KR102054827B1 - Two-channel radio frequency rotary joint with direct cooling of the central conductor tube - Google Patents

Abstract

Provided is a two-channel rotary joint for radio frequency with a method for directly cooling a central conductor. By connecting a cooling block to a central conductor positioned within a two-channel rotary joint, a fluid for cooling directly moves into the central conductor. The fluid for cooling is supplied from the cooling block to circulate inside the central conductor. The circulated fluid may be returned to the cooling block.

Description

Two-channel radio frequency rotary joint with direct cooling of the central conductor tube}

The present invention relates to a rotary joint for radio frequency, and more particularly, to a rotary joint for two-channel radio frequency using a central conductor direct cooling method.

In general, a rotary joint refers to a kind of rotary coupler for connecting signal lines between a fixed body and a rotating body.

1 is a view showing a conventional one-channel rotary joint, Figure 2 is a view showing a conventional two-channel rotary joint. The one-channel rotary joint means that there is one path such as a waveguide for transmitting energy, and the two-channel rotary joint means that there are two paths, such as a waveguide, that can transmit.

Referring to FIG. 1, the one-channel rotary joint includes a fixed part fixed to the center conductor at one end of a path such as a waveguide, and a rotating part rotatable in the vertical direction of the length of the center conductor at one end thereof. The bearing is attached internally to reduce the pressure.

Referring to FIG. 2, the two-channel rotary joint has two transmission paths, Channel A and Channel B. In order to prevent the passage of energy in a specific frequency range, a central conductor, a bearing which reduces friction of a rotating part, and a transmission in a specific frequency range are provided. It consists of chokes etc. grooved in the pipe wall.

The maximum allowable power of the rotary joint for radio frequency transmission with an average power of several kW or more is determined by the exposure maximum allowable temperature of the center conductor, and the temperature rises rapidly in proportion to the transmission energy. Therefore, lowering the temperature of the center conductor is directly related to the performance of the rotary joint.

In general, the method of lowering the temperature of the center conductor is indirect cooling with the cooling block which is mechanically connected to the center conductor (3- (a)). However, this cooling method has a limitation in performance as the center conductor attached to the cooling block is indirectly cooled by the heat conduction method.

Patent Publication 10-2018-0078013 Patent Registration 10-1309627

The technical problem to be solved by the present invention to solve the above limitations of the indirect cooling method, the center conductor is increased in proportion to the transmission energy of the rotary joint by increasing the cooling efficiency by changing the central conductor cooling method in the rotary joint to direct cooling method By reducing the temperature of the conductor, the maximum allowable power of the rotary joint itself is increased.

The problem of the present invention is not limited to those mentioned above, and other problems that are not mentioned will be clearly understood by those skilled in the art from the following description.

As a means for solving the above-described technical problem, according to an embodiment of the present invention, a two-channel radio frequency rotary joint using the central conductor direct cooling method, the first rotating body having a spherical waveguide and connected to the A body part including a second rotatable body rotatably assembled with the first rotatable body and connected with a spherical waveguide; A bearing member for reducing rotational friction between the first rotating body and the second rotating body; An airtight member for sealing between the engaging surfaces between the first and second moving bodies; And a central conductor in the form of a tube bored from the center of the body portion to allow energy to pass between the anode ends.

The central conductor may include: a cooling unit configured to lower a temperature of the body part by allowing a cooling fluid to move directly inside the central conductor; And a cooling block mechanically connected to one end of the cooling unit to supply a fluid to the cooling unit and to collect the fluid circulated through the cooling unit.

The cooling unit divides the internal space into partitions opposite to the cooling block at the end or middle part thereof, and receives the fluid supplied from the cooling block to one side of the partition wall and passes the inside, and passes through the open part to the other side of the partition wall. And discharging a fluid to the cooling block.

