DE102022106335A1 - VARIABLE AIR FUNNEL STRUCTURE - Google Patents

Abstract

A variable hopper structure is provided which reduces power consumption of an actuator for driving a movable hopper and improves durability of the actuator. An air filter 12, at least one fixed hopper 22, at least one movable hopper 23, and an actuator 40 driving the movable hopper 23 moves are provided. A funnel length is variable between an expanding state and a contracting state by a driving force of the actuator 40 . At least one elastic member 27 biasing the movable funnel 23 in one direction is further provided. The actuator 40 does not exert a driving force in a state where the movable hopper 23 is positioned at an extension position or a contraction position. The movable hopper 23 is held in a state where it is at the expanding position or the contracting position only by the biasing force of the elastic member 27 . The above configuration reduces power consumption of the actuator for maintaining a position of the movable hopper and improves durability of the actuator.

Description

[Technical scope]

The present invention relates to a variable venturi structure for an internal combustion engine.

[State of the art]

As a conventional method, there are variable venturi structures each arranged in the air cleaner that supplies intake air to the internal combustion engine. Such a variable air horn structure includes fixed horns and movable horns. These hoppers are arranged in an expanding state in which the movable hoppers are connected to the fixed hoppers. This variable venturi structure also includes an actuator that biases the movable hoppers in a direction toward the fixed hoppers to move the movable hoppers in a direction in which the movable hoppers are connected to the fixed hoppers. The expanding state of the funnels is maintained by continuously driving the actuator or intermittently driving the actuator (refer to Patent Document 1).

In such a variable air hopper structure, the actuator is continuously driven all the time or the actuator is driven intermittently to keep the expansion state of the hoppers. Thus, there are problems that the power consumption of the actuator is large and the durability of the actuator is required.

[Prior Art Document]

[patent specification]

Patent Specification 1: JP 2008-45535 A

[Outline of the Invention]

[Underlying Problem to be Solved by the Invention]

The present invention was made to solve the above problems, and it is an object of the present invention to provide a variable venturi structure that reduces power consumption of an actuator provided for maintaining a position of a movable horn and improves durability of the actuator .

[Means to Solve the Problem]

In order to achieve the above objective, a variable air funnel structure according to the present invention, on an air cleaner mounted on a vehicle having an internal combustion engine, has a fixed funnel, at least one movable funnel designed to be moved with respect to the fixed funnel and an actuator configured to move the movable hopper.

A funnel length in the air cleaner is variable between an expanding state and a contracting state by moving the movable funnel by a driving force of the actuator.

When the funnel length is in an expanding state, the movable funnel is positioned in an expanding position, and when the funnel length is in a contracting state, the movable funnel is positioned in a contracting position.

The variable venturi structure according to the present invention further includes at least one elastic member that biases the movable venturi in one direction.

In a state where the movable hopper is positioned at an expanding position or in a state where the at least one movable hopper is positioned at the shortening position, no driving force is output from the actuator.

The movable hopper is held only by a biasing force of the elastic member in the state where the movable hopper is positioned at the expanding position or in the state where the movable hopper is positioned at the contraction position.

According to the above configuration, it is possible to avoid driving the actuator for maintaining the state in which the movable hopper is positioned at the extension position or the contraction position. Furthermore, the durability of the actuator can be improved.

In the above configuration, in the expanding position, the movable funnel can be connected to the fixed funnel fixed in the air cleaner.
Then, the movable funnel can be maintained in a state where it is positioned at the expanding position only by the biasing force of the elastic member.

According to the above configuration, the movable hopper is pressed against the fixed hopper by the biasing force of the elastic member. Thus, it is possible to improve airtightness between the movable hopper and the fixed hopper. Furthermore, the elastic member absorbs vibration or the like. Thus, it is possible to suppress generation of excessive stresses in the movable hopper and the fixed hopper.

In the above configuration, an end portion of the movable hopper configured to be connected to the fixed hopper may have a flange formed as the same member as the movable hopper.

