DE102017121198A1 - Coolant pump for a coolant circuit of an internal combustion engine - Google Patents

Abstract

The invention relates to a coolant pump (1) for a coolant circuit of an internal combustion engine, comprising a pump housing (2), an impeller (4) and an axial drive shaft (3) with a drive disk (6), the drive shaft (3) sealingly into the pump housing (2) is guided, in which the impeller (4) in a pump chamber (8) of the pump housing (2) by the drive shaft (3) is rotatably arranged, wherein the impeller (8) has a suction-side, central axial coolant inlet port and a Compression-side radial coolant outlet opening (14) on the pump housing (2). According to the invention, the pump housing (2), in particular in the axial direction, between the drive disk (6) and the pump chamber (8) has a further chamber as inflow chamber (7) with a radial, suction-side coolant inflow opening (12) and with a axial central coolant overflow opening (9) as a coolant inlet opening of the impeller (8), so that both the suction-side coolant inflow opening (12) and the pressure-side coolant outlet opening (14) are arranged radially on a pump housing peripheral wall.

Description

The invention relates to a coolant pump for a coolant circuit of an internal combustion engine according to the preamble of claim 1, an engine coolant circuit with the coolant pump according to claim 11 and a vehicle, in particular a commercial vehicle, with the engine coolant circuit according to claim 12.

To dissipate the heat generated during operation of an internal combustion engine, coolant is pumped by the latter into a coolant circuit by means of a coolant pump arranged in coolant lines. A generally well-known, used in particular for vehicles coolant pump has a pump housing and an impeller and an axial drive shaft with a drive pulley. The drive shaft is tightly guided in the pump housing, wherein in the pump housing, the impeller is rotatably disposed in a pump chamber through the drive shaft. The impeller chamber also has a suction-side, central, axial coolant inlet opening and a pressure-side radial coolant outlet opening on the pump housing.

The drive disc is usually designed as a mechanically driven by a crankshaft of the internal combustion engine pulley, which is directed in front of the front, in particular in internal combustion engines in vehicles. The coolant inlet opening on the pump housing is arranged in a known manner opposite to the drive pulley and aligned in the vehicle to the rear. This conventional known coolant pump design requires by the widely spaced coolant connections, on the one hand to the mating drive side rear coolant inlet port and on the other hand, the radially laterally located coolant outlet port, a complex and space-consuming guidance of the coolant connection lines. In particular, the space requirement at the mating drive side is relatively large, since the coolant with a supply line must be shown at the rear of the pump housing. In addition, especially on the suction side relatively long connecting lines with multiple deflections and consequent unfavorable flow and pressure losses required.

The object of the invention is therefore to propose a coolant pump for a coolant circuit of an internal combustion engine, with which the routing of the coolant circuit in the region of the coolant pump with less space requirement is more cost effective and flow efficient feasible.

This object is achieved with the features of the independent claims. Preferred developments are disclosed in the subclaims.

According to claim 1, a coolant pump for a coolant circuit of an internal combustion engine is proposed, comprising a pump housing, an impeller and an axial drive shaft with a drive disk, wherein the drive shaft is guided tightly into the pump housing, in which the impeller in an impeller chamber of the pump housing by the drive shaft rotatable is arranged, and the impeller has a suction-side, central axial coolant inlet opening and a pressure-side radial coolant outlet opening on the pump housing. According to the invention, in the pump housing, in particular in the drive shaft axial direction, between the drive disk and the impeller chamber, a further chamber is integrated as inflow chamber with a radial suction-side coolant inflow opening and with an axial central coolant overflow opening as the coolant inlet opening of the impeller chamber in that both the suction-side coolant inflow opening and the pressure-side coolant outlet opening are arranged radially on the outside of a pump housing peripheral wall.

Thus, the complex supply of coolant from the counter drive side can be omitted and the suction side coolant supply as well as the coolant discharge can be done in the range of the coolant pump straight with little deflections and relatively short lines. In addition, the space requirement for the coolant pump, in particular at the counter drive side by the elimination of the hitherto attached there coolant supply ports is significantly smaller than before.

The advantage of the coolant pump design according to the invention is therefore essentially in simpler, less expensive cable routing of the connecting lines with improved flow conditions in the coolant circuit and in a total smaller space requirement. The relatively small space requirement is especially advantageous for vehicles, especially for commercial vehicles, because an available installation space is becoming smaller and smaller by an increasingly larger number of engine-side ancillaries.

