KR102079024B1 - Magnetic Field Station, Insert Assembly, Mount assembly and 2-Axis Magnetic Generating Equipment Including Thereof - Google Patents

Abstract

The present invention relates to a two-axis magnetism generation equipment. According to the present invention, the two-axis magnetism generation equipment comprises: a magnetic field station wherein a first N magnetic pole body capable of forming an N pole and a first S magnetic pole body capable of forming an S pole are disposed by facing each other on a virtual first axis at regular intervals; and an insert assembly wherein a Helmholtz coil is arranged, which is configured by a first insert coil and a second insert coil, and which can be arranged in or removed from the magnetic field station. The insert assembly is arranged at a position between the first N magnetic pole body and the first S magnetic pole body of the magnetic field station to allow a second axis, which is the central axis of the Helmholtz coil of the insert assembly, to vertically cross the first axis. Accordingly, the present invention is able to form a magnetic field of a greater strength than that of the conventional two-axis magnetism forming apparatus, and to easily upgrade the conventional one-axis magnetism forming apparatus into a two-axis magnetism forming apparatus.

Description

Magnetic Field Station, Insert Assembly, Mount assembly and 2-Axis Magnetic Generating Equipment Including Thereof

The present invention relates to a measuring device for detecting the electromagnetic properties of a sample affected by an external magnetic field, and more specifically, an electron represented by a sample when a magnetic field is formed in two-axis directions perpendicular to each other. It relates to a two-axis magnetic forming equipment to grasp the miracle characteristics.

Today, the effects of the development and dissemination of various devices using various types of electromagnetic devices greatly enhance the convenience of human life. In order to develop various kinds of electronic devices that enhance the convenience of human life, research and development of the electromagnetic characteristics of devices used in devices are essential.

In order to study the electromagnetic properties of device samples, magnetic forming devices equipped with electromagnets capable of forming a considerably high magnetic field are frequently used. 1 schematically shows an exemplary form of an electromagnetic property detecting device according to the prior art.

In the conventional magnetic forming apparatus as shown in (a) of FIG. 1, the N-pole 11 is formed on one side and the S-pole 12 is formed on the other side as a single-axis magnetic forming apparatus 10. Then, a sample is placed between these two stimuli and the magnetic properties are measured. As described above, since the two electromagnets 11 and 12 that form a magnetic field lie on one axis, it can be called a one-axis magnetic forming device.

Meanwhile, in FIG. 1 (b) and (c), a biaxial magnetic forming apparatus is schematically illustrated. The two-axis magnetic forming device 20 forms a magnetic field in one axis while simultaneously forming a magnetic field in a direction perpendicular to the one axis to measure the electromagnetic characteristics of the device.

In the prior art, the single-axis magnetic forming apparatus 10 and the two-axis magnetic forming apparatus 20 were separately manufactured and used, and as the single-axis magnetic forming apparatus 10, orthogonal to each other like the two-axis magnetic forming apparatus 20. The magnetism could not be formed on the biaxial axis.

Therefore, the two-axis magnetic forming device 20 had to be newly used and used for research activities. Furthermore, these magnetic forming devices 10 and 20 must be able to form a very strong magnetic force. In comparison, the biaxial magnetic forming device 20 was inevitably more expensive.

Therefore, it is inevitable to incur considerable R & D costs by simply providing such magnetic forming devices 10 and 20. Therefore, the basic research cost for the device sample acts as a large factor that is inevitably increased, and there is a problem that is a factor that inhibits the activation of R & D activities using a biaxial magnetic forming device.

Republic of Korea Patent Publication 10-2018-0101388

An object of the present invention is to solve the conventional problems as described above, a two-axis magnetic forming apparatus capable of forming a magnetic field in two directions (2-axis) perpendicular to each other of the existing one-axis magnetic forming apparatus It is to provide a technology that can be converted or upgraded to.

The magnetic field station of the biaxial magnetic forming apparatus according to an embodiment of the present invention for achieving the above object is a first coil wound around the outer periphery of the first core with the first core and the first core as the center. It includes, A first N stimulation body to form the N pole by the electric energy supplied from the outside; And a second coil wound along an outer circumference of the second core with a second core and the second core as the center, and a first S stimulation body forming an S pole by electric energy supplied from the outside; The first N-stimulator and the first S-stimulator are disposed to face each other at a predetermined interval on a virtual first axis, including at least a portion of the first core and the second core. A yoke body in contact with at least a portion of the U-shaped or U-shaped; And a bias coil wound around the yoke body.

Here, the yoke body, a central yoke (central yoke) that is arranged to be spaced apart from the first core or the second core by a predetermined distance, the central axis is parallel to the first axis; A first side yoke partly in contact with the central yoke and another part in contact with the first core; A second side yoke partly contacting the central yoke and another part contacting the second core; It may be characterized as another one to include.

Further, the diameter of the first core or the diameter of the second core may be characterized as another feature that is smaller than the diameter of the central yoke.

Further, another feature may be that the thickness (width) of the first coil is smaller than the diameter of the first core or the thickness of the second coil is smaller than the diameter of the second core.

In addition, another feature may be that a bias coil wound around the central yoke is provided.

Further, the winding density of the first coil or the second coil has a difference within the same or 50% compared to the winding density of the bias coil, or the winding number of the first coil or the second coil is the bias coil Another characteristic may be that it has the same or a difference within 50% compared to the number of windings.

Further, the magnetic field station, the first N-stimulator, the first S-stimulator and the yoke body coupled to the first N-stimulator, the first S-stimulator and the stand for supporting the yoke body; The stand includes the first N-stimulus body and the first S such that the imaginary plane including the first axis and the central axis of the yoke body has an inclination angle between 20 degrees and 90 degrees with respect to a horizontal plane. Another characteristic may be to support the stimulator and the yoke body.

