RU2554256C1 - Electromagnetic control system of valves of gas distributing mechanism of internal combustion engine (versions) - Google Patents

Abstract

FIELD: engines and pumps.

SUBSTANCE: electromagnetic control system of valves of a gas distributing mechanism of an internal combustion engine includes housing (1), in which upper and lower electromagnets (2) and (3) are located, coaxially to which springs (4) and (5) installed on the inner side of electromagnets (2) and (3) are located. The system includes a valve, the first disk armature (8) and additional second disk armature (9). The valve represents plate (7) with leg (6). The first disk armature (8) is connected to leg (6) of the valve and can interact with upper electromagnet (2). Leg (6) of the valve passes through the second disk armature (9). The second disk armature (9) has a possibility of interaction with lower electromagnet (3). In the upper part of the control system there additionally installed along the vertical axis is arming fork (12) that can interact with the disk armature of one of the electromagnets. The upper part of leg (6) of the valve is additionally provided with limit stop (10) with additional spring (11) that can interact with the disk armature of one of the electromagnets. Springs (4) and (5) of lower and upper electromagnets (2) and (3) have different stiffness. The invention describes versions of design of an electromagnetic control system of valves of a gas distributing mechanism of an internal combustion engine.

EFFECT: reducing useful current and increasing actuation speed of a valve.

5 cl, 12 dwg

Description

The invention relates to engine building and can be used as a valve control device for a gas distribution mechanism of an internal combustion engine.

A drive device for an electromagnetic valve is known, comprising a housing in which the upper and lower electromagnets are located. An anchor is located between the electromagnets, which is rigidly connected to the valve leg. Inside the electromagnet coils, on the valve leg, a spring is placed. The valve leg has the ability to move with the anchor (WO 2011/137663).

Similar designs of the electromagnetic valves of the gas distribution mechanism are also known, in particular FR 2969694, WO 2012/085484; KR 20120019265; US2012048222; KR 20120017982; WO 2011EP62395; ES 2373396, ES 2365916; JP 2011157953; ES 2359250; WO 2007/096826; JP 2005337078; JP 2005273515; US2003217714; US2002057154; US 6,477,993.

The closest technical solution chosen by the applicant as a prototype is the solenoid valve of the gas distribution mechanism of an internal combustion engine, comprising a housing that closes the upper and lower electromagnets, which springs are coaxially located, with one spring installed on the outside of the closing electromagnet, and the other with the inner side of the opening electromagnet, a disk anchor rigidly connected to the valve leg, the valve is additionally equipped with located coax For electromagnets, two springs, one of which is installed on the inside of the closing electromagnet, and the other on the outside of the opening electromagnet, and a guide sleeve installed in the cavity of the housing, which has an annular protrusion in the middle part in which grooves are made uniformly around the circumference, while the disk the anchor is made with protrusions evenly spaced around the circumference, mounted in said grooves with the possibility of reciprocating movement, in addition, between the protrusion of the guide bushings and external springs mounted elastic rings (patent for utility model RU No. 56479, 2006).

The disadvantage of this design is the high current consumption and low response speed of the electromagnetic valve.

An object of the invention is to increase the efficiency of the control of the phases of the gas distribution mechanism.

The technical problem is achieved by the fact that the electromagnetic valve control system of the gas distribution mechanism of the internal combustion engine according to embodiment one, comprises a housing in which the upper and lower electromagnets are located, coaxially located with the springs installed on the inside of the electromagnets, a valve representing a plate with a foot, a disk an anchor connected to the valve leg and configured to interact with an electromagnet, while, unlike the prototype, additionally install the second disk armature through which the valve leg passes, the first disk armature is made to interact with the upper electromagnet, and the second disk armature is made to interact with the lower electromagnet, in the upper part of the electromagnetic system, a cocking plug is additionally installed along the vertical axis, which is made with the possibility of interaction with a disk armature of one of the electromagnets, the upper part of the valve leg is provided with a stop with an additional spring, which is made with possible Stu interaction with a disk armature of a solenoid, and a spring lower and upper electromagnet performed with different stiffness.

The cocking plug can be configured to interact with the lower disk electromagnet armature, the additional spring has the ability to interact with the first disk electromagnet upper arm, while the spring stiffness of the lower electromagnet is greater than the spring stiffness of the upper electromagnet.

