KR20230026007A - Positioner interface system for multipurpose application in EMC test facility - Google Patents

Abstract

The present invention relates to a positioner interface system disposed in the chamber of an EMC test facility and coupled to an artificial satellite. A conventional positioner is fixed in the chamber or installed to move a short distance on a bottom. When the chamber is used for multiple purposes, there are space restrictions when conducting tests without using the positioner due to the fixed positioner. The present invention proposes a movable positioner interface system wherein wheels are disposed at the lower end of the positioner and a rail system is buried in the bottom of a multipurpose chamber.

Description

Positioner interface system for multipurpose application in EMC test facility}

The present invention relates to a positioner interface system, and more particularly, to a positioner interface system disposed in a chamber of an electromagnetic wave test facility and coupled to a satellite.

In order to measure satellite system electromagnetic waves and RF (communication antenna) characteristics, a special test facility called an electromagnetic wave chamber is required. 1 is an exemplary diagram of an electromagnetic wave test chamber. Area A is an area where electromagnetic testing is conducted, and equipment other than electromagnetic testing equipment must be placed outside the area. Since RF characteristics must configure far-field conditions, a separate device capable of forming a far-field within the electromagnetic wave chamber must be installed. Referring to FIG. 2, a chamber for antenna measurement is called CPTR (compact payload test range) or CATR (Compact antenna test range), and a reflector system, a positioner system, and a feeder system are included as main components in the electromagnetic wave chamber, and usually The CPTR components in the electromagnetic wave chamber are fixedly installed. Depending on the configuration and installation of the reflector system and feeder system, the testable area is defined and the performance of the test site is determined.

The center of the testable area is 5 to 6 meters above the ground. Accordingly, a positioner system is configured to position the satellite in the test area and configure the satellite to meet the test conditions. A typical positioner system is installed very robustly and stably as it is driven by 5 axes (at least 3 axes) with the satellite mounted in a high position.

Since the purpose of use is different for the satellite electromagnetic test chamber and the satellite communication system (RF/antenna) measurement chamber, it is common to configure and operate them independently. In order to efficiently use the chamber space, a multi-purpose chamber capable of performing various tests is required. When conducting an electromagnetic wave test in an antenna measurement chamber, it is difficult to access the system or configure a test environment. When performing an electromagnetic wave test in the middle of a reflector system or positioner system, there are many restrictions because it must be configured to prevent reflection from metal objects and use a limited space. .

On the other hand, when trying to remove the positioner from the test area, if there is a crane inside the chamber, it can be moved by crane, but in this case, the positioner must be moved as a whole or disassembled into several pieces according to the capacity of the crane. Disassembling and moving a huge structure and then precisely assembling it again when using it is cumbersome or inconvenient, so this method is difficult to be a realistic alternative.

When a component for measuring a communication system is installed and used as a multi-purpose facility, it is expected that there will be many limitations in performing an electromagnetic wave test of a satellite system if the prior art is applied. It is impossible to use satellite fixtures other than the positioners installed in the CPTR, and when using only the positioners already installed, the accessibility to the satellite is significantly reduced as the installation location of the satellite increases, and it is not easy to set up the electromagnetic wave test equipment. In addition, when using a small-sized movable jig, there is a space limitation that can be tested. To overcome this, an interface system capable of moving the positioner system is required.

Therefore, the present invention has been made to solve the problems of the prior art as described above, and proposes a positioner interface system for easily moving a positioner installed in a chamber according to the present invention.

In addition, a positioner interface system in which a rail system is buried in the bottom surface of the chamber and a cover corresponding to the cross section of the rail system is disposed to facilitate movement of auxiliary devices is proposed.

In addition, the rail system proposes a positioner interface system in which a plurality of rails are connected to each other and wheels are formed in a spherical shape so that the positioner moves in various directions.

The present invention is a positioner interface for moving a positioner spaced apart from the bottom surface of a multi-purpose electromagnetic wave chamber for electromagnetic wave test and communication system measurement, comprising: a plurality of wheels provided on a lower surface of the positioner; a controller provided in the positioner to control the movement of the wheel; and a rail system buried in the bottom surface of the multipurpose electromagnetic wave chamber and into which the wheels are inserted.

In addition, the rail system is characterized in that it includes a rail formed by a set of a plurality of mutually parallel rail grooves.

In addition, the rail system includes a plurality of straight rails, and the rails extend in the same or different directions, and one rail is formed to meet at least one other rail.

In addition, the rails are characterized in that they are connected in directions perpendicular to each other.

In addition, the rail system is characterized in that it includes at least one curved rail.