On the other hand, according to another embodiment of the present invention, the cooling unit of the rotary joint for two-channel radio frequency using the central conductor direct cooling method further includes a cooling tube in the inner space opposite the end or the middle of the cooling block open; Passing the fluid supplied from the cooling block to the inside of the cooling tube and passing through, and passing through the open portion of the fluid passing through the outside of the cooling tube to the cooling block; may include.

The first rotating body and the second rotating body communicate with the spherical waveguide with spaced seams, and the second rotating body communicates with the seam in the radial direction at an upper end adjacent to the first rotating body, and then in a predetermined space. It is to include a choke having a.

The first rotating body may further include: a main body in which a spherical waveguide is formed; A first cover spaced apart from an outer circumferential surface of the second rotating body, the sealing cover having airtightness by the hermetic member, and fixed to the main body to support the bearing member; And a second cover inserted between the second rotating body and the first cover to fix the airtight member.

According to the invention,

In the indirect cooling method by the thermal conductivity of the conventional simple center conductor in the two-channel rotary joint for radio frequency (RF) transmission / reception, the center conductor is secured directly by the cooling fluid by securing a path to move the fluid directly inside the center conductor. By switching to the cooling method, the cooling efficiency is increased compared to the indirect cooling method to increase the maximum allowable power of the rotary joint.

The problem of the present invention is not limited to those mentioned above, and other problems that are not mentioned will be clearly understood by those skilled in the art from the following description.

1- (a) is an example of a one-channel waveguide rotary joint form, FIG. 1- (b) is an example of a one-channel waveguide rotary joint cross section,
2- (a) is an example of a two-channel waveguide rotary joint form, FIG. 2- (b) is an example of a two-channel waveguide rotary joint cross section,
Figure 3 (a) is a diagram of a conventional two-channel rotary joint of the center conductor indirect cooling method, Figure 3- (b) is a two-channel channel of the direct cooling method including a partition in the center conductor according to an embodiment of the present invention. As for the form of the rotary joint,
4 is a cross-sectional view of a conventional two-channel rotary joint indirectly cooled central conductor;
FIG. 5 is a configuration diagram of a direct-cooling two-channel rotary joint including a tube inside the central conductor according to an embodiment of the present invention, and a passage diagram of fluid passage.

Objects, other objects, features and advantages of the present invention will be readily understood through the following preferred embodiments associated with the accompanying drawings. However, the present invention is not limited to the embodiments described herein and may be embodied in other forms. Rather, the embodiments introduced herein are provided so that the disclosure may be made thorough and complete, and to fully convey the spirit of the present invention to those skilled in the art.

Where the terms first, second, etc. are used herein to describe the components, these components should not be limited by these terms. These terms are only used to distinguish one component from another. The embodiments described and illustrated herein also include complementary embodiments thereof.

Also, the terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. In this specification, the singular also includes the plural unless specifically stated otherwise in the phrase. As used herein, the words 'comprises' and / or 'comprising' do not exclude the presence or addition of one or more other components.

In describing the specific embodiments below, various specific details are written to more specifically explain and help understand the invention. However, a person skilled in the art can understand that the present invention can be used without these various specific contents.

In some cases, it is mentioned in advance that parts of the invention which are commonly known in the description of the invention and which are not highly related to the invention are not described in order to prevent confusion in explaining the invention without cause.

Hereinafter, with reference to the accompanying drawings for the specific technical content to be carried out in the present invention will be described in detail.

1 shows a one-channel waveguide rotary joint form (1- (a)) and its cross section (1- (b)), FIG. 2 shows a two-channel waveguide rotary joint form (2- (a)) and a two-channel waveguide rotary joint form An example of a conventional rotary joint is shown as (2- (b)).

First, in one embodiment of the two-channel rotary joint according to the present invention, as shown in FIG. 2, the first rotating body 110 is configured to connect the rotating member to the relative fixing member, and has a spherical waveguide 300. And a body part including a second rotatable body 120 rotatably assembled with the first rotatable body and connected with the spherical waveguide 300 to reduce rotational friction between the first rotatable body and the second rotatable body. To the bearing member 520, the sealing member 900 for sealing between the coupling surface between the movement surface of the first and second rotating body, and in the form of a tube in the inner perforated at the center of the body portion, the anode end It comprises a central conductor 410 to pass energy between. In FIG. 2- (a), the fixing part 220 of the channel B is removed.

