JP3522782B2 - Pump device - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a tank containing a fluid to be pumped, a main pump section for sending a controlled amount of the fluid at a predetermined pressure, and a main pump section for delivering the fluid from the tank. And a supply pump for supplying more than the controlled amount.

Pump systems of the above type are used, for example, when the main pump part is of the type of high pressure pump. In this case, the feed pump ensures that sufficient fluid flow is always available, preferably at a predetermined pressure, at the inlet portion of the high-pressure pump.

[0003]

BACKGROUND OF THE INVENTION A pump device of the above type is described, for example, in EP-A-0299337, which pump device relates to a pump device for a motor vehicle fuel injector. In this case, the feed pump is connected to parallel pressure relief valves that return all excess fluid directly to the tank.

Depending on the power and the delivery pressure, the main pump part is subject to rather severe mechanical and / or thermal stresses,
This stress is very large for main pump section delivery pressures on the order of a few hundreds of 10 ⁵ Pa , thus necessitating steps to control or limit said stress.

[0005]

SUMMARY OF THE INVENTION The present invention provides a pump device of the above type which allows mechanical and / or thermal stresses in the components of the main pump part to be controlled easily and without failure. To aim.

[0006]

SUMMARY OF THE INVENTION According to the present invention, a tank containing a fluid to be pumped, a main pump section for delivering a controlled amount of the fluid at a predetermined pressure, and a fluid from the tank. A large thermal stress in a pump device including a supply pump that supplies the main pump unit in excess of the controlled amount, and a return unit that returns excess fluid to the tank along a given discharge passage. And / or at least a part of the discharge passage running in the region of the main pump part that is subject to mechanical stress is provided.

[0007]

The non-limiting embodiments of the invention are described below by way of example with reference to the accompanying drawings.

The pump device of FIG. 1 contains a tank T for containing the fluid to be pumped, a main pump section 10 consisting of an eccentric radial piston pump (high pressure pump) in the illustrated embodiment, and a fluid from the tank T The low pressure pump 11 which supplies to the pump part 10 is included. The high pressure pump 10 includes a hollow body 13 having a pair of opposite sides, namely an inflow side or left side and an outflow side or right side in FIG. The main body 13 houses three cylinders 12-1, 12-2, 12-3 (FIG. 2) which are arranged at equal angular intervals in the radial direction of 120 °. The central plane 14 of the diametrical body 13 for the three cylinders 12 intersects the axis 16 of the pump shaft 18.

The shaft 18 has sleeve bearings 20 and 22.
The holes 3 in the body 13 by means of two bearing parts of the type
It is rotatably mounted in 1. Two bearings 20 and 2
Between the two, the shaft 18 is provided with a cylinder-type eccentric portion 24 which is offset by a distance ME with respect to the axis of the shaft 18. By means of a sleeve bearing 26, the eccentric part 24 is fitted with a rotary eccentric or drive disk 28 provided with a central support hole 30 (FIG. 2). The outer peripheral surface of the disk 28 is 3
3 in which one flat portion 32-1, 32-2, 32-3 is interposed
Includes two circular pieces. The flat portion 32 is the cylinder 12
It is associated with and perpendicular to each axis. Each two adjacent flats 32 define a 60 ° angle alpha.

The eccentric disc 28 is fixed to the body 13 by the piston 12 in the angular position shown. When the shaft 18 is rotated, the center of the disk 28 rotates about the axis 16 with a radius ME. The flats 32 thus rotate about one circular path parallel to the flats themselves, as described in further detail below.
Periodically reduce or increase the pump chamber.

Each cylinder 12 includes a recess 64 (FIG. 1) and contains a non-slidable insert 36 having a guide hole 38 for slidably guiding the piston 40. The front surface of each piston 40 is radially outward,
The variable volume pump chamber 42 is defined and formed. Each chamber 42 has a fluid inlet 44 provided with a check valve 46 and a fluid outlet 48 provided with a check valve 50.

The inlet 44 is provided with a pipe 52 by the supply pump 11.
The fluid in the tank T is supplied along. The radial passage 54 of the body 13 is located on the inlet side of the body 13 and terminates in a distribution chamber 80 coaxial with the axis 16. An oblique branch passage 43 leads from the chamber 80 to another annular chamber 45.
Fluid is supplied to the cylinder 12 from each inlet 44.

