KR101855659B1 - Bypass passages solenoid valve - Google Patents

Abstract

The present invention relates to a bypass flow-path solenoid valve, which is provided in a communication passage and is composed of a housing, a solenoid portion, a plunger, and an airtight stopper so as to open a passage through which air is moved by multi- When the flow path is closed, the flow path is closed by moving the flow path in the moving direction of the air, thereby improving the response and reducing the size.

Description

BYPASS PASSAGES SOLENOID VALVE < RTI ID = 0.0 >

The present invention relates to a bypass channel solenoid valve.

In particular, after the plunger moves toward the high-pressure air passage, the airtight stopper is moved toward the high-pressure air passage so as to sequentially open the first and second flow paths, thereby minimizing the force exerted by the plunger. Pressure air passage. In addition, the present invention relates to a bypass flow solenoid valve capable of closing a flow path by moving in a direction opposite to a direction in which air flows in a high-pressure air passage, thereby opening the flow passage and quickly responding to closing of the flow passage.

Japanese Patent No. 10-1174207 discloses a "solenoid valve for opening and closing the flow path ".

A solenoid valve is a valve that plays a specific role through the movement set by the electrical signal.

When an electric signal is applied to the solenoid valve, the solenoid valve moves to the original position when the plunger moves in the set direction and then the electric signal is not applied.

Here, the solenoid valve does not cause any problem even if the above-described operating relationship is reversed.

The throttle valve serves to regulate the amount of air supplied to the engine.

The throttle valve is provided in a passage for supplying air to the engine.

In the passage for supplying such air, air which is moved in a direction opposite to the engine direction, that is, backflow air, is generated depending on various causes.

As an example, the air collides with the throttle valve and flows backward.

The throttle valve adjusts the amount of air supplied to the engine through the rotation. When the throttle valve is not pivoted to block the passage through which the air is moved, the throttle valve strikes the unrotated throttle valve and travels in a reverse direction (opposite to the engine, The turbocharger direction).

A bypass flow path is formed in the vehicle to prevent an output loss of the turbocharger, which is generated by supplying the above-described reverse flow air to the turbocharger.

The solenoid valve is installed in the bypass passage.

That is, the bypass passage solenoid valve is installed in a communication passage connecting between a high-pressure air passage connected to the engine side and a low-pressure air passage connected to the turbocharger.

The conventional bypass solenoid valve has a problem in response time.

That is, the solenoid valve operates in such a manner that the plunger moves in the direction in which the air moves in the high-pressure air passage, opens the communication passage, and then moves in the opposite direction to close the communication passage.

In this case, when the solenoid valve closes the communication passage, there is a problem that the communication passage can not be closed at the correct time by the high-pressure air.

Also, there is a problem that the plunger is disturbed by linear motion due to high pressure air.

A bypass channel solenoid valve having a reduced size is required because the plunger can move linearly and open or close the communication passage at an accurate timing and can open the communication passage even with a small electrical signal.

Korean Patent No. 10-1174207 discloses a solenoid valve for opening /

An object of the present invention is to provide a bypass channel solenoid valve having improved responsiveness.

An object of the present invention is to provide a bypass flow path solenoid valve in which response is improved when the communication path is closed by moving in a direction opposite to the direction in which air moves in the high pressure air path.

The present invention is configured such that the first flow path is opened through fine movement of the plunger and the airtight stopper is moved through the pressure in the chamber to open the second flow path so that the movement of the plunger is minimized so that the plunger moves to the minute electrical signal to open the flow path And the size of the bypass solenoid valve is reduced.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a bypass flow path solenoid valve in which the plunger and the airtight stopper are configured to move in a direction in which air flows in the high-pressure air path when the open path is closed, thereby closing the bypass path.

The present invention provides a bypass flow solenoid valve having a tip-shaped flange portion formed at a contact portion between an airtight portion and a hermetic stopper to improve airtightness and minimizing a contact portion between the airtight portion and the airtight stopper, .

