DE102010050605A1 - Device for controlling a coolant flow and cooling system - Google Patents

Abstract

The invention relates to a device (1) for regulating a coolant flow in a cooling system of an internal combustion engine (2) with a valve arrangement (3) which has a rotary slide valve (4) for switching at least one cooling circuit (5, 6) and / or a bypass circuit (7 ), as well as a coolant pump (8) designed as an impeller pump, which is connected to the valve arrangement (3) on the suction side. According to the invention, the coolant pump (8) has an internal between two end stops (9, 10) axially adjustable guide plate (11) for closing and exposing a pump outlet (12), the guide plate (11) for axial adjustment indirectly via a movement thread (13) a drive shaft (14) of the rotary valve (4) can be coupled. The invention also relates to a cooling system for an internal combustion engine (2) with such a device (1).

Description

Field of the invention

The invention relates to a device for controlling a coolant flow in a cooling system of an internal combustion engine with the features of the preamble of claim 1. Furthermore, the invention relates to a cooling system with such a device.

Internal combustion engines are largely water cooled today. For this purpose, cooling water is pumped by means of a coolant pump or a cooling water pump in a closed circuit through cooling channels in the region of the cylinder for cooling the internal combustion engine and then transported to an air-water cooler, where the heated water is cooled down again by means of the airstream. The pump required to circulate the water is preferably driven by the internal combustion engine. For this purpose, the pump is usually connected via a belt with a pulley of the crankshaft of the internal combustion engine.

The direct coupling between the coolant pump and crankshaft ensures a dependency of the rotational speed of the pump on the rotational speed of the internal combustion engine. This has the consequence that in the high speed range of the internal combustion engine, a correspondingly large volume flow is provided by the pump, which is not needed to this extent for cooling. When cold starting the internal combustion engine, however, the problem occurs that already circulating through the cooling channels coolant obstructs the heating of the combustion chambers and thus delays the achievement of an optimal operating temperature.

In order to avoid the above-mentioned problems controllable coolant pumps are used in modern internal combustion engines, the subsidized volume flow can be tailored to the respective needs.

In addition, coolant pumps are known from the prior art, which are connected on the suction side with a valve arrangement. The valve arrangement makes it possible to switch various sub-circuits of a cooling system, for example a cooling circuit and a bypass circuit, in order in this way to arrive at an optimum coolant temperature.

State of the art

From the DE 10 2008 007 766 A1 For example, a device for cooling an internal combustion engine emerges, which comprises a coolant circuit having coolant subcircuits and an electromechanical assembly with a rotary valve for the separate switching of the separate coolant subcircuits. The device should allow a fully variable control of the coolant temperature, in particular the cooling water temperature, as well as a heating and cooling of transmission oil. Furthermore, the device comprises a switchable coolant pump, in particular cooling water pump, for controlling a coolant volume flow. The coolant pump is switchable such that during the warm-up phase of the internal combustion engine, the coolant in the cooling circuit can be brought to a standstill. For this purpose, the switchable coolant pump cooperates with a pot arranged on the rotary valve. In a cold start of the internal combustion engine, the pot is located above an impeller of the coolant pump and provides for standing coolant respectively cooling water in the internal combustion engine and thus for a shorter warm-up phase of the same. If the rotary valve at the beginning rotated by a certain angle of rotation, so there is an axial movement of a pressure piece on a trapezoidal thread. Then, a spring forces the pot away from the impeller of the pump so that the pump is now able to deliver coolant. If the pressure piece continues to move away from the pot in the axial direction due to a continued rotary movement of the rotary valve, the rotary valve can be further rotated without this having any effect on the pot.

Based on the above-mentioned prior art, the present invention seeks to provide a device for controlling a coolant flow, which is particularly compact. At the same time the device should ensure precise control of a coolant flow and allow the setting of a zero flow rate.

The object is achieved by a device for controlling a coolant flow with the features of claim 1 and a cooling system with the features of claim 9. Advantageous developments of the invention are specified in the respective subclaims.

