Vehicle tank for receiving a liquid medium, and vehicle having such a vehicle tank

Abstract

A vehicle tank for receiving a liquid medium, encompassing: a tank body having a tank wall; a heat exchanger arranged in an interior of the tank body, the heat exchanger having a first heat-exchanger heat delivery surface that faces toward the tank wall and is spaced away from the tank wall; and an electric heating apparatus that is arranged in the interior of the tank body, the electric heating apparatus being arranged between the first heat-exchanger heat delivery surface and the tank wall.

Claims

1. A vehicle tank for receiving a liquid medium, encompassing: a tank body having a tank wall; a heat exchanger arranged in an interior of the tank body, the heat exchanger being planar and having an external shape of a plate; the heat exchanger comprising a first heat-exchanger heat delivery surface that faces toward the tank wall and is spaced away from the tank wall; and an electric heating apparatus that is arranged in the interior of the tank body, wherein the electric heating apparatus is arranged between the first heat-exchanger heat delivery surface and the tank wall.

2. The vehicle tank according to claim 1, wherein a gap that defines a gap thickness direction being embodied between the first heat-exchanger heat delivery surface and the tank wall, the vehicle tank having a reference direction proceeding parallel to the gap thickness direction; when the vehicle tank is installed as intended in an associated vehicle, the reference direction extending parallel to a vehicle reference direction, the vehicle reference direction being substantially parallel to the effective direction of gravity in a normal position of the associated vehicle, the associated vehicle, in the normal position in an operationally ready state, standing on a flat surface that extends perpendicularly to the effective direction of gravity.

3. The vehicle tank according to claim 2, wherein the electric heating apparatus comprising a first heating-apparatus heat delivery surface facing toward the first heat-exchanger heat delivery surface; and a projection of the first heat-exchanger heat delivery surface in the reference direction at least partly overlapping the first heating-apparatus heat delivery surface in an overlap region of the first heating-apparatus heat delivery surface.

4. The vehicle tank according to claim 3, wherein the electric heating apparatus comprising a second heating-apparatus heat delivery surface arranged oppositely from the first heating-apparatus heat delivery surface; and a ratio of a first maximally occurring spacing between the second heating-apparatus heat delivery surface and the tank wall to a second maximally occurring spacing between the overlap region and the first heat-exchanger heat delivery surface being less than 5.

5. The vehicle tank according to claim 3, wherein the first heat-exchanger heat delivery surface and/or the first heating-apparatus heat delivery surface extending transversely to the reference direction.

6. The vehicle tank according to claim 2, wherein the electric heating apparatus comprising a heating-apparatus opening which is embodied in a thickness direction of the electric heating apparatus and whose projection in the reference direction overlaps with a withdrawal arrangement of the vehicle tank.

7. The vehicle tank according to claim 6, wherein the heat exchanger having a heat-exchanger opening which is embodied in a thickness direction of the heat exchanger and whose projection in the reference direction overlaps with a withdrawal arrangement of the vehicle tank and wherein the projection of the heating-apparatus opening in the reference direction and the projection of the heat-exchanger opening in the reference direction having a common overlap with the withdrawal arrangement.

8. The vehicle tank according to claim 2, wherein the heat exchanger having a heat-exchanger opening which is embodied in a thickness direction of the heat exchanger and whose projection in the reference direction overlaps with a withdrawal arrangement of the vehicle tank.

9. The vehicle tank according to claim 2, wherein the first heat-exchanger heat delivery surface and/or a first heating-apparatus heat delivery surface extending transversely to the reference direction.

10. The vehicle tank according to claim 2, wherein the vehicle tank furthermore encompassing a withdrawal arrangement, arranged on the tank body, for withdrawing an associated liquid medium from the tank body; and the electric heating apparatus surrounding the withdrawal arrangement at least in portions.

11. The vehicle tank according to claim 10, wherein the electric heating apparatus comprising a heating-apparatus opening which is embodied in a thickness direction of the electric heating apparatus and whose projection in the reference direction overlaps with the withdrawal arrangement.

12. The vehicle tank according to claim 11, wherein the heat exchanger having a heat-exchanger opening which is embodied in a thickness direction of the heat exchanger and whose projection in the reference direction overlaps with the withdrawal arrangement and wherein the projection of the heating-apparatus opening in the reference direction and the projection of the heat-exchanger opening in the reference direction having a common overlap with the withdrawal arrangement.

13. The vehicle tank according to claim 10, wherein the heat exchanger having a heat-exchanger opening which is embodied in a thickness direction of the heat exchanger and whose projection in the reference direction overlaps with the withdrawal arrangement.

