KR20100013421A - Coupler for magnet pump - Google Patents

Abstract

PURPOSE: A coupler for a magnet pump is provided to minimize the magnet size or volume by maintaining the torque even with a smaller magnet. CONSTITUTION: A coupler(100) for a magnet pump comprises a shaft(200), a magnet ring(102), a magnet block(104), a plurality of magnets(106), and a covering(108). The shaft is inserted in the hollow of the magnet ring. The magnet ring is made of steel, magnetic material. The magnet block has a hollow polygonal column shape in which the magnet ring is inserted and is made of stainless steel, non-magnetic material. The magnets are attached to the different sides of the magnet block, respectively.

Description

Coupler for magnet pump {COUPLER FOR MAGNET PUMP}

The present invention relates to a coupler for a magnet pump, and more particularly, by using a magnet ring inserted in the center of a coupler used for power transmission of a magnet pump as a general steel material, a magnetic pump does not occur at high temperatures. It is about a coupler.

The magnet pump is designed to rotatably drive the impeller of the pump using the principle of magnet coupling between permanent magnets. The magnet pump is installed at the end of the drive shaft of the impeller located inside the pump housing, and the drive magnet is rotated from the outside. It is a device that drives the impeller by rotating the magnet coupler together.

When the impeller is driven using a magnet coupler, there is no rotational seal for sealing, so there is no risk of leakage, and since there is no direct contact, there is less risk of abrasion or breakage.

1 is a cross-sectional view showing the structure of a magnet pump coupler according to the prior art, Figure 2 is a cross-sectional view showing a magnet arrangement of the coupler.

As shown in the drawing, a magnet coupler of the prior art is provided between a first shaft (or drive shaft) 2 of a drive connected to a power source and a second shaft (or driven shaft) 4 of a driven connected into the fluid pump. In the state that is not directly connected between the two axes to implement the power transmission using the magnetic force of the magnet.

The drive shaft 2 and the driven shaft 4 are located in mutually divided spaces using a housing 6 attached to a fluid pump (not shown) and a spacer 8 attached to the housing 6, in particular The driven shaft 4 is located inside the fluid pump sealed by the housing 6 and a spacer 8 of nonmagnetic material.

Here, the cylindrical holder 10 having a hollow having a predetermined length is installed at the end of the drive shaft 2, and the magnets 10 are equally spaced at the holder 10 by using a plurality of magnet spacers 12. It is placed and mounted. The magnet 14 is installed to have the same polarity toward the inner circumferential surface, which imparts a uniform magnetic force to the object inserted into the hollow of the holder 10.

At the end of the driven shaft 4, a magnet 16 corresponding to the magnet 14 mounted at the end of the drive shaft 2 is arranged.

As shown in FIG. 2, the magnet 16 is arranged such that the magnets 16a have different polarities with respect to the magnets 14 mounted on the holder 10, and the magnets 16a are mounted using the magnet blocks 16b. Can be configured. At this time, the magnet 16a of the driven shaft 4 cooperates with the magnet 14 of the drive shaft 2 to double the magnetic force, whereby the rotational force of the drive shaft 2 is transmitted to the driven shaft 4 efficiently.

The magnet 16a mounted on the driven shaft 4 is fixed by the magnet block 16b, and a magnet ring (not shown) is interposed between the magnet block 16b and the driven shaft 4.

By the way, the temperature of the magnets disposed on the drive shaft 2 and the driven shaft 4 is increased by the heat generated when the pump rotates at a high speed.

Generally, the magnet is at a temperature of 300 ° C. or higher at high speed, and at this temperature, the magnetic force is reduced to 50% or less, so that the rotational force of the drive shaft 2 is not transmitted to the driven shaft 4.

When the magnetic force of the magnet is lowered, the attraction force between the drive shaft 2 and the coupler is weakened, and a slip phenomenon occurs, thereby decreasing the efficiency of the pump. In order to compensate for this problem, magnets are arranged in two rows so as to produce twice the magnetic force required at room temperature. Accordingly, there is a problem due to the cost increase and the volume increase of the coupler.

The present invention for solving the above problems is to provide a magnet pump coupler for making the same attraction force without deterioration of magnetic force by making the magnet ring for fixing the magnet disposed on the driven shaft made of ordinary steel material The purpose.

The present invention devised to solve the above problems is a coupler which is installed at the end of the impeller drive shaft of the magnet pump and synchronized with the rotation of the drive magnet to rotate together, the shaft integrally connected to the impeller drive shaft; A hollow is formed in the center, and the cylindrical magnet ring is fixed to the shaft is inserted into the hollow; Hollow is formed in the center, and the magnet ring of the polygonal pillar shape is fixed to the magnet ring is inserted into the hollow; A plurality of magnets, each of which is fixed to a plurality of outer surfaces of the magnet block, the N poles and the S poles arranged in a radial direction of a circle formed on an imaginary plane perpendicular to the central axis of the shaft; And a cylindrical covering covering the outer surface of the magnet, wherein the magnet block is made of a non-magnetic stainless material, and the magnet ring is made of a magnetic material of magnetic material.

The magnet ring is characterized in that it is made of any one material of S45C or SM45C, which is one of the mechanical structural carbon steel, SS41, which is a general structural rolled steel.

Magnets adjacent to each other is characterized in that the N pole and the S pole are arranged in opposite directions to each other.

According to the present invention, in manufacturing the magnet pump coupler, the size and capacity of the magnet can be minimized, thereby reducing the manufacturing cost, and using only half the size of the magnet can produce the same rotational force as before, so the volume of the coupler is reduced. It works.

Hereinafter, a coupler for a magnet pump (hereinafter referred to as a 'coupler') according to an embodiment of the present invention will be described with reference to the drawings.

