KR102661011B1 - Device for measuring waves shield and absorption - Google Patents

Abstract

The present invention provides a small electromagnetic wave shielding and absorption performance measuring device. A compact electromagnetic wave shielding and absorption performance measuring device according to the present invention has a main body having a partitioned first measurement space and a second measurement space, and an inlet portion for guiding the introduction of a measurement object into the first measurement space or the second measurement space. wealth; a partition wall installed on the main body to partition the first measurement space and the second measurement space, and having a connection hole connecting the first measurement space and the second measurement space; an opening and closing part disposed on the partition wall and opening and closing the connection hole; a first measurement unit that measures the electromagnetic wave absorption rate of the measurement object located in the first measurement space; a second measuring unit that measures an electromagnetic wave shielding rate of the measurement object located in the second measurement space; And, a control unit that transmits the measured electromagnetic wave absorption rate and electromagnetic wave shielding rate.

Description

Small electromagnetic wave shielding and absorption performance measuring device {Device for measuring waves shield and absorption}

The present invention relates to a small electromagnetic wave shielding and absorption performance measuring device, and more specifically, to a small electromagnetic wave shielding and absorption performance measuring device that can measure the electromagnetic wave shielding and absorption performance of an object in one device.

Conventionally, measuring the degree of influence of noise or electromagnetic waves generated from electronic devices on the human body or other electronic devices is called electromagnetic wave measurement or electromagnetic compatibility (EMC) test.

As electronic devices become more digital and faster, the amount of current circulating within the circuits of electronic devices increases, and the likelihood of electronic devices generating more noise and electromagnetic waves increases.

For this reason, regulations on electromagnetic noise or electromagnetic waves generated from electronic devices are being strengthened, and various electromagnetic wave measurement systems are being proposed to measure whether electronic devices satisfy these regulations.

Among electromagnetic wave measurement systems, there is a system that measures conducted noise (Conducted Emissions) and a system that measures radiated noise (Radiated Emissions). Noise or electromagnetic waves generated from electronic devices can be propagated to other electronic devices through wires such as power sources. Measuring noise propagated to other electronic devices through wires connected to electronic devices in this way is called conductive noise measurement. In contrast, electronic devices can radiate noise or electromagnetic waves into the air according to the flow of electromagnetic energy within the circuit, and measuring noise or electromagnetic waves radiated into the air in this way is called radiated noise measurement.

Meanwhile, radiated noise is received through a separate antenna for measuring electromagnetic waves and transmitted through wires, and the size of the electric signal propagated through these wires is small. It is necessary to convert such a small electrical signal into an electrical signal higher than the noise floor existing in the surrounding area and transmit it to an electromagnetic wave measurement signal analyzer.

Meanwhile, in this electromagnetic wave measurement system, the sample device that is the subject of electromagnetic wave measurement is placed inside an electromagnetic wave anechoic chamber treated with electromagnetic wave shielding and absorption, and the electromagnetic waves generated by the sample device are received through an antenna located inside the electromagnetic wave anechoic chamber. Analyze it using an external signal analyzer (which may be a computer).

Additionally, in order to measure electromagnetic wave absorption and shielding performance, only the directly reflected waves of the pure sample, which is the measurement object, must be measured. However, in the related art, there is a problem in that it is difficult to accurately measure electromagnetic wave performance due to the existence of electromagnetic waves directly transmitted from the actual transmission antenna and reflected waves from surrounding reflectors.

Additionally, conventionally, the electromagnetic wave absorption and shielding performance of an object is measured using an electromagnetic wave absorption and shielding performance measuring instrument. However, conventionally, electromagnetic wave absorption and electromagnetic wave shielding performance were measured using separate devices. As each device is used, the measurement process is delayed, and the measurement conditions that occur when the measurer moves the object to the corresponding process change. Therefore, in the related art, there is a problem in that it is difficult to accurately measure electromagnetic waves for an object.

Prior literature related to the present invention includes Republic of Korea Patent Registration No. 10-1530336 (June 15, 2015).

The first object of the present invention relates to a small electromagnetic wave shielding and absorption performance measuring device. More specifically, it is to provide a small electromagnetic wave shielding and absorption performance measuring device that can measure the electromagnetic wave shielding and absorption performance of an object in one device. .