From the distribution chamber 80, another system passage, or exhaust passage, described in more detail below, extends from which excess fluid not utilized by the piston 12 is returned to the tank T. This excess fluid is used to cool parts of the main pump section 10 that are subject to a large amount of thermal and / or mechanical stress, such as bearings and bearing surfaces and certain thermally stressed valve bodies. .

The discharge passage through which excess fluid is discharged is indicated by arrow S.
See below for more details. The discharge passage initially extends along the shaft 18 through the bearing 20 and along the eccentric portion 24 to the bearing 26 of the disk 28. At this point, the exhaust fluid flows through the flow section S ₁ for cooling and lubricating the bearing 26 and the flow section S ₂ through the chamber 27 formed in the pump housing body 13 and containing the recess for the insert 36.
It is divided into and.

Therefore, the flow portion S ₂ flows over the sliding contact surface between the flat portion 32 and each sliding shoe 62 that supports each piston 40. The portion S ₁ flows along the shaft 18 to the abutment end 29 of the support hole 31 and from there along a branch line 33 which is inclined slightly downward and also through a lateral hole 82 on the outlet side of the body 13. , To the water collection chamber 84 coaxial with the axis 16. The lateral hole 82 is connected to the tank T via the return line 35. From the chamber 27, the flow portion S ₂ also flows along the axial hole 83 which communicates with the lateral hole 82 and from there into the water collecting chamber 84.

The axis 1 is inserted in the hole 88 on the outflow side of the main body 13.
Concentric with 6 is a pressure relief valve 58 which is connected to the pressure outlet 48 by a line 56. The water collection chamber 84 surrounds the actuation rod 86 of the electromagnet 60, which exerts a variable load on the ball 87 of the pressure relief valve 58. Therefore, the passage through which the excess fluid from the supply pump 11 is discharged is not limited to the main pump portion, such as a bearing or sliding surface, which is subject to large mechanical stress, but also the pressure relief valve 5
8 as well, whereby the heat generated in the valve section will also be carried to the tank T by the exhaust fluid.

In an embodiment of the main part high-pressure pump 10,
The radially inner end of the piston 40 has a corresponding cup-shaped shoe 6 which is in sliding contact with each flat 32 of the eccentric disc 28.
Abut 2. The shoe 62 preferably has a cylindrical portion, the outer diameter of which is slightly smaller than the inner diameter W of the recess 64 of the insert 36.

The shoe 62 includes a circular disc portion 70 and a collar portion 72, the inner diameter of the collar portion being the guide disc 7.
4 is slightly larger than the outer diameter. Information disk 7
4 is mounted in an annular groove (not shown in detail) in the inner end portion of the piston 40, the rest of the piston being substantially cylindrical. The guide disc 74 is therefore the piston 4
It is mounted axially fixed to 0, without any further shallow annular groove being provided in order to minimize the weakening of the piston 40.

Return spring 66, shown in phantom in the drawing, has one end abutting shoulder 68 of insert 36 and the other end abutting disk 74. The disc 74 acts as a reaction surface for the return spring 66 and biases the piston 40 radially inward. In this way
As the volume of the pump chamber 42 increases, the piston 40 follows the radial inward movement of each flat 32 of the eccentric disc 28. Following this, the shoe 62 and each flat 32 slide laterally relative to each other. The stable flow of fluids S ₁ , S ₂ effectively cools and lubricates this sliding part, so that extra, eg hydraulic, means for reducing contact in this part is no longer necessary.

Rotation of the eccentric disc 28 produces a reciprocating frictional force Q on the shoe-like portion 62, which causes the shoe-like portion 62 to slide on the surface of the flat portion 32. The guide disk 74 aligns the shoe 62 in the position shown in the drawings, i.e., axially aligned with the pump piston 40, throughout the cycle of operation of the cylinder and piston assembly 12, 40.
Has the function of holding. In this way, the piston 40
Lateral position is ensured so that lateral frictional forces Q are absorbed radially via each piston 40 or guide 38 of the insert 36.