Further, it includes peripheral grooves formed along the longitudinal direction on both sides of the rail groove in the width direction and having a step difference between the bottom surface and the lower surface of the rail groove.

In addition, it is inserted into the rail system, and includes a cover corresponding to the cross-sectional shape of the rail groove and the peripheral groove.

In addition, the peripheral groove includes a coupling groove formed at regular intervals in the longitudinal direction, and a fixing device inserted into the coupling groove to limit movement of the positioner.

In addition, the wheel is formed in a spherical shape and is characterized in that it moves along the rail system.

In addition, the wheel is formed in a spherical shape, a plurality of grooves are formed on the outer surface, and the rail groove includes a protrusion corresponding to the groove, and the groove and the protrusion are engaged and moved.

In addition, the satellite to be tested; a positioner for arranging the satellite to be spaced apart from the bottom surface; Electromagnetic wave test space equipped with electromagnetic wave test equipment; Communication system measurement space equipped with communication system measurement equipment; A multi-purpose electromagnetic wave chamber comprising the positioner interface according to claim 1 for moving the positioner so that the positioner can be moved and disposed in each of the electromagnetic wave test space and the communication system measurement space.

According to the present invention, a positioner interface system for easily moving a positioner disposed in a multipurpose chamber is proposed.

In addition, a positioner interface system in which a rail system is buried in the bottom surface of the chamber and a cover corresponding to the cross section of the rail system is disposed to facilitate movement of auxiliary devices is proposed.

In addition, the rail system proposes a positioner interface system in which a plurality of rails are connected to each other and wheels are formed in a spherical shape so that the positioner moves in various directions.

1 is a layout diagram of an electromagnetic wave test chamber
Figure 2 is a communication system measurement chamber arrangement
3 is a plan view of the multipurpose chamber
4 is a plan view of a multi-purpose chamber to which the present invention is applied
5 is a perspective view of the rail system of the present invention
6 and 7 are exemplary views of the cover of the present invention
8 is an exemplary view of the fixing device of the present invention
9 is a modified example of the present invention

Conventional positioners are fixed in the chamber or installed to move a short distance on the floor surface, and when the chamber is used for multiple purposes, space is limited during a test without using the positioner due to the positioner having a fixed position.

The present invention proposes a movable positioner interface system by disposing wheels at the lower end of the positioner and forming a rail system buried in the bottom surface of a multipurpose chamber.

Hereinafter, a positioner interface system according to the present invention having the configuration described above will be described in detail with reference to the accompanying drawings.

[1] Overall configuration and operating principle of the present invention

3 is a plan view of a multi-purpose chamber for electromagnetic wave testing. The purpose of the multi-purpose chamber is to conduct electromagnetic wave tests and communication system measurement tests in the same space. Referring to FIG. 3 , area A in the space of the multi-purpose chamber is a space for electromagnetic testing. An electromagnetic test use space is set in the multi-purpose chamber, and when the electromagnetic test is conducted, other structures (2) other than the electromagnetic test equipment are not placed in the space. When configuring a multi-purpose chamber for electromagnetic wave testing, a structure 2 for testing a communication system may be arranged.

At this time, in the case of the electromagnetic wave test, it is necessary to configure so that reflection of the metal object does not occur, so that the metal surface of the structure 2 disposed in the multipurpose chamber is not exposed.

4 is a plan view of a multi-purpose chamber to which the present invention is applied. As a positioner 200 interface that moves the positioner 200 that disposes the satellite away from the bottom surface 1 of the multi-purpose electromagnetic wave chamber for electromagnetic wave test and communication system measurement test to be movable and dispositionable, provided on the lower surface of the positioner 200 a plurality of wheels; a controller provided in the positioner 200 to control the movement of the wheel; A rail system 300 formed buried in the bottom surface 1 of the multipurpose electromagnetic wave chamber and into which the wheels are inserted is included.

Referring to FIG. 4 , a rail system 300 guiding the positioner located in area A to leave area A is disposed. The rail system 300 is characterized in that it is disposed so as to be buried in the bottom surface 1 of the multipurpose chamber.

At this time, the rail system 300 includes a rail 310 in which a plurality of mutually parallel rail grooves are formed as a set. The rail system 300 includes a plurality of straight rails or curved rails. Straight rails and curved rails can be installed simultaneously. The rails 310 extend in the same or different directions, and one rail meets at least another rail.

In addition, in the rail system 300, the rails 310 may be connected in directions perpendicular to each other.

The storage location of the positioner 200 is arranged so as to be spaced apart from the door 4 as well as the space used for the electromagnetic wave test, so that other test equipment can be moved.