According to the above configuration, the movable hopper is biased toward a side of the fixed hopper by the elastic member. Thus, there is no need to provide a seal or the like as a separate element. Therefore, the airtightness can be improved with a simple structure.

In the above configuration, the fixed funnel can be fixed in the air cleaner.
The movable funnel can be separated from the fixed funnel in the shortening position.
In the shortening position, the movable funnel can be fixed at a position where the biasing force of the elastic member and the driving force of the actuator are balanced.

According to the above configuration, even if a vibration or the like is applied in a state where the movable hopper is maintained at the shortening position, the vibration is absorbed by the elastic member. Thus, it is possible to suppress excessive stresses from being generated in the peripheral components.

In the above configuration, the movable funnel can be moved along the at least one columnar member provided in the air cleaner.

The at least one elastic member may be at least one spring through which the columnar member is inserted.

According to the above configuration, there is no need to provide a space or structure for a separate casing of the elastic member.
Thus, the variable venturi structure can be reduced in size.

In the above configuration, the plurality of movable hoppers can be provided identically to the at least one movable hopper.
The plurality of movable hoppers adjacent to each other may be integrated into an integrated movable hopper through a connection portion. A plurality of column members identical to the at least one column member and a plurality of elastic members identical to the at least one elastic member may be provided so as to be positioned at diagonally facing corners in the integrated movable hopper.

According to the above configuration, each of the columnar members and each of the elastic members are provided at each of the diagonally facing corners in the plurality of movable hoppers that is integrated. Thus, inclination or the like of the movable hoppers is less likely to occur, and the movable hoppers can be moved seamlessly.

In the above configuration, the holding member may be provided in the air cleaner.
The columnar members, the elastic members, and the movable funnels may be attached to the holding member.
Then the holding element can be attached to the air filter.

According to the above configuration, the column members, the elastic members, and the movable funnels are assembled together in a sub-assembly attached to the support member. Then the holding element is fixed to the air filter. Thus, ease of assembly is improved.

[Effects of the invention]

According to a variable air hopper structure of the present invention, it is possible to avoid driving the actuator for maintaining the state in which the movable horn is positioned at an extension position or a contraction position. Furthermore, the durability of the actuator can be improved.

character list

• 1 14 is a left side view of a motorcycle to which an air hopper device according to an embodiment of the present invention is applied.
• 2 Fig. 12 is a left side view of the internal combustion engine.
• 3 12 is a perspective view of an air cleaner 12 from which an upper air cleaner box is removed.
• 4 12 is a perspective view of the variable venturi device.
• 5 12 is a front view of the variable venturi device viewed from the front.
• 6 Fig. 12 is a plan view of a variable venturi device viewed from above.
• 7 Fig. 14 is a perspective view of a holding member.
• 8th Fig. 12 is a plan view of the holding member.
• 9 14 is an enlarged cross-sectional view of a main part taken along the direction of arrows along line IX-IX in FIG 6 was created.
• 10 13 is a cross-sectional view and a cross-sectional view taken in the direction of arrows along the line XX in FIG 6 was drawn up, in which an expanding state of hoppers in which a movable hopper is positioned at an expanding position is shown.
• 11 Fig. 14 is a cross-sectional view showing a shortening state of funnels in which the movable funnel is in a shortening position in 10 positioned is shown.

[Mode for Realizing the Invention]

The following is an embodiment of the present invention with reference to 1 until 11 described.
1 Fig. 14 is an entire left side view of a motorcycle 100 mounting an internal combustion engine 1 to which a variable venturi device according to an embodiment of the present invention is applied.
In the present specification, the front, rear, left, and right directions are defined according to a normal standard of a vehicle in which the straight forward traveling direction of the motorcycle 100 is defined as the front. In the description regarding the vertical direction of the variable louver structure, in a central axis L of a louver 21, the intake air upstream side is defined as the upper side, and the intake air downstream side is defined as the lower side.

