DE102014017519A1 - Radiator for a cooling system of an internal combustion engine - Google Patents

Abstract

The invention relates to a radiator for a cooling system of an internal combustion engine, having at least two water boxes (2, 3) connected by coolant-flowed tubes (4) and a coolant inlet (5) to a water box, downstream of the coolant-flowed tubes (4 ) and a refrigerant flow volume operatively flowing therewith is connected to a coolant outlet (6) located at a water box. According to the invention, a control or regulating device which controls or regulates the size of the flow volume of the coolant volume flow flowing through the cooler (1) is arranged in at least one water tank (2, 3).

Description

The invention relates to a cooler for a cooling system of an internal combustion engine according to the preamble of claim 1.

A generic, well-known cooler for a cooling system of an internal combustion engine consists of at least two water boxes, which are connected by coolant flowed through pipes. In this case, a connection for a coolant inlet is arranged on a water tank, which is connected downstream of the coolant flow-through pipes with a arranged on a water tank coolant outlet.

For this purpose, two different arrangements of the coolant inlet and coolant outlet are generally known:

In one arrangement, the coolant inlet is disposed at a first header and the coolant outlet is disposed at a second header connected by a coolant-flowed tube bundle and spaced apart. The flow direction of the coolant here runs in a direction from the first water tank to the second water tank.

In an alternative arrangement, the coolant inlet is arranged on a first subregion of a first water channel and the coolant outlet is arranged on a second subregion of the same, first water channel which is separate therefrom. Each subregion is here connected to an associated first and second tube bundle with a second water box, in which a flow deflection takes place. The flow direction thus runs here from the coolant inlet at the first water tank to the second water tank, is deflected there and runs back to the coolant outlet at the first water tank.

In the conventional vehicle coolers described above, influencing the flow volume is not provided.

The resulting flow distribution depends on the parameters such as volume flow, media density, temperatures, pressure, flow gradients and coolant inlet or outlet. The resulting flow distribution in the interior of the cooler results in a corresponding temperature distribution in the component. This temperature distribution leads to a reduced thermal expansion of the component and thus influences the thermomechanics and thus the durability of the cooler. Due to today's vehicle concepts and the broad application and temperature range, the above conventional radiator concepts are not optimal in terms of component strength.

It is further known ( DE 10 2005 017 974 A1 ; DE 32 17 836 A1 ) to change the flow direction in parts of the coolant flowed through pipes by controllable shut-off valves in at least one water tank and switch, in particular between a so-called U-flow and a so-called I-flow. This makes it possible to switch between different flow curves with different internal pressure losses. An influence of the flow pattern for a temperature distribution, which has a positive effect on the radiator strength, is not provided here and not effectively possible by only two switching positions.

In addition, a vehicle radiator is known ( DE 10 2006 037 212 A1 ) with a main cooling circuit and a secondary cooling circuit, which can be operated individually by means of a valve arrangement or connected to one another for a comparatively higher cooling capacity depending on the operation of the internal combustion engine. Even with such an arrangement, fine regulation of the coolant flow is not possible to improve the radiator strength.

In a further known heat exchanger as a Aufladfluftkühler, which is intended to cool a coming from a turbo compressor compressed and warm air flow, there is between an input pipe and an output pipe both a connection via a two-layer heat exchange body and an immediate valve-controlled connection between the input pipe and the output pipe. When the valve is closed, the air flow is thus directed from the inlet tube via the heat exchange body to the outlet tube. When the valve is open, the air flow is passed in a kind of bypass connection directly from the inlet pipe to the outlet pipe, whereby an air flow through the heat exchange body is largely prevented. In this heat exchanger can thus be controlled by an operating parameters dependent division of the air flow to be cooled are made. However, the size of the flow volume is thus at most not affected in heat exchanger section as a whole. A favorable flow pattern, which has a positive effect on the temperature distribution with respect to the radiator strength of the entire radiator is not provided here and not selectively generated.

