KR20080019150A - Electromagnet piston compressor - Google Patents

Abstract

An electromagnetic piston compressor is provided to reciprocate the electromagnetic piston to an intended direction by simultaneous attraction and repulsion on the opposite sides of the electromagnetic piston when DC power is supplied to a coil. An electromagnetic piston compressor comprises an electromagnetic piston(8) disposed between an upper permanent magnet(1) and a lower permanent magnet(2). A DC power supplied to the electromagnetic piston creates reciprocate the electromagnetic piston by attraction and repulsive force exerting on the opposite sides of the electromagnetic piston at the same time.

Description

Electromagnet piston compressor {Electromagnet piston compressor}

1 is a basic drawing of an electromagnet piston compressor.

Lead wire 1 (13) and lead wire 2 (14) are connected to a coil installed in electromagnet piston 8 via a central axis (7) fixed to electromagnet piston (8).

When the + pole on the leading wire 1 (13), and the-pole flows on the leading wire 2 (14), when the electromagnet piston (8) at the top of the N pole and the bottom of the S pole to form the S pole, the repulsive force is formed with the upper permanent magnet (1), the lower Manpower is formed with the permanent magnet (2). At this time, the electromagnet piston 8 moves downward.

When the positive pole flows on the lead wire 1 (13) and the positive pole flows on the lead wire 2 (14), the electromagnet piston 8 forms an attraction force with the upper permanent magnet 1 when the upper pole of the S pole forms the N pole. The lower permanent magnet (2) is formed with a repulsive force. At this time, the piston 8 moves up.

② FIG. 2 is an application drawing of FIG. 1 and is replaced with upper electromagnet 25 and lower electromagnet 26 in place of upper permanent magnet 1 and lower permanent magnet 2 of FIG. Is the same as in Figure 1,

3 is an application drawing of FIG. 2, in which the electromagnet piston 8 is changed to a permanent magnet piston 31, and the basic operation principle is the same as that of FIG.

4 is a cross-sectional view of the upper intake valve (3), the upper discharge valve (4).

5 is a detailed view of the upper intake valve (3).

In general, the compression principle of the compressor converts the rotational motion of the motor into a reciprocating motion of the piston, thereby causing problems such as vibration, heat generation of the motor, noise of the motor, and vibration.

When the DC power enters the coil installed in the electromagnet piston (8), the electromagnet piston (8) has the permanent magnets at both ends and the attraction force on the opposite side, while the repulsive force acts at the same time, so that the electromagnet piston (8) moves in the direction predicted. The central axis 7 fixed to the kanda and the electromagnet piston 8 presses the switches 9, 10, 11, and 12 while moving up and down like the electromagnet piston 8. At this time, the electromagnetic sides 3, 4, 5, and 6 are opened and closed according to the signals of the switches 9, 10, 11, and 12, respectively.

1) How it works

① Description of FIG.

When the + pole enters the lead wire 1 (13) and the-pole enters the lead wire 14, the S pole is formed at the upper end of the N pole and at the lower end of the piston 8. At this time, the upper permanent magnet (1) and the repulsive force is formed and the lower permanent magnet (2) is formed of attractive force. The electromagnet piston 8 and the central axis 7 start the downward movement together, and the central axis 7 reaches the lower discharge switch 12 which is the lowest end point. The lower discharge switch 12 sends a direct current electric current to the lower discharge electromagnetic valve 6 so that the lower discharge valve 6 is opened.

Then, when the negative pole enters the lead wire 1 (13) and the positive pole enters the lead wire 14, the upper end of the electromagnet piston 8 is formed with the north pole of the S pole. At this time, the upper permanent magnet (1) and the attraction is formed and the lower permanent magnet (2) is formed with repulsive force. The electromagnet piston 8 and the central axis 7 start the upward movement together. At this time, the lower exhaust electron side 6 is closed and the upper intake electron side 3 is closed and the lower intake electron side 5 is opened at the moment when the central axis 7 leaves the lower intake switch 10. When the central axis 7 reaches the uppermost point, it reaches the upper discharge switch (11). The upper discharge switch 11 sends a direct current electric current to the upper discharge electron valve 4 so that the upper discharge valve 4 is opened.

When the positive pole enters the lead wire 1 (13) and the negative pole enters the lead wire 14, the upper end of the electromagnet piston 8 is formed at the lower end of the N pole. At this time, the upper permanent magnet (1) forms a repulsive force, and the lower permanent magnet (2) is formed a attraction force. The electromagnet piston 8 starts the lowering movement. At this time, the upper exhaust electron valve 4 is closed and the lower intake electron valve 5 is closed and the upper intake electron valve 3 is opened at the moment when the central shaft 7 leaves the upper intake switch 9.

The piston movement is repeated in this order.

② Figure 2.

The difference from FIG. 1 is that the upper electromagnet 25 is used in place of the upper permanent magnet 1, and the lower electromagnet 26 is used in place of the lower permanent magnet 2.

When the positive pole enters the lead wire 5 (27) and the negative pole enters the lead wire 6 (28) as the upper electromagnet 25, the upper electromagnet 25 forms the N pole in the direction of the electromagnet piston 8.