The insert assembly of the biaxial magnetic forming apparatus according to an embodiment of the present invention for achieving the above object is a first insert coil; A second insert coil arranged to coincide with the central axis of the first insert coil at a position spaced downward from the first insert coil by a radius of the first insert coil, and having a same radius as the first insert coil; And an insert bobbin in which the first insert coil and the second insert coil are maintained to maintain a wound shape and position, and a hollow having the same central axis as the first insert coil or the second insert coil is formed. ;, The insert bobbin is located between the first insert coil and the second insert coil, the middle block is formed with the observation sphere communicating with the hollow perpendicular to the central axis of the hollow; A ground block positioned below the second insert coil positioned below the middle block and provided with a refrigerant hole or a refrigerant pipe to allow the refrigerant to move inside; And a top block located above the first insert coil positioned above the middle block and provided with a refrigerant hole or a refrigerant pipe to allow the refrigerant to move inside. It may also be characterized as including one.

Further, in the insert assembly, the insert bobbin is coupled to the insert bobbin so as to be in contact with the top block, the middle block or the ground block of the insert bobbin, the receiving hole so that the core or pole of the electromagnet is close to the middle block A pair of stimulus receiving panels formed; further comprising, a pair of the stimulation receiving panel may be characterized by another feature that the insert bobbin is coupled to the insert bobbin on both sides of the insert.

Furthermore, in the insert assembly, for at least a portion of the first insert coil and at least a portion of the second insert coil for cooling of the first insert coil or the second insert coil, the front side of the insert bobbin In the front cooling jacket coupled to the insert bobbin; And contacting at least a portion of the first insert coil and at least a portion of the second insert coil for cooling of the first insert coil or the second insert coil, and to the insert bobbin at a rear side of the insert bobbin. Rear cooling jacket to be combined; Another feature may further include.

Mount assembly of the biaxial magnetic forming apparatus according to an embodiment of the present invention for achieving the above object is a ground yoke; A mount core formed upwardly by a predetermined height on the front side of the ground yoke; A mount coil wound around the mount core; A mount coil cooling block that contacts the outer circumferential surface of the mount coil and cools the mount coil by receiving refrigerant from the outside; And it is located on the upper side of the mount core, a stage that provides a place for the measurement of the sample; may be characterized by including one.

Here, a mount core insertion hole is formed so that the mount core is located in the center, and a mount core guide disposed on the ground yoke and positioned between the mount core and the mount coil; A hole is formed so that the upper end of the mount core is exposed, a bobbin guide coupled to the top of the mount core guide; And a stage block cooling block disposed between the upper side of the bobbin guide and the stage, and cooling the stage. Another feature may further include.

Furthermore, another feature may be that a cooling line is provided inside the stage cooling block so that the refrigerant supplied from the outside can cool the stage cooling block.

Further, the stage is coupled in contact with at least a portion of the upper side of the stage stage cooling block, and between the stage and the stage stage cooling block, a hole probe for monitoring a vertical magnetic field for a sample to be disposed above the stage can be inserted. Another feature is that a hole probe insertion groove is provided.

Further, the boosting core is disposed on the upper side of the ground yoke, but is erected in a direction parallel to the mount core; And a boosting coil wound around the boosting core. Another feature may further include.

Furthermore, the shape of the cross section of the boosting core may be another feature.

Further, on the left and right sides of the boosting coil, a boosting coil cooling plate for cooling the boosting coil is disposed, and a refrigerant pipe is disposed between the boosting coil cooling plate and the boosting coil to allow refrigerant to flow in and move. It can also be characterized as another.

Furthermore, a roof top yoke disposed on an upper end of the boosting coil; An icicle core having an upper end coupled to a portion of a lower side of the roof top yoke so that a central axis coincides with a central axis of the mount core; An ice coil wound around the ice core; And an icicle coil cooling block that contacts the outer circumferential surface of the icicle coil and cools the icicle coil. Another feature may further include.

In order to achieve the above object, the biaxial magnetic forming apparatus according to an embodiment of the present invention includes a first N-stimulation body capable of forming an N-pole and a first S-stimulus body capable of forming an S-pole. A magnetic field station disposed opposite to each other at a predetermined distance on an axis; And a Helmholtz coil composed of a first insert coil and a second insert coil, wherein the insert assembly can be disposed or removed from the magnetic field station; Including, but in the position between the first N-stimulator and the first S-stimulator of the magnetic field station so that the second axis, the central axis of the Helmholtz coil of the insert assembly intersects perpendicularly to the first axis The insert assembly may be arranged as one feature.

Here, the magnetic field station may be characterized as another magnetic field station having any one of the various characteristics of the magnetic field station.

Furthermore, the insert assembly may further be characterized by being an insert assembly having any one of several characteristics of the insert assembly.

In order to achieve the above object, the biaxial magnetic forming apparatus according to an embodiment of the present invention includes a first N-stimulation body capable of forming an N-pole and a first S-stimulus body capable of forming an S-pole. A magnetic field station disposed opposite to each other at a predetermined distance on an axis; And a second N-stimulus body capable of forming an N-pole or a second S-pole body capable of forming an S-pole, and a mount assembly capable of being disposed or removed from the magnetic field station; The first N-stimulator and the first of the magnetic field station to include the second N-stimulator or the second S-stimulator of the mount assembly on a second axis perpendicular to the first axis. One feature may be that the mount assembly is disposed at positions between S-stimuli.

Here, the magnetic field station may be characterized as another magnetic field station having any one of the various characteristics of the magnetic field station.

Here, the mount assembly may be another feature that the mount assembly is equipped with any one of various features of the mount assembly.

A magnetic field station, an insert assembly, a mount assembly, and a two-axis magnetic forming device including them according to the present invention can form a magnetic field having a stronger strength than a conventional magnetic forming device. Therefore, it can help to study the electromagnetic properties of the device. together. In addition, there is also an economical effect that can reduce the research cost by using a conventional one-axis magnetic forming apparatus as a two-axis magnetic forming apparatus by using an insert assembly or a mount assembly without having to purchase a separate two-axis magnetic forming apparatus.