The cocking plug can be rigidly connected to the disk anchor of the upper electromagnet, the additional spring has the ability to interact with the second disk anchor of the lower electromagnet, while the stiffness of the spring of the upper electromagnet is greater than the stiffness of the spring of the lower electromagnet.

Comparison of the claimed invention with the prototype shows that it differs in the following features:

- additionally installed a second disk anchor;

- the second disk armature is configured to interact with the lower electromagnet;

- the first disk armature is configured to interact with the upper electromagnet;

- the valve leg passes through the second disk armature;

- an emphasis is made in the upper part of the valve leg, which interacts with the additional spring installed on it;

- an additional spring on the other hand has the ability to interact with the disk armature of one of the electromagnets;

- a vertical plug is installed along the vertical axis in the upper part of the valve, which has the ability to interact with the disk armature of one of the electromagnets;

- the spring stiffness of the lower electromagnet is different from the spring stiffness of the upper electromagnet.

Therefore, we can assume that the claimed invention according to option one meets the criterion of "novelty."

In option two, the technical problem is also achieved by the fact that the electromagnetic valve control system of the gas distribution mechanism of the internal combustion engine contains a housing in which the upper and lower electromagnets are located, coaxially located with the springs installed on the inside of the electromagnets, a valve representing a plate with a leg, a disk anchor associated with the valve leg and configured to interact with an electromagnet, while, unlike the prototype, A second disk armature through which the valve leg passes was installed, the first disk armature is made to interact with the upper electromagnet, and the second disk armature is made to interact with the lower electromagnet, an emphasis is made in the upper part of the valve leg with an additional spring installed on it, which on the other hand, it has the ability to interact with the disk armature of the lower electromagnet, the latter is equipped with a cocking plug configured to interact with the disk armature of the ver it electromagnet by end stops, wherein the spring stiffness of the lower electromagnet upper electromagnet lower stiffness springs.

Comparison of the proposed solution with the prototype shows that it differs in the following features:

- additionally installed a second disk anchor through which the valve leg passes;

- the first disk armature is configured to interact with the upper electromagnet;

- the second disk armature is configured to interact with the lower electromagnet;

- an emphasis is made in the upper part of the valve leg with an additional spring installed on it;

- the additional spring on the other hand has the ability to interact with the disk armature of the lower electromagnet;

- the disk anchor of the lower electromagnet is equipped with a cocking plug configured to interact with the disk anchor of the upper electromagnet by means of end stops;

- moreover, the spring stiffness of the lower electromagnet is less than the spring stiffness of the upper electromagnet.

Therefore, we can assume that the claimed invention according to option two meets the criterion of "novelty."

In option three, the technical problem is also achieved by the fact that the electromagnetic valve control system of the gas distribution mechanism of the internal combustion engine contains a housing in which the upper and lower electromagnets are located, coaxially located with the springs mounted on the inside of the electromagnets, a valve representing a plate with a leg, a disk anchor associated with the valve leg and configured to interact with an electromagnet, while, unlike the prototype, A second disk armature through which the valve leg passes was installed, the first disk armature is made to interact with the upper electromagnet, and the second disk armature is made to interact with the lower electromagnet, an emphasis is made in the upper part of the valve leg with an additional spring installed on it, which on the other hand, it has the ability to interact with the disk anchor of the upper electromagnet, the second disk anchor of the lower electromagnet is equipped with a cocking plug, the disk anchor of the upper elec resistant glass provided with an electromagnet, and wherein the abutment glass platoon plug are movable relative to each other, and the spring stiffness of the lower electromagnet greater rigidity of the upper electromagnet springs.

Comparison of the proposed solution with the prototype shows that it differs in the following features:

- additionally installed a second disk anchor through which the valve leg passes;

- the first disk armature is configured to interact with the upper electromagnet;

- the second disk armature is configured to interact with the lower electromagnet;

- an emphasis is made in the upper part of the valve leg with an additional spring installed on it, which on the other hand has the ability to interact with the disk armature of the upper electromagnet;

- the lower disk anchor is equipped with a cocking fork;

- the disk armature of the lower electromagnet is equipped with a thrust cup;

- thrust cup and cocking plug have the ability to move relative to each other;

- the spring stiffness of the lower electromagnet is greater than the spring stiffness of the upper electromagnet.

Therefore, we can assume that the claimed invention according to option three meets the criterion of "novelty."

The invention according to the claimed options is implemented with

using well-known technological processes and equipment, therefore it meets the criterion of "industrial applicability".

