1. Introduction
Due to the rapid development of new energy vehicles, improving the performance of traditional internal combustion engine vehicles can greatly ease the competition within the automotive industry and the crisis of energy form change. Variable valve trains significantly reduce pumping loss and discharge loss of engine by enabling a continuously variable phase and lifting of the valve. At present, a variable valve train mainly includes either an electro-hydraulic drive, electric drive or an electromagnetic drive [
1]. Compared with the first two, the electromagnetic variable valve (EMVV) system does not need a transfer medium, and it has a simple structure and high power density. There have been many related research cases in the world, and it has become a research hotspot in related fields [
2,
3]. Although an EMVV system can realize the continuous adjustment and movement of the valve opening and closing, the external force easily interferes with valve opening and closing because of its structural characteristics, and the control accuracy is also affected. In addition, due to the fast velocity of the valve seating, it is easy to have a large impact collision with the engine cylinder head, and it can produce a large noise; it also has a greater impact on the engine life. Therefore, the scheme of the valve seating buffer (VSB) is extremely important for an EMVV system.
Currently, the scheme of the VSB of an electromagnetic drive valve train mainly includes control strategy research and an external mechanism. Yang et al. [
4] designed an energy compensation control for an optimized engine electromagnetic valve; valve “zero” seating velocity was achieved by neutralizing positive and negative work in the armature stroke. Paden et al. [
5] proposed a new type of EMVV structure, and the rapid response of the valve between opening and closing state was realized through the implementation of a control strategy while ensuring low valve seating velocity and power consumption. Compared to traditional, complex control strategies, the method of using external buffers has lower difficulty and does not require study of sophisticated control strategies; it can achieve valve seat buffering in the most simple and reliable way. Tu et al. [
6] used a one-way throttle valve to buffer the electro-hydraulic drive valve mechanism; the best buffer effect was achieved by changing throttling area and throttling stroke of the throttle valve, and the seating velocity was reduced, and the dynamic response of the valve was improved in this way. Pan et al. [
7] added a one-way valve to the upper end of the valve plunger to buffer the valve seating; the valve was simultaneously subjected to the oil pressure and spring force of the valve system during seating, which effectively decreased the valve seating velocity. Xu et al. [
8] introduced the disc spring into the EMVV system, so that it acted between the valve and the coil, which could store most of the kinetic energy of the coil and effectively reduced the impact stress by about 50%. The faster the seating velocity, the more obvious the effect. Nowadays, most of the solutions for valve seating buffer are realized by control methods, but, because the valve seating is fast, and the time is short, the control is really a difficult method.
Buffering, as an important part of shock absorption, is often used in vehicles, bridges, aerospace and other fields. Magnetorheological buffers have attracted much attention in recent years due to their low energy consumption, fast response and large output damping force. The working principle of magnetorheological fluid is to control the magnetic induction intensity in the flow channel by adjusting the current intensity of the coil and then changing the shear yield strength of the magnetorheological fluid, affecting the pressure drop at both ends of the buffer flow channel so as to achieve the purpose of outputting the buffer force. It has the advantages of stable performance, low input voltage and large yield stress. David Case et al. [
9] designed a small magnetorheological buffer for upper limb orthosis and model building, and experimental verification of the buffer was carried out, and the feasibility of applying small magnetorheological buffer to tremor motion attenuation was discussed. T.M. Gurubasavaraju et al. [
10] proposed a scheme applying a magnetorheological buffer to a semi-active suspension system; a quarter of the vehicle models were analyzed under different road conditions. The results showed that the semi-active suspension with magnetorheological buffer had better regularity and road stability. Alan Sternberg et al. [
11] proposed a large magnetorheological buffer for reducing the vibration of high-rise buildings; the design, manufacture and testing of the buffer prototype were completed. The test results were in good agreement with the established finite element model. In the actual design of magnetorheological buffers, most researchers often obtain some key parameters through experience, such as the size of the flow channel gap, the piston, etc. Therefore, it is necessary to optimize the structural parameters of the magnetorheological buffer after the structural design. Mao et al. [
12] proposed an optimistic method of the structuring of a magnetorheological buffer by using a nonlinear flow model; the test showed that the performance of the optimized prototype was greatly improved. Guan et al. [
13] used a multi-objective genetic algorithm, selected the output buffer force and adjustable multiple of the buffer as the optimization objectives, optimized the seven key variables of the magnetorheological buffer and, finally, obtained a large buffer force and highly adjustable multiple. Wu et al. [
14] optimized the magnetic circuit of a magnetorheological buffer through the APDL parametric language built-in ANSYS and achieved the expected requirements. Yang et al. [
15] proposed a novel structure of the annular multi-channel magnetorheological valve, designed its magnetic circuit and improved the pressure drop performance of the annular multi-channel magnetorheological valve.
