IT201900018572A1 - LIQUID FEED UNIT ON BOARD VEHICLE AND LIQUID FEED ASSEMBLY ON BOARD VEHICLE - Google Patents

Description

DESCRIPTION

FIELD OF APPLICATION

[0001] The present invention relates to an on-board liquid supply unit and a relative on-board liquid supply assembly. STATE OF THE TECHNIQUE

[0002] In recent times, in the field of internal combustion engines for automotive use, storage and controlled dispensing devices of liquids have become increasingly widespread to optimize the direct and / or indirect operation of internal combustion engines.

[0003] In particular, these devices provide for the controlled injection of water into the combustion chamber (typically in petrol-fueled internal combustion engines but not only) and the injection of a solution of water and urea for the treatment of gas exhaust in diesel fueled internal combustion engines.

[0004] In particular, the 'water injection' technology involves injecting water directly or indirectly (through the intake duct) into the combustion chamber to mitigate the tendency to detonate and to contain the temperature of the exhaust gases. Also in diesel cycle engines, water could be injected into the combustion chamber in the same way but with the aim of reducing the formation of nitrogen oxides.

[0005] Furthermore, in Diesel cycle engines there may be the need to inject demineralized water mixed with urea into the exhaust gas treatment system in the presence of a variable concentration SCR system.

[0006] All these applications therefore require a certain volume of liquid, comprising demineralized water and / or urea on board the vehicle, typically contained in a suitable tank.

[0007] These liquids, as seen, are used directly in the combustion chamber (water) or along the discharge line (water-urea mixtures).

[0008] The known solutions provide for the construction of liquid storage tanks (water / urea) which must be equipped with a plurality of accessories such as liquid filtering / control systems, liquid pumping systems, delivery and adduction ducts for create recirculation of liquids and heating systems that serve to defrost, if necessary, liquids that tend to solidify due to low temperatures. In fact, these liquid tanks are usually arranged in the lower part of the vehicle and in any case are not housed inside the passenger compartment, but are arranged outside and therefore can be subjected to temperatures that can reach several degrees below 273K.

[0009] It is clear that in the case of a water tank it is sufficient to reach 273 K to obtain the solidification of the liquid, while in the case of mixtures of water and urea it is also necessary to go below 260K.

[0010] The known solutions have some drawbacks and disadvantages.

[0011] In fact, it is necessary to ensure that the thawing of the liquid is as fast as possible because, as long as the liquid is in the solid phase, it is not possible to pump it into the engine and / or the exhaust system: therefore the operation of the propulsion unit does not is optimized.

[0012] Therefore it is necessary to provide a device that allows the defrosting of the liquid if necessary in extremely short times.

[0013] Obviously, this device must also be economical and reliable and must involve energy consumption which is as low as possible.

PRESENTATION OF THE INVENTION

[0014] The need is therefore felt in the art to solve the drawbacks and limitations mentioned in reference to the prior art.

[0015] This need is satisfied by a liquid supply unit on board the vehicle according to claim 1 and by a relative liquid supply unit on board the vehicle according to claim 13.

Other embodiments of the present invention are described in the dependent claims.

DESCRIPTION OF THE DRAWINGS

[0017] Further characteristics and advantages of the present invention will be more understandable from the description, reported below, of its preferred and non-limiting embodiments, in which:

[0018] figure 1 represents an overall schematic view of an on-board liquid supply assembly, according to an embodiment of the present invention;

[0019] figure 2 represents an overall schematic view of an on-board liquid supply assembly, according to a further embodiment of the present invention;

[0020] figure 3 represents a schematic perspective view of a liquid supply unit according to an embodiment of the present invention;

[0021] Figure 4 is a sectional view of an enlarged detail of the power supply unit of Figure 3.

[0022] The elements or parts of elements in common between the embodiments described below will be indicated with the same numerical references.

DETAILED DESCRIPTION

[0023] With reference to the aforementioned figures, 4 generally indicates an assembly for supplying liquids on board the vehicle.

[0024] It should be noted that the term vehicle must be understood in a broad sense; in other words, the present invention finds easy application in any type of vehicle equipped with an internal combustion engine 6, fed with any type of fuel.

[0025] The feeding assembly 4 comprises a liquid tank 8, a feeding group 12 for feeding said liquid into the vehicle, an integrated module 80, a feeding system 28 and related injectors 29,33, as best described below.