The principle of operation of all mechanisms identified as a result of patent research is based on the effect of attracting the anchor with an electromagnet, which is a fairly long process and requires a large consumption of electricity. As you know, in order to hold a pre-magnetized armature, an electric current is required 10 times less than the electric current to attract, due to the fact that the drawn armature of the electromagnet closes the magnetic flux through itself and the magnetic circuit is closed i.e. there are no losses in the magnetic gap. The claimed technical solutions work on the principle

pre-drawn anchors with a small electric holding current, and the speed of response depends only on the stiffness of the springs. An experimental verification of the claimed variants of the electromagnetic valve control system showed an increase in the efficiency of the control of the phases of the gas distribution mechanism, which obviously does not follow from the prior art. In addition, as a result of patent research, the claimed combination of features has not been identified, therefore, it is possible to draw a preliminary conclusion and the compliance of the claimed technical solution with the criterion of "inventive step".

The combination of three technical solutions in one application is determined by a single inventive concept, which is determined by the presence of an additional disk armature, the interaction of disk anchors with different sides of the electromagnets, and the presence of an additional spring, made with the possibility of interaction with disk anchors, which, in turn, determines the design features of the claimed options. Also, a single inventive concept is confirmed by tests of the inventive control system, which confirmed the achievement of a single technical result and the efficiency of all the claimed options.

Figure 1, 2, 3 - schematically shows a device according to option one.

Figure 4, 5, 6 shows an example of the inventive device according to option one, in which the cocking plug can be rigidly connected by a disk armature of the upper electromagnet.

7, 8, 9 show an example of the inventive device according to option two, where the cock is made with end stops.

Figure 10, 11, 12 shows an example of the inventive device according to option three with a thrust cup.

The device according to option one consists (Fig. 1) of a housing 1 in which an upper electromagnet 2 and a lower electromagnet 3 are installed. Coaxially to the electromagnets 2 and 3, springs 4 and 5 are located, which are installed on their inner side. On the vertical axis of the device inside the springs 4 and 5 is the leg 6 of the valve plate 7, which can interact with the disk armature 8. The device contains an additional disk armature 9, through which the valve leg 6 also passes. An additional disk armature 9 interacts with the lower electromagnet 3. An emphasis 10 is made in the upper part of the valve leg 6, which has the ability to interact with the additional spring 11, also located on the valve leg 6. The spring 11, on the other hand, has the ability to interact with the disk armature 8 of the upper electromagnet 2. At the top of the device, a cocking plug 12 is installed, which has the ability to interact with the disk armature 9 of the lower electromagnet 3. In this circuit, the spring stiffness 5 is greater than the spring stiffness 4. .1 shows cam 13 of camshaft, gas channel 14.

The device according to option one works as follows. In the initial position (Figure 1), the electromagnets 2 and 3 are connected to the current, while the gas channel 14 is closed by means of a valve plate 7. The disk anchors 8 and 9 are tightly held by electromagnets 2 and 3, compressing the pre-charged springs 4 and 5. First, the current of the upper electromagnet 2 is turned off, the disk anchor 8 ceases to be attracted by the magnetic field of electromagnet 2, the spring 4 instantly unclenches and transfers force through the disk anchor 8 to leg 6 of the valve. The valve plate 7 opens the gas channel 14 (Figure 2). The upper electromagnet 2 can again be connected to the current, while it will not be able to pull the disk armature back again with the holding current 8. Next (Figure 3), the current of the lower electromagnet 3 and the second disk armature 9 through the disk armature 8 and the additional spring 11 are turned off acting on the foot stop 6 of the valve under the action of the spring 5, the rigidity of which is greater than that of the spring 4, rises and pushes up the cock 12, while the valve plate 7 closes the gas channel 14, and the disk armature 8 is attracted again to the upper electromagnet 2. Additional The jig 11 provides a soft contact of the valve plate 7 to the seat of the gas channel 14. The cocking plug 12 (Fig. 1), under the action of the cam cam 13, presses the second disk armature 9, which is attracted to the connected lower electromagnet 3. The cam 13 is rotated, making it possible to repeat the cycle again under the influence of an electronic controller.

The design of the electromagnetic valve control system of embodiment one may be performed as shown in FIG. 4. A feature of this design is that the cock 12 is rigidly connected to the first disk armature 8 of the upper electromagnet 3, and the additional spring 11 is able to interact with the second disk armature 9 of the lower electromagnet 3.

