DE10255271C1 - Rotor pump with variable flow volume adjusted via rotatable setting ring altering relative positions of inner and outer rotors relative to suction and pressure connections - Google Patents

Abstract

The pump (10) has a pump housing (20) provided with a suction connection (44) and a pressure connection (46), containing an outer rotor (30) with a toothed inner periphery and an eccentric inner rotor (28) with a toothed outer periphery, driven by a drive shaft (26), provided with a coaxial setting ring (22) supporting the outer rotor. The latter has bypass grooves (50) connecting the feed space (42) between the teeth of the inner and outer rotors with the pressure connection.

Description

The invention relates to a variable-volume rotor pump, with a suction connection and a pressure connection having pump housing, one rotatable inside the housing stored, internally toothed outer rotor and one in this eccentrically mounted, externally toothed inner rotor, which by one in the pump housing, axially parallel to the outer rotor Drive shaft is drivable, whereby to change the Volume flow in the pump housing a coaxial to the drive shaft mounted, rotatable collar is provided in which the Outer rotor is mounted eccentrically and rotatably.  

Rotor pumps, in which the theoretical delivery volume is changeable along the center of the outer rotor a circle is shifted by the outer rotor in an in Pump housing rotatably mounted on the drive shaft Collar is mounted eccentrically and rotatably, and thereby the relative position of both rotors to the suction and pressure conclusions can be changed accordingly, are from DE 102 07 348 A1 known.

The torque to be applied for the rotor pump is calculated from the equation

M _d = (V _theor. Δp) / (k η _hm ),

in which:
M _d = torque
V _theor = theoretical volume flow
Δp = pressure difference between suction connection and pressure connection
k = constant
η _hm = hydraulic-mechanical efficiency

It has been shown that when the Volume flow, which is caused by a rotation of the adjusting ring  takes place, the required drive torque for the Rotor pump not changed or hardly changed.

The invention has for its object a rotor pump to provide the type mentioned at the beginning, in which the Drive torque decreases when the volume flow is reduced.

This task is the rotor pump of the aforementioned Art solved according to the invention in that the outer rotor with Bypassnuten is provided, which between the teeth of the Inner rotor and the outer rotor formed with the Pressure connection connects.

This construction has the main advantage that the required drive torque proportional to the delivered Volume flow is. This can be explained as follows. Is at a rotor pump according to the prior art (DE 102 07 348 A1) the collar in the direction of a reduced volume flow, then the outer rotor so adjusted in its eccentric bearing that the Delivery chamber between two teeth of the inner ring and the Inner surface of the outer ring is formed over a very narrow flow cross section in the pressure port opens. about this narrow cross-section can be in the delivery room located fluid does not flow out as quickly as it does over the Rotor pump or the inner rotor is promoted. Although one promoted lower volume, but increases the pressure in the  Delivery space due to the very narrow flow cross-section considerable, for which the corresponding torque is required. This increased pressure in the delivery chamber slightly increases the Pressure in the pressure connection, d. H. at the outlet of the rotor pump but neither required nor desired. It also expands thereby the outer diameter of the outer rotor, so that this is pressed more strongly into its bearing seat, whereby the hydraulic-mechanical efficiency is reduced.

In the rotor pump according to the invention, the narrowed cross-section from the delivery chamber to the pressure connection caused pressure increase in the delivery chamber that the fluid degraded the narrowed cross-section bypass the bypass groove and flow into the pressure connection can. Rather, due to the bypass groove in the delivery chamber Avoid rising pressure from the start.

As a result, the pressure in the pressure connection and thus the Δp not increased. Since there is no pressure increase in the delivery chamber, the diameter of the outer rotor is also not increased, which is why the hydraulic-mechanical efficiency too not worsened. It follows that the drive rotation torque is proportional to the volume flow delivered.

In a further development it is provided that the bypass groove is then fluidly connected to the pressure connection when the corresponding tooth of the inner rotor from the inner surface of the External rotor lifts off and the delivery chamber towards the pressure connection  opens. This ensures that the desired pressure, which must be present at the pressure connection, is built up.

The maximum possible funding volume and the maximum to be able to provide possible pressure is provided that the bypass groove only when the outer rotor is in a position for reduced volume flow communicates with the pressure connection.

A discontinuous change in the pressure in the delivery chamber and in the pressure connection and thus the drive torque thereby avoiding the opening cross section of the bypass groove in the direction of the pressure connection with decreasing Volume flow increases.

Further advantages and details of the invention emerge from the subclaims and the following description, in the particularly preferred with reference to the drawing Embodiments are described in detail.