As in 1 shown, a vehicle body frame 101 of the motorcycle 100 has a head tube 102, a pair of left and right main frames 103, a pair of left and right engine mounts 105, a pair of left and right swing frames 104 and a pair of left and right seat rails 106. The head tube 102 steerably supports a front fork 111 which further supports a front wheel 112 axially. The left and right main frames 103 extend backward and downward from the head tube 102 . The left and right engine mounts 105 are connected to the steering head tube 102 and front portions of the left and right main frames 103 and extend under the main frames 103 rearward and downward. The left and right swing frames 104 are continuously provided with rear end portions of the main frames 103 and extend downward. The left and right seat rails 106 extend rearward and upward from rear portions of both main frames 103 .

In the vehicle body frame 101, the engine 1 is mounted, and a front and a rear thereof are suspended under the main frames 103 by the engine hangers 105 and the swing frames 104, respectively. A swing arm 113 pivotally supported at a front end thereof by the swing frames 104 extends rearward, and in a rear end portion of the swing arm 113, a rear wheel 114 is axially supported. An endless chain 117 is wound around a driving sprocket 115 fitted on an output shaft 9 of the engine 1 and the driven sprocket 116 is fitted on a rear axle.

An air cleaner 12 is arranged above the engine 1 so as to be positioned behind the steering head pipe 102 in the body frame 101 . A fuel tank 17 covering a rear portion and an upper portion of the air cleaner 12 is attached to both main frames 103 in the vehicle body frame 101 . A main seat 107 and a passenger seat 108 are provided behind the fuel tank 17 while being held by the seat rails 106 . A radiator 18 is arranged in front of the internal combustion engine 1 .

2 14 is a left side view of the internal combustion engine 1, with illustration of the air cleaner 12 omitted. The internal combustion engine 1 forms what is known as a drive unit, which has a transmission 8 in a crankcase 2 .
The present engine 1 is a water-cooled parallel four-cycle engine. In the internal combustion engine 1, a crankshaft 7 is aligned in a vehicle width direction (left-right direction), and four cylinders are arranged side by side at an equal pitch in the vehicle width direction. The engine 1 is fixed to the vehicle frame 101 so as to be arranged transversely.

The crankcase 2 is designed to be divided vertically into an upper crankcase 2A and a lower crankcase 2B to be the To axially hold the crankshaft 7 aligned in the vehicle width direction (left-right direction) so that the crankshaft 7 is sandwiched between the upper crankcase 2A and the lower crankcase 2B from above and below.
A cylinder block 3 is formed integrally with an upper front portion of the upper crankcase 2A while being slightly inclined forward. On the cylinder block 3, the cylinder head 4 is overlapped, and the cylinder block 3 and the cylinder head 4 are fixed integrally by stud bolts. The cylinder head cover 5 is arranged on the cylinder head 4 . An oil pan 6 is mounted under the crankcase 2B.

The crankshaft 7 is rotatably held in the crankcase 2 and the transmission 8 is installed behind the crankshaft 7 .
On the rear side wall 4R of the cylinder head 4, slightly inclined forward, four throttle valves 10 and four funnels 21 are connected to the intake ports 4a while being arranged in a cylinder arrangement direction and provided so as to protrude upward. As in 1 and 3 shown, the funnels 21 are inserted into a clean side of the air filter 12 .

On a front side wall 4F of the cylinder head 4, exhaust pipes 15 are connected to exhaust ports 4b and extend forward. Then, the exhaust pipes 15 are bent downward and make a turn and run under the engine 1, while running rearward, are further bent upward and then connected to a muffler 16 arranged under the passenger seat 108 (see 1 ).

Next, a variable venturi device 20 serving as the variable venturi structure will be described in detail.
As in 1 As shown, the motorcycle 100 includes the air cleaner 12 that takes in and cleans the outside air, and the variable venturi device 20 that is attached to the throttle bodies 10 of the internal combustion engine 1. As shown in FIG.

