KR102363187B1 - An injector in use with bouncing reduced armature - Google Patents

Abstract

The present invention relates to an injector and, more specifically, to an injector capable of receiving a spring force to minimize bouncing. The injector, which has a magnetic part provided in a body having a fuel orifice and has a needle bar for opening and closing the fuel orifice in accordance with the operation of electromagnetic coils provided around the magnetic part, includes: a stopper part fixed to the needle bar; a guide ring provided on the same axis as the needle bar on a position opposed to the magnetic part while fixed to the body to guide the needle bar; an armature part moved between the guide ring and the magnetic part while kept extrapolated in the needle bar; a first spring pushing the stopper part such that the needle bar can close the fuel orifice by pressing the stopper part from a first state which is maximally compressed to a second state which is maximally relaxed; a second spring having one side supported by the magnetic part and having the other side supported by the armature part; and a leaf spring part spaced apart from the guide ring in the first state, and coming in contact with the guide ring in the second state while kept fixed on the armature part to minimize the bouncing of the armature part. Therefore, when the fuel orifice is closed by the needle bar, the bouncing can be minimized through the changeable spring structure, and, thus, there can be advantages of improving the stability of armature ascent behavior and improving the responsiveness of the injector.

Description

An injector in use with bouncing reduced armature}

The present invention relates to an injector, and more particularly, to an armature part bouncing reducing injector that is provided with a spring force to minimize bouncing.

1 is a conventional injector.

An injector is a device that injects fuel into the engine cylinder.

1 is a conventional injector, a magnetic part 90 is provided inside the body, an electromagnet coil part 80 is provided around the magnetic part 90, and a first spring 60 is provided in the hollow inside the magnetic part 90. ) is provided.

The first spring 60 closes the fuel injection hole while pushing the stopper part 50 with a compression spring and the valve needle 10 fixed to the stopper part 50 is pushed by the first spring 60 . The valve needle 10 is integrally fixed by the position ring 20 as well as the stopper part 50. An armature 30 is provided between the stopper part 50 and the position ring 20, and by the stopper part You can do a downward movement and an upward movement by using the positioning ring.

The valve needle 10 is slidably inserted into the center of the armature 30 .

The armature 30 receives a force in the upward direction in which the magnetic part 90 is located when a current is applied to the electromagnet coil part 80, thereby pushing up the stopper part 50, and eventually the valve needle 10 closes the injection hole. Open to allow fuel to be injected.

On the other hand, the second spring 40 is provided between the stopper part 50 and the armature 30 and after the valve needle closes the injection hole by the first spring, while pushing the armature 30 in the direction of the position ring 20 , the damper act as a spring

Such a conventional injector structure has used a general second spring in only one direction.

Therefore, when the valve needle closes the fuel hole, the armature bounces after a lower collision, which makes the armature lift unstable.

Such a problem eventually led to deterioration of the overall engine performance.

On the other hand, if the descending force of the armature is reduced in order to reduce the bouncing of the armature, the problem of reduced responsiveness when the fuel hole is closed cannot be avoided.

KR 1345431 B1

An object of the present invention to overcome the problems of the prior art as described above is to provide an injector capable of maximizing fuel injection responsiveness while minimizing the bouncing of the armature by providing different spring forces at the opening and closing timings of the injection hole of the needle bar. do it with

An injector having a needle bar provided with a magnetic part inside a body in which the fuel injection hole is formed and opening and closing the fuel injection hole according to the operation of an electromagnet coil provided around the magnetic part, the injector comprising: a stopper part fixed to the needle bar; a guide ring provided on the same axis as the needle bar at a position opposite to the magnetic part and fixed to the body to guide the needle bar; an armature part that moves between the guide ring and the magnetic part while being extrapolated to the needle bar; a first spring that pushes the stopper part from the first compressed state to the maximum relaxed second state to push the stopper part so that the needle bar closes the fuel injection hole; The armature part bouncing reduction injector including; a plate spring part that is spaced from the guide ring in the first state while being fixed to the armature part and is in contact with the guide ring in the second state to minimize the bouncing of the armature part include

In addition, the plate spring part is formed flat and has a fixing part fixed to the lower surface of the armature part, and the other side of the fixing part is bent and extended from the fixing part so that the elastic force acts in a direction away from the fixing part at the end of the fixing part. and a free end opposite to the armature part, characterized in that it has a bouncing reduced injector.

