Apparatus from controlling amount of intake air to engine

An apparatus for controlling the amount of intake air to an engine comprises a throttle body, a throttle valve disposed in the body, a bypass passage that bypasses the throttle valve. The throttle body forms a part of the air intake passage for the engine. In one embodiment of the invention, a guide passage is formed in the throttle body and extends upwardly from the bypass passage. The open end of the guide passage is disposed above the center line of the inside of the throttle body. In another embodiment of the invention, a barrier such as a protrusion or groove is formed in the inner surface of the throttle body and disposed above the open end of the bypass passage to prevent fuel, oil, and other substances from flowing into the bypass passage.

BACKGROUND OF THE INVENTION 
The present invention relates to an apparatus for controlling the amount of 
intake air to an engine and, more particularly, to an apparatus equipped 
with a structure in which a controlled amount of auxiliary air is supplied 
so as to bypass the throttle valve. 
In a known structure as disclosed in Japanese Utility Model Publication No. 
18124/1984 or Japanese Patent Laid-Open No. 5856/1984, a throttle valve is 
installed in an intake passage to control the amount of intake air to an 
engine, and a bypass passage that bypasses the throttle valve has a bypass 
control valve. The output power of the engine can be varied at will by 
arbitrarily controlling the amount of intake air to the engine by the use 
of the throttle valve. When the engine is warmed up, the bypass control 
valve is controlled according to various engine parameters, such as the 
temperature of the engine coolant and the engine speed under unloaded 
condition, to achieve desired objects. 
Various devices are installed in an engine compartment to enhance the 
performance of the engine and, therefore, large space is not left in the 
compartment. The bypass passage structure including the bypass control 
valve is detachably mounted to a throttle body which includes the throttle 
valve and forms the intake passage. The bypass passage structure and the 
throttle body form a compact unit. Of course, limitations are imposed on 
the arrangement of the various devices in the engine compartment. 
Under these conditions, the throttle body is disposed horizontally, i.e., 
the intake passage extends horizontally. Also, the valve shaft of the 
throttle valve perpendicular to the intake passage is disposed 
horizontally. The bypass passage structure including the bypass control 
valve is mounted either above or below the throttle body. In case that the 
structure is disposed below the throttle body, the spatial arrangement is 
more advantageous than the case where it is disposed above the throttle 
body. In the former case, the bypass passage that bypasses the throttle 
valve in the intake passage normally extends vertically downward through 
the throttle body and opens at the bottom of the throttle body. 
Fuel contained in the gas discharged from the engine, fuel contained in the 
circulating blowby gas, and moisture, carbon, oil mist, and other 
substances produced by combustion (hereinafter referred to as liquid 
adhesives) adhere to the inner surface of the throttle body. Especially, 
when the engine is not in operation, these adhering substances flow down 
the wall surface by the action of gravity and are collected in the lower 
part of the cylindrical wall surface. Then, they pass through the 
vertically extending bypass passage which opens at the bottom of the 
throttle body, and flow into the valve portion that controls the bypass 
passage. Eventually, they are deposited and caked on the metering portion 
of the valve seat and also on the sliding portion of the valve body. As a 
result, a metering error occurs and smooth operation of the valve body is 
impeded, so that the accuracy in controlling the amount of auxiliary air 
is deteriorated. 
SUMMARY OF THE INVENTION 
The present invention is intended to eliminate the foregoing problems with 
the prior art techniques. It is an object of the invention to provide an 
apparatus which controls the amount of intake air to an engine without 
causing any breakdown of the bypass system and without deteriorating the 
accuracy after the apparatus is used for a long time. 
An intake air amount control apparatus according to the invention comprises 
a throttle body, a guide passage formed in the throttle body, and a bypass 
passage disposed below the throttle body and connected with the guide 
passage, wherein at least one open end of the guide passage is disposed 
above the center line of an intake passage and in the inside of the 
throttle body. 
Another control apparatus according to the invention comprises a throttle 
body, a throttle valve disposed in the throttle body, a bypass passage 
which bypasses the throttle valve and has an open end provided in the 
lower portion of the throttle body, and a second valve for controlling the 
amount of air flowing through the bypass passage, wherein a barrier such 
as a protrusion, groove, or rib, is formed in the inner surface of the 
throttle body and disposed above the open end of the bypass passage. 
In accordance with the present invention, the open end of the bypass 
passage is formed in the inner wall of the throttle body and disposed 
above the center line of the intake passage, or the barrier is formed in 
the inner surface of the throttle body and disposed above the open end of 
the bypass passage. Therefore, liquid adhesives do not flow into the open 
end. When the engine is started next, the liquid adhesives staying either 
in the lower portion of the intake passage or around the barrier are 
absorbed into the engine by large suctional air flow and disappear.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS 
Referring to FIGS. 1-3, an embodiment of the present invention will be 
described. The apparatus has a throttle body extending horizontally and 
forming an intake passage, the inside of which is indicated by numeral 1. 