Disclosure of the invention

The proposed device for controlling a coolant flow in a cooling system of an internal combustion engine comprises a valve arrangement with a rotary valve for switching at least one cooling circuit and / or a bypass circuit and designed as an impeller pump coolant pump, which is connected on the suction side with the valve assembly. According to the invention the coolant pump has an inner between two end stops axially adjustable baffle for closing and releasing a pump outlet, wherein the baffle for axial adjustment indirectly via a movement thread with a drive shaft of the rotary valve can be coupled.

Characterized in that the axially adjustable baffle is an integral part of the coolant pump, the device according to the invention is designed particularly compact design. As an integral part of the coolant pump, the baffle is also protected against damage, so that the functionality of the baffle and thus controllability of the coolant pump is ensured as long as possible. The formation of end stops, between which the baffle is axially adjustable, also specifies a well-defined control range. When planting the baffle at a first end stop, the coolant pump is preferably completely closed and fully opened when the baffle at the second end stop.

Although the baffle is an integral part of the coolant pump, that is arranged within the pump, the baffle is coupled to the drive shaft of the suction side arranged rotary valve. Thus, the drive of the rotary valve, preferably an electric motor, can be used as a common drive. The coupling takes place via a movement thread, which converts the rotational movement of the drive shaft of the rotary valve in a translational movement for the axial adjustment of the baffle. Preferably, the coupling is designed such that actuation of the rotary valve does not necessarily cause an axial adjustment of the baffle. This means that a coupling of the baffle with the drive shaft of the rotary valve is possibly given only temporarily. In order to make the coupling of the coolant pump with the drive shaft of the rotary valve particularly compact and simple, the drive shaft is preferably arranged coaxially to the bearing shaft of the coolant pump.

According to a preferred embodiment of the invention, the baffle has a contour adapted to an impeller of the coolant pump contour with an outer peripheral side formed collar for closing and releasing the pump outlet. The adapted contour supports the interaction between impeller and baffle. For example, the impeller can form at least one end stop. Preferably, both the control range of the coolant pump predetermining end stops are formed by the impeller. For this purpose, the impeller may comprise an axially spaced cover plate, which forms a first end stop. The second end stop is then formed by the actual impeller. The axial distance between impeller and cover plate then gives the control range of the coolant pump. In order to ensure the axial distance, the impeller and the cover plate can be connected to each other via at least one Axialsteg. The axial web is guided through the baffle, so that this undergoes a guide in an axial adjustment through the axial web. The collar formed on the guide plate is preferably oriented in the direction of the impeller, in order to counteract a vortex formation, in particular during partial conveying operation of the coolant pump.

According to a further preferred embodiment of the invention, the guide plate has a pin-like projection, with which the guide plate is axially guided in a bore of a bearing shaft of the coolant pump. The axial guidance can be provided as an alternative or in addition to the guide via an axial web of the impeller. The bore in the bearing shaft of the coolant pump can be designed for this purpose as a blind hole. Furthermore, means for the rotationally secure mounting of the baffle with respect to the bearing shaft or with the bearing shaft rotatably connected impeller may be provided on the pin-like projection of the baffle and / or within the bore of the bearing shaft. An anti-rotation can also be effected via the at least one axial web.

The movement thread provided for coupling the guide plate to the drive shaft of the rotary valve comprises a trapezoidal thread and a threaded sleeve secured against rotation and engaging with the trapezoidal thread. Preferably, the threaded sleeve has at least one outer peripheral side flattening for supporting on a bore wall of a receiving bore to prevent rotation. The threaded sleeve can also be formed as a hexagon and inserted in a bore with a corresponding cross-section. However, the bearing of the threaded sleeve must be such that it remains axially displaceable. Because the axial displaceability of the threaded sleeve is a prerequisite for the rotational movement of the drive shaft of the rotary valve is converted via the movement thread in a translational movement. About the threaded sleeve, the baffle is also at least indirectly acted upon by an effective pressure force in the axial direction and / or tensile force. That is, the axial adjustment of the baffle can be effected via the threaded sleeve by the baffle threaded sleeve can be effected by the guide plate is pressed against an end stop or pulled towards an end stop. If the coupling between the baffle and the movement thread is designed such that only a compressive force is transferable, the provision of the baffle must be realized in other ways. For example, the Reset be effected by means of at least one return spring.