1 is a view schematically showing a magnetic field forming apparatus according to a conventional embodiment.
2 is a perspective view schematically showing a biaxial magnetic forming apparatus including a magnetic field station and an insert assembly according to an embodiment of the present invention.
3 is a view schematically showing a magnetic field station according to an embodiment of the present invention.
4 is a perspective view exemplarily showing another form of a core pole provided at an end of a core of a magnetic field station according to an embodiment of the present invention.
5 is a side view schematically showing a magnetic field station according to another embodiment of the present invention.
6 is a view schematically showing an insert assembly according to an embodiment of the present invention.
7 is a view showing various forms of a mount assembly according to an embodiment of the present invention by way of example.
8 is an exploded perspective view schematically showing a mount assembly according to an embodiment of the present invention.
9 is an exploded perspective view schematically showing a mount assembly according to another embodiment of the present invention.
10 is an exploded perspective view schematically showing a mount assembly according to another embodiment of the present invention.
11 is a view schematically showing a two-axis magnetic forming apparatus mounted on a magnetic field station according to another embodiment of the present invention.
12 is a view schematically showing a biaxial magnetic forming apparatus in which a mount assembly according to another embodiment of the present invention is mounted in a magnetic field station.

Hereinafter, preferred embodiments will be described with reference to the accompanying drawings so that the present invention may be more specifically understood.

2 is a perspective view schematically showing a two-axis magnetic forming equipment including a magnetic field station and an insert assembly according to an embodiment of the present invention, Figure 3 is a schematic view showing a magnetic field station according to an embodiment of the present invention , Figure 4 is a perspective view showing another form of the core pole provided at the end of the core of the magnetic field station according to an embodiment of the present invention, Figure 5 schematically shows a magnetic field station according to another embodiment of the present invention A side view, FIG. 6 is a view schematically showing an insert assembly according to an embodiment of the present invention, and FIG. 7 is a view exemplarily showing various forms of a mount assembly according to an embodiment of the present invention.

8 is an exploded perspective view schematically showing a mount assembly according to an embodiment of the present invention, FIG. 9 is an exploded perspective view schematically showing a mount assembly according to another embodiment of the present invention, and FIG. 10 is another exploded perspective view of the present invention Figure 11 is an exploded perspective view schematically showing a mount assembly according to an embodiment, Figure 11 is a view schematically showing a biaxial magnetic forming equipment mounted on a magnetic field station according to another embodiment of the present invention, Figure 12 is the present invention This is a view schematically showing a biaxial magnetic forming apparatus mounted on a magnetic field station according to another embodiment of the present invention.

Hereinafter, a magnetic field station, an insert assembly, a mount assembly, and a two-axis magnetic forming apparatus including them according to embodiments of the present invention will be described with reference to the drawings.

Referring first to FIG. 2, a 2-axis magnetic forming device according to an embodiment of the present invention includes a first N stimulating body capable of forming an N pole and a first S capable of forming an S pole Helmholtz coils composed of a magnetic field station 100 and a first insert coil and a second insert coil are arranged in which magnetic poles are disposed to face each other at predetermined intervals on a virtual first axis, and are arranged on the magnetic field station. Or it may be made to include an insert assembly 200 that can be removed.

Here, the insert assembly is disposed at a position between the first N-stimulator and the first S-stimulator of the magnetic field station so that the second axis, which is the central axis of the Helmholtz coil of the insert assembly 200, intersects perpendicular to the first axis. It is desirable.

First, a description will be given of a magnetic field station.

As shown in the perspective view of Figure 3 (a) and the cross-sectional view of Figure 3 (b), the magnetic field station 100 according to an embodiment of the present invention includes a first N-stimulator 120, a first S-stimulator 140, the yoke body 110 and the bias coil 117 may be included.

The first N stimulation body 120 includes a first coil 125 wound around an outer circumference of the first core 121 with the first core 121 and the first core 121 as the center, and outside The N-pole is formed by the electric energy supplied from.

The first S-stimulus 140 includes a second coil 145 wound along the outer circumference of the second core 141 with the second core 141 and the second core 141 as the center. The S-pole is formed by the electric energy supplied from.

In addition, the first N stimulator 120 and the first S stimulator 140 face each other at predetermined intervals on a virtual first axis (axis) as referenced in FIG. 3. 120) and the first S stimulus 140 are disposed.

The yoke body 110 is in contact with at least a portion of the first core 121 and at least a portion of the second core 141, and has a U or U shape.

The bias coil 117 is a coil wound around the yoke body 110.

The yoke body 110 may have a U-shaped or U-shaped form as at least one member, and includes a central yoke 111, a first side yoke 115, and a second side yoke 113 as follows. It is also preferably made.

As referred to in the figure, the central yoke (central yoke) 111 is disposed spaced apart from the first core 121 or the second core 141 by a predetermined distance, the central axis is disposed parallel to the first axis.

Here, the diameter of the first core 121 or the diameter of the second core 141 is preferably smaller than the diameter of the central yoke 111. That is, it is preferable that the diameter of the central yoke 111 is larger than the diameter of the first core 121 or the second core 141.

Since the central yoke 111 is easily self-saturating, it must be larger than the diameter of the first core 121 or the second core 141 to increase the magnetic field efficiency, so the diameter of the central yoke 111 is the first core 121 That is, it is preferable that the diameter is larger than the diameter of the second core 141. Here, the magnetic field efficiency refers to the intensity of the output magnetic field relative to the input current.

In addition, the first side yoke 115 is disposed such that a portion of the first side yoke 115 is in contact with the central yoke 111 and another portion of the first side yoke 115 is in contact with the first core 121. .

The second side yoke 113, like the first side yoke 115, a part of the second side yoke 113 is in contact with the central yoke 111, and the second side yoke 113 of the second core 141 It is arranged so that the other part is in contact.

In this way, the yoke body 110 may be configured through the central yoke 111, the first side yoke 115, and the second side yoke 113.

In addition, it is preferable that the thickness (width) of the first coil 125 is formed smaller than the diameter of the first core 121. Here, the thickness of the coil means a width or width between an outer diameter and an inner diameter in a coil wound around a core and having a shape similar to a donut.