A throttle valve 2 is mounted in the throttle body. A valve shaft 3 is 
disposed horizontally and at the right angle to the axis of the intake 
passage. Barriers 4 are formed in the intake passage. Bypass passages 5a 
and 5b extend vertically downward from the bottom of the inside of the 
throttle body. The bypass passage 5b opens into the intake passage at a 
location above the center line of the intake passage through a guide 
passage 5c extending from the bypass passage 5b. The bypass passage 5a 
directly opens into the intake passage. A flange 50 is used to mount the 
throttle body to an engine. The aforementioned guide passage 5c is formed 
in this flange 50 in the form of a channel. The guide passage 5c 
cooperates with a flange (not shown) on the engine side to form a passage 
like a tunnel. 
The amount of air flowing through the intake passage in the inside 1 of the 
throttle body toward the engine in the direction indicated by the arrow A 
is arbitrarily controlled by the use of the throttle valve 2. Then, fuel 
injection nozzles (not shown) provided on intake manifolds (not shown) of 
the engine inject fuel according to the amount of air. As a result, an 
air-fuel mixture enters the engine. When no load is imposed on the engine, 
the throttle valve 2 assumes the illustrated position. Under this 
condition, the amount of auxiliary air flowing through the bypass passages 
5a and 5b is controlled to maintain the engine speed at a constant value 
suitable for the temperature of the engine coolant. 
For this purpose, the apparatus is equipped with a proportional solenoid 
valve 9 having a valve housing 15. This housing 15 has an air inlet port 
28a and an air exit port 28b which are in communication with the bypass 
passages 5a and 5b, respectively. Auxiliary air flows from the air inlet 
port 28a to the air exit port 28b through a valve hole 31 formed in a 
cylinder 32. A valve body 41 consisting of a movable iron core is disposed 
in the cylinder 32 to control the open area of the hole 31. The core is 
mounted between springs 42 and 43 and controlled according to the electric 
current flowing through a solenoid coil 40. 
An electronic control circuit (not shown) compares the engine speed 
actually measured with an intended engine speed and produces a signal 
corresponding to the difference (see Japanese Utility Model Publication 
No. 18124/1984). The solenoid coil 40 is energized with this signal to 
control the position of the valve body 41 in proportion to the current 
value of the signal. Thus, the open area of the hole 31 is controlled to a 
value corresponding to the position of the valve body 41. As a result, the 
amount of air flowing through the bypass passages 5a and 5b are controlled 
so that the engine speed becomes equal to the intended speed. Of course, 
fuel is injected from the fuel injection nozzles according to the amount 
of air and enters the engine together with air. 
During the operation of the engine, the air-fuel mixture flows at a large 
flow rate in the direction indicated by the arrow A so that the liquid 
adhesives to the inner surface 1 of the throttle body pose no problems. 
However, when the engine is at rest, the liquid adhesives contained in the 
gas discharged from the engine and in the circulating blowby gas adhere to 
the inner surface 1 of the throttle body and move down by the action of 
gravity. However, the liquid adhesives hardly flow into the guide passage 
5c, because this guide passage 5c opens into the intake passage at a 
location close to the top of the inner surface 1 of the throttle body. 
Hence, the liquid adhesives do not flow through the bypass passage 5b. 
The liquid adhesives moving down toward the bypass passage 5a encounter the 
barriers 4, each taking the form of a groove defined by a vertical wall 4a 
and a horizontal wall 4b. Then, they spread horizontally along the 
horizontal walls 4b. Therefore, they do not directly flow into the bypass 
passage 5a. When the engine is started next and the amount of intake air 
increases, the intake air blow off the liquid adhesives remaining on the 
horizontal walls 4b. The liquid adhesives remaining on the lower portion 
of the inner surface 1 of the throttle body are forced out of recesses 44 
and atomized by the large amount of intake air, so that they disappear. 
In the illustrated example, the bypass passage 5b extends from the guide 
passage 5c formed in the flange 50. A similar guide passage extending from 
the bypass passage 5a may be formed instead of the barriers 4. 
Referring next to FIG. 4, there is shown another apparatus according to the 
invention. This apparatus is similar to the apparatus shown in FIGS. 1-3 
except that barriers 4 are formed in front of the bypass passage 5b 
instead of the guide passage 5c. 
In the illustrated examples, the horizontal walls 4b of the barriers 4 
extend literally horizontally. The horizontal walls 4b may be inclined 
downwardly to the right from the bypass passage 5a and inclined downwardly 
to the left from the bypass passage 5b. If casting technique allows, an 
annular barrier such as a protrusion or rib may be formed around each of 
he bypass passages 5a and 5b as shown by the rib 4' of FIG. 5. 
In the above examples, the bypass passages include the proportional 
solenoid valve 9. This valve may be replaced by a temperature-responsive 
valve which operates by thermowax or the like. In this case, of course, 
similar advantages can be obtained. 
As described above, in the novel apparatus of the present invention, 
barriers are formed on the inner surface of the throttle body above the 
bypass passage, or a guide passage extends from the bypass passage and is 
disposed near the top of the inner surface of the throttle body. 
Therefore, liquid adhesives which were contained in the gas discharged 
from the engine and in the circulating blowby gas do not flow into the 
bypass passage. As a result, the accuracy in the controlled amount of 
auxiliary air does not deteriorate and the control mechanisms do not cease 
to operate, even if the apparatus is used for a long period.