EP1881171A1 - Valve for controlling a coolant flow for the heat exchanger of a motor vehicle and system with at least one said valve - Google Patents

Abstract

A control valve has a first valve opening (2) for coolant flow for a heater which can be closed via a first controlled closure element (3), and a second valve opening (4) for bypassing the heater and for limiting the pressure via at least a second closure element (8). The first closure element (3) and the second closure element (8) are arranged in a sub-assembly. An independent claim is given for a system with at least one valve.

Description

The present invention relates to a valve for controlling a coolant flow for a radiator of a motor vehicle according to claim 1 and a system with at least one valve. For heating the passenger compartment of a motor vehicle, a heat exchanger, in particular a radiator is usually used, which usually has a finned tube block of tubes such as flat tubes, through which a first medium, in particular a water-containing cooling liquid, flows. Adjacent to the tubes, in particular to the flat tubes, ribs such as corrugated ribs are arranged or connected to the tubes, in particular flat tubes, cohesively, for example, by soldering, welding, gluing, etc. Heat is transferred to a second medium, in particular air, flowing past the flat tubes and / or the corrugated fins through the ribs, in particular the corrugated ribs, but also through the tubes, in particular the flat tubes. The air warms up. The heated air is used to heat the passenger compartment of a motor vehicle.

The first medium, in particular the cooling medium, such as a water-containing cooling liquid or air or another cooling liquid flows at least in sections through an internal combustion engine of a motor vehicle and thereby cools the internal combustion engine of the motor vehicle. The heat absorbed by the first medium, in particular the cooling medium, as already mentioned, is transferred in the first heat exchanger, in particular the radiator, to air flowing past it. From the internal combustion engine flows at least in a first line section heated by the engine cooling medium to the first heat exchanger, in particular the radiator, flows through this in the tubes, in particular in the flat tubes and leaves the first heat exchanger, in particular the radiator and flows into a second line section again combustion engine.

Furthermore, an at least third line section is known for bypassing the first heat exchanger, in particular the radiator. At least part of the first cooling medium or the entire first cooling medium can be fed directly back to the internal combustion engine after leaving the engine through the bypass line.

Furthermore, at least one pump, such as an electric pump, is known, which is arranged in the first line section or in the second line section or in the bypass channel and pumps the first medium, in particular the cooling fluid, through the motor.

Further, a valve element is known, which controls the flow of the first heat exchanger, in particular of the radiator, such that the first heat exchanger, in particular the radiator, first medium is supplied or no first medium is supplied.

Furthermore, second separately formed valve elements for controlling and / or regulating the flow rate of the first medium, in particular cooling liquid, through the bypass channel are known.

This number of separately formed valve elements for flow control of cooling medium through the bypass channel and for controlling the flow of the first heat exchanger, in particular the radiator, require a large space and a large number of lines for the respective valves, see Figure 2 (Stand of Technology).

Figure 2 shows a system according to the prior art with a first heat exchanger, in particular a radiator HK and with a first valve V1 and a second valve V2.

Medium such as cooling medium flows through an inlet into a first line section ELA. At a branch point, a bypass BP branches off from the first line section ELA. A second valve V2, in particular a magnetically controlled valve, controls the flow of cooling fluid, such as water-containing cooling fluid. According to the position of the second valve V2 of the radiator HK and the heater HK upstream pump P is flowed with coolant or not flowed with coolant. When the second valve opens, cooling medium enters the heating element HK via the circulation pump P, flows through it and then flows in the direction of the outlet A. Before exiting, the bypass BP flows into the second line section ZLA. A first valve V1 controls the flow of cooling fluid or coolant through the bypass BP.

It is an object of the present invention to reduce the space requirement for controlling or controlling the flow of a heat exchanger or for controlling the flow of a first fluid through a bypass channel as well as to simplify the regulation or control and / or to reduce the number of components.

The object is solved by the features of claim 1.

It is proposed a valve for controlling a coolant flow for a radiator of a motor vehicle with at least a first valve opening for a coolant flow for a radiator, which is closable by means of a first controllable closure element, with at least one second valve opening for bypassing the radiator and for pressure relief, which by means of at least one second closure element is closable, wherein the first closure element and the second closure element are arranged in a structural unit.