Similarly, the thickness of the second coil 145 is also preferably smaller than the diameter of the second core 141. If the thickness of the coil is smaller than the diameter of the core, it is preferable because it is advantageous to increase the magnetic field efficiency.

And, it is also preferable that the bias coil 117 wound around the central yoke 111 is provided. It is preferable because the magnetic field efficiency can be further increased by the central yoke 111 and the bias coil 117 wound around the central yoke 111.

In addition, the winding density of the first coil 125 is preferably the same as the winding density of the bias coil 117, and the winding density of the first coil 125 is within 50% of the winding density of the bias coil 117. It is desirable to have a difference.

Similarly, the winding density of the second coil 145 is also preferably the same as the winding density of the bias coil 117, and it is also desirable to have a difference within 50% of the winding density of the bias coil 117.

Alternatively, the number of turns of the first coil 125-also referred to as the number of turns-is preferably equal to the number of turns of the bias coil 117, and the number of turns of the first coil 125 is the number of turns of the bias coil 117 It is preferable to have a difference within 50% as compared to.

Likewise, the number of turns of the second coil 145 is preferably the same as the number of turns of the bias coil 117, and it is also desirable to have a difference within 50% of the number of turns of the bias coil 117.

More preferably, the winding density of the first coil 125 and the second coil 145 is the same as the winding density of the bias coil 117, or the winding density of the first coil 125 and the second coil 145 If is configured to be equal to the winding density of the bias coil 117, it is more advantageous to increase the magnetic field efficiency.

The base plate 161 is the first N stimulation body 120, the first S stimulation body 140 and the first N stimulation body 120, the first S stimulation body 140 from the lower side of the yoke body 110 and It serves as a basic foundation for supporting the York body 110.

The base plate 161 is also preferable, but the following stand 160, which may be further included in the magnetic field station 100, is also preferable.

5, the stand 160 is coupled to the first N-stimulator 120, the first S-stimulator 140 and the yoke body 110, the first N-stimulator 120, the first It supports the S-stimulator 140 and the yoke body 110. In particular, the stand 160 is the first N-stimulator 120 so that the stand 160 has an inclination angle between 20 degrees and 90 degrees with respect to the horizontal plane of the imaginary plane including the first axis and the central axis of the yoke body 110 ), It is preferable to support the first S stimulus 140 and the yoke body 110

As such, when the stand 160 has an inclination, when the first N stimulation body 120 and the first S stimulation body 140 are positioned at a constant height with respect to a horizontal surface, a space for a probe or an experimental instrument is provided. It is preferable because it can.

In addition, when a magnetic field station is installed on a ferromagnetic base such as an optical table, the thickness of the stand 160 is more than twice the gap between the core poles at the ends of the first N-stimulator 120 and the first S-stimulator 140. Having a size is preferable because it can suppress magnetic flux leakage.

In addition, at the ends of each of the first core 121 and the second core 141, there is a first core pole 123 and a second core pole 143. It is preferable that the ends of the first core pole 123 and the ends of the second core pole 143 are flat surfaces as referred to in FIG. 3 (b), but the first core as referred to in FIG. 4. It is also preferable that the ends of the poles 1231 and the second core poles 1431 are formed with stepped portions.

When the first core pole 1231 and the second core pole 1431 are formed as described above, it is preferable because the strength and uniformity of the horizontal magnetic field formed in the first axis direction that is the horizontal direction can be increased.

Here, when the stepped portion of the first core pole 1231 and the second core pole 1431 is formed to have an angle between 35 and 55 degrees of the inclined surface, it helps to increase the strength of the magnetic field. When the central portions of the 1 core pole 1231 and the second core pole 1431 have a concave shape as shown in FIG. 4, it is preferable because it helps to maximize the strength of the magnetic field.

Next, an insert assembly according to an embodiment of the present invention will be described.

Referring to FIG. 6, the insert assembly 200 according to an embodiment of the present invention basically includes a first insert coil 211, a second insert coil 212, and an insert bobbin 220. Here, it is also preferable that the first insert coil 211 and the second insert coil 212 together constitute a Helmholtz coil. Of course, solenoids other than Helmholtz coil are also possible, and self-uniformity can be improved.

The first insert coil 211 is wound on the insert bobbin 220 as referenced in the drawing.

Further, the second insert coil 212 is wound on the insert bobbin 220 at the lower side of the first insert coil 211. Preferably, the second insert coil 212 is disposed such that the center axis coincides with the first insert coil 211 at a position spaced downward from the first insert coil 211 by a radius of the first insert coil 211. , It is preferable that the second insert coil 212 and the first insert coil 211 have the same radius.

In addition, the insert bobbin 220 has an outer appearance in which the first insert coil 211 and the second insert coil 212 are wound as described above.

That is, the insert bobbin 220 supports the first insert coil 211 and the second insert coil 212 to maintain the wound shape and position. In addition, a hollow is formed in the insert bobbin 220, and the central axis of the hollow is formed to coincide with the central axis of the first insert coil 211 or the central axis of the second insert coil 212.

The insert bobbin 220 is made of a middle block 223, a ground block 221 and a top block 225, it is preferably made of a material having a high thermal conductivity, such as a copper or aluminum-based material.

The middle block 223 is positioned between the first insert coil 211 and the second insert coil 212 as referred to in FIG. 6. Accordingly, a gap between the first insert coil 211 and the second insert coil 212 may be set by the thickness or height of the middle block 223.

Also, the middle block 223 is preferably formed with an observation hole 224 communicating with the hollow in a direction perpendicular to the central axis of the hollow.

A sensor or a Hall probe used to measure a sample or a magnetic property of the sample as the central portion of the middle block 223 in the hollow may enter through the observation hole 224.

In addition, it is preferable because light such as a laser can be irradiated through the observation hole 224 during an optical property measurement experiment.

Inside the middle block 223, it is preferable that a refrigerant hole or a refrigerant pipe is provided to allow the refrigerant to move. When the middle block 223 is cooled because the refrigerant flows through the refrigerant hole or the refrigerant pipe provided inside the middle block 223, the first insert coil 211 or the second insert coil 212 can be conduction cooled. desirable.