The operation of the device (Figure 4) is as follows. In the initial position, the electromagnets are connected to the current, while the gas channel 14 is open, and the cocking plug 12 is in the upper extreme position. The disk anchors 8 and 9 are tightly held by the electromagnets 2 and 3, thereby holding the pre-compressed springs 4 and 5. First, the current of the lower electromagnet 3 is turned off, the second disk armature 9 ceases to be attracted by the magnetic field of the electromagnet, the spring 5 instantly expands, acting on the disk armature 9 through the additional spring 11 and through the emphasis 10, raising the valve leg 6, while the valve plate 7 closes the gas channel 14, the soft fit of the valve plate 7 to the seat of the gas channel 14 provides an additional spring 11. tromagnit 3 can be connected again by the current pull back the disc armature 9, he can not. Next (Figure 5), the current of the electromagnet 2 and the disk armature 8 with the cocking plug 12 are turned off, under the action of the spring 4, the rigidity of which is greater than the stiffness of the spring 5, pushes the valve leg 6 down through the disk armature 9, while the gas channel 14 opens, and the disk anchor 9 is attracted to the electromagnet 3. Under the action of the cam 13 of the camshaft, through the rocker arm 15 and the cock 12, the disk anchor 8 is attracted back to the electromagnet 2. The cam 13 departs and the cycle under the control of the electronic controller repeats.

The device according to option 2 consists of a housing 1 (Fig. 7), in which an upper electromagnet 2 and a lower electromagnet 3 are installed. Coaxially to the electromagnets 2 and 3, springs 4 and 5 are located, which are installed on their inner side. On the vertical axis of the device inside the springs 4 and 5 is the leg 6 of the valve plate 7, which has the ability to interact with the disk armature 9 of the lower electromagnet. The device contains an additional disk anchor 8. An emphasis 10 is made in the upper part of the valve leg 6, which has the ability to interact with an additional spring 11, also located on the leg 6. The spring 11, on the other hand, can interact with the disk armature 9 of the lower electromagnet 3. Disk anchor 9 is equipped with a cocking plug 12, which is able to interact with the disk anchor 8 of the upper electromagnet by means of end stops 17, and the spring stiffness of the upper electromagnet is greater than the stiffness of the lower spring its electromagnet.

The device according to option two works as follows. In the initial position, the electromagnets are connected to the current, while the gas channel 14 is closed, and the cocking plug 12 is in the upper extreme position (Fig.7). The disk anchors 8 and 9 are tightly held by the electromagnets 2 and 3, thereby holding the pre-compressed springs 4 and 5. First, the current of the lower electromagnet 3 is turned off, the disk anchor 9 ceases to be attracted by the electromagnet's magnetic field, the spring 5 instantly opens, lowering the valve leg 6 down, at the same time, the valve plate 7 opens the gas channel 14. The electromagnet 3 can again be connected under current, it will not be able to pull back the disk armature 9 (Fig. 8). Next (Fig. 9), the current of the electromagnet 2 and the disk armature 9 are switched off under the action of the spring 4, the stiffness of which is greater than the stiffness of the spring 5, captures the stops 17 of the cock 12, which through the disk armature 9, the additional spring 11 and the stop 10 lifts the leg 6 with the valve plate 7, while the valve plate 7 closes the gas channel 14, and an additional spring 11 ensures a soft fit of the valve plate 7 to the seat of the gas channel 14. The disk armature 9 is tightly drawn to the electromagnet 3. Under the action of the cam 13 of the camshaft (Fig. 7) disk yak Ori 8 returns to its original position. Next, the cam 13 is rotated, the cycle is repeated under the action of an electronic controller.

The design of the electromagnetic valve control system of embodiment three may be performed as shown in FIG. 10. A feature of this design is that the disk armature 8 of the upper electromagnet is equipped with a thrust cup 16, and the thrust cup 16 and cocking fork 12 are movable relative to each other.

