KR20060074355A - Moving coil type linear actuator - Google Patents

Abstract

The movable coil type linear actuator of the present invention includes a casing made of a nonmagnetic material; It is disposed in the casing and is a permanent magnet composed of N pole and S pole, and at least two permanent magnets 6a, 6b positioned to face each other at least in the upper and center portions of the casing, and the lower and center portions of the casing face each other. At least two permanent magnets 6c and 6d; It is made of nonmagnetic material and extends so as to be inserted into the space between the permanent magnets 6a and 6b. The coil is wound up to be inserted into the space between the upper coil part and the permanent magnets 6c and 6d. A movable coil part including a lower coil part and a guide part connected to an external driving mechanism; And a current input terminal for supplying current to each of the coils of the upper coil part and the lower coil part, thereby providing a linear actuator having excellent linearity and simple structure.

Description

Moving coil type linear actuator

1 is an internal exploded perspective view of a movable coil type linear actuator of the present invention;

2 is a perspective view showing the overall appearance of the casing of the present invention;

3 is an internal exploded cross-sectional view showing the forward movement action of the actuator of the present invention;

4 is an internal exploded cross-sectional view showing the retraction movement action of the actuator of the present invention; And

5 is an internal exploded cross-sectional view of the actuator of the present invention showing the gap between permanent magnets; And

6 is a configuration diagram schematically showing the principle of arrangement of the coil of the present invention.

The present invention relates to a moving coil type linear actuator.

Recently used linear actuators include piezo type linear actuators, pulse motor driven linear actuators, and proportional electronic linear actuators. Piezo-type linear actuators move smoothly in a small structure and have almost no friction and backlash (moving due to the inertia of the members' engagement), but they are expensive and are used for fine control of the micro and nano domains. Pneumatic systems have disadvantages that are difficult to apply. Pulse motor driven linear actuator has the advantage of simple mechanical structure with little backlash, high precision positioning and easy maintenance due to the control of open loop type. Since it is determined by the support mechanism, there is a disadvantage that an ultra precision assembly technique is required. In addition, the proportional electronic linear actuator has the advantage of satisfactory linearity as a small part structure, high driving force, and linear motion on the urine. have.

In addition, the problems of the prior art actuators are summarized, and the mechanical structure is complicated and the inertia of the mover is large, resulting in a low responsiveness, and increasing the driving force when applied to a pneumatic / hydraulic system while maintaining linearity when manufacturing small size. It has a hard disadvantage.

From this, in order to construct a high energy density magnetic circuit, an auxiliary device and other systems for generating residual magnetic flux must be provided, and a control technique for securing linear driving force for driving a general and general pneumatic / hydraulic system is required. It can be said that the request of the prior art.

Therefore, the present invention has a simple mechanical structure, low inertia of the mover, excellent voice inside, high energy density magnetic circuit configuration, small size and low cost, and can be applied to general pneumatic / hydraulic systems. It is an object to provide a movable coil type linear actuator.

Moving coil type linear actuator of the present invention for achieving the above object is a casing made of a non-magnetic material; It is disposed in the casing and is a permanent magnet composed of N pole and S pole, and at least two permanent magnets 6a, 6b positioned to face each other at least in the upper and center portions of the casing, and the lower and center portions of the casing face each other. At least two permanent magnets 6c and 6d; It is made of nonmagnetic material and extends so as to be inserted into the space between the permanent magnets 6a and 6b. The coil is wound up to be inserted into the space between the upper coil part and the permanent magnets 6c and 6d. A movable coil part including a lower coil part and a guide part connected to an external driving mechanism; And a current input terminal for supplying current to each of the coils of the upper coil portion and the lower coil portion.

Further, the movable coil type linear actuator of the present invention has a core part of the upper, middle, and lower portions for supporting the permanent magnets 6a, 6b, 6c, and 6d, and has a support core made of a magnetic material installed in close contact with the inside of the casing. It further comprises.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is an exploded perspective view of the inside of a movable coil type linear actuator 1 of the present invention. Most of the actuators of the present invention are surrounded by an inverted “c” shaped casing 2 having a front portion 204. As shown in FIG. 2, the casing 2 is manufactured in a substantially rectangular parallelepiped shape in which a guide hole 206 is formed in the center of the front portion 204. The casing 2 of the present invention needs to be made of a nonmagnetic material in operation of the actuator. Over the rear wall 202 of the casing 2 and a substantial portion of the upper and lower walls 200 and 200, a support core made of magnetic material is provided adjacent to these walls. The support core has an inverted “E” shape, which branches from each of the top, middle and bottom points of the support 300 and extends along the casing to the upper core 302, the center core 304 and the lower core 302 ′. A pair of permanent magnets 6a composed of N-pole and S-pole magnets 61a and 62a are disposed at the front lower portion of the upper core 302, and each of the front upper and lower surfaces of the central core 304 is disposed. Also, permanent magnets 6b and 6c each consisting of magnets 61b and 62b; 61c and 62c of the north pole and the south pole are disposed, and the magnets of the north pole and the south pole are formed on the front surface of the lower core 302 '. A pair of permanent magnets 6d consisting of 61d and 62d are arranged, and it is seen that the arrangement of these magnets is vertically symmetrical with respect to the center core 304, which is necessary for coherent and balanced movement of the actuator. will be.

In addition, a pair of terminal portions 51 and 52 for current input are provided through the through hole of the front portion 204 of the casing 2.

