EP2039902A2 - Device for calibrating the flow of a cooling agent in a cooling circuit and cooling circuit - Google Patents

Abstract

The device (3) has components provided with a set of geometries in dependence of the temperature of a cooling agent, where the geometries correspond to a set of meta stable states. One of the meta stable states corresponds to a less flow rate, and the other meta stable state corresponds to a high flow rate. The device passes from a meta stable condition into another meta stable condition during transition of the temperature of the cooling agent from a temperature range into another temperature range.

Description

TECHNICAL AREA

The invention relates to a device for adjusting the flow of a coolant in a cooling circuit, in particular for controlling the coolant flow through a cooling water expansion tank, and a coolant circuit, in particular in a motor vehicle. In addition, the invention relates to a fluid system, comprising at least one conduit having a first opening cross section for the passage of a fluid, and a fluid system, comprising a conduit system having a first opening cross section for the passage of a fluid, and a second opening cross section.

STATE OF THE ART

In cooling water circuits of motor vehicles Kühlwasserausgleichsbehälter are arranged to by means of a buffer volume of air volume changes of the coolant, for example, as a result of temperature changes, different hose expansions, etc., compensate. Furthermore, cooling water expansion tanks also serve to remove air accumulations from the cooling liquid, since the efficiency of the cooling system would be considerably worsened by air accumulation in the cooling liquid.

However, due to the additional cooling liquid located in the cooling water expansion tanks, the warm-up properties of the engine to be cooled deteriorate, since in the warm-up phase, the additional cooling water in the cooling water expansion tank also has to be heated.

In the hitherto known piping systems for liquid media with a cooling water expansion tank therefore the cooling water in the cooling water expansion tank is kept in the warm-up phase until reaching the operating temperature controlled by actuators via valves in the cooling water expansion tank. The valves are controlled by external units such as temperature sensors, which are in the Cooling water main circuit are arranged and actuators. A disadvantage of these systems is that several components (temperature sensors, actuators, valves) are required and thus an increased space requirement in the limited engine compartment is required. In addition, several steps are required for mounting and fixing the components.

As a flow restrictor bimetallic or wax elements are used, for example, which adjust the flow rate relatively continuously. However, wax elements are relatively expensive and expensive.

As an alternative to the thermal control of the volume flow by temperature sensors and valves, it is also known in the prior art to provide a pressure control. In this case, the cooling water located in the cooling water expansion tank passes only after reaching a certain pressure in the cooling circuit in the main cooling water circuit. However, since the pressure dynamics also depends on the engine load in the warm-up phase, it can not be ruled out in the pressure control that the cooling water located in the cooling water expansion tank reaches the cooling circuit already before reaching the operating temperature due to a high pressure.

OBJECT OF THE INVENTION

The present invention is therefore based on the object of specifying a line system for liquid media for a coolant circuit with a coolant expansion tank, which has a space-saving, easy to install and suitable for the purpose of warming up an engine flow adjustment.

TECHNICAL SOLUTION

This object is achieved by a device for adjusting the volume flow in a coolant circuit according to claim 1, a fluid system according to claim 10 or 15, and a coolant circuit according to claim 12.

The inventive device for adjusting the flow of a coolant in a cooling circuit, in particular for controlling the coolant flow through a cooling water expansion tank, has at least one first (meta) stable state, the corresponds to a low flow, and at least a second (meta) stable state, which corresponds to a high flow, wherein the device is designed such that it is at a transition of the temperature of the coolant from a first temperature range to a second temperature range of the first (meta) stable state in the second (meta) stable state passes.

In this way, the flow of coolant or cooling water through a conduit, in particular by an inflow line to a cooling water expansion tank, set temperature dependent. The transition between the two states does not occur linearly, but abruptly as a function of the temperature. The principle can thus be described as a very rough control cycle of two output values (states). This characteristic corresponds to the requirements for solving the above-mentioned application. The flow remains completely limited until the temperature in a certain area of the cooling water circuit has actually exceeded a certain value.

The two states are taken on the principle of a temperature-sensitive "crackpot frog". By (meta) stable states are meant stable states and metastable states between which the device can change as soon as a certain amount of temperature change occurs. In general, a bistable element can be used, but it is also possible to provide more than two (meta) stable states, if this is desired for the volume flow control.

