Information
-
Patent Grant
-
6776137
-
Patent Number
6,776,137
-
Date Filed
Friday, November 7, 200321 years ago
-
Date Issued
Tuesday, August 17, 200420 years ago
-
Inventors
-
Original Assignees
-
Examiners
Agents
- Dennison, Schultz, Dougherty & MacDonald
-
CPC
-
US Classifications
Field of Search
US
- 123 361
- 123 399
- 251 305
- 251 307
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International Classifications
-
Abstract
A throttle body has a main body made of resin. A throttle valve, a motor, and a gear mechanism, are disposed within the main body, so that the rotation of the motor is transmitted to the throttle valve via the gear mechanism. The gear mechanism includes a drive gear, mounted to an output shaft of the motor, and an intermediate gear disposed between the drive gear and the throttle valve. A metal plate is mounted to a motor casing of the motor and the intermediate gear is mounted to the metal plate. The interface between the intermediate gear and the throttle valve is adjustable.
Description
This application claims priority to Japanese patent application serial number 2002-361478, the contents of which are incorporated herein by reference.
BACKGROUND OF THE INVENTION
1. Field of the Invention
The present invention relates to throttle bodies that have throttle valves actuated by motors for controlling the rotational speed of internal combustion engines. In particular, the present invention relates to throttle bodied that have metal plates for supporting gear shafts of gear mechanisms that transmit rotation of motors to throttle valves.
2. Description of the Related Art
There are known throttle bodies that have motor actuated throttle valves. For example, Japanese Laid-Open Patent Publication No. 2001-303983 teaches a throttle body in which a throttle valve, a throttle shaft, a motor, and a gear mechanism, are disposed. The throttle body of this publication is used as an automobile part and is modified to provide a lightweight structure by using resin as the material of the throttle body. The throttle valve is secured to the throttle shaft and the motor rotatably drives the throttle shaft. A gear mechanism, comprising a plurality of gears and gear support shafts, serves to transmit the driving force of the motor to the throttle shaft.
However, by using a resin material for the throttle body, potential deformation of the throttle body may occur due to residual molding stress and/or strain or due to forces applied to the throttle body during the assembly process. This deformation could cause a change in the relative distances between the gear shafts. As a result, the gear teeth may be unintentionally stressed, resulting in excessively wear and rough operation of the gears. Therefore, in order to solve these problems, the above publication proposes to use a single metal plate in order to support all of the gear shafts.
However, there still exists a possibility of deformation because the metal plate must be relatively large in order to support all of the individual gear shafts. The deformation can occur when the metal plate is secured to the throttle body or during the molding process of the throttle body itself, since the throttle body is formed integrally with the metal plate as an insert molding process. Unfortunately, a problem exists in that it is very difficult to correct any changes in the distance caused due to the deformation of the metal plate. In addition, use of a relatively large sized metal plate may result in increased material costs.
SUMMARY OF THE INVENTION
It is accordingly an object of the present invention to teach improved techniques for reducing the material cost of a throttle body and facilitating correction of distance between gears of a gear mechanism of the throttle body.
According to one aspect of the present teachings, throttle bodies include a main body made of a lightweight material; preferably resin, for example, ABS resin. A throttle valve, a motor, and a gear mechanism, are disposed within the main body, so that the rotation of the motor is transmitted to the throttle valve via the gear mechanism. The gear mechanism includes a drive gear mounted to an output shaft of the motor and an intermediate gear disposed between the drive gear and the throttle valve. A metal plate, e.g., preferably a steel plate, is mounted to a motor casing of the motor and the intermediate gear is mounted to the metal plate. An adjusting device serves to adjust the position of the intermediate gear laterally across a face of the main body.