 The movable coil part 3 of the actuator 1 of the present invention has an upper coil part 32 and a lower coil part 33 branched into two from the lower end of the cylindrical guide part 31 and the guide part 31. Is made of. The movable coil portion of the present invention is made of a nonmagnetic material. Coils 32 'and 33' are wound around the upper coil portion 32 and the lower coil portion 33, respectively. The upper coil portion 32 is sufficiently inserted into the empty space between the upper core 302 and the central core 304, and the lower coil portion 33 is the empty space between the lower core 302 'and the central core 304. The coil 32 'is opposed to the permanent magnets 6a and 6b by being fully inserted therein, and the coil 33' is opposite to the permanent magnets 6c and 6d. The coil 32 'is connected to the current input terminal 51 by a cable, and the coil 33' is connected to the current input terminal 52 by a cable.

Coils 32 'and 33' of the present invention are shown as being randomly wound on the respective coil portions 32 and 33 in Fig. 1, but as shown in Fig. 6, the (-) terminal at the (+) terminal is shown. Note that Fleming's law can be smoothly followed if it is coiled consistently in one direction, either from the (-) terminal to the (+) terminal.

The movable coil part 3 of the present invention is connected to a pneumatic / hydraulic system (not shown) as a member moving linearly back and forth with an input of electric current, as described later, to impart drive force by the movement thereof.

In addition, a ball bearing 4 is provided around the guide hole 206 of the casing 2 to smoothly guide the linear movement of the movable coil part 3, that is, the front and rear of the guide part 31.

Hereinafter, the operation of the actuator 1 of the present invention will be described with reference to FIGS. 3 and 4. 3 and 4, the coil is not shown for convenience in order to indicate the direction of the current acting on the coil.

In FIG. 3, a positive current is applied to the current input terminal 51, and a negative current is applied to the terminal 52. In FIG. Positive current is supplied to the coil 32 ', and negative current is supplied to the coil 33'. However, since the movable coil portion 3 is made of a nonmagnetic material, as a result of the current not moving along the movable coil portion, as shown in FIG. 3, the positive current flowing through the coil 32 'is shown in FIG. Ascending vertically upward, the current flowing in the coil 33 'falls downward in the vertical direction of the figure. The flow of current that is bridged between the coils 32 '. 33' is indicated by arrow A in the figure.

The magnetic field acts in the direction of the arrow M between the permanent magnets 6a and 6b with the coil 32 'interposed therebetween, and the magnetic field between the permanent magnets 6c and 6d with the coil 33' interposed therebetween. Acts in the direction of the arrow (M ').

Therefore, according to Fleming's left-hand rule, the upper coil portion 32 of the movable coil portion 3 is forced in the left direction as shown by the arrow F1, and the lower coil portion 33 is also like the arrow F2. The force is applied to the left side of the drawing. Since the actuator 1 of the present invention has a vertically symmetrical structure, the magnitudes of the forces F1 and F2 are the same, and thus the movable coil part 3 is linearly supported forward by the ball bearing 4 in a stable and balanced manner. Will move.

Here, after a predetermined time elapses, as shown in FIG. 4, when a negative current is applied to the current input terminal 51 and a positive current is applied to the terminal 52, the left hand law of Fleming is reversed. As a result, the upper coil part 32 receives the force in the right direction of the drawing as shown by the arrow F1 ', and the lower coil part 33 receives the force in the right direction of the drawing as shown by the arrow F2'. Therefore, the movable coil part 3 is linearly moved backward while being supported by the ball bearing 4 in a stable and balanced manner.

In this way, the actuator of the present invention is to change the polarity of the current for a predetermined time to produce a linear motion of the movable part with a coil, and because the operating force is adjusted to be constant, in a mass meter, for example, pneumatic / hydraulic system It is characterized by excellent linear control of pneumatic and hydraulic pressure.

In the actuator of the present invention, the magnitude of the force is affected by the number of turns of the coil, the magnetic permeability of the magnet, the strength of the current, but as shown in FIG. It is greatly affected by the distance (d, d ') between opposing permanent magnets. This is because the strength of the magnetic field is increased or decreased by the size of this gap. Therefore, the actuator of the present invention has an advantage of ensuring a uniform and linear driving force by properly controlling the distances of the gaps d and d '.

As mentioned above, although preferred embodiment of this invention was described, this invention is not limited to an Example, A various change is possible within the technical idea of a claim described below.

The movable coil type linear actuator of the present invention described above allows the working force to be constant even when the actuator moves, so that the pneumatic / hydraulic pressure in the pneumatic / hydraulic system can be efficiently linearly controlled, and the number of parts is reduced by a simple mechanical structure. It does not require an accessory device such as a magnetic circuit or an auxiliary device, and thus has an excellent effect of contributing to cost reduction.

Claims (2)

A movable coil type linear actuator, wherein the actuator is A casing made of a nonmagnetic material; It is disposed in the casing and is a permanent magnet composed of N pole and S pole, and at least two permanent magnets 6a, 6b positioned to face each other at least in the upper and center portions of the casing, and the lower and center portions of the casing face each other. At least two permanent magnets 6c and 6d; It is made of nonmagnetic material and extends so as to be inserted into the space between the permanent magnets 6a and 6b. The coil is wound up to be inserted into the space between the upper coil part and the permanent magnets 6c and 6d. A movable coil part including a lower coil part and a guide part connected to an external driving mechanism; And Current input terminal for supplying current to the coils of the upper coil portion and the lower coil portion Movable coil type linear actuator comprising a. 2. A support core according to claim 1, wherein the support core is made of a magnetic material having upper, center, and lower core portions for supporting the permanent magnets 6a, 6b, 6c, and 6d, and are installed in close contact with the inside of the casing. A movable coil type linear actuator further comprising.

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