The technical object of the present invention is not limited to the above-mentioned technical objects and other technical objects which are not mentioned can be clearly understood by those skilled in the art from the following description will be.

The bypass flow path solenoid valve according to an embodiment of the present invention may be composed of a housing, a solenoid unit, a plunger, and a hermetic stopper.

Here, the solenoid portion may include a bobbin, a coil wound around the bobbin, and a core for guiding a magnetic force generated when electricity is applied to the bobbin.

The bypass flow path solenoid valve according to the embodiment of the present invention is a bypass flow path solenoid valve installed in a communication path connecting between a high pressure air path and a low pressure air path and opening or closing the communication path according to an electrical signal, A hole communicating with the high-pressure air passage, a hole communicating with the low-pressure air passage, an airtight portion, and a chamber formed therein; A solute portion disposed at one side of the housing and generating a magnetic force according to an electrical signal; A plunger reciprocating a predetermined distance according to a magnetic force of the solenoid portion and opening a first flow path; And the plunger is formed so as to pass therethrough, one side surface and the other side surface being in contact with the plunger and the airtight portion to seal the communication passage, air is moved to the chamber through the first flow path opened according to the movement of the plunger When the pressure of the chamber becomes higher than the pressure of the high-pressure air passage, moves the second passage to move the air to the low-pressure air passage.

Therefore, a bypass solenoid valve having improved responsiveness can be realized.

Here, a guide having a predetermined length is formed around the plunger so that the plunger can move in a linear direction.

Therefore, the plunger can be moved linearly even when it is moved in the direction opposite to the direction in which the air in the high-pressure air passage is moved.

The plunger includes a first length and a second length longer than the first length. The length of the guide is not less than the second length so that the plunger moves in accordance with the electromagnet signal, The first passage is formed in the space defined by the difference in length between the second length and the length of the guide portion and in the space between the plunger and the airtight stopper.

Therefore, the first flow path can be formed even with small movement of the plunger.

Here, a stopper is provided at an end portion of the plunger at a distance from the guide portion.

Therefore, the stopper guides movement of the plunger, but does not close the first flow path.

Here, the plunger is formed with a step portion.

Thus, the air is guided and moved by the step portion of the plunger.

Here, a stopper is provided at an end of the plunger to prevent the plunger from moving beyond a predetermined range.

Here, the plunger reciprocates between the airtight stopper and the other side surface of the one side surface stopper.

At least one of the airtight stopper and the plunger is formed with a tip protruding at one side thereof.

Therefore, the space between the airtight stopper and the plunger is effectively airtight, and when the plunger and the airtight stopper collide, the contact area is reduced and the noise is reduced.

Here, the protruding flange portion is formed on at least one of the sealing portion of the housing and the sealing portion of the airtight stopper.

That is, due to the presence of the flange portion, the space between the housing and the airtight stopper is effectively airtight. When the airtight stopper and the housing collide with each other, the contact area is reduced and the noise is reduced.

Here, the plunger and the airtight stopper move in the direction of the high-pressure air passage to form respective flow paths.

Therefore, when the plunger and the airtight stopper close the flow path, the air in the high-pressure air flow path is moved in the moving direction, so that the flow path can be closed promptly.

The bypass solenoid valve according to an embodiment implemented through the above-described configuration can improve the responsiveness.

The bypass channel solenoid valve according to an embodiment implemented through the above-described structure moves in a direction opposite to the direction in which the air of the high-pressure air passage moves, thereby improving the responsiveness when the communication passage is closed have.

The bypass flow path solenoid valve according to an embodiment implemented through the above-described configuration opens the first flow path through the fine movement of the plunger and moves the airtight stopper through the pressure of the chamber to open the second flow path, The movement can be minimized and the plunger can be moved to the minute electrical signal to open the flow path, thereby realizing the effect of reducing the size.