The radially inner front end of the piston 40 is preferably parallel to the outer surface of the disc portion 70 of the shoe portion 62 which is in sliding contact with the flat portion 32 of the eccentric disc 28.
It abuts the inner bottom surface of the second disc portion 70. The piston 40 and the shoe 62 are therefore formed separately, making these components more resilient by eliminating the stresses in the portion of the piston 40 and the shoe 62 and compensating for any slack between them and the housing body 13. Try to position it well. Therefore, a certain amount of slack does not destabilize the shoe 62 with respect to the lateral force Q it receives,
It exists between the outer peripheral surface of the guide disk 74 and the inner surface of the collar portion 72.

The height of the collar portion 72 is 2 of the eccentricity ME.
The height is preferably such that the guide disc 74 remains surrounded by the collar portion 72 throughout the stroke of the piston 40, which corresponds to double the stroke.
The collar portion thus eliminates any loss of the shoe 62 formed separately from the piston 40, which causes the piston 40 to move in the guide 38 of the insert 36 in the highest outer position (top in FIG. 1). When it disappears, the accidental detachment of the shoe is eliminated. The portion S ₂ of excess fluid from the feed pump 11 flowing through the chamber 27 constantly cools the contact surface between the piston 40 and the bottom of the cup-shaped shoe 62, so that there is a small movement in this part. Even if it occurs, excessive thermal stress does not occur.

In the above embodiment, the feed pump 11
Excess fluid from flows through the discharge passages S, S ₁ , S ₂ , 35 so as to be directly returned to the tank T. FIG. 3 shows a slightly different embodiment in which the discharge line 35 to the tank T is fitted with a pressure relief valve 190 and the pressure along the discharge passage is 2 × 10 ⁵ Pa or 3 × upstream of the valve 190. 10 ⁵ Pa
Limited to.

From the above description, the pumping device of the present invention runs the excess fluid over the area of the main pump portion 10 that is subject to large thermal and / or mechanical stresses, along the given discharge passage along the tank T. It is obvious that the load capacity of the pumping device can be increased without any modification of the device or circuit. Supply pump 11
Excess fluid from can be used to cool the working and other parts of the high pressure pump 10. In this way, a stable fluid flow of controlled direction and velocity is achieved through the main pump section 10 to minimize wasted space that would otherwise be heated.

The invention is particularly advantageous in the case of a pump system in which the main pump part 10 is provided with a plurality of radial pistons 40 actuated by eccentric cams 28. In this case, the cooling fluid from the supply pump 11 is advantageously guided through the housing body 13 and along the pump shaft 18. Therefore, by subjecting the main pump part housing part to minimal additional machining, the bearings 20, 22, 26
All parts that are subject to high mechanical and thermal stress, such as the eccentric mechanism 28 and the eccentric mechanism 28 are automatically smoothed.

Another advantage is usually the main pump section 10
It also exists in the fact that the pressure relief valve 58 provided in the tank is also filled with excess fluid that is returned to the tank T. Due to the normally high switching pressure of the pressure relief valve 58, the pumping device receives a large amount of heat at this time when it is activated, but this heat is effectively carried to the tank T together with the discharge fluid.
By using the eccentric cam 28 to actuate the radial piston 40, the sliding surface of the shoe 62 of the main pump portion 10 is subject to high mechanical stress and no other mitigation means are required. In this way, the operating life of the main pump part is increased and the efficiency and reliability of the main pump part is significantly improved by a simple structure.

It will be apparent that modifications and improvements can be made to the pump system described above without departing from the scope of the claims. For example, in the above embodiment, the feed pump 1
1 may also be provided with an additional pressure relief valve, the discharge line of which supplies fluid to line 52. further,
The radial piston pump can be replaced by a different type of high pressure pump.

[Brief description of drawings]

FIG. 1 is a schematic view of a pump device of the present invention.

2 is a cross section taken along the line IIA-IIA in FIG.
The right half is a view as seen from the direction IIB-IIB in FIG. 1.

FIG. 3 is a detailed view of a portion III of FIG. 1 according to a modification.