In this paper, a scheme for adding a VSB is proposed to solve the problem of the large seating impact of electromagnetic valve, and the VSB is designed and optimized. An EMVV can effectively improve the power and fuel economy of an engine, but the existing integration layout of the system cannot meet the problem of limited setting space during actual installation, and the traditional modeling method cannot fully show the complex coupling structural characteristics of the EMVV system. Therefore, this paper firstly proposes a new structure for an EMVV system and then a collision model is established for the problem of soft landing, and the model is verified by Zheng’s [
16] test bench. The structure, material and size parameters of the proposed buffer are designed in detail, and some key parameters of the buffer are optimized by the Nelder–Mead (N-M) algorithm. Finally, a co-simulation model is built based on the coupling relationship between the actuator and the buffer of the EMVV system; the effectiveness and advantages of the designed VSB are verified by analyzing the valve seating performance of the system.
3. Design of Valve Seating Buffer
3.1. Structure Design
The magnetorheological buffer consists of a piston, piston rod, cylinder, cover, coil and magnetorheological fluid. When the buffer works, the piston rod drives the piston to move, the magnetorheological fluid with increased viscosity under the action of the magnetic field generated by the coil is squeezed, forms pressure difference and generates buffer force. In general, the magnetorheological buffer can be divided into a damping unit and a damping cylinder.
3.1.1. Channel Form
The flow channel of the damping unit is a channel that, through the magnetorheological fluid, affects the output buffer force. The main channel forms of the magnetorheological fluid are annular channel and disc channel. The annular channel has a simple structure and convenient installation, and it can decrease the volume of the buffer effectively. As for the disc channel, although the structure is relatively complex, its special structure can improve the utilization rate of the magnetic field and buffer force. Therefore, the annular channel and disc channel are combined as a mixed channel in this paper.
Figure 6 is the structure of the mixed channel; it not only ensures small volume of the buffer, but also improves the performance of the buffer by promoting the utilization rate of the magnetic field.
3.1.2. Coil Number
As the input source of the buffer, the number of the electromagnetic coil has an important influence on the buffer performance. The coil has had single circle and multiple circles in recent research. A single circle is suitable for the magnetorheological buffer, which has a small volume; it can reduce control difficulty and improve space utilization. Although multiple circles have higher control difficulty, the diversity of the control strategies and the error-tolerant rate of the buffer are promoted. Because the VSB designed in this paper should have small volume and brief structure, the single circle is selected.
Coil turn is also a factor that has an effect on buffer force. In this paper, the coil turn is defined as the ratio of the area at the coil to the cross-sectional area of the single-turn coil. However, in the actual process of winding coil, a gap is generated between the coils, which leads to the actual turn number to be less than the calculated value. Thus,
η is defined as a gap coefficient to eliminate the effect of the gap between coils on coil turn. The gap coefficient depends on coil diameter. The larger the wire diameter selected for the coil, the larger the gap and the greater
η. After correction, the calculation formula of the coil turns is:
where
N is coil turns,
CoilR is the groove depth at the coil,
CoilH is the groove width at the coil and the product of the two is the area at the coil.
S is the cross-sectional area of wires.
η is taken as 0.78 in this paper.
