DE4007002A1 - Heat storage unit for heating motor vehicle - has inner container attached by ribs from outer container - Google Patents

Abstract

The heat storage unit has a heat storage core installed inside an inner container (10) which is enclosed in a thermally insulated outer container (12) which is preferably evacuated and there is a space (14) between inner and outer containers. The inner container is attached to the outer container by means of ribs made from a material of low thermal conductivity. These ribs prevent lateral movement of the inner container but permit axial movement which is limited by springs (36,90,92). USE - For heating a motor vehicle, by using the heat from the engine exhaust.

Description

The invention relates to a heat accumulator, in particular Latent heat storage for engine heat fed Motor vehicle heaters, with a memory core containing inner container, one under Formation of a preferably evacuated isolation room the inner container with a surrounding outer container, two led from the outside through the isolation room Lines, one as an inflow line and their other than reflux line for a heat transfer Medium serves, the inner container on two Wall sections facing away from each other a group of webs with low thermal conductivity is suspended from the outer container between a first wall section of the inner container and the outer container at least one spring such is clamped that it strives to distance opposite wall sections of the Ion container and the outer container change, and wherein between the two wall sections of the Inner container connecting container wall and the corresponding container wall of the outer container of the Isolation room has its smallest thickness. A heat store this type is from DE-S 37 25 165 known.

In order to prevent the stored heat from being lost protect is a highly effective insulation between Inner container and outer container required, whereby especially a relatively small volume the insulation is desired so that the total volume the heat accumulator can be kept small, like this especially when installing in motor vehicles  is required because there is little room for additional Aggregates is available. To the vehicle weight The weight should not be an additional burden of such a heat store kept low will.

One that particularly meets these requirements Insulation is a vacuum gap between the inner container and outer container. There is a fixation of the inner container required inside the outer container, which in turn is as light as possible exhibit and cause as little heat loss as possible should.

In the known heat accumulator, the aim was therefore that the inner container in as simple as possible Is reliably established in the outer container, this fixation also according to the requirements the lowest possible weight, the lowest possible heat loss and compensation for temperature fluctuations thermal expansion should correspond.

Fixing the inner housing in the outer housing by a suspension has the advantage that essentially only tensile forces have to be transmitted, whereby small cross sections become possible, on the one hand the required weight and on the other hand also the keep heat losses occurring low. The feather keeps the suspension under tension, balances the influence thermal expansion and suppresses or dampens unwanted vibrations.

In an effort to reduce the installation volume of the heat accumulator to keep it as low as possible,  the thickness of the isolation room in which the end walls of the Inner container connecting area except for a few Reduce millimeters. With such a construction the walls of the inner and outer container keep their distance safely in this area, in particular with high vacuum insulation prevent the containers from touching each other.

It has been shown that only one wall section associated spring is unable to to ensure such positional security. Due to thermal Influences in manufacturing and operation Elongations or reductions can occur in the area of the suspensions assigned to the two wall sections of the inner container different absolute Accept values, d. that is, in a by the spring in Area of a wall section stressed on train Suspension can be the suspension in the area of the other wall section a movement between Allow inner container and suspension or outer container, as a result, outer and inner containers their can leave parallel position to each other. The appearance unwanted vibrations or rattling noises then cannot be prevented the insulation effect can also be impaired.

The invention has for its object a heat storage of the type mentioned at the outset, that shifts between inner and outer containers can be safely prevented with simple means and that all bars of the suspensions on both Wall sections of the inner container facing away from one another always under tension.  

The solution to this problem is that the another, second wall section of the inner container assigned webs in the direction of these wall sections connecting container wall relative to Inner container can be moved, but cannot be moved across are connected to the inner container, and that between these webs and the inner container at least one spring is arranged, which strives is the distance between those attacking the inner container Fastening sections of the webs and the second wall section of the inner container in the Change direction in which the first wall section assigned spring on the inner container acts.

It is unaffected by manufacturing tolerances, different thermal influences and design-related, deviating absolute changes in length in the area of both wall sections Always hang the inner container in the outer container kept under tension so that rattling noises cannot occur. In addition, the inner container remains as far as the range of the relatively low Isolation gap between his two from each other Concerns facing wall sections, always in the middle aligned with the outer container.