In particular, coolant, in particular a water-containing cooling liquid, can be supplied to a radiator via the first valve opening. The first valve opening can be closed by means of a first controllable closure element or can be closed by means of a first controllable closure element. By "controllable" is to be understood that the first closure element can be controlled electrically and / or magnetically and / or by means of hydraulics and / or by means of pneumatics. The at least second valve opening is used in particular for bypassing the radiator and / or for limiting the pressure. By "bypassing" is to be understood that the first medium, in particular cooling liquid is not passed through the heat exchanger, in particular the radiator, but is passed around the radiator and at least one internal combustion engine can be fed back directly. In particular, the second valve opening can serve to limit the pressure, in particular that at a high pressure in the at least one heat exchanger, in particular the radiator and / or in at least one line, the pressure can be reduced, in which the first medium, in particular the cooling fluid, can flow through the second valve opening. The first closure element and the second closure element can be arranged in a structural unit, in particular in a housing.

In an advantageous embodiment, the first closure element can be controlled by means of at least one electromagnet and / or by means of at least one coil or can be controlled by at least one electromagnet and / or by means of at least one coil or by means of at least one electromagnet and / or by means of at least one coil driven. In this way, the first closure element can particularly advantageously open or close the at least one first valve opening.

Furthermore, it can be particularly preferably provided that the first closure element can be controlled by means of at least one vacuum unit. In this way, the first closure element can open or close the first valve opening particularly advantageous.

Furthermore, it can be provided that the first closure element is formed at least in sections cone-like and / or has a pin-like area for guiding. In this way, the closure of the first valve opening can be sealed particularly advantageous. Furthermore, the first closure element can particularly advantageously close the at least first valve opening.

In a further advantageous development, the pin-like region is arranged at least in sections in a guide counter-element. In this way, the first closure element can be guided in a particularly advantageous manner.

A further advantageous embodiment is characterized in that on the guide counter-element, at least in sections, a first spring element is arranged for opening the first valve opening in the case of a de-energized electromagnet and / or in the case of a current-depleted coil. In this way, it can be particularly advantageously prevented that in the de-energized state, in particular in the event of a power failure, the first valve opening remains closed and, in particular, the heating power is low.

Furthermore, it can be provided that the second closure element is at least partially connected to a second spring element and / or is designed such that when a limit pressure is exceeded, the second opening is at least partially opened. In this way, the first medium, in particular the cooling medium, can be discharged via the bypass particularly advantageously when a limiting pressure is exceeded.

Furthermore, a system with at least one valve is proposed which has at least one first heat exchanger, in particular a radiator, for heating a passenger compartment of a motor vehicle and at least one second heat exchanger for heating, in particular a rear passenger cell.

Furthermore, it can be particularly preferably provided that the system has at least one third heat exchanger for heating a passenger compartment with the internal combustion engine switched off. In this way, the passenger compartment can be heated particularly advantageously even with the internal combustion engine by means of a heater.

Furthermore, it can be provided that the system has at least one pump, in particular an auxiliary pump, for pumping a first medium for engine cooling and / or passenger compartment heating and / or at least one Bypass line for bypassing at least the first heat exchanger has. In this way, the first medium, in particular the cooling medium, particularly advantageous to the first heat exchanger, in particular the radiator, are supplied.

Further advantageous embodiments of the invention will become apparent from the dependent claims and from the drawing. The subject matters of the dependent claims relate both to the valve according to the invention for controlling a coolant flow for a radiator of a motor vehicle and to the system according to the invention with at least one valve.

Figur 1:

ein Ventil zur Steuerung eines Kühlmittelstroms für einen Wärmetauscher, insbesondere einen Heizkörper, eines Kraftfahrzeugs,

Figur 2:

ein System mit einem ersten Wärmetauscher mit einem ersten Ventil und einem zweiten Ventil gemäß dem Stand der Technik,

Figur 3:

ein erstes Ausführungsbeispiel eines Systems mit einem Ventil zur Steuerung eines Kühlmittelstroms für einen Wärmetauscher, insbesondere einen Heizkörper, eines Kraftfahrzeugs und

Figur 4:

ein weiters Ausführungsbeispiel eines Systems mit einem Ventil zur Steuerung eines Kühlmittelstroms für einen ersten Wärmetauscher und einen zweiten Wärmetauscher.