The air filter 12 has an air filter box 13 and a filter 14 arranged in the air filter box 13 (see Fig 3 ). The air cleaner box 13 is formed by a lower air cleaner box 13a and an upper air cleaner box 13b. The upper air filter box 13b is attached to the lower air filter box 13a, and thus the air filter box 13 has a space partitioned from the outside. The interior of the air filter box 13 is divided into a dirty side and a clean side by the filter 14 interposed therebetween.

3 12 is a perspective view of the air cleaner 12 in a state where the upper air cleaner box 13b is removed from the lower air cleaner box 13a. The filter 14 is attached to a front side in a vehicle direction of the air filter box 13 , and the variable air filter device 20 is arranged to a rear side of the air filter box 13 . The variable air filter device 20 has the funnels 21 corresponding to each of the cylinders of the internal combustion engine 1, respectively. Therefore, the variable air filter device 20 according to the present embodiment has the four hoppers 21 .

The variable venturi device 20 includes an actuator 40 . A length of the funnels 21 is changed according to an engine speed of the engine 1 via a driving force of the actuator 40 . In the variable air hopper device 20, the length of the hopper 21 is lengthened when the engine speed is in a low speed range, and the length of the hopper 21 is shortened when the engine speed is in a high speed range. Thus, the variable air funnel device 20 attempts to exert power to ensure high torque throughout the engine speed ranges.

4 FIG. 14 is a perspective view showing the variable venturi device 20. FIG. 5 12 is a front view of the variable venturi device 20. FIG. Each of the hoppers 21 has a fixed hopper 22 and a movable hopper 23 . The movable hopper 23 is moved with respect to the fixed hopper 22 in a direction along the central axis L of the fixed hopper 22 .

The fixed funnel 22 has a cylinder portion 22a having a cylindrical shape through which the intake air flows. An upper end of the cylinder portion 22a is formed as a flange portion 22b which is bent and has a flange shape. With further reference to 5 At least one attachment portion 22c is formed on an outer peripheral surface of the cylinder portion 22a so as to protrude from the cylinder portion 22a. A screw (not shown) is inserted through the attachment portion 22c. The screw is screwed into the lower air cleaner box 13a, and thus the fixed funnel 22 is fixed to the lower air cleaner box 13a.

A pair of adjacent fixed hoppers 22 are connected to each other and formed as an integral fixed hopper 32 . In the present embodiment, flange portions 22b of a pair of adjacent fixed hoppers 22 on the right side are connected to each other, and thus the pair of adjacent fixed hoppers 22 on the right th side as an integrated fixed funnel 32 is formed. At the same time, flange portions 22b of a pair of adjacent fixed hoppers 22 on the left side are continuously provided with each other, and thus the pair of adjacent fixed hoppers 22 on the left side is formed as another integrated fixed hopper 32.

The movable funnel 23 has a cylindrical portion 23a having a cylindrical shape through which the intake air flows. An upper end of the cylindrical portion 23a is formed as an upstream side flange portion 23b having a flange shape, and a lower end of the cylindrical portion 23a is formed as a downstream side flange portion 23c having a flange shape. The upstream-side flange portion 23 b and the downstream-side flange portion 23 c are formed as the same member as the cylindrical portion 23 a of the movable hopper 23 . On an outer peripheral surface of the cylindrical portion 23a, an insertion portion 23d of a columnar member is formed so as to protrude from the outer peripheral surface of the cylindrical portion 23a. A columnar member 26, which will be described later, is inserted through the columnar member insertion portion 23d.

The flange portions 23b on the upstream side of a pair of movable hoppers 23 are continuously provided with each other and are thus integrated. Furthermore, as in 5 As shown, the cylindrical portions 23a of the pair of movable hoppers 23 are integrated by a connecting portion 23e. In this way, the pair of movable hoppers 23 is formed as an integrated movable hopper 33 that is integrated. In the present embodiment, a pair of adjacent movable hoppers 23 on the right side and a pair of adjacent movable hoppers 23 on the left side are integrated into the respective integrated movable hoppers.