5 is a perspective view of a rail system. The positioner is driven by a precise motor control method, and when the positioner is used for its purpose, basic functions such as movement, control, and stop of the positioner are controlled by the control unit provided in the positioner.

Referring to FIG. 5 , in the rail system, a rail 310 in which a plurality of parallel rail grooves 311 are formed as a set is disposed, and one rail 310-1 is at least one other rail 310-2. ) are arranged to meet. A plate 210 is disposed at the lower end of the positioner, and the positioner 200 is moved along the rail system 300 by wheels disposed on the lower surface of the plate 210.

At this time, the wheel is formed in a spherical shape and moves along the rail system 300 . Since the weight of the positioner 200 is quite heavy, it is difficult to apply a normal wheel of a general cylindrical type, and thus, by applying a wheel formed in a spherical shape, restrictions on directionality are minimized. As a result, the rail formed in a straight line and the rail formed in a curve can be moved without restriction, and the axis of the wheel is freely moved without deformation in the section where the rails intersect.

In addition, the wheels may be modified so that more frictional force for moving the positioner 200 is applied. In general, the surface material and outer shape of the wheel can be changed to increase the frictional force.

A modified embodiment of the wheel will be described. The wheel is formed in a spherical shape, a plurality of grooves are formed on an outer surface, and the rail groove includes a protrusion corresponding to the groove, and the groove and the protrusion are engaged and moved.

When controlling the movement of the positioner, a groove is formed on the outer surface of the wheel so that power can be reliably received from a motor disposed in the positioner in the same manner as a gear. In addition, by disposing a protrusion corresponding to the groove on the lower surface of the rail groove, the wheels are engaged and moved, the positioner is precisely moved, and the moved distance can be checked. The groove formed on the outer surface of the wheel may be formed in a hemispherical shape.

The cross section of the rail groove 311 may be formed in a semicircular shape, and a shape in which a spherical wheel can easily move is sufficient.

6 and 7 are exemplary views of the cover of the present invention. After moving the positioner out of the electromagnetic test use space, cover the rail groove 311 of the rail system 300 formed buried in the bottom surface of the multipurpose chamber with the cover 400 to set up satellites or specimens in the test area make this possible

Referring to FIG. 6 , a rail system 300 is formed on the bottom surface of the multipurpose chamber, and a rail groove 311 into which wheels are inserted is formed. The rail groove 311 is filled by the cover 400 corresponding to the cross section of the rail groove 311 . It also applies to straight rails, curved rails and rails with intersections.

At this time, the cover 400 may simply have a cross section corresponding to the rail groove 311, but the portion inserted into the rail groove 311 is formed of a plurality of polygonal pillars to support the load received vertically and at the same time weight can be reduced.

It may be covered with a simple metal plate, but when the width of the groove of the rail system 300 is wide, when a heavy satellite structure passes, the rail groove 311 may not withstand the load and may be bent. In addition, when the metal cover 400 is raised on the rail groove 311, a step may occur between the existing floor surface 1 and the cover 400, which may hinder the movement of the satellite structure. Therefore, the cover 400 is formed in a structure in which a portion entering the rail groove 311 can receive force.

Referring to FIG. 7 , the rail system 300 is formed along the longitudinal direction on both sides in the width direction of the rail groove 311, and a step is formed between the bottom surface 1 of the chamber and the lower surface of the rail groove 311. A peripheral groove 312 is included. The peripheral groove 312 is configured at a height lower than the bottom surface 1 of the existing chamber. The cover 400 is inserted into the rail system and is formed to correspond to the cross-sectional shapes of the rail groove 311 and the peripheral groove 312. The cover 400 is inserted into the rail system to make it flat with the bottom surface 1 of the chamber. Due to this, the cover 400 can withstand the load of equipment moving on the cover 400 and eliminates the step difference with the bottom surface 1 of the chamber.

When the cover 400 is placed and subjected to load by moving equipment, the peripheral groove 312 receives the load applied to the rail groove 311 and prevents the lower surface of the rail groove 311 from being deformed.

8 is an exemplary view of the fixing device of the present invention. When using the positioner, precision control is performed using power, but after moving the positioner, power is not supplied, so it is fixed by its own load. However, since there is a risk of slipping, a fixing device is placed at the positioner fixing position for stable fixation.

The fixing device 500 can be installed on the bottom surface of the multipurpose chamber, and an example of being installed in the peripheral groove 312 will be described. The peripheral groove 312 includes coupling grooves 313 spaced at regular intervals in the longitudinal direction, and the fixing device 500 is inserted into the coupling groove 313 to limit the movement of the positioner 200 .

