulus of elasticity, which is the same in the longitudinal and transverse directions. In this special case, the radial deformation U becomes positive if the transverse strain number v is greater than 0.5. By a further increase in the transverse strain number V, the radial deformation U can be further increased.

Thus, by a specification in which the elastic modulus in the transverse direction E _{Q is} greater than the modulus of elasticity in the longitudinal direction E _L and / or a specification in which the transverse strain number v is greater than 0.5, a positive and large radial deformation U can be achieved. It is also possible that the properties of the material of the pump piston 16 along the axis 17 in that direction 38 be varied to match the also along the axis 17 to achieve varying pressure in the guide gap.

By a positive radial deformation U, that is by a radial deformation U, with increasing pressure P in the pump working space 20 increases, as it results from the formula (4) and (5), thus can also be a certain expansion of the cylinder bore 15 of the approach 14 be compensated in whole or in part with increasing pressure. Thus, an undesirable increase in leakage over the guide gap can be reduced or prevented. In particular, leakage occurring during operation can occur even at high pressures in the pump working space 20 be limited to relatively low values. This is the high pressure pump 1 of the embodiment also for generating very high pressures in the pump working space 20 suitable.

Based on 4 illustrates an embodiment in which the radial deformation U is positive. Depending on the particular application, however, it is also possible to use the pump piston 16 be designed so that it assumes a cylindrical shape at the high pressure P reached in the pump working space or maintains. This is particularly advantageous in embodiments in which the cylinder bore 15 not or only slightly with increasing pressure P in the pump working space 20 expands.

The pump piston 16 For example, it may be formed of a metallic material. Targeted rolling and solidification processes can be used to produce an anisotropic modulus of elasticity in the pump piston 16 to achieve. Here, specifically, a difference between the elastic modulus in the longitudinal direction E _L , that is, along the axis 17 , And the modulus of elasticity in the transverse direction E _Q , that is in Rich tion of the radius R, given. Furthermore, it is possible to use the pump piston 16 made of glass fiber and / or carbon fiber materials, wherein the glass and / or carbon fibers anisotropic, in particular with a larger proportion in the radial direction, in the pump piston 16 are arranged. Due to the relatively small elastic modulus in the longitudinal direction E _L , the deformation 36 under pressure along the axis 17 of the pump piston 16 large, the material being the material of the pump piston 16 due to the large transverse strain number v preferably in the transverse direction, that is in the radial direction, evades, while the pump piston 16 due to the pressure load on its outside 35 because of the high modulus of elasticity in the transverse direction E _Q is constricted only very slightly.

By a variable design of the modulus of elasticity in the longitudinal and transverse directions, a deformation of the pump piston 16 be specified under pressure.

The Invention is not limited to the described embodiments limited.

QUOTES INCLUDE IN THE DESCRIPTION

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Cited patent literature

• - DE 102005046670 A1 [0002, 0003]

Claims (10)

High pressure pump ( 1 ), in particular radial or inline piston pump for fuel injection systems of air-compressing, self-igniting internal combustion engines, with at least one pump assembly ( 13 ) and a drive shaft ( 6 ), the pump assembly ( 13 ) one in a cylinder bore ( 15 ) along an axis ( 17 ) of the cylinder bore ( 15 ) guided pump piston, of the drive shaft ( 6 ) is drivable, and wherein the pump piston ( 16 ) in the cylinder bore ( 15 ) a pump work space ( 20 ), characterized in that the pump piston ( 16 ) is at least partially formed of a material having an anisotropic elastic modulus. High-pressure pump according to claim 1, characterized in that the material of the pump piston ( 16 ) having an anisotropic elastic modulus has a transverse strain number not smaller than 0.3. High-pressure pump according to claim 1 or 2, characterized in that the material of the pump piston ( 16 ) has a modulus of elasticity along the axis ( 14 ) of the cylinder bore ( 15 ) is smaller than perpendicular to the axis ( 14 ) of the cylinder bore ( 15 ). High-pressure pump according to one of claims 1 to 3, characterized in that the material of the pump piston ( 16 ) is a metallic or partially metallic material that is processed anisotropically. High-pressure pump according to claim 4, characterized in that the material of the pump piston ( 16 ) is processed by at least one anisotropic rolling process and / or at least one anisotropic solidification process. High-pressure pump according to one of claims 1 to 3, characterized in that the material of the pump piston ( 16 ) is a glass and / or carbon fiber material which is anisotropically reinforced by glass and / or carbon fibers. High-pressure pump according to one of claims 1 to 6, characterized in that the pump piston ( 16 ) an end face ( 19 ), that the end face ( 19 ) of the pump piston ( 16 ) in the cylinder bore ( 15 ) a pump work space ( 20 ) and that the pump piston ( 16 ) is designed so that when an action on the end face ( 19 ) of the pump piston ( 16 ) with a high in the pump work space ( 20 ) prevailing pressure an at least substantially vanishing radial deformation of the pump piston ( 16 ) occurs at least in the portion of the material having the anisotropic modulus of elasticity. High-pressure pump according to claim 7, characterized in that the material of the pump piston ( 16 ) having an anisotropic elastic modulus has a transverse strain number in a range of about 0.3 to about 0.5. High-pressure pump according to one of claims 1 to 6, characterized in that the pump piston ( 16 ) an end face ( 19 ), that the end face ( 19 ) of the pump piston ( 16 ) in the cylinder bore ( 15 ) in the pump workspace ( 20 ) is limited and that the pump piston ( 16 ) is designed so that when an action on the end face ( 19 ) of the pump piston ( 16 ) with a high in the pump work space ( 20 ) prevailing pressure a positive radial deformation of the pump piston ( 16 ) occurs at least in the portion of the material having the anisotropic elastic modulus. High-pressure pump according to claim 9, characterized in that the material of the pump piston ( 16 ) having an anisotropic elastic modulus has a transverse strain number greater than 0.5.