As in 4 As illustrated, the variable venturi device 20 has a holding member 24 which holds a rotary shaft 45 which is rotated by transmission of the motive force transmitted from the actuator 40. As shown in FIG.

As in 7 and 8th 1, an expanding portion 24b is formed in the holding member 24 so as to extend forward from the center in the left and right direction of a rod-shaped main body portion 24a extending in the left and right direction. Tip ends of the extension portion 24b are formed as bifurcated branch portions 24c. One of the branching areas 24c runs obliquely right forward and the other branching area 24c runs obliquely left forward. At left and right end portions of the main body portion 24a and end portions of the branch portions 24c, respective column member holding portions 24d holding the respective column members 26 are provided so as to protrude upward (see FIG 4 ). Screw holes 24e through which the screws 30 are inserted are provided on left and right sides of the main body portion 24a and a branch point between the extension portion 24b and the branch portions 24c of the extension portion 24b. As in 4 As shown, the bracket member 24 is fixed to the lower air cleaner box 13a by inserting the bolts 30 through the bolt holes 24e of the bracket member 24 and screwing the bolts 30 into the bolt attachment portions 13a ₁ of the lower air cleaner box 13a.

As in 7 and 8th 1, rotating shaft holding portions 24f are formed on the left and right sides of the main body portion 24a of the holding member 24 so as to protrude upward. The rotary shaft holding portions 24f hold the rotary shaft 45 which will be described later. On an upper surface of each of the rotary shaft holding portions 24f, a recessed portion 24g that holds the rotary shaft 45 is formed. Then, after the rotary shaft 45 is placed at the recessed portions 24g, upper surfaces of the rotary shaft holding portions 24f are covered with plate-shaped members 24h, and the plate-shaped members 24h are fixed to the rotary shaft holding portions 24f by screws 24i, thereby making the rotary shaft 45 rotatable hold as in 4 shown.

9 14 is an enlarged cross-sectional view taken in the direction of arrows along line IX-IX in FIG 6 was created. As in 9 As shown in FIG 7 shown. As in 4 As shown, the column members 26 are arranged to be positioned at diagonally facing corners in the integrated movable hoppers 33 each having the pair of movable hoppers 23 that is integrated. That is, the pillar members 26 are arranged on the inside of the vehicle body in the front of the integrated movable hoppers 33 and on the outside of the vehicle body in the rear of the integrated movable hoppers 33 .

As in 9 1, a bushing 25 is inserted into each of the inserting portions 23d of the columnar members of the movable hoppers 23. As shown in FIG. The bushing 25 has a cylindrical portion 25a having a cylindrical shape and a flange portion 25b formed at an upper portion of the cylindrical portion 25a. The columnar member 26 erected on the columnar member holding portion 24d of the holding member 24 is inserted through the bushing 25 fitted into the columnar member insertion portion 23d of the movable hopper 23 . The integrated movable hopper 33 is arranged movably in the vertical direction along the columnar members 26 . The bushings 25 reduce friction generated when the integrated movable hopper 33 is moved along the columnar members 26 and also improve durability.

A spring 27 serving as an elastic member is placed in contact with the flange portion 25b of the bushing 25. As shown in FIG. The spring 27 is attached to the column member 26 such that the column member 26 is inserted through the inside of the spring 27 . With further reference to 4 a coupling member 28 for coupling the pair of pillar members 26 located at the diagonally facing corners is attached so that the top ends of the springs 27 are in contact with the coupling member 28 . Both ends of the coupling member 28 are fastened and fixed to end portions of the columnar members 26 by bolts 29 . Each of the springs 27 is mounted in a compressed state between the flange portion 25b of the bushing 25 and the coupling member 28, and thus the movable hoppers 23 are always biased in a direction toward the fixed hoppers 22.