Advantageously, the pitch of the movement thread on the control path of the rotary valve is adjusted so that when the rotary valve is closed and the coolant pump is closed and / or open the rotary valve and the coolant pump is open. The trapezoidal thread may for example be formed on a pump-side end of the drive shaft of the rotary valve, which is rotatably mounted in a housing part of the valve assembly. The housing part has for this purpose a bearing bore. To the bearing bore, a bore with an enlarged diameter for receiving and rotationally fixed mounting of the threaded sleeve can connect. In addition to the bearing bore and / or the receiving bore, the housing part also has at least one throughflow opening for the coolant.

Advantageously, the axially adjustable baffle is biased axially by means of the spring force of at least one compression spring against an end stop. For axial adjustment of the baffle via the threaded sleeve therefore first the spring force of the compression spring must be overcome. For resetting the baffle, in turn, the spring force of the compression spring can be used. The compression spring can - if present - received in the bore of the bearing shaft of the coolant pump and be supported on the one hand on the bearing shaft, on the other hand on the pin-like approach of the baffle. The provision of the guide plate on the spring force of a compression spring can also serve to realize a fail-safe function, as it is already known from other controllable coolant pumps.

According to a further preferred embodiment of the invention, the baffle has a cup-shaped insert which is axially displaceably mounted in the baffle and biased by the spring force of a compression spring in the axial direction. In contrast to the above-mentioned return spring which is provided for bias further compression spring serves as a compensation spring (lost motion spring). You should allow a discontinuous axial adjustment of the baffle with constant drive of the rotary valve. This means that after reaching an end stop the movement of the threaded sleeve on the axial position of the baffle has no influence. With continued movement of the threaded sleeve, only the pot-like insert is moved relative to the baffle. If the threaded sleeve moves back, the compensation spring holds the cup-shaped insert in contact with the threaded sleeve. Thus, the compensation spring can also serve as a return spring.

For receiving and displaceable mounting of the cup-shaped insert of the pin-like projection of the baffle may be at least partially formed hollow cylindrical. In order to ensure a guidance of the cup-shaped insert, guiding means can also be provided. These may comprise at least one outer peripheral side formed on the cup-shaped insert nose, which is in engagement with a formed in the guide plate or in the peg-shaped projection of the guide plate guide groove. Advantageously, the guide groove is Z-shaped. For one thing, due to the Z-shape in the axial direction effective stops are formed, which prevent falling out of the spring-loaded cup-shaped insert from the baffle. On the other hand, the Z-shape of the guide groove simplifies the installation of the cup-shaped insert. The orientation of the Z-shape depends on the direction of rotation of the pump.

Further preferably, the spring stiffness of the provided for biasing the cup-shaped insert compression spring is selected higher than the spring stiffness of the provided for biasing the baffle pressure spring. This ensures that an axial movement of the threaded sleeve is only compensated by an axial displacement of the cup-shaped insert when the baffle is applied to an end stop, that is, the coolant pump is completely closed or opened.

The compression spring provided for biasing the cup-shaped insert and the compression spring provided for biasing the guide plate are preferably arranged coaxially within the bore of the bearing shaft of the coolant pump. This allows for a compact arrangement of the springs, on the other hand, a uniform distribution of the spring forces on the baffle or the cup-shaped insert.

The claimed for solving the above-mentioned object further cooling system for an internal combustion engine comprises a device according to the invention for controlling a coolant flow and at least one cooling circuit with a radiator and / or a bypass circuit for bypassing the radiator. The cooling circuit and / or the bypass circuit is or can be switched via the rotary valve of the valve arrangement. By switching on or off a cooling circuit and / or a bypass circuit thus the coolant temperature can be varied and an optimal coolant temperature can be adjusted.

According to a preferred development of the cooling system according to the invention, at least one further consumer, for example an engine oil cooler, and / or a thermocouple, for example a heater, is connected to the cooling system. about the rotary valve is then a demand-based distribution of the coolant flows effected.

