DE102007010958A1 - Heizölvorwärmer - Google Patents

Abstract

A heating oil preheater (1) is provided with at least one heating element (2) which has a heating surface (9) and at least one oil channel housing (5) which has at least one oil channel (11) with a first boundary wall, the outside of which on the heating surface (9) is present. It would like to realize such a Heizölvorwärmer with a simple structure. For this purpose, it is provided that the oil channel housing (5) is formed as an aluminum profile, at least in a region in which the heating element (2) rests against the oil channel housing (5), the inside at least one of the boundary wall (7) projecting heat-conducting wall (10). having.

Description

The The invention relates to a Heizölvorwärmer with at least a heating element having a heating surface, and at least an oil passage housing, the at least one oil passage having a first boundary wall, the outside thereof abuts the heating surface.

Such Heizölvorwärmer is for example off DE 42 16 008 A1 known. The oil passage housing has an oil passage, are arranged in the heat conducting body. These heat-conducting body can have different shapes. Proposed are a good thermal conductivity porous material or a separately formed shaped body made of sintered bronze.

US 4,447,706 shows an oil preheater, wherein the oil passage housing is formed by a Flachkantrohr. Alternatively, you can also cut out flat channels in a plastic or provide tightly adjacent holes in a plastic.

DE 24 22 216 A1 shows a nozzle rod for an oil burner, wherein the heating is performed by heating elements, which extend axially to an oil feed pipe. Alternatively, one can use heating elements that are wrapped around the oil feed tube. These heating elements are cast in a heat storage aluminum.

DE 198 59 014 A1 shows an oil preheater, which is composed of a plurality of elements, namely a tube, an outer heat distribution element and an inner heat distribution element, wherein a heating resistor is in heat-conducting connection with the outer heat distribution element.

Heizölvorwärmer are used to deliver that to an oil burner Bring fuel oil to an elevated temperature. This elevated temperature sets the viscosity of the heating oil and facilitates its atomization. The better the fuel oil is atomized, the lower is the environmental impact of the combustion of heating oil.

The known Heizölvorwärmer are relatively expensive in production. To a good heating of the heating oil to allow the flow cross-sections, through which the fuel oil can flow, if possible kept small. The smaller these cross sections are, the bigger there is a danger that the heating oil preheater gets clogged and overloaded the fuel oil pump during operation.

Of the Invention is based on the object, a Heizölvorwärmer to realize with a simple structure.

These Task is at a Heizölvorwärmer the beginning mentioned type solved in that the oil passage housing at least in a region in which the heating element rests against the oil channel housing, is designed as an aluminum profile, the inside at least one Having protruding from the boundary wall Wärmeleitwand.

With This configuration can be achieved, that you at a relatively large Heat transfer surface only a single Handle element, namely the aluminum profile. The Aluminum profile has two tasks. It surrounds the oil channel. Already through the boundary wall of the oil channel can then Heat to be transferred to the fuel oil. The heat transfer will continue through this improves that of the boundary wall the heat conduction wall protrudes inward into the oil passage. Because the oil channel housing is formed overall as an aluminum profile, the heat-conducting wall integrally connected to the boundary wall, allowing a Heat flow from the heating element to the boundary wall and from there to the Wärmeleitwand without larger Losses is possible. This makes it possible for the free cross section through which the fuel oil flow can make something bigger. This will be the risk reduces the plugging of the heating oil preheater. At the same time results in a lower pressure drop over the Heizölvorwärmer, which contributes to the oil pump to protect. There is comparatively little material used. By using an aluminum profile, the manufacturing costs are low held. In addition, the use of aluminum cheap, because it is against organic oils, so biological produced fuels, much more resistant than copper or brass. The slightly lower thermal conductivity of aluminum over copper or brass can through a corresponding dimensioning of the heat conducting wall can be compensated.

Preferably, the heat-conducting wall connects the first boundary wall with a second boundary wall, which lies opposite the first boundary wall. The Wärmeleitwand then has a second function. It not only serves to transfer heat to the fuel oil that flows along the heat-conducting wall. The Wärmeleitwand also serves the mechanical support of the second boundary wall with respect to the first boundary wall, so that it can muster, for example on the second boundary wall, a force with which the oil passage housing is pressed against the heating element and the greater this force, the better is generally the Heat transfer between the heating element and the oil channel housing. This force can then be applied for example by a spring. The Wärmeleitwand divides the Oil channel in several channels.