The bypass flow path solenoid valve according to an embodiment implemented through the above-described configuration is configured such that when the open flow path is closed, the plunger and the airtight stopper are moved in the direction in which the air in the high pressure air path moves and closed, .

The bypass flow path solenoid valve according to an embodiment implemented through the above-described configuration has a tip-shaped flange portion formed at a portion where the airtight portion and the airtight stopper come into contact with each other to improve airtightness, minimize the abutment portion, .

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a view showing a position where a bypass flow path solenoid valve according to an embodiment of the present invention is installed; FIG.
2 is a cross-sectional view of a bypass flow path solenoid valve according to an embodiment of the present invention.
3 is a view illustrating a state in which a first flow path of a bypass flow path solenoid valve according to an embodiment of the present invention is opened.
4 is a view illustrating a state in which the second flow path of the bypass flow path solenoid valve according to the embodiment of the present invention is opened.

Hereinafter, an embodiment of the present invention will be described in detail with reference to exemplary drawings. However, this is not intended to limit the scope of the invention.

It should be noted that, in adding reference numerals to the constituent elements of the drawings, the same constituent elements are denoted by the same reference symbols as possible even if they are shown in different drawings. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

In addition, the size and shape of the components shown in the drawings may be exaggerated for clarity and convenience of explanation. In addition, terms specifically defined in consideration of the constitution and operation of the present invention are only for explaining the embodiments of the present invention, and do not limit the scope of the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a view showing a position where a bypass flow path solenoid valve according to an embodiment of the present invention is installed; FIG.

2 is a cross-sectional view of a bypass flow path solenoid valve according to an embodiment of the present invention.

3 is a view illustrating a state in which a first flow path of a bypass flow path solenoid valve according to an embodiment of the present invention is opened.

4 is a view illustrating a state in which the second flow path of the bypass flow path solenoid valve according to the embodiment of the present invention is opened.

In this specification, a low pressure in a low-pressure air passage is defined as including a negative pressure.

A bypass solenoid valve according to an embodiment of the present invention includes a housing 100, a solenoid unit 10, a plunger 200, and a hermetic stopper 500.

The bypass flow solenoid valve is installed in a bypass flow path which is formed in order to prevent the efficiency of the air supplied to the engine from being supplied to the turbocharger in a reverse direction.

Therefore, the bypass passage is composed of the high-pressure air passage, the low-pressure air passage, and the communication passage connecting therebetween.

Here, the bypass flow path solenoid valve is provided in the communication passage and serves to open or close the communication passage through which the air in the high-pressure air passage moves to the low-pressure air passage.

The housing 100 includes a hole 110 communicating with the high-pressure air passage, a hole 120 communicating with the low-pressure air passage, an airtight portion 130, and a chamber 140.

The high-pressure air passage and the low-pressure air passage may be arranged in the shape of "a " in one embodiment.

That is, according to Fig. 2, a high-pressure air passage may be formed in the lower portion and a low-pressure air passage may be formed in the left portion.

A chamber 140 may be formed in the housing 100, and the plunger 200 may be installed through the housing.

The housing 100 can be held in contact with the high-pressure air passage and the low-pressure air passage.

The airtight portion 130 abuts against the airtight stopper 500 and performs a hermetic action.

That is, the airtight portion 130 abuts against the airtight stopper 500, so that air in the high-pressure air passage can not be moved to the communication passage.

The airtight portion 130 may have a flange portion 131 formed in the direction of the high-pressure air passage.

Here, the flange portions 510 and 520 may also be formed in the airtight stopper 500.

The gap between the flange portions 131 of the housing 100 is formed to be smaller than the gap between the other flange portions 520 of the airtight stopper 500. [

Therefore, when observing the cross section of the bypass flow path solenoid valve according to the embodiment of the present invention, the flange portion 131 of the housing 100 is observed in a form in which the other flange portion 520 of the airtight stopper 500 receives .

The flange portion 131 of the housing 100 minimizes the contact portion with the airtight stopper 500 while hitting the airtight stopper 500 so that the airtight stopper 500 collides with the airtight stopper 500 to reduce the noise generated by the airtight stopper 500 do.

