1. Field of the Invention
This invention relates to an electromagnetic actuator, an optical scanner using an electromagnetic actuator and a method of preparing an electromagnetic actuator.
2. Related Background Art
Conventional actuators prepared by utilizing the micro-machining technology are mostly based on the use of electrostatic force or piezoelectric phenomena. However, thanks to the availability of the micro-machining technology for utilizing magnetic materials in recent years, actuators using electromagnetic force have been developed.
As electric power is supplied to the coil 1005a of the actuator, the movable member 1003 is pulled toward the core 1004a to consequently displace the movable member 1003 to the left in FIG. 1. When, on the other hand, the coil 1005b is electrically energized, the movable member 1003 is displaced to the right in FIG. 1. The force F1 generated in the actuator is expressed by formula (1) below;
F1=0.5μ0N12i12w1t1(d1−x1)−2 (1 )
where μ0 is the magnetic permeability of vacuum, N1 is the number of turns of the coils, i1 is the electric current made to flow to the coil 1005a or 1005b, w1 is the width of the magnetic pole, t1 is the thickness of the magnetic pole and d1 is the length of the gap. If the spring constant of the springs 1007 is k1, the displacement x1of the actuator is expressed by using the relationship of formula (2) below;
F1=k1x1 (2)
However, since actuators having a configuration as described above by referring to
In view of the above identified technological problems of the prior art, it is therefore the object of the present invention to provide an electromagnetic actuator that can minimize the leakage of magnetic flux and hence the power consumption rate to improve the energy efficiency and remarkably increase the force it can generate, an optical scanner comprising such an electromagnetic actuator and also a method of preparing such an electromagnetic actuator.
According to the invention, the above-described object is achieved by providing an electromagnetic actuator comprising:
a stationary member having a first core section carrying a first coil wound around its periphery;
a movable member magnetically coupled with the stationary member with a gap therebetween and having a second core section carrying a second coil wound around its periphery;
a support member for displaceably supporting the movable member relative to the stationary member; and
an electric current source for displacing the movable member relative to the stationary member by supplying electricity to the first and second coils.
In another aspect of the invention, there is provided an optical scanner comprising an electromagnetic actuator according to the invention and a mirror arranged on the movable member of the electromagnetic actuator.
In another aspect of the invention, there is provided an optical scanner comprising an electromagnetic actuator according to the invention and a lens arranged on the movable member of the electromagnetic actuator.
In still another aspect of the invention, there is also provided a method of preparing an electromagnetic actuator comprising a stationary member having a first core section carrying a first coil wound around its periphery, a movable member magnetically coupled with the stationary member with a gap therebetween and having a second core section carrying a second coil wound around its periphery and a support member for displaceably supporting the movable member relative to said stationary member, the method comprising steps of:
forming the stationary member, the movable member and the support member on a single substrate by means of photolithography and plating; and
removing the substrate from under the movable member so as to make the movable member to be supported by the substrate by way of the support member.
An electromagnetic actuator according to the invention comprises a movable member and a stationary member having respective coils and cores which are magnetically coupled with each other so that a troidal coil is formed by each of the movable member and the stationary member to reduce the leakage of magnetic flux. Therefore, the electromagnetic actuator can minimize the consumption rate of electric current and maximize the energy efficiency. Additionally, both the movable member and the stationary member are provided with respective coils, the total number of turns of the coils can be increased to consequently raise the force that the actuator can generate.
The electric circuit of the above arrangement can be simplified by electrically connecting the stationary coil and the movable coil to consequently simplify the process of preparing the actuator. Additionally, the phenomenon that the force generated in the actuator is inversely proportional to the square of the gap separating the stationary member and the movable member can be eliminated when the stationary member and the movable member are provided with projections and depressions and arranged in such a way that they are combined interdigitally and hence the force generated in the actuator can be determined simply as a function of the electric current flowing through the coils. With such an arrangement, it is possible to control an electromagnetic actuator according to the invention provides by far easier than any conventional electromagnetic actuators.
Still additionally, the stationary member and the movable member of an electromagnetic actuator can be located accurately relative to each other to accurately control the gap separating them by forming both the stationary member and the movable member on a single substrate. It is also possible to simplify the process of preparing an electromagnetic actuator according to the invention by forming the stationary member, the movable electromagnetic and the support member as integral parts thereof. Furthermore, the support member can be made to directly follow the movement of the movable member without friction and play when the support member is formed by using parallel hinged springs. It is also possible to select the rotational direction of the movable coil so that an attraction type electromagnetic actuator or a repulsion type electromagnetic actuator may be prepared freely at will.
It is possible to prepare an optical scanner comprising an electromagnetic actuator according to the invention by micromachining to make the deflector show an excellent energy efficiency and a wide angle of deflection.