In addition, the second purpose of the present invention is to provide a small electromagnetic wave shielding and absorption performance measuring device that can perform two or more measurement processes in one device and enable sequential measurement processes for objects to be performed automatically.

In addition, the third object of the present invention is to achieve accurate electromagnetic wave measurement of an object by constructing a wall that can block and dissipate electromagnetic waves induced by other components such as antennas in each measurement space and reflected waves reflected from surrounding reflectors. The goal is to provide a compact electromagnetic wave shielding and absorption performance measuring device.

In order to achieve the above problems, the present invention provides a small electromagnetic wave shielding and absorption performance measuring device.

A compact electromagnetic wave shielding and absorption performance measuring device according to the present invention has a main body having a partitioned first measurement space and a second measurement space, and an inlet portion for guiding the introduction of a measurement object into the first measurement space or the second measurement space. wealth; a partition wall installed on the main body to partition the first measurement space and the second measurement space, and having a connection hole connecting the first measurement space and the second measurement space; an opening and closing part disposed on the partition wall and opening and closing the connection hole; a first measurement unit that measures the electromagnetic wave absorption rate of the measurement object located in the first measurement space; a second measuring unit that measures an electromagnetic wave shielding rate of the measurement object located in the second measurement space; And, a control unit that transmits the measured electromagnetic wave absorption rate and electromagnetic wave shielding rate.

The opening and closing unit includes a first moving rail installed in an area around the upper and lower ends of the connection hole,

a door arranged to be linearly movable on the first moving rail;

A first linear motor is provided to move the door to open and close the connection hole under the control of the control unit,

The first moving rail and the door,

It is preferably formed of an electromagnetic wave shielding material.

In addition, a second moving rail is installed in the main body portion to connect the first measurement space and the second measurement space through the connection hole,

A seating member on which the measurement object is placed is movably disposed on the second moving rail,

The seating member is preferably moved by a second linear motor driven under the control of the control unit.

The seating member is formed of an electromagnetic wave shielding material,

The periphery of the seating member is preferably formed in an embossed shape to form an anti-reflective structure.

An electromagnetic wave anti-reflection layer is formed on the first inner wall of the first measurement space and the second inner wall of the second measurement space,

It is preferable that a plurality of protruding members having sharp ends are formed on the outer surface of the electromagnetic wave anti-reflection layer.

In particular, the electromagnetic wave anti-reflection layer is formed in multiple layers,

It is preferable that a vacuum layer is further formed between the multiple electromagnetic wave anti-reflection layers.

In addition, an electromagnetic wave blocking layer formed of an electromagnetic wave blocking material is further formed between the multiple electromagnetic wave anti-reflection layers,

The electromagnetic wave blocking layer is preferably formed in a wave shape.

In addition, a plurality of extension bars extending a certain length upward are formed around the seating member,

At the bottom of the seating member, a pressure air providing portion is disposed to provide constant pressure air upward through air holes formed in the seating member,

The measurement object is preferably arranged to be surrounded by the plurality of extension bars and floated upward to a certain height by the provided pressurized air.

Through the above solution, the present invention relates to a small electromagnetic wave shielding and absorption performance measuring device. More specifically, it has the effect of measuring the electromagnetic wave shielding and absorption performance of an object with a single device.

In addition, the present invention has the effect of performing two or more measurement processes in one device and allowing sequential measurement processes for objects to be performed automatically.

In addition, the present invention provides the effect of achieving accurate electromagnetic wave measurement of an object by constructing a wall that can block and dissipate electromagnetic waves induced by other components such as antennas in each measurement space and reflected waves reflected from surrounding reflectors. have

Figure 1 is a diagram showing the configuration of a small electromagnetic wave shielding and absorption performance measuring device of the present invention.
Figure 2 is a diagram showing an example of the configuration of the first measuring unit according to the present invention.
Figure 3 is a diagram showing an example of a second measuring unit according to the present invention.
Figure 4 is a diagram showing an example of an opening and closing unit according to the present invention.
Figure 5 is a diagram showing an example in which the second moving rail is installed in the main body according to the present invention.
Figure 6 is a diagram showing another example of a seating member according to the present invention.