Preferably, the device comprises at least one component which, depending on the temperature of the coolant, assumes either a first geometry which corresponds to the first (meta) stable state or a second geometry which corresponds to the second (meta) stable state. According to the invention, therefore, a component, preferably in the inflow region of the Kühlwasserausgleichsbehälters integrated, depending on the respective cooling water temperature on the component its shape or its geometry changes so that a cooling water flow into the cooling water expansion tank allows or prevented. The geometry of the component, which is arranged in the flow area, determines the flow area. The device automatically changes the geometry due to the effect of temperature. The stepwise change in geometry at a temperature impact is intrinsic to the material and the geometric design of the device.

The component can assume its geometry as a function of the temperature of the coolant flowing through it. In this way, a direct influence of the temperature of the coolant is ensured on the component.

The device may be wholly or partly made of bimetal. The device may also consist wholly or partly of a shape memory material (shape memory alloys FGL).

The device preferably has at least one first opening cross section for the flow or for the passage of cooling medium past the device in the first (meta) stable state. Since the Kühlwasserausgleichsbehälter is located in a secondary cooling circuit and the coolant from the main circuit can not get into the secondary circuit, it comes in the flow-preventing state of the temperature-sensitive component to temperature differences in the main circuit and the secondary circuit. Since the flow through the cooling water expansion tank is to be set / controlled by the device according to the invention as a function of the temperature in the main cooling circuit, it is advantageous to configure the device according to the invention in such a way that a small coolant flow is made possible even in the flow-preventing state. As a result, the temperature difference between the main cooling circuit and the temperature applied to the component according to the invention can be considerably reduced, so that a more accurate adjustment is made possible. The adjustment thus takes place with the aid of a leakage current or a bypass current. The bypass can therefore in principle e.g. be provided as opening (s) in or on the device.

In particular, the device has at least one second opening cross-section for the flow or for the passage of cooling medium past the device in the second (meta) stable state. The component switches between the states with different cross-sections by their special design, their structure, eg material selection, etc. Due to the shape and structure of the device, a desired opening and closing characteristic as a function of the temperature can be realized.

The second opening cross section is larger, in particular substantially larger, than the first opening cross section. The first opening area may be zero or nearly zero.

The transition from the first (meta) stable state to the second (meta) stable state, and possibly vice versa, is preferably non-linear as a function of the temperature of the coolant, that is to say abruptly after exceeding a certain activation potential by the temperature difference. The different states can also be "approached" in a kind of hysteresis.

A fluid system according to the invention comprises at least one line with a first opening cross section for the passage of a fluid, and at least one device as described above, which is arranged for closing and / or for releasing the first opening cross section.

In particular, the fluid system has at least one second opening cross section for the passage of a fluid in addition to the first opening cross section, wherein the second opening cross section is unlocked, regardless of the temperature of the fluid. The fluid transport from an area in front of the device and behind the device can thus also take place via a bypass which is always always unlocked.

An inventive coolant circuit, in particular in a motor vehicle, comprises at least one device as described. By using the device, an optimal, "tailored" characteristic for the limitation of a fluid flow can be realized. In particular, a discrete setting between two or more opening states is made possible.

However, it should be emphasized that the invention should not be limited to this application, but in all possible applications, eg. As solar applications, heating technology, plumbing, etc., can be used, in which the management of a fluid medium is required.

The coolant circuit preferably comprises at least one

Coolant expansion tank.

The device is arranged in particular in the coolant expansion tank.

A fluid system according to the invention comprises a line system having a first opening cross section for the passage of a fluid, and a second opening cross section, wherein the fluid system comprises a device as described above, which is arranged for closing and / or releasing the second opening cross section in addition to the first opening cross section. The device thus releases a bypass to increase the flow rate from one part of the system to the other part of the system. The system can be used, for example, in conjunction with an additional heat exchanger for heating, but also in conjunction with all other possible applications in which thermal management is necessary.

In a preferred embodiment, the device is arranged in the inflow area and / or in the outflow area of the coolant compensation tank.