The ground block 221 is positioned below the second insert coil 212 positioned below the middle block 223. In addition, a coolant hole or a coolant tube is preferably provided inside the ground block 221 so that the coolant can move.

A current is applied to the first insert coil 211 and the second insert coil 212 to form a magnetic field, and current flows. At this time, Joule heat is generated in the first insert coil 211 and the second insert coil 212 through which current flows.

In general, the Joule heat generated in the coil increases the temperature of the test environment, that is, the temperature around the sample, thereby providing a variable that interferes with the experiment. In addition, when the temperature of the coil increases due to the heat generated in the coil, a problem is also caused that the coil is damaged.

Therefore, it is preferable to conduct the cooling of the second insert coil 212 by cooling the ground block 221 using a refrigerant.

As the refrigerant moves through the refrigerant hole or the refrigerant pipe provided inside the ground block 221, the ground block 221 is cooled. Therefore, the second insert coil 212 that is heated may be cooled by the ground block 221.

The top block 225 is positioned above the first insert coil 211 positioned above the middle block 223. In addition, the top block 225 is provided with a refrigerant hole or a refrigerant pipe to allow the refrigerant to move inside, like the ground block 221.

As the refrigerant moves through the refrigerant hole or the refrigerant pipe provided inside the top block 225, the top block 225 is cooled. Therefore, the first insert coil 211 that is heated may be conduction-cooled by the top block 225.

It is also preferable to further include the stimulus receiving panels 241 and 246 in the insert assembly 200.

The stimulus receiving panels 241 and 246 are coupled to the insert bobbin 220 such that the top block 225, the middle block 223, or the ground block 221 of the insert bobbin 200 is in contact with each other. In addition, the magnetic pole station panels 241 and 246 accommodate the first and second cores 121 and 141 or the first and second core poles 123 and 143 of the magnetic field station 100 to be close to the middle block 223. It is preferable that holes are formed.

The stimulus-receiving panels 241 and 246 are also preferably heat-conductive materials such as copper or aluminum-based materials.

In FIG. 6, it is exemplarily shown that the receiving hole is formed in the middle portion of the stimulus receiving panels 241 and 246. The receiving hole is also formed in the first and second core poles (123, 143) in the magnetic field station 100 described above, the outer peripheral surface is formed in a tapered shape, the receiving hole is also preferably formed to be tapered in the stimulus receiving panel (241, 246) Do.

The stimulus receiving panels 241 and 246 are preferably provided in a pair as referenced in the drawings. Then, the pair of stimulus receiving panels 241 and 246 are coupled to the insert bobbin 220 from both left and right sides with the insert bobbin 220 interposed therebetween.

And when the surfaces of the first and second core poles 123 and 143 coupled to the stimulus receiving panels 241 and 246 contact the left and right surfaces of the insert bobbin 220, the heat generated in the first and second insert coils 211 and 212 Since the first and second core poles 123 and 143 form a path to be conducted, the heat dissipation performance can be further increased.

In addition, in the insert assembly 200, it is also preferable to further include a front cooling jacket 231 and a rear cooling jacket 236.

The front cooling jacket 231 contacts at least a portion of the first insert coil 211 and at least a portion of the second insert coil 212 for cooling the first insert coil 211 or the second insert coil 212, It is coupled to the insert bobbin 220 on the front side of the insert bobbin 220.

In addition, the front cooling jacket 231 is preferably formed with an observation hole 234 communicating with the observation hole 224 provided in the middle block 223 of the insert bobbin 220.

The rear cooling jacket 236 contacts at least a portion of the first insert coil 211 and at least a portion of the second insert coil 212 for cooling the first insert coil 211 or the second insert coil 212, It is coupled to the insert bobbin 220 at the rear side of the insert bobbin 220.

The front cooling jacket 231 and the rear cooling jacket 236 are also made of a heat conductor such as copper or aluminum based material to cool the heat generated by the first insert coil 211 or the second insert coil 212. It is preferred.

Further, more preferably, the insert assembly 200 further includes an upper cooling jacket 251 and a lower cooling jacket 256.

The upper cooling jacket 251 is coupled to the upper side of the top block 225. In addition, a hole communicating with the hollow formed in the insert bobbin 220 is formed in the upper cooling jacket 251. In addition, it is also desirable that the upper cooling jacket 251 is provided with a power terminal 280 for supplying current to the first insert coil 211 or the second insert coil 212.

The lower cooling jacket 256 is coupled to the lower side of the ground block 221. The lower cooling jacket 256 is also formed with a hole communicating with the hollow of the insert bobbin 220.

It is also preferable that the insert assembly 200 includes a radiation shield 260 in the form of a pipe. The radiation shielding rod 260 is inserted into the hollow of the insert bobbin 220 and prevents or suppresses radiation by shielding the radiation heat so that the sample does not receive heat due to radiation heat.

In addition, when the strength of the magnetic field is insufficient when experimenting with the sample, it is also preferable that the insert magnetic core 270 disposed inside the hollow of the insert bobbin 200 is further included to compensate for this. As shown in the exploded view of FIG. 6 (b), the insert magnetic core 270 may be inserted inside the radiation shielding rod 260 and disposed inside the hollow of the insert bobbin 220.

As described above, the biaxial magnetic forming equipment according to the embodiment of the present invention may be implemented through the magnetic field station 100 and the insert assembly 200 according to the embodiment of the present invention. In addition, when the insert assembly 200 according to the embodiment of the present invention is mounted on a conventional one-axis magnetic forming apparatus, it can be upgraded to a two-axis magnetic forming apparatus.

In addition, it is also preferable that the biaxial magnetic forming equipment is configured to include a mount assembly instead of the insert assembly 200.

The biaxial magnetic forming apparatus according to another embodiment of the present invention may include a magnetic field station and a mount assembly.

