DE102011006528A1 - Air flow measuring device - Google Patents

Abstract

The invention relates to an air flow measuring device, which is to be arranged in an intake pipe of an engine, with an inlet (6), a sensor (2), an internal flow channel (7) and an outlet (8). The inlet (6) is open to the upstream side of the suction pipe. The sensor (2) exchanges heat with the air taken in via the inlet (6) in order to measure the air mass flow. The sensor (2) is open in the internal flow channel (7) aite of the intake pipe and allows the air to flow back into the intake pipe. The internal flow channel (7) has an elbow part in the air flow direction downstream of the sensor (2). The elbow part has a slot (17). The elbow part provides a connection between the internal flow channel (7) and the suction pipe. Part of the air flowing backwards through the suction pipe flows into the internal flow channel (7) via the outlet (8) and back into the suction pipe via the slot (17).

Description

The invention relates to an air flow measuring device to be arranged in an intake pipe of an engine, which measures the air mass flow or the mass flow of the air sucked into the engine.

Note that in the following description in the intake pipe, the forward direction from the air cleaner (upstream) to the engine (downstream) and the reverse direction from the engine (downstream) to the air cleaner (upstream) is oriented.

For measuring the mass flow of the air sucked into the engine, a thermal sensor is often used because a thermal sensor is advantageously capable of measuring the mass flow as an air mass flow. The thermal sensor generates an output value equivalent to the mass flow by causing heat transfer to the air (heat exchange with the air). The thermal sensor has a heating element that releases heat to the air. The thermal sensor controls the heat generation by the heating element, for example, so that the difference between (a) the temperature of the air thermally unaffected by the heating element and (b) the temperature of the heating element reaches a predetermined value.

As a result, in a coordinate system whose ordinate axis indicates the amount of heat and whose axis of abscissa indicates the air mass flow, the 7B shown relationship between (a) draw the amount of heat emitted by the heating element to the air and (b) of the air mass flow as a rising characteristic. Accordingly, although the amount of heat increases with an increase in the air mass flow, the rate of increase in the amount of heat decreases with an increase in the air mass flow relative to the air mass flow. The thermal sensor generates the output value equivalent to the mass flow as a function of the amount of heat which the heating element discharges to the air by the control based on the above-discussed context.

Due to a pulsation caused by opening and closing of the engine valves, air in the intake pipe alternately flows in the forward and reverse directions, whereby the output value of the thermal sensor of the pulsation repeatedly increases and decreases accordingly. As a result, because of the above-discussed relationship according to the rising characteristic between (a) the amount of heat and (b) the mass air flow, the measured value of the thermal sensor becomes inevitably and erroneously smaller than the actual value. In order to increase the output value of the thermal sensor and bring the measured value closer to the actual value, there are the in 7A shown air flow measuring device 100 , The air flow meter 100 defines an internal flow channel 101 in which a thermal sensor 102 is provided. The internal flow channel 101 deviates from a straight flow through the intake manifold.

As the air flow measuring device 100 the internal flow channel 101 has, which deviates from a straight-line flow, and the thermal sensor 102 in the internal flow channel 101 is arranged, has the air flow measuring device 100 a correction function for increasing the erroneously reduced output value in accordance with the ratio L2 / L1. Where L1 is the length of a flow channel through which the air flows, if not through the internal flow channel 101 but flows straight through the intake pipe. L2 corresponds to the length of the internal flow channel 101 , Since the output value can be increased with an increase in the ratio L2 / L1, if L2 / L1 is set to a desired value, a reduction of the measured value due to pulsation can be limited according to the correction function.

In the airflow meter discussed above 100 must be through the internal flow channel 101 return streamed air back into the intake pipe. There were therefore different configurations for an output 103 proposed over which the air flows back to the intake pipe. For example, in the JP 2007-327790 A the outlet has an opening parallel to the flow direction of the suction pipe, whereby the flow direction of the air leaving the exit is perpendicular to the flow direction of the suction pipe. Next has in the JP 4169802 B the outlet is an opening perpendicular to the flow direction of the suction pipe and toward the downstream side of the suction pipe. The flow direction of the air leaving the outlet therefore substantially coincides with the flow direction of the air in the intake pipe.