Embodiments of the invention are illustrated in the drawings and will be explained in more detail below, with a limitation of the invention is not intended to take place. Show it

FIG. 1:

a valve for controlling a coolant flow for a heat exchanger, in particular a radiator, of a motor vehicle,

FIG. 2:

a system having a first heat exchanger with a first valve and a second valve according to the prior art,

FIG. 3:

a first embodiment of a system with a valve for controlling a flow of coolant for a heat exchanger, in particular a radiator, a motor vehicle and

FIG. 4:

a further embodiment of a system comprising a valve for controlling a coolant flow for a first heat exchanger and a second heat exchanger.

FIG. 1 shows a valve 1 for controlling a coolant flow for a heat exchanger, in particular a radiator, of a motor vehicle.

The valve 1 has a valve housing 5. On the valve housing 5 an inflow pipe 18 for the inflow of coolant and a radiator connection piece 17 are arranged. Further, a bypass connection piece 16 is arranged on the valve housing 5. In the illustrated embodiment, the inflow pipe 18 and / or the radiator connection piece 17 and / or the bypass connection piece 16 is formed integrally with the valve housing 5. In another embodiment, the bypass connection piece 16 and / or the radiator connection piece 17 and / or the inflow pipe 18 to the valve body 5 materially, in particular by welding, soldering, gluing, etc. and / or positively connected.

In the illustrated embodiment, the valve housing 5 is formed of a plastic. In another embodiment, the valve housing 5 is formed of metal such as aluminum or stainless steel or ceramic or of a fiber composite material. The valve housing 5 is made for example by means of a non-forming manufacturing process such as injection molding or die casting. In another embodiment, the valve housing 5 is formed from a forming process such as pressing or stamping.

The bypass connecting piece 16 is at least partially tubular and has a bypass connection opening 20. At the end of the bypass connection piece, which is arranged opposite to the bypass connection opening 20, the bypass connection piece is designed in the shape of a flange. At the flange-shaped unspecified section of the bypass port 16 is positively to the valve housing 5, in particular by screwing and / or cohesively, in particular by soldering, welding, gluing, etc. with the valve housing 5 connected. About the bypass connection piece 16 a not shown tube or pipe element is pushed and attached, for example by means of a clamp on the bypass connection piece 16. In another embodiment, the hose element or pipe element, not shown, may be positively and / or materially connected to the bypass connection piece 16. In particular, for better support adjacent to the bypass port 20, a non-designated projection formed from the bypass port, which improves in particular the maintenance of the pushed onto the bypass port 16 pipe element or hose member.

Adjacent to the bypass connecting piece is followed by a substantially cylindrical first valve housing space of the first valve housing 5, in which the second closing element 8 and the second spring element 12 are arranged. The first valve housing chamber 29 has a unspecified first opening, which is arranged adjacent to the bypass connection piece 16. Furthermore, the valve housing 5 has a second valve opening 4, which is designed in particular as a valve seat for the second closure element 8. In the exemplary embodiment illustrated, the first valve housing space 29 has a larger diameter than the bypass connection piece 16. In particular, a stop for the second spring element 12 is formed between the first closure housing space 29 and the bypass connection piece 16. In another embodiment, the bypass connection piece has a larger diameter than the first valve housing space 29. In another embodiment, the first valve housing chamber 29 has the same diameter as the bypass connection piece 16.

The second spring element 12 is formed in the illustrated embodiment substantially as a spiral spring. In another embodiment the second spring element 12 is formed for example as a leaf spring element or as another spring element.

The second closure element 8 is designed essentially as a circular plate element, from which a nub is formed. If the inflow to the bypass is closed, then an unspecified annular portion of the second closure element 8 bears against a section of the valve housing 5. The nub-shaped section of the second closure element 8 is arranged substantially in the second valve opening 4. If the bypass channel is open, the second closure element, for example, assumes the position 30, in which the second closure element is shown in dashed lines. By means of the second valve opening 4, medium such as, for example, cooling medium, in particular a water-containing cooling liquid, can then enter the first valve housing space 29 and exit from the valve 1 via the bypass connecting piece 16 in the direction of the second media outlet M2A and flow into the bypass channel (not shown).

