DE102017001284B4 - Heat exchanger - Google Patents

Abstract

Heat exchanger (1) with a multiplicity of flow channels (3) for a medium to be temperature-controlled, which are arranged fluidically parallel to one another, each of which is connected on the inlet side to a flow inlet and on the outlet side to a flow outlet (2), at least one of the flow channels (3) having a cross-section adjustment element ( 7) is assigned to adjust the flow cross-section, characterized in that the cross-section adjustment element (7) adjusts the flow cross-section passively depending on a pressure difference of the medium across the cross-section adjustment element (7) and consists at least partially of an elastic material so that it is elastic Nozzle is present, with at least one further of the flow channels (3) being assigned a further cross-section adjustment element (7) for setting the flow cross-section, which is also present as an elastic nozzle and has an elasticity that depends on the elasticity of the Que rschnittsverstellelement (7) forming nozzle is different.

Description

The invention relates to a heat exchanger with a large number of flow channels for a medium to be temperature-controlled, which are arranged fluidically parallel to one another, each of which is connected on the inlet side to a flow inlet and on the outlet side to a flow outlet, with at least one of the flow channels being assigned a cross-section adjustment element for adjusting the flow cross-section.

The heat exchanger is used to transfer heat between several media, namely, for example, from the medium to be tempered to another medium or vice versa. The heat exchanger is preferably designed in such a way that the media are completely separated from one another in terms of flow. This means that the media do not come into contact with one another in terms of flow, at least while they are flowing through the heat exchanger, but only heat is exchanged between them. The heat is transferred from the warmer of the media to the colder of the media. The heat exchanger is used to control the temperature of the medium to be tempered by means of the further medium. The further medium is preferably fed to the heat exchanger at a certain temperature, so that a desired temperature of the medium to be tempered is established on the outlet side of the heat exchanger. This is in particular lower than the temperature of the medium on the inlet side of the heat transfer.

The heat exchanger has several flow channels through which the medium flows during the operation of the heat transfer. The flow inlet and the flow outlet are fluidically connected to one another via the flow channels. In terms of flow, the flow channels run parallel between the flow inlet and the flow outlet. Each of the flow channels is therefore connected on the inlet side to the flow inlet and on the outlet side to the flow outlet. The medium to be tempered is fed to the heat exchanger via the flow inlet and removed at the flow outlet. For example, the flow inlet and / or the flow outlet are each present as a chamber, in particular as an inlet chamber or as an outlet chamber. The flow inlet or the inlet chamber is fluidically connected to an inlet connection of the heat exchanger and the flow outlet or the outlet chamber is connected to an outlet connection of the heat exchanger.

The heat exchanger is present, for example, as a cooler, that is to say it is used to cool the medium to be tempered. For example, the heat exchanger is designed as a charge air cooler. In this case in particular, the heat exchanger is designed for the maximum necessary cooling capacity. Conversely, however, this also means that with a mass flow of the medium to be tempered which is smaller than the mass flow present at the maximum cooling capacity, the effective cooling capacity of the heat exchanger is too high, so that the medium to be tempered is cooled too much. This can lead to the precipitation of condensate within the heat transfer, in particular within the flow channels or at least one of the flow channels.

With a subsequent increase in the mass flow, this condensate is carried along by the medium to be tempered, in particular in the direction of a device to which the medium to be tempered is fed. This device is in the form of an internal combustion engine, for example. If the amount of the entrained condensate is too high, the device, for example the internal combustion engine, can be damaged. For this reason, it is provided that the cross-section adjustment element is assigned to at least one of the flow channels.

The cross-section adjustment element is used to adjust the flow cross-section of the flow channel. Preferably, several of the flow channels, preferably all of the flow channels, are each assigned such a cross-sectional adjustment element. In this case, the respective cross-sectional adjustment element is used to set the flow cross-section of the respective flow channel, in particular only of the respective flow channel.

From the prior art, for example, is the document US 2010/0050997 A1 known. This relates to a charge air cooler for a motor vehicle with a step-charged internal combustion engine. The charge air cooler has an air outlet opening and two air inlet openings, each air inlet opening being assigned a heat exchanger module. Air ducts of the two heat exchanger modules are finally brought together in an air box of the charge air cooler, which is connected to the air outlet opening. This means that compressed charge air from two charging units can only be brought together in the area of the charge air cooler. In order to improve the pressure conditions when only one charging unit is in operation, a non-return valve is provided in an air duct. Thus, a module for a separate merging of the airways can be saved, which reduces the installation space requirement.

