KR19980084959A - Molten metal flow meter using room temperature permanent magnet - Google Patents

Abstract

The present invention relates to a molten metal flowmeter using a room temperature permanent magnet, the object of which is to facilitate the manufacture of a permanent magnet flowmeter for measuring the flow rate of the molten metal or conductive fluid, the room temperature magnet and ordinary iron, pure iron or pure metal or paramagnetic It is to provide a molten metal flow meter using a room temperature permanent magnet to maintain a constant magnetic flux at all times by reducing the magnetic flux variation during manufacturing by using a magnetic furnace composed of a material.

The present invention provides a permanent magnet flowmeter for measuring the flow rate of molten metal or conductive fluid; The permanent magnet flow meter includes a permanent magnet group formed of a plurality of identical permanent magnets; A passage connecting the permanent magnet group; A magnet case for fixing the permanent magnet group and the magnetic path; A terminal rod mounted to the end of the magnet case; Pole pieces respectively mounted at ends of the terminal rods; The permanent magnet flow meter is provided on one side to provide a molten metal flow meter using a room temperature permanent magnet consisting of a cooling fin (PIN) that emits radiant heat or conductive heat when high-temperature radiant heat strongly affects the furnace.

Description

Molten metal flow meter using room temperature permanent magnet

The present invention relates to a molten metal flowmeter using a room temperature permanent magnet, and in particular, a room temperature permanent magnet for measuring the flow rate of a molten metal or a conductive fluid using a magnetic furnace formed of a material of room temperature and ordinary iron, pure iron, or pure metal or paramagnetic material. It relates to a molten metal flowmeter using.

In general, the permanent magnet flowmeters that have been commercialized so far use molten metal or certain fluids in a magnetic field, and use them at high temperatures in such a way as to measure eddy currents by Fleming's left-hand law in the vertical direction of the flowing fluid. It is manufactured by using ALNICO series permanent magnet.

Conventional commercialized devices were used as magnets themselves, and they were used as castings, so they had to be manufactured using materials of high-temperature magnets at high temperatures, and using isotropic magnets when producing castings.

Also, in the case of casting, the casting is magnetized and then the potato effect is used to reduce the magnetic force to maintain a proper magnetic force. At this time, in order to have a desired magnetic force, several potatoes have to be applied.

In addition, when the gyro is made of cast permanent magnets, there are various problems such as dismantling after making the gyro, or the self-maintaining force is destroyed or greatly changed when damaged.

The present invention has been made in consideration of the above problems, and an object thereof is to facilitate the manufacture of a permanent magnet flowmeter for recovering the flow rate of molten metal or conductive fluid, and to allow the use of room temperature magnets and ordinary iron, pure iron or pure It is to provide a molten metal flowmeter using a room temperature permanent magnet to reduce the production cost by using a magnetic furnace made of materials and to maintain a constant magnetic flux at all times by reducing the magnetic flux variation during manufacturing.

The present invention provides a permanent magnet flowmeter for measuring the flow rate of molten metal or conductive fluid; The permanent magnet flow meter includes a permanent magnet group formed of a plurality of identical permanent magnets; A passage connecting the permanent magnet group; A magnet case for fixing the permanent magnet group and the magnetic path; A terminal rod mounted to the end of the magnet case; Pole pieces respectively mounted at ends of the terminal rods; The permanent magnet flow meter is provided on one side to provide a molten metal flow meter using a room temperature permanent magnet consisting of a cooling fin (PIN) that emits radiant heat or conductive heat when high-temperature radiant heat strongly affects the furnace.

1 is a permanent magnet flow meter showing a configuration according to the present invention

Figure 2 is an elliptical permanent magnet flowmeter showing a configuration according to the present invention

3 is a circular permanent magnet flowmeter showing a configuration according to the present invention

Figure 4 is a permanent magnet flow meter formed of a plurality of arrays of magnet groups according to the present invention

* Description of the symbols for the main parts of the drawings *

(1): annular pipe (or annular tube) (2A, 2B, 2C): room temperature permanent magnet

(3): PIECE (PIECE) (4A, 4B): Pole piece

(5): lead wire (6): terminal ruler fixing pin

(7A, 7B): Terminal Jar (8): Magnetic Case (CASE)

(9): magnet case holder (10): support shelf

(11): magnet case clamp 12: magnet case hanger (HANGER)

(13A, 13B): Pole contact surface 14: Bolt hole (HOLE)

(15): cooling fin

Figure 1 shows a permanent magnet flowmeter showing a configuration according to the present invention, a fluid flowing annular pipe (or annular tube), a room temperature permanent magnet, a magneto of the paramagnetic body, and a magnetic pole mounted to the end of the magnetic furnace and It is composed of a cooling device for preventing the transfer of high-temperature radiant heat to the magnet or the magnetic path to the room temperature permanent magnet and the magnetic path to fix the magnetic path.

