The invention relates to a heatable fluid line having a pipe which has an inner space and having a heating device which is arranged in the inner space.
Such a fluid line is known from DE 10 2011 102 244 A1.
The invention is explained below with reference to a fluid line which is used to transport a carbamide solution (UREA) from a storage container to a consumer location. UREA is used in diesel engines in order to reduce the emission of nitrogen oxides.
When such a fluid line is used in an environment in which relatively low temperatures may occur, there is the risk of the carbamide solution freezing so that it is no longer capable of flowing. This situation occurs at temperatures of less than −11°. In order to nonetheless reduce the emission of pollutants within a specific time after an engine has been started, it is known to heat the fluid line so that the carbamide solution is made flowable again and can be supplied to the consumer location.
Another problem is that the carbamide solution can also freeze in an injection region. At this location, there is a nozzle arrangement through which UREA is discharged. If this nozzle arrangement is still filled with the carbamide solution and the carbamide solution freezes, this may lead to damage.
In order to overcome this problem, attempts have been made after the engine has been switched off to draw back the carbamide solution from the fluid line in order to free the nozzles from the carbamide solution. However, a problem arises in this instance in that a relatively large volume is present between the heating device and the pipe. This volume is brought about by the fact that a heating device which is arranged in the inner space of the pipe also has to be guided through a connector which is inserted into the pipe. Accordingly, the heating device may not exceed a specific cross-section. However, the suction of a relatively large quantity of carbamide solution as is determined by the relatively large volume is relatively difficult in many cases.
However, it has been found that, even with such an embodiment, a suction of the carbamide solution when the engine is switched off cannot be achieved with the necessary level of reliability. When UREA is not sufficiently drawn back, UREA remains in the injection arrangement. This can lead to damage at low temperatures.
An object of the invention is to protect the injection arrangement.
This object is achieved with a heatable fluid line of the type mentioned in the introduction in that a volume reduction element is arranged between the pipe and the heating device. When a volume reduction element is arranged in the inner space, that is to say, in the intermediate space between the heating device and the inner side of the pipe, a volume reduction in the annular gap between the pipe and the heating device can be achieved so that less carbamide solution has to be drawn back. This can generally be readily implemented. As a result of the volume reduction element, the nozzle arrangement is protected after the engine has been switched off. In this instance, it is preferable for the volume reduction element to have a recess which extends along the heating device.
As a result of the installation of the volume reduction element, although the volume in the annular gap between the pipe and heating rod has been reduced, a relatively large wetted surface is produced with a correspondingly high level of flow resistance so that the pump when drawing back the carbamide solution occasionally reaches its limits or is overloaded. The recess has a smaller wetted surface and consequently a lower flow resistance so that the pump can draw UREA from the injection arrangement. When a recess is used in the volume reduction element, it is then possible to make the annular gap between the volume reduction element and the pipe even smaller than before so that the volume between the pipe and the heating device does not have to be increased or does not have to be increased significantly. That is to say, therefore, it is possible to leave the suction behavior, in particular the suction volume, of the pump unchanged and nonetheless to achieve an adequate suction and consequently protection of the injection arrangement.
Preferably, the recess extends as far as the heating device. The heating device can then act directly on the fluid in the fluid line without the heating power first having to pass through the volume reduction element. This not only results in excellent use of the thermal energy, but it is also possible to achieve rapid thawing of frozen fluid in the line.
Preferably, the recess has in the peripheral direction of the heating device an extent which corresponds at least to a radial thickness of the volume reduction element. The recess is therefore in principle provided at least with a square or with a rectangular cross-section (if the curvatures are not taken into account) so that there is a sufficient flow cross-section through which the fluid can flow and through which the fluid can also be drawn off.
Preferably, the heating device is constructed as a heating rod and the volume reduction element is clip-fitted onto the heating rod. This enables relatively simple production. A heating rod has a degree of rigidity so that it can be inserted into the pipe and it is possible to ensure that the heating rod extends through the pipe at the desired length. When the volume reduction element is clip-fitted onto the heating rod, it is retained on the heating rod only by friction, but this friction can be sized in such a manner that the volume reduction element on the heating rod is not displaced in the longitudinal direction when the heating rod is inserted into the pipe. The bending resistance of the heating rod with the volume reduction element clip-fitted thereto can be kept smaller than the bending resistance of a heating rod with an extruded volume reduction element. Consequently, the flexibility of the fluid line is on the whole configured in a favorable manner.
Preferably, the volume reduction element is at least partially formed by a hollow member which is separated in the longitudinal direction. It is possible, for example, to use as a hollow member a plastics material pipe which is cut in the longitudinal direction. The cutting line does not necessarily in this instance have to form a straight line, although this is preferable. The cutting or separation line may also extend in a helical or undulating manner without this in principle changing anything concerning the structure of the fluid line. A volume reduction element which is formed by a hollow member can be produced in a very simple manner.