The document also shows DE 38 11 852 A1 a vertical type heat exchanger in which a fluid flows vertically downward. The heat exchanger has a cylindrical housing which is divided by upper and lower tube plates into an upper water chamber, a lower water chamber and a heat exchange passage therebetween. In the heat exchange passage, a plurality of metallic exchanger tubes are arranged parallel to one another, the two ends of which are held by the upper and lower tube plates, respectively. A plurality of metallic fluid flow throttle bodies adjustably contact a lower end surface of the exchanger tubes, these throttle bodies being inserted into the lower mouth of the respective exchanger tube. Each throttle body is provided with a thin bore for throttling the fluid flow, an upper tapered part for insertion into the relevant exchanger tube mouth and a lower cylinder part, the tapered part touching the end face of the exchanger tube with a surface area so that a sealing metal contact is created when the throttle body is inserted into the exchanger tube.

The publication also describes DE 43 09 360 A1 a heating heat exchanger for motor vehicles with a bundle of parallel, ribbed heat exchanger tubes, as well as with at least one water tank which has a tube base on which the ends of the tubes at one end of the bundle are each outside and inside with a press fit, with the free cross section of the in the end of the respective tube protruding from the tube sheet protrudes in each case an insert piece which is designed as an element which acts on the flow behavior of the flowing medium in the tube.

It is the object of the invention to propose a heat exchanger which has advantages over known heat exchangers, in particular has a simple structure and enables the flow cross-section to be set reliably by means of the cross-section adjustment element.

According to the invention, this is achieved with a heat exchanger having the features of claim 1. It is provided that the cross-section adjustment element passively adjusts the flow cross-section depending on a pressure difference of the medium via the cross-section adjustment element and consists at least partially of an elastic material so that it is present as an elastic nozzle, with at least one further of the flow channels having a further cross-section adjustment element for adjusting the flow cross-section is assigned, which is also present as an elastic nozzle and has an elasticity that is different from the elasticity of the nozzle forming the cross-section adjustment element.

It is therefore not intended to actively control the cross-section adjustment element by means of an actuator. Rather, the cross-section adjustment element should work passively and automatically adjust the flow cross-section as a function of the pressure element of the medium via the cross-section adjustment element. The pressure difference of the medium across the cross-section adjustment element is to be understood as the difference between the pressure immediately upstream of the cross-section adjustment element and the pressure immediately downstream of the cross-section adjustment element. With a smaller pressure difference, the cross-section adjustment element sets a smaller flow cross-section than with a larger pressure difference. In other words, the cross-section adjustment element increases the flow cross-section as the pressure difference increases.

The cross-section adjustment element is preferably designed in such a way that the flow cross-section increases steplessly as the pressure difference increases. Alternatively, however, a discrete setting of the flow cross-section can of course also be provided, within the framework of which the cross-section adjustment element only enables the setting of at least two different flow cross-sections which are different from and spaced apart from one another.

In order to enable a particularly precise passive setting of the flow cross-section, the cross-section adjustment element is designed as an elastic nozzle. The cross-section adjustment element thus has a nozzle shape, at least at times. In other words, this means that the flow cross-section of the cross-sectional adjustment element changes, preferably becomes smaller, in the flow direction. In the longitudinal section through the cross-section adjustment element, it can be provided, for example, that the flow cross-section is reduced to zero at a pressure difference which is smaller than a first pressure difference, so that the cross-section adjustment element has a flow cross-section of greater than zero on its side facing the flow inlet, which reduced to zero in the direction of the flow outlet.

If, on the other hand, the pressure difference exceeds a second pressure difference, which is greater than zero, it can be provided that the flow cross-section of the cross-section adjustment element decreases in the flow direction, but always has a flow cross-section different from zero in the flow direction, or alternatively a flow cross-section that is constant in the flow direction. In the latter case, it is particularly preferred that in a Pressure difference of greater than or equal to the first pressure difference and less than or equal to the second pressure difference, the cross-section adjustment element has the flow cross-section which decreases in the direction of flow, that is to say is essentially nozzle-shaped.