Because the throttle gear is mounted to the metal plate that is in turn mounted to the motor casing, the distance between the drive gear of the motor and the intermediate gear can be reliably maintained to a suitable length. In addition, because the adjusting device can adjust the position of the intermediate gear laterally across the face of the main body, the position of the intermediate gear relative to an element that is mounted on or supported by the main body can be suitably adjusted. In particular, the position relative to a throttle gear that engages the intermediate gear can be adjusted. As a result, any undesired wear of the gears within the gear mechanism due to the incorrect spacing of gears could be reduced or minimized. In addition, because the metal plate only supports the intermediate gear and is mounted to the motor casing, the metal plate may have a relatively small overall size. Therefore, the throttle body can be manufactured at a lower cost while still providing overall improved controllability of the throttle valve.
In still another aspect of the present teachings, throttle bodies further include a fixing device that serves to fix the metal plate in position relative to the main body. In this construction, it is advantageous that the adjusting mechanism serves to adjust the relative position between the metal plate and the main body in order to adjust the position of the intermediate gear relative to an element that is mounted on or supported by the main body. With this construction, the positions of the drive gear and the intermediate gear can be simultaneously adjusted relative to the main body.
Preferably, the metal plate is fixed in position relative to the motor casing and the intermediate gear is rotatably mounted on a gear shaft that is secured to the metal plate.
In further aspect of the present teachings, the fixing device comprises a screw(s) and the adjusting mechanism comprises at least one mounting hole formed in the metal plate. The mounting hole(s) is(are) adapted to receive the fixing device and in one aspect has an elongated configuration having a length that is greater than the width of the mounting hole. Therefore, the adjusting mechanism may have a relatively simple configuration and a relatively low number of parts.
Preferably, the mounting hole(s) is(are) elongated in a circumferential direction substantially about the output shaft of the motor.
Preferably, the screw (s) engages a threaded hole(s) that is(are) formed in the main body.
In a still further aspect of the present teachings, the gear mechanism additionally includes a throttle gear that is coupled to the throttle valve and is rotatable with the throttle valve. The throttle gear engages the intermediate gear. Therefore, by adjusting the position of the intermediate gear, the interface between the intermediate gear and the throttle gear may be suitably established.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1
is a cross sectional view of a representative throttle body according to the present invention;
FIG. 2
is a side view of a main body of the throttle body with a cover removed;
FIG. 3
is a side view of a metal plate of the throttle body; and
FIG. 4
is a sectional view showing the operation of one of mounting holes of the metal plate.
DETAILED DESCRIPTION OF THE INVENTION
Each of the additional features and teachings disclosed above and below may be utilized separately or in conjunction with other features and teachings to provide improved throttle bodies and methods of using such throttle bodies. Representative examples of the present invention, which examples utilize many of these additional features and teachings both separately and in conjunction, will now be described in detail with reference to the attached drawings. This detailed description is merely intended to teach a person of skill in the art further details for practicing preferred aspects of the present teachings and is not intended to limit the scope of the invention. Only the claims define the scope of the claimed invention. Therefore, combinations of features and steps disclosed in the following detailed description may not be necessary to practice the invention in the broadest sense, and are instead taught merely to particularly describe representative examples of the invention. Moreover, various features of the representative examples and the dependent claims may be combined in ways that are not specifically enumerated in order to provide additional useful embodiments of the present teachings.
A representative embodiment will now be described with reference to the drawings. Referring to
FIGS. 1
to
3
, a representative throttle body
1
includes a main body
2
that is made of a lightweight molded material, preferably a synthetic resin such as ABS resin, by using a suitable molding process, preferably an injection molding process. An intake air channel
2
a
is formed in the main body
2
. A throttle shaft
3
is rotatably supported within the main body
2
and extends across the intake air channel
2
a
. A throttle valve
4
is disposed within the intake air channel
2
a
and is secured to the throttle shaft
3
via fastening devices, preferably screws
5
. As the throttle shaft
3
rotates, the throttle valve
4
rotates within the intake air channel
2
a
, so that the amount of air flowing through the intake air channel
2
a
can be controlled. A throttle gear
6
is secured to one end (the lower end as viewed in
FIG. 1
) of the throttle shaft
3
. A biasing device, shown as a torsion coil spring
7
, is disposed within the main body
2
and serves to bias the throttle valve
4
in the closing direction. To achieve this result, one end of the torsion coil spring
7
is attached to the throttle gear
6
. The other end of the torsion coil spring
7
is attached to the main body
2
. The torsion coil spring
7
biases the throttle valve
4
via the throttle gear
6
.