14. The vehicle tank according to claim 1, wherein the heat exchanger comprising a thermal-fluid inlet, a thermal-fluid outlet, and a heating conduit, proceeding between the thermal-fluid inlet and the thermal-fluid outlet, for carrying an associated thermal fluid; and the heat exchanger comprising a heat-exchanger opening embodied in a thickness direction of the heat exchanger; a portion of the heating conduit closest to the heat-exchanger opening having a spacing from the thermal-fluid inlet which is less than its spacing from the thermal-fluid outlet, the spacing being determined in each case along a thermal-fluid flow path in the heating conduit.

15. The vehicle tank according to claim 1, wherein the electric heating apparatus encompassing PTC elements.

16. The vehicle tank according to claim 1, wherein the heat exchanger comprising a thermal-fluid inlet, a thermal-fluid outlet, and a heating conduit, proceeding between the thermal-fluid inlet and the thermal-fluid outlet, for carrying a thermal fluid along a thermal-fluid flow path; the heat exchanger comprising a heat-exchanger opening embodied in a thickness direction of the heat exchanger; and the heating conduit encompassing at least two extent portions located one behind another in a radial direction of the heat-exchanger opening, in which portions the thermal-fluid flow path proceeds transversely to the radial direction of the heat-exchanger opening.

17. The vehicle tank according to claim 1, wherein the heat exchanger comprising a thermal-fluid inlet, a thermal-fluid outlet, and a heating conduit, proceeding between the thermal-fluid inlet and the thermal-fluid outlet, for carrying a thermal fluid; and the heat exchanger comprising a heat-exchanger opening embodied in a thickness direction of the heat exchanger; the heat exchanger encompassing a winding section that encompasses a first extent portion of the heating conduit, a redirecting portion of the heating conduit, and a second extent portion of the heating conduit, which together constitute a continuous portion of the heating conduit which is continuously passable for the thermal fluid along a thermal-fluid flow path proceeding in the winding section; when a thermal-fluid flow is present in the winding section, a first direction of the thermal-fluid flow in the first extent portion pointing away from a second direction of the thermal-fluid flow in the second extent portion.

18. The vehicle tank according to claim 1, wherein the heat exchanger having a virtual heat-exchanger envelope; the heat-exchanger envelope being a three-dimensional body whose outer surface encompasses and/or is constituted by a first heat-exchanger envelope surface, a second heat-exchanger envelope surface arranged oppositely from the first heat-exchanger envelope surface, and a heat-exchanger envelope periphery surface connecting the first heat-exchanger envelope surface and the second heat-exchanger envelope surface; an extent of the heat-exchanger envelope along each of two mutually perpendicular surface directions that each proceed, at a point on the first heat-exchanger envelope surface, tangentially to the first heat-exchanger envelope surface, being several times greater than an extent of the heat exchanger in a thickness direction of the heat exchanger.

19. A vehicle having a vehicle tank for receiving a liquid medium, wherein the vehicle tank is embodied as a vehicle tank according to claim 2; the vehicle having a vehicle reference direction substantially parallel to the effective direction of gravity with the vehicle in a normal position; the vehicle in the normal position standing on a flat surface that extends perpendicularly to the effective direction of gravity; and the reference direction of the vehicle tank coinciding with the vehicle reference direction.

20. The vehicle tank according to claim 1, wherein the tank wall is a tank bottom.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) The invention may take physical form in certain parts and arrangement of parts, a preferred embodiment of which will be described in detail and illustrated in the accompanying drawings which forms a part hereof and wherein:

(2) FIG. 1 is a schematic cross section of an embodiment of a vehicle tank according to the present invention;

(3) FIG. 2 is a view, in a direction opposite to a reference direction, of an embodiment of an electric heating apparatus and of a heat exchanger, which can be used individually or together in the embodiment of FIG. 1;

(4) FIG. 3 is a schematic view of a cross section of an embodiment of the heat exchanger of FIG. 2;

(5) FIG. 4 is a schematic view of a cross section of a further embodiment of the heat exchanger of FIG. 2;

(6) FIG. 5 is an enlarged partial view of the cross section of FIG. 4; and

(7) FIG. 6 is a schematic view of a vehicle according to the present invention in a normal position.