The design as an elastic nozzle is basically to be understood as meaning that the cross-section adjustment element consists at least partially of an elastic material, for example an elastomer, rubber or the like, and seen at least in section, in particular in longitudinal section, at least temporarily a flow cross-section that decreases in the direction of flow having. This enables a targeted adjustment of the mass flow of the medium to be tempered through the heat exchanger as a function of the pressure difference across the cross-section adjustment element. The temperature control output or the cooling output of the heat exchanger is adjusted as required.

Another embodiment of the invention provides that the flow channels can be flowed around by a further medium for temperature control of the medium. The further medium has already been referred to above. This serves to control the temperature of the medium to be tempered and is completely separated from it in terms of flow. To exchange the heat between the media, the medium to be tempered can flow through the flow channels and the further medium can flow around them.

Another embodiment of the invention provides that the cross-section adjustment element has flap elements running parallel to one another. The flap elements are at least partially spaced apart from one another when viewed in longitudinal section. In order to achieve a flow cross-section of zero, given mass flows or pressure differences of the medium may be in contact with one another, in particular with a pressure difference that is smaller than the aforementioned first pressure difference.

A preferred further embodiment of the invention provides that the flap elements are connected to one another on both sides via a connecting element. On each of the flap elements there is therefore on the one hand a first connecting element and on the other hand a second connecting element. Each of these connecting elements engages on the one hand on a first of the flap elements and on the other hand on a second of the flap elements, so that the flap elements are connected to one another via both connecting elements. The connecting elements and the flap elements are preferably designed in one piece and / or made of the same material, in particular they consist of the same elastic material.

Another embodiment of the invention provides that the connecting elements each have a predetermined kink located between the flap elements. The connecting elements are designed to bend at the predetermined kink point, in particular to bend in the direction of a longitudinal center axis of the cross-sectional adjustment element. The predetermined kink is preferably arranged at a distance from both flap elements, in particular it lies centrally between them. The intended kink point can be in the form of a desired kink line, which preferably lies parallel to the longitudinal center axis of the cross-sectional adjustment element or is at the same distance from both flap elements at each point in the direction of flow.

A particularly preferred embodiment of the invention provides that the intended kinks can be displaced towards one another when the connecting elements are bent at the intended kinks, so that the connecting elements have a first distance from one another with a first flow cross section and a second distance from one another with a second flow cross section. For the sake of completeness, it should be pointed out that the first flow cross section is different from the second flow cross section. This also applies to the first distance and the second distance. By kinking the connecting elements, the cross-section adjustment element having the valve element and the connecting elements functions in the manner of a heart valve.

For example, each of the connecting elements has a first section at its intended kink and a second section at its intended kink. In the case of different flow cross-sections, these sections are now angled differently to one another. This means that there is a first angle between the sections in the case of the first throughflow cross section and a second angle in the case of the second throughflow cross section. These two angles are different from each other. For example, with a correspondingly large flow cross section, in particular with the maximum possible flow cross section, one of the angles is 180 °, so that the two sections are aligned with one another, that is, they are in extension of one another.

A further development of the invention provides that the connecting elements are designed in one piece and / or with the same material as the flap elements. Such a design has already been pointed out. The material used for the connecting elements and the flap elements is elastic material provided, for example an elastomer, rubber or the like.

Another embodiment of the invention provides that the cross-section adjustment element overlaps the entire cross-section of the respective flow channel. This is particularly the case if the cross-section adjustment element adjoins that flow channel on the side of the flow inlet or side of the flow outlet. Alternatively, it can of course be provided that the cross-section adjustment element is arranged in the flow channel. In this case, in particular, it is provided that the cross-section adjustment element encompasses the entire cross-section of the respective flow channel.

Another embodiment of the invention provides that the flow channels are rectangular when viewed in cross section. The rectangular shape is realized in that each of the flow channels is bordered by at least four edges, seen in cross section, two of the edges being arranged parallel to one another and being perpendicular to the other two or enclosing a right angle with them. The edges can be spaced from one another. It is therefore not necessary for edges that are angled to one another, in particular edges that are perpendicular to one another, to come into direct contact with one another. Rather, they can be present at a distance from one another and, for example, be connected to one another via an arc, for example a round arc or circular arc. The edges of the flow channel which are angled towards one another can have different dimensions. Alternatively, they can also have the same dimensions, so that the flow channel is square in cross section. Of course, other geometric configurations of the flow channels can also be implemented. For example, when viewed in cross section, the flow channels are round, oval or polygonal.