However, the above configurations and arrangements of the outputs have several advantages and disadvantages. In particular, in the JP 2007-327790 A even in the case of a pulsation-induced backward flow outside of the air flow measuring device, an inflow of the backward-flowing air into the internal flow channel is limited via the outlet, since the opening of the outlet runs parallel to the flow direction of the suction tube. As a result, a pulsation-induced reduction of the output value is effectively limited. However, when air flowing outside the air flow meter in the forward direction drifts and flows toward the exit, the dripped air flows readily through the outlet in the internal flow channel, whereby the air outlet at the outlet is undesirably interrupted or influenced and thereby the output value is changed unintentionally.

Next opens in the JP 4169802 B the output to the downstream side of the intake pipe, whereby even in the case of a drift of forward-flowing air, the air outlet is not significantly influenced by the output. However, air flowing in the backward direction readily flows into the internal flow channel via the outlet, which makes it very difficult to avoid a pulsation-related reduction in the measured value.

Further, the conventional air flow meter has 100 for improving the measured value, the above-mentioned correction function based on the ratio L2 / L1. The amount by which the measured value is corrected upward is determined by the correction function to be a substantially constant value based on L2 / L1. On the other hand, the amount by which the measured value is erroneously reduced due to pulsation varies depending on the actual mass air flow and the frequency of the pulsation (engine speed). As a result, even if L2 / L1 is set so that the measured value for a given air mass flow range or for a given engine speed range substantially coincides with the actual value, the correction of the reduced measured value may be too large or small when the mass air flow or Engine speed deviates significantly from the respective area.

Based on the above-described disadvantages, it is an object of the present invention to provide an air flow meter for measuring the mass flow of the air sucked into an engine, which is less affected by air pulsation or drift.

This object is achieved by an air flow measuring device with the features of claim 1. An air flow measuring device to be arranged in the intake pipe of an engine according to the invention has an inlet, a sensor, an internal flow channel and an outlet. The inlet is open toward an upstream side of the intake pipe and receives a portion of the air flowing through the intake pipe in the forward direction from the upstream side to the downstream side of the intake pipe. The sensor is configured to exchange heat with the air received through the inlet to measure the mass flow of air drawn into the engine. The sensor is arranged in the internal flow channel. The outlet is open towards the downstream side of the intake manifold and allows air taken in through the sensor and returned to the intake manifold to flow back through the sensor. The internal flow channel has an upstream end at the entrance and a downstream end at the exit in the direction of air flow. The internal flow passage has a pipe bend portion in the airflow direction at a location downstream of the sensor. The pipe bend portion has a slot in a flow passage wall defining the pipe bend portion. The pipe bend part provides a connection between the internal flow channel and the intake pipe. When air flows through the intake pipe in the backward direction from the downstream side to the upstream side of the intake pipe, a part of the backward flowing air flows back through the exit into the internal flow passage and then back into the intake pipe via the slit.

Advantageous developments or embodiments are the subject of dependent claims.

The invention will be understood with further features and advantages from the following description, the claims and the drawings. In the drawings:

1 a longitudinal sectional view illustrating the internal structure of an air flow measuring device according to an embodiment of the invention;

2A a longitudinal sectional view of the air flow measuring device for illustrating the ratio L2 / L1 according to the embodiment of the invention;

2 B a map illustrating the relationship between the air mass flow and the amount of heat according to the embodiment;

3 a side view of the air flow measuring device according to the embodiment;

4 one in one direction IV in 1 seen rear view of the air flow measuring device according to the embodiment;

5 one in a direction V in 1 seen front view of the air flow measuring device according to the embodiment;

6 one in a direction VI in 1 seen bottom view of the air flow measuring device according to the embodiment;

7A a longitudinal sectional view illustrating the internal structure of a conventional air flow measuring device; and

7B a map illustrating the relationship between the mass air flow and the amount of heat according to the prior art.

