DE102006051724A1 - Conduit system e.g. double wall hose assembly, for use in e.g. diesel engine, has inner conduit, where current is applied at two pairs of electrical conduits, such that inner conduit is heated by warming electrical conduits - Google Patents

Abstract

The conduit system has an inner conduit (2), through which the fluid flows. Two pairs of electrical conduits (6, 7) are attached to the inner conduit in their longitudinal direction, and are connected with one another to form closed conduits, respectively. Current is applied at the pair of electrical conduits (6) and/or at the pair of the electrical conduits (7), in such a manner that the inner conduit is heated by warming the electrical conduits.

Description

The The invention relates to a conduit system for conveying a fluid.

line systems to promote or transporting fluids are widely known in the art. In internal combustion engines lead systems come in the form of fuel lines for use. In combustion engines according to the auto-ignition principle, i.e. Diesel engines are heated fuel lines, to flocculate the diesel fuel at low temperatures to prevent and operate the diesel vehicle in such To ensure temperatures. In the same way is with diesel vehicles the heating of the fuel tank known to be at low temperatures liquid state diesel fuel. The retrofitting from conventional Fuel lines with heating wires or the like is relatively expensive. In addition takes over such a modified fuel line usually only one function, i.e. a promoting or transporting the fluid in one direction. With a circulation principle Therefore, a plurality of fuel lines are required namely a supply line and a return line.

The dosing of flowable materials is also important in an exhaust gas purification process for automotive diesel engines, which is known as "selective catalytic reduction", abbreviated to SCR .. By means of the SCR technology, a diesel engine is set to maximum efficiency and compliant particle emissions Using this technology, the threshold levels Euro 4 and Euro 5 can be reached for nitrogen oxide emissions, which requires a reducing agent, mostly AdBlue ^TM , which is an aqueous urea solution that is injected into the exhaust stream of the diesel engine and the required reducing agent, namely ammonia for the SCR reactions in the catalyst releases.Thus, the NO _x emissions of the diesel exhaust gases are effectively reduced while optimizing the diesel engine to a low efficiency out.This advantageously results in a low power fuel consumption and low particulate emissions.

Due to its specific properties, the reducing agent AdBlue ^TM sets very stringent development requirements for the exhaust aftertreatment systems with regard to frost resistance, clogging at low temperatures due to crystallization and material compatibility of the medium-conducting components. Since the aqueous urea solution begins to crystallize in the form of AdBlue ^TM already at about -11 ° C, a heating of the corresponding lines that carry this agent to the exhaust system, required to ensure trouble-free exhaust aftertreatment even in winter at low temperatures.

From the DE 10 2004 046 881 A1 For example, a feed system for an aqueous urea solution for treating exhaust gases of an internal combustion engine is known. A feed line and a return line of this feed system have at least one line region with at least a first sub-channel and a second second sub-channel, which is guided in parallel in terms of flow, wherein the sub-channels have different thermal insulation properties. As a result, the heat absorbed by a dosing unit should be able to be dissipated to the environment with simultaneous isolation of the entire medium circuit. A disadvantage of this delivery system is that a plurality of sub-channels is to be provided in order to achieve the desired heat dissipation.

Corresponding The invention is based on the object, a conduit system to create that while promoting a fluid according to the circulation principle is particularly space-saving and has a high functional integration for heating.

These The object is achieved by a conduit system having the features of claim 1 and solved by a conduit system with the features of claim 4. advantageous Further developments of the invention are the subject of the dependent claims.

One inventive conduit system for Promote a fluid comprises an inner conduit through which the fluid flows, at least one pair of first electrical lines connected to the inner Line mounted substantially in the longitudinal direction and connected together to form a closed conductor, and at least one pair of second electrical leads connected to the inner conduit mounted substantially in the longitudinal direction and interconnected to form a closed conductor. In this case, the pair of first electrical lines and / or a current is applied to the pair of second electrical leads, so that the inner pipe by heating the corresponding electrical Lines is heated.

One Advantage of the conduit system according to the invention is that the heating of the inner conduit through the one Pair of electrical lines is achieved, with the other Pair of electric wires a temperature of the inner wire measured or other information can be forwarded.

In an advantageous embodiment of the invention the inner conduit may be enclosed by an outer jacket serving as a protective layer for the inner conduit. Conveniently, at least one channel can be formed in the outer jacket, which can be flowed through by a fluid, in particular in a direction opposite to the inner conduit. Thus, the channel forms a return for the fluid relative to the inner conduit. Instead of using two separate fluid lines for feeding and returning the fluid to or from a hydraulic consumer, this can be done by means of the conduit system according to the invention in the form of a single element.