Preferably are several Wärmeleitwände of the first boundary wall from and a mean distance between the Wärmeleitwänden is provided, which is smaller than a mean extent of Wärmeleitwände of the first boundary wall path. If several heat-conducting walls are provided, one can in a preferred embodiment, the distances configured equal between the Wärmeleitwänden. This then ensures a relatively uniform Distribution of fuel oil on the spaces between the Wärmeleitwänden. Same distances but are not essential. When the distances are not the same, then a mean distance is formed by that is the sum of the distances by the number of distances divided. In the same way, it is usually beneficial if the heat conducting walls the same "height", So extension away from the first boundary wall, have. But this is not mandatory. If they do not have the same extension, then a mean extent is formed from the sum of the extents all heat-conducting walls divided by the number the Wärmeleitwände. If you now the middle Extension greater than the middle one Distance between the Wärmeleitwänden, then yields a relatively large heat transfer surface for the heating oil with a relatively small layer thickness of heating oil. This can be a good heating reach the fuel oil even if the Heizölvorwärmer in the direction of flow of fuel oil only a limited Length.

Preferably is the average extension of the Wärmeleitwände from the first boundary wall away 3 to 4 times the middle Distance. This results in a flow path for the fuel oil between two Wärmeleitwänden, which in principle has a rectangular cross-section. The rectangle formed by the cross-section has a broad side, which is about 3 to 4 times the height of the rectangle. This allows a satisfactory heat transfer.

Preferably the heat conducting walls have an average thickness in the range of 0.5 to 1.2 times the mean distance lies. The heat-conducting walls do not have to have the same thickness, although this is geous before. The average thickness is then calculated from the sum of the thicknesses divided by the number of heat conducting walls. The thickness is the extension of a Wärmeleitwand parallel to the first Boundary wall. By the ratio between the middle Thickness and the distance one can the available Take advantage of the space in the oil channel housing particularly well. On the one hand, a satisfactory heat conduction through the heat-conducting walls ensured. on the other hand is by limiting the thickness of the heat conducting walls ensured. That there is enough space, through the fuel oil in Heizölvorwärmer can flow.

Preferably limited at least one Wärmeleitwand a in cross section essentially triangular section of the oil channel. By choosing a "triangle" for the section of the oil channel even then you get a good heat transfer and thus a satisfactory temperature for the heating oil, if spatially unfavorable conditions available.

This is especially true when the substantially triangular Section of the oil channel one laterally outside Section of the oil channel forms. In this case you can the oil channel housing approximately trapezoidal form.

preferably, the oil channel housing has at least one end portion in which the aluminum profile is inserted. This facilitates the Production. Basically, for the heating oil preheater then only a few parts required. In addition to the heating element needed one the oil channel housing and two end sections, which are simply put together. The end section has the task the oil channel housing with an inlet or outlet to connect for the heating oil. About that In addition, the end portion has the task of the fuel oil over the cross section of the oil channel housing as possible evenly distributed.

in this connection is preferred that the end portion has a Einsteckraum with a having provided with an opening end face in the the aluminum profile is inserted with a distance to the front side is. The insertion space then provides the connection between the opening and the oil channel housing. The fuel oil, which enters through the opening in the insertion, can then over the cross section of the oil channel housing spread and so the oil channel housing with the appropriate Flow through distribution. At the other end of the oil channel housing is the fuel oil is then collected in the insertion space before passing through the opening in the front can drain.

Preferably, the end portion is formed of cold pressed aluminum. The use of aluminum for the end section has the advantage that at least substantially the same coefficient of thermal expansion is obtained for the end section and the oil channel housing. Even with temperature changes that result in operation, thermal stresses are then avoided or at least kept small. Aluminum can be brought into the desired shape by means of cold pressing without the need for complex metal-cutting shapes. By cold pressing be the end section also has sufficient mechanical strength.

preferably, are the aluminum profile and the end portion soldered together, welded or glued. This can be a seal between the aluminum profile and the end portion omitted. The tightness is rather by the connection between the aluminum profile and generated the end portion.

preferably, the outside is at least partially planar. This facilitates the heating element and the oil channel housing to bring each other to the plant.

alternative or additionally, it may be provided that the outside is at least partially curved. This is especially true beneficial if the outside and the heating element with Their forms are adapted to each other, so that here too a flat Plant can be made. A vault assures that the heating element laterally opposite the oil channel housing can be moved.

in this connection is preferred that the outside at least partially has a circular curvature. A circular, more precisely, a cylindrical curvature leaves produce easily with the required accuracy.

preferably, the outside has a concave curvature. In this curvature then the heating element can be inserted. The heating element may then have, for example, a cylindrical shape, the radius of the cylinder matches the radius of the curvature.

preferably, the heating oil preheater has two aluminum profiles on, between which the heating element is arranged. You can then press the two aluminum profiles against each other, for example with the help of a spring, so that both aluminum profiles against the Heating element are pressed.