An advantageous embodiment is that for connecting the assigned webs to the second wall section according to the number of envisaged Connection points in the direction of action of the springs extending connecting bolts are attached to which the attachment sections of the Bridges are connected.  

The webs preferably run obliquely to this Direction of action of the springs that they by the springs be loaded on train.

Each group of webs comprises at least two, preferably but about three to four bridges to lateral To counteract displacements of the housing.

After a particularly useful training are the Bridges at least one group to a suspension element combines, which is a particularly simple assembly results.

Another appropriate training is that at least one suspension element rotates with the Inner container is connected, preferably on a wall section of the inner container in symmetrical Arrangement and two apart Fastening points arranged for the suspension element are. There is further appropriate training in that the suspension element two the attachment points Connections assigned to the inner container has two V- ribs arranged in a shape to form an outer frame that the other junction on their Include bisectors between them so that the two pairs of bars arranged in a V-shape Cross to form a diamond-shaped inner frame.

The attachment points are preferably as Connection bolts formed.

The first wall section of the inner container assigned spring can either be between this first  Wall section and the opposite Wall section of the outer container or between this first wall section and this wall section associated suspension element clamped be. The spring is preferably in the center the wall section of the inner container is supported.

After further appropriate training, that can Suspension element on the cooperating with the spring first wall section of the inner container with be provided at a central junction, in which the bridges unite.

Preferably, the spring loaded first wall section a guide sleeve for the Spring arranged, and the central junction of the Suspension element is as a this guide sleeve encircling ring formed.

Another appropriate training is that the effective length of the first wall section of the inner container associated spring adjustable is.

The suspension elements are preferably stamped parts educated.

Based on the following description of one in the Drawing shown embodiment of the invention this will be explained in more detail. It shows

Fig. 1 is an axial section through an inventive shaped heat accumulator comprising a cylindrical housing shape,

Fig. 2 shows a variant of the heat accumulator shown in Fig. 1 with altered suspension,

Fig. 3 is a view of the left are arranged in Fig. 1 suspension member,

FIG. 4 shows a view of a first, one-piece embodiment of the suspension element and arranged on the right in FIG

Fig. 5 is a view of a two-part embodiment of this suspension element.

The heat accumulator shown consists of a circular cylindrical inner container 10 and a similar outer container 12 , between which an insulating space 14 is hidden. A feed line 16 and a return flow line 18 are connected to the upper housing 20 of the inner housing 10 and are led vertically downwards out of the outer container 12 through the insulating space 14 .

The outer container 12 consists of a cylindrical casing 24 reinforced by beads 22 , which concentrically surrounds the inner container 10 with a small distance of the order of a few millimeters, and two end walls 26 and 28 inserted into this casing 24 . A suspension element 30 is attached to the inside of the outer container 12 , for example by welding, adjacent to the left end wall 26 ( FIG. 1). A further suspension element 32 is attached to the right end wall 28 on the inner surface of the casing 24 and connected to the inner container 10 via connecting bolts 54 and 56 .

In the center of the left end wall 20 of the inner container 10 , a guide sleeve 34 for a helical compression spring 36 is attached, which is clamped coaxially to the axis of the container 10 and 12 between the inner container 10 and the outer container 12 . The end wall 26 of the outer container 12 opposite the end wall 20 also has a guide sleeve 38 for the compression spring 36 , which is provided with an axially adjustable insert 40 for changing the effective length of the compression spring 36 .

The suspension element 30 ( FIG. 3) has an inner, ring-shaped frame 42 , from which four radial webs 44, each offset by 90 °, extend outwards, which are provided at their ends with fastening flanges 46 for connection to the jacket 24 . The webs 44 are angled relative to the plane of the inner frame 42 , so that they enclose an acute angle to the axis of the inner frame and are constantly kept under tension by the compression spring 36 . For fastening the inner frame 42 to the end wall 20 , a pressure plate 48 can be used, which likewise surrounds the guide sleeves 34 in an annular manner and which is connected to the end wall 20 of the inner container 10 .