In an alternative embodiment comprises a conduit system according to the invention an inner conduit through which the fluid flows and one inside Line surrounding outer jacket, in which at least one channel formed by a fluid, especially in a direction opposite to the inner line, flows through can be, so the channel, based on the inner pipe, a return forms. As explained above, this has the advantage that the piping system at the same time as a supply line and as a return line for a Can serve fluid or from a hydraulic consumer.

The aforementioned embodiment of the inventive conduit system may advantageously be a pair of first electrical lines connected to the inner conduit substantially attached to the longitudinal direction and connected to form a closed conductor, and at least one pair of second electrical leads, those on the inner conduit substantially in the longitudinal direction attached and to form a closed conductor together are connected. In this case, the pair of first electrical lines and / or a current is applied to the pair of second electrical leads so that the inner line by heating the electrical wires is heated.

The inventive conduit system can be used advantageously to a central control and supply unit with a hydraulic resistance and / or an electrical resistance connect to. For this purpose, the conduit system according to the invention serves for simultaneous Transport of a fluidic mass flow, a heat flow, an electric current and / or information, for example in terms of the temperature of the inner pipe, the hydraulic resistance and / or of electrical resistance. As explained above, the line system according to the invention from two fluid lines, namely the inner conduit and the formed in the outer shell Channel, and two pairs of electrical lines, i. the couple consist of first and second electrical lines. Especially useful the electrical leads are embedded in the outer jacket, e.g. on an outer wall of the inner duct or adjacent to it, so that they thereby in the longitudinal direction led the inner line and against damage or the like from the outside protected are. The outer coat can over four radial segments support the inner pipe, the electrical Lines are each embedded in one of the four segments. Between four segments of the outer shell each one extending in the axial direction chamber is formed, each of which forms the channel. Thus, the outer jacket fulfills two functions, namely Pick up the electrical wires and provide a return in the form of the channel (s) formed therein.

In Shape of the inner conduit and the channel within the outer shell is the conduit system according to the invention designed as a double-walled hose line. The inner pipe is preferably made very stiff, so that the fluid with it an overpressure promoted can be. By the outer coat made of a flexible material is the inner pipe secured against buckling and vibration stresses. The flexible outer jacket self needed no reinforcements, but protects the fluid in particular in the inner line against cold and Heat.

Of the modular structure of the conduit system according to the invention leads to the Advantage that at the same time several tasks can be fulfilled. By the inner wire leaves promote a fluid under pressure to a hydraulic consumer, wherein at the same time not needed Part of the fluid used for cooling of the hydraulic consumer serves to through the channel in the outer jacket a storage tank or the like can be fed back. Conveniently, is a heat exchange between the outer jacket and the inner pipe possible. When the fluid in the hydraulic consumer receives heat and subsequently is conveyed back through the channel, will this heat transferred to the inner pipe, so that the fluid pumped back through the channel simultaneously the inner pipe is heated.

Alternatively and / or additionally, the heating of the inner conduit can be effected by energizing one of the pairs of electrical conductors. The temperature of the inner lead can be measured by connecting an instrument amplifier to the other non-energized pair of electrical leads. This is possible if the non-energized pair of electrical lines to the other pair of electrical lines on the consumer side electrically connected, that is connected in parallel. This means that one each Conduction of the pair of first electrical lines and a line of the pair of second electrical lines on the consumer side are electrically connected to each other and to a terminal of an electrical load according to the principle of four-wire technology. Advantageously, an electric current can thereby be conducted through the one pair of electrical lines, whereby information can be obtained by the respective other pair of electrical lines. By connecting an instrument amplifier to the non-energized electrical lines, a voltage can be measured, which drops over it. The voltage measured by means of the instrument amplifier allows a conclusion on the temperature of the non-energized line and thus the inner line to. The same applies to an electrical consumer or its temperature.

By the connection an instrumentation amplifier to the pair of second electrical lines can be in consequence of said Parallel connection with the two first electrical lines of the Measure voltage drop on these lines, resulting in a conclusion to the temperature of the inner pipe, the nozzle and / or the directional control valve is won. Thus, the provision of separate temperature transducers or the like along the duct system or at the nozzle or on the directional valve for temperature measurement is not required.

In Advantageous development of the invention, the pair of first electrical Cables made of a low-resistance metal, for example Copper. Furthermore, the second pair of electrical lines be made of a high-resistance metal, for example a Nickel-chromium alloy or the like, having a low temperature coefficient of electrical resistance. The heating of the inner pipe takes place preferably via the pair of second electrical lines with the high resistance, so that by generating a loss of electrical heat in these Lines heated the inner pipe and thereby the fluid to a desired operating temperature heated becomes. The mentioned compressive stiffness of the inner pipe can be simply by making a wire mesh in a good heat conducting Material is embedded in the form of a plastic matrix. In this Way, the inner pipe can be inexpensively manufactured in long lengths.