DESCRIPTION OF PREFERRED EMBODIMENTS

(8) Referring now to the drawings wherein the showings are for the purpose of illustrating preferred and alternative embodiments of the invention only and not for the purpose of limiting the same, FIG. 1 shows a vehicle tank 20 for receiving a liquid medium (not shown) such as water or an aqueous urea solution. Vehicle tank 20 encompasses a tank body 22 having a tank bottom 24 that is an embodiment of a tank wall, as well as a heat exchanger 26 and an electric heating apparatus 28 arranged in the interior of the tank body. Electric heating apparatus 28 is arranged spaced away from tank bottom 24, and is retained in that position by struts or pegs 30a to 30d. Heat exchanger 26 is likewise arranged spaced away from tank bottom 24 and from the remainder of tank 20, and is retained in that position by pegs or struts 32a and 32b. Heat exchanger 26 preferably proceeds parallel to tank bottom 24 and/or to electric heating apparatus 28, which preferably also proceeds parallel to tank bottom 24. Arranged on tank bottom 24 are struts 34a, 34b that can stiffen the tank bottom and can reduce a sloshing motion of the liquid medium.

(9) The tank bottom comprises a vehicle tank sump 36, embodied as a depression, at whose deepest point is provided a withdrawal apparatus 38, embodied as a filter and arranged at the end of a schematically depicted withdrawal conduit 41, for withdrawing the liquid medium from tank 20.

(10) When vehicle tank 20 is installed as intended in a vehicle standing on a flat and horizontally arranged surface, a reference direction 40 of vehicle tank 20 preferably proceeds parallel to the effective direction of gravity and is aligned with the effective direction of gravity. Heat exchanger 26, electric heating apparatus 28, and tank bottom 24 are arranged successively to one another in the reference direction, preferably oriented transversely or perpendicularly to reference direction 40, so that heating apparatus 28 is arranged between heat exchanger 26 and tank bottom 24. Heat exchanger 26 comprises a first heat-exchanger heat delivery surface 42 that is spaced away from tank bottom 24 and faces toward electric heating apparatus 28. Electric heating apparatus 28 is arranged in a gap 44 which is arranged between first heat-exchanger heat delivery surface 42 and tank bottom 24, and which defines a gap thickness direction 45 that is preferably parallel to reference direction 40 and is preferably perpendicular respectively to tank bottom 24 and/or to first heat-exchanger heat delivery surface 42 and to electric heating apparatus 28.

(11) Electric heating apparatus 28 and heat exchanger 26 can each be embodied substantially as a planar body, in particular substantially as a planar cuboid.

(12) Electric heating apparatus 28 comprises a heating-apparatus opening 46 embodied in its thickness direction, and heat exchanger 26 comprises a heat-exchanger opening 48 embodied in its thickness direction, which align when viewed in the reference direction and are preferably each embodied as a cylindrical opening. When viewed in reference direction 40, heating-apparatus opening 46 surrounds withdrawal apparatus 38, which can extend parallel to reference direction 40 sufficiently far that it passes through heating-apparatus opening 46. In this case as well, in which an object passes through an opening, the projection of that opening in the reference direction is intended to be regarded as overlapping with that object.

(13) If first heat-exchanger heat delivery surface 42 is projected in the reference direction onto a first heating-apparatus heat delivery surface 50, facing toward it, of electric heating apparatus 28, that projection completely overlaps first heating-apparatus heat delivery surface 28 and thus defines, on the entire first heating-apparatus heat delivery surface 50, an overlap region of that surface.

(14) Struts or pegs 30a to 30b and struts or pegs 32a and 32b are dimensioned in terms of length in such a way that spacing A1 between a second heating-apparatus heat delivery surface 52 and tank bottom 24 outside vehicle tank sump 36 is equal to approximately 10 mm, and spacing A2 between first heat-exchanger heat delivery surface 42 and first heating-apparatus heat delivery surface 50, constituting the overlap region, is equal to approximately 15 mm. Because the inner surface of tank bottom 24, outside vehicle tank sump 36; first heat-exchanger heat delivery surface 42; second heating-apparatus heat delivery surface 52; and first heating-apparatus heat delivery surface 50 are preferably oriented in parallel fashion, the aforementioned spacings also indicate the maximum spacings.

(15) If heat-exchanger opening 48 is projected in reference direction 40, the projection operation can proceed from a cross-sectional surface 54 of that opening which is defined by a plane 56 proceeding perpendicularly to the drawing plane of FIG. 1. The edge rays of the projected image are indicated by dashed lines. This projection overlaps both with withdrawal apparatus 38 and with heating-apparatus opening 46; what is regarded as the target surface in the context of projection onto heating-apparatus opening 46 is the latter's cross-sectional surface 58 that is defined by a plane 60 proceeding perpendicularly to the drawing plane of FIG. 1. The projection of heating-apparatus opening 46 in reference direction 40 (which can be based on cross-sectional surface 58) also overlaps with withdrawal apparatus 38. Because heating-apparatus opening 46 aligns with heat-exchanger opening 48 when viewed in reference direction 40, their projections onto withdrawal apparatus 38 overlap completely.