An adjusting means, preferably a screw
8
, is mounted within the main body
2
and is positioned to oppose to the throttle gear
6
in a rotational direction, preferably in the closing direction of the throttle valve
4
. Therefore, as the throttle gear
5
rotates in the closing direction, the throttle gear
6
contacts one end of the adjusting screw
8
so that the throttle gear
6
, and subsequently the throttle valve
4
, is inhibited from further rotation. The adjusting screw
8
determines the full-close position of the throttle valve
5
. Additionally, magnets
9
are fitted into recesses
6
a
formed in the throttle gear
6
for a throttle sensor
18
system used to determine the physical orientation of the throttle valve
4
.
Referring to
FIG. 1
, the main body
2
includes a substantially cylindrical cavity portion
2
b
that defines a space for receiving a motor
10
. A metal plate
11
is fixedly joined to one axial end (the lower end as viewed in
FIG. 1
) of a motor casing
10
b
of the motor
10
by using appropriate bonding technique, such as welding. Alternatively, the metal plate
11
may be joined to the motor casing
10
b
by fastening means; some examples include screws, rivets, spring clips, spot welding, or snap fitting, among others. In addition, the metal plate
11
may be formed integrally with the motor casing
10
.
As shown in
FIG. 3
, the metal plate
11
has a substantially rhomboidal configuration with rounded points of intersected and has a circular central hole
11
b
through which an output shaft
10
a
of the motor
10
extends (see FIG.
1
). A pair of mounting holes
11
a
are formed at both ends on oppose sides in the diametrical direction of the metal plate
11
. The metal plate
11
is secured to the main body
12
by inserting screws
12
into the mounting holes
11
a
and tightening the screws
12
into corresponding threaded holes
2
d
(one threaded hole
2
d
is shown in
FIG. 4
) formed in the main body
2
. As shown in
FIG. 3
, each of the mounting holes
11
a
has a configuration elongated in the circumferential direction (about the axis of the central hole
11
b
), so that the angular position of the metal plate
11
about the axis of the central hole
11
b
relative to the main body
2
can be adjusted within a range equal to the circumferential length of a mounting hole
11
a
minus the length of the diameter of a shank
12
a
(see
FIG. 4
) of the screw
12
. A gear shaft
14
is inserted into an insertion hole
11
c
formed in the metal plate
11
. An appropriate fixing technique, some examples of which include threading, gluing, brazing, crimping, and press fitting, fixes the gear shaft
14
within the insertion hole
11
c
. The insertion hole
11
c
is positioned at one end of the metal plate
11
in a direction radially outward from the axis of the central hole
11
b
. In the current embodiment shown, the radial direction is approximately perpendicular to a line connecting the two mounting holes
11
a
with the axis of the central hole
11
b
, but this particular orientation is specific to this embodiment and many other orientations can also be used. Because, the gear shaft
14
is fixed to the metal plate
11
, the angular position of the gear shaft
14
about a drive gear
15
that is fixed to the output shaft
10
a
of the motor
10
can be adjusted by changing the fixing positions of the screws
12
relative to the metal plate
11
by utilizing the elongated mounting holes
11
a.
An intermediate gear
14
is rotatably mounted on the gear shaft
14
. The intermediate gear
14
has a large gear portion
13
a
and a small gear portion
13
b
that engage the drive gear
15
and the throttle gear
13
, respectively. Because the angular position of the gear shaft
14
about the drive gear
15
can be adjusted as described above, the relative position of the intermediate gear
13
and the throttle gear
6
can be adjusted in order to provide a proper engagement between the intermediate gear
13
and the throttle gear
6
.