[0026] The liquid reservoir 8 can have any shape and size and can be made both with metallic materials and, preferably, with polymeric materials.

[0027] The feeding assembly 12 is fluidly associated with said liquid reservoir 8.

[0028] The feeding assembly 12 comprises a pump 16 having a pump body 20 provided with a chamber 24 for containing a liquid. The containment chamber 24 is not necessarily a containment volume for the liquid in the strict sense, but can simply be constituted by passageways of liquid inside the devices that make up the pump 16. Therefore, the containment chamber 16 is intended as a generic volume that receives liquid inside the pump body 20, ie between a liquid supply duct 40 and a liquid distribution duct 44, better described below.

[0029] The at least one pump 16 is configured to send said liquid to a fuel system 28 of the internal combustion engine 6 and / or to an exhaust gas treatment system 28a of the internal combustion engine 6.

[0030] The fuel system 28 will in turn be equipped with injectors 29 configured to inject the liquid directly into the combustion chamber (direct injection) or into a pre-chamber (indirect injection). The exhaust gas treatment system 28a of the internal combustion engine 6 may be equipped, for example, with an injector 33 configured to inject the liquid along the exhaust line.

[0031] Typically, demineralized water is used as the liquid for injection into the fuel system 28, while a mixture of water and urea is used for injection into the exhaust gas treatment system 32 of the internal combustion engine 6.

[0032] The pump body 20 is equipped with a relative electric motor 36 for pumping said liquid.

[0033] For the purposes of the present invention, the electric motor can be of any power and type, according to the capacity requirements dictated by its use.

[0034] The pump body 20 is also equipped with a liquid supply duct 40 entering said pump body 20, and a liquid distribution duct 44 leaving said pump body 20.

[0035] In particular, the liquid supply duct 40 is in turn fluidly connected with said liquid reservoir 8 from which it receives the liquid to be fed to the containment chamber 24 of the pump body 20.

[0036] The liquid distribution duct 44 is in turn fluidly connected with the fuel system 28 of the engine 6 or with the exhaust gas treatment system 28a, according to the intended use (and consequently to the liquid used), so that the liquid can be dispensed through the respective injectors 29,33.

[0037] The feeding assembly 12 further comprises a heater 48, for example positioned on the pump body 20, to heat the liquid contained in the pump body 20 and / or in said supply ducts 40 and distribution 44, to heat the pump body 20, thaw any liquid present inside it (in particular in the containment chamber 24) and avoid freezing of the liquid in operating phases at temperatures below 273 K.

[0038] According to a possible embodiment, the heater 48 is associated with the pump body 20 on the opposite side with respect to the electric motor 36. In this way the pump body 20 benefits from the heat or thermal flow coming both from the actual heater and from the electric motor 36. Furthermore, the pump body 20 is exposed to the environment as little as possible since, at opposite ends, it is shielded by the heater 48 and by the electric motor 36 respectively.

[0039] The heating element 48 can be a rigid electric heater, for example composed of PTC pads that is spread over almost all of the pump body 20.

[0040] The heater device 48 may comprise an electrical thermo-resistance; alternatively or in addition, said heating device 48 can also comprise a liquid-liquid heat exchanger.

[0041] The heating element 48 can deliver a modulable power, which can be higher in the case of using water, and lower in the case of water-urea mixtures, necessary to ensure the thawing of a volume of liquid sufficient to allow delivery and subsequent injection of liquid through the injectors 29,33.

[0042] The heating element 48 can be made in various ways. For example, the heating element 48 can comprise a module associated externally to the pump body 20, preferably, but not exclusively, on the opposite side with respect to the electric motor 36,

[0043] It is also possible to provide that said heater includes a module inserted at least partially inside the pump body 20.

[0044] Furthermore, the heating element 48 can be constituted at least partially, or even integrally, by the electric motor 36 associated with the pump body 20.

[0045] In other words, it is possible to make a heating element 48, or to use, partially or integrally, the electric motor 36 as the heating element of the pump body 20. In any case, the electric motor 36 contributes to the function of the heating element of the pump body 20.

[0046] According to an embodiment, the liquid supply duct 40 is provided with an inlet filter 52.