The object of the invention is to develop a generic radiator for a cooling system of an internal combustion engine so that a temperature distribution is generated in the radiator, which has a positive effect on the radiator strength.

This object is achieved in that in at least one water tank a the size of the flowing through the radiator flow volume of the coolant volume flow controlling or regulating device is arranged.

According to the invention, a more or less large flow volume is thus supplied to the cooler by means of the control or regulating device and passed therethrough, whereby the thermo-mechanical load of the entire cooler is largely uniform and can be adjusted depending on parameters in accordance with the influenceable size of the flow volume.

The measure according to the invention can be used simply in a cooler design which is known per se, in which a coolant inlet is provided at a first water tank and a coolant outlet at a second water tank, wherein the two water tanks are connected by a tube bundle through which coolant flows.

The inventive measure can also be easily used in an alternative radiator design in which the coolant inlet and coolant outlet are mounted on a first water tank and at a second water tank only a flow deflection takes place. The two water boxes are here connected by two tube bundles, which are flowed through in different directions and are each connected to a portion of the first water box.

The control or regulating device influencing the entire volume flow through the cooler can be arranged in front of a tube plate of an associated tube bundle immediately after the coolant inlet in the water tank or water box part region assigned to it. Thus, an economically favorable component-saving volume flow size is supplied to the radiator already at the coolant inlet. Alternatively and optionally in addition, a corresponding control or regulating device may also be provided directly in front of the radiator outlet, whereby the flow of coolant flowing in at the coolant inlet is influenced accordingly.

In a more concrete embodiment, the control or regulating device has a control valve through which the current coolant volume flow flows, with which the coolant volume flow possible at the coolant inlet and / or at the coolant outlet is reduced or regulated to a desired flow volume as a function of a reference variable. Thus flows in accordance with the performance of a coolant pump with a fully open control valve, the maximum possible coolant flow rate through the radiator. To reduce the thermomechanical component load, the flow volume through the cooler can be reduced overall by reducing the flow rate by means of the control valve.

As a reference variable for the control or regulating device, in particular a directly or indirectly determined temperature in the coolant flow and / or in / on the cooler can be used, via which an appropriate desired flow volume is determined by means of an algorithm. In addition, if appropriate, a flow velocity and / or pressure in the coolant volume flow can be taken into account.

Suitably, the control or regulating device is designed so that flows for all operating cases, a basic coolant flow rate through the radiator, this can be done in particular by the fact that the control valve for such a base coolant volume flow has at least one constantly open passage opening. An additional control refrigerant flow rate is then used to affect the total flow volume. In particular, for this purpose, the control valve may have adjustable opening openings in the opening diameter.

In such an embodiment, it is taken into account that a basic function of the cooler must always be available anyway, which is given by the basic coolant volume flow. By the control or regulating device, only the additional control refrigerant flow rate is controlled or regulated, whereby simple constructive solutions are possible.

In a preferred well-functioning and mechanically simple embodiment, the control valve is integrated after the opening for a coolant inlet or before the opening for a coolant outlet in the associated water tank. The valve seat is cylindrical here and is formed by a cup-shaped portion of a water box wall and a subsequent valve seat wall part. The valve seat wall part has at least one valve seat control opening to a collecting compartment which is formed between the valve seat wall part and a tube bottom spaced therefrom, from which the coolant flowed through pipes extend to the other water tank. Further, an adjustable by an actuator hollow and flowed through by the coolant valve body is arranged in the valve seat. This valve seat is adjustable with at least one coolant inlet opening with respect to the coolant inlet and with at least one valve body control opening with respect to the at least one valve seat control opening for influencing the volume flow. Accordingly, the valve body is adjustable with respect to the coolant outlet in an arrangement on the coolant outlet with at least one coolant outlet opening.

In a first concrete embodiment of the valve body, this consists of a hollow, mutually closed cylinder body arranged on the cylinder circumference valve body control openings. The valve body is axially displaceable here by means of an actuator in the valve seat. Advantageously, the displacement can be carried out starting from a starting position against the force of a return spring, so that in case of malfunction of the control or regulating device of the valve body is returned by the return spring back into the uncritical dimensioned starting position.

