U.S. patent application number 10/552864 was filed with the patent office on 2007-07-19 for method for metering a reagent into the exhaust gas flow of an internal combustion engine.
Invention is credited to Michael Gerlach.
Application Number | 20070163238 10/552864 |
Document ID | / |
Family ID | 33038954 |
Filed Date | 2007-07-19 |
United States Patent
Application |
20070163238 |
Kind Code |
A1 |
Gerlach; Michael |
July 19, 2007 |
Method for metering a reagent into the exhaust gas flow of an
internal combustion engine
Abstract
A method for metering a reagent into the exhaust gas flow of an
internal combustion engine is provided, in which the reagent is
guided in at least one component and in which a measure for the
temperature of the component is recorded. The measure for the
temperature is compared to a predefined temperature threshold
value. A counter counts the number of times the threshold is
exceeded. If the counter state exceeds a predefined count threshold
value, a service signal is emitted. The temperature threshold value
is fixed, for example, at the freezing temperature of the reagent.
One embodiment provides that the counter counts an exceeding of the
temperature threshold value only when the component is filled with
the reagent.
Inventors: |
Gerlach; Michael;
(Waiblingen-Neustadt, DE) |
Correspondence
Address: |
KENYON & KENYON LLP
ONE BROADWAY
NEW YORK
NY
10004
US
|
Family ID: |
33038954 |
Appl. No.: |
10/552864 |
Filed: |
March 11, 2004 |
PCT Filed: |
March 11, 2004 |
PCT NO: |
PCT/EP04/50287 |
371 Date: |
June 16, 2006 |
Current U.S.
Class: |
60/286 ; 60/295;
60/301 |
Current CPC
Class: |
F01N 3/2066 20130101;
B01D 53/90 20130101; B01D 53/9431 20130101; Y02T 10/12 20130101;
B01D 53/9495 20130101; F01N 2610/02 20130101; Y02T 10/24
20130101 |
Class at
Publication: |
060/286 ;
060/295; 060/301 |
International
Class: |
F01N 3/00 20060101
F01N003/00; F01N 3/10 20060101 F01N003/10 |
Foreign Application Data
Date |
Code |
Application Number |
Apr 9, 2003 |
DE |
10316184.8 |
Claims
1-10. (canceled)
11. A method for metering a reagent into an exhaust gas flow of an
internal combustion engine, the method comprising: guiding the
reagent in at least one component; recording a measure for a
temperature of the component; comparing the measure for the
temperature to a predefined temperature threshold value; counting a
number of times the temperature threshold value is exceeded in a
counter; predefining a count threshold value for the number of
times the temperature threshold value is exceeded; and making
available a service signal in response to an exceeding of the count
threshold value.
12. The method according to claim 11, wherein the temperature
threshold value is equivalent to a freezing temperature of the
reagent.
13. The method according to claim 12, further comprising, after
shutting down the internal combustion engine, during coasting,
ascertaining whether the component is filled with the reagent.
14. The method according to claim 13, wherein the counter is an ice
counter, and the ice counter counts an exceeding of the temperature
threshold value only when the component is filled with the frozen
reagent.
15. The method according to claim 13, wherein, during the
ascertaining of whether the component is filled with the reagent, a
compressed air signal is evaluated.
16. The method according to claim 13, wherein, during the
ascertaining of whether the component is filled with the reagent,
an operation of an emergency stop switch is taken into
consideration.
17. The method according to claim 11, further comprising counting
an exceeding of the temperature threshold value only at a start of
the internal combustion engine.
18. The method according to claim 11, further comprising obtaining
the measure for the temperature of the component from a signal of
at least one temperature sensor.
19. The method according to claim 18, wherein the temperature
sensor records the temperature of the component.
20. The method according to claim 18, wherein the temperature
sensor records an air temperature.