(16) Power connectors 62a, 62b to electric heating apparatus 28, and a cooling-water inflow 64a and cooling-water outflow 64b to the heat exchanger, are depicted merely schematically in FIG. 1 and in the further Figures, and a plurality of power connectors, and a plurality of cooling-water inflows and cooling-water outflows on the heat exchanger, can be provided.

(17) FIG. 2 is a view, oppositely from reference direction 40, toward a possible embodiment of heat exchanger 26 and electric heating apparatus 28 shown in FIG. 1. The overlap region of first heating-apparatus heat delivery surface 50 is, however, smaller than the entire first heating-apparatus heat delivery surface 50, as is readily apparent.

(18) Electric heating apparatus 28 encompasses a plurality of electrically interconnected PTC thermistors constituting heating elements 66, only a few of the heating elements being labeled with a reference character in the interest of clarity. In order to receive pegs, such as pegs 30a to 30d, for retaining heating apparatus 28, corresponding receptacles 68 are provided in electric heating apparatus 28 that is embodied as a plate, and thus in particular in planar fashion. Corresponding receptacles 69 for receiving pegs, such as pegs 32a, 32b, for retaining heat exchanger 26 are provided on heat exchanger 26.

(19) Heat exchanger 26 is embodied from two separate individual parts 26a and 26b, and has a heat-exchanger opening 48 that is delimited by individual parts 26a and 26b and by two plane segments 70a and 70b that proceed perpendicularly to the drawing plane of FIG. 2 and connect the respective individual parts 26a and 26b to one another.

(20) Each of the individual heat-exchanger parts 26a, 26b comprises a thermal-fluid inlet 72a, 72b, a thermal-fluid outlet 74a, 74b, and a heating conduit 76a, 76b that proceeds between the respective thermal-fluid inlet 72a, 72b and the respective thermal-fluid outlet 74a, 74b. Individual heat-exchanger parts 26a, 26b are embodied substantially mirror-symmetrically with respect to a plane 80 proceeding perpendicularly to the drawing plane of FIG. 2, so that only individual part 26a will be described in further detail below, and the description also applies to individual part 26b. A thermal-fluid inlet and/or thermal-fluid outlet can be embodied with a metal reinforcement.

(21) Innermost portion 82a of heating conduit 76a proceeds along a periphery of heat-exchanger opening 48. Since thermal-fluid inlet 72a is embodied directly on innermost portion 82a, its spacing from thermal-fluid inlet 72a along the thermal-fluid flow path proceeding in heating conduit 76a is less than from thermal-fluid outlet 74a. The heating conduit can have an inside diameter of 6 mm, a wall thickness of 1.7 mm, and a minimum radius of curvature greater than or equal to 8 mm.

(22) Heating conduit 76a encompasses extent portions 84a1 to 84a8, of which respective pairs 84a1 and 84a2; 84a2 and 84a3; 84a3 and 84a4; 84a4 and 84a5; 84a5 and 84a6; 84a6 and 84a7; and 84a7 and 84a8 are each made up of extent portions directly adjacent with reference to a radial direction R of the periphery of heat-exchanger opening 48. In such a pair, the thermal-fluid flow path of the thermal fluid proceeds in the respective individual extent portions transversely, preferably perpendicularly, to radial direction R, as indicated in extent portions 84a2 and 84a3 by arrows S1 and S2.

(23) A pair of directly adjacent extent portions is connected by a respective redirecting portion 86, and constitutes with it a winding section that is continuously passable for the thermal fluid and thus also for its thermal-fluid flow path, two adjacent winding sections each comprising a shared extent portion. In a winding section, the thermal fluid flows in the extent portions respectively in directions pointing away from one another (see arrows S1 and S2), the directions enclosing an angle of at least 135 to 180°, in FIG. 2 substantially 180°.

(24) FIG. 3 schematically depicts a cross section T-T of heat exchanger 26 of FIG. 2, only the sectioned surfaces of the extent portions being depicted. To ensure clarity, shading of the sectioned surfaces has been omitted in FIG. 3 and in FIGS. 4 and 5.