BRIEF DESCRIPTION OF THE FIGURES

Figur 1

einen Querschnitt durch eine Fluidleitung mit einem erfindungsgemäßen Verschlusselement;

Figuren 2a, 2b

das Verschlusselement aus Figur 1 in zwei unterschiedlichen Öffnungszuständen;

Figur 3

einen Graphen, der die Öffnungscharakteristik eines konventionellen und eines erfindungsgemäßen Verschlusselements zeigt; und

Figur 4

einen Kühlkreislauf mit einem erfindungsgemäßen Verschlusselement.

Further details of the invention will become apparent from the following description of preferred embodiments and from the drawings. In the drawings, the subject invention is exemplified, it show

FIG. 1

a cross section through a fluid line with a closure element according to the invention;

FIGS. 2a, 2b

the closure element FIG. 1 in two different opening states;

FIG. 3

a graph showing the opening characteristics of a conventional and a closure element according to the invention; and

FIG. 4

a cooling circuit with a closure element according to the invention.

DESCRIPTION OF PREFERRED EMBODIMENTS

The FIG. 1 shows a cross section through a fluid line 1, comprising a channel 2 for the passage of a fluid and a closure element 3 according to the invention, the Flow volume of the fluid through the channel 2 sets. The closure element 3 is fastened by means of a suitable attachment 4.

In the illustration according to the FIG. 1 the channel 2 is completely closed. A bypass 5 ensures that a certain volume flow always flows from the line area in front of the closure element 3 into the line area behind the closure element 3, in order to transport temperature changes in the fluid of a system (for example a cooling water circuit) to the closure element 3.

The closure element 3 changes, as in the FIGS. 2a and 2b represented its geometry as a function of temperature. In the FIG. 2a the closure element 3 is shown in a first state at a temperature below a first threshold temperature T _g1 , which corresponds to a practically completely closed state. In the FIG. 2b the closure element 3 is shown in a second state at a temperature above a second threshold temperature T _g2 (T _g2 greater than or equal to T _g1 ), which corresponds to a virtually maximum open state.

The closure element 3 is formed, for example, as a bimetallic element or from a shape memory material. The material changes its geometry depending on the temperature. In the embodiment according to the FIGS. 2a and 2b This is indicated by a change in position s of the lower edge of the element 3 in the second state relative to its position in the first state.

The FIG. 3 shows a graph indicating the opening characteristics of a conventional (line I) and a closure element according to the invention 3 (line II). In this case, the variable s, as defined above, is shown by way of example as a geometric change relative to the temperature T.

Like from the FIG. 3 can be seen, a conventional bimetal element bends to a certain characteristic, for example, approximately linearly with the temperature (see. FIG. 3 , Line I), while a closure element 3 is formed according to the invention such that in a first state at a temperature below a threshold temperature Tg a practically completely closed state s ₁ (s _{1 is} about zero) is realized while immediately above the threshold temperature Tg a maximum open state s _{2 is} set (see. FIG. 3 , Line II).

This nonlinear behavior with practically two discrete metastable states can be achieved, for example, by a suitable contour 6 (cf. FIG. 2 ) of the surface of the closure element 3 can be adjusted. Accordingly, the surface structure 6 is designed such that the shape of the element changes abruptly with temperature.

FIG. 5 shows a cooling water circuit for cooling a motor 9, which comprises a heat exchanger 7 and an expansion tank 13 for cooling fluid and an engine cooling circuit for cooling a motor 9. The cooling liquid is moved by a water pump 11 for the engine cooling circuit in this.

In the engine cooling circuit is also a thermostat 10 which controls the flow of coolant from the engine cooling circuit via a line 8 in the heat exchanger 7. The thermostat 10 can in any case flow a certain leakage current through the line 8 into the heat exchanger 7. When the temperature rises, the thermostat 10 opens according to a certain characteristic with the temperature rise, so that the flow of cooling fluid through the conduit 8 in the heat exchanger 7 can increase.