Here, in the magnetic field station, the first N-stimulus body capable of forming the N-pole and the first S-stimulus body capable of forming the S-pole are arranged to face each other at predetermined intervals on the virtual first axis, More specific details are as described above.

The mount assembly 301, 302, 303 as referred to in FIG. 7 is provided with a second N-stimulator capable of forming an N-pole or a second S-stimulator capable of forming an S-pole, and a magnetic field station 100 Can be placed on or removed.

Here, on the virtual second axis perpendicular to the first axis, mount it at a position between the first N-stimulator and the first S-stimulator of the magnetic field station such that the second N-stimulator or the second S-stimulator of the mount assembly is located. It is preferred that the assemblies 301, 302, 303 are arranged.

Hereinafter, the mount assemblies 301, 302, and 303 according to the embodiment of the present invention will be described.

Referring to FIG. 7, the mount assembly according to an embodiment of the present invention basically includes a ground yoke 310, a mount core 320, a mount coil 330, a mount coil cooling block 340, and a stage 350 do.

The mount assembly (301, 302, 303) is shown in Figure 7 (a), (b), (c) three types are possible, the mount assembly shown in Figure 7 (a) ( 301) is the basic form.

First, in the basic form of the mount assembly 301 shown in FIGS. 7A and 8, the ground yoke 310 is located under the mount assembly 301 and serves as a basic foundation for the mount assembly 301.

As referenced in the drawing, the mount core 320, the mount coil 330, and the mount coil cooling block 340 are disposed on the upper side of the ground yoke 310 based on the ground yoke 310 as a support base.

The mount core 320 is formed above the ground yoke 310 by a predetermined height above the ground yoke 310.

The mount coil 330 is disposed on the ground yoke 310, and is wound around the mount core 320.

The mount coil cooling block 340 contacts the outer circumferential surface of the mount coil 330 and cools the mount coil 330 by receiving refrigerant from the outside.

And the stage 350 is located on the upper side of the mount core 320, and provides a place for measuring the sample.

It is also preferable that the mount assembly 301 further includes a mount core guide 360, a bobbin guide 365, and a stage-to-cooling block 370.

The mount core guide 360 is formed with a mount core insertion hole as referred to in FIG. 8 so that the mount core 320 can be positioned at the center, and is disposed on the ground yoke 310, and the mount core 320 is mounted. And between the mount coil 330.

And the bobbin guide 365 is formed with a hole so that the upper end of the mount core 320 is exposed, it is coupled to the top of the mount core guide 360.

The stage cooling block 370 is disposed between the upper side of the bobbin guide 365 and the stage 350. The stage stage cooling block is disposed between the top side of the bobbin guide and the stage stage. The stage cooling block 370 is provided with a cooling line 372 inside the stage cooling block 370 so that the refrigerant supplied from the outside cools the stage cooling block 370 to cool the stage 350. It is desirable.

As the refrigerant moves through the cooling line 372 provided in the stage cooling block 370, the stage cooling block 370 is cooled. And. As the cooling stage 370 is cooled, the stage 350 is not overheated.

The stage 350 is coupled to at least a portion of the upper side of the stage cooling block 370. Then, between the stage 350 and the stage cooling block 370, the hole probe insertion groove 352 so that a hole probe (not shown) for monitoring a vertical magnetic field for a sample to be disposed on the stage 350 can be inserted. It is preferable that this is provided.

Reference numeral 380 is a support panel that supports the refrigerant inlet port so that the refrigerant can flow into the side of the cooling coil 372 provided inside the mount coil cooling block 340 or the stage-to-cooling block 370.

As described above, the mount assembly has a basic shape including a ground yoke 310, a mount core 320, a mount coil 330, a mount coil cooling block 340, and a stage 350 as shown in FIG. 7 (a). It is also preferred.

Here, the form of a mount assembly further comprising a boosting core 410 and a boosting coil 420 in the mount assembly 301 as in FIG. 7 (a) is also preferred, and the boosting coil cooling plates 441 and 446 may be used. Also preferred is the form of the mount assembly as in FIGS. 7 (b) and 9 which further include. 7 (b) and 9 exemplarily show an applied embodiment of the mounting assembly 302 further comprising a boosting core 410, a boosting coil 420, and a boosting coil cooling plates 441 and 446. Did.

The boosting core 410 is disposed on the upper side of the ground yoke 310, and is preferably placed in a direction parallel to the mount core 320.

The boosting coil 420 is formed by winding around the boosting core 410.

And, the shape of the cross-section of the boosting core 410 is preferably in a rectangular shape as referred to in FIG. 7B or 9.

When the shape of the cross section of the boosting core 410 has a rectangular shape, the boosting coil 420 is also wound to form a square shape. When the cross-section of the boosting core 410 has a rectangular shape, the first N stimulation body 120, the first S stimulation body 140 and the yoke body 110 of the magnetic field station 100 when mounted in the magnetic field station 310 ) Has the advantage of increasing the space utilization.

In addition, the circular cross-sectional area of the boosting core 410 is within a limited space between the first N-stimulator 120, the first S-stimulator 140, and the yoke body 110 of the magnetic field station 100. Since the area of the cross-section can be made wider than that of the shape, the magnetic saturation point is extended to reduce the magnetic resistance. The advantage is that the total magnetic flux increases as the magnetic resistance decreases, thereby increasing the magnetic force.

And, the shape of the cross-section of the boosting core 410 has a rectangular shape, and the longer the length of the boosting core 410, the longer the winding layer in which the boosting coil 420 is wound is stretched and wound, thereby reducing the heat generation density. Therefore, sufficient heat dissipation effect may be obtained only by cooling the left and right sides of the boosting coil 420.

On the left and right sides of the boosting coil 420, a boosting coil cooling plate 441 and 446 for cooling the boosting coil 410 may be sufficiently disposed, and the boosting coil cooling plates 441 and 446 and the boosting coil ( It is also preferable that the refrigerant pipe 430 is disposed so that the refrigerant flows in between 420).

When the boosting cooling plates 441 and 446 and the refrigerant pipe 430 are provided as described above, it is preferable because the boosting coil that generates heat can be cooled so as not to overheat.