As in 4 and 10 As shown, the actuator 40 has an output shaft 40a. To the output shaft 40a, one end of the first link 41 is attached in a non-rotatable manner thereto. To the other end of the first link 41, one end of the second link 42 is rotatably coupled, and to the other end of the second link, one end of a third link 43 is rotatably coupled.

At the other end of the third link, the rotary shaft 45 rotatably supported by the support member 24 is attached in a non-rotatable manner thereto. A rotating force of the actuator 40 is transmitted to the rotating shaft 45 through the first link 41, the second link 42, and the third link 43 rotatably coupled to each other.

As in 6 As shown, the two rotation levers 46 are attached to the rotation shaft 45 and are positioned on the left and right sides of the rotation shaft 45 . Each of the rotating levers 46 is attached so as to correspond to a position of each of the connecting portions 23e of the integrated movable hoppers 33. FIG. As in 10 1, one end 46a of the rotating lever 46 is fixed to the rotating shaft 45 so as to be rotated integrally with the rotating shaft 45. As shown in FIG. The other end 46b of the rotary lever 46 is a roller 46c rotatably mounted.

As in 10 As shown, in the connecting portion 23e connecting the pair of movable funnels 23, a C-shaped recessed portion 23f is formed and is opened in a cross section in the front-rear-rear direction. A metal member 23g having a shape conforming to the inside of the recessed portion 23f is fitted into the recessed portion 23f, and is fixed to the connecting portion 23e by a screw 23h. The inside of the metal member 23g of the connecting portion 23e is formed as a roller insertion portion 23i in which the roller 46c attached to the other end 46b of the rotary shaft 46 is inserted.

Upper and lower surfaces of the metal member 23g and an outer peripheral surface of the roller 46c are set to be in contact with each other. The roller 46c moves seamlessly in the front and rear direction in the roller insertion portion 23i while rotating. Thus, slippage between the rotary lever 46 and the movable hoppers 23 is reduced, and hence durability is improved.

The integrated movable hoppers 33 are moved in the vertical direction along the columnar members 26 by the driving force of the actuator 40 and the biasing forces of the springs 27 .

The actuator 40 is provided with an arm position detection sensor 50 . The arm position detection sensor 50 detects a rotation angle of the output shaft 40a and performs feedback control on positions of the movable hoppers 23 when the length of the hoppers is in a shortening state. With the arm position detection sensor 50, it is possible to continuously control a movement of the movable hoppers 23, and it is also possible to control a moving speed of the movable hoppers 23.

Next, an operation of the variable venturi device 20 will be described.
As in 5 and 10 shown when the actuator 40 is not actuated are the movable trich ter 23 biased to one side of the fixed funnels 22 by only the biasing forces of the springs 27 are absorbed. The movable hoppers 23 are moved until the flange portions 23c on the downstream side of the movable hoppers 23 come into contact with the flange portions 22b of the fixed hoppers 22 and are thus positioned in an expanding area. In the hoppers 21, the fixed hoppers 22 and the movable hoppers 23 are connected, and thus the hopper length becomes an expanding state.

When the hopper length is in the expanding state, the movable hoppers 23 are arranged in a state where the movable hoppers 23 are constantly pressed against the fixed hoppers 22 only by the biasing forces of the springs 27 .

When actuating the actuator 40, as in 4 and 11 As shown, the output shaft 40a of the actuator 40 rotates clockwise in the drawings. With this rotation, through the first link 41, the second link 42 and the third link 43, the rotary shaft 45 is rotated clockwise in the drawings. Then, the rotating levers 46 are rotated integrally with the rotating shaft 45 .

When each of the rotary levers 46 is rotated, the roller 46c at the tip end of the rotary lever 46 moves obliquely upward. Then, the roller 46c moves while rotating in the metal member 23g of the connection portion 23e of the movable hoppers 23 forward.