In addition, the leaf spring portion having a predetermined curvature and extending from the fixed portion curved first round portion; a first straight part extending in a straight line from the first round part and forming a predetermined angle with the fixing part; a second round portion bent at an end of the first straight portion; and a second straight part extending straight from the second round part toward the fixing part, wherein the free end part is bent with a predetermined curvature in a direction away from the fixing part at the end of the second straight part. It includes an injector to reduce armature bouncing, characterized in that.

In addition, the free end part is spaced apart from the fixed part when current is applied to the electromagnet coil part so that the needle bar opens the fuel injection hole, and when the current is cut off the electromagnet coil part, the needle bar closes the fuel injection hole It includes an injector to reduce armature bouncing, characterized in that it is in contact with the fixing part.

In addition, the curvature of the second round portion includes an armature portion bouncing reduction injector, characterized in that greater than the curvature of the first round portion.

In addition, the plate spring portion includes an armature portion bouncing reduction injector, characterized in that it includes a third round portion formed to correspond to the curvature of the outer peripheral surface of the needle bar.

In addition, a plurality of the plate spring portion includes an armature portion bouncing reduction injector, characterized in that fixed at equal intervals along the circumference of the armature portion.

In addition, the plate spring portion includes an armature portion bouncing reduction injector, characterized in that it further comprises a fixing ring extrapolated to the outer circumferential surface of the needle bar while extending from the fixing portion.

In addition, an injector having a needle bar provided with a magnetic part inside the body in which the fuel injection hole is formed, and opening and closing the fuel injection hole according to the operation of an electromagnet coil provided around the magnetic part, a stopper part fixed to the needle bar; a guide ring provided on the same axis as the needle bar at a position opposite to the magnetic part and fixed to the body to guide the needle bar; an armature part that moves between the guide ring and the magnetic part while being extrapolated to the needle bar; a first spring for pushing the stopper part from the maximum compressed first state to the maximum relaxed second state to push the stopper part so that the needle bar closes the fuel injection hole; a second spring having one side supported by the magnetic unit and the other side supported by the armature unit; A leaf spring part spaced apart from the guide ring in the first state while being fixed to the armature part and contacting the guide ring in the second state to minimize bouncing of the armature part together with the first spring and the second spring ; Includes an armature part bouncing reduction injector containing.

In addition, the plate spring part is formed flat and has a fixing part fixed to the lower surface of the armature part, and the other side of the fixing part is bent and extended from the fixing part so that the elastic force acts in a direction away from the fixing part at the end of the fixing part. and a free end opposite to the armature part, characterized in that it has a bouncing reduced injector.

In addition, it includes an armature portion bouncing reduction injector, characterized in that the elastic force of the second spring is greater than the elastic force of the leaf spring portion.

In addition, the leaf spring portion having a predetermined curvature and extending from the fixed portion curved first round portion; a first straight part extending in a straight line from the first round part and forming a predetermined angle with the fixing part; a second round portion bent at an end of the first straight portion; and a second straight part extending straight from the second round part toward the fixing part, wherein the free end part is bent with a predetermined curvature in a direction away from the fixing part at the end of the second straight part. It includes an injector to reduce armature bouncing, characterized in that.

In addition, the free end part is spaced apart from the fixed part when current is applied to the electromagnet coil part so that the needle bar opens the fuel injection hole, and when the current is cut off the electromagnet coil part, the needle bar closes the fuel injection hole It includes an injector to reduce armature bouncing, characterized in that it is in contact with the fixing part.

In addition, the curvature of the second round portion includes an armature portion bouncing reduction injector, characterized in that greater than the curvature of the first round portion.

In addition, the plate spring portion includes an armature portion bouncing reduction injector, characterized in that it includes a third round portion formed to correspond to the curvature of the outer peripheral surface of the needle bar.

In addition, a plurality of the plate spring portion includes an armature portion bouncing reduction injector, characterized in that fixed at equal intervals along the circumference of the armature portion.

In addition, the plate spring portion includes an armature portion bouncing reduction injector, characterized in that it further comprises a fixing ring extrapolated to the outer circumferential surface of the needle bar while extending from the fixing portion.

In addition, the second spring includes an armature portion bouncing reducing injector, characterized in that the diameter decreases from the portion supported by the magnetic portion toward the portion supported by the armature portion.

In addition, the armature includes a bouncing reducing injector, characterized in that the stopper support portion is formed in contact with the stopper portion on the upper surface of the armature portion.

