KR20090007137A - Solenoid - Google Patents

Abstract

A solenoid is provided to generate the same moving force regardless of position of plunger by limiting moving range of plunger within uniform magnetic field. A solenoid comprises a cylinder(150), a core(160), magnets(110,120), and a plunger(140). The core is arranged in a hollow(150) of the cylinder according to length direction, and is made of material capable of magnetizing. The magnets surround the core. N polarity and S polarity are distributed in an inner circumference and an outer circumference of the magnet. The plunger comprises a bobbin(141), a coil(130), a flange(142), and a conduction member(143). The bobbin surrounds the core, and is inserted inside the magnet. The coil surrounds a circumference surface of the bobbin. Electricity is flowed in the coil. The flange is fixed in one end of the bobbin. Both ends of the coil are connected to one end of the conduction member.

Description

Solenoid {Solenoid}

The present invention relates to solenoids utilized in various valves, locks, switches and relays.

The solenoid means a coil wound uniformly in a cylindrical shape having a length longer than the diameter. When a direct current flows through the conductive wire, a magnetic field is formed around the conductive wire to attract the iron core or the plunger to the coil.

1 is a cross-sectional view schematically showing the operation of the conventional solenoid, it will be described with reference to this.

The conventional solenoid 10 is composed of a coil 11 wound around a conductor and a plunger 12 linearly moving in the coil 11. The conductive wire is wound around the circumference of the cylinder 13 having the hollow 14 and fixed in the form of a coil 11, and the plunger 12 is disposed to be movable along the hollow 14.

Referring to the operation of the conventional solenoid 10 described above, as shown in FIG. 1A, when a DC current flows along the coil 11, a magnetic field flowing from left to right around the cylinder 13 is induced. That is, the left side has the north pole and the right side has the south pole.

As a result, the cylinder 13 wound around the coil 11 becomes an electromagnet, and pulls the plunger 12 made of a magnetizable material toward the cylinder 13, and eventually the hollow 14 as shown in Fig. 1 (b). ) Is inserted.

Of course, by placing a carburetor (not shown) to support the plunger 12 to the right side of the plunger 12, when the direct current flow into the coil 11 is blocked and the magnetic force is lost, the carburetor to the plunger 12 It may be pushed out of the cavity 14 and returned to its original position.

On the other hand, the plunger 12 may be a permanent magnet having its own magnetic force in addition to the magnetizable material.

As shown in Fig. 1 (a), the plunger 12, which is a permanent magnet, is inserted into the hollow 14 of the cylinder 13 with the N pole to the right and the S pole to the left, and a direct current is applied to the coil 11. As described above, the right side of the cylinder 13 becomes the S pole and the left side the N pole as described above, so that the plunger 12 is hollowed as shown in FIG. 1 (b) by the attractive force between the cylinder 13 and the plunger 12. 14).

On the other hand, when a direct current flows in the reverse direction to the coil 11, the right side of the cylinder 13 becomes the N pole and the left side the S pole, as opposed to FIG. 1 (a). 13) pushed out.

In other words, when the plunger 12 is a permanent magnet, the moving direction of the plunger 12 can be controlled by simply changing the direction of the direct current flowing through the coil 11.

The solenoid 10 described above is capable of linear movement of the plunger 12 by applying electromagnetic induction, and the force received by the plunger 12 is determined in proportion to the strength of the current and the number of turns per length of the coil 11. do. In addition, when the plunger 12 is a permanent magnet, the force received by the plunger 12 is proportional to the magnetic force of the permanent magnet.

That is, in order to increase the moving force of the plunger 12, the number of turns of the coil 11 must be increased, the strength of the current must be increased, or the magnetic force of the plunger 12 must be increased.

However, the conventional solenoid 10 may move out of the range of the magnetic field induced in the coil 11 because the plunger 12 moves along the cylinder 13 on which the coil 11 is wound, thereby receiving the plunger 12. As the magnetic force changes depending on the position of the plunger 12, the moving force of the plunger 12 is not constant. In addition, although the number of turns of the coil 11 may be increased to increase the moving force of the plunger 12, there is a limit because the number of turns cannot be increased indefinitely due to spatial limitations.

On the other hand, the plunger 12 may be a permanent magnet to increase the moving force, but to increase the magnetic force of the plunger 12 for the purpose of improving the moving force, the density must be increased, so that the load of the plunger 12 eventually increases. There was a difficulty in increasing the mobility efficiently.

In addition, the conventional solenoid 10 may increase the number of turns of the coil 11, increase the strength of the current, or increase the magnetic force of the plunger 12, thereby increasing the moving force of the plunger 12. Since 12 moves out of the range of the magnetic field of the coil 11 during its movement, there is a problem that the operation of the plunger 12 is not uniform.