The movable hoppers 23 are moved upward along the columnar members 26 against the biasing forces of the springs 27 by the driving force of the actuator 40 . The flange portions 23c on the downstream side of the movable hoppers 23 are separated from the flange portions 22b of the fixed hoppers 22. The movable funnels 23 are fixed at a position where the biasing forces of the springs 27 and the driving force of the actuator 40 are balanced. Then, the state is transferred to the shortening state where the hopper length is short, and the movable hoppers 23 are maintained in the state where the movable hoppers 23 are positioned at the shortening position. At this time, the arm position detection sensor 50 performs the feedback control so that the movable hoppers 23 are positioned at a predetermined shortening position.

The variable venturi device 20 according to the present embodiment is configured as described above, and thus the following effects become apparent.

The variable air funnel device 20 has the air cleaner 12 which is attached to the motorcycle 100 which has the engine 1, the fixed funnels 22, the movable funnels 23 which are moved with respect to the fixed funnels 22, and the actuator 40 which has the movable Funnel 23 moves. By moving the movable funnel 23 by the driving force of the actuator 40, the funnel length in the air cleaner 12 is variable between the expansion state and the contraction state. When the hopper length is in the expanding state, the movable hopper 23 is positioned at the expanding position. When the funnel length is in the shortening state, the movable funnel 23 is positioned in the shortening position. The variable venturi device 20 further includes the springs 27 that bias the movable venturis 23 in one direction. In the state where the movable hopper 23 is positioned at the expanding position, the actuator 40 does not exert the driving force and the movable hopper 23 is maintained in the state where the movable hopper 23 is at the expanding position only by the urging force of the spring 27 is positioned. Therefore, the power consumption of the actuator 40 that drives the movable hopper 23 can be reduced. Furthermore, it is not necessary to operate the actuator 40 all the time, and thus the durability of the actuator 40 can be improved.

Moreover, the movable hopper 23 is pressed against the fixed hopper 22 only by the biasing force of the spring 27 in the extension position. Thus, it is possible to improve airtightness between the movable hopper 23 and the fixed hopper 22 . Furthermore, the spring 27 absorbs vibration or the like. Thus, it is possible to suppress generation of excessive stresses in the movable hopper 23 and the fixed hopper 22 .

Further, the end portion of the movable hopper 23 connected to the fixed hopper 22 is formed as the flange portion 23c on the downstream side formed as the same member as the movable hopper 23. As shown in FIG. The movable hopper 23 is biased to one side of the fixed hopper 22 by the spring 27 . Therefore, it is not necessary to provide a seal or the like as a separate member, and thus airtightness can be improved with a simple structure.

The fixed funnel 22 is fixed in the air cleaner 12 . The movable funnel 23 is the most fixed Current hopper 22 is separated in the shortening position, and in the shortening position, the movable hopper 23 is fixed at a position where the biasing force of the spring 27 and the driving force of the actuator 40 are balanced. Therefore, even if the vibration or the like is applied in a state where the movable hopper 23 is maintained at the shortening position, the vibration is absorbed by the spring 27. Thus, it is possible to suppress excessive stresses from being generated in the peripheral components.

In addition, the movable funnel 23 is moved along the columnar member 26 provided in the air cleaner 12 . The columnar member 26 is inserted through the spring 27 . Thus, it is not necessary to provide a space or structure for a self-contained housing of the elastic member. Therefore, the variable venturi device 20 can be reduced in size.

The multiple movable hoppers 23 are provided. The adjacent movable hoppers 23 are integrated into the integrated movable hopper 33 through the connection portion 23e. The multiple column members 26 and the multiple springs 27 are provided to be positioned along the diagonally facing corners in the integrated movable hopper 33 . Thus, inclination or the like of the movable hoppers 23 is less likely to occur, and the movable hoppers 23 can be moved seamlessly.

The holding member 24 is provided in the air cleaner 12 . The column members 26, the springs 27 and the movable funnels 23 may be attached to the support member 24. The holding member 24 is attached to the air cleaner 12 . Thus, the holding member 24 can be fixed in the air cleaner 12 after the columnar members 26, the elastic members 27 and the movable funnels 23 are assembled together in a sub-assembly attached to the holding member 24. Thus, ease of assembly is improved.