11 shows a form in which the mount assembly 302 as illustrated in FIG. 7B is mounted on the magnetic field station 100 of the present invention. In FIG. 11, reference numeral 590 may be a fixing bar to assist the mount assembly 302 to be stably positioned in the magnetic field station.

As described above, the mount assembly as referred to in FIGS. 7 (b) and 9 is also preferable, and in the form of the applied mount assembly 303 as shown in FIGS. 7 (c) and 10, which are further applied forms. It is also possible.

7 (c) and FIG. 10 exemplarily show an applied type of mount assembly.

7 (c) and 10, the mounted assembly 303 of the applied form as referred to in FIG. 7 (b) and the mount assembly 302 in FIG. 9 described above is the roof top yoke 510, It further includes an icicle core 520, an icicle coil 530, and an icicle coil cooling block 540.

The roof top yoke 510 is disposed on the top of the boosting coil 530, as shown in FIG. 10, and supports the icicle core 520.

The upper end of the icicle core 520 is coupled to a portion of the lower surface of the roof top yoke 510 so that the central axis of the icicle core 520 coincides with the central axis of the mount core 320.

And the icicle coil 530 is formed by winding around the icicle core 520. The icicle coil cooling block 540 contacts the outer circumferential surface of the icicle coil 530 and receives coolant from the outside to cool the icicle coil 530.

As described above, the mount assembly 301 as in FIG. 7 (a) may form a magnetic field at the lower side of the sample disposed in the stage 350, and the mount assembly 303 as in FIG. 7 (c) may be It is preferable because a magnetic field can be formed on the upper side and the lower side of the sample disposed in the stage 350.

The form in which the mount assembly 303 as shown in FIG. 7C is mounted on the magnetic field station 100 of the present invention is schematically illustrated in FIG. 12. In FIG. 12, reference numeral 590 is preferable because it can assist the mount assembly 303 to be stably positioned in the magnetic field station 100 as a fixing bar as described above.

As described above, the mount assembly of the present invention can be upgraded to a two-axis magnetic field forming apparatus by simply mounting on an existing one-axis magnetic field forming apparatus.

Alternatively, by mounting the mount assembly of the present invention on the magnetic field station according to the present invention described above, it is also possible to implement a biaxial magnetic forming device according to another embodiment of the present invention.

As described above, the magnetic field station and the insert assembly or the mounting assembly according to the embodiment of the present invention can implement the biaxial magnetic forming device of the present invention, and form a magnetic field of greater intensity than the conventional biaxial magnetic forming device. It has the advantage of being able to.

In addition, by mounting the insert assembly or the mounting assembly according to an embodiment of the present invention to a conventional one-axis magnetic forming apparatus, the one-axis magnetic forming apparatus can be easily upgraded to a two-axis magnetic forming apparatus.

Therefore, it is possible to form a two-axis magnetic forming apparatus by simply mounting the insert assembly or the mounting assembly according to the present invention to the conventional one-axis magnetic forming apparatus without having to purchase a separate two-axis magnetic forming apparatus as in the prior art. It also has the advantage of reducing the cost of purchase.

In addition, there is also an advantage that the problem of space limitation does not occur because there is no problem of securing the installation space required by additionally providing the 2-axis magnetic forming device separately from the 1-axis magnetic forming device.

As described above, the detailed description of the present invention has been made by the embodiments with reference to the accompanying drawings, but since the above-described embodiments are merely described as preferred embodiments of the present invention, the present invention is described above. It should not be understood as being limited to the embodiment only, and the scope of the present invention should be understood as the following claims and equivalent concepts.

100: magnetic field station
120: first N-stimulation body 140: first S-stimulation body
110: York body 160: stand
200: insert assembly
211: 1st insert coil 212: 2nd insert coil
220: insert bobbin 231: front cooling jacket
236: rear cooling jacket 241, 246: stimulus receiving panel
301, 302, 303: Mount assembly
310: ground yoke 320: mount core
330: Mount coil 340: Mount coil cooling block
350: stage
410: boosting core 420: boosting coil
510: roof top yoke 520: icy core
530: Icy coil 540: Icy coil cooling block

Claims (24)

