KR102307758B1 - vane pump - Google Patents

Abstract

A vane pump (12) having a housing having an inner plate (22), an outer plate (24) and a perimeter liner (26), the rotor (20) having a plurality of slots opening into the peripheral surface, each A blade 40 is slidably disposed in the slot, and a spring is compressed at a lower portion of the slot that presses the blade 40 outward, so that the blade is a housing forming a plurality of arcuate chambers (C). It slides against the liner 26 . The blade pump has an inlet 48 opening into the chamber C and a second inlet 58 opening into the inner end 38 of the slot.

Description

vane pump

The present invention relates to blade pumps, and more particularly to means for maintaining fluid pressure around the blades of said pumps.

In a blade pump, a blade sliding radially within a slot of a rotor moves in and out of that slot as a function of rotation of the rotor. Fluid communication is provided to allow fluid to flow inwardly towards the bottom of the slot to compensate for pressure drop and spikes as the blade moves.

In diesel injection equipment, a blade pump is generally used as a feed pump that draws fuel from a low pressure tank and delivers it to a high pressure pump. Under certain conditions of engine equipment, such as at high RPM and low atmospheric pressure, pressure spikes are observed around the blades that cause cavitation erosion in the rotor and impede blade displacement and feed pump operation.

Accordingly, it is an object of the present invention to solve the above problems by providing a blade pump having a housing having an inner plate, an outer plate, and a peripheral liner defining an inner space in which the rotor rotates about a main axis. The rotor has a first face that slides against an inner plate, a second face that slides against the outer plate, and a peripheral cylindrical face. The rotor has a plurality of slots open into the peripheral surface, a blade is slidably disposed in each slot, and a spring is compressed at a lower or inner end of the slot against an inner end of the blade to compress the blade. by outwardly pressing the blade, the blade protrudes out of the slot, and the outer end of the blade slides against the liner of the housing, thereby forming a plurality of spaces between the peripheral surface of the rotor, the liner and the outer end of the blade. to form an arcuate chamber of The volume of the chamber changes periodically, large and small, as the rotor rotates.

The blade pump further has an inlet opening into the large volume chamber and an outlet opening into the small volume chamber, so that, in use, the fluid entering the inlet fills the large volume and is compressed and pushed toward the outlet.

The blade pump further has a second inlet opening into the inner end of the slot such that, in use, the fluid flows through the first inlet into the chamber and through the second opening into the spring compressed volume.

Further, the second inlet extends over an angular width such that, in use, the inner end of the slot is filled over the extended angle of rotation of the rotor.

The angular width is substantially 2/3 of the angle between two consecutive slots.

Further, the second opening has an arcuate shape.

Further, the rotor further includes a groove recessed into a first side, each groove opening at an inlet end in an inner end of the slot and extending into the first side toward a closed end, thereby closing the second inlet in use The fluid flowing through it flows into the groove towards the inner end of the slot, while the inner end no longer faces the second inlet.

Further, the groove extends over an angular width W such that, upon operation of the pump, the inner end of the slot is filled for an extended period of time.

The angular width of the groove is substantially 2/3 of the angle between two consecutive slots.

Each blade also has two sealing tip edges sliding against the liner and an outer end having a fluid communication channel, the fluid communication channel being through the blade into an inner end of the slot through which the spring is compressed. It extends from an inner end at which the channel opens to an outer end at which the channel opens between the tip edges.

The present invention also relates to a fuel pump assembly disposed within a fuel injection device, the fuel pump assembly comprising a feed pump for drawing fuel from a low pressure tank and delivering it to a high pressure pump, the feed pump as described above. It is a blade pump.

The present invention will be described by way of example with reference to the accompanying drawings.
1 is a cross-sectional view of a diesel pump including a blade pump and a high pressure pump.
FIG. 2 is an axial cross-sectional view of the blade pump of FIG. 1 , rotating about a main axis X1 .
FIG. 3 is an enlarged view of a part of FIG. 2 , which shows in detail the area of the blade in the axial direction X1 cross-section;
FIG. 4 is a radial cross-sectional view of the blade pump of FIG. 2 , the cross-sectional view showing a first side of the pump;
FIG. 5 is an enlarged view of FIG. 4 of an inlet area disposed on the first side;
6 is an enlarged view showing the details of the blade in the radial direction (X1) section.
Fig. 7 is a 3D view of the rotor of the pump of Fig. 2;

In an internal combustion engine with direct fuel injection equipment, the pump assembly 10 shown in FIG. 1 directs fuel from a low pressure tank that pressurizes and delivers fuel to a high pressure reservoir that is dispensed to the fuel injectors.