(Embodiment)

(Configuration of Embodiment)

With the help of 1 to 6 then becomes the configuration of an air flow meter 1 described according to the present embodiment.

The air flow meter 1 is designed for placement in an intake manifold of an engine and is used to measure the mass flow of air drawn into the engine.

It should be noted that in the following description, a forward direction in the intake pipe is defined as the direction from an air cleaner (upstream) to the engine (downstream). Similarly, a backward direction in the intake manifold is defined as the direction from the engine (downstream) to the air cleaner (upstream).

The air flow meter 1 receives a portion of the air flowing through the intake pipe in the forward direction and measures by inducing a heat transfer (heat exchange) to the intake air, the mass flow, ie the air mass flow, directly.

The air flow meter 1 includes a thermal sensor 2 , a housing 3 and a plug 4 , The thermal sensor 2 generated by the heat transfer (heat exchange) to the air an output value that is equivalent to the mass flow. The thermal sensor 2 is in the case 3 added. Over the plug 4 becomes the through the sensor 2 generated output value to an electronic control device (ECU), not shown. The ECU determines the mass flow of the air drawn into the engine based on the air flow meter 1 obtained based on the air mass flow various control / regulatory processes, eg. B. fuel injection, from.

The sensor 2 has a heating element (not shown) that releases heat to the air. The sensor 2 For example, the amount of heat generated by the heating element controls such that the difference between (a) the temperature of the air that is not thermally affected by the heating element and (b) the temperature of the heating element reaches a predetermined value. As a result, the relationship between (a) the quantity of heat emitted by the heating element to the air and (b) the air mass flow in a coordinate system whose ordinate axis indicates the amount of heat and its abscissa axis the air mass (see 2 B ) as a rising curve (eg saturation curve). As shown, the amount of heat generally increases with an increase in the mass air flow, but as the mass air flow increases, the rate of increase in the amount of heat relative to the mass air flow decreases. The sensor 2 generates the output value equivalent to the mass flow depending on the amount of heat that the heater emits to the air through the control based on the rising curve relationship discussed above.

The housing 3 is open to the upstream side of the intake manifold and has an inlet 6 , an internal flow channel 7 and an exit 8th , The entrance 6 takes up a part of the air flowing through the intake pipe in the forward direction. The internal flow channel 7 Leave the over the entrance 6 flow through the collected air. In the internal flow channel 7 is the sensor 2 added. The exit 8th is open to the downstream side of the intake pipe. The exit 8th Eat those over the entrance 6 taken and over the sensor 2 flowed back air to the intake pipe. The sensor 2 generates the equivalent of the air mass flow output value by a heat exchange with the on the input 6 absorbed air.

The air flow direction in the internal flow channel 7 is defined as follows. The entrance 6 forms the upstream end of the internal flow channel 7 , The exit 8th forms the downstream end of the internal flow channel 7 , The flow direction from the entrance 6 to the exit 8th corresponds to the forward direction in the internal flow channel 7 while the flow direction from the outlet 8th to the entrance 6 the reverse direction in the internal flow channel 7 equivalent.

The internal flow channel 7 can be, for example, in an inlet flow channel 10 , an outlet flow channel 11 and a U-turn flow channel 12 divide. The inlet flow channel 10 extends from the entrance 6 in the downstream direction. The exit flow channel 11 extends from the exit 8th in the upstream direction. The sensor 2 is in the U-turn flow channel 12 which makes a U-turn around the input flow channel 10 with the exit flow channel 11 connect to.

The inlet flow channel 10 extends straight from the entrance 6 in the downstream direction. The flow in the inlet flow channel 10 runs parallel to the forward flow in the intake pipe. Furthermore, a dust discharge flow channel is provided 13 connected to the downstream end of the inlet flow channel 10 is connected and dust in the over the entrance 6 contained air taken in, for discharging straight forward flow through. At its downstream end, the Staubaustragströmungskanal 13 For this purpose, a Staubaustragsöffnung 14 , The flow channel width of the Staubaustragströmungskanals 13 is in the direction of the dust discharge opening 14 smaller.