In a second concrete embodiment of the valve body, this likewise consists of a hollow cylinder body which is closed on all sides, valve body control openings being arranged here on the cylinder circumference and / or on the cylinder bottom. The valve body is rotatable here in the valve seat about the cylinder axis, wherein depending on the valve position valve body control openings associated valve seat control openings for adjusting the flow more or less cover. In particular, valve body control openings are provided on the cylinder bottom of the valve body, lead to the flow channels to the collecting compartment in front of the tube sheet. Even with a valve body with a rotational adjustment of this can be moved according to the above axial adjustment against the force of a return spring.

The actuator used in the control or regulating device can be actuated in a conventional manner depending on setting parameters electrically and / or pneumatically and / or hydraulically or by physical effects, in particular by means of Wachsdehnelementen or bi-metal springs.

The control or regulating device should generally be designed so that, in the case of a malfunction, an initial position which is not critical for the radiator function is approached automatically.

With reference to a drawing concrete embodiments of the invention will be further explained.

Show it:

1 1 is a schematic view of a radiator for a cooling system of an internal combustion engine of a first embodiment,

2 a schematic view of a radiator for a cooling system of an internal combustion engine of a second embodiment,

3 a sectional view of a control valve at the coolant inlet of a channel box in a first embodiment, and

4 a control valve at the coolant inlet of a channel box in a second embodiment.

In 1 is highly schematic a cooler 1 for a cooling system of an internal combustion engine shown with a first water tank 2 and a second spaced water box 3 , which over (not shown in detail) coolant flowed through pipes 4 are connected. At the first water tank 2 is the connection of a coolant inlet 5 and at the second water box 3 the connection of a coolant outlet 6 , On at the coolant inlet 5 supplied coolant volume flow thus runs here according to the flow arrow 7 straight through the pipes 4 to the second water tank 3 and thus to the coolant outlet 6 ,

In 2 is a largely similar cooler 1 shown, which also has a first water tank 2 and a second water box 3 with pipes in between 4 having. The water tank 2 but here is through a partition 8th into a first subarea 9 with the coolant inlet 5 and a second subarea 10 with the coolant outlet 6 separated. Starting from the first section 9 here flows the coolant volume flow according to the flow arrow 11 in a first tube bundle 12 to the second water tank 3 where a flow deflection takes place with a return flow in the opposite direction according to the flow arrow 13 through a second tube bundle 14 , which at the second subarea 10 the water box 2 is connected to the coolant outlet 6 ,

The control or regulating device according to the invention for influencing the flow volume size of the coolant volume flow flowing through the radiator can both the coolant inlet 5 as well as the coolant outlet 6 be assigned. In the embodiments according to 3 and 4 is the arrangement after the coolant inlet 5 in the water tank 2 represented according to the with A in the 1 and 2 indicated location.

In 3 is a first embodiment of a control valve 15 a control or regulating device shown with which the coolant inlet 5 possible coolant volume flow controlled or regulated in response to a reference variable can be reduced to a desired flow volume. The control valve 15 is in the water tank 2 integrated and has a cylindrical valve seat 16 on, which by a cup-shaped portion 17 a water tank wall 18 and a subsequent shell-shaped portion as a valve seat wall part 19 is formed. Then on the valve seat wall part 19 is in the water tank 2 a collection compartment 20 for the coolant that made through a tube sheet 21 is limited, of which the coolant flowed through pipes 4 depart.

In the valve seat 16 is a cylindrical, can-shaped valve body 22 used, which for flow adjustment by means of a (not shown) actuator according to arrow 23 is adjustable by a rotation about the cylinder axis.