(25) Each individual part 26a and 26b of the heat exchanger can be completely enclosed by a cuboidally shaped virtual heat-exchanger envelope 90a, 90b that is indicated with dotted lines in FIG. 3. A virtual heat-exchanger envelope can also be assembled from the two cuboidally shaped virtual heat-exchanger envelopes 90a, 90b. Because of the mirror symmetry with respect to plane 80 of heat exchanger 26, that symmetry also transfers to envelopes 90a, 90b, so that once again only envelope 90a will be described and those statements also apply to envelope 90b.

(26) Heat-exchanger envelopes 90a, 90b each have an outer surface 92 having a first heat-exchanger envelope surface 94, a second heat-exchanger envelope surface 96 arranged oppositely from first heat-exchanger envelope surface 94, and a heat-exchanger envelope periphery surface 98 connecting the first heat-exchanger envelope surface and the second heat-exchanger envelope surface. These surfaces are each merely indicated in FIG. 3, but the shape of a cuboid is known. If the virtual heat-exchanger envelope is assembled from virtual heat-exchanger envelopes 90a, 90b, then the first heat-exchanger envelope surface is assembled from the first heat-exchanger envelope surfaces of heat-exchanger envelopes 90a, 90b, the second heat-exchanger envelope surface is assembled from the second heat-exchanger envelope surfaces of heat-exchanger envelopes 90a, 90b, and the same is analogously the case for the heat-exchanger envelope periphery surface.

(27) The extent of the heat-exchanger envelope in the X direction that is depicted, which proceeds parallel to the first heat-exchanger envelope surface, is more than three times greater than the extent of the heat-exchanger envelope in the Z direction that is depicted. The same is true of the ratio of the extent of the heat-exchanger envelope in the Y direction proceeding perpendicularly to the drawing plane of FIG. 3.

(28) Heat-exchanger envelope 90a, 90b proceeds tangentially to points on the extent portions at which they contact the latter. Those points are part of the first heat-exchanger heat delivery surface and of a second heat-exchanger heat delivery surface 91, arranged oppositely from the first heat-exchanger heat delivery surface, of heat exchanger 26.

(29) FIG. 4 schematically depicts a cross section T-T of an embodiment of heat exchanger 26 of FIG. 2 having an alternative arrangement of extent portions in a Z direction, only the sectioned surfaces of the extent portions being depicted. Those reference characters which identify elements embodied differently from the embodiment of FIG. 3 have been marked with an apostrophe ('). With regard to the remainder of the configuration, reference is made explicitly to the statements regarding FIGS. 1 to 3, which apply here as well. Parts 26a′ and 26b′ of the heat exchanger are mirror-symmetrical in the embodiment of FIG. 4 as well, but that need not be the case.

(30) Considering a triplet of three extent portions 84a1′, 84a2′, 84a3′ adjacent in a radial direction of the heat-exchanger opening, it encompasses two pairs 84a1′ and 84a2′, and 84a2′ and 84a3′, of extent portions directly adjacent to one another. The sectioned surfaces resulting from the T-T section which are shown proceed perpendicularly to the thermal-fluid flow path in heating conduit 76a, and define respective cross-sectional surfaces of the heating conduit having surface center points 100a1 to 100a3. Respective straight line segments 102 and 104, which intersect at an angle of 6.5° as shown in the enlargement of FIG. 4 shown in FIG. 5, extend between surface center points 100a1 and 100a2, and 100a2 and 100a3. Such an arrangement ensures that adjacent extent portions are not too far away from one another and heat exchanger 26 is correspondingly embodied in planar fashion.

(31) Several such triplets can of course be present adjacently to one another, and can have extent portions, or in fact a pair of extent portions, in common with one another.

(32) FIG. 6 shows a vehicle 106 that is in a normal position, i.e. it is standing on a flat surface 108 that extends perpendicularly to effective direction of gravity S, in an operationally ready state, i.e. in particular is standing on wheels 110 provided for forward motion. The vehicle has a vehicle reference direction F that, in a normal position, proceeds parallel to effective direction of gravity S. A vehicle tank 20 is built into vehicle 106 (as indicated merely schematically in FIG. 6) in such a way that reference direction 40 of vehicle tank 20 coincides with vehicle reference direction F.

(33) While considerable emphasis has been placed on the preferred embodiments of the invention illustrated and described herein, it will be appreciated that other embodiments, and equivalences thereof, can be made and that many changes can be made in the preferred embodiments without departing from the principles of the invention. Furthermore, the embodiments described above can be combined to form yet other embodiments of the invention of this application. Accordingly, it is to be distinctly understood that the foregoing descriptive matter is to be interpreted merely as illustrative of the invention and not as a limitation.