Referring to
FIG. 1
, a cover
16
is mounted to the main body
2
in order to close an internal space
2
c
that is defined within the main body
2
in order to accommodate various internal elements of the main body
2
, including but not limited to, the throttle gear
6
, the intermediate gear
13
, and the drive gear
15
. The cover
16
includes a cover body
17
. The cover body
17
has a recess
14
configured to receive and support one end of the gear shaft
14
when the cover
16
is mounted to the throttle body
2
. In addition, a throttle sensor
18
is mounted on the cover body
17
prior to the mounting of the cover
16
onto the main body
2
of the throttle body
1
. To this end, the throttle sensor
18
is positioned to face to the magnets
9
of the throttle gear
6
when the cover
16
is mounted to the throttle body
1
. The throttle sensor
18
cooperates with the magnets
9
to output signals that represent the degree of opening of the throttle valve
4
. The signals outputted from the throttle sensor
18
are transmitted to an ECU (electronic control unit) of an internal combustion engine (not shown) in order to control the operation of the engine. The motor
10
is electrically connected to an outside power source, e.g., a battery, via an electric line (not shown), which is in turn connected to the ECU, so that the rotation of the motor
10
can be controlled by the ECU.
According to the representative embodiment, the gear shaft
14
that supports the intermediate gear
13
is secured to the metal plate
11
that is secured to the motor casing
10
b
. Therefore, the metal plate
11
may have a relatively small size and may be manufactured at a lower cost due to the smaller size. In addition, the small metal plate
11
may reliably maintain the relative positions between the drive gear
15
of the motor
10
and the intermediate gear
13
without being negatively affected by either residual molding stress and/or strain or by forces applied to the throttle body
2
during the assembly process. In addition, the relative positions of the intermediate gear
13
and the throttle gear
6
can be adjusted in order to provide a proper engagement between the intermediate gear
13
and the throttle gear
6
. Therefore, the drive gear
15
, the intermediate gear
13
, and the throttle gear
6
, may properly engage with each other without causing extraordinary wear. As a result, there is improved controllability of the throttle valve
4
along with lower manufacturing cost for throttle body
1
.
The above representative embodiment may be modified in various ways without departing from the scope of the present invention.
For example, although the mounting holes
11
a
of the metal plate
11
are elongated in the circumferential direction about the axis of the output shaft
10
a
of the motor
10
in the representative embodiment, the mounting holes
11
a
may be elongated in any other directions, such as radial direction of the output shaft
10
a
and a direction inclined relative to the radial direction. In addition, each mounting hole
11
a
may be configured by the combination of elongated holes extending in different directions and intersect with each other, so that the freedom of adjustment can be increased. For example, at least one mounting hole
11
a
may have a distorted configuration comprising many different shapes or combination of shapes, for example, configurations such as a crisscross configuration, a T-shaped configuration, or any other intersecting configurations. The mounting holes
11
a
are not required to be identically shaped; one mounting hole
11
a
may be elongated while the opposing mounting hole
11
a
may not be elongated.
In addition, although the screws
12
engage with the threaded holes
12
a
formed in the main body
2
in the above representative embodiment, the screws
12
may be replaced with threaded shafts that are fixed in position relative to the main body
2
.
Claims
- 1. A throttle body comprising:a main body made of resin; a throttle valve, a motor and a gear mechanism disposed within the main body; so that the rotation of the motor is transmitted to the throttle valve via the gear mechanism, wherein the gear mechanism includes a drive gear mounted to an output shaft of the motor and an intermediate gear disposed between the drive gear and the throttle valve; a metal plate mounted to a motor casing of the motor, wherein the intermediate gear is mounted to the metal plate; and an adjusting device arranged and constructed to adjust the position of the intermediate gear relative laterally across a face of the main body.
- 2. A throttle body as in claim 1, further including a fixing device arranged and constructed to fix the metal plate in position relative to the main body, wherein the adjusting mechanism serves to adjust the relative position between the metal plate and the main body.
- 3. A throttle body as in claim 2, wherein the metal plate is fixed in position relative to the motor casing.
- 4. A throttle body as in claim 3, further including a gear shaft that is secured to the metal plate, and the intermediate gear is rotatably mounted on the gear shaft.