Any assembling process can be made unnecessary when the movable member, the stationary member and the support member of an electromagnetic actuator are formed on a substrate by means of photolithography and plating. Then, these components can be aligned highly accurately and the gap separating the movable member and the stationary can be minimized. Additionally, such an electromagnetic actuator is adapted to mass production and cost reduction. If a silicon substrate is used for the substrate, it can be subjected to an anisotropic etching process for accurately forming openings in the substrate.
Now, the present invention will be described in greater detail by referring to the accompanying drawings that illustrate preferred embodiments of the invention.
The stationary member 102 has comb-like teeth arranged at the opposite ends thereof and located in such a way that it is magnetically connected with the movable member 103 having a lateral side that is also toothed in a comb-like manner. The stationary core 104b and the movable core 104a are respectively provided with a stationary coil 105b and a movable coil 105a that are wound therearound. Referring to
Now, another embodiment of electromagnetic actuator according to the invention will be described by referring to
The electric current source 508, the movable coil 505a and the stationary coil 505b are electrically connected with each other in series. The movable core 504a is resiliently supported by a spring 507 having a spring constant of k. The movable coil 505a and the stationary coil 505b are made of a low resistance metal such as copper or aluminum and electrically insulated from the movable core 504a and the stationary core 504b. The movable core 504a and the stationary core 504b are made of a ferromagnetic material such as nickel, iron or Permalloy. As the movable coil 505a and the stationary coil 505b are fed with an electric current from the electric current 508, a magnetic flux is generated in the movable core 504a and the stationary core 504b to run in the direction of arrows shown in FIG. 3. The magnetic flux circularly runs through the magnetic circuit in the direction as indicated by arrows in
The magnetic resistance Rg(x) between the oppositely disposed teeth of the combs is given by formula (3) shown below:
where μ0 is the magnetic permeability of vacuum, d is the distance of the air gap, t is the thickness of the teeth of the combs, n is the number of unit air gaps, x is the displacement of the movable member and x0 is the overlapping distance of the teeth of the oppositely disposed combs in the initial state. If the magnetic resistance in areas other than the air gaps is R, the potential energy w of the entire magnetic circuit and the force F generated in the air gaps is expressed by formulas (4) and (5) respectively:
and
where N is the sum of the number of turns of the coil 505a and that of the coil 505b and i is the electric current flowing through the coils 505a and 505b.
If the movable core 504a and the stationary core 504b are made of a material showing a magnetic permeability sufficiently higher than the magnetic permeability of vacuum, R is made practically equal to 0 and the generated force F is expressed by formula (6) below.
From formula (6) above, it will be seen that the generated force F of this embodiment is proportional to the square of the number of turns of the coils. While the generated force F fluctuates slightly depending on the displacement x because the magnetic permeability cannot be infinitely high, such fluctuations in the generated force are small if compared with conventional magnetic actuators.
If the spring constant of the parallel hinged springs is k, the static displacement of the actuator is obtained from the balanced relationship of the spring force and the generated force as expressed by formula (7) below.
F=kx (7)
A comb-shaped repulsion type electromagnetic actuator can be realized by modifying the direction of winding of the movable coil 505a or the stationary coil 505b of the comb-shaped attraction type electromagnetic actuator.
Now, still another embodiment of electromagnetic actuator according to the invention will be described by referring to
The electric current source 208, the movable coil 205a and the stationary coil 205b are electrically connected with each other in series. The movable core 204a is resiliently supported by a spring 207 having a spring constant of k. The movable coil 205a and the stationary coil 205b are made of a low resistance metal such as copper or aluminum and electrically insulated from the movable core 204a and the stationary core 204b. The movable core 204a and the stationary core 204b are made of a Ferromagnetic material such as nickel, iron or Permalloy.
As the movable coil 205a and the stationary coil 205b are fed with an electric current from the electric current source 208, a magnetic flux is generated in the movable core 204a and the stationary core 204b to run in the direction of arrows shown in FIG. 4. The magnetic flux circularly runs through the magnetic circuit in the direction as indicated by arrows in
The magnetic resistance of one air gap between the oppositely disposed surfaces is given by formula (x+x0)/μ0tw and since a magnetic path transverses two air gaps, the magnetic resistance Rg(x) of the two air gaps separating the plates is given by formula (8) below:
where μ0 is the magnetic permeability of vacuum, t is the thickness of the end surface sections, w is the width of the end surface sections, x is the displacement of the movable member and x0 is the length of the air gaps in the initial state. If the magnetic resistance in areas other than the air gaps is R, the potential energy w of the entire magnetic circuit and the force F generated in the air gaps is expressed by formulas (9) and (10) respectively:
and
where N is the sum of the number of turns of the coil 205a and that of the coil 205b and i is the electric current flowing through the coils 205a and 205b.
If the movable core 204a and the stationary core 204b are made of a material showing a magnetic permeability sufficiently higher than the magnetic permeability of vacuum, R is made practically equal to 0 and the generated force F is expressed by formula (11) below.