As a result, the conventional solenoid 10 could not be utilized for a job requiring a large moving force and a precise operation.

Accordingly, the present invention has been invented to solve the above problems, the plunger can operate at a constant speed irrespective of the position while having a relatively large moving force, the solenoid of the solenoid that can be used in the operation requiring precise operation Provision is a technical task.

The present invention to achieve the above technical problem,

Cylinder 150;

A core 160 of magnetizable material which is fixed to the hollow 151 of the cylinder 150 in the longitudinal direction;

Magnets (110, 120) having a polarity (N, S) is distributed to the inner circumference and the outer circumference, respectively, while surrounding the core 160 spaced apart; And

The plunger 140 includes a bobbin 141 that is movably fitted into the magnets 110 and 120 while surrounding the core 160, and a coil 130 that surrounds the circumferential surface of the bobbin 141 and flows electricity. Solenoid consisting of.

According to the present invention as described above, by placing the magnet in a fixed cylinder instead of the moving plunger, even if the density of the magnet to increase the magnetic force to solve the problem of increasing the load of the plunger, the movement range of the plunger By limiting it to a uniform magnetic field, the same movement force is generated regardless of the position of the plunger, so that it can be applied to a job or an apparatus requiring precise motion.

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

Figure 2 is an exploded perspective view of the solenoid according to the present invention, will be described with reference to this.

The solenoid 100 according to the present invention is a cylinder 150 having a hollow 151, a core 160 fixedly disposed along the hollow 151, and a core 160 disposed along an inner surface of the hollow 151. Magnets 110 and 120 spaced apart from each other, and a plunger 140 that is movably inserted along the longitudinal direction of the hollow 151.

At this time, the plunger 140 includes a bobbin 141, and the coil 130 is wound around the circumferential surface of the bobbin 141, so that the coil 130 is plunger 140 unlike the conventional solenoid 100. And moves along the cylinder 150.

Meanwhile, magnets 110 and 120 are inserted into the hollow 151 of the cylinder 150 to cover the inner surface of the hollow 151. In the embodiment according to the present invention, the hollow 151 is circular, and the first and second magnets 110 and 120 are curved to closely contact the inner surface of the hollow 151 having a curved surface, so that the core 160 is centered. Are arranged opposite to each other.

Here, the magnets 110 and 120 are illustrated and described as being two permanent magnets of the first magnet 110 and the second magnet 120, but are not limited thereto, and three or more magnets may be formed of the hollow 151. It may be arranged along the inner surface.

On the other hand, the core 160 is installed in the center of the first cover 170 is fixed to one side end of the cylinder 150. At this time, the core 160 is located at its center along the longitudinal direction of the hollow 151 as described above.

The core 160 is a magnetizable material, and is magnetized by the first and second magnets 110 and 120 to have polarity.

3 is a diagram illustrating an example of distribution of magnetic poles by a magnet, which will be described with reference to the drawing.

The first and second magnets 110 and 120 built into the hollow 151 have an inner circumferential portion at the S pole and an outer circumferential portion at the N pole. Therefore, the outer circumferential surfaces of the first and second magnets 110 and 120 are tightly fixed to the inner surface of the hollow by repulsive force (repulsive force).

Meanwhile, the core 160 is magnetized to the N pole due to the S pole, which is the polarity of the inner circumference of the first and second magnets 110 and 120. As a result, a magnetic field is formed between the first and second magnets 110 and 120 and the core 160, and the direction thereof is from the core 160 of the N pole to the inner circumference of the first and second magnets 110 and 120 of the S pole. Is headed.

The cylinder 150 serves to shield the above-described magnetic field in the hollow 151, thereby minimizing the dispersion and disappearance of the magnetic field generated in the first and second magnets 110 and 120 to the outside.

Subsequently, the plunger 140 may include a bobbin 141 and a coil 130 that wraps around the circumferential surface of the bobbin 141, and a flange 142 may be fixed to one end of the bobbin 141. . The flange 142 is a conductive member 143 for supplying a DC current to the coil 130 is wired, and correspondingly, even if the plunger 140 is inserted into the hollow cylinder 151, the conductive member ( A groove 152 is formed to open the hollow 151 so that the 143 can be drawn out. The groove 152 shows the movement of the plunger inserted into the cylinder of the solenoid according to the present invention. As shown in the perspective view, the cutout is formed in a length corresponding to the moving range of the plunger 140 so that the conducting member 143 does not interfere with the movement of the plunger 140.

On the other hand, since the bobbin 141 should be able to move with the core 160 to be movable, it should be a hollow tubular shape so that the core 160 can be inserted.

A second cover 180 may be covered and fixed to the other end of the cylinder 150.

