AT500423B1 - RADIAL PUMP - Google Patents

Abstract

The radial pump, especially a cooling medium pump for an internal combustion engine has at least one first group (5) of impeller blades (6) pivotable around axes (9) parallel to the impeller axis. The group of pivotable impeller blades is located in the region of the flow outlet (22). The group of pivotable impeller blades are automatically pivotable in dependence upon the rotational speed. The pivotable blades are pivot-mounted in the region of the flow outlet side ends of fixed impeller blades (4).

Description

2 AT 500 423 B1

The invention relates to a radial pump, in particular coolant pump for an internal combustion engine, with at least a first group of rotatable about axes parallel to the impeller axis blades, wherein the group of pivotable blades is arranged in the region of the flow outlet of the impeller, the group of pivotable run-5 paddle a group with the impeller rigidly connected rigid blades is preceded.

When cooling internal combustion engines mainly engine speed-dependent radial pumps are used. In the case of coolant pumps of larger vehicle internal combustion engines, it is often necessary to deliver a considerable flow rate at low speeds. But this is associated with a very large flow rate at maximum speed, which in turn leads to unacceptably high pressures in the coolant circuit. Short circuits to reduce the quantities flowing through the engine circuit must be made with large cross-sections and are always associated with power dissipation. On the other hand, when designed for maximum speed, there is a risk that the pressure rise in idle will not be sufficient to maintain sufficient cooling.

From EP 1 310 678 A1 a radial pump with impeller blades elastically deformable by Coriolis forces of the coolant flow is known, wherein the exit angle defined between blades and an impeller tangential plane decreases with increasing rotational speed. The 20 blades are either made of an elastically yielding material or are each hinged about an axis per blade and articulated against the force of return springs, with simultaneous adjustment of the blades is ensured by a synchronizer ring. However, moving blades made of elastic material have the disadvantage that vibrations can lead to material fatigue and thus to premature failure.

The US 2,946,288 A describes a centrifugal pump with a constant speed rotating impeller with sliding blades, all blades are the same and experience not only a rotational, but also a translational motion. The adjustment is made by a pressure-controlled, separate mechanism from the outside. The blades are connected by bolts to a control disc, which can be adjusted via a twisting mechanism relative to the pump rotation. By adjusting the blades, the characteristic of the radial pump can be moved depending on the adjustment of the adjustment to set a desired operating point can. A disadvantage 35 is that a considerable effort is required for the external control.

GB 1 159 371 A discloses a centrifugal pump impeller with rotatably mounted blades, which adjust themselves according to the flow conditions, whereby shock losses at the blade tips are to be avoided. Furthermore, radial pumps are known with pivoting barrel-40 blades from the publications US 3,033,015 A, US 3,510,229 A and EP 0 166 104 A1, wherein the blades fold when changing the direction of rotation. DE 1 119 671 B shows a wastewater centrifugal pump with flexible channel folding belt, which releases a larger channel when coarser body passes and then moves back to the starting position. A synchronizer for simultaneous movement of all run-45 blades is not provided.

Radial pumps with pivotable blades, which are upstream of the impeller rigidly connected rigid blades are known from the publications US 3,090,543, DE 14 03 504 A and DE 296 06 296 U1. From none of these documents, however, it appears that the so-rotating blades are automatically pivotable in response to the speed.

EP 1 310 678 A1 has already been extensively explained in the application description. Depending on Coriolis forces, the entire rotor blades are elastically deformed or deflected. A small deformation or deflection already has a relatively large impact on the flow rate and the efficiency. Therefore, this design is very sensitive to tolerances, 3 AT 500 423 B1 which requires high production requirements. Since the subject of the present application, only a relatively small portion of the blades is designed to be pivotable, the tolerance sensitivity is much lower. 5 object of the invention is to increase the efficiency of a radial pump in the simplest possible way.

According to the invention this is achieved in that the group of pivotable blades are automatically pivotable in response to the speed. 10

The blades are thus not adjustable in their entirety, but only the rotatably mounted ends of the blades. These have the greatest influence on the characteristic curve position in the map, specifically on the pressure reduction in the upper rpm range. An adjustment of the inlet areas of the blades is not required and not desired, the 15 rigid blades can thus be designed for optimal conditions.

Flow separation and turbulence are avoided when the pivotable blades are articulated in the exit area of the rigid blades. 20 In order to enable a simultaneous blade adjustment, it is provided that the pivoting blades are simultaneously adjustable by a synchronizing ring.