This is on the valve body peripheral wall 24 here an elongated peripheral control opening 25 attached, depending on the rotational position of the valve body 22 at the coolant inlet 5 available coolant volume flow can reduce by a partial cover of the inlet opening. Next are at the valve body bottom 26 Floor control openings are provided, one of which is a floor control opening 27 is visible, which with associated valve seat control openings 28 be wholly or partially brought to cover. Downstream close to the valve seat control openings 28 flow channels 29 . 30 at. The valve body bottom 26 also has a central passage opening 31 on, which (not adjustable) with the entrance of a central flow channel 32 flees. The flow channels 29 . 30 . 32 are with outflow openings 33 . 34 . 35 to the collection compartment 20 and thus to the pipes 4 connected.

The arrangement shown has the following function: that at the coolant inlet 5 by means of the peripheral control opening 25 adjustable total, flowing through the radiator flow volume (flow arrow 36 ) passes through the hollow valve body 22 and according to the respective control position (indicated by the size of the flow arrows further shown) in the flow channels 29 . 30 . 32 and is from there the collection compartment 20 and the pipes connected to it 4 fed.

In 4 is an alternative embodiment of a control valve 15 shown. Again, a cylindrical valve seat 16 through a bowl-shaped portion 17 a water box wall and a subsequent valve seat wall portion 19 educated. This is followed by a collection compartment 20 which continues through a tube sheet 21 with connected coolant flowed pipes 4 is limited.

In the valve seat 16 is a can-shaped closed cylindrical valve body 22 used, which, however, in contrast to the embodiment of 3 here by means of an actuator (not shown) axially (double arrow 37 ) against the force of a return spring 38 is relocatable. At the circumference of the valve body 22 on the one hand is a valve body inflow opening 39 arranged through which the coolant inlet 5 supplied coolant volume flow (flow arrow 40 ) in the high valve body 22 arrives. On the other hand, here on the valve body circumference valve body outflow 41 . 42 . 43 provided, which depending on the valve body position with associated collecting compartment inlet openings 44 . 45 . 46 for flow release to the pipes 4 be wholly or partially brought to cover.

In 4 is the valve body 22 shown in a starting position, wherein the flow volume (flow arrow 40 ) through the valve body 22 , the valve body exhaust port 43 and the Sammelabteileinströmöffnung 45 in the collection compartment 20 and from there into the pipes 4 arrives.

When the valve body 22 with its valve body outlets 41 and 42 moved down, these come wholly or partially to cover with the Sammelabteileinströmöffnungen 44 and 46 so that with the flow arrows 47 and 48 specified flow according to all or part of the collection compartment 20 is released.

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 102005017974 A1 [0007]
• DE 3217836 A1 [0007]
• DE 102006037212 A1 [0008]

Claims (12)