A first N stimulus body including a first core and a first coil wound along an outer circumference of the first core around the first core, and forming an N pole by electric energy supplied from the outside; And
A first S stimulation body including a second core and a second coil wound along an outer circumference of the second core around the second core, and forming an S pole by electric energy supplied from the outside; Including,
The first N-stimulation body and the first S-stimulation body are disposed to face each other at a predetermined interval on a virtual first axis,
A yoke body in contact with at least a portion of the first core and at least a portion of the second core and having a U or U shape; And
Includes; a bias coil wound around the yoke body;
The yoke body,
A central yoke disposed at a predetermined distance from the first core or the second core, and having a central axis parallel to the first axis;
A first side yoke partly in contact with the central yoke and another part in contact with the first core;
A second side yoke partly contacting the central yoke and another part contacting the second core; Including,
The diameter of the first core or the diameter of the second core is smaller than the diameter of the central yoke,
A bias coil wound around the central yoke is provided,
The winding density of the first coil or the second coil has the same or a difference within 50% compared to the winding density of the bias coil,
The winding number of the first coil or the second coil has the same or a difference within 50% compared to the winding number of the bias coil,
The first coil and the second coil overlap on both sides of the bias coil,
The first core, the second core and the yoke body form a similar '類 似' letter shape,
The magnetic field station, characterized in that the first coil and the second coil generates a magnetic flux between the first core and the second core.
delete delete According to claim 1,
The magnetic field station, characterized in that the thickness (width) of the first coil is smaller than the diameter of the first core, or the thickness of the second coil is smaller than the diameter of the second core.
delete delete According to claim 1,
The magnetic field station,
A stand coupled to the first N-stimulator, the first S-stimulator and the yoke body to support the first N-stimulator, the first S-stimulator and the yoke body; Including more,
The stand has the first N-stimulus body, the first S-stimulus body and the yoke such that a virtual plane including the first axis and the central axis of the yoke body has an inclination angle between 20 and 90 degrees with respect to a horizontal plane. Magnetic field station, characterized in that to support the body.
A first insert coil;
A second insert coil arranged to coincide with the central axis of the first insert coil at a position spaced downward from the first insert coil by a radius of the first insert coil, and having a same radius as the first insert coil; And
An insert bobbin supporting the first insert coil and the second insert coil to maintain a wound shape and position, and having a hollow having the same central axis as the first insert coil or the second insert coil; Including,
The insert bobbin,
A middle block positioned between the first insert coil and the second insert coil, and having an observation hole communicating with the hollow perpendicular to a central axis of the hollow;
A ground block positioned below the second insert coil positioned below the middle block and provided with a refrigerant hole or a refrigerant pipe to allow the refrigerant to move inside; And
A top block located above the first insert coil positioned above the middle block and provided with a refrigerant hole or a refrigerant pipe to allow the refrigerant to move inside; Insert assembly characterized in that it comprises a.
The method of claim 8,
In the insert assembly,
The insert block is coupled to the top block, the middle block or the ground block of the insert bobbin so as to be in contact with the insert bobbin, and the core or pole of the electromagnet accommodates a pair of magnetic poles formed with a receiving hole so as to be close to the middle block. Panel; further comprising,
The pair of the stimulus receiving panel is an insert assembly, characterized in that coupled to the insert bobbin on both sides of the left and right with the insert bobbin therebetween.
The method of claim 9,
In the insert assembly,
In contact with at least a portion of the first insert coil and at least a portion of the second insert coil for cooling of the first insert coil or the second insert coil, coupled to the insert bobbin at the front side of the insert bobbin Front cooling jacket; And
In contact with at least a portion of the first insert coil and at least a portion of the second insert coil for cooling of the first insert coil or the second insert coil, coupled to the insert bobbin at a rear side of the insert bobbin Rear cooling jacket; Insert assembly characterized in that it further comprises.
Ground yoke;
A mount core formed upwardly by a predetermined height on the front side of the ground yoke;
A mount coil wound around the mount core;
A mount coil cooling block that contacts the outer circumferential surface of the mount coil and cools the mount coil by receiving refrigerant from the outside; And
It is located on the upper side of the mount core, a mounting assembly, characterized in that it comprises; a stage that provides a place where the measurement of the sample is made.
The method of claim 11,
A mount core insertion hole is formed so that the mount core is located at the center, and is disposed on the ground yoke, but a mount core guide positioned between the mount core and the mount coil;
A hole is formed so that the upper end of the mount core is exposed, a bobbin guide coupled to the top of the mount core guide; And
A stage block cooling block disposed between the upper side of the bobbin guide and the stage, to cool the stage; Mount assembly characterized in that it further comprises.
The method of claim 12,
Mount assembly characterized in that the cooling line is provided on the inside of the stage cooling block so that the refrigerant supplied from the outside to cool the stage cooling block.
The method of claim 13,
The stage is coupled in contact with at least a portion of the upper surface of the stage cooling block, and between the stage and the stage cooling block, a hole probe for monitoring a vertical magnetic field for a sample to be placed on the stage is inserted. Mount assembly characterized in that the insertion groove is provided.
The method of claim 14,
A boosting core disposed on an upper side of the ground yoke and erected in a direction parallel to the mount core; And
A boosting coil wound around the boosting core; Mount assembly characterized in that it further comprises.
The method of claim 15,
The shape of the cross-section of the boosting core is a rectangular assembly.
The method of claim 16,
A boosting coil cooling plate for cooling the boosting coil is disposed on the left and right sides of the boosting coil, and a refrigerant pipe is disposed between the boosting coil cooling plate and the boosting coil to allow refrigerant to flow in and move. Mount assembly made with.
The method of claim 17,
A roof top yoke disposed on an upper end of the boosting coil;
An icicle core having an upper end coupled to a portion of a lower side of the roof top yoke so that a central axis coincides with a central axis of the mount core;
An ice coil wound around the ice core; And
An icicle coil cooling block that contacts the outer circumferential surface of the icicle coil and cools the icicle coil; Mount assembly characterized in that it further comprises.
A magnetic field station in which a first N stimulation body capable of forming an N pole and a first S stimulus body capable of forming an S pole are disposed to face each other at predetermined intervals on a virtual first axis; And
A Helmholtz coil composed of a first insert coil and a second insert coil, and an insert assembly capable of being disposed or removed from the magnetic field station; Including,
The insert assembly is positioned at a position between the first N-stimulator and the first S-stimulator of the magnetic field station so that the second axis, the central axis of the Helmholtz coil of the insert assembly, intersects perpendicularly to the first axis. Two-axis magnetic forming equipment, characterized in that arranged.
The method of claim 19,
The magnetic field station,
Claim 2, characterized in that the magnetic field station according to any one of claims 1, 4 and 7.
The method of claim 19,
The insert assembly,
Claim 2 to claim 10 characterized in that the insert assembly according to any one of the two-axis magnetic forming equipment.
A magnetic field station in which a first N stimulation body capable of forming an N pole and a first S stimulus body capable of forming an S pole are disposed to face each other at predetermined intervals on a virtual first axis; And
A second N-stimulus body capable of forming an N-pole or a second S-pole body capable of forming an S-pole, and a mount assembly capable of being disposed or removed from the magnetic field station; Including,
Between the first N-stimulator and the first S-stimulator of the magnetic field station such that the second N-stimulator or the second S-stimulator of the mount assembly is located on a second axis perpendicular to the first axis. The two-axis magnetic forming equipment, characterized in that the mounting assembly is disposed at the position.
The method of claim 22,
The magnetic field station,
Claim 2, claim 4 and claim 7, characterized in that the magnetic field station according to any one of the two-axis magnetic forming equipment.
The method of claim 22,
The mount assembly,
Claim 2 to claim 18, characterized in that the mounting assembly according to any one of the two-axis magnetic forming equipment.

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