Referring to FIG. 8, a rail groove 311 is formed on the bottom surface 1 of the multipurpose chamber, and the bottom surface 1 of the multipurpose chamber and the rail groove 311 are formed on both sides in the width direction of the rail groove 311. A peripheral groove 312, which is a step with respect to the lower surface, is formed. In the peripheral groove 312, a coupling groove 313 formed in a vertical direction is formed, and the fixing device 500 is inserted into the coupling groove 313 to limit the movement of the positioner 200.

At this time, the fixing device 500 is inserted into one or more coupling grooves 313. In addition, the upper surface of the fixing device 500 may be disposed equal to or lower than the bottom surface 1 of the chamber, and the structure may be covered so as not to interfere with the electromagnetic wave test and the communication system measurement test.

According to the present invention, the positioner can be easily moved so that one chamber can be used for multiple purposes, and other auxiliary devices can be easily moved by burying and arranging the rail system on the bottom surface of the chamber and filling the groove formed through the cover. It has the effect of making it happen.

In addition, the rail system to be arranged may have a curved rail as well as a straight rail, and spherical wheels are arranged to easily move along the rail system.

The positioner interface system of the present invention can be applied to all electromagnetic wave testing facilities and can be applied to all mechanical and electronic industries.

Since the present invention can make various changes and have various embodiments, specific embodiments are illustrated in the drawings and described in detail. However, this is not intended to limit the present invention to specific embodiments, and should be understood to include all modifications, equivalents, or substitutes included in the spirit and technical scope of the present invention.

It is understood that when an element is referred to as being "connected" or "connected" to another element, it may be directly connected or connected to the other element, but other elements may exist in the middle. It should be.

Unless defined otherwise, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which the present invention belongs.

Terms such as those defined in commonly used dictionaries should be interpreted as having a meaning consistent with the meaning in the context of the related art, and unless explicitly defined in this application, it should not be interpreted in an ideal or excessively formal meaning. don't

The present invention is not limited to the above embodiments, and the scope of application is diverse, and various modifications and implementations are possible without departing from the gist of the present invention claimed in the claims.

Reference Numerals 1: bottom surface 2: structure 3: reflector system
4 : door
100: satellite
200: positioner
210: plate
300: rail system
310: rail
311: rail groove 312: peripheral groove 313: coupling groove
400: cover
500: fixture

Claims (11)

As a positioner interface that moves and displaces a positioner that is installed away from the bottom of the multi-purpose electromagnetic wave chamber for electromagnetic wave test of satellite and communication system measurement,
A plurality of wheels provided on the lower surface of the positioner;
a controller provided in the positioner to control the movement of the wheel; and
a rail system buried in the bottom surface of the multi-purpose electromagnetic wave chamber and into which the wheels are inserted;
A positioner interface including a.
According to claim 1,
The positioner interface, characterized in that the rail system comprises a rail formed by a set of a plurality of mutually parallel rail grooves.
According to claim 2,
The rail system includes a plurality of straight rails,
The positioner interface, characterized in that the rails extend in the same or different directions, and one rail is formed to meet at least one other rail.
According to claim 3,
The positioner interface, characterized in that the rails are connected in a direction perpendicular to each other.
According to claim 2,
The positioner interface according to claim 1, wherein the rail system comprises at least one curved rail.
According to claim 2,
The positioner interface includes peripheral grooves formed along the longitudinal direction on both sides of the rail groove in the width direction and having a step difference between the bottom surface and the lower surface of the rail groove.
According to claim 6,
A positioner interface including a cover inserted into the rail system and corresponding to cross-sectional shapes of the rail groove and the peripheral groove.
According to claim 6,
The peripheral groove includes coupling grooves formed at regular intervals in the longitudinal direction,
A positioner interface including a fixing device inserted into the coupling groove to limit movement of the positioner.
According to claim 2,
The positioner interface, characterized in that the wheel is formed in a spherical shape and moves along the rail system.
According to claim 2,
The positioner interface, characterized in that the wheel is formed in a spherical shape, a plurality of grooves are formed on an outer surface, and the rail groove includes a protrusion corresponding to the groove, so that the groove and the protrusion are engaged and moved.
satellite under test;
a positioner for arranging the satellite to be spaced apart from the bottom surface;
Electromagnetic wave test space equipped with electromagnetic wave test equipment;
Communication system measurement space equipped with communication system measurement equipment; and
a positioner interface according to claim 1 for moving the positioner so that the positioner can be moved and disposed in each of the electromagnetic wave test space and the communication system measurement space;
A multi-purpose electromagnetic wave chamber comprising a.

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