The chamber 140 provides a space in which a certain amount of air moved from the high-pressure air passage to the communication passage can be collected when the plunger 200 moves to open the first passage.

Therefore, when a certain amount of air is present in the chamber 140, a higher pressure is generated than in the high-pressure air passage.

In this case, when the air in the chamber 140 is higher in pressure than the air in the high-pressure air passage which applies pressure to the airtight stopper 500, the airtight stopper 500 is moved downward with reference to Fig. 2 2 Euro will be opened.

The solenoid portion 10 is disposed on one side of the housing 100.

The solenoid unit 10 generates a magnetic force by an electric signal to move the plunger 200 by a predetermined range.

The solenoid portion 10 may be composed of a bobbin, a coil, a core, or the like.

The bobbin can be coiled.

The coil is energized by a connector (not shown).

The core induces the direction of the magnetic force generated by the application of the coiled coil electricity.

The plunger 200 reciprocates a predetermined distance according to an electrical signal.

For example, in the case of FIG. 2, it travels back and forth over a distance set upward and downward.

The plunger 200 moves in a direction opposite to the direction in which the air in the high-pressure air passage moves, that is, in a direction under pressure by the air in the high-pressure air passage, thereby opening the first passage.

The guide part 300 may be installed around the plunger 200.

The guide unit 300 guides the plunger 200 so that the plunger 200 can move linearly even in a situation where high pressure air obstructs linear movement.

The guide portion 300 is formed with a predetermined length. The guide portion 300 is in contact with the flange 510 formed in the downward direction of the airtight stopper 500.

Therefore, the guide portion 300 accommodates a part of the airtight stopper 500 and the plunger 200. [

The plunger 200 is configured to have a first length and a second length.

The second length is longer than the first length.

The length of the guide portion 300 is not less than the second length.

Therefore, the guide portion 300 can form the first flow path by the gap or the space formed between the plungers 200.

The other side of the plunger 200 comes into contact with one side of the airtight stopper 500 and hermetically acts so that air in the high-pressure air passage can not be moved to the communication passage.

The other side of the airtight stopper 500 also hits the airtight portion 130 of the housing 100 and hermetically acts to prevent air in the high-pressure air passage from moving to the communication passage.

Therefore, air in the high-pressure air passage can not be moved to the low-pressure air passage via the communication passage.

The plunger 200 moves downward by an electrical signal.

Therefore, a space is formed between the other side of the plunger 200 and one side of the airtight stopper 500.

Here, as described above, a space is formed between the guide part 300 and the plunger 200 by the difference in length.

Accordingly, the high-pressure air located in the high-pressure air passage can be moved into the chamber 140 of the housing 100 through the first flow path.

That is, the first flow path means a space formed between the other side of the plunger 200 and one side of the airtight stopper 500 and the difference in length between the guide part 300 and the stopper 400 having the second length.

The plunger 200 has a step portion 210 formed therein.

The step 210 guides the movement of the air.

A plurality of step portions 210 may be formed on the plunger 200.

A space through which the plunger 200 can pass is formed in the airtight stopper 500. Before the plunger 200 is moved, the stepped portion 210 is located in such a space of the airtight stopper 500.

The space through which the plunger 200 of the airtight stopper 500 penetrates is longer than the first length and shorter than the second length.

Therefore, the airtight stopper 500 can hermetically function by abutting the one side flange portion 510 of the airtight stopper 500 with the other side having the second length.

When the plunger 200 is moved by an electrical signal, as shown in FIG. 3, the step portion 210 is located at a position which is no longer accommodated in the airtight stopper 500.

Thus, when the plunger 200 is moved downward by an electrical signal, the air moved by the first flow path can be guided and moved into the chamber 140 of the housing 100 in the presence of the step 210 .

According to an embodiment, the step portion 210 of the plunger 200 may be formed in a rounded shape to facilitate the guide of air movement.