In a particularly preferred embodiment of the invention, it is provided that the pivotable blades are elastically displaceable by Coriolis forces of the coolant flow, wherein preferably defined between the pivotable blades and Laufradtangentialebenen exit angle decrease with increasing speed. The blade adjustment is thus carried out not dependent on the outside of certain variables, but automatically as a function of the pump speed, and it is particularly advantageous if the blades are loaded by at least one spring element in the direction of a maximum exit angle defi-30 nierenden basic position. At low speeds, there is thus no or only a slight adjustment, whereas the adjustment increases more and more up to the maximum speed. Due to the reset mechanism, the adjustment automatically reduces again when the forces are reduced again by reducing the speed. 35 The adjustment of the vanes results in a shift in the efficiency and performance curves over the entire speed range. The power loss generated with rigid design of the wings in the upper speed range is significantly reduced by means of the combination of rigid and pivotable blades. 40 The blades may be at least partially made of sheet steel or plastic.

The invention will be explained in more detail below with reference to FIGS.

1 shows an impeller of a radial pump according to the invention, FIG. 2 shows the front side of the main body of the impeller with the rigid blades, FIG. 3 shows the rear side of the main body of the impeller, FIG. 4 shows a synchronizer ring of the impeller, FIG. 5 shows a pivotable blade in an oblique view and Fig. 6 shows a pump map.

The impeller 1 consists of a base body 2 with a group 3 of stationary blades 50 and a group of pivotable rotor blades 6. The pivotable blades 6 are in the region of the flow outlet 22 of the impeller 1, specifically in the region of the outlet ends 8 The rigid blades 4 via trunnions 10, 11 in holes 12 of the body 2 and a dashed line in Fig. 1 indicated cover 7 rotatably mounted about axes 9 parallel to impeller axis 1a, wherein the pivotable running blades 6 between the base body 3 and the cover 7th are arranged.

Claims (6)

In order to synchronize all pivotable blades 6, each pivotable blade 6 has an engagement pin 13 for a synchronizing ring 14, wherein the synchronizing ring 14 is guided over sliding surfaces 17 on running surfaces 15 of the cover disc 7. With reference numeral 16 recesses in the base body 2 are designated for receiving return springs 18, wel-5 che on projections 19 of the synchronizing ring 14 attack. The engagement pins 13 are guided in slots 20, 21 of the base body 2 and the synchronizing ring 14. At low speeds, the pressures on the pivotable blades 6 are low, the flow rate Q and the pressure difference Δρ are unchanged from a one-piece guided impeller with rigid blades. As is apparent from Fig. 1, take the pivoting blades 6 their maximum circulation diameter, with the exit angle a, adjusts, which is measured between the pivotable blades 6 and a tangent plane ε. At high speeds, the Coriolis forces of the coolant flow cause a deflection of the pivotable blades 6 against the return springs 18 located in the recess 16 between 15 base 2 and synchronizer ring 14 in the direction of smaller exit angles a2. This causes a lowering of the pressure difference Δρ. Although the centrifugal forces counteract the reduction of the exit angles a1f a2, with a suitable design of the return springs 18, the desired effect arises. The fact that no throttling is required at higher speeds, eliminating the throttle losses. 20 Fig. 6 shows a pump characteristic diagram for the radial pump, wherein in each case the pressure difference Δρ is plotted against the flow Q. I and II are the engine throttle curves of a conventional radial pump with rigid impeller blades. The dashed line III, however, shows an engine slip curve of the described radial pump with a group 3 of rigid blades 4 and a group 5 of pivoting blades 6. It is clearly seen that for the curve III at low speeds, a sufficiently high pressure difference Δρ to maintain the cooling capacity is ensured, and that on the other hand at high engine speeds inadmissible high pressures in the coolant circuit can be avoided. Radial pump, in particular coolant pump for an internal combustion engine, with at least a first group (5) of about 35 axes (9) parallel to the impeller axis (1a) pivotable 35 blades (6), wherein the group (5) of pivoting blades ( 6) in the region of the flow outlet (22) of the impeller (1) is arranged, wherein the group (5) of pivotable blades (6) is preceded by a group (3) with the impeller (1) rigidly connected rigid blades (4), characterized in that the group (5) of pivotable blades (6) are automatically pivotable in dependence on the speed. 40 2. Radial pump according to claim 1, characterized in that the pivotable blades (6) in the region of the flow outlet-side ends (8) of the rigid rotor blades (4) are articulated. 3. Radial pump according to claim 1 or 2, characterized in that the pivotable blades (6) at the same time by a synchronizing ring (14) are adjustable. 4. Radial pump according to one of claims 1 to 3, characterized in that the pivotable blades (6) are elastically adjustable by Corioliskräfte the coolant flow verso, preferably between the pivotable blades (6) and running radtangentialebenen (ε) defined exit angle (a1t a2 ) decrease with increasing speed. 5. Radial pump according to claim 4, characterized in that the pivotable running blades (6) by at least one spring element (18) in the direction of a maximum 5 AT 500 423 B1 exit angle (öi) defining basic position are loaded. 6. Radial pump according to one of claims 1 to 5, characterized in that the moving blades (4, 6) at least partially made of sheet steel or plastic. For this purpose 3 sheets of drawings 10 15 20 25 30 35 40 45 50 55