The Invention will be described below with reference to preferred embodiments described in conjunction with the drawing. Herein show:

1 a Heizölvorwärmer on average,

2 an end portion of the heating oil preheater,

3 the Heizölvorwärmer in a partially cut perspective view,

4 a modified embodiment of a Heizölvorwärmers.

One in the 1 and 3 illustrated Heizölvorwärmer 1 has a heating element 2 on, which may be formed for example as a PTC element. The heating element 2 gets electrical energy via connection lines 3 . 4 fed. As it changes its electrical resistance with temperature, the heating element acts 2 largely self-regulating, ie it can be kept at a certain temperature.

The in 1 and 3 illustrated Heizölvorwärmer 1 has two oil channel housing 5 on, in two Endab sections 6 are plugged in. Each oil channel housing 5 is designed as an aluminum profile, which can be produced for example by extrusion. For producing a heating oil preheater 1 it is only necessary to separate a desired length of an aluminum profile. This separated part is then together with the heating element 2 in the end sections 6 used. The oil channel housing 5 are then with the end sections 6 soldered, glued or welded. This is the Heizölvorwärmer 1 in principle finished. The end sections 6 can make sure that the two oil channel housing 5 with sufficient force against the heating element 2 be pressed. If this is not the case, then you can use a non-illustrated bracket to the two oil channel housing 5 against the heating element 2 to press.

Both oil channel housing 5 are identical, so that only one is described below.

Each oil channel housing has a first boundary wall 7 and a second boundary wall 8th on. The outside of the first boundary wall 7 lies on the heating element 2 on, with the area at which the oil channel housing 5 on the heating element 2 abuts, as a heating surface 9 referred to as. If, as in 1 shown, the heating oil preheater 1 two oil channel housing 5 has, then has the heating element 2 accordingly two heating surfaces 9 ,

From the first boundary wall 7 There are several heat conducting walls 10 approximately perpendicular. The heat conducting walls 10 connect the first boundary wall 7 with the second boundary wall 8th , Accordingly, forces acting on the second boundary wall 8th be exercised by the Wärmeleitwände 10 on the first boundary wall 7 transfer.

Between the Wärmeleitwänden 10 are channels 11 trained, can flow through the fuel oil. At this flow, heat is transferred from the heating element 2 is generated, over the first boundary wall 7 and the heat-conducting walls 10 transferred to the flowing fuel oil.

The heat conducting walls 10 all have about the same distance a from each other. If the distances a are not equal, then, for the purposes of the following explanation, one may consider a mean distance that results from the sum of the distances a divided by the number of distances a.

Furthermore, the heat conducting walls 10 a thickness d on. The thicknesses d of the heat conducting walls 10 are the same. If this is not the case, then an average thickness is considered which results from the sum of the thicknesses d of the heat-conducting walls 10 divided by the number of heat conducting walls 10 ,

Finally, the heat-conducting walls have 10 an extension e of the first boundary wall 7 path. These extensions are for almost all heat conduction walls 10 equal. Out 1 it turns out that the two outer heat-conducting walls 10 ' have a smaller extension. Again, you can have a mean extent of Wärmeleitwände 10 . 10 ' consider that is the sum of the extensions e of the heat conducting walls 10 . 10 ' Divi diert by the number of Wärmeleitwände 10 . 10 ' results.

A favorable dimensioning results when the average distance a between the Wärmeleitwänden 10 smaller than the mean extension e of the Wärmeleitwände 10 . 10 ' from the first boundary wall. This results in rectangular channels 11 in which the "broadside" is available for heat transfer from the oil channel housing to the fuel oil flowing through. At the same time, the "layer thickness" of the heating oil, which must be penetrated by the heat, kept small. The mean extension should be 3 to 4 times the mean distance a.

The heat conducting walls 10 preferably have an average thickness d which is in the range of 0.5 to 1.2 times the mean distance a. The thickness d of the heat conducting walls 10 . 10 ' is chosen so that on the one hand a sufficiently large cross section for the heat conduction is available, on the other hand, not too much material is used. It is in a given volume enough flow area for the flowing fuel oil available.

The two outer channels 11 ' in each oil channel housing 5 have a substantially triangular shape. Each oil channel housing then has an approximately trapezoidal cross-section. This allows you to the Heizölvorwärmer 1 easier to accommodate in a cylindrical envelope, which is often desired.