From formula (11) above, it will be seen that the generated force F of this embodiment is proportional to the square of the number of turns of the coils.
If the spring constant of the parallel hinged springs is k, the static displacement of the actuator is obtained from the balanced relationship of the spring force and the generated force as expressed by formula (12) below.
F=kx (12)
A flat surface repulsion type electromagnetic actuator can be realized by modifying the direction of winding of the movable coil 205a or the stationary coil 205b of the flat surface attraction type electromagnetic actuator.
The present invention will be described further below by way of examples.
An electromagnetic actuator having a configuration as shown in
The stationary member 102 has comb-like teeth arranged at opposite ends thereof and located in such a way that it is magnetically connected with the movable member 103 having a lateral side that is also toothed in a comb-like manner. The stationary core 104b and the movable core 104a are provided respectively with a stationary coil 105b and a movable coil 105a that are wound therearound. The stationary coil 105b, the movable coil 105a and electric current source 108 are connected in series so that the operation of the actuator is controlled by the electric current source 108.
Now, a method used for preparing the actuator of this example will be described below. In this example, the stationary member 102, the movable member 103, the movable core 104a, the stationary core 104b, the movable coil 105a, the stationary coil 105b, the movable coil 105a, the support member 106 and the parallel hinged springs 107 are prepared by means of micromachining technology. Coil lower surface wiring 114, coil lateral surface wiring 115 and coil upper surface wiring 116 are prepared in the above mentioned order for both the movable coil 105a and the stationary coil 105b (see FIG. 5L).
Now, the method used for preparing the actuator of this example will be described in greater detail by referring to
Firstly as shown in
Thereafter, as shown in
Thereafter, as shown in
Finally, as shown in
Since the electromagnetic actuator of this example that was prepared in a manner as described above showed an excellent energy efficiency because a single troidal coil was formed by the movable member and the stationary member to minimize the leakage of magnetic flux. Additionally, since the movable member and the stationary member comprise respective coils and cores, the number of turns of the coils can be raised to increase the force generated in the actuator.
Mirror 311 is arranged on the movable member 303. The stationary member 302 has comb-like teeth arranged at the opposite ends thereof and located in such a way that it is magnetically connected with the movable member 303 having a lateral side that is also toothed in a comb-like manner. The stationary core 304b and the movable core 304a are provided respectively with a stationary coil 305b and a movable coil 305a that are wound therearound. The stationary coil 305b, the movable coil 305a and electric current source 308 are connected in series so that the operation of the actuator is controlled by the electric current source 308. The stationary member 302 and the movable member 303 are provided with teeth projecting like those of combs that are interdigitally arranged. This arrangement could be prepared by way of a process similar to the one described above by referring to Example 1.
With this arrangement, the movable member 403 is resiliently supported in such a way that it is held in parallel with the substrate 401 and can freely move relative to the latter.
Lens 411 is arranged on the movable member 403 to transmit laser beams. The stationary member 402 has comb-like teeth arranged at the opposite ends thereof and located in such a way that it is magnetically connected with the movable member 403 having a lateral side that is also toothed in a comb-like manner. The stationary core 404b and the movable core 404a are provided respectively with a stationary coil 405b and a movable coil 405a that are wound therearound. The stationary coil 405b, the movable coil 405a and electric current source 408 are connected in series so that the operation of the actuator is controlled by the electric current source 408. The stationary member 402 and the movable member 403 are provided with teeth projecting like those of combs that are interdigitally arranged. This arrangement can be prepared by way of a process similar to the one described above by referring to Example 1.
As described above in detail, an electromagnetic actuator according to the invention can be operated at a low power consumption rate to improve the energy efficiency if compared with conventional electromagnetic actuators because of a minimized leakage of magnetic flux. Additionally, since both the stationary member and the movable member of an electromagnetic actuator according to the invention are provided with respective coils and cores, the total number of turns of the cores can be increased to raise the force generated in the electromagnetic actuator.
Furthermore, according to the invention, a reflection type optical scanner showing a large deflection angle and a high energy efficiency and comprising a mirror and an electromagnetic actuator mechanically connected to the mirror can be prepared by micro-machining.
Similarly, according to the invention, a transmission type optical scanner showing a large deflection angle and a high energy efficiency and comprising a lens and an electromagnetic actuator mechanically connected to the lens can be prepared by micromachining.
Number | Date | Country | Kind |
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2000-180907 | Jun 2000 | JP | national |
This application is a division of application Ser. No. 09/871,637 filed Jun. 4, 2001 now U.S. Pat. No. 6,674,350, now allowed.
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Number | Date | Country | |
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20040056741 A1 | Mar 2004 | US |
Number | Date | Country | |
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Parent | 09871637 | Jun 2001 | US |
Child | 10669001 | US |