In Advantageous development of the invention, the outer jacket of a thermally and / or electrically insulating material, the preferably over a wide temperature range is temperature stable. For this purpose points the outer jacket at least in sections a low thermal conductivity on. This causes a recording of the heating wires in the form of the second pair electrical cables no damage of the outer material, if in the heating wires an electrical heat loss arises. In particular, if the pair of second electrical lines arranged with the high-resistance resistor on an inner side of the outer shell is, the electrical heat loss generated therein mainly after inside in the direction of the inner pipe, but not discharged to the outside. At the same time serves as the outer jacket than Insulating layer for The inner pipe contained therein and protects against cold or heat.

In Advantageous development of the invention may be to the inner line and connected to the channel a hydraulic consumer. Such a hydraulic consumer consists for example of a Directional valve, which at one end of the pipe system to the inner Line and is connected to the at least one channel and a having first switching position and a second switching position. In its first switching position, the directional control valve is switched to flow, wherein it switched to tributary flow in its second switching position is. In the second switching position of the directional control valve, the fluid flows from the inner line in the at least one channel back. The Driving the directional control valve can be done simply by doing it designed as a solenoid valve and to the pair of first electrical lines connected with low resistance. By energizing the first electrical lines enters the directional or solenoid valve from its first switching position to the second switching position, wherein Optionally, the solenoid valve at the same time by energizing this electrical lines is heated. In case of interruption of the energizing the coil of the solenoid valve can be reset to its first switching position simply by a return spring take the valve body due to the spring force back suppressed. By energizing the coil of the solenoid valve with the first electrical Lines that expediently made Copper is a low-loss and precise driving the directional control valve for setting its first or second switching position possible.

In an advantageous embodiment of the invention may be connected to the directional control valve, a nozzle with a defined opening pressure, which is acted upon in the first switching position of the directional control valve with the fluid. In other words, the fluid in the first switching position of the directional control valve can be discharged or ejected from the nozzle when a certain pressure limit value is exceeded. With respect to an SCR exhaust aftertreatment system can thus be by a precise control of the pressure within the inner pipe, the injection timing and the injection amount of the fluid or a urea solution in an exhaust line of the driving steer. If the nozzle is connected to the pair of first electrical lines in the same way as the solenoid valve, it can be advantageously heated when these lines are energized. In particular, in winter operation thereby ensuring a release of the nozzle even at low temperatures and prevents clogging of the nozzle.

The Heating the inner pipe is advantageously carried out by the energizing the two copper wires. If the fluid in the directional valve absorbs heat and thereby heated to an operating temperature, the partial flow of the fluid which is returned through the channel, at the same time the inner line by means of heat conduction heat. Thus, the fluid will be present in the environment Low temperature due to the absorption of heat in the directional valve to a desired Operating temperature heated. Here, the flow rate of the partial flow in the fluid through the Channel increased be to intensify the heat conduction acting on the inner pipe. Heating of the inner pipe can be done in the same way take place that in the directional control valve an excess temperature prevails and thereby heating the fluid to an operating temperature, wherein the flow rate of the fluid in both the inner conduit and are also increased in the partial flow of the fluid in the channel.

at the conduit system according to the invention it is a system of hydraulic and electrical Lines for safe conveying a fluid, e.g. an aqueous solution in a thermally harsh environment. The line system is characterized a high degree of integration of its functions. It serves for simultaneous transport of a fluidic mass flow, a heat flow, an electric current and information, for example the Temperature in the line system itself or connected to it Components prevails.

It it is understood that the above and the following yet to be explained features not only in the specified combination, but also in other combinations or alone, without to leave the scope of the present invention.

The Invention is below several embodiments in the drawing schematically illustrated and with reference to the drawing in detail described.

It demonstrate:

1 an inventive conduit system in a cross-sectional view,

2 a fundamentally simplified switching logic of the line system of 1 .

3a - 3d various switching states of the electrical lines of the conduit system of 1 , and

4 a basic installation of the pipe system of 1 in an exhaust aftertreatment system.

1 shows a conduit system according to the invention 1 in a cross-sectional view. An inner pipe 2 which has a substantially circular cross-section is of an outer shell 3 enclosed. The inner pipe is made of a flexible but pressure-resistant material. For example, there is the inner pipe 2 from a plastic matrix, in which a wire mesh is embedded. The inner pipe 2 is traversed by a fluid. Since the inner conduit is designed to be pressure-resistant, the fluid can flow from a supply unit through the inner conduit 2 be promoted with a positive pressure to a hydraulic resistance or consumer.