In addition, a second spring support part on which the second spring is seated is formed on an upper surface of the armature part, and a space part wider than the width of the second spring support part is formed on a lower surface of the armature part. includes

According to the present invention as described above, there are the following effects.

First, since bouncing is minimized by the variable spring structure when the needle bar closes the fuel injection hole, the stability of the armature ascending behavior is improved and the responsiveness of the injector is improved.

Second, since the spring force applied to the armature in the first state and the second state can be set differently, there is an advantage in that the armature bouncing is reduced.

1 is a conventional injector;
2 is an injector according to a preferred embodiment of the present invention;
3(a) and 3(b) are side views of a leaf spring part according to a preferred embodiment of the present invention;
4 is a perspective view showing a first plate spring part, a second plate spring part, a third plate spring part, and a fourth plate spring part installed on the lower surface of the armature part in which the needle bar is accommodated according to the preferred embodiment of the present invention;
5 is a cross-sectional view illustrating a combination of a stopper part, a needle bar, an armature part and a leaf spring part according to another preferred embodiment of the present invention;
6 is a bottom view of an armature according to a preferred embodiment of the present invention;
Figure 7 is a cross-sectional view when the armature according to the second preferred embodiment of the present invention is raised to the maximum
8 is a cross-sectional view when the armature according to the second preferred embodiment of the present invention is lowered to the maximum

Since the present invention can have various changes and can have various embodiments, specific embodiments are illustrated in the drawings and will be described in detail in the detailed description. However, this is not intended to limit the present invention to specific embodiments, it should be understood to include all modifications, equivalents, and substitutes included in the spirit and scope of the present invention.

In describing each figure, like reference numerals are used for like elements.

Terms such as first, second, etc. may be used to describe various elements, but the elements should not be limited by the terms. The above terms are used only for the purpose of distinguishing one component from another.

For example, without departing from the scope of the present invention, a first component may be referred to as a second component, and similarly, the second component may also be referred to as a first component. The term “and/or” includes a combination of a plurality of related listed items or any of a plurality of related listed items.

Unless defined otherwise, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs.

Terms such as those defined in a commonly used dictionary should be interpreted as having a meaning consistent with the meaning in the context of the related art, and should not be interpreted in an ideal or excessively formal meaning unless explicitly defined in the present application. shouldn't

2 is an injector according to a preferred embodiment of the present invention.

A schematic configuration of the injector will be described and then described in detail.

The injector includes a housing 101 , a magnetic part 102 , a needle tip part 104 , an electromagnet coil part 110 , a stopper part 200 , a needle bar 300 , a first part 301 , an armature part 400 . ), and a first spring (S1) is provided in the inner space of the magnetic part (102), and a plate spring part (600) is provided between the armature part (400) and the guide ring (500).

A direction used in the following description is first defined.

The downward or downward direction means the direction in which the needle tip part 310 provided in the stopper part 200 closes the fuel injection port 104 of the injector, and the upward or upward direction means the needle tip part 310 is It means the direction in which the fuel injection port 104 of the injector is opened.

In addition, the movement or operation in the downward or downward direction is a movement or an operation that is pushed by the first spring (S1) when the first spring (S1) is relaxed. In this operation, the armature 400 presses the stopper unit 200 by applying a current to the electromagnet coil unit 110, so that the stopper unit 200 eventually rises while overcoming the elastic force of the first spring S1. It refers to the action that follows.

Meanwhile, the repulsive force hereinafter may be understood as a force rebounding in the upward direction immediately after the needle tip part 310 closes the fuel injection port 104 of the injector.

In the ascending operation, the needle tip portion 310 opens the fuel injection port 104 , and in the end of the descending operation, the needle tip portion 310 closes the fuel injection hole 104 .

On the other hand, the spring according to a preferred embodiment of the present invention is largely divided into a first spring (S1), a second spring (S2), and a leaf spring portion (600).

The upper end of the first spring S1 is fixedly supported inside the injector, and the other end is supported by the stopper unit 200 to always push the stopper unit 200 downward.

More specifically, the first spring S1 may have a first state in which the armature 400 is maximally compressed as the armature 400 presses the stopper unit 200 to increase the maximum.

The first spring S1 pushes the needle bar to close the fuel injection port in the second state in which it is fully relaxed.

The second spring S2 has one end supported by the magnetic unit 102 and the other end supported by the armature 400 , thereby always pushing the armature 400 downward.