For a structurally more concrete embodiment, it is proposed that the impeller chamber and the inflow chamber are substantially formed as flat cylindrical, coaxial and juxtaposed cans, which in terms of flow through the central coolant overflow are connected. In this case, a circumferential and, in particular radially inward, open to the coolant overflow opening open annular channel is preferably formed in the inflow. More preferably, the drive shaft is guided through the inflow through the pump impeller into the pump chamber. With such a construction results in a particularly compact and functional coolant pump. To improve the flow, the annular channel of the inflow chamber can also have an inclined surface, directed in particular as a tapered surface, as the coolant guide surface, directed toward the central coolant overflow opening.

Appropriately, the coolant inlet opening and the coolant outlet opening are arranged with their line connections easily accessible side by side.

The drive disk can be a drive pulley with a circumferential profile in the usual way, in particular for a driven by a crankshaft of the engine toothed and / or V-belt. Basically, the drive disk of the drive shaft but also part of a gear train, for example, be designed as a gear and possibly also electrically, hydraulically or pneumatically driven.

In a development of the coolant pump design according to the invention, a viscous coupling, in particular for a speed variation, can be arranged between the drive disk and the drive shaft.

Further preferably, it is provided that the drive shaft projects through the drive pulley and protrudes from the drive pulley with a, in particular free, end region axially opposite to the inflow chamber, and that a rotational speed sensor for measuring the drive shaft rotational speed is assigned to this end region. In this way, the drive shaft speed can be measured easily and effectively.

Preferably, the speed sensor is fixed to the pump housing. More preferably, the speed sensor is sealed by means of a sealing device arranged by the pump chamber in a, a receiving space forming recess of the pump housing or received. Thus, the speed sensor can be easily and reliably arranged on the coolant pump.

Furthermore, an internal combustion engine coolant circuit is claimed with the coolant pump according to the invention. In addition, a vehicle is claimed with the internal combustion engine coolant circuit according to the invention. The resulting advantages are identical to the already appreciated advantages of the coolant pump according to the invention, so that they are not repeated at this point.

Reference to a drawing, the invention is further exemplified.

The single FIGURE shows a cross section through a coolant pump 1 with a pump housing 2 and a drive shaft 3 , on the inside of the pump housing 2 on the one hand an impeller 4 is arranged as an impeller. On the other hand, the drive shaft 3 outside the pump housing 2 via a (schematically illustrated) viscous coupling 5 with a drive pulley 6 coupled. The pump housing 2 contains two chambers, the first (seen from the drive side) an inflow chamber 7 and then second, a pump chamber 8th ,

The inflow chamber 7 and the impeller chamber 8th are formed as flat, cylindrical, coaxial and juxtaposed cans, which through a central coolant overflow 9 are fluidly connected to each other. The central drive shaft is visible via a seal 10 in and through the inflow chamber 7 guided and in the impeller chamber 8th with the impeller 4 connected for a rotary drive. In the cylindrical inflow chamber is a circumferential annular channel 18 formed, the one to a coolant overflow 9 executed oblique surface 11 having as coolant guide surface.

A suction-side coolant inflow opening 12 at the inflow chamber 7 and a pressure-side coolant outlet opening 14 at the impeller chamber 8th lie radially outward on the respective chamber peripheral surface. The coolant line connection elements and coolant lines in the area of the coolant pump 1 are through the arrows 13 and 15 shown schematically.

Furthermore, the drive shaft protrudes through 3 here the drive pulley 6 , such that the drive shaft 3 with a free end area 19 axially opposite to the inflow chamber 7 from the drive pulley 6 protrudes. This free end area 19 the drive shaft 3 Here is also a speed sensor 20 assigned to measure the drive shaft speed. The measured drive shaft speed is used here as an example for the control or regulation of the viscous coupling 5 used.

The speed sensor 20 Here is an example of the pump housing 2 established. In addition, the speed sensor is here sealed by means of a sealing device of the pump chamber 8th in a, a receiving space forming recess 21 of the pump housing 2 arranged.