The U-turn flow channel 12 is for example C-shaped. The two ends of the U-turn flow channel 12 with the inlet flow channel 10 or the outlet flow channel 11 connected. The U-turn flow channel 12 Leave the over the entrance 6 absorbed air from the inlet flow channel 10 to the exit flow channel 11 make a U-turn. The sensor 2 is in the U-turn flow channel 12 arranged, at a position at which the air flow of the flow direction in the inlet flow channel 10 is opposite.

The U-turn flow channel 12 branches at the downstream end of the inlet flow channel 10 from a rectilinear flow channel emerging from the inlet flow channel 10 and the dust discharge flow channel 13 is formed, at a right angle. In other words, the input flow channel divides 10 at its downstream end into the U-turn flow channel 12 and the dust discharge flow channel 13 , Due to the inertia, dust particles move from the inlet flow channel 10 straight into the Staubaustragströmungskanal 13 where they go via the dust discharge opening 14 be discharged into the intake pipe. In contrast, the flow direction of the air changes to that of the direction of the inlet flow channel 10 deviates and into the U-turn flow channel 12 flows.

The exit flow channel 11 is at the downstream end of the U-turn flow channel 12 connected. The exit flow channel 11 is a pipe bend part that controls the air flow at the downstream end of the U-turn flow channel 12 in the internal flow channel 7 flows in the forward direction, deflected at a right angle in the flow direction of the Ansaugströmungskanals. As mentioned above, the pipe bend part directs the airflow from a first direction in a second direction orthogonal to the first direction. For example, the first direction corresponds to the forward direction in the internal flow channel 7 at the downstream end of the U-turn flow channel 12 , Further, the second direction corresponds to the forward direction in the input flow channel 10 (or intake manifold). As a result, the air stream flowing through the pipe bend part draws an L-shaped track, as in FIG 1 is shown. The downstream end of the pipe bend portion forms the exit 8th , The exit flow channel 11 is further divided at its upstream end into two channels, which are on both sides of the inlet flow channel 10 are arranged. Thus, the outputs 8th on the two sides of the inlet flow channel 10 arranged (see 1 . 2 . 5 and 6 ). In other words, the exit flow channel is 11 divided into two channels, which with respect to a plane of symmetry (see 4 to 6 ) are arranged symmetrically. The plane of symmetry corresponds for example to the longitudinal sectional planes of the inlet flow channel 10 and the U-turn channel 12 representing the axes of the flow channels 10 . 12 include.

As mentioned above, the internal flow channel looks 7 a diversion, which deflects the air flow temporarily from the rectilinear flow in the intake pipe. The internal flow channel 7 has a correction function to increase the output value of the sensor 2 by going over the entrance 6 temporarily absorbs absorbed air from the straight flow in the intake pipe (see 2A ).

In 2A L1 corresponds to the length of a flow channel of the air flowing through the intake pipe, not from the internal flow channel 7 is recorded. L2 also corresponds to the length of the internal flow channel 7 , The air flow meter 1 defines the internal flow channel 7 , which deviates from the straight-line flow, and has the in the internal flow channel 7 provided sensor 2 , The air flow meter 1 thus has a correction function for increasing the output value in accordance with the ratio L2 / L1. Due to this correction function, the output value increases with an increase of L2 / L1.

In the case 3 is an outlet cover 15 formed corresponding to a part that the flow channel outer wall of the output flow channel 11 forms.

The outlet cover 15 has a slot 17 extending in a direction perpendicular to the flow direction through the intake manifold and the intake flow passage 10 extends. The slot 17 provides a connection between the internal flow channel 7 and the intake pipe (see 1 to 3 ) ago. When air passes through the intake pipe in Backward direction flows, some of the air flows over the exit 8th in the internal flow channel 7 one, being over the output 8th inflowing air over the slot 17 flows back into the intake pipe.