At the end of the plunger 200, a stopper 400 is provided.

The stopper 400 prevents the plunger 200 from moving beyond a predetermined distance.

For example, when the plunger 200 is moved downward by an electrical signal, it stops moving so as not to move beyond a predetermined distance.

Here, the stopper 400 may be, for example, a flange.

The stopper 400 is formed to surround the plunger 200 and spaced apart from the guide unit 300 having a predetermined length.

Therefore, the stopper 400 does not close the first flow path formed by the movement of the plunger 200.

Due to the presence of the stopper 400, the plunger 200 does not move by more than the predetermined distance in the downward direction, and does not move by more than the similarly set distance by the airtight stopper 500 in the upward direction.

That is, one end of the plunger 200 is restricted by the stopper 400 and the other end is restricted by the airtight stopper 500, so that the plunger 200 can reciprocate within a set range.

The airtight stopper 500 is in contact with the plunger 200 at one side and the airtight portion 130 of the housing 100 at the other side.

The airtight stopper 500 is formed so that the plunger 200 can be penetrated.

Thus, as described above, the plunger 200 prevents the plunger 200 from moving beyond the set range.

The airtight stopper 500 forms a second flow path.

That is, after the first flow path is formed by the movement of the plunger 200, the second flow path is formed by increasing the pressure in the chamber 140.

The plunger 200 moves downward to form a gap or space between the airtight stopper 500 and the space formed between the length of the stopper 400 and the length of the plunger 200 having the second length, .

Accordingly, high-pressure air in the high-pressure air passage is moved to the chamber 140 through the first flow path.

In this case, the air filled in the chamber 140 pushes the airtight stopper 500 at a higher pressure than air in the high-pressure air passage.

Accordingly, the airtight stopper 500 moves downward to be separated from the airtight portion 130 of the housing 100 so as to be spaced apart to form a second flow path through which the air can be moved

That is, the second flow path is formed by separating the airtight stopper 500 and the airtight portion 130 of the housing 100 from each other.

The airtight stopper 500 has flanges 510 and 520 formed on one side and the other side.

The flange portion 510 formed on one side of the airtight stopper 500 is disposed to abut the guide portion 300.

The flange portion 520 formed on the other side of the airtight stopper 500 contacts the airtight portion 130 of the housing 100.

Here, the flange portion 510 formed at one side of the airtight stopper 500 is formed to have a length capable of accommodating the plunger 200 having at least the first length.

That is, the flange portion 510 formed on one side of the airtight stopper 500 is longer than the first length and shorter than the second length.

A space through which the plunger 200 can pass is formed in the interval of the flange portion 510 formed at one side of the airtight stopper 500.

The flange portion 520 formed on the other side of the airtight stopper 500 is formed to be longer than the length between the flange portions 131 formed in the airtight portion 130 of the housing 100 in the embodiment.

The other flange portion 520 of the airtight stopper 500 can be observed in a shape accommodating the flange portion 131 of the housing 100. [

Here, the flange portions 510 and 520 of the one or the other airtight stopper 500 abut against the plunger 200 and the housing 100, respectively, and perform a hermetic action.

Here, the flange portions 510 and 520 of the one or the other airtight stopper 500 minimize the portion where the plunger 200 and the housing 100 abut each other, thereby realizing the effect of reducing the noise.

That is, it is possible to minimize the noise generated when the airtight stopper 500 moves downward to open the second flow path, and then moves upward to come into contact with the airtight portion 130 of the housing 100.

The flange 510 formed on one side of the airtight stopper 500 acts as a stopper 400 of the plunger 200.

According to another embodiment, either the airtight stopper 500 or the plunger 200 may be formed in the shape of a protruding tip.

That is, a portion of one side of the airtight stopper 500 or the other side of the plunger 200 may be formed in the shape of a protruding tip.