Figure 3 is a perspective view showing the structure of a coupler according to an embodiment of the present invention, Figure 4 is an exploded perspective view of the coupler, Figure 5 is a view showing a planar and cross-sectional structure of the coupler.

As shown in Figures 3 to 5, the coupler 100 of the present invention is a device that is installed at the end of the shaft 200 connected to the impeller (not shown) to transmit the rotational force transmitted from the drive shaft to the impeller.

Each of the components constituting the coupler 100 has a hollow cylindrical shape.

At the center of the coupler 100 is a cylindrical magnet ring 102 having a hollow formed in the center thereof.

On the outside of the magnet ring 102 is arranged a magnet block 104 of the hexagonal pillar shape.

Since the diameter of the cylindrical hollow formed in the center of the magnet block 104 is formed almost the same as the outer diameter of the magnet ring 102, the magnet ring 102 is fixed to the inside of the magnet block 104.

The outer surface of the magnet block 104 is divided into six sides, and six magnets 106 are seated one by one on the six outer surfaces. The north pole and the south pole of the magnet 106 are alternately arranged in the circumferential direction of a circle formed on an imaginary plane perpendicular to the central axis of the shaft 200.

This arrangement of the magnets 106 is shown in FIG.

In the present invention, only the case in which the magnet block 104 has a hexagonal pillar shape is described. However, depending on the number of the magnets 106, the magnet block 104 may be a pentagonal pillar, an octagonal pillar, or a polygonal pillar having another shape.

The outer surface of the magnet 106 is covered with a cylindrical covering 108.

The covering 108 serves to prevent the magnet 106 from falling out of the coupler 100.

And the upper and lower surfaces of the covering 108 is attached to the annular wall plate one by one.

The magnet 106 is thus sealed by the covering 108 and the wall plate 110.

The shaft 200 is inserted into the hollow of the magnet block 104 and fixed while contacting the magnet ring 102.

Grooves may be formed on the outer surface for firm fixing of the magnet ring 102 and the magnet block 104, and inserting protrusions may be inserted into the grooves to prevent slippage during rotation.

The length of the magnet ring 106 is about half as short as that of the magnet block 104, the magnet 106, and the covering 108. Therefore, when all the couplers 100 are assembled, the center part is in a state of being slightly entered. The shaft 200 is fitted here and fixed.

In general, the portion constituting the coupler 100 is made of a stainless material that does not rust even when there is moisture, stainless is a nonmagnetic material, there is a characteristic that the magnetization does not occur even if a magnetic force is applied.

By the way, in the present invention, the magnet ring 102 is made of a general steel material which is a magnetic material, and typically S45C (or SM45C), which is one of mechanical structural carbon steel, or SS41, which is a general structural rolled steel, is used.

SS34, SS50, SS55, etc. may be used as the rolled steel.

Since the steel material is a magnetic material, magnetization occurs when the magnets 106 are adjacent to each other to generate magnetic force.

When the magnetic material is used for the middle magnet ring 102, even if high temperature heat is generated by the rotation of the shaft 200, the magnetic force of the magnet 106 inserted into the coupler 100 does not occur. In the case of a coupler of the prior art, a phenomenon in which the magnetic force falls below 50% occurs at a temperature of 300 ° C or more, but such a phenomenon does not occur in the coupler 100 of the present invention.

Therefore, when the pump is operated by using the magnet 106 having a size that can only generate as much magnetic force as necessary at room temperature, since the damage of the magnetic force is small at a high temperature, the installation of an additional magnet 106 is unnecessary.

Although the preferred embodiments of the present invention have been described above with reference to the accompanying drawings, the above-described technical configuration of the present invention may be embodied by those skilled in the art to which the present invention pertains without changing its technical spirit or essential features of the present invention. It will be appreciated that the present invention may be practiced as. Therefore, the above-described embodiments are to be understood as illustrative and not restrictive in all respects, and the scope of the present invention is indicated by the appended claims rather than the detailed description, and the meaning and scope of the claims and All changes or modifications derived from the equivalent concept should be interpreted as being included in the scope of the present invention.

1 is a cross-sectional view showing the structure of a magnet pump coupler according to the prior art.

2 is a cross-sectional view showing a magnet arrangement of the coupler.

Figure 3 is a perspective view showing the structure of a coupler according to an embodiment of the present invention.

4 is an exploded perspective view of a coupler.

5 shows a planar and cross-sectional structure of a coupler.

6 is a cross-sectional view showing an arrangement of the magnets 106.

Claims (3)

As a coupler installed at the end of the impeller drive shaft of the magnet pump and synchronized with the rotation of the drive magnet to rotate together, A shaft integrally connected to the impeller drive shaft; A hollow is formed in the center, and the cylindrical magnet ring is fixed to the shaft is inserted into the hollow; Hollow is formed in the center, and the magnet ring of the polygonal pillar shape is fixed to the magnet ring is inserted into the hollow; A plurality of magnets, each of which is fixed to a plurality of outer surfaces of the magnet block, the N poles and the S poles arranged in a radial direction of a circle formed on an imaginary plane perpendicular to the central axis of the shaft; Includes; cylindrical covering surrounding the outer surface of the magnet; The magnet block is made of a non-magnetic stainless material, The magnet ring is a magnetic pump coupler, characterized in that the magnetic material is made of steel. The method of claim 1, The magnet ring is a coupler for a magnet pump, characterized in that made of any one material of S45C or SM45C, which is one of the mechanical structural carbon steel, SS41, which is a general structural rolled steel. The method of claim 2, Magnets adjacent to each other is characterized in that the N pole and the S pole are arranged in opposite directions to each other, magnet pump coupler.

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