The outer coat 3 has four segments 4 on, in contact with the inner pipe 2 are and support these. Between the segments 4 of the outer coat 3 is in each case in the axial direction of the conduit system 1 (ie perpendicular to the plane of the drawing 1 ) a chamber 5 formed, which forms a channel. The channels 5 can also be traversed by a fluid. Thus, the piping system includes 1 two separate delivery chambers for the fluid, namely the inner conduit 2 and the channels 5 , The outer coat 3 is made of a flexible material and has at least in sections a low thermal conductivity. The inner pipe is corresponding 2 through the outer jacket 3 well insulated against heat or cold.

The inner pipe 2 and the channels 5 can be connected to a hydraulic resistance or hydraulic consumers, for example, a directional control valve. Through the inner pipe 2 the fluid is conveyed from a supply unit, for example a tank or the like, to the directional control valve. By a suitable switching of the directional control valve, at least a partial flow of the fluid through the channels 5 - related to the inner pipe 2 in the opposite direction - be promoted. In other words, the channels form 5 a return based on the inner line 2 to return the fluid to the tank or the like.

In the segments 4 of the outer coat 3 are embedded electrical lines. In particular, this is a pair of first electrical lines 6 , which are made of a low-resistance metal. In particular, the material copper is suitable for this purpose. Furthermore, in the segments 4 a pair of second electrical lines 7 embedded, which are made of a high-resistance metal. For this purpose, for example, a nickel-chromium alloy or the like, which has a low temperature coefficient of electrical resistance is suitable. As in 1 shown are the first electrical wires 6 and the second electrical lines 7 each opposite in the segments 4 of the outer coat 3 embedded. Both the copper pipes 6 as well as the electrical wires 7 can each be connected together to form a closed conductor. To the copper pipe 6 or to the electrical lines 7 consisting of the nickel-chromium alloy may be connected to an electrical resistance. This can each one of the two copper lines 6 with one of the two nickel-chromium alloy lines 7 be connected in parallel. The functioning of the electrical cables 6 . 7 is with reference to the 2 and 3 explained in detail.

In 2 is a principally simplified representation of the hydraulic and electrical lines of the piping system 1 shown when it is used to connect a supply unit with a hydraulic consumer. As a supply unit is a tank 8th provided in which a metering pump 9 is arranged. The Tank 8th contains a fluid. Furthermore, a directional control valve 10 provided, which is in the form of a 3/2-way valve and a coil 11 is magnetically controlled. The pipe system 1 connects the tank 8th with the solenoid valve 10 , where the inner pipe 2 a supply line and the channels 5 each form a return line. By operation of the metering pump 9 lets the fluid out of the tank 8th through the inner pipe 2 with overpressure to the solenoid valve 10 promote.

The solenoid valve 10 has a first switching position and a second switching position. In its first switching position, the solenoid valve is switched to flow. To a corresponding output of the solenoid valve 10 is an injector 12 connected in the first switching position of the solenoid valve 10 can be acted upon by the fluid. Between the injector 12 and the solenoid valve 10 is a pressure relief valve 13 provided so that the fluid through the injector 12 is ejected only when exceeding a certain pressure value.

The solenoid valve 10 is switched in its second switching position to the tributary, in which case the fluid from the inner pipe 2 at least partially or completely into the channels 5 is returned. The solenoid valve 10 is by a return spring 14 biased in its first switching position. By energizing the coil 11 becomes the solenoid valve 10 switched to the second switching position to the said backflow of the fluid through the channels 5 to achieve. In the channel 5 or the channels 5 is another pressure relief valve 15 provided that prevents a pressure drop or water hammer.

The electrical wires 6 . 7 of the pipe system 1 are in the upper part of 2 shown. The connections of the two copper lines 6 are labeled A, B, and the connections of the two electrical wires 7 consisting of the nickel-chromium alloy, are designated C, D. The sink 11 is on the two copper wires 6 connected so that the coil 11 forms an electrical resistance or consumer. According to the principle of four-wire technology, the second electrical lines 7 on the consumer side with a corresponding copper line 6 connected in parallel. In other words, each is a copper wire 6 and a second electrical line 7 on the consumer side with each other and with a connection of the coil 11 electrically connected. The sink 11 is operated by energizing the terminals A, B. This means that when applying a current to the two copper wires 6 the solenoid valve 10 is energized to start from its first switching position against the force of the return spring 14 switch to its second switching position. Due to the low resistance of the copper wires 6 is a precise driving of the coil 11 or the solenoid valve 10 guaranteed for a quick switching. When de-energizing the coil 11 , ie when opening the circuit relative to the terminals A, B, the solenoid valve 10 as a result of the return spring 14 shifted back to its first switching position.