Hereinafter, with reference to the drawings, embodiments of the present invention will be described in detail so that those skilled in the art can easily implement the present invention.

The present invention may be implemented in many different forms and is not limited to the embodiments described herein.

In order to clearly explain the present invention, parts that are not relevant to the description are omitted, and identical or similar components are given the same reference numerals throughout the specification.

Hereinafter, the “top (or bottom)” of the substrate or the provision or arrangement of any component on the “top (or bottom)” of the substrate means that any component is provided or disposed in contact with the upper (or lower) surface of the substrate. means that

Additionally, it is not limited to not including other components between the substrate and any components provided or disposed on (or under) the substrate.

Hereinafter, with reference to the accompanying drawings, a small electromagnetic wave shielding and absorption performance meter according to the present invention will be described.

Figure 1 is a diagram showing the configuration of a small electromagnetic wave shielding and absorption performance measuring device of the present invention.

Referring to Figure 1, the small electromagnetic wave shielding and absorption performance measuring device according to the present invention has a first measurement space (1) and a second measurement space (2), and the first measurement space (1) or the second measurement space (2) The main body portion 100 has an entrance portion 110 for guiding the introduction of the measurement object 10 into the measurement space 2, and the first measurement space 1 and the second measurement space 2 are divided into the main body portion 100. A partition wall unit 200 is installed on the main body unit 100 and has a connection hole 210 connecting the first measurement space 1 and the second measurement space 2, and is disposed on the partition wall unit 200. An opening and closing part 300 that opens and closes the connection hole 210, a first measuring part 400 that measures the electromagnetic wave absorption rate of the measurement object 10 located in the first measurement space 1, and It includes a second measurement unit 500 that measures the electromagnetic wave shielding rate of the measurement object 10 located in the second measurement space 2, and a control unit 600 that transmits the measured electromagnetic wave absorption rate and electromagnetic wave shielding rate. do.

Figure 2 is a diagram showing an example of the configuration of the first measuring unit according to the present invention. Figure 3 is a diagram showing an example of a second measuring unit according to the present invention.

As shown in Figure 2, the first measurement unit is equipped with two antennas to measure the electromagnetic wave absorption rate of the measurement object.

As shown in FIG. 3, the second measurement unit is equipped with two antennas and measures the electromagnetic wave shielding rate for the measurement object.

Figure 4 is a diagram showing an example of an opening and closing unit according to the present invention.

Referring to FIG. 4, the opening and closing unit 300 according to the present invention has a first movable rail 310 installed in the area around the upper and lower ends of the connection hole 210, and can move in a straight line on the first movable rail 310. It has a door 320 arranged in a similar manner and a first linear motor 330 that moves the door 320 to open and close the connection hole 210 under the control of the control unit 600.

The first moving rail 310 and the door 320 are made of an electromagnetic wave shielding material.

Figure 5 is a diagram showing an example in which the second moving rail is installed in the main body according to the present invention.

Referring to FIG. 5, the main body 100 according to the present invention includes a second moving rail connecting the first measurement space 1 and the second measurement space 2 through the connection hole 210. 130) is installed.

A seating member 700 on which the measurement object 10 is placed is movably disposed on the second moving rail 130.

The seating member 700 is moved by the second linear motor 140 driven by the control of the control unit 600.

The seating member 700 is formed of an electromagnetic wave shielding material.

Around the seating member 700, it is formed in an embossed shape to form an anti-reflective structure.

An electromagnetic wave anti-reflection layer 800 is formed on the first inner wall of the first measurement space 1 and the second inner wall of the second measurement space 2.

On the outer surface of the electromagnetic wave anti-reflection layer 800, a plurality of protruding members 810 having sharp ends are formed.

In particular, although not shown in the drawing, the electromagnetic wave anti-reflection layer 800 may be formed in multiple layers.

Additionally, a vacuum layer may be further formed between the multiple electromagnetic wave anti-reflection layers 800.

In addition, an electromagnetic wave blocking layer made of an electromagnetic wave blocking material is further formed between the multiple electromagnetic wave anti-reflection layers 800.

The electromagnetic wave blocking layer is formed in a wave shape.

Figure 6 is a diagram showing another example of a seating member according to the present invention.