The first spring (S1) and the second spring (S2) may be compression coil springs, and in particular, the second spring (S2) may preferably be a compression coil spring having a shape in which the diameter of the upper end is larger than the diameter of the lower end. .

In addition, it may be preferable that the spring force of the second spring S2 is greater than the spring force of the leaf spring part 600 .

The plate spring part 600 is a bent plate-shaped spring, and is fixed to the lower surface of the armature part 400 and is positioned between the armature part 400 and the guide ring 500 .

The leaf spring part 600 moves according to the operation of the armature part 400 , and in particular, the lower end of the plate spring part 600 may contact or be spaced apart from the guide ring 500 .

In more detail, the leaf spring part 600 is spaced apart from the guide ring 500 when the armature part 400 rises, and the armature part 400 descends so that the needle tip part 310 closes the fuel injection port 104 . When in contact with the guide ring (500).

First, the leaf spring part 600 will be described.

3 (a) and 3 (b) are side views of the leaf spring part 600 according to a preferred embodiment of the present invention.

The leaf spring part 600 includes a fixed part 601 , a first round part 602 , a first straight part 603 , a second round part 604 , a second straight part 605 , and a free end part 606 . may include

The fixing part 601 is a part fixed to the armature 400 and is formed flat.

The first round portion 602 is a portion bent and extended from the fixing portion 601 and has a predetermined curvature.

The first straight part 603 extends in a straight line from the first round part 602 and forms a predetermined angle with the fixing part 601 .

The second round portion 604 is a curved portion at the end of the first straight portion 603 .

The curvature of the second round portion 604 may preferably be greater than the curvature of the first round portion 602 .

The second straight portion 605 extends straight from the second round portion 604 toward the fixing portion 601 .

The free end 606 is a bent portion having a predetermined curvature at the end of the second straight portion 605 and faces the fixed portion 601 .

3 (a) shows a state in which the free end 606 is in contact with the fixed part 601 , and FIG. 3 ( b ) shows a state in which the free end 606 is spaced apart from the fixed part 601 .

More specifically, when an external force acts on the second round part 604, the free end 606 is supported while in contact with the fixed part 601, and when the external force does not act on the second round part 604, the free end ( 606 is spaced apart from the fixing portion 601 .

Meanwhile, the spring force of the leaf spring part 600 may vary according to an angle between the fixing part 601 and the first straight part 603 .

In other words, the larger the angle between the fixing part 601 and the first straight part 603 is, the stronger the spring force of the leaf spring part 600 may be.

4 is a first plate spring part 610, a second plate spring part 620, and a third plate spring part ( 630) and a perspective view in which the fourth leaf spring part 640 is installed.

The first plate spring part 610 , the second plate spring part 620 , the third plate spring part 630 , and the fourth plate spring part 640 may be identical to each other as the aforementioned plate spring part 600 . .

As shown, the first plate spring part 610 , the second plate spring part 620 , the third plate spring part 630 , and the fourth plate spring part 640 are predetermined with respect to the center of the armature part 400 . They are installed spaced apart.

The needle bar 300 passes through the armature 400 , and the stopper part 200 is fixed to the upper end of the needle bar 300 .

The needle bar 300 may include a first portion 301 , a second portion 302 , a third portion 303 , a fourth portion 304 , a fifth portion 305 and a sixth portion 306 . can

Around the first portion 301 , the first leaf spring portion 610 , the second leaf spring portion 620 , the third leaf spring portion 630 , and the fourth leaf spring portion 640 are surrounded at equal intervals, but are in contact. don't do it

In other words, around the first part 301, the first plate spring part 610, the second plate spring part 620, the third plate spring part 630 and the fourth plate spring part 640 are needle bars ( 300) is not in contact.

The second portion 302 is a portion whose diameter increases while extending downwardly from the first portion 301 and has a predetermined inclination in the cross-sectional shape of the outer circumferential surface.

The third portion 303 is a portion having the largest diameter in the needle bar 300 and is formed in a predetermined section with a predetermined diameter in the longitudinal direction of the needle bar 300 .

The fourth portion 304 is a portion whose diameter is reduced while extending downwardly from the third portion 303, and has a cross-sectional shape of an outer circumferential surface having a predetermined inclination.

The fifth portion 305 extends downward from the fourth portion 304 with a predetermined diameter.

The sixth portion 306 may be a portion that is inclined so that the diameter of the first portion 301 becomes slightly narrower in the upward direction.