On the other end wall 50 of the inner container 10 , a bracket 52 is attached for connecting the suspension element 32 , on the vertical plane of symmetry of the inner container 10 with the same distance from the axis of this inner container 10, two connecting bolts 54 and 56 are arranged, which on an inner frame 58 of the suspension element 32 are assigned two bores 60 and 62 . From the sections 64 and 66 of the inner frame 58 surrounding these bores 60 and 62, webs 68 and 70 or 72 and 74 extend in pairs. The webs 68 and 70 or 72 and 74 of each pair of webs are each arranged in a V-shape such that they unite in section 64 or 66 and the bores 62 or 60 arranged in the other section 66 or 64 on their bisector lies and is enclosed by them. The two web pairs 68 and 70 or 72 and 74 thus cross each other, as a result of which the inner frame 58 is given a diamond-shaped shape. The outer ends of the webs 68 to 74 are connected to one another by an annular outer frame 76 which has a bend 78 which can be connected to the inner surface of the jacket 24 .

The outer sections of the webs 68 to 72 between the inner frame 58 and the outer frame 76 are angled in the same sense with respect to the plane of the inner frame 58 as the webs 44 of the suspension element 30 with respect to its inner frame 42 .

Between the inner frame 58 of the suspension element 32 and the bracket 52 , the connecting bolts 54 and 56 are enclosed by compression springs 90 and 92 , which, regardless of the compression spring 36 and the thermal expansion in the region of the suspension element 30, always keep the webs 68 to 74 under tension.

In this arrangement, the suspension element 30 serves primarily for the axial fixing between the inner container 10 and the outer container 12 , while the suspension element 32 primarily determines the radial distance between the two containers 10 and 12 and at the same time a rotation of the two containers 10 and 12 against each other prevented.

Instead of arranging the compression spring 36 directly between the inner housing 10 and the outer housing 12 , it can, as can be seen from FIG. 2, for example also be supported directly on the inner housing 10 and indirectly on the outer housing 12 in that the compression spring 36 on the one hand is supported on the end wall 20 of the inner housing 10 and on the other hand on the suspension element 30 , the compression spring 36 being pulled through by a guide bolt 80 connected to the end wall 20 , on which an adjustable nut 82 is arranged on the side of the suspension element 30 facing away from the inner housing 10 is.

If this arrangement is chosen in which the webs 44 are unwound in an opposite direction to the arrangement in FIG. 1 in order to be subjected to a tensile stress again under the action of the spring 36 , the webs 68 to 74 must also be angled in the opposite direction, so that the compression springs 90 and 92 - as can be seen from FIG. 2 - must be arranged between the inner frame 58 and abutments 94 and 98 arranged at the free end of the connecting bolts 54 and 56 , respectively.

In Fig. 2, the hanging element 32 is formed in two parts, that is, it consists of two V-shaped elements 132 , which are shown in Fig. 5, the use of which due to the opposite inclined position of the webs 68 and 70 on the one hand and 72 and 74 on the other In the area of the nodes of these webs, twists occurring in the one-piece embodiment are avoided.

Claims (16)