Description
BACKGROUND INFORMATION
[0001] In German Patent Application No. DE 101 39 142, a measuring
device is described for ascertaining a concentration of a
urea-water solution, which is applied as a reagent for an NOx
adsorption catalyst in the exhaust gas flow of an internal
combustion engine. From the urea-water solution ammonia is obtained
which, in a regeneration phase of the NOx adsorption catalyst,
brings about a reduction of nitrogen oxides. An ascertainment of
the concentration of the urea-water solution is provided, whereby a
precise metering of the reducing agent into the exhaust gas flow
may be implemented. An indirect measuring method for ascertaining
the concentration is provided, in which the vapor pressure of the
urea-water solution, that is stored in a storage vessel, is
measured, using a pressure sensor. The vapor pressure is created by
the ammonia generated because of the hydrolysis of the urea plus
the vapor pressure of the solvent water, so that because of the
layout, an evaluation unit is able to ascertain the correspondingly
reduced urea quantity or the urea concentration in the urea-water
solution.
[0002] Also provided is a temperature sensor for registering the
temperature of the urea-water solution. Using the signal of the
temperature sensor, the dependence of the pressure on the
temperature may be taken into consideration. The urea-water
solution has a freezing point which is approximately -11 degrees C.
To the extent that the previously known metering device is exposed
to environmental conditions, the freezing of the urea-water
solution cannot be excluded. The sudden change in density in
connection with the freezing mechanically stresses the components
that are filled with the urea-water solution.
[0003] An object of the present invention is to provide a method
for metering a reagent into the exhaust gas flow of an internal
combustion engine, which increases reliability.
SUMMARY OF THE INVENTION
[0004] The method according to the present invention, for metering
a reagent into the exhaust gas flow of an internal combustion
engine, in which the reagent is guided in at least one component
and in which a measure of the temperature of the component is
recorded, provides that the measure for the temperature is compared
to a predefined temperature threshold value, that the number of the
threshold exceedings are counted in a counter, that the count
threshold value for the number of threshold exceedings is
specified, and that a service signal is made available when the
count threshold value is exceeded.
[0005] The method according to the present invention makes it
possible to detect a one-time, or, preferably a multiple exceeding
of the temperature threshold value, and thereupon to make available
the service signal. The measure for the temperature of the
component similarly reflects the temperature of the reagent. The
temperature threshold value is, for example, established at a value
at which one property of the reagent changes. The service signal
then indicates that the property of the reagent has changed once or
several times. The service signal may be used as notice that, for
example, the component in which the reagent is carried, or the
reagent itself should be exchanged. The method according to the
present invention thereby increases the reliability of metering the
reagent into the exhaust gas flow of the internal combustion
engine.
[0006] One embodiment provides that the temperature threshold value
is equivalent to the freezing temperature of the reagent. Using
this embodiment, freezing of the reagent or, for instance, a
possible icing up of the component is detected by the reagent
possibly contained therein.
[0007] One embodiment provides that, after the shutting down of the
internal combustion engine, it is ascertained during coasting
whether the component is filled with the reagent. Using this
measure, the additional decisions may be made dependent on whether
there is still reagent in the component after the shutting down of
the internal combustion engine.
[0008] This embodiment forms the basis for the further embodiment
of the present invention, according to which the counter is
designed as an ice counter. The ice counter counts an exceeding of
the temperature threshold value only when the component is filled
with the frozen reagent. Thereby it may be reliably detected how
often the component filled with the reagent has frozen, and whether
the number of freezing episodes has exceeded the counter threshold
value. The service signal may be seen as a notice, to test the
component, and, if necessary, to exchange it.
[0009] One embodiment provides that, during the ascertainment as to
whether the component is filled with the reagent, an air pressure
signal is analyzed. As a function of a definite embodiment of the
metering of the reagent, purging (blowing out) the reagent by
compressed air may be provided. Thereby it may be ensured that, for
instance, after the shutting down of the internal combustion
engine, there is no longer any reagent in the component.