According to the invention it is provided that at least one further of the flow channels is assigned a further cross-sectional adjustment element for setting the flow cross-section, which is also present as an elastic nozzle and has an elasticity that is different from the elasticity of the nozzle forming the cross-sectional adjustment element. In other words, the heat exchanger has a plurality of cross-sectional adjustment elements, namely at least the at least one cross-sectional adjustment element and the at least one further cross-sectional adjustment element.

At least some of the plurality of cross-sectional adjustment elements preferably have elasticities that differ from one another, so that they set different flow cross-sections with the same pressure difference. It can therefore be provided that at the first pressure difference the cross-section adjustment element already sets a flow cross-section of greater than zero, while the further cross-section adjustment element completely closes the further flow channel, i.e. has a flow cross-section of zero.

If there is a multiplicity of cross-sectional adjustment elements, cross-sectional adjustment elements that are directly adjacent to one another preferably have elasticities that differ from one another. In particular, the elasticity decreases steadily in a certain direction starting from one of the cross-section adjustment elements. It is particularly preferred here that the cross-section adjustment elements are arranged symmetrically. A centrally arranged cross-section adjustment element therefore has a certain elasticity. This cross-sectional adjustment element is adjoined on both sides by a cross-sectional adjustment element, in particular a plurality of cross-sectional adjustment elements. The elasticity of these adjoining cross-sectional adjustment elements increases or decreases continuously based on the elasticity of the centrally arranged cross-sectional adjustment element.

• 1 eine schematische Darstellung eines Bereichs eines Wärmeübertragers, sowie
• 2-6 Querschnittsverstellelemente des Wärmeübertragers bei unterschiedlichen Druckdifferenzen.

The invention is explained in more detail below with reference to the exemplary embodiments shown in the drawing, without restricting the invention. It shows

• 1 a schematic representation of a region of a heat exchanger, as well as
• 2-6 Cross-section adjustment elements of the heat exchanger at different pressure differences.

The 1 shows a heat exchanger 1 in a schematic representation. The heat exchanger 1 is used to control the temperature of a medium to be tempered, which flows through a flow inlet of the heat exchanger, not shown here 1 fed and at a flow outlet 2 of the heat exchanger 1 is removed.

The flow inlet and the flow outlet 2 are via a large number of flow channels arranged in parallel to one another in terms of flow technology 3 connected to one another, of which only a few are indicated here by way of example. The flow channels 3 lie in flow tubes 4th in front. In each of the flow channels 3 are preferred (optional) surface enlargement elements 5 arranged (only marked as an example).

The flow channels 3 or the flow tubes 4th another medium can flow around them. To do this, limit the flow tubes 4th with each other further flow channels 6th for the further medium. Also in the other flow channels 6th surface enlarging elements can be arranged. These are shown, but not marked separately.

At least one of the flow channels 3 is a cross-section adjustment element 7th assigned. In the exemplary embodiment shown here, a plurality of the flow channels are 3 each associated with such a cross-sectional adjustment element. For example, there are several flow channels that are immediately adjacent to one another 3 each with such a cross-sectional adjustment element 7th Mistake. The cross-section adjustment elements 7th can in particular in this case be designed in one piece and / or made of the same material with one another and / or jointly on the flow channels 3 or the flow tubes 4th be attached.

Each of the cross-section adjustment elements 7th is on the outlet side of the flow channel 3 provided, so on its the flow outlet 2 facing side. The cross-section adjustment element 7th represents the flow cross section of the respective flow channel 3 passive as a function of a pressure difference in the medium across the cross-section adjustment element 7th and is also designed as an elastic nozzle. Only one of the cross-section adjustment elements is referred to below 7th entered into more detail. However, the explanations apply to all of the cross-section adjustment elements 7th transferable.

The cross-section adjustment element has flap elements running parallel to one another 8th and 9 on. These are via fasteners 10 and 11 each connected to each other. Each of the fasteners 10 and 11 thus engages on the one hand on the flap element 8th and on the flap element 9 at. The fasteners 10 and 11 each have one between the flap elements 8th and 9 lying predetermined kink 12th on. They are designed in such a way that they are at the intended kink 12th in the direction of the other connecting element 11 respectively 10 can buckle. In other words, the intended kinks are 12th if the fasteners buckle 10 and 11 at the intended kinks 12th displaceable towards each other. The buckling of the fasteners 10 and 11 takes place in particular in such a way that it is between the flap elements in areas 8th and 9 intervene, especially if the cross-section adjustment element 7th sets a minimum flow cross-section, in particular the flow channel 3 Completely blocked in terms of flow.