In this instance, it is preferable for the hollow member to have an inner cross-section which is smaller than an outer cross-section of the heating rod. This applies in the hollow member to the state in which the hollow member has not yet been fitted to the heating rod. As a result of the sizing of the inner cross-section of the hollow member, two effects are produced. On the one hand, it is ensured that the hollow member is arranged with a degree of tension on the heating rod when it has been clip-fitted to the heating rod. On the other hand, the desired recess is produced as a result of the sizing since the volume reduction element is slightly splayed when it is clip-fitted onto the heating rod.
Preferably, the volume reduction element is arranged with at least two portions on the heating device. This has, for example, advantages when the heating device has a greater length. In this instance, the volume reduction element can be fitted portion by portion which facilitates the production.
In this instance, it is preferable for the at least two portions to leave an intermediate space free between them. It is not absolutely necessary for the portions to be assembled beside each other in a manner of speaking end-to-end on the heating device. It is readily possible to leave intermediate spaces between the individual portions. In this instance, although a slightly larger volume is produced, this is not detrimental since such a volume is not disruptive either when UREA is drawn from the injection arrangement or when UREA is conveyed to the injection arrangement.
In this instance, it is particularly preferable for the intermediate space to be arranged in a curved portion of the fluid line. In many cases, the fluid line does not extend in a linear manner, but instead has one or more curved portions. The final shape of the fluid line is based on the desired application. In this embodiment, a linear or extended pipe with the heating device and volume reduction element located thereon may first be provided by the heating device being inserted into the pipe in a linear manner. If one or more portions are provided with a curvature afterwards and, at the positions at which the curved portions are provided, a volume reduction element is not provided, the formation of the curvature is then simplified since the volume reduction element does not also have to be bent. Furthermore, this embodiment also enables, for example, at the outer side of the curvature, the pipe to move slightly closer to the heating device without this approach movement being disrupted by the volume reduction element. Under some circumstances, a volume change may be accepted, but may reduce the flow resistance so that the flow resistance for the entire fluid line can be optimized.
Preferably, the fluid line is thermo-fixed with the heating device and the volume reduction element. As a result of the thermo-fixing, the fluid line is maintained in a predetermined shape. During the thermo-fixing operation, a connection between the pipe and the volume reduction element is not required and in many cases is also undesirable. However, as a result of the friction between the volume reduction element and the heating device, the volume reduction element remains in its position. However, slight displacements are harmless.
Preferably, at least at one end of the pipe, a connector with a connection piece is inserted into the pipe, wherein the connection piece has a wall having a thickness which corresponds to a maximum of the thickness of the volume reduction element. Since the heating device has to be guided through the connection piece, there remains between the heating device and the pipe outside the connection piece a relatively large free space which, as set out above, can be reduced by the volume reduction element. When the thickness of the wall of the connection piece is adapted to the thickness of the volume reduction element, that is to say, the “radial extent”, it is possible to ensure that a substantially uniform flow resistance is produced in the pipe outside the connection piece and in the connection piece.
In this instance, it is preferable for a spacing between the volume reduction element and the connection piece in the longitudinal direction to correspond to at least the thickness of the volume reduction element. There is consequently sufficient space available to enable the fluid located in the line to move from the annular gap between the volume reduction element and the pipe into the annular gap between the heating device and the connection piece.
The invention is described below with reference to a preferred embodiment together with the drawings, in which:
In
A volume reduction element 5 which is illustrated in
The inner cross-section 6 of the volume reduction element 5 is slightly smaller than an outer cross-section of the heating rod 3.
As can be seen in
If the unit which is formed by the heating rod 3 and the volume reduction element 5 is now inserted into the pipe 2 (
Between the volume reduction element 5 and the pipe 2 there remains as before an annular gap 10 which is also filled with the fluid during operation and through which fluid can also flow. However, this annular gap 10 has a relatively large wetted surface so that there is also produced in this instance a correspondingly large flow resistance.
It should first be recognized that the volume reduction element 5 has two portions 5, 5′ which are separated from each other by an intermediate space 11. This intermediate space 11 is arranged in a curved portion 12 of the fluid line 1. It is illustrated that the portions of the volume reduction element 5, 5′ have a relatively large spacing from the curved portion 12. In reality, this spacing will be significantly smaller.
At one end of the pipe, a connection piece 13 of a connector which is not illustrated in greater detail is inserted into the pipe 2. This connection piece 13 has a wall having a thickness d. Since the heating rod 3 also has to be guided through this connection piece, the heating rod 3 must have an outer cross-section which is significantly smaller than the inner cross-section of the connection piece 13 in order to enable a fluid flow.