5 is a cross-sectional view of the stopper unit 200, the needle bar 300, the armature 400, and the leaf spring unit 600 that are coupled to each other according to another preferred embodiment of the present invention.

The stopper part 200 may include a first spring support part 201 , a stopper upper part 202 , a stopper middle part 203 , and a stopper lower part 204 .

The first spring support part 201 forms the uppermost surface of the stopper part 200 , and the first spring S1 is supported on the first spring support part 201 .

The stopper upper portion 202 is a portion protruding in the circumferential direction with a predetermined diameter from the upper end of the stopper portion 200 .

The stopper lower portion 204 is a portion protruding in the circumferential direction with a predetermined diameter from the lower end of the stopper portion 200 .

It may be preferable that the outer circumferential diameter of the stopper upper portion 202 is larger than the outer circumferential diameter of the stopper lower portion 204 .

The stopper middle part 203 is a part connecting the stopper upper part 202 and the stopper lower part 204, and the outer peripheral diameter of the stopper middle part 203 is the outer peripheral diameter of the stopper upper part 202 and the stopper lower part ( 204) may be preferably formed to be smaller than the diameter of the outer circumferential surface.

In the stopper part 200 , the lower surface of the stopper lower part 204 is in contact with the stopper support part 401 of the armature part 400 .

The armature 400 includes a stopper support portion 401, a second spring support portion 402, a body portion 403, a through hole 404, a second stepped portion 405, a space portion 406, and a first lower surface of the armature. It may include a portion 407 and an armature second lower surface portion 408 .

The stopper support 401 forms the center of the armature 400 , and the stopper 200 is in contact with the inner peripheral surface of the stopper support 401 .

The second spring support 402 is a space in which the second spring S2 is accommodated.

The body part 403 is the thickest part of the armature part 400 .

The through hole 404 may be a passage through which fuel may be in fluid communication.

The second stepped portion 405 is an inner upper wall forming the space portion 406 , and the space portion 406 may have a space opened downward of the armature portion 400 .

The space portion 406 may be hollowed out to reduce the weight of the armature 400 .

The armature first lower surface portion 407 and the armature second lower surface portion 408 form the lowermost end of the armature portion 400 .

The leaf spring portion 600 is being fixed to the lower armature portions 407 and 408 .

In more detail, the fixing part 601 is fixed to the armature first lower surface part 407 and the armature second lower surface part 408 .

The fixing ring 700 may be inserted into the outer circumferential surface of the first part 301 .

In more detail, the fixing ring 700 may be fixed to the end of the fixing part 601 .

It may be preferable that the fixing ring 700 is extrapolated to and fixed to the first part 301 in the shape of a hollow bar.

The fixing part 601 may be fixed while making surface contact with the armature first lower surface part 407 and the armature second lower surface part 408 , and an end of the fixing part 601 may be fixed to the fixing ring 700 .

According to the second preferred embodiment of the present invention, the first plate spring part 610 to the fourth plate spring part 640 may be respectively fixed to the fixing ring 700 inserted into the first part 301 .

In addition, the plurality of plate spring parts 600 may be fixed at equal intervals along the circumference of the fixing ring 700 , and therefore workability is improved when assembling the plurality of plate spring parts 600 to the needle bar 300 . can be improved

On the other hand, the plurality of leaf spring parts 600 may mean two or more, but more preferably at least three or more.

6 is a bottom view of the armature 400 according to a preferred embodiment of the present invention.

The armature first lower surface portion 407 has a larger diameter among the lower surfaces of the armature 400 according to a preferred embodiment of the present invention, and the second armature lower surface portion 408 has a diameter among the lower surfaces of the armature 400 . represents a small part.

In other words, the second lower surface 408 of the armature may point to the lower surface of the stopper support 401 .

The space portion 406 is a space between the armature first lower surface portion 407 and the armature second lower surface portion 408 .

The through-hole 404 may include a first through-hole 404-1, a second through-hole 404-2, a third through-hole 404-3, and a fourth through-hole 404-4. .

The first through-hole 404-1, the second through-hole 404-2, the third through-hole 404-3, and the fourth through-hole 404-4 are formed around the axis of the needle bar 300. The armature 400 is vertically penetrated while having a predetermined radius.

The leaf spring part 600 has the through-hole 404, the first through-hole 404-1, the second through-hole 404-2, the third through-hole 404-3, and the fourth through-hole 404- 4) does not discriminate.

Accordingly, fuel can flow naturally without obstruction through the through hole 404 .