The illustrated coolant pump 1 has the following function: with driven impeller 4 becomes coolant through the coolant inflow port 12 (Arrow 13 ) in the annulus 18 the inflow chamber 7 sucked and from there through the coolant overflow 9 in the impeller chamber 8th (see flow arrows 16 . 17 ). From there it is via the coolant outlet opening 14 (See arrow 15 ) the coolant in the cooling circuit on. Obviously, here are the coolant inlet opening 12 and the coolant outlet opening 14 axially next to each other, so that connection cables are easy to bring and mount.

In commonly known, common coolant pump designs is the inflow chamber 7 absent and coolant is through a central opening opposite the drive pulley 6 in the impeller chamber 8th promoted. On the other hand, it is obvious with the coolant pump 1 the suction side of the drive pulley 6 facing. Since thus the suction direction is reversed, a pump used in the previously known pump design 4 rotated by 180 ° on the drive shaft.

LIST OF REFERENCE NUMBERS

1

Coolant pump

2

pump housing

3

drive shaft

4

impeller

5

Viscokupplung

6

Drive pulley

7

inflow

8th

impeller chamber

9

Coolant overflow

10

poetry

11

sloping surface

12

Coolant inflow

13

arrow

14

Coolant outlet opening

15

arrow

16

flow arrow

17

flow arrow

18

annular chamber

19

free end area

20

Speed sensor

21

recess

Claims (12)

Coolant pump (1) for a coolant circuit of an internal combustion engine, with a pump housing (2) and an impeller (4) and an axial drive shaft (3) with a drive pulley (6), wherein the drive shaft (3) guided tightly into the pump housing (2) in which the pump impeller (4) is rotatably arranged in an impeller chamber (8) of the pump housing (2) by the drive shaft (3), the impeller chamber (8) having a suction-side, central axial coolant inlet opening and a pressure-side radial coolant Having outlet opening (14) on the pump housing (2), characterized in that the pump housing (2), in particular in the axial direction between the drive disc (6) and the pump chamber (8) has a further chamber as inflow chamber (7) with a radial, suction-side coolant inflow opening (12) and with an axial central coolant overflow opening (9) as a coolant inlet opening of the pump chamber (8), so that sowoh l the suction-side coolant inlet opening (12) and the pressure-side coolant outlet opening (14) are arranged radially on a pump housing peripheral wall. Coolant pump after Claim 1 , characterized in that the impeller chamber (8) and the inflow chamber (7) are substantially formed by flat, cylindrical, coaxial and juxtaposed bushings which are fluidly connected by the central coolant overflow orifice (9). Coolant pump after Claim 2 , characterized in that in the inflow chamber (7) a circumferential and, in particular radially inwardly, to the coolant overflow opening open annular channel (18) is formed. Coolant pump after Claim 3 , characterized in that the annular channel (18) of the inflow chamber (7) has a coolant overflow opening (9) directed towards, in particular tapered, inclined surface (11) as a coolant guide surface. Coolant pump according to one of Claims 1 to 4 , characterized in that the drive shaft (3) through the inflow chamber (7) through the impeller (4) into the pump chamber (8) is guided. Coolant pump according to one of Claims 1 to 5 , characterized in that the coolant inlet opening (12) and the coolant outlet opening (14) with corresponding coolant line connections (13, 15) are arranged radially on the pump housing (2) and in the axial direction next to each other. Coolant pump according to one of Claims 1 to 6 , characterized in that the drive pulley is a Antriebriemenscheibe (6) with a circumferential profile, in particular for a driven by a crankshaft of the internal combustion engine toothed and / or V-belt. Coolant pump according to one of Claims 1 to 7 , characterized in that between the drive pulley (6), in particular between a Antriebriemenscheibe as drive pulley (6), and the drive shaft (3) a Viscocoupplung (5) is arranged. Coolant pump according to one of Claims 1 to 8th , characterized in that the drive shaft protrudes through the drive pulley and protrudes with a, in particular free, end region axially opposite to the inflow chamber of the drive pulley, and that this end region is associated with a speed sensor for measuring the drive shaft speed. Coolant pump after Claim 9 , characterized in that the speed sensor is fixed to the pump housing and / or sealed by a sealing means of the pump chamber in a, a receiving space forming recess of the pump housing is arranged. Internal combustion engine coolant circuit, with a coolant pump according to one of the preceding claims. Vehicle, in particular commercial vehicle, with an internal combustion engine coolant circuit according to Claim 11 ,

Images