Air flow measuring device
First Claim
1. An air flow measuring device comprising:
- a housing part including a bypass passage that takes in a part of air flowing through an air passage, and a dust discharge passage that discharges dust contained in the taken-in air; and
a flow rate detecting element provided in the bypass passage so as to measure a flow rate of air flowing through the bypass passage, whereinthe bypass passage is configured to communicate between an intake port for air that opens on a front side of the housing part and an outlet port that opens on a rear side of the housing part so that a part of air flowing from the intake port flows into the bypass passage and another part of air flowing from the intake port flows in the discharge passage,the bypass passage includes a reduced passage that reduces a cross-sectional area of the bypass passage in a predetermined range in a flow direction of the air flowing through the bypass passage, wherein;
the flow rate detecting element is disposed in the reduced passage;
the cross-sectional area of the reduced passage increases at a predetermined ratio from a maximum reduction part of the reduced passage, at which a cross-sectional area of the reduced passage becomes the smallest, toward a downstream side in the flow direction of the air;
the reduced passage includes a cross-sectional area increasing region;
the cross-sectional area of the reduced passage is formed to be equal to the cross-sectional area of the bypass passage at a downstream end of the cross-sectional area increasing region, which intersects with a wall surface of the bypass passage;
B is the cross-sectional area of the reduced passage at the downstream end of the cross-sectional area increasing region;
X is a distance from an upstream end of the cross-sectional area increasing region to the downstream end of the cross-sectional area increasing region along a flow direction of air flowing through the reduced passage;
the distance of X is longer than a distance from an upstream end of a cross-sectional area reducing region to a downstream end of the cross-sectional area reducing region along the flow direction of air flowing through the reduced passage; and
the cross-sectional area of B is smaller than a cross-sectional area of the reduced passage at the upstream end of the cross-sectional area reducing region.
1 Assignment
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Accused Products
Abstract
The cross-sectional area of a reduced passage increases at a constant ratio from a maximum reduction part where a cross-sectional area of the reduced passage becomes the smallest toward a downstream side. The cross-sectional area of the reduced passage is equal to the cross-sectional area of a bypass passage at a downstream end of a cross-sectional area increasing region intersecting with a wall surface of the bypass passage. (Cross-sectional area increase ratio)=(B−A)/X is satisfied. A [mm2] is the cross-sectional area of the reduced passage at an upstream end of the increasing region. B [mm2] is the cross-sectional area of the reduced passage at the downstream end of the increasing region. X [mm] is a distance from the upstream end to the downstream end of the increasing region along an air flow direction through the reduced passage. The ratio is 1.5 [mm2/mm] or smaller.
5 Citations
6 Claims
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1. An air flow measuring device comprising:
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a housing part including a bypass passage that takes in a part of air flowing through an air passage, and a dust discharge passage that discharges dust contained in the taken-in air; and a flow rate detecting element provided in the bypass passage so as to measure a flow rate of air flowing through the bypass passage, wherein the bypass passage is configured to communicate between an intake port for air that opens on a front side of the housing part and an outlet port that opens on a rear side of the housing part so that a part of air flowing from the intake port flows into the bypass passage and another part of air flowing from the intake port flows in the discharge passage, the bypass passage includes a reduced passage that reduces a cross-sectional area of the bypass passage in a predetermined range in a flow direction of the air flowing through the bypass passage, wherein; the flow rate detecting element is disposed in the reduced passage; the cross-sectional area of the reduced passage increases at a predetermined ratio from a maximum reduction part of the reduced passage, at which a cross-sectional area of the reduced passage becomes the smallest, toward a downstream side in the flow direction of the air; the reduced passage includes a cross-sectional area increasing region; the cross-sectional area of the reduced passage is formed to be equal to the cross-sectional area of the bypass passage at a downstream end of the cross-sectional area increasing region, which intersects with a wall surface of the bypass passage; B is the cross-sectional area of the reduced passage at the downstream end of the cross-sectional area increasing region; X is a distance from an upstream end of the cross-sectional area increasing region to the downstream end of the cross-sectional area increasing region along a flow direction of air flowing through the reduced passage; the distance of X is longer than a distance from an upstream end of a cross-sectional area reducing region to a downstream end of the cross-sectional area reducing region along the flow direction of air flowing through the reduced passage; and the cross-sectional area of B is smaller than a cross-sectional area of the reduced passage at the upstream end of the cross-sectional area reducing region. - View Dependent Claims (2, 3, 4)
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5. An air flow measuring device comprising:
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a bypass passage that takes in a part of air flowing through an air passage; a flow rate detecting element that measures a flow rate of air flowing through the bypass passage; and a reduced passage that reduces a cross-sectional area of the bypass passage in a predetermined range in a flow direction of the air flowing through the bypass passage, wherein; the flow rate detecting element is disposed in the reduced passage; the cross-sectional area of the reduced passage increases at a constant ratio from a maximum reduction part of the reduced passage, at which a cross-sectional area of the reduced passage becomes the smallest, toward a downstream side in the flow direction of the air; the reduced passage includes a cross-sectional area increasing region; the cross-sectional area of the reduced passage is formed to be equal to the cross-sectional area of the bypass passage at a downstream end of the cross-sectional area increasing region, which intersects with a wall surface of the bypass passage; an equation;
(cross-sectional area increase ratio) =(B−
A)/X
(1)
is satisfied,where; A is the cross-sectional area of the reduced passage at an upstream end of the cross-sectional area increasing region; B is the cross-sectional area of the reduced passage at the downstream end of the cross-sectional area increasing region; and X is a distance from the upstream end of the cross-sectional area increasing region to the downstream end of the cross-sectional area increasing region along a flow direction of air flowing through the reduced passage; the cross-sectional area increase ratio defined by the above equation (1) is set to be equal to or smaller than 1.5; the distance of X is longer than a distance from an upstream end of a cross-sectional area reducing region to a downstream end of the cross-sectional area reducing region along the flow direction of air flowing through the reduced passage; and the cross-sectional area of B is smaller than a cross-sectional area of the reduced passage at the upstream end of the cross-sectional area reducing region. - View Dependent Claims (6)
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Specification