[0010] Another embodiment provides that, during the ascertainment
as to whether the component is filled with the reagent, the
operation of an emergency stop switch is taken into consideration.
In general, the operation of an emergency stop switch will prevent
coasting, so that one may assume that the component is filled with
the reagent.
[0011] One embodiment provides that an exceeding of the temperature
threshold value is counted only at the starting of the internal
combustion engine. Using this measure, the point in time of
counting the individual exceedings of the temperature threshold
value is established exactly. To the extent that in the exceeding
of the temperature threshold value an exceeding towards lower
temperatures is involved, one may assume that the coldest
temperature is present at the starting procedure.
[0012] One embodiment provides that the measure for the temperature
of the component is obtained from the signal of at least one
temperature sensor. The temperature sensor may, for instance,
record the temperature of the component or the air temperature.
BRIEF DESCRIPTION OF THE DRAWING
[0013] The FIGURE shows a technical environment in which a method
according to the present invention proceeds.
DETAILED DESCRIPTION
[0014] The Figure shows an internal combustion engine 10, that has
a catalytic converter 11 post-connected to it for exhaust gas
purification. A metering valve 14 is provided for adding a reagent
13 into exhaust gas flow 12 of internal combustion engine 10.
Reagent 13 is made available by a reagent pump 15, which obtains
reagent 13 from a reagent storage tank 16. Both reagent pump 15 and
metering valve 14 may be purged using compressed air that is
supplied by a compressor 17.
[0015] Metering valve temperature signal 19 made available by a
metering valve temperature sensor 18 that is assigned to metering
valve 14, reagent pump temperature signal 21 made available by a
reagent pump temperature sensor 20 that is assigned to reagent pump
15, reagent tank temperature signal 23 made available by a reagent
tank temperature sensor 22 that is assigned to reagent tank 16, as
well as temperature sensor signal 25 made available by a
temperature sensor 24 are supplied to a temperature selection 26,
which emits a temperature signal 27 to a first comparator 28.
[0016] First comparator 28 compares temperature signal 27 to a
temperature threshold value 29, and, as a function of the
comparison result, emits a temperature warning signal 30 both to a
first AND operation 31 and to a second AND operation 32. The two
AND operations 31, 32 also receive clamp-15 (terminal-15) signal 34
supplied by key switch 33. Second AND operation 32 also receives a
purging error signal 36 stored by a memory 35.
[0017] A vehicle electrical system 37 is connected both to key
switch 33 and a coasting control 39 via an emergency stop switch
38. Coasting control 39 is also connected to clamp-15 signal 34.
Coasting control 39 emits a coasting signal 40 both to compressor
17 and to a purging detector 41. Purging detector 41, which emits
purging error signal 36 to memory 35, also receives a compressed
air signal 43 made available by compressed air sensor 42 that is
assigned to compressor 17.
[0018] First AND operation 31 emits a freezing count signal 44 to a
freezing counter 45, to which is also supplied a diagnosis signal
48 made available by a diagnosis unit 46 via a diagnosis interface
47, and which makes available a freezing counter signal 49.
[0019] Second AND operation 32 emits an ice count signal 50 to an
ice counter 51, which passes on an ice counter signal 52 to a
second comparator 53. Second comparator 53 compares ice counter
signal 52 to a count threshold value 54 and emits a service signal
55 to a service signal memory 56, as a function of the comparison.
Diagnosis signal 48 is supplied both to service signal memory 56
and to ice counter 51. Service signal memory 56 emits a switching
signal 57 to a service indicator 58.
[0020] The method according to the present invention functions as
follows:
[0021] Catalytic converter 11 situated in the exhaust gas flow 12
of internal combustion engine 10 cleans the at least one component
of the exhaust gases of internal combustion engine 10. Catalytic
converter 11 is preferably developed as an SCR (selective catalytic
reduction) catalytic converter, which, in cooperation with reagent
13 renders harmless to a great extent at least one exhaust gas
component, preferably NOx. Reagent 13 is, for instance, a
urea-water solution, which metering valve 14 introduces into
exhaust gas flow 12. In exhaust gas flow 12, or at a component not
shown, ammonia is obtained from the urea-water solution, which is
used as a reducing agent in the SCR catalytic converter.