Meanwhile, a third round part 607 may be formed in the leaf spring part 600 .

In other words, the third round portion 607 may be formed to be rounded to correspond to the curvature of the outer circumferential surface of the needle bar 300 .

Next, the operation of the injector according to a preferred embodiment of the present invention will be described.

Since the operating principle of the above-described preferred embodiment of the present invention and the second preferred embodiment of the present invention are the same, the operating principle of the second preferred embodiment of the present invention will be described below.

7 is a cross-sectional view when the armature 400 according to the second preferred embodiment of the present invention is raised to the maximum.

The leaf spring 600 is fixed to the armature 400 and moves together with the armature 400 .

7 shows a state in which current is applied to the electromagnet coil unit 110 , and the armature unit 400 is lifted toward the magnetic unit 102 .

The armature 400 overcomes both the elastic force of the first spring S1 and the elastic force of the second spring S2 and pushes up the stopper part 200 while ascending upward.

At this time, while the needle bar 300 fixed to the stopper part 200 is raised, the needle tip part 310 opens the fuel injection port 104 .

Meanwhile, the leaf spring part 600 has a state spaced apart from the guide ring 500 by a predetermined distance.

In other words, the spring force of the leaf spring unit 600 has no effect on the armature unit 400 in the state shown in FIG. 7 .

On the other hand, in this case, the free end 606 is spaced apart from the fixed portion (601).

8 is a cross-sectional view when the armature 400 according to the second preferred embodiment of the present invention is lowered to the maximum.

The sixth part 306 is a part that is inclined so that the diameter of the first part 301 becomes slightly narrower in the upward direction, and the armature 400 is secured with a more reliable fastening force by the sixth part 306 . can

More specifically, FIG. 8 shows a state in which current is cut off in the electromagnet coil unit 110 , the stopper unit 200 is pressed downward by the elastic force of the first spring S1 , and the stopper unit 200 The fixed needle bar 300 closes the fuel injection hole 104 .

At this time, the leaf spring part 600 is in contact with the guide ring 500 .

More specifically, the free end 606 of the leaf spring part 600 is in contact with the fixing part 601 , and the fixing part 601 is in contact with the guide ring 500 .

The leaf spring unit 600 is in a state with a strong spring force that maintains the maximum compressed state until a current is applied to the electromagnet coil unit 110 again.

This strong spring force greatly improves the armature lifting behavior and injector responsiveness.

When current is applied to the electromagnet coil unit 110 again, the armature unit 400 is immediately raised by the elastic repulsive force of the leaf spring unit 600 , thereby maximizing fuel injection responsiveness.

Next, in the process from immediately after the current is applied to the electromagnet coil unit 110 to the electromagnet coil unit 110 after the current is cut off to the state of FIG. 8 as shown in FIG. 7, the movement of the needle bar 300 is Explain.

When the current is cut off in the electromagnet coil unit 110 in the state in which the needle bar 300 is in the maximum rising state, that is, the fuel injection port is opened, the armature unit 400 is a stopper that is pushed downward by the first spring S1. It begins to descend by the part 200, and at the same time, the needle bar 300 fixed to the stopper part 200 begins to descend.

That is, when the needle bar 300 starts to descend, the leaf spring part 600 is in a state spaced apart from the guide ring 500 .

In other words, at the point when the needle bar 300 starts to descend, the needle bar 300 receives the descending force completely by the first spring S1, and the spring force by the leaf spring 600 is not affected at all. will be left in a non-existent state.

In other words, the leaf spring part 600 is in a state with a weak spring force.

That is, if the spring force applied to the armature 400 is too strong when the armature 400 descends, the responsiveness may be delayed when the armature 400 descends.

Therefore, it is advantageous for the leaf spring part 600 to maintain a weak spring force except before/after the bouncing of the armature part 400 .

Accordingly, the operation of the needle tip portion 310 of the needle bar 300 to close the fuel injection hole 104 can be performed quickly, and the delay operation when the fuel injection hole 104 is closed disappears.

Meanwhile, the needle bar 300 continues to descend so that the leaf spring part 600 comes into contact with the guide ring 500 .

When the second round part 604 first contacts the guide ring 500 , the free end 606 is still spaced apart from the fixing part 601 .

Next, if the needle bar 300 continues to descend for a minute time, the spring elastic force of the leaf spring 600 gradually increases the upward force with respect to the armature 400 .