[Explanation of symbols]

10 ... Main pump part 11 ... Supply pump 12 ... Three cylinders 13 ... Hollow body (housing body) 18 ... Shaft 20, 22 ... Bearing 26 ... Sleeve bearing 27 ... Chamber 28 ... Eccentric disk 31 ... Hole 32 ... Flat portion 33 ... Branch pipe 35 ... Discharge pipe 40 ... Piston 43 ... Branch passage 44 ... Fluid inlet 48 ... Fluid outlet 52 ... Pipe 54 ... Radial passage 58, 60 ... Pressure relief valve 62 ... Shoe-like portion 70 ... Circular disc portion 82 ... lateral hole 84 ... water collecting chamber 86 ... operating rod 87 ... ball S, S _1, S ₂ ... flow section T ... tank

─────────────────────────────────────────────────── ─── Continuation of front page (51) Int.Cl. ⁷ Identification symbol FI F04B 1/053 (72) Inventor Franz Pavelek Debey-8771 Marktiedenfeld, Heckerstraße, 7 (72) Inventor Bernhard Arnold, Germany, Debey-8771 Roden-Anzbach, Mittrea Gasse, 8 (56) References JP-A-1-110877 (JP, A) Mitsuihei 4-103265 (JP, U) (58) ) Fields surveyed (Int.Cl. ⁷ , DB name) F04B 1/04 F02M 53/00 F02M 59/44 F04B 1/047 F04B 1/053

Claims (9)

(57) [Claims] 1. A tank (T) containing a fluid to be pumped, and an eccentric radial piston pump (10) for delivering a controlled amount of the fluid at a predetermined pressure. A main pump part 10) including a hollow body (13) having a housing chamber (27) for housing an eccentric cam (28) carried by a pump shaft (18); A pump device comprising two sleeve bearings (20, 22) rotatably mounted in a body (13), said fluid being further controlled from said tank (T) to said piston pump (10). A supply pump (11) that supplies more than a certain amount, the total excess of fluid starting from a distribution chamber (80) concentric with said pump shaft (18) A discharge passage (52, 5) extending to a valley bottom portion of the eccentric cam (28) that receives mechanical stress.
4, S, S ₁ , S ₂ , 33, 82), in the pump device, the discharge passages (52, 54, S, S ₁ , S ₂ , 33, 8)
2) axially extends from one of the bearings (20, 22) through the accommodation chamber (27) to the other of the bearings (20, 22), and an excess amount of fluid is supplied from the downstream side of the discharge passage to the tank. A pump device, wherein the pump device is returned to (T). 2. The piston pump (10) is 300 ×
2. Pumping device according to claim 1, for fueling motor vehicles, operating at pressures in the range of 10 < ⁵ > Pa to 1600 * 10 < ⁵ > Pa. 3. A pressure relief valve (190) incorporated in a return conduit (35) of the discharge passage (52, 54, S, S ₁ , S ₂ , 33, 82) downstream of the hollow body (13). )
The pump device according to claim 1, which comprises: 4. The piston pump (10) comprises a plurality of pistons (40) radially arranged in the hollow body (13), the eccentric cam (28) being an eccentric bearing () of the shaft (18). 26) including a sliding surface (32) mounted to actuate said radial piston (40),
The discharge passages (52, 54, S, S ₁ , S ₂ , 33, 8
2) is also the eccentric bearing (26) and the sliding surface (32)
The pumping device according to claim 1, including: 5. The hollow body (13) with one of the sleeve bearings (20, 22) proximate the distribution chamber (80).
The sleeve bearing (20, 22) arranged on the input side of the
On the other hand, the discharge hole (33) allows the hollow body (13)
Hole (31) in the hollow body (13) including a bump end (29) connected to a water collection chamber (84) located on the output side of the
The pump device according to claim 4, wherein the pump device is attached to the pump device. 6. The discharge passages (52, 54, S, S ₁ ,
S _2, the pump device according to claim 1 comprising an electromagnetic type pressure relief valve (58,60,86,87) embedded in 33,82). 7. The electromagnetic pressure relief valve (58, 60,
A pump arrangement according to claim 5 or 6, wherein 86, 87) comprises an outlet end (86, 87) surrounded by the water collecting chamber (84). 8. The water collecting chamber (84) has the discharge passage (5).
2, 54, S, S ₁ , S ₂ , 33, 82) branch path (8
The pump device according to claim 7, which is directly connected to the accommodation chamber (27) via 3). 9. The eccentric cam is formed by a circular drive disc (28) mounted for rotation on an eccentric portion (24) of the shaft (18), the sliding surface (32) being each sliding shoe. The pumping device according to claim 8, including a plurality of flat portions (32) contacting each piston (40) via a portion (62).