Preferred embodiments of the invention are explained below with reference to the accompanying drawings. These show:

1 a schematic representation of a cooling system according to the invention,

2 a section through a device according to the invention,

3 - 6 each a section of the 2 in the coupling region of the coolant pump with the drive shaft of the rotary valve, wherein the guide plate occupies a different axial position,

7 a detail from the 2 in the coupling region of the coolant pump with the drive shaft of the rotary valve,

8th a perspective view of the detail of the 7 .

9 a diagram illustrating the control range of the coolant pump in response to the rotational movement of the drive shaft and

10 a further embodiment of a device according to the invention.

Detailed description of the drawings

That in the 1 illustrated example of a cooling system according to the invention comprises a device 1 for controlling a coolant flow, which among other things for cooling an internal combustion engine 2 can be used. To the cooling circuit are also a motor oil cooler 26 as another consumer as well as a heater 27 connected. In addition, optional components can be added 33 connected to the cooling system. In order to enable a demand-based distribution of the coolant flows, the cooling system also has different cooling circuits 5 . 6 and a bypass circuit 7 to bypass a radiator 25 in the cooling circuit 5 on. By the bypass circuit thus an uncooled coolant flow is already provided, which allows the setting of an optimal coolant temperature. For this purpose, coolant from the bypass circuit 7 with coolant from the cooling circuit 5 mixed. The mixing takes place via a valve arrangement 3 which is part of the device according to the invention 1 for controlling the coolant flow. As a further component, the device 1 a coolant pump 8th on the suction side with the valve assembly 3 is connected. The coolant pump 8th is adjustable to the volume flow of the coolant, for example during cold start of the internal combustion engine 2 to be able to reduce to zero. That is, there is no coolant to the internal combustion engine 2 promoted. In this way, the internal combustion engine reaches 2 faster their optimal operating temperature.

The valve arrangement 3 includes for switching the cooling circuits 5 . 6 and the bypass circuit 7 a rotary valve 4 , The required for switching rotary movement of the rotary valve 4 is via a drive shaft 14 an electric motor 28 causes.

Again 2 it can be seen which a section through a device according to the invention 1 shows that is the coolant pump 8th facing end of the drive shaft 14 in a bearing bore 34 a housing part 30 rotatably mounted and with a trapezoidal thread 20 provided with a threaded sleeve 21 interacts. Because of the threaded sleeve 21 in a to the bearing bore 34 subsequent drilling 35 is rotatably mounted but axially displaceable, is on the movement thread 13 comprising the trapezoidal thread 20 and the threaded sleeve 21 the rotational movement of the drive shaft 14 of the rotary valve 4 in a translational movement of the threaded sleeve 21 implemented. Moves the threaded sleeve 21 in the direction of the coolant pump 8th , it passes or on the threaded sleeve 21 attached pot 29 after bridging a gap area in contact with an axially adjustable baffle 11 the coolant pump 8th or a cup-shaped insert 23 of the baffle 11 , In contact with the baffle 11 or the cup-shaped insert 23 can the threaded sleeve 21 at least indirectly over the pot-shaped use 23 a compressive force on the baffle 11 or the cup-shaped insert 23 to transfer, which initially an axial adjustment of the baffle 11 and then an axial displacement relative to the baffle 11 causes (see sequence of 2 to 6 ). The adjustment range of the baffle 11 gets through two end stops 9 . 10 limited by an impeller 15 be formed. Against the first end stop 9 is the baffle 11 by means of the spring force of a compression spring 22 axially biased. To an axial adjustment of the baffle 11 over the threaded sleeve 21 To effect, first, the spring force of the compression spring 22 be overcome. The compression spring 22 serves to return the baffle 11 against the end stop 9 when the threaded sleeve 21 in the direction of the electric motor 28 moved back and no more pressure on the baffle 11 exercises. Also the pot-shaped use 23 is the spring force of a compression spring 24 applied. The compression spring 24 is in a cone-like approach 17 of the baffle 11 recorded, with which the baffle 11 in a hole 18 the bearing shaft 19 the coolant pump 8th is guided.