1. Heat accumulator, in particular latent heat accumulator for powered by engine exhaust heat vehicle heaters, comprising a memory core inner container (10), a form of a preferably evacuated insulated space (14) the inner container (10) surrounding and spaced outer container (12), two from the outside through the Insulated space ( 14 ) guided lines ( 16, 18 ), one of which serves as an inflow line and the other as a return line for a heat-transporting medium, with the inner container ( 10 ) on two wall sections ( 20, 50 ) facing away from each other via a group of webs ( 44; 68, 70, 72, is suspended 74) with low thermal conductivity on the outer container (12), between a first end wall (20) of the inner container (10) and the outer container (12) at least one spring (36) is clamped in such a way that it strives to determine the distance between opposing wall sections ( 20, 26; 50, 28 ) d to change the inner container ( 10 ) and the outer container ( 12 ), and between the container wall ( 51 ) connecting the two wall sections ( 20, 50 ) of the inner container ( 10 ) and the corresponding container wall ( 24 ) of the outer container ( 12 ) the insulating space ( 14 ) has its smallest thickness, characterized in that the webs ( 68, 70, 72, 74 ) assigned to the other, second wall section ( 21 ) of the inner container ( 10 ) in the direction of the container wall ( 20, 50 ) connecting the wall sections ( 20, 50 ) 51 ) are displaceable relative to the inner container ( 10 ), but are non-displaceably connected to the inner container ( 10 ) transversely thereto, and that at least one spring ( 90, 92 ) is located between these webs ( 68, 70, 72, 74 ) and the inner container ( 10 ) ) which strives to increase the distance between the fastening sections ( 64, 66 ) of the webs ( 68, 70, 72, 74 ) engaging the inner container ( 10 ) and the second wall section ( 50 ) to change the inner container in the direction in which the spring ( 36 ) assigned to the first wall section ( 20 ) acts on the inner container ( 10 ). 2. Heat accumulator according to claim 1, characterized in that for connecting the associated webs ( 68, 70, 72, 74 ) to the second wall section ( 50 ) corresponding to the number of connection points provided in the direction of action of the springs ( 36, 90, 92 ) extending connecting bolts ( 54, 56 ) are attached, to which the fastening sections of the webs ( 68, 70, 72, 74 ) are connected in a longitudinally displaceable manner. 3. Heat accumulator according to one of claims 1 or 2, characterized in that the webs ( 44, 68, 70, 72, 68 ) run obliquely to the direction of action of the springs ( 36, 90, 92 ) that they pull through the springs be charged. 4. Heat accumulator according to one of claims 1 to 3, characterized in that each group comprises at least two webs ( 44; 68, 70, 72, 74 ). 5. Heat accumulator according to one of the preceding claims, characterized in that the webs ( 44; 68, 70, 72, 74 ) at least one group are combined to form a suspension element ( 30; 32 ). 6. Heat accumulator according to claim 5, characterized in that at least one suspension element ( 32 ) is connected to the inner container ( 10 ) in a rotationally fixed manner. 7. Heat accumulator according to claim 6, characterized in that on a wall section ( 50 ) of the inner container ( 10 ) in a symmetrical arrangement and at a distance from each other two fastening points ( 54, 56 ) for the suspension element ( 32 ) are arranged. 8. Heat storage device according to claim 7, characterized in that the suspension element ( 32 ) has two attachment points ( 54, 56 ) on the inner container ( 10 ) facing connection points ( 60, 62 ), each of which has two V-shaped webs ( 68 , 70; 72, 74 ) to an outer frame ( 76 ), which enclose the other connection point ( 62, 60 ) on their bisector between them, so that the two pairs of V-shaped webs form a diamond-shaped inner frame ( 58 ) cross. 9. Heat accumulator according to claim 2 and one of claims 7 or 8, characterized in that the fastening points ( 54, 56 ) are designed as connecting bolts. 10. Heat storage device according to one of the preceding claims, characterized in that a spring ( 36 ) between the first end wall ( 20 ) of the inner container ( 10 ) and the opposite end wall ( 26 ) of the outer container ( 12 ) is clamped. 11. Heat storage device according to one of the preceding claims, characterized in that a spring ( 36 ) is clamped between the first wall section ( 20 ) of the inner container ( 10 ) and the suspension element ( 30 ) assigned to this end wall. 12. Heat accumulator according to one of claims 10 or 11, characterized in that the spring ( 36 ) is supported in the center of the first wall section ( 20 ) of the inner container ( 10 ). 13. Heat accumulator according to claim 12, characterized in that the suspension element ( 30 ) on the spring ( 36 ) cooperating with the first wall section ( 20 ) of the inner container ( 10 ) is provided with a central connection point ( 42 ) in which the webs ( 44 ) unite. 14. Heat accumulator according to claim 13, characterized in that on the end face ( 20 ) acted upon by the spring ( 36 ) a guide sleeve ( 38 ) for the spring ( 36 ) is arranged and the central connection point ( 42 ) of the suspension element ( 30 ) as one this guide sleeve ( 38 ) encompassing ring. 15. Heat accumulator according to one of claims 10 to 14, characterized in that the effective length of the spring ( 36 ) is adjustable. 16. Heat storage device according to claim 5, characterized in that the suspension elements ( 30, 32 ) are formed as stamped parts.