The drawing shows:  

Fig. 1 is a cross sectional view of a variable volume flow pump rotor in a position at maximum flow;

2 shows a cross section of a variable volume flow pump rotor in a position with minimal flow rate, wherein the inner rotor from a to g is rotated counterclockwise.

Fig. 3 shows a longitudinal section III-III of Fig. 2a; and

Fig. 4 shows a section IV-IV through the bypass groove according to Fig. 2d.

The rotor pump, designated overall by 10, has a pump housing 20 in which an adjusting ring 22 is rotatably and fixably mounted on a drive point 26 . An outer rotor 30 meshing with an inner rotor 28 is rotatably and eccentrically mounted in the adjusting ring 22 . The adjusting ring 22 carries on the outer circumference two diametrically assigned and radially projecting flat pistons 66 and 68 , each of which is adjustable along a circular segment-shaped piston guide 70 or 72 formed on the pump housing 20 .

A conveying space 42 is formed between two teeth 32 and 34 of the inner rotor 28 and the inner peripheral surface 36 between two teeth 38 and 40 of the outer rotor 30 , in which the fluid sucked in via a suction connection 44 is conveyed and pressurized. As soon as a connection between the delivery chamber 42 and a pressure connection 46 is established at 46, the fluid located in the delivery chamber 42 is displaced into the pressure connection 46 .

The position of the adjusting ring 22 is shown in FIG. 1, in which the greatest delivery rate (V _theormax ) of the rotor pump 10 is given. FIGS. 2a to 2g shows the position of the adjusting ring 22, wherein V _theormin.

If the rotor pump 10 is in a position for a reduced volume flow, the overflow cross section at 48 is very narrow. As soon as the delivery chamber 42 is connected to the pressure connection 46 via the overflow cross section 48 , the delivery chamber 42 and the pressure connection 46 also communicate via a bypass groove 50 , which is provided in the outer rotor 30 . Fluid can flow into the pressure connection 46 via this bypass groove 50 , as a result of which an undesirable pressure increase in the delivery space 42 is avoided. The bypass groove 50 is arranged in the outer rotor 30 such that it is connected to the pressure connection 46 when the delivery space 42 is being connected to the pressure connection 46 via the overflow cross section 48 .

In FIGS. 2a to 2g, the inner rotor is shown in various rotational positions 28 in which the in the pumping chamber 42, exploiting Dende fluid is gradually displaced into the pressure port 46. It can be seen here that the overflow cross section 48 increases only slightly, but the overlap 52 of the bypass groove 50 with the pressure connection 46 increases more.

A bypass groove 50 is advantageously located on both end faces of the outer rotor 30 , so that a balanced distribution of forces prevails. This can be seen from FIG. 4, which can also be seen that the opening cross section of the bypass groove 50 decreases in the direction of the pressure connection 46 .

Claims (4)

1.Variable-volume rotor pump ( 10 ), with a pump housing ( 20 ) having a suction connection ( 44 ) and a pressure connection ( 46 ), an internally toothed outer rotor ( 30 ) rotatably mounted inside the housing and an externally toothed inner rotor ( 28 ) mounted therein. which can be driven by a drive shaft ( 26 ) mounted in the pump housing ( 20 ) axially parallel to the outer rotor ( 30 ), a rotatable adjusting ring ( 22 ) mounted coaxially to the drive shaft ( 26 ) being provided to change the volume flow in the pump housing ( 20 ), in which the outer rotor ( 30 ) is mounted eccentrically and rotatably, characterized in that the outer rotor ( 30 ) is provided with bypass grooves ( 50 ) which between the teeth ( 32 , 34 , 38 , 40 ) of the inner rotor ( 28 ) and Connect the delivery chamber ( 42 ) of the outer rotor ( 30 ) to the pressure connection ( 46 ). 2. Rotor pump according to claim 1, characterized in that the bypass groove ( 50 ) is then fluidly connected to the pressure connection ( 46 ) when the corresponding tooth ( 34 ) of the inner rotor ( 28 ) lifts off the inner surface ( 36 ) of the outer rotor ( 30 ) and opens the delivery chamber ( 42 ) to the pressure connection ( 46 ). 3. Rotor pump according to one of the preceding claims, characterized in that the bypass groove ( 50 ) only communicates with the pressure connection ( 46 ) for a reduced volume flow when the outer rotor ( 30 ) is in a position. 4. Rotor pump according to claim 3, characterized in that the opening cross section of the bypass groove ( 50 ) increases in the direction of the pressure connection ( 46 ) with a decreasing volume flow.