The leaf spring part 600 pushes the armature part 400 upward with the maximum elastic force from the moment the free end part 606 abuts the fixed part 601, and this series of operations is performed by the needle tip part 310 as fuel. It is maintained while closing the nozzle 104 .

On the other hand, the second spring (S2) serves to attenuate the bouncing of the armature portion 400 by applying a force in a direction opposite to the leaf spring portion (600).

In other words, the leaf spring part 600 makes it possible to minimize the impact force applied to the armature part 400 until the armature part 400 stops in the descending operation of the armature part 400. It is possible to minimize the bouncing of

That is, the leaf spring part 600 significantly reduces the bouncing phenomenon in which the armature part 400 is rebounded from the maximum descending position together with the second spring S2.

In other words, the leaf spring part 600 minimizes the repulsive force acting on the armature part 400 .

Accordingly, the leaf spring 600 serves as a damper to effectively suppress the repulsive force of the armature 400 together with the second spring S2.

Accordingly, since the needle bar 300 can maintain the closed state immediately after closing the fuel injection hole 104 , it is possible to make the behavior of the armature 400 more stable, and thereby undesirable secondary injection of fuel will be able to suppress

On the other hand, considering the height of the leaf spring portion 600, the second spring (S2) may be preferably a conical compression coil spring that can have a low height during maximum compression.

Since the conical compression coil spring minimizes shaking in the left and right directions with respect to the longitudinal direction, it is possible to more stably support the elevating movement of the armature 400 .

The spring force of the leaf spring part 600 described above is applied to minimize the effect on the bouncing of the armature part 400 .

In addition, as described above, the first straight part 603 extends in a straight line from the first round part 602 and forms a predetermined angle with the fixing part 601 , the first straight part 603 and the fixing part As the angle between the 601 increases, the spring force supported by the second round part 604 on the guide ring in a state where the free end 606 is spaced apart from the fixed part 601 may be weakened.

Meanwhile, the length of the second straight part 605 may be variously determined according to the distance at which the armature part 400 is raised.

In addition, the curvature of the first round part 602 and the second round part 604 may be variously determined according to the spring force and durability of the leaf spring.

101: housing unit
102: magnetic part
103: first stepped portion
104: fuel nozzle
110: electromagnet coil unit
200: stopper part
201: first spring support
202: stopper upper part
203: stopper middle part
204: stopper lower part
300: needle bar
301: first part
302: second part
303: third part
304: fourth part
305: fifth part
306: sixth part
310: needle tip part
400: amateur
401: stopper support
402: second spring support
403: body
404: through hole
404-1: first through hole
404-2: second through hole
404-3: third through hole
404-4: fourth through hole
405: second stepped portion
406: space part
407: first lower surface part
408: second lower surface portion
500: guide ring
600: plate spring part
601: fixed part
602: first round part
603: first straight part
604: 2nd round part
605: second straight part
606: free end
607: 3rd round part
610: first leaf spring part
620: second leaf spring part
630: third leaf spring part
640: fourth leaf spring part
700: fixing ring
S1: first spring
S2: second spring

Claims (20)