Radiator for a cooling system of an internal combustion engine, with at least two water tanks ( 2 . 3 ), which pass through coolant-flow pipes ( 4 ) and with a coolant inlet ( 5 ) at a water box, downstream of the coolant flowed through pipes ( 4 ) and an operationally flowing coolant volume flow with a arranged on a water tank coolant outlet ( 6 ), characterized in that in at least one water tank ( 2 . 3 ) one the size of the through the radiator ( 1 ) flowing flow volume of the coolant volume flow controlling or regulating control device is arranged. Radiator for a cooling system of an internal combustion engine according to claim 1, characterized in that the coolant inlet ( 5 ) at a first water tank ( 2 ) and the coolant outlet ( 6 ) on a second through coolant-flowed tubes ( 4 ) connected as a tube bundle and spaced water tank ( 3 ) is arranged. Radiator for a cooling system of an internal combustion engine according to claim 1, characterized in that the coolant inlet ( 5 ) at a first subregion ( 9 ) of a first water box ( 2 ) and the coolant outlet ( 6 ) at one of the first subarea ( 9 ) by a partition wall ( 8th ) divided second subarea ( 10 ) of the first water box ( 2 ), each subregion ( 9 . 10 ) with an associated first tube bundle ( 12 ) and second tube bundle ( 14 ) with a second water tank ( 3 ) is connected to the flow deflection. Radiator for a cooling system of an internal combustion engine according to one of claims 1 to 3, characterized in that a mechanical adjusting device ( 15 ) of the control or regulation device after the coolant inlet ( 5 ) in an associated water tank ( 2 ) or water box subarea ( 9 ) in front of a tube sheet ( 21 ) of an associated tube bundle is arranged, and / or that a mechanical actuating device ( 15 ) of the control or regulation device before the coolant outlet ( 6 ) in an associated water tank ( 3 ) or water box subarea ( 10 ) after a tube sheet ( 21 ) is arranged an associated tube bundle. Radiator for a cooling system of an internal combustion engine according to any one of claims 1 to 4, characterized in that the control or regulating device flows through a flow of current coolant flow control valve ( 15 ), with which the coolant inlet ( 5 ) and / or at the coolant outlet ( 6 ) possible coolant volume flow is controlled or regulated in response to a reference variable is reduced to a desired flow volume. Radiator for a cooling system of an internal combustion engine according to claim 5, characterized in that the reference variable for the control or regulating device at least one directly or indirectly determined temperature in the coolant flow and / or in / on the radiator ( 1 ) and / or a flow velocity of the coolant volume flow and / or a pressure in the coolant volume flow. Radiator for a cooling system of an internal combustion engine according to claim 5 or claim 6, characterized in that the flow volume through the coolant flow-through tubes ( 4 ) is composed of a basic coolant volume flow and a control coolant volume flow such that the control valve ( 15 ) for the base coolant volume flow at least one non-closable, constantly open passage opening ( 31 ), and that the control valve ( 15 ) for the control coolant volume flow at least one adjustable in opening diameter optionally closable control port ( 27 and 28 ; 41 and 44 ; 42 and 46 ) between a valve seat ( 16 ) and a valve body ( 22 ) having. Radiator for a cooling system of an internal combustion engine according to claim 7, characterized in that the control valve ( 15 ) after the opening for a coolant inlet ( 5 ) or before the opening for a coolant outlet ( 6 ) is integrated in the associated water box, in such a way that a cylindrical valve seat ( 16 ) by a bowl-shaped portion ( 17 ) a water box wall ( 18 ) and a subsequent valve seat wall part ( 19 ) is formed, the at least one valve seat control opening ( 28 ) to a collecting compartment ( 20 ), which between the valve seat wall part ( 19 ) and a spaced tube bottom ( 21 ), and in that an adjustable by an actuator, hollow valve body ( 22 ) in the valve seat ( 16 ) arranged with at least one coolant inlet opening ( 25 ) or with at least one coolant outlet opening with respect to the coolant inlet ( 5 ) or the coolant outlet and with at least one valve body control opening ( 27 ) with respect to the at least one valve seat control port ( 28 ) is adjustable. Radiator for a cooling system of an internal combustion engine according to claim 8, characterized in that the valve body ( 22 ) a hollow, all-round closed cylinder body with on the cylinder circumference arranged valve body control openings ( 39 . 41 . 42 . 43 ), in the valve seat, in particular against the force of a return spring ( 38 ) is displaced axially. Radiator for a cooling system of an internal combustion engine according to claim 8, characterized in that the valve body ( 22 ) a high all-round closed cylinder body with on the valve body peripheral wall ( 24 ) and / or on the valve body floor ( 26 ) arranged valve body control openings ( 25 . 27 ), which is in the valve seat ( 16 ), is optionally rotatably displaced against the force of a return spring, wherein in particular the valve body control openings ( 28 ) at the valve body bottom ( 26 ) Flow channels ( 29 . 30 . 32 ) to the collecting compartment ( 20 ) are subordinate. Radiator for a cooling system of an internal combustion engine according to one of claims 1 to 10, characterized in that the control or regulating device comprises an actuator which depends on control parameters electrically and / or pneumatically and / or hydraulically or by physical effects, in particular by means of wax expansion elements or Bi Metal springs is actuated. Radiator for a cooling system of an internal combustion engine according to any one of claims 1 to 11, characterized in that the control or regulating device is designed so that in case of malfunction, an uncritical for the radiator function starting position is approached automatically.

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