[0047] Preferably, said inlet filter 52 is arranged at the inlet of the pump body 20 so as to be influenced by the heat generated by the heater 48.

[0048] Said inlet filter 52 to pump 16 is used to filter the fluid (be it water or a water-urea mixture) entering the pump body 20 and prevent particles released by the pump 16 from ending up in the liquid tank 8 in circuit emptying phase.

[0049] According to an embodiment, the distribution duct 44 is provided with an outlet filter 56.

[0050] Preferably, said outlet filter 56 is arranged at the outlet of the pump body 20 so as to be influenced by the heat generated by the heater 48.

[0051] The outlet filter 56 arranged on the distribution duct 44 of the pump body 20 is used to prevent particles released by the pump 16 during operation from ending up in the calibrated recirculation hole 68 (better described below) and / or in the injectors 29,33 filling them.

[0052] According to an embodiment, said inlet filters 52 and outlet 56 are mesh filters, preferably with metal mesh. It is also possible to provide mesh filters with plastic mesh.

[0053] Preferably, said filters provide a mesh comprised between 10 microns and 30 microns.

[0054] According to an embodiment, said inlet filters 52 and outlet 56 have a circular shape and are positioned inside the respective ducts 40,44 being substantially counter-shaped with respect to the passage lumen of the ducts themselves.

[0055] According to an embodiment, said filters are positioned in proximity to a coupling section of the respective supply ducts 40 and distribution 44 in the pump body 20. In this way there are two advantages.

[0056] On the one hand, after removing the supply pipes 40 and distribution pipes 44 from the pump body 20, it is possible to easily and quickly access the filters for their respective removal, cleaning and / or replacement.

[0057] On the other hand, the filters 52,56 at least partially receive the heat flow coming from the heater 48 and therefore actively contribute in turn to the thawing of the liquid.

[0058] The positioning and locking of the filters can take place by driving each filter 52,56 into the pump body 20 by interference; it is also possible to lock each filter 52,56 between a shoulder 58 of the pump body 20 and a threaded hydraulic connection 59 of the corresponding liquid supply duct 40 or liquid distribution duct 44.

[0059] The inlet filter 52 and / or outlet 56 can be provided with a plastic or metal frame; in the case of driving it is possible to foresee the presence of a metal ring external to the frame itself.

[0060] According to a possible embodiment, the distribution duct 44 is provided with a recirculation branch 60 equipped with a relative recirculation valve 64 with a calibrated hole 68.

[0061] Said recirculation branch 60 is fluidly connected to the liquid reservoir 8, so as to recirculate the liquid leaving the pump 16 in said liquid reservoir 8.

[0062] The recirculation valve 64 with calibrated hole 68 is calibrated in such a way as to guarantee a minimum flow of fluid (water / water-urea mixture) in order to cool the pump 16. The integrated module 80 for the control and management of liquids on board the vehicle can comprise a plurality of sensors, such as for example a liquid quality sensor, and / or at least one liquid level sensor and / or at least one liquid temperature sensor. Said integrated module is preferably mechanically connected to the tank 8.

[0063] As can be appreciated from what has been described, the present invention allows to overcome the drawbacks presented in the known art.

[0064] The present invention makes it possible to significantly reduce the thawing times of the liquid in the feeding group, compared to the solutions of the known art.

[0065] Furthermore, the invention allows to effectively counteract the tendency to freeze the liquid inside the power supply unit, both thanks to the fact that it allows to effectively channel the heat flow of the heater and of the electric motor of the pump into the pump body, and because it provides for an effective recirculation of liquid which in turn tends to counteract the solidification of the liquid.

[0066] Furthermore, the positioning of the filters, both inlet and outlet, in correspondence with the pump body allows to improve the operation of the pump. In fact, on the one hand, the inlet filter prevents particles released by the pump from ending up in the liquid tank when emptying the circuit and also protects the pump from any particles present inside the tank that can damage the pump itself.

[0067] On the other hand, the outlet filter prevents particles released by the pump during operation from ending up in the calibrated recirculation hole 68 (better described below) and / or in the injectors by clogging them. In addition, the downstream filter also protects the pump during the emptying phase from particles that can be sucked in by the injectors.