In an injector having a needle bar provided with a magnetic part and opening and closing a fuel injection port according to the operation of an electromagnet coil provided around the magnetic part,
a stopper part fixed to the needle bar;
a guide ring provided on the same axis as the needle bar to guide the needle bar;
an armature part that moves between the guide ring and the magnetic part while being extrapolated to the needle bar;
a first spring for pushing the stopper part from the maximum compressed first state to the maximum relaxed second state to push the stopper part so that the needle bar closes the fuel injection hole;
a leaf spring part that is fixed to the armature part, spaced apart from the guide ring in the first state, and comes in contact with the guide ring in the second state to minimize bouncing of the armature part;
The plate spring part has a fixing part formed flat on one side and fixed to the lower surface of the armature part, and the other side of the fixing part is bent and extended from the fixing part so that an elastic force is applied to the end in a direction away from the fixing part. and a free end opposite to; characterized in that it has a
Armature part bouncing reduction injector.
delete According to claim 1,
The leaf spring part,
a first round portion bent and extended from the fixing portion while having a predetermined curvature;
a first straight part extending in a straight line from the first round part and forming a predetermined angle with the fixing part;
a second round portion bent at an end of the first straight portion;
Including; a second straight portion extending straight from the second round portion toward the fixing portion;
The free end portion is characterized in that formed by bending with a predetermined curvature in a direction away from the fixed portion at the end of the second straight portion,
Armature part bouncing reduction injector.
According to claim 1,
The free end part is spaced apart from the fixed part when a current is applied to the electromagnet coil part and the needle bar opens the fuel injection hole, and the electric current is cut off to the electromagnet coil part so that the needle bar closes the fuel injection hole. characterized in contact with the government,
Armature part bouncing reduction injector.
4. The method of claim 3,
The curvature of the second round portion is characterized in that greater than the curvature of the first round portion,
Armature part bouncing reduction injector.
4. The method of claim 3,
The leaf spring portion characterized in that it comprises a third round portion formed to be rounded to correspond to the curvature of the outer peripheral surface of the needle bar,
Armature part bouncing reduction injector.
According to claim 1,
A plurality of the leaf spring parts are characterized in that fixed at equal intervals along the circumference of the armature part,
Armature part bouncing reduction injector.
4. The method of claim 3,
The plate spring portion, characterized in that it further comprises a fixing ring extrapolated to the outer peripheral surface of the needle bar while extending from the fixing portion,
Armature part bouncing reduction injector.
In an injector having a needle bar provided with a magnetic part and opening and closing a fuel injection port according to the operation of an electromagnet coil provided around the magnetic part,
a stopper part fixed to the needle bar;
a guide ring provided on the same axis as the needle bar to guide the needle bar;
an armature part that moves between the guide ring and the magnetic part while being extrapolated to the needle bar;
a first spring that pushes the stopper part from the maximum compressed first state to the maximum relaxed second state to push the stopper part so that the needle bar closes the fuel injection hole;
a second spring having one side supported by the magnetic unit and the other side supported by the armature unit;
A leaf spring that is spaced apart from the guide ring in the first state while being fixed to the armature portion and is in contact with the guide ring in the second state to minimize bouncing of the armature portion together with the first spring and the second spring. including;
Armature part bouncing reduction injector.
10. The method of claim 9,
The plate spring part is formed flat and has a fixing part fixed to the lower surface of the armature part, and the other side faces the fixing part so that the elastic force acts in a direction away from the fixing part while bending and extending from the fixing part. It is characterized in that it has a free end;
Armature part bouncing reduction injector.
10. The method of claim 9,
characterized in that the elastic force of the second spring is greater than the elastic force of the leaf spring part,
Armature part bouncing reduction injector.
11. The method of claim 10,
The leaf spring part,
a first round portion bent and extended from the fixing portion while having a predetermined curvature;
a first straight part extending in a straight line from the first round part and forming a predetermined angle with the fixing part;
a second round portion bent at an end of the first straight portion;
Including; a second straight portion extending straight from the second round portion toward the fixing portion;
The free end portion is characterized in that formed by bending with a predetermined curvature in a direction away from the fixed portion at the end of the second straight portion,
Armature part bouncing reduction injector.
11. The method of claim 10,
The free end part is spaced apart from the fixed part when a current is applied to the electromagnet coil part and the needle bar opens the fuel injection hole, and the electric current is cut off to the electromagnet coil part so that the needle bar closes the fuel injection hole. characterized in contact with the government,
Armature part bouncing reduction injector.
13. The method of claim 12,
The curvature of the second round portion is characterized in that greater than the curvature of the first round portion,
Armature part bouncing reduction injector.
13. The method of claim 12,
The leaf spring portion characterized in that it comprises a third round portion formed to be rounded to correspond to the curvature of the outer peripheral surface of the needle bar,
Armature part bouncing reduction injector.
10. The method of claim 9,
A plurality of the leaf spring parts are characterized in that fixed at equal intervals along the circumference of the armature part,
Armature part bouncing reduction injector.
11. The method of claim 10,
The plate spring portion, characterized in that it further comprises a fixing ring extrapolated to the outer peripheral surface of the needle bar while extending from the fixing portion,
Armature part bouncing reduction injector.
10. The method of claim 9,
The second spring is characterized in that the diameter decreases from the portion supported by the magnetic portion toward the portion supported by the armature portion,
Armature part bouncing reduction injector.
10. The method of claim 9,
A stopper support portion in contact with the stopper portion is formed on the upper surface of the armature portion,
Armature part bouncing reduction injector.
10. The method of claim 9,
A second spring support portion on which the second spring is seated is formed on the upper surface of the armature portion, and a lower surface of the armature portion comprises a space portion having a width greater than that of the second spring support portion,
Armature part bouncing reduction injector.

Images