[0022] Reagent 13 is accommodated in reagent tank 16, from which it
is conveyed to metering valve 14 by reagent pump 15. Metering valve
14 may be designed with or without air support. In the case of an
air-supported metering valve 14, the required compressed air is
made available by compressor 17. The compressed air then preferably
reaches metering valve 14 directly.
[0023] According to one advantageous embodiment, after the shutting
down of internal combustion engine 10, purging reagent 13 is
provided from metering valve 14, from reagent pump 15 and from
further components not shown in greater detail. Using this measure,
one may achieve that the components, such as, for instance,
metering valve 14 and/or reagent pump 15 are protected after the
shutting down of internal combustion engine 10. If there were
longer action, it is possible that corrosion or embrittlement might
occur. However, in particular, using this measure, freezing may be
prevented of components 14, 15 when filled with reagent 13.
[0024] In order to record the temperature of components 14, 15,
preferably at least one temperature sensor is provided. In the
exemplary embodiment shown, metering valve temperature sensor 18
assigned to metering valve 14, reagent pump temperature sensor 20
assigned to reagent pump 15, reagent tank temperature sensor 22
assigned to reagent tank 16 as well as temperature sensor 24 are
provided. Temperature sensor 24 preferably records the air
temperature. Temperature sensor 24 may be situated, for example, in
an intake region of internal combustion engine 10 that is not shown
in greater detail, or in an air conditioner that is also not shown,
provided internal combustion engine 10 is situated in a motor
vehicle.
[0025] The at least one temperature sensor 18, 20, 22, 24
preferably records a measure for the temperature of the most
sensitive component 14, 15. The measure for the temperature of
component 14, 15 is similarly a measure for the temperature of
reagent 13. Temperature signals 19, 21, 23, 25 made available by
temperature sensors 18, 20, 22, 24 are supplied to temperature
selection 26, which passes on one of temperature signals 19, 21,
23, 25 as temperature signal 27 to first comparator 28. The first
comparator emits temperature warning signal 30 via temperature
signal 27, in response to each exceeding or undershooting of
temperature threshold value 29. Temperature selection 26 may pass
on, for example, the highest or the lowest temperature as
temperature signal 27. If necessary, a particular selection may be
fixed.
[0026] Using the measure provided according to the present
invention, each undershooting or exceeding of temperature threshold
value 29 by temperature signal 27 may be counted, and, upon the
exceeding of count threshold value 54, service signal 55 may be
issued. Temperature signals 19, 21, 23, 25 especially make possible
the detection of freezing of at least one component 14, 15, that is
filled with reagent 13. The freezing point of a urea-water solution
that may be provided as reagent 13 is at least approximately around
-11 degrees C. This temperature may easily be reached or undershot
in wintertime. We next look only at such an undershooting of the
freezing point of reagent 13.
[0027] Freezing counter 45 counts each appearance of freezing count
signal 44, which appears in response to each appearance of
temperature warning signal 30, provided the AND condition in first
AND operation 31 is satisfied. The AND condition designates that,
simultaneously with the appearance of temperature warning signal
30, clamp-15 signal 34 has to be present, which key switch 33 makes
available. The clamp-15 signal means that an operating person has
operated key switch 33 for starting internal combustion engine 10,
and that key switch 33 is connected to vehicle electrical supply 37
for the energy supply of the entire installation, via emergency
stop switch 38. Using this measure, it is achieved that freezing
count signal 44 is able to appear at first AND operation 31 only
after the starting of internal combustion engine 10. Freezing
counter 45 counts the appearance of freezing count signal 44 and
emits freezing counter signal 49. Freezing counter signal 49 may,
for instance, be compared to a predefined boundary value, a
specified measure being able to be taken if the boundary value is
exceeded.