A housing of the injection nozzle 12 is with the solenoid valve 10 thermally conductive connected. If the fluid through the injector 12 in the first switching position of the solenoid valve 10 can be injected in the injector 12 increased temperatures occur as a result of the compression of the fluid. To the injector 12 In addition to convection suitable to cool, the solenoid valve 10 by energizing the coil 11 switched to its second switching position, so that the fluid is the solenoid valve 10 flows through it in the tributary, whereby it without a discharge from the injection nozzle 12 from the inner pipe 2 into the channels 5 is redirected. As a rule, the temperature of the fluid in the tank 8th lower than in the injector 12 when there the fluid is injected under pressure. Therefore, a circulation of the fluid in the inner pipe 2 and the channels 5 if the solenoid valve 10 brought into its second switching position, to a cooling of the injection nozzle 12 contribute.

When using a fluid that freezes at low temperatures and according to the Flüs sigzustandand goes into the solid state, is a heating of the pipe system 1 and / or the tank 8th important to ensure trouble-free operation of the injector even in such weather conditions 12 to ensure. Below is with reference to 3 a heating of the pipe system 1 and the components connected to it.

As shown by 3a is to the terminals C, D of the second electrical lines 7 a constant current is applied, with the terminals A, B of the two copper lines 6 are shorted. As a result of a loss of electrical energy in the second electrical lines 7 is generated, the pipe system 1 heated homogeneously in its longitudinal direction. This waste heat acts essentially radially inwards on the inner pipe 2 so that the fluid is thereby heated to a desired operating temperature at an under-temperature present in the environment. The electrical wires 7 form in this switching position the electrical consumer, which in the representation of 3a is shown by a corresponding switching symbol. The Tank 8th can also be suitably heated so that solidification of the fluid therein at the under temperature in the environment is effectively prevented.

In the 3b is a constant current to the terminals A, B of the two copper lines 6 applied, wherein the terminals C, D of the two second electrical lines 7 are de-energized. By energizing the two copper wires 6 As explained above, the solenoid valve 10 transferred to its second switching position, so that the fluid from the inner pipe 2 back to the channels 5 flows and to the tank 8th is promoted back. In addition, the solenoid valve 10 also by energizing the copper wires 6 be heated. If the injector 12 also to the two copper lines 6 is connected, according to the switching position of 3b at the same time the injector 12 be heated. For this purpose, a separate switch may be provided, so that when energizing the terminals A, B by pressing this switch, the injection nozzle 12 optionally heated. The heating of the solenoid valve 10 and / or the injector 12 is in the representation of 3b shown by a corresponding Schalysysmbol. The sink 11 fulfills a dual function: switching the solenoid valve 10 and simultaneously heating it.

In the switching position according to 3c is also applied to the terminals A, B, a constant current, in contrast to 3b now the terminals C, D of the second electrical lines 7 to an instrument amplifier 16 are connected. As explained above, when energizing the two copper lines 6 in addition to a driving of the solenoid valve 10 at the same time the solenoid valve 10 itself and / or the injection nozzle 12 be heated. As a result of the parallel connection of the respective second electrical lines 7 to the corresponding copper lines 6 can by means of the instrumentation amplifier 16 the voltage to be measured in the two second electrical lines 7 drops. The through the instrument amplifier 16 The voltage measured at the terminals C, D can be converted to a temperature at the solenoid valve 10 and / or the injector 12 is present. This means that in the switching position of 3c by energizing the copper wires 6 the solenoid valve and / or the injector 12 is heated, wherein by connecting the instrumentation amplifier 16 at the connections C, D the temperature at the injection nozzle 12 can be measured. The heating of the solenoid valve 10 and / or the injector 12 is in the representation of 3b shown by a corresponding Schalysysmbol.

In the switching position of 3d is a constant current to the terminal C of a second electrical line 7 applied, wherein the terminal A of the parallel-connected copper line 6 is grounded. Thus arises in the energized second electrical line 7 an electrical heat loss, by means of the inner pipe 2 or the fluid guided therein are heated. The instrument amplifier 16 is here to the terminals A and D of the grounded copper line 6 or the non-energized second electrical line 7 connected. By measuring the voltage which drops between the terminals A and D, respectively, a temperature of the electrical line and thus of the line system can be determined 1 determine.

In addition to or in addition to heating the pipe system 1 through the in the second electrical lines 7 generated electrical heat loss, the fluid in the inner pipe 2 be heated by it or kept at a sufficiently high temperature by it in the solenoid valve 10 Absorbs heat. By a backflow of the fluid through the channels 5 This heat is due to the good heat conduction of the inner pipe 2 kept at its operating temperature. In this case, preferably the throughput of the partial flow of the fluid through the channels 5 elevated. The same applies to the case that in the directional valve prevails an excess temperature, whereby the fluid is also heated to an operating temperature. Here are the flow rate of the fluid in the inner pipe 2 and / or the partial flow of the fluid in the channels 5 elevated.