The end section 6 has an opening 12 on that in one end face 13 is arranged. Through the opening 12 in one end section 6 can flow into heating oil. Through the opening 12 in the other end section 6 The heated fuel oil can drain off.

The end section 6 points for both oil channel housing 5 each one insertion space 14 on, in the respective oil channel housing 5 can be easily inserted. A tight connection results from the above-mentioned soldering, gluing or welding.

As in particular from 3 can be seen remains after inserting the oil passage housing 5 in the end section 6 a distance 15 to the front 13 , At this distance 15 is then a distributor space formed by the fuel oil from the opening 12 so it is distributed through all channels 11 . 11 ' can pass through substantially evenly. However, an exactly uniform distribution is not required.

4 shows a modified embodiment. While in the embodiment after 1 to 3 the heating element 2 has a cuboid shape, has the heating element 2 in the embodiment 4 a cylindrical shape. Accordingly, the heating surface 9 curved in a circular cross section and indeed convex. The oil channel housing 5 has a first boundary wall 7 on, which is concave with the same radius. In this case, the Wärmeleitwände extend 10 essentially in the radial direction.

QUOTES INCLUDE IN THE DESCRIPTION

This list The documents listed by the applicant have been automated generated and is solely for better information recorded by the reader. The list is not part of the German Patent or utility model application. The DPMA takes over no liability for any errors or omissions.

Cited patent literature

• - DE 4216008 A1 [0002]
• - US 4447706 [0003]
• - DE 2422216 A1 [0004]
• - DE 19859014 A1 [0005]

Claims (16)

Heizölvorwärmer with at least one heating element having a heating surface, and at least one oil passage housing having at least one oil passage having a first boundary wall, the outside of which abuts the heating surface, characterized in that the oil passage housing ( 5 ) at least in an area in which the heating element ( 2 ) on the oil channel housing ( 5 ) is applied, is formed as an aluminum profile, which in the interior at least one of the boundary wall ( 7 ) protruding heat conduction wall ( 10 ) having. Heizölvorwärmer according to claim 1, characterized in that the heat-conducting wall ( 10 ) the first boundary wall ( 7 ) with a second boundary wall ( 8th ) connecting the first boundary wall ( 7 ) is opposite. Heizölvorwärmer according to claim 1 or 2, characterized in that a plurality of Wärmeleitwände ( 10 ) from the first boundary wall ( 7 ) and a mean distance (a) between the Wärmeleitwänden ( 10 ) is provided which is smaller than a mean extent (e) of the Wärmeleitwände ( 10 ) from the first boundary wall ( 7 ) path. Heizölvorwärmer according to claim 3, characterized in that the average extent (e) of the Wärmeleitwände ( 10 ) from the first boundary wall ( 7 ) is 3 to 4 times the average distance (a). Heizölvorwärmer according to claim 3 or 4, characterized in that the Wärmeleitwände ( 10 ) have an average thickness (d) which is in the range of 0.5 to 1.2 times the average distance (a). Heizölvorwärmer according to one of claims 1 to 5, characterized in that at least one heat-conducting wall ( 10 ) has a cross-sectionally substantially triangular section ( 11 ' ) of the oil channel. Heizölvorwärmer according to claim 6, characterized in that the substantially triangular section ( 11 ' ) of the oil passage forms a laterally outer portion of the oil passage. Heizölvorwärmer according to one of claims 1 to 7, characterized in that the oil passage housing ( 5 ) at least one end portion ( 6 ), in which the aluminum profile is inserted. Heizölvorwärmer according to claim 8, characterized in that the end portion ( 6 ) a Einsteckraum ( 14 ) with one with an opening ( 12 ) provided end face ( 13 ) into which the aluminum profile is spaced ( 15 ) to the front side ( 13 ) is inserted. Heizölvorwärmer according to claim 9, characterized in that the end portion ( 6 ) is formed of cold pressed aluminum. Heizölvorwärmer according to claim 9 or 10, characterized in that the aluminum profile and the end portion ( 6 ) are soldered, welded or glued together. Heating oil preheater according to one of Claims 1 to 11, characterized in that the outside at least partially flat. Heating oil preheater according to one of Claims 1 to 12, characterized in that the outside is at least partially curved. Heating oil preheater according to claim 13, characterized in that the outside at least partially has a circular curvature. Heating oil preheater according to claim 14, characterized in that the outside of a concave curvature having. Heizölvorwärmer according to one of claims 1 to 15, characterized in that it comprises two aluminum profiles, between which the heating element ( 2 ) is arranged.