The slot 17 is in a part of the outlet cover 15 provided, which has a radially outermost part of a in the output flow channel 11 defined generated vortex or swirl flow. The slot 17 extends from the upstream end of the exit flow channel 11 out in the downstream direction. For example, there are a plurality of streamlines that are a forward direction of the one in the exit flow channel 11 specify generated vortex or swirl flow. The slot 17 is along the streamline A (see 1 ) of the plurality of streamlines extending at the radially outermost part of the vortex or swirl path in the internal flow channel. The slot 17 thus extends from the upstream end of the streamline A in the exit flow channel 11 along the streamline A downstream.

The exit 8th and the slot 17 are further provided so that the longitudinal direction of the output 8th essentially with the longitudinal direction of the slot 17 matches (see 1 to 3 ). The length dimension of the slot 17 is equal to 1/3 of the length dimension of the output 8th (please refer 3 ). In other words, the longitudinal axis of the output extends 8th substantially parallel to the longitudinal axis of the slot 17 , The exit 8th has in particular a flat opening, as it is in 5 is shown. The opening of the exit 8th thus has a substantially with the longitudinal direction of the slot 17 consistent longitudinal direction.

Furthermore, the slot has 17 considered perpendicular to the longitudinal axis has a width less than or equal to 2 mm (see 3 ).

(Advantages of the embodiment)

According to the air flow meter 1 is the exit 8th in the downstream direction of the intake pipe open.

Even if air flowing through the intake pipe in the forward direction drifts, the influence of air drift on the air outlet is via the outlet 8th limited.

Furthermore, the exit flow channel 11 with the downstream end of the U-turn flow channel 12 connected, in which the sensor 2 is included. Next has the output flow channel 11 the pipe bend part, which is the flow at the downstream end of the U-turn flow channel 12 aligned in the forward direction, deflects at right angles. The slot 17 is in the outlet flow channel 11 formed flow channel wall and sees a connection between the internal flow channel 7 and the intake pipe. As air flows backward through the intake manifold, some of the air flows over the outlet 8th in the internal flow channel 7 and then over the slot 17 back into the intake pipe.

As a result, air flowing backward through the intake pipe flows over the exit 8th though in the internal flow channel 7 and flows backward through the internal flow channel 7 , But the air flows over the slot 17 back into the intake pipe before putting the sensor 2 reached. Thus, an influence on the output value of the sensor caused by an air pulsation can 2 reduces and thereby an undesirable reduction of the measured value are limited.

As mentioned above, an air flow meter 1 be provided with a structure in which the influence of an air pulsation or an air deviation is limited.

Furthermore, the pipe bend part forms the output flow channel 11 and has a downstream end, which is the exit 8th forms. The slot 17 is provided in a certain part of the pipe bend part defining flow channel wall. The particular part corresponds to the flow channel wall which defines the radially outermost part of the vortex or swirl flow created by the pipe bend part. The slot 17 extends from the upstream end of the pipe bend portion in the downstream direction of the pipe bend portion.

As a result, over the slot 17 more air mistakenly over the exit 8th in the internal flow channel 7 has flowed back into the intake pipe 7 back flow, reducing the influence of air pulsation on the output value of the sensor 2 can be further reduced. As a result, an undesirable reduction in the measured value can be limited.

The exit 8th has a longitudinal direction substantially in the longitudinal direction of the slot 17 matches. The length dimension of the slot 17 is greater than or equal to 1/3 of the length dimension of the output 8th ,

As a result, over the slot 17 more air coming over the exit 8th mistakenly in the flow channel 7 has flowed back, back to the intake pipe. As a result, the influence of air pulsation on the output value of the sensor 2 be further reduced. Thus, an undesirable reduction of the measured value can be limited.

The slot 17 has perpendicular to its longitudinal axis a width less than or equal to 2 mm.