The fuel pump assembly 10 , which in a selected embodiment is a diesel pump, includes a transfer pump 12 and a high pressure pump 14 , both pumps fixed to the cambox 16 . A camshaft 18 rotating within the cambox 16 imparts a rotary motion to the transfer pump 12 and a reciprocating linear motion to one or more pistons of the high pressure pump 14 .

The transfer pump 12 described is the blade pump 12 shown and described with reference to FIGS. 2 to 7 .

A typical blade pump 12 has a housing with peripheral walls defining an interior space S in which the rotor 20 rotates about a main axis X1. The peripheral wall comprises an inner plate 12 (also called distribution plate 22) transverse to the main axis X1, an outer plate 24 transverse to the main axis X1, and a peripheral liner defining a cylindrical track. (26).

The rotor 20 has a cylindrical shape and has a first face 28 configured to slide against an inner surface of an inner plate 22 of the housing, and a first parallel surface configured to slide against an inner surface of an outer plate 24 of the housing. It has two faces 30 , and a peripheral cylindrical face 32 away from the liner 26 .

The rotor 20 has a plurality of slots 34 extending radially from an outer opening 36 in the peripheral face 32 to an inner end 38 closer to the axis X1 . Within each slot 34 there are blades ( 40) is slidably disposed. Each blade 40 is pushed outwardly by a spring 46 compressed between the inner end 38 of the slot and the inner end 42 of the blade, the outer end 44 of the blade being the liner of the housing. It is pressed against the 26 and slides against the liner 26 in use. The main axis X1 and the liner axis X2 are offset and the configuration of the rotor within the housing is between the peripheral face 32 of the rotor, the liner 26 of the housing and the outer end 44 of the blades, such that in use the rotor rotates. A plurality of arcuate chambers (C) that periodically change between a large volume and a small volume are formed.

The blade pump 12 further comprises an inlet 48 and an outlet 50, both provided in the inner plate 2 of the housing, the inlet 48 opening into a first chamber C1 of increasing volume. and the outlet 50 is opened into the second chamber C2 whose volume is reduced. The offset between the main axis X1 and the liner axis X2 is set such that the top of the rotor 20 is nearly tangential to the liner, so that the chamber at the top has a volume of near zero while the volume of the chamber at the bottom is maximum. do.

In use, fuel fills the first chamber C1 , and as the rotor 20 rotates about the main shaft X1 , the fuel is moved toward the outlet 50 and compressed. The fuel discharged through the outlet 50 is delivered to the high pressure pump 14 . Further, as shown in FIG. 4 and enlarged in FIG. 6 , each blade 40 has a double tip edge 52 , 54 and an inner channel 56 , wherein the inner channel 56 is formed by a spring in which the channel is spring-loaded. radially extending between an inner end (42) of the blade opening into a compartment and an outer end (44) of the blade opening between the two tip edges (52, 53), wherein the channel (52) opens between the two tip edges (52, 53); Each of the tip edges 52 , 53 slides against the liner 26 . In use, the blades 40 periodically slide in and out of each slot 34 , and fuel flows through the channels 56 to avoid pressure drops and pressure spikes in the inner end 38 of the slots.

The inlet 48 and outlet 50, as seen in the rear view of FIG. 4 , have an angular width of approximately 90° in selected exemplary embodiments of a blade pump having four blades at 90° to each other. It is an elongate, arcuate opening arranged diametrically opposite to each other to contain The rotor 20 rotates clockwise in FIG. 4 , with the narrowing tail of the first chamber C1 visible through the inlet 48 , while the narrowing head of the second chamber C2 passes through the outlet 50 . looks through

The blade pump 12 further has a second inlet 58 disposed radially and inwardly parallel to the first inlet 48 . In the embodiment provided, the second inlet 58 has an elongated arcuate shape and an angular width W58 of 90°. In other embodiments, the second inlet 58 may be a simple hole. The radial distance between the first inlet 48 and the second inlet 58 is substantially the length of the slot 34 , so that as the first inlet 48 fills the first chamber C1 , the second inlet ( 58 , the second inlet 58 fills directly into the spring compartment at the inner end 38 of the slot bypassing the channel 56 .

The rotor 20 of the blade pump also extends from a large inlet 62 opening into the inner end 38 of each slot towards a closed pointed end 64 digging into the first face 28 of the rotor. and an arcuate groove (60). As seen in the 3D view of FIG. 7 , the groove 60 extends on an arc approximately slightly shorter than 80° at a substantially constant radial distance from the major axis X1 and narrows as it approaches the pointed end 64 . has a losing shape. 4 and 5 , the groove 60 passes through the front of the second inlet 58 , and when the slot 34 emerges from the openings of the first inlet 48 and the second inlet 58 , , groove 60 continuously faces the second inlet 58 to keep fluid communication open from the second inlet 58 to the inner end 38 of the slot. When combining the angular width W58 of the second inlet 58 and the angular width W60 of the groove 60, the inner end 38 of the groove is extended for an extended period of time approximately corresponding to a rotation of the rotor of about 170°. Maintain fluid communication with the inlet during operation. In the general case of a pump with N blades spread every 360°/N, the angular width W58 of the second inlet opening 58 has approximately said angle 360°/N, and the angular width W60 of the groove 60 ) is slightly shorter than the angle 360°/N. Instead of a narrowing shape, other embodiments are possible for the groove 60 which may have a constant width. Also in the figure, the groove 60 follows the slot 34 , which means that in use the slot 34 first passes through the entrance front, followed by the groove 60 .

