KR20100021876A - Structure for setting patch antenna - Google Patents

Abstract

PURPOSE: A structure for mounting patch antenna is provided to control beam pattern by controlling angle for mounting the patch antenna. CONSTITUTION: A plate-phase patch antenna(50) having uniform antenna pattern(51) is mounted on a setting space(110). An antenna case(100) covers outer rim of the patch antenna. An electromagnetic wave absorber(300) is inserted between the patch antenna and antenna case. The electromagnetic wave absorber is formed in the setting space. The antenna case is formed in a square plate phase. The patch antenna is formed in a square plate phase having smaller area then the antenna case. The rim of the antenna case is arranged with the rim or the patch antenna in parallel A cover member comprises an outer partition(210).

Description

Patch Antenna Mounting Structure {STRUCTURE FOR SETTING PATCH ANTENNA}

The present invention relates to a patch antenna mounting structure, and more particularly, to a patch antenna mounting structure capable of minimizing the reception effect due to the mounting position of the patch antenna by mounting the patch antenna on the metal antenna case.

Typically, RFID is applied to warehouse goods management, supermarkets, parking management, etc. For example, when a tag having unique information recorded on the item is mounted, the controller uses the information received through the tag to display the current display stand. We can automatically grasp the remaining quantity of goods, etc. Even if the consumer does not calculate separately, we can easily collect the information about the purchased goods, and can provide it with convenience such as payment by credit card. It became a necessary system for living.

RFID (radio frequency identity) (RFID) is a field of automatic recognition, such as a barcode, magnetic, IC-card, etc. is a state-of-the-art method for wirelessly recognizing information recorded using microwave or long wave.

The principle of the RFID is to receive the information stored in the tag through the antenna, so that the controller recognizes and analyzes the information and acquires the unique information of the article on which the tag is mounted. ㅇ It is not affected by the environment such as dust and magnetic flux, and it is possible to recognize it on the move due to the fast passing speed, it can be recognized at a long distance, and it is impossible to forge by giving unique ID in the manufacturing process.

A radio frequency identification system is generally composed of a reader, an antenna, and a tag, and an antenna plays an intermediary role between a tag and a reader, and sends a signal as a radio wave to activate or deactivate a tag, and to read and write data. do.

There are many kinds of antennas, but there are many types of high frequency antennas that are generally used. Dipole Antennas, Monopole Antennas, Patch Antennas, Horn Antennas, Parabolic Antennas, Helical Antennas, Slot Antennas, and the like.

A microstrip antenna is a type of flat antenna, in which one of the conductor plates bonded to both sides of the insulator is a strip (thin sheet), called a microstrip line. It is named micro because it can be manufactured and made into a microstructure. The strip and the conductor plate become two feed lines and become the track. It is the microstrip antenna that cuts the strip line from the end to half-wavelength position and feeds the coaxial line on the underside of the fingerboard with a cross point in the center of the strip instead of the transmission line. The wider the strip, the wider the frequency bandwidth and the easier it is for radio waves to radiate. A microstrip antenna in the forward direction is called a square patch antenna, and a circle is called a circular patch antenna.

Since the microstrip antenna is made of printed board, it is suitable for mass production, and has various characteristics such as low height and flatness.

For this reason, it is used a lot as an array antenna element which requires a large amount of small antennas. In recent years, the use of wireless communication is rapidly increasing, and in order to meet the popularization of antennas, it is necessary to satisfy another desire of miniaturization, inexpensiveness, and mass production while maintaining the performance of antennas as desired.

One of the antennas that can meet these needs is a microstrip antenna. Microstrip antennas, on the other hand, are generally characterized by small frequency bandwidth and low efficiency, but they have been recently researched and developed because of their advantages.

In addition, RFID systems are currently used in various fields, and there are various applications in which steel products are used. Applications include steel mill roll shops and steel self-history management, gas cylinder management, and reactor drums.

First, steel mills can tag steel itself to manage steel products, and roll shops to manage rolls in roll shops.Steel product management involves attaching barcodes to cold rolled coils. Second, it is impossible to read and write data. Second, if the surroundings of barcodes such as dust or humidity are damaged according to the surrounding environment, accurate data cannot be obtained and the distance to be recognized is limited.

In the case of introducing an RFID system in an industrial site with high steel or metal influences, the conventional patch antenna has a problem in that it is radiated backward from the surface to which it is attached, and in addition, the beam pattern is variable. In addition, there is a problem that erroneous detection and non-detection of product information occurs due to a decrease in reception rate of the antenna itself.

The present invention has been made to solve the above problems, an object of the present invention is to install a patch antenna mounting structure which can minimize the effect of the reception rate according to the mounting position of the patch antenna by mounting the patch antenna on the antenna antenna of the metal material In providing.

Another object of the present invention to provide a patch antenna mounting structure that can adjust the beam pattern by adjusting the installation angle of the patch antenna inside the antenna case.