Also the pot-shaped use 23 is guided in the axial direction. For this purpose, the cup-shaped commitment 23 on the outer circumference several noses 32 on, each in a guide groove 31 in the cone-like approach 17 of the baffle 11 intervene (see 7 ). The guide grooves 31 are Z-shaped (see 8th ), to the insertion of the cup-shaped insert 23 in the peg-like approach 17 to facilitate as well as falling out of the cup-shaped insert 23 to prevent. Because the Z-shaped guide groove 31 at the same time forms a stop for the spring-loaded cup-shaped insert 23 out.

The compression spring 24 whose spring force is the pot-shaped use 23 holds in abutment with the stop, serves in the present case as a compensation spring. For this purpose, the spring stiffness of the compression spring 24 larger than that of the compression spring 22 chosen, the spring force of the baffle 11 against the end stop 9 axially biased. Upon actuation of the rotary valve 4 over the drive shaft 14 Accordingly, initially an axial adjustment of the baffle 11 causes when the threaded sleeve 21 or her pot 29 in contact with the cup-shaped insert 23 of the baffle 11 arrives. Has the baffle 11 the end stop 10 achieved, is about the continued movement of the threaded sleeve 21 an axial displacement of the cup-shaped insert 23 opposite the baffle 11 causes, that is, the movement of the threaded sleeve 21 is about the movement of the cup-shaped insert 23 against the spring force of the compression spring 24 compensated. A correspondingly discontinuous axial adjustment of the baffle 11 with constant drive via the drive shaft 14 is schematic in the diagram of 9 shown. On the x-axis is the continuous drive and on the y-axis, the discontinuous movement of the baffle 11 applied. During a first phase 1 the actuation of the drive shaft 14 lies the threaded sleeve 21 or her pot 29 not yet at the baffle 11 or on the cup-shaped insert 23 of the baffle 11 on (state according to the 2 and the 3 ). Consequently, no axial adjustment of the baffle 11 causes. First, the gap between the threaded sleeve 21 and the baffle 11 be bridged. During a second phase II is the threaded sleeve 21 or the pot 29 on the baffle 11 or the cup-shaped insert 23 on (state according to the 4 and the 5 ). The baffle 11 is over the threaded sleeve 21 against the spring force of the compression spring 22 towards the end stop 10 emotional. With reaching the end stop 10 ends the second phase II. This is followed by the phase III, in which the pot-shaped use 23 the further movement of the threaded sleeve 21 or the drive shaft 14 compensated. The baffle 11 is still at the end stop 10 of the impeller 15 at. The return of the baffle 1 takes place by means of the spring force of the compression spring 22 when the threaded sleeve 21 back in the direction of the electric motor 28 emotional. The control range of the coolant pump 8th is therefore traversed only in phase II. In phases I and III lies the baffle 11 either at the end stop 9 or 10 on, that is, the coolant pump 8th is completely closed or fully open.

For opening and closing the coolant pump 8th has the baffle 11 an outer peripheral side collar 16 by means of which a pump outlet 12 the coolant pump 8th can be opened or closed (see 3 to 6 ). The pump outlet 12 is through at least one peripheral opening of the impeller 15 formed and is preferably with a the impeller 15 surrounding annular channel in connection (not shown).

An alternative embodiment of a device according to the invention 1 for controlling a flow of coolant to be determined by the 10 be explained in more detail. In this embodiment, the compression spring 22 for resetting the baffle 11 dispensable. Because the pot 29 the threaded sleeve 21 Can both compressive forces and tensile forces on the baffle 11 or the cup-shaped insert 23 of the baffle 11 transferred, the present not axially displaceable relative to the baffle 11 is. In that regard, an actuation of the drive shaft 14 of the rotary valve 4 always also to an axial adjustment of the baffle 11 , The slope of the trapezoidal thread 20 is accordingly with the control trajectories of the rotary valve 4 tuned in such a way that with completely closed rotary valve 4 also the coolant pump 8th is completely closed and vice versa.

On a forced guidance of the baffle 11 according to the embodiment of the 10 can also be dispensed with, if it is ensured that during operation of the coolant pump 8th the hydraulic forces the return of the baffle 11 effect in the direction of the suction mouth. According to an alternative embodiment, which incidentally of the 10 Accordingly, it is provided that the pot 29 the threaded sleeve 21 only pressure forces on the baffle 11 or the cup-shaped insert 23 of the baffle 11 transfers.