The room temperature permanent magnets 2A, 2B, and 2C are disc-shaped ceramic magnets (for example, Nd-based or Sm-based magnets) of the same size, and are stacked in a plurality so as to control the strength of the magnetic force. The magnet pieces are attached so that the number of magnets can be made into one or more magnet groups.

The permanent magnets 2A, 2B and 2C are inserted into the middle of the gyro and are made of magnets. The permanent magnets 2A, 2B and 2C are connected between the permanent magnets 2A, 2B and 2C. (3) must be present.

The length of the furnace is changed depending on the number of annular pipes (1) for measuring the flow of the fluid or the number of permanent magnets (2C) group located on the ground. The magnetic poles (7A, 7B) are changed depending on the number of magnet groups. The ruler piece 3 which is located at the center of the ruler does not change.

In addition, the permanent magnet (2C) group located in the center of the magnet should be stacked with the magnet pieces according to the thickness of the pipe for measuring the fluid.In order to maintain the correct distance, instead of the magnet piece in the middle of the permanent magnet (2C) group, 3A must be made and inserted. In this way, the length of the magnetic path may be changed by inserting the magneto piece 3A in the center of the permanent magnet group 2C according to the size of the pipe.However, the length of the terminal magnets 7A and 7B may be adjusted to suit the pipe spacing. It may be. In some cases, the length of the slaw may be adjusted by adjusting the lengths of the pole pieces 4A and 4B.

The terminal pieces 7A and 7B are equipped with pole pieces 4A and 4B, and serve to balance the direction of the magnetic flux. When the pole pieces 4A and 4B are attached, the surface of the end grooves 7A and 7B and the contact surface of the pole pieces 4A and 4B should be processed so that there is no space on the contact surface, and they are brought into contact with an adhesive.

The magnet case 8 is to prevent the permanent magnet and the gyro from moving after assembly, separated in the up and down direction of the ground, coupled by the case hanger 12 and the case clamp 11, which is coupled to one side A fixing pin 6 is attached to the terminal ruler to hold the terminal jars 7A and 7B. The terminal ruler fixing pin 6 has a protrusion at the end of the magnet case 8 so that when the magnet case 8 is closed, the protrusion is inserted into the groove of the terminal jar so that the terminal jars 7A and 7B do not move.

In addition, at the bottom of the magnet case 8, the magnet case pedestal 9 and the support shelf 10 are integrally coupled so that they can be attached to other structures or placed upright.

The size of the disks of the permanent magnets 2A, 2B, and 2C is the same size, but in some cases, magnet pieces of the same size and different sizes may be combined to form a magnet group. Further, a magnet group in which the diameter of the magnet gradually decreases from the center of the magnet toward the end may be formed.

The shape of the magnet may be deformed according to the structure of the entire magnet, that is, the shape of the magnet is changed to be almost similar to the direction of the magnetic flux that varies according to the shape (square shape, ellipse, circle).

In addition, the present invention is manufactured using a room temperature magnet, but each device of the present invention must be equipped with a cooling function because it is mainly used at high temperatures. Low heat transfer of heat to magnets and magnets is no problem, but when used at very high temperatures, a cooling device is required. In other words, if the magnet is kept at a high temperature, it does not matter if the magnet is below the Curie point, but if it exceeds the Curie point, a cooling device should be installed.

The cooling apparatus can be divided into installing cooling fins and installing cooling jackets, and the use of the cooling medium should be selected to be harmless or less harmful to the process. Most suitable is the cooling by natural convection.

The cooling fin structure of the cooling device can be of helical shape and disc shape, and the helical and disc shape can be further split to make the cooling surface wider. The installation position of the cooling fins should be installed away from the ends of the poles so that they do not receive direct radiant heat from the hot fluid tube. In addition, the size of the cooling fins may be increased from the magnetic pole to the larger and may be the same size. Cooling fins may be installed on the magnetic poles at the ends of the poles, or cooling fins may be provided on the magnet and the case holding the magnetic paths. The cooling fins installed in the gyro may be welded to or inserted into the gyro. In addition, the material of the cooling fins should use a weak magnetic material such as aluminum or copper, which has little or no influence on the characteristics of the furnace.

Figure 2 is an elliptical permanent magnet flowmeter showing a configuration according to the present invention, Figure 3 shows a circular permanent magnet flowmeter showing a configuration according to the present invention, a triangular gyro piece disk between the magnet and the magnet located in the curved portion By inserting the round shape of the gyro to form an elliptical and circular permanent magnet flow meter.

The disk size of the magnet used at this time may be a magnet of the same size, or may be a magnet of a different size. Of course, when using a magnet of a different size can be gradually reduced from the center of the magnet to the end of the magnet, and in some cases, the magnet can be stacked to the same size, and then gradually reduced in size to use. In addition, the thickness of a disk uses what is convenient for use.