The activation of the solenoid valve 10 for switching between the first and the second Switching position can refer to the explanation according to 2 also done the other way around. This means that the solenoid valve 10 when not energized coil 11 is in its initial state, ie in its second switching position in the tributary, in which the fluid from the inner conduit 2 into the channels 5 is returned. Only with a Bestromen of the copper lines 6 becomes the coil 11 energized and thereby the solenoid valve 10 transferred to the first switching position, in which the injection valve 12 is acted upon by the fluid. After a de-energizing the coil 11 pushes the return spring 14 the solenoid valve 10 back to its second switching position.

It is understood that the control of the coil 11 of the solenoid valve 10 in a different way than through the copper pipes 6 can be done. This means that the coil 11 is connected to other electrical lines and this is energized starting from another external power source to switch the solenoid valve.

4 shows a schematic simplified representation of an SCR exhaust aftertreatment system, in which the conduit system according to the invention 1 is integrated. For the fluid in the tank 8th is an aqueous urea solution, also known as AdBlue ^TM . With the dosing pump 9 it is a diaphragm pump, ideally in the tank 8th is integrated. This helps prevent aspiration problems for the AdBlue ^TM . The dosing pump 9 is with the tank 8th thermally and mechanically coupled and thus protected against environmental influences and fluctuating operating conditions.

The injector 12 is on an exhaust line 17 a diesel engine (not shown) upstream of a catalytic converter 18 connected. The pipe system 1 connects the solenoid valve 10 to which the injector 12 is connected, with the metering pump 9 , The dosing pump 9 creates a continuous flow of AdBlue ^TM from the tank 8th towards the solenoid valve 10 or to the injection nozzle 12 , wherein the flow rate of the maximum required amount of AdBlue ^TM / time unit corresponds. The dosing pump 9 as well as the first electrical wires 6 and the second electrical lines 7 of the pipe system 1 are via contact plugs 19 with a control unit 20 connected, in turn, with a motor control 21 communicates. The flow rate for the fluid or the AdBlue ^TM is via the control unit 20 in a desired range adapted to the operating conditions of the diesel engine, for the solenoid valve 10 to guarantee an optimal operating point.

The solenoid valve 10 is via a thermal insulation on the exhaust system 17 attached, using the injector 12 a spray of AdBlue ^TM can be generated in the exhaust pipe. As explained above, the solenoid valve is 10 to a 3/2-way valve, which by the metering pump 9 supplied AdBlue ^TM volumetric flow for cooling the injection nozzle 12 uses and then back into the tank 8th feeds back. According to the explanation of 2 this will be in the second switching position of the solenoid valve 10 when energizing the copper lines 6 achieved. To prevent boiling of the AdBlue ^TM and to suppress pressure surges, the AdBlue ^{TM operates} through the pressure relief valve 13 biased to a certain level of pressure, but runs in the channels 5 relatively depressurized in the tank 8th back. The solenoid valve 10 is designed so that the valve spool is operated largely pressure-compensated, except for the small opening of the injection nozzle, which is closed by a needle. Thus, a relatively small magnet or a relatively small coil 11 for connecting the solenoid valve 10 be used.

If the copper wires 6 are de-energized at their terminals A, B, the solenoid valve 10 as a result of the return spring 14 transferred to the first switching position, whereby the injection nozzle 12 released and the AdBlue ^TM with a predetermined pressure in the exhaust system 17 is injected. The injector 12 is dimensioned so that at the predetermined injection pressure, the restoring force of the pressure relief valve 13 exceeds a maximum flow through the injector 12 flows. This ensures that when switching the solenoid valve 10 No pressure drop occurs or a water hammer is triggered, which can affect the dosing accuracy. The mean amount of the injected fluid or AdBlue ^TM is thus determined by the duty cycle with which the solenoid valve 10 is operated.

For a trouble-free operation of the exhaust aftertreatment system of 4 a plurality of sensors are provided which check or monitor levels or pressures. In detail, these are a level sensor 22 that the level of the AdBlue ^TM in the tank 8th supervised. Furthermore, in the tank 8th temperature sensors 23 provided the temperature of the AdBlues ^™ inside the tank 8th measure up. A pressure sensor 24 measures the pressure inside the inner pipe 2 , As above with reference to the various switching positions of 3 explained, the temperature of the injector 12 or the management system 1 by means of an instrument amplifier 16 be determined, which is suitable for the electrical wiring 6 . 7 is connected.

The outer coat 3 is made of a flexible material and protects the inner pipe 2 against bending and vibration stresses, esp dere through the segments 4 that the inner line 2 support. The outer coat 3 itself requires no reinforcements, and serves as an insulation for the inner conduit due to its low thermal conductivity 2 , The outer coat 3 is assembled according to the requirements of the vehicle manufacturer in length and attached to the vehicle chassis suitable.

It is understood that the conduit system according to the invention 1 can also be used in any other applications in which the heating of a line carrying the fluid, a circulation function eg for cooling a hydraulic consumer, transporting electrical signals that allow a conclusion on a temperature of the conduit system itself or of components connected thereto , and / or any other advantageous effect as explained above are of importance.