Referring to FIG. 6, a plurality of extension bars 710 extending upward by a certain length are formed around the seating member 700 according to the present invention.

A pressure air supply unit 730 is disposed at the bottom of the seating member 700 to provide constant pressure air upward through the air holes 720 formed in the seating member 700.

The measurement object 10 is arranged to be surrounded by the plurality of extension bars 710, and can be levitated upward to a certain height by the provided pressurized air.

Through the above configuration and operation, the present invention relates to a small electromagnetic wave shielding and absorption performance measuring device, and more specifically, has the effect of measuring the electromagnetic wave shielding and absorption performance of an object with a single device.

In addition, the present invention has the effect of performing two or more measurement processes in one device and allowing sequential measurement processes for objects to be performed automatically.

In addition, the present invention provides the effect of achieving accurate electromagnetic wave measurement of an object by constructing a wall that can block and dissipate electromagnetic waves induced by other components such as antennas in each measurement space and reflected waves reflected from surrounding reflectors. have

Above, specific embodiments of the small electromagnetic wave shielding and absorption performance measuring device of the present invention have been described, but it is obvious that various implementation modifications are possible without departing from the scope of the present invention.

Therefore, the scope of the present invention should not be limited to the described embodiments, but should be determined by the claims and equivalents thereof as well as the claims described later.

That is, the above-described embodiments should be understood in all respects as illustrative and not restrictive, and the scope of the present invention is indicated by the claims to be described later rather than the detailed description, and the meaning and scope of the claims and All changes or modified forms derived from the equivalent concept should be construed as falling within the scope of the present invention.

100: main body
200: Bulkhead part
300: opening and closing part
400: 1st measuring unit
500: 2nd measurement unit
600: Control unit

Claims (5)

a main body portion having a divided first measurement space and a second measurement space, and an inlet portion for guiding the introduction of a measurement object into the first measurement space or the second measurement space;
a partition wall installed in the main body to partition the first measurement space and the second measurement space, and having a connection hole connecting the first measurement space and the second measurement space;
an opening and closing part disposed on the partition wall and opening and closing the connection hole;
a first measurement unit that measures the electromagnetic wave absorption rate of the measurement object located in the first measurement space;
a second measurement unit that measures an electromagnetic wave shielding rate of the measurement object located in the second measurement space; and,
A control unit that transmits the measured electromagnetic wave absorption rate and electromagnetic wave shielding rate;
The opening and closing unit includes a first movable rail installed in an area around the upper and lower portions of the connection hole, a door disposed to be linearly movable on the first movable rail, and the connection by moving the door under control of the control unit. Equipped with a first linear motor that opens and closes the hall,
The first moving rail and the door are formed of an electromagnetic wave shielding material,
A second moving rail is installed in the main body unit to connect the first measurement space and the second measurement space through the connection hole,
A seating member on which the measurement object is placed is movably disposed on the second moving rail,
The seating member is moved by a second linear motor driven under control of the control unit,
The seating member is formed of an electromagnetic wave shielding material,
Around the seating member, it is formed in an embossed shape to form an anti-reflective structure,
An electromagnetic wave anti-reflection layer is formed on the first inner wall of the first measurement space and the second inner wall of the second measurement space,
On the outer surface of the electromagnetic wave anti-reflection layer, a plurality of protruding members having sharp ends are formed,
The electromagnetic wave anti-reflection layer is formed in multiple layers,
A vacuum layer is formed between the multiple electromagnetic wave anti-reflection layers,
An electromagnetic wave blocking layer formed of an electromagnetic wave blocking material is further formed between the multiple electromagnetic wave anti-reflection layers,
The electromagnetic wave blocking layer is formed in a wave shape,
A plurality of extension bars extending a certain length upward are formed around the seating member,
Compact electromagnetic wave shielding and absorption performance measuring instrument.
According to clause 1,
At the bottom of the seating member, a pressure air providing portion is disposed to provide constant pressure air upward through air holes formed in the seating member,
The measurement object is arranged to be surrounded by the plurality of extension bars and is levitated upward to a certain height by the provided pressurized air.
Compact electromagnetic wave shielding and absorption performance measuring instrument. delete delete delete