[0028] For example, freezing counter signal 49 may remain stored in
freezing counter 45, and be read out for diagnosis purposes by a
diagnosis unit 46 that may, perhaps, be connected via diagnosis
interface 47. Furthermore, freezing counter 45 may be canceled
using diagnosis signal 48.
[0029] Of special advantage is the measure that temperature warning
signal 30 is counted only if component 14, 15 is filled with
reagent 13, so that, upon the appearance of temperature warning
signal 30, one may assume icing up of component 14, 15. Because of
the sudden change in density of reagent 13, that appears in
response to icing up, component 14, 15 may be damaged.
[0030] Inasmuch as even a one-time freezing up of components 14, 15
is critical, count threshold value 54 may be set to the number one.
That means that each individual exceeding of count threshold value
54 leads to the appearance of service signal 45. In test series it
was determined that, in practice, more than one icing up, for
example, 50 icing up occurrences may be gotten through before a
breakdown must be expected. Metering valve 14 has proven to be
especially at risk. Similarly, it has been shown that it is
sufficient to draw upon reagent pump temperature signal 21,
supplied by reagent pump temperature sensor 20, as a measure for
the temperature of metering valve 14 or reagent 13 in metering
valve 14.
[0031] Since it may be assumed that, during the operation of
internal combustion engine 10, freezing of reagent 13 does not
occur by heating at least one of component 14, 15 or reagent 13
directly, one may assume that freezing of component 14, 15 occurs
only in the shut-down state of internal combustion engine 10.
[0032] It is therefore advantageously determined whether component
14, 15 is filled with reagent 13 in the shut down state of internal
combustion engine 10. According to a first exemplary embodiment,
compressed air signal 43 is evaluated for this. After the operation
of key switch 33 for shutting down internal combustion engine 10,
coasting control 39 still activates compressor 17, using coasting
signal 40, for a specified time, in which component 14, 15 is
flushed by the compressed air and reagent 13 is purged.
[0033] First of all, the case may occur that, during coasting time,
the air pressure is not sufficient, or no compressed air at all is
available. This state is recorded by compressed air sensor 42,
which may be assigned, for example, to compressor 17. Purge
detector 40 determines, with the aid of compressed air signal 43,
that an error has occurred, and emits purge error signal 36 to
memory 35. Memory 35 has the task of storing purge error signal 36
until the next operation of key switch 33.
[0034] According to another exemplary embodiment, the operation of
emergency stop switch 38 is taken into consideration. Emergency
stop switch 38 completely separates, from vehicle electrical supply
37, not only key switch 33 but also coasting control 39, so that
purging of components 14, 15 using compressed air cannot take
place. This state may be determined in purge detector 40 with the
aid of coasting signal 40 and clamp-15 signal 34. If no coasting
signal 40 appears when clamp-15 signal 34 is present, purge error
signal 36 is emitted to memory 35.
[0035] In response to the satisfied AND condition, second AND
operation 32 emits ice count signal 50 to ice counter 51. Ice
counter signal 52 supplied by ice counter 51 is compared by second
comparator 53 to count threshold value 54. When count threshold
value 54 is exceeded, service signal 55 is made available and
stored in service signal memory 56. At the same time, service
indicator 58 is able to be activated by switching signal 57.
[0036] Stored service signal 55 may be read out during a diagnosis
by diagnosis unit 46 using diagnosis signal 48. At the same time,
stored service signal 55 as well as ice counter 51 may be canceled
using diagnosis signal 48, and service indicator 58 may be reset.
In this connection, the appearance of service signal 55 gives
notice that component 14, 15 should be tested based on the
exceeding of the specified number of freezing occurrences and
exchanged if necessary.
* * * * *