- 5. A throttle body as in claim 4, wherein the adjusting mechanism comprises at least one mounting hole formed in the metal plate, and the mounting hole is adapted to receive a fixing device has an elongated configuration having a length that is greater than the width of the mounting hole.
- 6. A throttle body as in claim 5, wherein the fixing device comprises a screw.
- 7. A throttle body as in claim 5, wherein the mounting hole is elongated in a circumferential direction of the metal plate substantially about the axis of the output shaft of the motor.
- 8. A throttle body as in claim 6, wherein the screw engages a threaded hole formed in the main body.
- 9. A throttle body as in claim 5, wherein the gear mechanism further includes a throttle gear that is coupled to the throttle valve and is rotatable with the throttle valve, and the throttle gear engages the intermediate gear.
- 10. A throttle body comprising:a main body made of resin; and a throttle valve, a motor and a gear mechanism disposed within the main body; so that the rotation of the motor is transmitted to the throttle valve via the gear mechanism, wherein the gear mechanism includes a drive gear mounted to an output shaft of the motor and an intermediate gear disposed between the drive gear and the throttle valve; and a metal plate mounted to a motor casing of the motor, wherein the intermediate gear is mounted to the metal plate; and an adjusting device arranged and constructed to adjust the position of the intermediate gear relative laterally across a face of the main body; and a fixing device arranged and constructed to fix the metal plate in position relative to the main body, wherein the adjusting mechanism serves to adjust the relative position between the metal plate and the main body; and a gear shaft secured to the metal plate, wherein the intermediate gear is rotatably mounted on the gear shaft.
- 11. A throttle body as in claim 10, wherein the adjusting mechanism comprises at least one mounting hole formed in the metal plate, and the mounting hole is adapted to receive the fixing device and has a distorted configuration allowing adjustment in at least one dimension in a plane parallel to the metal plate.
- 12. A throttle body as in claim 10, wherein the adjusting mechanism comprises at least one mounting hole formed in the metal plate, and the mounting hole is adapted to receive the fixing device and has an elongated configuration having a length that is greater than the width of the mounting hole.
- 13. A throttle body as in claim 10, wherein the adjusting mechanism comprises at least one mounting hole formed in the metal plate, and the mounting hole is adapted to receive the fixing device and has a t-shaped configuration allowing adjustment in at least two dimensions in a plane parallel to the metal plate.
- 14. A throttle body as in claim 10, wherein the gear mechanism further includes a throttle gear that is coupled to the throttle valve and is rotatable with the throttle valve, and the throttle gear engages the intermediate gear.
- 15. A throttle body comprising:a main body made of resin; and a throttle valve, a motor and a gear mechanism disposed within the main body; so that the rotation of the motor is transmitted to the throttle valve via the gear mechanism, wherein the gear mechanism includes a drive gear mounted to an output shaft of the motor and an intermediate gear disposed between the drive gear and the throttle valve; and a metal plate mounted to a motor casing of the motor, wherein the intermediate gear is mounted to the metal plate; and an adjusting device arranged and constructed to adjust the position of the intermediate gear relative laterally across a face of the main body; and a fixing device arranged and constructed to fix the metal plate in position relative to the main body, wherein the adjusting mechanism serves to adjust the relative position between the metal plate and the main body; and a gear shaft secured to the metal plate, wherein the intermediate gear is rotatably mounted on the gear shaft; and wherein the gear mechanism further includes a throttle gear that is coupled to the throttle valve and is rotatable with the throttle valve, and the throttle gear engages the intermediate gear; and wherein the adjusting mechanism comprises at least one mounting hole formed in the metal plate, and the mounting hole is adapted to receive a fixing device and has a distorted configuration allowing adjustment in at least one dimension in a plane parallel to the metal plate.
Priority Claims (1)
Number |
Date |
Country |
Kind |
2002-361478 |
Aug 2002 |
JP |
|
US Referenced Citations (3)
Foreign Referenced Citations (1)
Number |
Date |
Country |
2001303983 |
Oct 2001 |
JP |