As a result, a state in which the forward direction through the sensor can be avoided 2 streamed air over the slot 17 flows into the intake pipe, without the output 8th to reach. Because the width of the slot 17 is very small, only a small part of the through the sensor 2 streamed air over the slot 17 flow into the intake pipe. Thus, most of the flows through the sensor 2 streamed air only after having total length L2 of the internal flow channel 7 flowed through the exit 8th back into the intake pipe. As a result, the slot is substantially prevented 17 the length of the internal flow channel 7 shortened and thereby affects the ratio L2 / L1.

If the width is transverse to the longitudinal direction of the slot 17 is too big, it can happen that only little air in the backward direction through the internal flow channel 7 flows over the slot 17 leakage, as an air drift in the intake pipe, the air flow through a large slot 17 can significantly influence. The width is therefore set to less than or equal to 2 mm, which suppresses the influence of a drift and thereby sufficient air through the slot 17 can escape.

(Modification)

The air flow measuring device according to the present invention is not limited to the above embodiment. There may be various modifications of the air flow meter 1 result.

For example, in the air flow meter 1 the embodiment of the pipe bend part the output flow channel 11 and the downstream end of the pipe bend portion forms the exit 8th , The exit flow channel 11 but may further include a rectilinear portion extending from the exit 8th from continuous and straight extending in the upstream direction. The pipe bend part may therefore be provided at the upstream end of the rectilinear part.

Other advantages and modifications will become apparent to those skilled in the art. The air flow measuring device according to the invention is therefore not limited to the specific details, embodiment and modification described and shown above, but solely by the features of the claims.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• JP 2007-327790 A [0007, 0008]
• JP 4169802 B [0007, 0009]

Claims (5)

An air flow measuring device to be disposed in an intake pipe of an engine, comprising: an upstream inlet of the intake pipe (Fig. 6 ) receiving a part of the air flowing through the intake pipe in a forward direction from the upstream side to the downstream side of the intake pipe; a sensor ( 2 ) for heat exchange with the via the entrance ( 6 ) to measure the air mass sucked into the engine; an internal flow channel ( 7 ), in which the sensor ( 2 ) is included; and an outlet (6) open in the downstream direction of the intake pipe ( 8th ), which over the entrance ( 6 ) and through the sensor ( 2 ) streamed air back to the intake pipe, characterized in that: the internal flow channel ( 7 ) in the air flow direction an upstream end at the entrance ( 6 ) and a downstream end at the exit ( 8th ) Has; the internal flow channel ( 7 ) in the air flow direction at a location downstream of the sensor ( 2 ) has a pipe bend part; the pipe bend part in a flow channel wall defining the pipe bend part a slot ( 17 ), which has a connection between the internal flow channel ( 7 ) and the intake manifold; and when air flows through the intake pipe in the backward direction from the downstream side to the upstream side of the intake pipe, a part of the backward flowing air via the exit (FIG. 8th ) into the internal flow channel ( 7 ) and then over the slot ( 17 ) flows back into the intake pipe. Air flow meter according to claim 1, wherein: the downstream end of the pipe bend part is the exit ( 8th ) forms; The slot ( 17 ) is provided in a part of the flow channel wall, which defines a radially outermost part of the vortex or swirl flow generated by the pipe bend part; and the slot ( 17 ) extends downstream from the upstream end of the pipe bend portion. Airflow meter according to claim 1 or 2, wherein: the output ( 8th ) has a longitudinal direction substantially with a longitudinal direction of the slot ( 17 ) matches; and the slot ( 17 ) has a length dimension greater than or equal to 1/3 of a length dimension of the output ( 8th ). An air flow meter according to claim 3, wherein: the slot ( 17 ) has a width perpendicular to the longitudinal direction; and the width of the slot ( 17 ) is less than or equal to 2 mm. Airflow meter according to claim 1 or 2, wherein: the output ( 8th ) has a flat opening; the opening of the exit ( 8th ) has a longitudinal direction substantially with a longitudinal direction of the slot ( 17 ) matches; and the slot ( 17 ) has a length dimension greater than or equal to 1/3 of the length dimension of the opening of the outlet ( 8th ).

Images