The several cross-section adjustment elements shown here 7th have different elasticities. In particular, the centrally present cross-section adjustment element has 7th via the lowest elasticity, whereas the elasticity is outwardly on both sides of the cross-section adjustment element 7th subsequent cross-section adjustment elements 7th continuously decreases, so that the furthest from the central cross-section adjustment element 7th spaced cross-section adjustment element 7th the highest elasticity of the cross-section adjustment elements 7th having. The elasticities of the cross-section adjustment elements are preferred 7th symmetrical, so that the cross-section adjustment elements 7th on both sides of the central cross-section adjustment element 7th at the same distance from this also have the same elasticity.

How the heat exchanger works 1 is based on the 2-6 explained. In the 2 is the heat exchanger for a pressure difference in the medium across the cross-section adjustment elements 7th shown, which is smaller than a first pressure difference. In this case, the cross-section adjustment elements 7th set to a minimum flow cross-section, in particular a flow cross-section of zero. Correspondingly, the medium to be tempered can only pass through the flow channels that are too extreme 3 flow through.

Based on the one in the 2 the state shown, the pressure difference now increases over the in the 3 , 4th , 5 and 6th states shown steadily until in the 6th the state shown the cross-section adjustment 7th are fully open, the flap members 8th and 9 are preferably arranged parallel to one another, so that the flow cross-section of the cross-sectional adjustment elements 7th in the flow direction the medium remains constant or at least almost constant.

It can be seen that the outer cross-section adjustment elements are first 7th open, so the furthest from the central cross-section adjustment element 7th remote cross-section adjustment elements 7th because they have the highest elasticity. As the pressure difference increases, the cross-section adjustment elements now give 7th more and more of the flow channels 3 free until where in the 6th shown condition of all flow channels 3 are completely released for flow.

With such a design of the heat exchanger 1 a reliable passive setting of a suitable flow cross-section can be realized, which depends on the pressure difference of the medium. To this extent, excessive cooling of the medium to be tempered is avoided, so that condensate accumulates in the flow channels 3 is largely prevented. It also prevents condensate from being suddenly discharged. This causes damage to the flow to the heat exchanger 1 connected device avoided to which the temperature-controlled fluid is fed. The device is designed, for example, as an internal combustion engine.

Claims (9)

Heat exchanger (1) with a plurality of flow channels (3) for a medium to be temperature-controlled, which are arranged fluidically parallel to one another, each of which is connected on the inlet side to a flow inlet and on the outlet side to a flow outlet (2), with at least one of the flow channels (3) having a cross-section adjustment element ( 7) is assigned to set the flow cross-section, characterized in that the cross-section adjustment element (7) adjusts the flow cross-section passively depending on a pressure difference of the medium across the cross-section adjustment element (7) and consists at least partially of an elastic material so that it is elastic Nozzle is present, with at least one further of the flow channels (3) being assigned a further cross-sectional adjustment element (7) for setting the flow cross-section, which is also present as an elastic nozzle and has an elasticity that depends on the elasticity of the Qu cutting adjustment element (7) forming nozzle is different. Heat exchanger after Claim 1 , characterized in that the flow channels (3) can be flowed around by a further medium for temperature control of the medium. Heat exchanger according to one of the preceding claims, characterized in that the cross-section adjustment element (7) has flap elements (8, 9) running parallel to one another. Heat exchanger after Claim 3 , characterized in that the flap elements (8, 9) are connected to one another on both sides via a connecting element (10, 11). Heat exchanger after Claim 4 , characterized in that the connecting elements (10, 11) each have a predetermined kink (12) located between the flap elements (8, 9). Heat exchanger after Claim 5 , characterized in that the predetermined kinks (12) can be displaced towards one another when the connecting elements (10, 11) are bent at the predetermined kinks (12), so that the connecting elements (10, 11) have a first distance in the case of a first flow cross-section and a second distance Have flow cross-section a second distance from one another. Heat exchanger after Claim 5 or 6th , characterized in that the connecting elements (10, 11) are designed in one piece and / or made of the same material with the flap elements. Heat exchanger according to one of the preceding claims, characterized in that the cross-section adjustment element (7) overlaps the entire cross-section of the respective flow channel (3). Heat exchanger according to one of the preceding claims, characterized in that the flow channels (3) are rectangular, round, oval or polygonal when viewed in cross section.

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