From the heat exchanger 7, another line 8 leads back into the engine cooling circuit. In addition, a vent line 14 leads from the heat exchanger 7 in the expansion tank 13. An engine vent line 15 opens, starting from the engine cooling circuit, in the vent line fourteenth

The flowing through the vent line 14 fluid flow is limited by a throttle valve 12, which is a closure element 3, as in connection with the FIGS. 1 to 3 described includes. The closure element 3 forms a flow restriction for flowing through the vent line 14 fluid.

If, after a cold start, the temperature of the coolant in the engine cooling circuit increases, the thermostat 10 opens so that warmer coolant can enter the heat exchanger 7.

About the vent line 14 and the engine vent line 15, a fluid flows in the form of a leakage current (by the in the FIG. 1 shown bypass 5 can flow). This leakage current conveys a fluid in the direction of throttle valve 12 and closure element 3. By a temperature increase in the fluid opens the closure element 3 from a certain limit temperature T _g of a practically closed state (see. FIG. 2a ) in a maximum open state (see. FIG. 2b ).

In this way it is ensured that at a cold start of the engine 9 minimal heat losses occur in the engine cooling circuit, while after reaching a minimum temperature T _{g of} the expansion tank 13 can take its function. The closure element 3 ensures that an optimum characteristic with regard to the inflow of fluid into the expansion tank 13 can be achieved.

The invention is not limited to the illustrated embodiments, which merely exemplify design features. In particular, the invention is not limited to the rectangular design, i. H. Any other geometries can be realized.

Claims (15)

Device (3) for adjusting the flow of a coolant in a cooling circuit, in particular for controlling the coolant flow through a cooling water expansion tank,
characterized in that
the device (3) has at least one first (meta) stable state, which corresponds to a low flow, and has at least one second (meta) stable state, which corresponds to a high flow, wherein the device (3) is designed such that it at a transition of the temperature of the coolant from a first temperature range to a second temperature range from the first (meta) stable state to the second (meta) stable state passes. Device (3) according to claim 1,
characterized in that
the device (3) comprises at least one component which, depending on the temperature of the coolant, assumes either a first geometry which corresponds to the first (meta) stable state or a second geometry which corresponds to the second (meta) stable state. Device (3) according to claim 2,
characterized in that
the component assumes its geometry as a function of the temperature of the coolant flowing through it. Device (3) according to one of the preceding claims,
characterized in that
the device (3) consists wholly or partly of bimetal. Device according to one of the preceding claims,
characterized in that
the device (3) consists wholly or partly of a shape memory material. Device according to one of the preceding claims,
characterized in that
the device (3) has at least one first opening cross section for the flow or for the passage of cooling medium past the device in the first (meta) stable state. Device (3) according to one of the preceding claims,
characterized in that
the device (3) has at least one second opening cross-section for the flow or for the passage of cooling medium past the device in the second (meta) stable state. Device (3) according to claim 7,
characterized in that
the second opening cross section is larger than the first opening cross section. Device (3) according to one of the preceding claims,
characterized in that
the transition from the first (meta) stable state to the second (meta) stable state, and vice versa, is non-linear as a function of the temperature of the coolant. Fluid system (1), comprising at least one line (2) with a first opening cross section for the passage of a fluid,
characterized in that
the fluid system (1) comprises at least one device (3) according to one of the preceding claims 1 to 9, which is arranged for closing and / or for releasing the first opening cross-section. Fluid system (1) according to claim 10,
characterized in that
the fluid system (1) has at least one second opening cross-section (5) for the passage of a fluid in addition to the first opening cross-section, wherein the second opening cross-section (5) is unlocked irrespective of the temperature of the fluid. Coolant circuit, in particular in a motor vehicle,
characterized in that
the coolant circuit comprises at least one device (3) according to one of the preceding claims 1 to 9. Coolant circuit according to claim 12,
characterized in that
the coolant circuit comprises at least one coolant expansion tank (13). Coolant circuit according to claim 13,
characterized in that
the device is arranged in the coolant compensation container (13), in the inflow region and / or in the outflow region of the coolant compensation container (13). Fluid system comprising a conduit system having a first opening cross section for the passage of a fluid, and a second opening cross section,
characterized in that
the fluid system comprises a device (3) according to one of the preceding claims 1 to 9, which is arranged for closing and / or for releasing the second opening cross section in addition to the first opening cross section.

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