In another embodiment, the second closure element 8 has an at least partially conical and / or cylindrical shape or a shape of the combination of the aforementioned forms. Adjacent to the first valve housing chamber 29, a second valve housing chamber 31 connects. Via the medium inlet direction flows through the inflow opening 19 of the inflow nozzle 18 first cooling medium, in particular water-containing cooling liquid in the second valve housing chamber 31 a. The inflow nozzle 18 has in the illustrated embodiment unspecified at least partially round grooves, which are formed circumferentially around the inflow pipe 18. In this way, a hose or pipe element can be pushed onto the inflow pipe 18. A detachment of the unspecified pipe element or hose member is particularly advantageously prevented. Further, for example, that can not shown hose member secured to the inflow pipe 18 by means of a clamp and / or connected. In the valve housing 5, a substantially annular element 33 is formed or formed integrally with the valve housing 5 in another embodiment. The ring element 33 has the first valve opening 2. The first valve opening 2 is designed in particular as at least partially conical valve seat for the first closure element 3. Adjacent to the second valve housing space 31 and separated by the first valve opening 2, a third valve housing space 32 is formed. When the first closure element 3 is open, cooling medium, such as aqueous cooling liquid or air, can enter the third valve housing space 32 through the first valve opening 2 and exit via the radiator connection stub 17 from the radiator connection stub opening 21 in the direction of the first medium exit direction M1A and, for example, not to the heat exchanger (not shown) shown radiator, flow. The first closure element 3 is shown in dashed lines in the closed position 34.

The first closure element 3 is cone-shaped. At the cone-shaped portion, a first guide member 9 connects. The first closure element 3 and the first guide element 9 are integrally formed in the illustrated embodiment. In another embodiment, the first closure element 3 and the first guide element 9 can be integrally formed, in particular by welding, soldering, gluing etc. and / or in a form-fitting manner. The first guide element 9 is designed essentially as a pin element. In another embodiment, the first closure element 3 is cylindrical and has a round or oval or triangular or polygonal cross-sectional area or a cross-sectional area of the combination of the aforementioned forms.

At least in sections, a second guide element 25 is arranged on the first guide element 9. In particular, the second guide element 25 is shrunk onto the first guide element 9 or, for example, connected to the first guide element 9 by material connection. The second guide element 25 is designed essentially as a cylinder-cone element.

The first closure element 3 assumes a first end position when the first guide element 9 contacts the first stop surface 24 of the cylinder housing. The first stop surface 24 may for example be part of a rubber element or other damping element for damping the first guide element 9. In particular, in the closed position 34 of the first closure element 3, the cone element of the second guide element 25 contacts an associated conical surface of the guide counter element 10. The guide counter element 10 has an unspecified bore, which essentially accommodates the first guide element 9. In this way, the first guide element 9 is guided at least in sections in the bore of the guide counter-element 10. The guide counter-element 10 is made in one piece with the valve housing 5 or in another embodiment with the valve housing 5 positively and / or materially connected. Between the second guide member 25 and the guide counter-element 10, a first spring element 11 is arranged. The first spring element 11 may be formed, for example, as a spiral spring or a leaf spring. The first spring element 11 is further arranged on the first guide element 9. If the first closure element 3 is in particular in the closed position 34, the first spring element 11 is pretensioned such that a spring force acts on the second guide element 25 and also on the guide element 10 in the currentless state of the valve 1, so that the second guide element 25 and the guide counter-element 10 are pressed apart and the first closure element releases the first valve opening. in the de-energized state is thus ensured that the first medium, in particular cooling medium such as in particular the aqueous coolant can escape from the radiator connection piece 17 via the radiator connection port 21 in the direction of the first media exit direction M1A. The first guide element 9 and the second guide element 25 are in particular made of a magnetizable material such as metal, in particular iron or aluminum or a steel. Essentially concentric with the first guide element 9 and / or with the second guide element 25, a coil 6 or an electromagnet 7 is arranged in the valve housing 5. The coil 6 and the electromagnet 7 are powered by an electrical connection. If the coil 6 or the electromagnet is energized, a magnetic force MK is generated, which moves the first closure element 3 or the first guide element 9 in the direction of the magnetic force MK, so that the first closure element 3 occupies the closure position 34 and the first valve opening 2 closes. The first closure element 3 is formed, for example, from a material such as rubber or from another sealing material, so that in the closure position 34 of the first closure element 3 no medium such as cooling medium through the first valve opening 2 in the third valve housing chamber 32 from the second valve housing chamber 31 can occur ,