When the positive pole enters the lead wire 7 (29) and the negative pole enters the lead wire 8 (30) as the lower electromagnet 26, the lower electromagnet 26 forms the N pole in the direction of the electromagnet piston 8.

The other part is the same as that of FIG.

 ③ Explanation of the third.

The difference from FIG. 2 is that the electromagnet piston 8 is changed to the permanent magnet piston 31.

The permanent magnet piston 31 has the upper end of the N pole and the lower end of the S pole. At this time, the + pole enters the lead wire 5 (28) of the upper electromagnet 25 and the negative pole enters the lead wire 6 (29). Numeral 25 forms an N pole in the direction of the permanent magnet piston 31. At this time, the permanent magnet piston 31 and the upper electromagnet 25 forms a repulsive force.

At this time, when the + pole enters the lead wire 7 (29) of the opposite lower electromagnet 26 and the-pole enters the lead wire 8 (30), the lower permanent magnet 26 forms the N pole in the direction of the permanent magnet piston (31). At this time, the permanent magnet piston 25 and the lower electromagnet 26 forms an attractive force. At this time, the permanent magnet piston 31 is moved to the lower permanent magnet (26).

The permanent magnet piston 31 starts the downward movement and the permanent magnet center axis 31 reaches the lower discharge switch 12 which is the lowest end point. The lower discharge switch 12 sends a direct current electric current to the lower discharge electromagnetic valve 6 so that the lower discharge valve 6 is opened.

At this time, when the negative pole enters the lead wire 5 (28) of the upper electromagnet 25 and the positive pole enters the lead wire 6 (29), the upper permanent magnet 25 forms the S pole toward the permanent magnet piston 31. At this time, the permanent magnet piston 31 and the upper electromagnet 25 forms an attractive force.

At this time, when the negative pole enters the lead wire 7 (29) of the opposite lower electromagnet 26 and the positive pole enters the lead wire 8 (30), the lower permanent magnet 26 forms the S pole toward the permanent magnet piston 31. At this time, the permanent magnet piston 25 and the lower electromagnet 26 forms a repulsive force. At this time, the permanent magnet piston 31 is moved toward the upper permanent magnet (25).

At this time, the lower discharge electron valve 6 is closed and the upper magnetic intake electronic surface 3 is closed and the lower intake electron valve 5 is opened at the moment when the permanent magnet center shaft 31 leaves the lower intake switch 10. When the permanent magnet center shaft 31 reaches the uppermost point, it reaches the upper discharge switch (11). The upper discharge switch 11 sends a direct current electric current to the upper discharge electron valve 4 so that the upper discharge valve 4 is opened.

When the pole of the direct current power source which enters the upper electromagnet 25 and the lower electromagnet 26 enters again, the permanent magnet piston 25 moves toward the lower electromagnet 26.

In this way, the permanent magnet piston 31 repeats the up and down movement.

2) Electron actuation principle.

The structural feature of this solenoid valve ensures airtightness because the moving parts are all inside.

The structure and operation of the intake valve and the discharge valve are the same, and when the positive pole flows in the lead wire 3 (17) and the negative pole flows in the lead wire 4 (18), the valve electromagnet 16 forms a magnetic force. At this time, the valve permanent magnet 21 and the attraction force on the electromagnet side of the valve 15 is formed. The valve permanent magnet 21 moves toward the valve electromagnet 16 along the electromagnetic variation center shaft 24. In this case, since the valve permanent magnet 21 and the valve 15 are coupled to each other, the valve 15 is moved together with the valve permanent magnet 21 to open the valve. At this time, in order to prevent the impingement of the valve permanent magnet (21) and the valve electromagnet (16) there is an open coil spring (16). Current is cut off. At this time, the magnetic force is lost and the valve 15 is closed by the restoring force of the opening coil spring 16. The closing spring 20 absorbs the shock to reduce the closing shock.

By converting electrical energy into straight motion, energy efficiency is good, and it can reduce problems such as vibration, noise, and heat generation.

In one movement, one side of the intake is compressed at the same time, twice as efficient.

Attraction is applied to one side of the piston, while on the other side, the repulsive force acts simultaneously to increase the motility of the piston.

Claims (3)

The electromagnet piston (8) is located between the upper permanent magnet (1) and the lower permanent magnet (2), and when the direct current power is supplied to the electromagnet piston (8) between the upper permanent magnet (1) and the lower permanent magnet (2) To make the reciprocating motion of the electromagnet piston 8 by the force of attraction and repulsive force. When the electromagnet piston 8 is located between the upper electromagnet 25 and the lower electromagnet 26 and the DC power enters the electromagnet piston 8, the upper electromagnet 25 and the lower electromagnet 26, To make the reciprocating motion of the electromagnet piston 8 by force. The permanent magnet piston 31 is located between the upper electromagnet 25 and the lower electromagnet 26, and when the direct current power enters the upper electromagnet 25 and the lower electromagnet 26, the permanent magnet piston is formed by the attraction force and the repulsive force. To make the reciprocating motion of (31).

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