KR20200071641A - System - Google Patents

Abstract

The present invention relates to a refrigerant-free electromagnet device which can stably derive a desired effect without a complex structure, maximize the performance of a device while minimizing heat loss to reduce energy costs, and minimize vibration transferred from a freezer to increase the accuracy and stability of the device and strengthen durability. The refrigerant-free electromagnet device comprises: a vacuum receptor which is formed in a donut shape with a horizontal center axis, and is hollow to form a space maintained in a vacuum state; a freezer accommodation unit which is coupled to an upper portion of the vacuum receptor and has a hollow cylindrical shape with a vertical center axis; a freezer coupled to the upper end of the freezer accommodation unit to perform a function as a low heat source; a heat-blocking receptor arranged in the same form as the vacuum receptor in the vacuum receptor to block heat from the outside; a freezer second-stage unit wherein one end thereof is coupled to the low heat end of the freezer and the other end thereof is arranged to be positioned in the heat-blocking receptor across the freezer accommodation unit; a bobbin which is arranged in a hollow cylindrical shape at the center in the heat-blocking receptor, and accommodates a superconductive electromagnet; and a second-stage metal heat conductor coupled to the outer circumference of the bobbin and connected to an end of the freezer second-stage unit to discharge heat.

Description

Refrigerant-free electromagnet device {System}

The present invention relates to a non-refrigerant electromagnet device used in a magnetic resonance imaging device, and more particularly, to a non-refrigerant electromagnet device employing a conduction cooling method that conducts cooling by conduction without using a cryogenic refrigerant such as helium. It is about.

Since the electromagnet device operates under cryogenic temperature, a method of cooling the electromagnet to cryogenic temperature through heat conduction is used to cool the electromagnet to a cryogenic temperature using a refrigerant such as liquid helium or to connect the freezer with an electromagnet and a metal having excellent conductivity.

The method of using a refrigerant such as liquid helium has problems such as an increase in maintenance cost as well as a complicated and large-sized device due to the use of a cryogenic refrigerant.

As an alternative to this, in recent years, a conduction cooling method has been applied to a small electromagnet device, and as a representative example, Republic of Korea Patent Publication No. 10-2014-0045382 (2014.4.16., published) is intended to cool the superconducting coil and the same. It is a superconducting magnet device characterized in that it has a low temperature refrigerator.

However, such a conventional technique has a problem in that the structure is complicated, the heat loss due to heat conduction to the outside is large, and the vibration generated in the low temperature refrigerator is transmitted to achieve the desired purpose.

Republic of Korea Patent Publication No. 10-2014-0045382 (2014.4.16., published)

Invented to solve the above problems, the present invention has an object to provide a non-refrigerant electromagnet device that can stably derive a desired effect without complicated structure.

In addition, an object of the present invention is to provide a non-refrigerant electromagnet device capable of maximizing the performance of a device while minimizing heat loss to reduce energy costs.

In addition, an object of the present invention is to provide a non-refrigerant electromagnet device that minimizes vibration transmitted from a freezer to improve image quality of a magnetic resonance imaging device, increase accuracy and stability of a device, and enhance durability.

As a means for solving the problems as described above, the present invention, the refrigerant-free electromagnet device,

The central axis is formed in the shape of a donut with a horizontal arrangement, and the inside is made of hollow, so that a space is formed and the space is a vacuum receptor that maintains a vacuum.

A hollow cylinder-shaped refrigerator accommodating portion coupled to the upper portion of the vacuum receptor and having a central axis disposed vertically.

A refrigerator that is coupled to the upper end of the refrigerator receiving portion to perform a function as a low heat source,

The heat shield receptor is disposed inside the vacuum receptor in the same form as the vacuum receptor to shield heat from the outside,

One end coupled to the low-temperature end of the freezer and the second end of the freezer which is disposed so that the other end is located inside the heat shield receptor via the freezer receiving portion,

A hollow cylinder disposed in the inner center of the heat shield receptor and receiving a superconducting electromagnet, and

It is characterized in that it comprises a two-stage metal thermal conductor coupled to the outer periphery of the bobbin and connected to the end of the second end of the refrigerator to discharge heat.

In addition, the connection between the end portion of the refrigerator and the end portion of the metal heat conductor of the end portion of the refrigerator is made of a two end portion flexible metal heat conduction link connecting both ends of each other.

In addition, it is characterized in that it further comprises a flexible metal heat conduction link at one end connecting the end of the one end of the refrigerator and the upper end of the heat shield receptor.

In addition, the bobbin is formed of a hollow cylindrical body, and one end thereof is provided with a flange section with an expanded cross section,

It characterized in that it further comprises a support member for reducing heat transfer, one end of which is coupled to the inner surface of the flange portion and penetrates the heat shield container and the other end is coupled to the side wall of the vacuum container.

Through the above-described problem solving means, the present invention, the refrigerant-free electromagnet device, can achieve a desired effect stably without having a complicated structure, and minimizes heat loss to the outside to reduce energy costs while reducing the performance of the device. It can be maximized, and minimizes vibration transmitted from the freezer, thereby improving the image quality of a magnetic resonance imaging device, improving the accuracy and stability of the device, and enhancing durability.

1 is a perspective view showing a refrigerant-free electromagnet device according to the present invention.
2 is a cross-sectional view showing a refrigerant-free electromagnet device according to the present invention.
3 is a cross-sectional view showing a refrigerant-free electromagnet device according to the present invention from another direction.

Preferred embodiments of the refrigerant-free electromagnet device according to the present invention will be described in detail with reference to the accompanying drawings.

1 is a perspective view showing a refrigerant-free electromagnet device according to the present invention, FIG. 2 is a cross-sectional view showing a refrigerant-free electromagnet device according to the present invention, and FIG. 3 shows a refrigerant-free electromagnet device according to the present invention from another direction It is one section.