It is still another object of the present invention to provide a patch antenna mounting structure capable of suppressing diffraction to the side edges of a patch antenna and suppressing and controlling radiation to the rear and side thereof.

In order to achieve the above object, the present invention provides a patch antenna mounting structure.

The patch antenna mounting structure is provided with a seating space in which a patch antenna on a plate on which a predetermined antenna pattern is formed is provided, an antenna case covering an outer edge of the patch antenna, and interposed between the patch antenna and the antenna case. It includes an electromagnetic wave absorber provided in the seating space.

Here, the edge of the antenna case is preferably parallel to the edge of the patch antenna.

In addition, the edge of the antenna case preferably forms an acute angle with the edge of the patch antenna.

In addition, the antenna case is provided with a cover member for covering the outer edge of the patch antenna.

Here, the cover member is an outer partition wall extending a predetermined length upward from the bottom edge of the antenna case so as to be spaced a predetermined distance from the outer edge of the patch antenna, and upwards from the bottom surface of the antenna case to be in close contact with the edge of the patch antenna. It is preferable to have an inner partition which extends a certain length.

The height of the outer partition and the inner partition from the bottom surface of the antenna case is preferably different from each other.

The cover member further includes a plurality of auxiliary partitions between the outer partition and the inner partition.

Here, the auxiliary partitions are preferably provided on the bottom surface of the antenna case to be parallel to the outer partition and the inner partition.

And, the height of the cover member from the bottom of the antenna case is preferably increased sequentially from the inner partition along the outer partition.

In addition, the height of the cover member from the bottom of the antenna case is preferably formed differently from the inner partition along the outer partition.

In addition, the outer partition, the inner partition and the auxiliary partitions are preferably formed to be inclined at a constant with the inner bottom surface of the antenna case to adjust the beam pattern.

In addition, it is preferable that a cover inclined member inclined toward the seating space is further formed on the top of the outer partition, the inner partition, and the auxiliary partitions.

The present invention has the effect of minimizing the effect of the reception rate according to the mounting position of the patch antenna by mounting the patch antenna on the metal antenna antenna.

In addition, the present invention has the effect of adjusting the beam pattern by adjusting the installation angle of the patch antenna in the interior of the antenna case, and by adjusting the angle of the partition walls.

In addition, the present invention has the effect of suppressing the diffraction to the side edge of the patch antenna, and suppressing and adjusting the radiation to the rear, side.

Hereinafter, with reference to the accompanying drawings, it will be described a patch antenna mounting structure of the present invention.

1 is a perspective view showing one embodiment of a patch antenna mounting structure of the present invention. 2 is a cross-sectional view taken along the line II ′ of FIG. 1. 3 is a cross-sectional view illustrating another example of the cover member of FIG. 1. 4 is a cross-sectional view illustrating still another example of the cover member of FIG. 1.

First, with reference to Figures 1 to 4, it will be described an embodiment of the patch antenna mounting structure of the present invention.

The patch antenna mounting structure includes a seating space 110 in which the patch antenna 50 on the plate on which a predetermined antenna pattern 51 is formed is provided, and an antenna case covering an outer edge of the patch antenna 50 ( 100 and the electromagnetic wave absorbing material 300 provided in the seating space 110 to be interposed between the patch antenna 50 and the antenna case 100.

As shown in FIG. 1, the antenna case 100 has a square plate shape, and the patch antenna 50 also has a square plate shape having a predetermined area smaller than that of the antenna case 100.

The edge of the antenna case 100 is disposed to be parallel to the edge of the patch antenna 50.

Thus, the four sides of the patch antenna 50 may be parallel to the four sides of the antenna case 100.

Here, the antenna case 100 is provided with a cover member 200 to cover the outer edge of the patch antenna 50.

As illustrated in FIG. 1, the cover member 200 may have only an outer partition wall 210 to cover an edge of the patch antenna 50.

In addition, as shown in FIG. 2, the cover member 200 may have an outer partition 210 and an inner partition 220.

The inner partition wall 220 extends a predetermined length upward from a bottom surface of the antenna case 100 so as to be in close contact with an edge of the patch antenna 50.

The outer partition wall 210 extends a predetermined length upward from the bottom edge of the antenna case 100 so as to be spaced apart from the outer edge of the patch antenna 50 by a predetermined distance.

Here, the heights from the bottom of the antenna case 100 of the outer partition 210 and the inner partition 220 are formed differently.

Preferably, the height of the inner partition wall 220 is lower than the height of the outer partition wall 210.

Therefore, the inner partition wall 220 and the outer partition wall 210 can suppress diffraction toward the side edges of the patch antenna 50 and also suppress radiation to the rear and sides.

In addition, referring to FIGS. 2 and 3, the cover member 200 may further include a plurality of auxiliary partitions 230 between the outer partition 210 and the inner partition 220.