Further, on the first guide member 9, a diaphragm 14 is arranged such that it frees dirt from the first guide member 9 and at the same time the space 32 against a fourth valve housing chamber 35 seals. In particular, the electromagnet 7 and the coil 6, the first spring element 11 and the second guide element 2 are arranged in the fourth valve housing space 35. The membrane 14 has an opening substantially corresponding to the cross-sectional area of the first guide element 9. The membrane 14 is formed for example of rubber or other sealing material. In the illustrated embodiment the membrane 14 is integrally formed with a first sealing element 22. In another embodiment, the first sealing element 22 and the membrane 14 are not formed in one piece. The first sealing element 22 is formed for example of rubber or other sealing material and prevents medium from the third valve housing chamber 32 enters the fourth valve housing chamber 35 and, for example, the coil 6 or the at least one electromagnet 7 and the electrical connections 13 damages, for example by liquid such as cooling medium or other medium enters the fourth valve housing chamber 35. At least one second sealing element 23 and / or at least one third sealing element 27 likewise prevents, for example, medium, in particular cooling medium, in particular water-containing cooling liquid, from reaching the at least one electromagnet or at least one coil 6 and damaging the same.

The valve 1 can take the following positions:

The first closure element 3 can be arranged in the closure position 34 and the second closure element 8 can likewise be arranged in the closure position. Medium such as Kühtftüssigkeit then enters through the inflow port 19 via the inflow nozzle 18 in the direction of the media inlet direction ME in the second valve housing chamber 31, but can neither enter the first valve housing chamber 29 in the third valve housing chamber 32.

If the first closure element 3 in the closed position 34 and the second closure element 8 in the open position 30, the first medium such as coolant or other cooling medium via the inflow opening 19 in the inflow pipe 18 and thus in the second valve housing chamber 31 and enter via the opened second valve opening 4 enter the first valve housing chamber 29 and enter via the bypass port 20 in the bypass.

Is the first closure element 3 is open, d. H. the first valve opening 2 is opened, and the second closure element 8 is closed, d. H. the second valve opening 4 is closed, so first medium such as coolant or other cooling medium such as air via the inflow port 19 into the inflow port 18 and thus the second valve housing chamber 31 and enter via the first valve opening 2 in the third valve housing chamber 32 and further in enter the radiator connection piece 17 with the radiator connection nozzle opening 21 and flow over the radiator connection nozzle opening 21 to the radiator. No medium can enter the first valve housing space 29.

If the first closure element 3 is opened and the second closure element 8 is likewise opened and is thus in the opening position 30, medium such as aqueous coolant or, for example, air or another cooling medium can enter the second valve housing chamber 31 via the inflow port 18 and the inflow port 19 and both enter through the second valve opening 4 in the first valve housing chamber 29 and thus flow to the bypass as well as in the third valve housing chamber 32 and flow through the radiator port 21 to the radiator or to another heat exchanger.

The valve for controlling the coolant flow protects the at least one heat exchanger, in particular the heater from overpressure and / or from cavitation at too high a flow of the first medium, in particular cooling medium. Furthermore, the valve for controlling the coolant flow has a differential pressure control function. The valve for controlling the coolant flow furthermore allows, in particular, an unlimited flow through the bypass with first medium, in particular with cooling medium.

Further, the valve for controlling the flow of coolant allows switching between flow through the bypass and flow through the at least one heat exchanger, in particular the radiator.

FIG. 3 shows a system with a valve 1 according to the invention for controlling the coolant flow to a heat exchanger, in particular radiator HK, or likewise for controlling the bypass channel BP. Identical features are provided with the same reference numerals as in the previous figures.

The system comprises an internal combustion engine M, the valve 1 according to the invention, a pump P for pumping cooling medium, such as a water-containing cooling liquid, and a heat exchanger WT. In another embodiment, the system may additionally have a heater SH.