Although the embodiments of the present invention have been described above, it goes without saying that the mode of the present invention is not limited to the present embodiment and the present invention can be implemented in various modes within the scope of the spirit of the present invention.

Reference List

1

combustion engine

12

air filter

20

Variable air funnel device

22

Fixed funnel

23

Movable funnel

23b

Flange area on the upstream side

23c

Flange area on the downstream side

23e

connection area

24

holding element

26

column element

27

Feather

33

Integrated movable hopper

40

actuator

100

motorcycle

QUOTES INCLUDED IN DESCRIPTION

This list of documents cited by the applicant was 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.

Patent Literature Cited

• JP200845535A [0004]

Claims (7)

A variable venturi structure comprising: an air cleaner (12) mounted on a vehicle (100) having an internal combustion engine (1); at least one fixed hopper (22); at least one movable hopper (23) adapted to be moved with respect to the at least one fixed hopper (22); and an actuator (40) which is designed to move the at least one movable funnel (23), wherein a funnel length in the air filter (12) is variable between an expanding state and a shortening state, in that the at least one movable funnel (23) is moved by a driving force of the actuator (40), wherein the at least one movable hopper (23) is positioned in an expanding position when the hopper length is in an expanding state, wherein the at least one movable hopper (23) is positioned in a shortening position when the hopper length is in a shortening state, characterized in that the variable air hopper structure further comprises at least one elastic member (27) biasing the at least one movable hopper (23) in one direction, wherein in a state in which the at least one movable hopper (23) is positioned in the extension position, or in a state in which the at least one movable hopper (23) is positioned at the shortening position, the actuator (40) exerts no driving force, and wherein the at least one movable hopper (23) in the state in which the at least one movable hopper ( 23) is positioned at the expanding position, or in the state where the at least one movable funnel (23) is positioned at the contracting position, is held only by a biasing force of the at least one elastic member (27). Variable air funnel structure according to claim 1 , wherein in the expanding position, the at least one movable hopper (23) is connected to the at least one fixed hopper (22) fixed in the air cleaner (12), and the at least one movable hopper (23) in the state where the at least one movable funnel (23) positioned in the expanding position is held only by the biasing force of the at least one elastic element (27). Variable air funnel structure according to claim 2 , wherein an end portion of the at least one movable air funnel (23), which is designed to be connected to the at least one fixed funnel (22), has a flange (23c) which, as a same element as the at least one movable funnel (23 ) is trained. Variable air funnel structure according to one of Claims 1 until 3 , wherein the at least one fixed funnel (22) is fixed in the air filter (12), the at least one movable funnel (23) is separated from the at least one fixed funnel (22) in the shortening position, and the at least one movable funnel in the shortening position (23) is fixed in a position in which the biasing force of the at least one elastic member (27) and the driving force of the actuator (40) are balanced. Variable air funnel structure according to one of Claims 1 until 4 wherein the at least one movable funnel (23) is configured to be moved along at least one column member (26) provided with the air cleaner (12), and the at least one elastic member (27) is at least one spring (27). , through which the at least one column element (26) is inserted. Variable air funnel structure according to claim 5 wherein the at least one movable hopper (23) comprises a plurality of movable hoppers (23), and the plurality of movable hoppers (23) are provided, the plurality of movable hoppers (23) adjacent to each other in an integrated movable funnel (33) is integrated by a connecting portion (23e), and the at least one column member (26) comprises a plurality of column members (26), and the at least one elastic member (27) comprises a plurality of elastic members (27), and the plurality of column members (26) and the plurality of elastic members (27) are provided to be positioned at diagonally facing corners in the integrated movable hopper (33). Variable air funnel structure according to claim 5 or 6 wherein a holding member (24) is provided in the air cleaner (12), the plurality of columnar members (26), the plurality of elastic members (27) and the plurality of movable funnels (23) are attached to the holding member (24), and that Holding element (24) is attached to the air filter (12).

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