LIST OF REFERENCE NUMBERS

1

contraption

2

Internal combustion engine

3

valve assembly

4

rotary vane

5

cooling circuit

6

cooling circuit

7

bypass circuit

8th

Coolant pump

9

end stop

10

end stop

11

baffle

12

pump outlet

13

motion thread

14

drive shaft

15

impeller

16

collar

17

peg-like approach

18

drilling

19

bearing shaft

20

trapezoidal thread

21

threaded sleeve

22

compression spring

23

pot-shaped use

24

compression spring

25

cooler

26

Engine oil cooler

27

heater

28

electric motor

29

pot

30

housing part

31

guide

32

nose

33

component

34

bearing bore

35

drilling

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 102008007766 A1 [0006]

Claims (10)

Contraption ( 1 ) for controlling a coolant flow in a cooling system of an internal combustion engine ( 2 ) with a valve arrangement ( 3 ), which has a rotary valve ( 4 ) for switching at least one cooling circuit ( 5 . 6 ) and / or a bypass circuit ( 7 ), and a coolant pump designed as an impeller pump ( 8th ), the suction side with the valve assembly ( 3 ), characterized in that the coolant pump ( 8th ) an inboard between two end stops ( 9 . 10 ) axially adjustable guide plate ( 11 ) for closing and releasing a pump outlet ( 12 ), wherein the baffle ( 11 ) for axial adjustment indirectly via a movement thread ( 13 ) with a drive shaft ( 14 ) of the rotary valve ( 4 ) can be coupled. Apparatus according to claim 1, characterized in that the baffle ( 11 ) one to an impeller ( 15 ) of the coolant pump ( 8th ) adapted contour with an outer peripheral side formed collar ( 16 ) for closing and releasing the pump outlet ( 12 ) owns. Apparatus according to claim 1 or 2, characterized in that the guide plate ( 11 ) a peg-like approach ( 17 ), with which the baffle ( 11 ) in a bore ( 18 ) a bearing shaft ( 19 ) of the coolant pump ( 8th ) is axially guided. Device according to one of the preceding claims, characterized in that the movement thread ( 13 ) a trapezoidal thread ( 20 ) and one in engagement with the trapezoidal thread ( 20 ), secured against rotation threaded sleeve ( 21 ), over which the baffle ( 11 ) is acted upon at least indirectly with an effective in the axial direction of compressive force and / or tensile force. Device according to one of the preceding claims, characterized in that the axially adjustable guide plate ( 11 ) by means of the spring force of at least one compression spring ( 22 ) against an end stop ( 9 . 10 ) is axially biased. Device according to one of the preceding claims, characterized in that the guide plate ( 11 ) a cup-shaped insert ( 23 ), which in the baffle ( 11 ) axially displaceably mounted and by means of the spring force of a compression spring ( 24 ) is biased in the axial direction. Apparatus according to claim 6, characterized in that the spring stiffness of the bias of the cup-shaped insert ( 23 ) provided compression spring ( 24 ) higher than the spring stiffness of the bias of the baffle ( 11 ) provided compression spring ( 22 ) is selected. Apparatus according to claim 6 or 7, characterized in that for the bias of the cup-shaped insert ( 23 ) provided compression spring ( 24 ) and the bias of the baffle ( 11 ) provided compression spring ( 22 ) coaxially within the bore ( 18 ) of the bearing shaft ( 19 ) of the coolant pump ( 4 ) are arranged. Cooling system for an internal combustion engine ( 2 ) with a device ( 1 ) according to one of the preceding claims and at least one cooling circuit ( 5 . 6 ) with a cooler ( 25 ) and / or a bypass circuit ( 7 ) to bypass the radiator ( 25 ), whereby the cooling circuit ( 5 . 6 ) and / or the bypass circuit ( 7 ) via the rotary valve ( 4 ) of the valve assembly ( 3 ) are switchable. Cooling system according to claim 9, characterized in that at least one further consumer, for example an engine oil cooler ( 26 ), and / or a thermocouple, for example a heater ( 27 ) is connected to the cooling system or are and via the rotary valve ( 4 ) a needs-based distribution of the coolant flows is effected.

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