In the illustrated embodiment, the heat exchanger WT is a radiator. In another embodiment, the heat exchanger WT is a coolant radiator and / or an exhaust gas cooler and / or a charge air cooler and / or a condenser for an air conditioner and / or a gas cooler for an air conditioner and / or an oil cooler and / or an evaporator for an air conditioning system.

In the internal combustion engine M, a second heat exchanger for cooling the internal combustion engine is arranged. After cooling medium such as water-containing cooling liquid or air has flowed through the second heat exchanger for cooling in the internal combustion engine, the coolant heated in the internal combustion engine M flows to the valve according to the invention 1. To the functions of the valve 1, see Figure 1. A first line section ELA leads from the engine M. Valve 1 and on to pump P. Pump P pumps the coolant through the system. The first line section leads in the illustrated embodiment further to a third heat exchanger SH, in particular to a heater, and then to the heat exchanger WT, in particular to the radiator. In another embodiment, the coolant flows through the first line section ELA after flowing through the pump P directly to the first heat exchanger WT, in particular to the radiator. After flowing through the first heat exchanger WT, in particular the radiator, the coolant flows in a second line section ZLA to the internal combustion engine M, in particular to the second heat exchanger for cooling the internal combustion engine, which is arranged in the internal combustion engine M. The bypass BP opens into the second line section ZLA. The valve for controlling the coolant flow protects the at least one heat exchanger, in particular the heater from overpressure and / or from cavitation at too high a flow of the first medium, in particular cooling medium. Furthermore, the valve for controlling the coolant flow has a differential pressure control function. The valve for controlling the flow of coolant also allows in particular an unlimited flow through the bypass with the first medium, in particular with cooling medium.

FIG. 4 shows a system with a valve 1 according to the invention for controlling the coolant inflow. In contrast to Figure 3, in addition to the first heat exchanger WT1, in particular the radiator, at least one further heat exchanger WT2, in particular a coolant radiator and / or an exhaust gas cooler and / or a charge air cooler and / or a condenser for an air conditioner and / or a gas cooler for a Air conditioning and / or an oil cooler and / or an evaporator for air conditioning provided.

The features of the various embodiments can be combined with each other. The invention can also be used for other than the areas shown.

Claims (10)

Valve for controlling a coolant flow for a radiator of a motor vehicle
comprising,
a first valve opening (2) for a coolant inflow for a radiator, which can be closed by means of a first controllable closure element (3),
at least one second valve opening (4) for bypassing the radiator and for limiting the pressure, which can be closed by means of at least one second closure element (8),
characterized in that
the first closure element (3) and the second closure element (8) are arranged in a structural unit. Valve according to claim 1, characterized in that the first closure element (3) by means of at least one electromagnet (7) and / or by means of at least one coil (6) is controllable. Valve according to claim 1 or 2, characterized in that the first closure element (3) by means of at least one vacuum box is controlled. Valve according to one of the preceding claims, characterized in that the first closure element (3) is at least partially cone-shaped and / or has a pin-like area to the guide (9). Valve according to claim 4, characterized in that the pin-like regions (9) is arranged at least in sections in a guide counter-element (10). Valve according to claim 4 or 5, characterized in that on the guide counter-element (10) at least in sections, a first spring element (11) for opening the first valve opening (2) is energized with no current electromagnet (7) and / or in de-energized coil (6) , Valve according to one of the preceding claims, characterized in that the second closure element (8) at least partially connected to a second spring element (12) and / or is designed such that when a limit pressure is exceeded, the second opening (4) is at least partially opened , System having at least one valve according to one of claims 1 to 7
at least a first heat exchanger (WT) for heating a passenger compartment of a motor vehicle and
at least one second heat exchanger for cooling an internal combustion engine (M) of a motor vehicle. System according to claim 8, characterized in that the system comprises at least a third heat exchanger (SH) for heating a passenger compartment with the internal combustion engine (M). System according to claim 8 or 9, characterized in that the system comprises at least one pump (P) for pumping a first medium for engine cooling and / or passenger compartment heating and / or at least one bypass line (BP) for bypassing at least the first heat exchanger (WT) ,

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