The second cover 180 may be further included in order to limit the moving distance of the plunger 140, when the second cover 180 is provided so that the movement of the plunger 140 can be transmitted to the outside 140 may include a withdrawal stand 144. Therefore, the second cover 180 should have a withdrawal groove 181 through which the withdrawal table 144 is movable.

The drawing numbers "153", "171", and "182", which are not described, are drawn out of the coupling grooves formed in the cylinder 150, the first cover 170, and the second cover 180, respectively. The fastening members (not shown) of the cylinder 150, the first cover 170 and the second cover 180 is tightly coupled to each other while being fitted into the fastening grooves 153, 171, 182.

5 is a cross-sectional view showing an operation of the solenoid according to the present invention, will be described with reference to this.

In the solenoid 100 according to the present invention, as described above, the first and second magnets 110 and 120 are disposed on the inner surface of the hollow hole 151 of the cylinder 150, and the core 160 is located at the center of the hollow 151. ) Is positioned, and the plunger 140 is movably inserted between the first and second magnets 110 and 120 and the core 160.

In this case, the core 160 is magnetized to the N pole, and the inner circumference of the first and second magnets 110 and 120 facing the core 160 is the S pole, so that the magnetic field is formed around the core 160. To face the first and second magnets 110 and 120.

On the other hand, as shown in Figure 5 (a), when a DC current flows in the coil 130, according to the Fleming's left hand law, the plunger 140 is moved to the left by a force (see Figure 5 (b)). Of course, if the direction of the direct current flowing in the coil 130 in the state of Figure 5 (b) to reverse the plunger 140 will move to the right by force.

Subsequently, the solenoid 100 according to the present invention does not depart from the range in which the first and second magnets 110 and 120 and the core 160 are positioned even when the plunger 140 moves in the coil 130 through which the DC current flows. .

Referring to FIG. 5, even when the plunger 140 is positioned at the rightmost side of the hollow 151 or at the leftmost side of the hollow 151 as shown in FIG. 5B, as shown in FIG. ) Are both ends of the first cover 170 and the second cover 180, respectively, so that the movement range of the coil 130 is limited to the range where the first and second magnets 110 and 120 and the core 160 are located. do.

As a result, since the solenoid 100 according to the present invention is always moved by a force in a uniform magnetic field regardless of the position of the plunger 140, the plunger 140 does not change the movement force according to the position to precise operation Can be utilized.

1 is a cross-sectional view schematically showing the operation of the conventional solenoid,

2 is an exploded perspective view showing a solenoid according to the present invention,

3 is a diagram showing an example of distribution of magnetic poles by a magnet;

Figure 4 is a perspective view showing the movement of the plunger inserted into the cylinder of the solenoid according to the present invention,

5 is a cross-sectional view showing the operation of the solenoid according to the present invention.

-Explanation of terms for main parts of attached drawings-

100; Solenoids 110, 120; 1st, 2nd magnet

130; Coil 140; plunger

141; Bobbin 142; flange

143; Conducting member 144; Withdrawal stand

150; Cylinder 151; Hollow

152; Home 153; Fastening groove

160; Core 170; First cover

180; Second cover 181; Withdrawal Home

Claims (6)

Cylinder 150; A core 160 of magnetizable material which is fixed to the hollow 151 of the cylinder 150 in the longitudinal direction; Magnets (110, 120) having a polarity (N, S) is distributed to the inner circumference and the outer circumference, respectively, while surrounding the core 160 spaced apart; And The plunger 140 includes a bobbin 141 that is movably fitted into the magnets 110 and 120 while surrounding the core 160, and a coil 130 that surrounds the circumferential surface of the bobbin 141 and flows electricity. ; Solenoid, characterized in that consisting of. The method of claim 1, Solenoid, characterized in that the moving range of the coil 130 is within the range wrapped by the magnet (110, 120). The method of claim 1, wherein the plunger 140 A flange 142 is fixed to one end of the bobbin 141, and both ends of the coil 130 are electrically connected to one end disposed on the flange 142, and the other end further includes a conducting member 143 drawn out. Solenoid characterized in that. The method of claim 3, wherein The cylinder 150 is a solenoid, characterized in that the groove 152 through which the conducting member 143 is formed so that the other end of the conducting member 143 does not interfere when the plunger 140 is moved. The method of claim 1, The magnets (110, 120) are two or more disposed so as to face each other around the core (160), the solenoid, characterized in that tightly fixed to the inner surface of the hollow 151 by the repulsive force. The method according to any one of claims 1 to 5, Both ends of the cylinder 150 are closed by the first cover 170 and the second cover 180 having the withdrawal groove 181, respectively, and one end of the plunger 140 penetrates the withdrawal groove 181. Solenoid, characterized in that the drawer 144 is configured.

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