Figure 3 (a) is a conventional two-channel rotary joint of the center conductor 410 indirect cooling method, the RF (radio frequency) rotary joint for the temperature rises in proportion to the transmission energy, the maximum allowable power is The maximum allowable exposure temperature of the center conductor 410 is determined.

In the case of transmitting a very small electric power of about several tens of watts through the rotary joint, the heat dissipation is usually performed by a self-mechanical device to which the rotary joint is attached, without using the cooling block 800 (Cold Block).

On the other hand, in the case of high power transmission in which the power transmitted is more than several hundred watts on average, the temperature of the central conductor 410 rises in proportion to the transmission energy in the rotary joint, and accordingly, the instrument expands due to the temperature rise, and mechanical errors may occur. Due to the change in the temperature (heating) characteristics of the surface resistance, the transmission capacity of the rotary joint may be degraded.

Therefore, according to one embodiment of the two-dimensional rotary joint according to the present invention, in this case it is possible to cool through the cooling fluid by attaching the cooling block 800 to the rotary joint. However, the indirect cooling method of simply attaching the cooling block 800 to the center conductor 410 is cooled by the center conductor 410 by the thermal conductivity of the center conductor 410 itself (3- (a)).

Figure 3 (b) is a configuration diagram of a two-channel rotary joint of the direct cooling method including a partition in the center conductor 410 according to an embodiment of the present invention (3- (b)), Figure 4 is a conventional center conductor 410 is a cross-sectional view of the indirect cooling two-channel rotary joint, Figure 5 is a schematic view of the direct-cooling two-channel rotary joint including a tube inside the central conductor 410 according to an embodiment of the present invention and the passage of fluid As a path diagram, a preferred embodiment of a two-channel rotary joint of the central conductor 410 direct cooling method according to the present invention will be described in detail with reference to the drawings.

Next, another embodiment of the two-channel rotary joint of the central conductor 410 direct cooling method according to the present invention is a cooling fluid directly inside the central conductor 410 as shown in Figs. The cooling unit 700 and the cooling unit 700 to lower the temperature of the body portion to be moved mechanically connected to one end of the cooling unit 700 to supply fluid to the cooling unit 700, the cooling unit 700 It comprises a cooling block 800 for collecting the circulated fluid.

The cooling unit 700 represents the inside of the central conductor 410 through which the cooling fluid can move. The cooling unit 700 receives the cooling fluid from the cooling block 800 to directly circulate the cooling unit 700 and cools the circulated cooling fluid again. The central conductor 410 is cooled by discharging to the block 800.

The cooling unit 700 may be a method of inputting and outputting a fluid by forming a partition therein. In this case, the partition wall may be designed such that the cooling fluid flows through the central conductor 410 in the form of a tube in a shape in which the end or the middle portion of the partition is opposite to the cooling block 800. Assuming that the inside of the central conductor 410 is divided into left and right through the partition wall, and the fluid is discharged from the cooling block 800 to the left side of the partition wall and the fluid is recovered to the right side of the partition wall, the fluid is discharged from the cooling block 800 to the left side of the partition wall. Through the center conductor 410 through the partition wall is moved to the right side of the partition through the open portion is moved back along the center conductor 410 is recovered to the cooling block (800).

In addition, the cooling unit 700 may be configured to form a cooling tube therein to input and output fluid. In this case, the cooling tube may be designed such that the cooling fluid flows through the central conductor 410 in the form of a tube in a form in which an end or an intermediate portion opposite to the cooling block 800 is partially opened. The fluid is discharged from the cooling block 800 and moves along the central conductor 410 through the inside of the cooling tube, and then moves out of the cooling tube through the open portion of the cooling tube, and then moves along the central conductor 410 to cool the cooling block. With 800.