The device operates as follows (Figure 10). In the initial position, the electromagnets are connected to the current, while the gas channel 14 is open. The disk anchors 8 and 9 are tightly held by the electromagnets 2 and 3, thereby holding the pre-compressed springs 4 and 5. First, the current of the upper electromagnet 3 is turned off, the disk armature 8 ceases to be attracted the magnetic field of the electromagnet, the spring 4 instantly unclenches, acting on the disk armature 8, which through the thrust cup 16, an additional spring 11, emphasis 10, raises the valve leg 6 up, the valve plate 7 closes the gas channel 14 (Fig.11). The soft fit of the valve plate 7 to the seat of the gas distribution channel 14 is provided by an additional spring 11. The electromagnet 3 can again be connected under current, it will not be able to pull back the disk armature 8 with a holding current. Then, the current of the electromagnet 2 is turned off and the disk armature 9 acts on the valve leg 6 under the action of the spring 5, while the valve plate 7 opens the gas channel 14, and the spring 4 is compressed, because its rigidity is less than that of the spring 5. The disk anchor 8 (Fig. 12) is attracted to the connected electromagnet 2. Under the action of the cam 13, through the rocker 15, the cock 12, the disk anchor 9 is attracted back to the connected electromagnet 3. Then the cam 13 moves away, and the cycle repeats under the influence of an electronic controller.

Thus, each of the claimed options, the electromagnetic valve control system of the gas distribution mechanism of the internal combustion engine, can improve the efficiency of the control of the phases of the gas distribution mechanism.

Claims (5)

1. An electromagnetic valve control system for a gas distribution mechanism of an internal combustion engine, comprising a housing in which the upper and lower electromagnets are located, coaxially arranged with springs mounted on the inside of the electromagnets, a valve comprising a plate with a leg, a disk armature connected to the valve leg and made with the possibility of interaction with an electromagnet, characterized in that the control system additionally has a second disk armature through which there is a valve leg, the first disk armature is made to interact with the upper electromagnet, and the second disk armature is made to interact with the lower electromagnet, an additional plug is installed in the upper part of the control system along the vertical axis, which is made to interact with the disk armature of one of electromagnets, the upper part of the valve leg is additionally equipped with a stop with an additional spring, which is made with the possibility of interaction with a disk yak rem one of the electromagnets, wherein the upper and lower springs of the electromagnets are made with varying stiffness. 2. The electromagnetic control system according to claim 1, characterized in that the cocking plug can be configured to interact with the lower disk electromagnet armature, the additional spring has the ability to interact with the first disk armature of the upper electromagnet, while the spring stiffness of the lower electromagnet is greater than the rigidity of the upper spring electromagnet. 3. The electromagnetic control system according to claim 1, characterized in that the cocking plug can be rigidly connected to the disk anchor of the upper electromagnet, the additional spring has the ability to interact with the second disk anchor of the lower electromagnet, while the spring stiffness of the upper electromagnet is greater than the stiffness of the lower spring electromagnet. 4. An electromagnetic valve control system for a gas distribution mechanism of an internal combustion engine, comprising a housing in which the upper and lower electromagnets are located, coaxially arranged with springs mounted on the inside of the electromagnets, a valve comprising a plate with a leg, a disk armature connected to the valve leg, and made with the possibility of interaction with an electromagnet, characterized in that the control system additionally has a second disk armature through which there is a valve leg, the first disk armature is made to interact with the upper electromagnet, and the second disk armature is made to interact with the lower electromagnet, an emphasis is made in the upper part of the valve leg with an additional spring installed on it, which on the other hand has the ability to interact with the disk an anchor of the lower electromagnet, the latter is equipped with a cocking plug made with the possibility of interaction with the disk anchor of the upper electromagnet by means of end stops in, the rigidity of the upper electromagnet lower spring rigidity of the upper electromagnet springs. 5. An electromagnetic valve control system for a gas distribution mechanism of an internal combustion engine, comprising a housing in which upper and lower electromagnets are located, coaxially arranged with springs mounted on the inside of the electromagnets, a valve comprising a plate with a leg, a disk armature connected to the valve leg and made with the possibility of interaction with an electromagnet, characterized in that the control system additionally has a second disk armature through which there is a valve leg, the first disk armature is made to interact with the upper electromagnet, and the second disk armature is made to interact with the lower electromagnet, an emphasis is made in the upper part of the valve leg with an additional spring installed on it, which on the other hand has the ability to interact with the disk the anchor of the upper electromagnet, the second disk anchor of the lower electromagnet is equipped with a cocking plug, the disk anchor of the upper electromagnet is equipped with a thrust cup, and molecular weight and glass platoon plug are movable relative to each other, and the spring stiffness of the lower electromagnet greater rigidity of the upper electromagnet springs.

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