X1: spindle
S: interior space
C: chamber
C1: first chamber - inlet chamber
C2: second chamber - outlet chamber
W58: Angular width of inlet
W60: Angular width of the groove
10: fuel pump assembly
12: transfer pump - blade pump
14: high pressure pump
16: cam box
18: camshaft
20: rotor
22: inner plate of the housing
24: outer plate of the housing
26: liner
28: first side of the rotor
30: second side of the rotor
32: the peripheral surface of the rotor
34: slot
36: outer opening
38: inner end
40: blade
42: inner end of the blade
44: outer end of the blade
46: spring
48: entrance
50: exit
52: tip edge
54: tip edge
56: blade inner channel
58: second entrance
60: groove
62: big entrance of the groove
64: pointed end of the groove - closed end

Claims (8)

A vane pump (12) having a housing having an inner plate (22), an outer plate (24) and a perimeter liner (26), wherein the perimeter liner (26) has a rotor (20) about a main axis (X1). A rotating inner space (S) is formed, wherein the rotor (20) has a first surface (28) sliding relative to the inner plate (22) and a second surface (30) sliding relative to the outer plate (24). and a peripheral cylindrical surface 32 , wherein the rotor 20 has a plurality of slots 34 opening into the peripheral surface 32 , in which the blade 40 slides. operably disposed, a spring 46 is compressed at the lower or inner end 38 of the slot against the inner end 42 of the blade to urge the blade 40 outwardly, so that the blade engages the slot. (34) projecting outwardly, and the outer end 44 of the blade slides against the liner 26 of the housing, whereby the peripheral face 32 of the rotor, the liner 26 and the outer end of the blade (44) form a plurality of arcuate chambers (C, C1, C2) between, the volumes of the chambers (C, C1, C2) periodically change large and small as the rotor 20 rotates,
The vane pump 12 further has an inlet 48 opening into the large volume chamber C1 and an outlet 50 opening into the small volume chamber C2, so that when in use, the vane pump 12 flows into the inlet 48 The large volume of fluid fills and is compressed and pushed towards the outlet (50);
The vane pump 12 further has a second inlet 58 that opens into the inner end 38 of the slot so that, in use, the fluid flows through the first inlet 48 into the chamber C1 and flow through the second inlet (58) into the volume in which the spring is compressed;
The rotor 20 further has a groove 60 recessed into a first side 28, each groove 60 open at an inlet end 62 in an inner end 38 of the slot and a closed end ( extending into the first side towards 64 , while in use the inner end 38 is no longer facing the second inlet 58 , fluid entering through the second inlet 58 is flows into the groove (60) towards the inner end (38) of the slot,
The groove 60 extends over an angular width W60 such that upon operation of the pump 12, the inner end 38 of the slot fills for an extended period of time.
characterized by,
vane pump.
According to claim 1,
the second inlet (58) extends over an angular width (W) such that in use the inner end (38) of the slot is filled over the extended angle of rotation of the rotor;
vane pump.
3. The method of claim 2,
wherein the angular width is substantially 2/3 of the angle between two consecutive slots;
vane pump.
4. The method according to any one of claims 1 to 3,
the second inlet 58 has an arcuate shape;
vane pump.
delete According to claim 1,
the angular width W60 of the groove is substantially 2/3 of the angle between two consecutive slots 34;
vane pump.
4. The method according to any one of claims 1 to 3,
Each blade (40) has two sealing tip edges (52, 54) sliding against the liner (26) and an outer end (44) having a fluid communication channel (56), the fluid communication channel ( 56 is the tip edge of the channel 56 from the inner end 42 where the channel 56 opens into the inner end 38 of the slot where the spring 46 is compressed through the blade 40 . extending to an outer end 44 that opens between (52, 54);
vane pump.
A fuel pump assembly (10) disposed within a fuel injection equipment, comprising:
The fuel pump assembly (10) comprises a feed pump (12) for drawing fuel from the low pressure tank and delivering it to a high pressure pump (14), the feed pump according to any one of the preceding claims. which is a vane pump (12);
fuel pump assembly.

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