In the two-channel rotary joint of the central conductor 410 direct cooling method according to the present invention, the first and second rotors are connected to the spherical waveguide 300 with a spaced seam, the second time The whole may include a choke having a predetermined space in communication with the seam in the radial direction at an upper end adjacent to the first rotating body.

In addition, the first rotating body has a sealing body which is spaced from the main body formed with a spherical waveguide 300 and the outer circumferential surface of the second rotating body is sealed by the hermetic member and fixed to the main body so that the bearing member ( 520 may include a first cover supporting the second cover and a second cover inserted between the second rotating body and the first cover to fix the airtight member.

100: rotating part 110: channel A (1) rotating part 120: channel B (2) rotating part
200: fixing part 210: channel A (1) fixing part 220: channel B (2) fixing part
300: waveguide
400, 410: center conductor
500, 510, 520: Bearing
600: Choke
700: cooling unit 800: cooling block
900: airtight member

Claims (6)

delete delete In the radio frequency rotary joint configured to connect the rotating member to the relative stationary member,
A body part including a first rotating body having a spherical waveguide and connected to the first rotating body, the second rotating body being rotatably assembled with the first rotating body;
A bearing member for reducing rotational friction between the first rotating body and the second rotating body;
An airtight member sealing a coupling surface between the first rotating body and the moving surface of the second rotating body; And
Cooling fluid to lower the temperature of the body portion by allowing the cooling fluid to move directly inside the central conductor therein is mechanically connected to one end of the cooling unit to supply the fluid to the cooling unit, circulating the cooling unit A central conductor comprising a cooling block for collecting the fluid, the center conductor characterized in that in the form of a tube bored inside the body portion, passing energy between the anode ends;
Including but not limited to:
The cooling unit
The internal space is divided into partitions having opposite ends or intermediate portions open to the cooling block so that the fluid supplied from the cooling block is passed through either side of the partition wall, and the fluid passes through the open portion to the other side of the partition wall. Discharging it to the cooling block;
Two-channel rotary joint, characterized in that. In a radio frequency rotary joint configured to connect a rotating member to a relative stationary member,
A body part including a first rotating body having a spherical waveguide and connected to the first rotating body, the second rotating body being rotatably assembled with the first rotating body;
A bearing member for reducing rotational friction between the first rotating body and the second rotating body;
An airtight member sealing a coupling surface between the first rotating body and the moving surface of the second rotating body; And
Cooling fluid to lower the temperature of the body portion by allowing the cooling fluid to move directly inside the central conductor therein is mechanically connected to one end of the cooling unit to supply the fluid to the cooling unit, circulating the cooling unit A central conductor comprising a cooling block for collecting the fluid, the center conductor characterized in that in the form of a tube bored inside the body portion, passing energy between the anode ends;
Including but not limited to:
The cooling unit,
A cooling tube having an end or an intermediate portion opposite to the cooling block in the inner space;
And further comprising, passing through the fluid supplied from the cooling block to the inside of the cooling tube, and discharges the fluid passing through the outside of the cooling tube through the open portion to the cooling block;
2-channel rotary joint, characterized in that. The method according to claim 3 or 4,
The first rotating body and the second rotating body,
Communicating with a spherical waveguide with spaced seams,
The second rotating body,
A choke having a predetermined space is formed in communication with the seam in the radial direction at an upper end adjacent to the first rotating body;
2-channel rotary joint, characterized in that. The method according to claim 3 or 4,
The first rotating body,
A main body in which a spherical waveguide is formed;
A first cover spaced apart from an outer circumferential surface of the second rotating body and having a sealing surface which is hermetically sealed by the hermetic member and fixed to the main body to support the bearing member; And
A second cover inserted between the second rotating body and the first cover to fix the airtight member;
2-channel rotary joints comprising a.

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