3.1.3. Combination of Damping Unit and Damping Cylinder
The combination modes of the damping unit and damping cylinder include embedded type and bypass type. Bypass type occupies a large volume, but it is more convenient to install and replace parts, and the piston neutral problem does not affect the buffer force. Embedded type is a piston with a coil moving in a sealed damping cylinder, changing the magnetic field of the magnetorheological fluid in the cylinder and squeezing the magnetorheological fluid to produce buffer force. An embedded buffer has a compact structure, small occupied volume and high magnetic field utilization, so the embedded scheme is selected as the combination of damping unit and damping cylinder in this paper.
3.2. Material Design
3.2.1. Magnetorheological Fluid
As the core material of magnetorheological buffer, the performance requirements of magnetorheological fluid mainly include low zero-field viscosity and high maximum shear yield strength. The viscosity of magnetorheological fluid increases and transforms into Bingham fluid in a very short time when it is affected by magnetic field, and it is a Newtonian fluid without a magnetic field. The typical Bingham model can be described as:
where
(Pa) is the shear stress of magnetorheological fluid.
(Pa
s) is the zero-field viscosity of magnetorheological fluid, an important parameter to measure the performance of magnetorheological fluid.
(Pa) is the shear yield strength of the magnetorheological fluid.
(s
−1) is the shear rate of the magnetorheological fluid, that is:
In the Bingham model, the magnetorheological fluid in the plug flow area is non-differentiable, which makes it difficult to solve in practical calculation. Therefore, through consulting the literature, this paper uses the approximate Bingham plastic model proposed by David Case [
18]. The model becomes continuously differentiable by decomposing the plug flow area into continuous tiny regions, which can be described as:
where
is a constant used to eliminate discontinuities, usually approaching 0 in this model.
is the proportional term of the slope, usually approaching infinity. The dynamic viscosity of the magnetorheological fluid obtained by deformation of Equation (4) is:
MRF-122EG magnetorheological fluid produced by the American LORD Company is adopted in this paper. Its specific performance parameters are shown in
Table 1.
In order to couple the electromagnetic field with the flow field, the relationship between the yield stress
(kPa) and the magnetic induction
B (T) of MRF-122EG is obtained by curve fitting:
3.2.2. Valve Core Material
Valve core material is soft magnetic material that is prone to magnetization and demagnetization processes and has low coercive force. Industrial pure iron is one of the most widely used soft magnetic materials [
19]; the performance of saturation magnetic induction and magnetic permeability in soft magnetic materials is excellent, but high conductivity also leads to high loss. Soft magnetic materials affect the response time of magnetorheological buffers through conductivity. According to the current research status of soft magnetic materials, new composite material has a large magnetic saturation induction intensity, so it does not reach the magnetic saturation in practical application and does not affect the maximum buffer force. Therefore, in order to improve the dynamic response velocity of the buffer, this paper chooses new composite material as the soft magnetic material of the valve core.
3.2.3. Cylinder Material
The cylinder body is one of the most important parts of the magnetic circuit of magnetorheological buffers; its magnetic property plays a key role in the magnetic performance. As for the selection of cylinder material, on the one hand, the material should have good magnetic properties. On the other hand, due to the diameter of the designed buffer being very small, the cylinder material should have better processing performance, which has the ability to maintain strength while being machined to a small diameter and small thickness. At present, the most widely used cylinder material is industrial pure iron, which has good magnetic properties but is not easy to process. Therefore, this paper chooses No. 10 steel as the cylinder material of the buffer, which has similar magnetic properties to industrial pure iron but has better machinability and lower price.
3.3. Dimension Design
After selecting the mixed-channel, embedded VSB structure scheme, the key dimensions need to be structurally designed; the structure of the design buffer is shown in
Figure 7. The buffer is connected to the magnetic disk and the valve core is moved up and down by a piston rod. The magnetorheological fluid flows in the mixed channel. After the coil is energized, the magnetorheological effect occurs, so the viscosity of the magnetorheological fluid increases and outputs the controllable buffer force. According to the design requirements, the designed buffer can output buffer force of about 100 N with a maximum current of 2.5 A and a damping unit velocity of 0.5 m/s. The selected design variables and their ranges are shown in
Table 2.