4 shows a permanent magnet flowmeter in which the magnet group is formed in a plurality of arrangements according to the present invention. When the diameter of the pipe is large and a large magnet is required, the magnet groups 2A and 2B are formed in four arrangements. To adjust the pipe spacing with the pole pieces 4A and 4B, and to adjust the length of the end jaws 7A and 7B of the gyro having a circular cross section of a size to accommodate all the cross sections of the arranged magnets. In some cases, the length of the gyro 3 may be adjusted. In addition, the shape of the said magnetic path may change with the shape of the arrangement | positioning of the magnet group 2A, 2B.

As described above, the present invention uses a room temperature magnet which can easily obtain a magnet that creates a magnetic field in a flow meter, and by combining the magnets properly, the magnetic force of the magnet can be easily adjusted. Large quantities can be produced and manufacturing costs can be reduced.

In addition, the present invention is easy to assemble and dismantle, as well as to change the magnetic flux in the fluctuation of the flow rate range of the fluid or the diameter size of the fluid pipe.

Claims (17)

A permanent magnet flow meter for measuring the flow rate of molten metal or conductive fluid; The permanent magnet flow meter is a permanent magnet group formed of a plurality of identical permanent magnets, A conduit connecting the permanent magnet group, A terminal rod mounted to the end of the magnet case, Pole pieces respectively attached to the ends of the terminal; A magnet case for fixing the permanent magnet group and the magnetic path; Mounted on one side of the permanent magnet flow meter is a molten metal flow meter using a room temperature permanent magnet, characterized in that consisting of a cooling fin (PIN) that emits radiant heat or conductive heat when high-temperature radiant heat strongly affects the path. The method of claim 1; The permanent magnet is a molten metal flow meter using a permanent magnet at room temperature, characterized in that using a disk-type permanent magnet. The method of claim 1; The permanent magnet is a molten metal flow meter using a permanent magnet at room temperature, characterized in that using a permanent magnet at room temperature, or a magnet made of a ceramic-based material at room temperature. The method of claim 1; Permanent magnets at room temperature, characterized in that between the magnet and the magnet of the permanent magnet group can be produced in the form of a magneto straight or oval or circular shape by inserting a disk of the same size as a permanent magnet or a disk-shaped disk of a triangular shape Used molten metal flow meter. The method of claim 1; A molten metal flow meter using a room temperature permanent magnet, characterized in that the length of the magnetic path can be adjusted by inserting a magnetic path between the magnet and the magnet of the permanent magnet group. The method of claim 1; A molten metal flow meter using a room temperature permanent magnet, characterized in that the magnetic force of the magnet can be easily adjusted by adjusting the number of permanent magnets of the permanent magnet group formed of the plurality of permanent magnets. The method of claim 1; A molten metal flow meter using a room temperature permanent magnet, characterized in that the strength of the magnet can be adjusted by adjusting the size of the permanent magnet of the permanent magnet group formed of a plurality of permanent magnets. The method of claim 1; The permanent magnet is a molten metal flow meter using a permanent magnet at room temperature, characterized in that it can be modified in various forms according to the shape of the magnetic furnace. The method of claim 1; The permanent magnet group is melted using room temperature permanent magnets, characterized in that the diameter of the magnet is gradually reduced from the center of the magnet toward the anode direction, or formed of several magnets of the same size and different magnets. Metal flow meter. The method of claim 1; The cooling fin is formed in a helical shape or a disk shape, and the molten metal flow meter using a permanent magnet at room temperature, characterized in that it is further divided to increase the cooling surface. The method of claim 1; The material of the cooling fin is a molten metal flow meter using a room temperature permanent magnet, characterized in that a material having less influence on the characteristics of the furnace, but using a weak magnetic material such as aluminum (Aluminium) or copper (Copper). The method of claim 1, The cooling fin is a molten metal flow meter using a permanent magnet at room temperature, characterized in that the mounting by welding or inserting into the furnace. The method of claim 1; The cooling fin is installed at the end of the gyro, that is, away from the tube through which the fluid flows, so that radiant heat is reflected directly to the cooling fin from the tube through which the high temperature fluid flows, thereby preventing further heat transfer. Molten metal flow meter. The method of claim 1; A molten metal flow meter using a room temperature permanent magnet, characterized in that to increase the cooling effect by gradually increasing the size of the cooling fin in the direction of the permanent magnet at the end of the furnace. The method of claim 1, A molten metal flow meter using a room temperature permanent magnet, characterized in that the cooling fin is attached to a magnet case for fixing a magnet and a magnet. The method of claim 1; A molten metal flow meter using a permanent magnet at room temperature, characterized in that the arrangement of two or more permanent magnet groups to control the density of the magnetic flux. The method of claim 1; A molten metal flow meter using a permanent magnet at room temperature, characterized in that the magnetic strip is inserted into the array of the permanent magnet group to adjust the length of the magnet group.