Claims (37)

Line system ( 1 ) for conveying a fluid, with an inner conduit ( 2 ), through which the fluid flows, at least one pair of first electrical lines 6 attached to the inner pipe ( 2 ) are mounted substantially in the longitudinal direction and connected to each other to form a closed conductor, and with at least a pair of second electrical lines ( 7 ) on the inner pipe ( 2 ) are mounted substantially in the longitudinal direction and connected to each other to form a closed conductor, wherein the pair of first electrical lines 6 and / or to the pair of second electrical lines ( 7 ) a current can be applied, so that the inner line ( 2 ) is heated by heating the electrical wires. Line system ( 1 ) according to claim 1, wherein the inner conduit ( 2 ) of an outer jacket ( 3 ) is enclosed Line system ( 1 ) according to claim 2, wherein in the outer shell ( 3 ) at least one channel ( 5 ) formed by a fluid, in particular in a direction opposite to the inner line ( 2 ) is flowed through, so that the channel ( 5 ) relative to the inner pipe ( 2 ) forms a return. Line system ( 1 ) for conveying a fluid, with an inner conduit ( 2 ), which is traversed by the fluid, and an inner tube enclosing the outer jacket ( 3 ), in which at least one channel ( 5 ) formed by a fluid, in particular in a direction opposite to the inner line ( 2 ) is flowed through, so that the channel ( 5 ) relative to the inner pipe ( 2 ) forms a return. Line system ( 1 ) according to claim 4, with at least one pair of first electrical lines ( 6 ) mounted on the inner lead substantially in the longitudinal direction thereof and connected together to form a closed conductor, and having at least a pair of second electrical leads (10). 7 ), which are attached to the inner lead substantially in the longitudinal direction thereof and connected to each other to form a closed conductor, wherein to the pair of first electrical lines ( 6 ) and / or to the pair of second electrical lines ( 7 ) a current can be applied, so that the inner line ( 2 ) is heated by heating the electrical wires. Line system ( 1 ) according to one of Claims 2 to 5, in which the outer jacket ( 3 ) over four radial segments ( 4 ) supports the inner line, the electrical lines ( 6 . 7 ) in each of the four segments ( 4 ) are embedded. Line system ( 1 ) according to claim 6, wherein the outer jacket ( 3 ) between the four segments each having an axially extending chamber, each of the channel ( 5 ) trains. Line system ( 1 ) according to one of claims 1 to 7, in which the pair of first electrical lines ( 6 ) and / or to the pair of second electrical lines ( 7 ) An electrical resistance can be connected. Line system ( 1 ) according to one of claims 1 to 8, in which in each case an electrical line ( 7 ) of the pair of first electrical lines with a corresponding electrical line ( 6 ) of the pair of second electrical lines is connected in parallel. Line system ( 1 ) according to claim 9, in which to a line ( 6 ) of the first electrical lines and to a line ( 7 ) of the second electrical lines, a current can be applied, so that the heating of the inner line ( 2 ) via at least one of these two electrical lines. Line system ( 1 ) according to one of claims 1 to 10, in which the to the respective electrical lines ( 6 . 7 ) is constant, wherein the electric current in the two lines is substantially the same in amount. Line system ( 1 ) according to one of claims 1 to 11, in which the first or the second electrical line ( 6 . 7 ) to which a current is applied is an input of an instrumentation amplifier ( 16 ), the other input of the instrumentation amplifier ( 16 ) Is connectable to the respective other first or second electrical line, so that so that the voltage or the temperature of the latter line is measurable. Line system ( 1 ) according to one of claims 1 to 12, in which the pair of first electrical lines ( 6 ) of a low-resistance metal and the pair of second electrical lines ( 7 ) are made of a high-resistance metal. Line system ( 1 ) according to claim 13, wherein the heating of the inner conduit by the application of a current to the pair of second electrical lines ( 7 ) he follows. Line system ( 1 ) according to claim 14, wherein the fluid in the inner conduit ( 2 ) at a sub-temperature present in the environment by generating a loss of electrical loss in at least one of the lines of the pair of second electrical lines ( 7 ) can be heated with high resistance to an operating temperature. Line system ( 1 ) according to claim 14 or 15, wherein the pair of second electrical lines ( 7 ) has a low temperature coefficient with respect to the electrical resistance. Line system ( 1 ) according to one of claims 1 to 16, in which the electrical lines ( 6 . 7 ) on an outer wall of the inner pipe ( 2 ) or adjacent thereto. Line system ( 1 ) according to one of claims 2 to 17, in which the electrical lines ( 6 . 