[0068] Furthermore, the positioning of said filters in correspondence with the pump body ensures that the heat supplied to the pump body can effectively reach the filters themselves: this aspect is relevant since the filters, constituting a mechanical barrier to the passage of the liquid, they normally constitute portions in correspondence with which the liquid tends more easily to freeze. Therefore, the heating of the pump body allows the defrosting of the water that may have remained on the filters after the previous emptying.

[0069] The advantage of this solution is to integrate in the pump body all the components that are needed to be able to operate a pump, outside the tank, in different operating-environmental conditions, in a water injection system and / or in a selective catalyst reduction (SCR) system.

[0070] A person skilled in the art, in order to meet contingent and specific needs, may make numerous changes and variations to the modules described above, all of which are contained within the scope of the invention as defined by the following claims.

Claims (14)

CLAIMS A liquid supply unit (12) on board the vehicle, comprising - a pump (16) comprising a pump body (20) equipped with a containment chamber (24) for a liquid, in which the pump body (20) is equipped with a relative electric motor (36) for pumping said liquid , - a delivery duct (40) of liquid entering said pump body (20), - a distribution duct (44) of liquid leaving said pump body (20), - a heating device (48) to heat the liquid contained in the pump body (20) and / or in said supply (40) and distribution ducts (44), so as to heat the pump body (20), thaw the any liquid present inside it and avoid freezing of the liquid in operating phases at temperatures below 273 K, - in which the supply duct (40) is equipped with an inlet filter (52), arranged at the inlet of the pump body (20) so as to be influenced by the heat generated by the heater (48), - in which the distribution duct (44) is equipped with an outlet filter (56) arranged at the outlet of the pump body (20) so as to be influenced by the heat generated by the heater (48). Power supply unit (12) according to claim 1, wherein said inlet (52) and / or outlet (56) filters are mesh filters, preferably with metal mesh. Power supply unit (12) according to claim 1 or 2, wherein said inlet (52) and / or outlet (56) filters have a mesh comprised between 10 microns and 30 microns. Feeding group (12) according to any one of claims 1 to 3, wherein said inlet (52) and / or outlet (56) filters have a circular shape and are positioned inside the respective supply ducts ( 40) and distribution (44) being substantially counter-shaped with respect to a passage lumen of the same ducts (40,44). Feeding unit (12) according to any one of claims 1 to 4, in which each filter (52,56) is inserted into the pump body (20) by interference. 6. Feeding unit (12) according to claim 1, in which each filter (52,56) is blocked between a shoulder (58) of the pump body (20) and a threaded hydraulic connection (59) of the corresponding supply duct liquid (40) or liquid distribution conduit (44). Feeding group (12) according to any one of the preceding claims, wherein said heating device (48) comprises a module associated externally to the pump body (20). 8. Power supply unit (12) according to any one of the preceding claims, wherein said heater device (48) comprises a module inserted at least partially inside the pump body (20). Feeding unit (12) according to any one of the preceding claims, wherein said heating device (48) is constituted at least partially by the electric motor (36) associated with the pump body (20). Feeding unit (12) according to any one of the preceding claims, in which the heating device (48) is associated with the pump body (20) on the opposite side with respect to the electric motor (36). Feeding unit (12) according to any one of claims 1 to 10, wherein the distribution duct (44) is provided with a recirculation branch (60) equipped with a relative recirculation valve (64) with a calibrated hole (68). Feeding unit (12) according to claim 11, wherein the recirculation valve (64) with calibrated hole (68) is calibrated so as to ensure a minimum flow of fluid (water / water-urea mixture) in order to cool the pump (16). 13. Supply assembly (4) for liquids on board the vehicle, comprising: - a liquid reservoir (8), - a fuel system (28) of an internal combustion engine (6) and / or an exhaust gas treatment system (28a) of an internal combustion engine (6), - a feed assembly (12) according to any one of claims 1 to 12, said assembly (12) being fluidly associated with said liquid reservoir (8) and being mechanically separated from the liquid reservoir (8). On-board liquid supply assembly (4) according to claim 13, comprising: - an integrated module (80) for the control and management of liquids on board the vehicle mechanically connected to the tank (8), - a fuel system (28) and / or an exhaust gas treatment system (28a) connected via the liquid distribution pipe (44), - injectors (29) configured to inject the liquid directly into the combustion chamber or in a pre-chamber, or an injector (33) configured to inject the liquid along the exhaust gas treatment system (32).