As shown in Figures 1 to 3, the refrigerant-free electromagnet device according to the present invention is formed in a donut shape whose central axis is horizontally disposed, and the inside is formed of a hollow, so that a space is formed and the space is vacuumed. ), and a vacuum receptor (1) made of steel, aluminum, etc., which serves as an outer casing, and a refrigerator coupled to the top of the vacuum receptor (1) and having a central axis vertically arranged to be described later ( 3) a freezer receiving part 2 made of a material such as steel in the form of a hollow cylinder accommodating the second end part 5 of the freezer connected to the refrigerator, and a low heat source coupled to the upper end of the freezer receiving part 2 Refrigerator (3) performing a function as 低熱原), and heat shield receptor (4) disposed inside the vacuum receptor (1) in the same form as the vacuum receptor (1) to shield heat from outside, such as radiant heat Wow, one end is coupled to the low heat end of the refrigerator 3 (低熱端, substantially corresponding to an evaporator or low heat heat exchanger), and the other end is located inside the heat shield container 4 through the freezer receiving portion 2. A freezer 2nd end part (5) arranged to perform cooling by heat conduction, and a bobbin (6) arranged in a hollow cylindrical shape in the central portion of the heat shield receptor (4) and receiving a superconducting electromagnet, and the bobbin (6) ) Is connected to the outer circumferential edge of the freezer and is connected to the end of the second end 5 of the refrigerator, and includes a second end metal heat conductor 7 for discharging heat.

Here, when used as a magnetic resonance imaging device, the object to be tested is introduced into the intermediate through-hole of the vacuum container 1 made of a donut, and the refrigerator 3 is a conventional refrigerator 3 having a compressor, As described above, the heat shield receptor 4 is a member installed for the purpose of blocking radiant heat and the like, and is preferably made of aluminum, but is not limited thereto.

Through this structure, the low heat source of the refrigerator 3 is connected to the bobbin 6 and the electromagnet through the second end portion 5 of the refrigerator to conduct conduction cooling.

In addition, the present invention is characterized in that the connection of the end of the refrigerator 2nd end part 5 and the 2nd end metal heat conductor 7 consists of a 2nd end flexible metal heat conduction link 8 connecting both ends of each other. Here, the meaning of'flexible' means that sufficient flexibility is provided, which is such that vibration can be absorbed through deformation during transmission of external vibration, and through this, it is generated due to driving of the refrigerator 3 It solves the problem caused by the vibration transmitted through the second end portion 5 of the refrigerator is directly transmitted to the superconducting electromagnet. In contrast, when vibration is directly transmitted to the electromagnet, the durability is deteriorated, and the accuracy of data that can be measured through a refrigerant-free electromagnet device is deteriorated.

In addition, as a main feature of the present invention, as can be seen from the previous description, the refrigerator 3 is composed of two stages, and the heat shield receptor 4 is provided with an opening on the upper outer periphery, and an end of the refrigerator at one end And a first end flexible metal heat conduction link 9 connecting both ends of the heat shield receptor 4 and the upper ends thereof.

The first end flexible metal heat conduction link 9 further promotes heat shield from the outside by cooling the heat shield receptor 4.

In addition, the present invention, the bobbin (6) is formed of a hollow cylindrical body, and one end thereof is provided with a flange portion (10) with an expanded cross section, one end coupled to the inner surface of the flange portion (10) and the heat shield receptor It characterized in that it further comprises a heat transfer reduction support member 11 through which the other end is coupled to the side wall of the vacuum receptor (1).

As described above, the bobbin 6 primarily seeks to prevent heat loss compared to being heat-conducted to both sides through support of the cantilever type, and secondarily, the heat transfer from the bobbin 6 to the outside is bobbin ( 6) The heat loss can be relatively reduced by heat conduction through the heat transfer reduction support member 11, which is formed in a considerable length inside through the flange portion 10 and the heat transfer reduction support member 11 to maintain low temperature. There will be.

Through the configuration as described above, the present invention, the refrigerant-free electromagnet device, can achieve a desired effect stably without having a complicated structure, and minimizes heat loss to the outside to reduce energy costs while maximizing the performance of the device. It is possible to minimize the vibration transmitted from the freezer (3) to increase the accuracy and stability of the device, and has the advantage of enhancing durability.

1: vacuum receptor
2: Freezer housing
3: Freezer
4: Heat shield receptor
5: Freezer 2nd stage
6: Bobbin
7: 2-stage metal heat conductor
8: 2-stage flexible metal heat conduction link
9: 1 end flexible metal heat conduction link
10: flange section
11: Support member for reducing heat transfer

Claims (1)

The central axis is formed in a donut shape horizontally arranged, and the inside is made of hollow, so that a space is formed, and the space is a vacuum receptor that maintains a vacuum,
A hollow cylinder-shaped refrigerator accommodating portion coupled to the upper portion of the vacuum receptor and having a central axis vertically disposed therein,
A refrigerator that is coupled to the upper end of the refrigerator receiving portion to perform a function as a low heat source,
The heat shield receptor is disposed inside the vacuum receptor in the same form as the vacuum receptor to shield heat from the outside,
One end coupled to the low heat end of the freezer and the second end of the freezer which is disposed so that the other end is located inside the heat shield container through the freezer receiving part,
A hollow cylinder disposed in the inner center of the heat shield receptor and receiving a superconducting electromagnet, and
It is coupled to the outer periphery of the bobbin and is connected to the end of the second end of the refrigerator, and comprises a second end metal heat conductor for discharging heat,
The connection between the end portion of the second end of the refrigerator and the second end of the metal heat conductor is made of a two end end flexible metal heat conduction link connecting both ends of each other.
Refrigerant-free electromagnet device

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