7 ) in the outer jacket ( 3 ) are embedded. Line system ( 1 ) according to one of claims 2 to 18, in which the outer jacket ( 3 ) is made of an insulating and / or temperature-stable material. Line system ( 1 ) according to one of claims 1 to 19, in which the inner conduit ( 2 ) is made of a flexible and pressure-resistant material. Line system ( 1 ) according to claim 20, wherein the inner conduit ( 2 ) is made of a highly thermally conductive material and in particular of a plastic matrix, in which a wire mesh is embedded exists. Line system ( 1 ) according to one of claims 3 to 21, in which the inner pipe ( 2 ) and to the canal ( 5 ) a hydraulic resistance ( 10 . 12 ) is connectable. Line system ( 1 ) according to one of claims 1 to 22, further comprising a directional control valve ( 10 ), which at one end of the conduit system to the inner conduit ( 2 ) and to the at least one channel ( 5 ) is connected and has a first switching position and a second switching position, wherein the directional control valve ( 10 ) is switched to flow in the first switching position and to the secondary flow in the second switching position, wherein the fluid in the second switching position of the inner line ( 2 ) into the at least one channel ( 5 ) flows back. Line system ( 1 ) according to claim 23, wherein the directional control valve ( 10 ) is a solenoid valve. Line system ( 1 ) according to claim 24, wherein at the directional valve a nozzle ( 12 ) is connected with a defined opening pressure, which is acted upon in the first switching position of the directional control valve with the fluid, so that the fluid from the nozzle ( 12 ) is dischargeable. Line system ( 1 ) according to claim 24 or 25, wherein the coil ( 11 ) of the solenoid valve ( 10 ) by means of the pair of first electrical lines ( 7 ) is energized with low resistance, thereby switching the directional control valve from the first switching position to the second switching position and / or the directional control valve ( 10 ) and / or the nozzle ( 12 ) are heated. Line system ( 1 ) according to claim 26, wherein the solenoid valve comprises a return spring ( 14 ), which the solenoid valve ( 10 ) returned to a starting position. Line system ( 1 ) according to one of claims 23 to 27, wherein the nozzle ( 12 ) to the pair of first electrical lines ( 6 ) is connected with low-resistance, so that the nozzle ( 12 ) when energizing these lines ( 6 ) is heated. Line system ( 1 ) according to claim 28, wherein the pair of second electrical lines ( 7 ) an instrument amplifier ( 16 ) is connected, due to the parallel connection with the first two electrical lines, the voltage drop across these lines and thus the temperature of the solenoid valve ( 10 ) and / or the nozzle ( 12 ) to eat. Line system ( 1 ) according to one of claims 13 to 27, in which one of the second electrical lines ( 7 ) is applied with a high-impedance resistor, a constant current, wherein the parallel-connected first electrical line ( 6 ) is connected to ground with low resistance to the inner line ( 2 ) by means of the first electrical line, wherein an input of an instrumentation amplifier ( 16 ) to the grounded first electrical line ( 6 ) and the other input of the instrumentation amplifier are connected to the respective other line of the first and second electrical line, so as to the temperature of the energized second electrical line ( 7 ). Line system ( 1 ) according to one of claims 23 to 30, in which the fluid in the inner conduit ( 2 ) at a low temperature present in the environment by a heat absorption in the directional control valve ( 10 ) is heated to an operating temperature, wherein the flow rate of the partial flow of the fluid through the channel ( 5 ) is increased. Line system ( 1 ) according to claim 31, wherein the solenoid valve ( 10 ) is energized by means of the lines of the pair of first electrical lines made of low-resistance metal, wherein the terminals of the lines of the pair of second electrical lines of high-resistance metal are open. Line system ( 1 ) according to one of claims 23 to 32, in which the fluid in the inner conduit ( 2 ) in the presence of an under temperature in the environment by a directional control valve ( 10 ) is heated to an operating temperature, wherein the flow rate of the fluid in the inner conduit ( 2 ) and / or the partial flow of the fluid in the channel ( 5 ) is increased. Line system ( 1 ) according to any one of claims 12 to 33, wherein said low-resistance metal is made of copper or the like and said high-resistance metal is made of a nickel-chromium alloy or the like having a low temperature coefficient. Line system ( 1 ) according to one of claims 3 to 34, in which the channel ( 5 ) of a partial flow of the inner conduit ( 2 ) flowing fluid with respect to the inner conduit ( 2 ) can be flowed through in the opposite direction, wherein heat from the channel to the inner line is transferable. Line system ( 1 ) according to one of claims 2 to 35, in which the outer jacket ( 3 ) at least partially has a low thermal conductivity. Line system ( 1 ) according to one of claims 1 to 36, in which in each case one line ( 6 ) of the pair of first electrical lines and a line ( 7 ) of the pair of second electrical lines on the load side are electrically connected to each other and to a terminal of an electrical load according to the principle of four-wire technology.