3.4. Optimization Design
At present, the most commonly used optimization algorithms in structural optimization include the multi-objective optimization algorithm [
20], bound optimization BY quadratic approximation (BOBYQA) algorithm [
21], Nelder–Mead (N-M) algorithm [
22,
23,
24] and so on. In the actual optimization process, different optimization objectives cannot achieve the optimal value at the same time. Both BOBYQA and N-M optimize targets based on established finite element models. The optimization object of this paper is the buffer, and the optimization parameter is the dimension parameter of the buffer. The adjustable coefficient of buffer force is taken as the objective function of optimization, which is single-objective optimization. The ultimate goal is to make the adjustable coefficient of the buffer reach the maximum value. Because the modeling software used in this paper and the co-simulation platform COMSOL Multiphysics have a built-in N-M algorithm, the optimization can be directly processed after modeling, which can greatly improve efficiency and save time. Therefore, this paper uses the N-M algorithm to optimize the dimension of the buffer. The workflow of the N-M algorithm is shown in
Figure 8.
- 2.
Generate point
by reflecting the W (Worse):
where
is reflection coefficient, usually taken as 1.
is the center of figure:
In two-dimensional space, n is 2. If , the direction of reflection is correct to the target value, then the iteration is terminated. If , turn to the third step. Otherwise, take the fourth step;
- 3.
Construct expansion point
in the same direction of the reflection point:
where
is the expansion coefficient, usually taken as 2. If
, replace
with
and terminate iteration. Otherwise, replace
with
and terminate iteration;
- 4.
Choose shrinkage mode. If
, point
is generated:
where
is shrinkage coefficient, usually taken as 0.5. If
, replace
with
and terminate iteration. Otherwise, take the fifth step.
If
, iterate to obtain the point
:
If , replace with and terminate iteration. Otherwise, take the fifth step;
where the range of shrinkage coefficient
is 0~1, usually taken as 0.5,
{2,...,
n + 1}. Repeat steps 1 to 5 until the termination condition of the iteration is reached or the maximum number of iterations is reached. The final approximate solution of the unknown target value
x is represented by the optimal solution
.
According to the above-selected objective function, optimization variables and optimization algorithm, the multi-physics finite element model of the designed buffer is established, and the relevant settings are carried out in COMSOL software. It is found that the adjustable coefficient reaches a stable value of about 24.76 after about 280 iterations. The optimized variables and the rest key parameters of the buffer are shown in
Table 3.
The diameter of the optimized buffer is negligibly small, and the space of coil is small, so it is necessary to select the diameter of the copper winding to be as small as possible when the maximum current is 2.5 A. By querying the related information of varnished wire, the varnished wire of type QY-2/2200.100GB6109.6-88 is selected. According to the optimized structural parameters and Equation (1), the coil turns of the designed buffer are 136, and the optimized coil has two radial winding layers and 63 axial winding laps.
5. Conclusions
In this paper, an external buffer is proposed, aiming to resolve the problem of large impact and noise of EMVV landing. The structure, material and dimension design process of the VSB rdescribed in detail, and the key size parameters of the buffer are optimized based on the N-M algorithm. Meanwhile, the coupling relationship between the actuator and the buffer in the EMVV system is studied; a scheme where the VSB is embedded in the EMVA is proposed. In addition, a COMSOL and MATLAB/Simulink co-simulation platform and co-simulation model are built based on the scheme. Finally, the results of the co-simulation are compared, and the valve seating performance is analyzed.
The integration scheme proposed in this paper not only improves the integration of the system, but also greatly reduces the volume of the whole system, which is a tremendous boost for the engine in its limited setting space. Furthermore, the valve seating velocity and the valve rebound height are reduced from 0.58 m/s and 0.67 mm to 0.03 m/s and 0.02 mm, and the reduction ratios are 94.8% and 97%, respectively. The co-simulation results show that opening the designed buffer before the valve seating can obviously relieve the valve seating impact, overwhelmingly improve the valve seating performance of the EMVV system and prolong the engine life. However, due to the small radial dimension of the designed buffer, machining accuracy and assembling mode are strongly required in processing. Therefore, it is necessary to further optimize the combination of the damping unit and the damping cylinder and the assembling mode of the damping unit of the buffer.