The volume reduction element 5 has a thickness D which is at least as large as the thickness d of the connection piece 13. That is to say, the thickness d of the connection piece 13 is at a maximum as large as the thickness D of the volume reduction element 5, 5′. It is consequently ensured that a flow of the fluid through the connection piece 13 is not impeded to a greater extent than a flow through the pipe 2 with the internal volume reduction element 5, 5′.
A spacing a between the volume reduction element 5 and the connection piece 13 corresponds to at least the thickness D of the volume reduction element 5. However, it may also be larger.
In order to produce the fluid line 1, the pipe 2 is first left in an extended or linear orientation. The heating rod 3 also has a linear form and is thus initially free from curvatures or the like. Next, the volume reduction element 5 illustrated in
The heating rod 3 which is provided with the volume reduction element 5 or a plurality of volume reduction elements 5, 5′ can then be inserted into the pipe 2, which is readily possible since both the pipe and the heating rod 3 with the volume reduction element(s) 5, 5′ have a linear form. Afterwards, the pipe 2 with the heating rod 3 and the volume reduction elements 5, 5′ is bent into the desired form so that one or more curved portions 12 are produced. The pipe which has been shaped is then thermo-fixed. As a result of the recess 9, there is produced a relatively low flow resistance for a fluid in the pipe 2. Since the recess 9 extends as far as the heating rod 3, the heating rod 3 can directly heat the fluid located in the pipe without a heat flux being necessary through the volume reduction element 5. This is naturally nonetheless present and also heats a fluid in the annular gap 10.
Number | Date | Country | Kind |
---|---|---|---|
10 2014 108 499 | Jun 2014 | DE | national |
Filing Document | Filing Date | Country | Kind |
---|---|---|---|
PCT/EP2015/063465 | 6/16/2015 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2015/193305 | 12/23/2015 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
1435311 | Knight | Nov 1922 | A |
1474528 | Hurst | Nov 1923 | A |
2408253 | Diebold | Sep 1946 | A |
2583761 | Axelson | Jan 1952 | A |
2599671 | Thompson | Jun 1952 | A |
2750487 | Hynes | Jun 1956 | A |
2793917 | Ward | May 1957 | A |
3283123 | Atkinson | Nov 1966 | A |
3924661 | Bornhoffer | Dec 1975 | A |
4401156 | Wojtecki | Aug 1983 | A |
4754782 | Grantham | Jul 1988 | A |
4883943 | Davis | Nov 1989 | A |
5018260 | Ziu | May 1991 | A |
5086836 | Barth | Feb 1992 | A |
5497809 | Wolf | Mar 1996 | A |
5503192 | Platusich | Apr 1996 | A |
5859953 | Nickless | Jan 1999 | A |
6167883 | Beran | Jan 2001 | B1 |
7635008 | Follett | Dec 2009 | B2 |
7637287 | Reinhard | Dec 2009 | B2 |
7650911 | Follett | Jan 2010 | B2 |
7919733 | Ellis | Apr 2011 | B2 |
8555929 | Ertel | Oct 2013 | B2 |
9464747 | Eckardt et al. | Oct 2016 | B2 |
20080012293 | Freiberger et al. | Jan 2008 | A1 |
20100037971 | Scherer | Feb 2010 | A1 |
20100186844 | Koskey, Jr. | Jul 2010 | A1 |
20120291881 | Eckardt et al. | Nov 2012 | A1 |
20120291904 | Eckardt et al. | Nov 2012 | A1 |
20140029927 | Leblanc | Jan 2014 | A1 |
Number | Date | Country |
---|---|---|
10 2005 047 806 | Apr 2007 | DE |
10 2008 018 658 | Oct 2009 | DE |
10 2011 102 151 | Nov 2012 | DE |
10 2011 102 244 | Nov 2012 | DE |
10 2011 053 053 | Feb 2013 | DE |
1818588 | Aug 2007 | EP |
2 527 702 | Nov 2012 | EP |
2 527 703 | Nov 2012 | EP |
2 478 161 | Sep 1981 | FR |
50-073048 | Nov 1948 | JP |
2012-241901 | Dec 2012 | JP |
2013083274 | Jun 2013 | WO |
Entry |
---|
German Office Action conducted in counterpart German Appln. No. 10 2014 108 499.3 (dated Jul. 7, 2017) (w/ machine translation). |
Japan Office Action conducted in counterpart Japan Appln. No. 2016-570330 (dated Dec. 25, 2017) (w/ English language translation). |
Korean Office Action conducted in counterpart Appln. No. 10-2017-7001341 (9 pages). |
Number | Date | Country | |
---|---|---|---|
20170130886 A1 | May 2017 | US |