Here, the auxiliary partitions 230 are provided on the bottom surface of the antenna case 100 to be in parallel with the outer partition 210 and the inner partition 220.

In addition, the height of the cover member 200 from the bottom surface of the antenna case 100 may be sequentially increased along the outer partition wall 210 from the inner partition wall 220, as shown in FIG.

By providing the auxiliary partitions 230 as described above, the inner and outer partitions 220 and 210 further suppress the diffraction from the side edges of the patch antenna 50 and further rearward and sideward. Can further suppress radiation.

Meanwhile, as shown in FIG. 4, the height of the cover member 200 ′ from the bottom of the antenna case 100 may be different from the inner partition 220 along the outer partition 210. .

That is, one of the inner partition 220 and the auxiliary partitions 230 ′ may have the same height, and the other of the outer partition 210 and the auxiliary partitions 230 ′ may have the same height. In this case, the height of the inner partition wall 220 forms a level lower than the height of the outer partition wall 210.

In this case, diffraction of various patterns from the side edges of the patch antenna 50 can be suppressed.

5 is a perspective view showing another embodiment of the patch antenna mounting structure of the present invention.

On the other hand, referring to Figure 5, the present invention is the cover inclined member 250 which is inclined toward the seating space 110 at the upper end of the outer partition 210, the inner partition 220 and the auxiliary partitions (230) ) Is further formed with a cover member 200 ".

Accordingly, the cover inclined member 250 may suppress and adjust diffraction radiated in the side portion of the patch antenna 50, particularly in the inclined direction.

Although not shown, the outer partition, the inner partition, and the auxiliary partition may be inclined not only at right angles with the inner bottom surface of the antenna case to adjust the beam pattern.

6 is a perspective view showing another embodiment of the patch antenna mounting structure of the present invention.

6, the edge of the antenna case 100 ′ may form an acute angle θ with the edge of the patch antenna 50.

Accordingly, the beam pattern may be adjusted by adjusting the installation angle of the patch antenna 50 inside the antenna case 100.

1 is a perspective view showing one embodiment of a patch antenna mounting structure of the present invention.

2 is a cross-sectional view taken along the line II ′ of FIG. 1.

3 is a cross-sectional view illustrating another example of the cover member of FIG. 1.

4 is a cross-sectional view illustrating still another example of the cover member of FIG. 1.

5 is a perspective view showing another embodiment of the patch antenna mounting structure of the present invention.

6 is a perspective view showing another embodiment of the patch antenna mounting structure of the present invention.

* Description of Signs of Main Parts of Drawings *

50: patch antenna

100: antenna case

110: seating space

200: cover member

210: outer bulkhead

220: inner partition

230, 230 ': secondary bulkhead

250: cover inclined member

300: electromagnetic wave absorber

Claims (10)

An antenna case having a seating space in which a patch antenna on a plate on which a predetermined antenna pattern is formed is provided, and covering an outer edge of the patch antenna; And Patch antenna mounting structure including an electromagnetic wave absorber provided in the seating space so as to be interposed between the patch antenna and the antenna case. The method of claim 1, The edge of the antenna case is a patch antenna mounting structure, characterized in that parallel to the edge of the patch antenna. The method of claim 1, The edge of the antenna case is a patch antenna mounting structure, characterized in that forming an acute angle with the edge of the patch antenna. The method of claim 2 or 3, The antenna case is provided with a cover member for covering the outer edge of the patch antenna, The cover member has an outer partition wall extending a predetermined length upward from a bottom edge of the antenna case so as to be spaced a predetermined distance from the outer edge of the patch antenna, and a predetermined length upward from the bottom surface of the antenna case so as to be in close contact with the edge of the patch antenna. Patch antenna mounting structure, characterized in that it has an inner partition extending. The method of claim 4, wherein The patch antenna mounting structure, characterized in that the height of the outer partition and the inner partition from the bottom surface of the antenna case is different. The method of claim 4, wherein The cover member further includes a plurality of auxiliary partitions between the outer partition and the inner partition, The auxiliary partitions are patch antenna mounting structure, characterized in that provided on the bottom surface of the antenna case in parallel with the outer partition and the inner partition. The method of claim 6, And a height of the cover member from the bottom of the antenna case is sequentially increased along the outer partition from the inner partition. The method of claim 6, The height of the cover member from the bottom of the antenna case is a patch antenna mounting structure, characterized in that formed differently from the inner partition along the outer partition. The method of claim 6, The cover antenna mounting structure further comprises a cover inclined member that is inclined toward the seating space on the top of the outer partition, the inner partition and the auxiliary partitions. The method of claim 6, The outer partition, the inner partition and the auxiliary partitions are patch antenna mounting structure, characterized in that formed to be inclined at a constant with the inner bottom surface of the antenna case to adjust the beam pattern.

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