Accordingly, the contact portion between the airtight stopper 500 and the plunger 200 can be minimized, and the airtight effect is excellent owing to the shape of the tip, but the noise generated when the hitting is encountered can be minimized.

The bypass flow path solenoid valve formed as described above moves in a direction opposite to the direction in which air in the high-pressure air passage is moved in the formation of the first flow path and the second flow path to form the first flow path and the second flow path.

That is, the bypass flow path solenoid valve moves in a direction to overcome the pressure of the high-pressure air path, thereby opening the first flow path and the second flow path.

Referring to FIGS. 3 and 4, the plunger 200 moves downward to open the first flow path.

Also, the airtight stopper 500 also moves downward to open the second flow path.

Here, when the plunger 200 and the airtight stopper 500 close the flow path, they move in the direction in which the air in the high-pressure air path travels and close the flow path.

Therefore, the flow path is closed while moving in the same direction as the direction in which the air in the high-pressure air passage is moved, thereby improving the responsiveness.

In addition, the plunger 200 moves only to the portion where the stopper 400 of the guide portion 300 is formed to open the first flow path.

The airtight stopper 500 is moved through the pressure in the chamber 140 formed through the first flow path.

Therefore, since the plunger 200 requires only a minimum electrical signal when moving, the size of the plunger 200 does not matter.

While the present invention has been particularly shown and described with reference to particular embodiments thereof, it will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit of the invention, It will be apparent to those of ordinary skill in the art.

10: Solenoid section 100: Housing
110: (toward the high-pressure air passage) hole
120: (toward the low-pressure air passage) hole
130: airtight portion 131: flange portion (airtight portion)
140: chamber 200: plunger
210: step portion 300: guide portion
400: stopper 500: airtight stopper
510: a flange portion formed on one side (of the airtight stopper)
520: flange portion formed on the other side (of the airtight stopper)

Claims (10)

A bypass flow solenoid valve installed in a communication passage connecting between a high-pressure air passage and a low-pressure air passage and opening or closing the communication passage according to an electrical signal,
A hole communicating with the high-pressure air passage, a hole communicating with the low-pressure air passage, an airtight portion, and a chamber formed therein;
A solenoid disposed at one side of the housing and generating a magnetic force according to an electrical signal;
A plunger reciprocating a predetermined distance according to a magnetic force of the solenoid portion and opening a first flow path; And
The plunger is formed to penetrate, and one side surface and the other side surface are in contact with the plunger and the airtight portion, respectively, so that the communication passage is airtight. Air is moved to the chamber through the first flow path opened according to the movement of the plunger And a hermetic stopper which is moved when the pressure of the chamber becomes higher than the pressure of the high-pressure air passage to move the second passage to move the air to the low-pressure air passage,
Wherein a guide portion having a predetermined length is formed around the plunger so that the plunger can move in a linear direction. delete The method according to claim 1,
The plunger,
A first length and a second length longer than the first length,
The length of the guide portion is not less than the second length,
When the plunger is moved according to an electrical signal to form a space between the airtight stoppers,
And the first flow path is formed in a space formed by a difference in length between the second length and the length of the guide portion and in a space between the plunger and the airtight stopper. The method of claim 3,
Wherein a stopper is provided at an end portion of the plunger at a distance from the guide portion. The method according to claim 1,
The plunger has a stepped portion,
Wherein the guide member guides the movement of the air. The method according to claim 1,
Wherein a stopper is provided at an end of the plunger to prevent the plunger from moving beyond a predetermined range. The method according to claim 6,
Wherein the plunger reciprocates between one side of the airtight stopper and the other side of the stopper. The method according to claim 6,
Wherein at least one of the airtight stopper and the plunger has a tip protruded on one side thereof. The method according to claim 1,
Wherein a protruding flange portion is formed on at least one of a portion where the airtight portion of the housing and a portion where the airtight stopper abuts. The method according to claim 1,
Wherein the plunger and the airtight stopper move in the direction of the high-pressure air passage to form respective flow paths.

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