SE525840C3 - - Google Patents

Description

And the antenna can be miniaturized.

Another object of the invention is to propose a manufacturing method for an antenna where the desired dielectric constant can be obtained by arbitrarily selecting the dielectric material to minimize the limitation in the design and the conductive lead of the antenna can be constructed in a suitable manner to minimize the occurrence of defects during manufacturing.

To achieve these objects, the method of manufacturing an antenna according to the present invention comprises the following steps: i) preparing a first and a second flexible substrate; ii) forming a diagonal first conductive pattern on one major surface of the first flexible substrate; iii) forming a number of inclined second conductive patterns on the second flexible substrate at predetermined intervals; iv) forming an interconnecting pattern on the second major surface of the first flexible substrate so that the first conductive pattern of the first flexible substrate is electrically connected to the second conductive pattern of the second flexible substrate; v) winding the second flexible substrate around a substantially cylindrical substrate; and vi) winding the first flexible substrate around the substantially cylindrical substrate on top of the second flexible substrate.

Brief Description of the Figures The above object and other advantages of the present invention will become more apparent from the detailed description of a preferred embodiment of the present invention with reference to the accompanying drawings in which: Figure 1 illustrates the structure and condition after installation of a conventional dual band antenna; Figure 2 is a schematic view showing the structure of the dual band antenna of the present invention; Figure 3 is a sectional view showing the condition after installation of the dual band antenna according to the present invention; Figures 4a, 4b and 4c illustrate the manufacturing method of the dual band antenna of the present invention; Figure 5 illustrates the installation method of the dual band antenna in a first embodiment of the present invention; Figure 6 schematically illustrates the method of manufacturing the dual band antenna in a second embodiment of the present invention; Figure 7 schematically illustrates the method of manufacturing the dual band antenna in a third embodiment of the present invention; Figure 8 schematically illustrates the method of manufacturing the dual band antenna in a fourth embodiment of the present invention; and Figure 9 is a graphical illustration showing the reception band and sensitivity curve of the dual band antenna of the present invention. Detailed Description of the Preferred Embodiments The present invention will be described in detail with reference to the accompanying Figures.

Figure 2 is a schematic view showing the structure of the dual band antenna according to the present invention. Figure 3 is a sectional view showing the condition after installation of the dual band antenna according to the present invention.

The dual band antenna of the present invention includes a primary coil 100 and a secondary coil 200 which surround the primary coil 100 and thereby form an antenna 300.

The primary coil 100 has a helical shape and has a predetermined length and predetermined gradients, it also having a constant coil diameter. The center line of the primary coil 100 is substantially divided into a vertical line.

As shown in Figure 4a, the primary coil 100 is simultaneously a helical coil housed in a helical channel 120 which has a predetermined length and predetermined slopes and which forms a helix around a first cylindrical body 110. The first cylindrical body 110 is made of a resin, a ceramic, or a magnetic material.

Under these conditions, the primary coil 100 consists of a wire of a certain diameter, which is made of Cu, Ag or an alloy with shape memory. Otherwise, the primary spool 100 may consist of a rolled strip. Thus, the primary coil 100 is secured within the helical channel 120 of the first body 110, while the upper portion of the primary coil 100 projects from one side of the first body 110.

The secondary coil 200, which is connected in a single piece to the primary coil 100, is connected to the upper part of the primary coil 100. The secondary coil 200 has a helical shape and has a length and pitch which is greater than that of the primary coil 100.

The secondary coil 200 is made of a material and has a diameter which is the same as that of the primary coil, or is made of a rolled strip. The vertical axis of the secondary coil 200 is in the same position as the vertical axis of the primary coil.

At the same time, a second body 220 has a hollow holding space 210 for accommodating the first body 110 around which the primary coil 100 has been wound around the helix of the mounting channel 120. Another helical mounting channel 230 is formed around the second body 220 and the helical mounting channel 230 has a length and pitches that are the same as that of the second coil 200 so that the secondary coil 200 can be slid into the helical mounting channel 230.

As shown in Figure 4b, the second body 220 around which the secondary coil 200 has been wound has a dielectric constant and a permeability equal to or equal to those of the first body 110.

As shown in Figure 4c, the primary coil 100 wound around the first body in the helical shape projects from the outside of the first body 110. The protruding portion of the first coil 100 is electrically connected to the secondary coil 200 which is wound around the secondary body 220, resulting in In the design of a dual band antenna 300. In the primary and secondary coils 100 and 200, the pitch and angular direction can be adjusted so that a single band antenna can be designed to receive signals through a single frequency band.

In this way, an antenna with a single frequency band is formed by the primary and secondary coils 100 and 200. Furthermore, the secondary coil 200 wound around the secondary body 220 in a helical shape makes it possible to form an antenna for receiving signals through another frequency band. In this way, a dual band antenna 300 can be made.

Then, as shown in Figure 5, the antenna 300 comprising the primary and secondary coils 100 and 200 is pushed into a housing 310 made of a resin.

Thereafter, a filler material consisting of an epoxy resin or a curable resin is injected into the housing 310 so that the dual band antenna can be housed and attached to the housing 310.

Under this condition, the antenna 300 does not need a special fastener but is fixed firmly by filling the filler material 320 into the housing 310. Correspondingly, the machinability and productivity are improved.

As an alternative, the dual band antenna 300 comprising the primary and secondary coils 100 and 200 may be formed by an injection molding injection by letting a plastic composite material or a dielectric material of ceramic surround the antenna 300. Here, the ceramic dielectric material must have a dielectric constant corresponding between 2 and 50.

As graphically illustrated in Figure 9, the antenna 300 which includes the primary and secondary coils 100 and 200 exhibits an extended bandwidth for the sequence response and a reduced frequency response value (dB). This means that the frequency reception capacity becomes larger.

Figure 6 schematically illustrates the method of manufacturing the dual band antenna in a second embodiment of the present invention. To form two helical coils with different pitches and diaphragms, a plurality of through holes 440 are formed at regular intervals on an inner substrate 41a and outer substrate 410b, so as to form a chemical substrate (arms may be a tefron substrate or a resin substrate). be used). On the chemical substrate, conductive patterns are formed using pattern forming means.

The leading patterns are formed as follows. More specifically, a cover layer is formed on the chemical substrate by using Cu, Ni, Ag or Au and by applying a non-electrolytic cover layer. Thereafter, the cover layer is etched by photolithography so that the primary cover patterns 430a can be performed on the inner substrate 41a and secondary coil patterns 430b can be performed on the outer substrates 41Ob.

Thereafter, the part of the ceramic substrate where the coil patterns have not been formed is cut and a creamy solder is pressed between the inner substrate 41a and the outer substrates 410b to perform a soldering. Otherwise, the general adhesive and a glass enamel are used to bond the inner and outer substrates 4110a and 410b together. Upon bonding the inner and outer substrates 410a and 41b together, the primary coil patterns 430a formed on the top and bottom of the inner substrate 410 are connected to each other through through holes 440 to form a primary coil 100. Further connected the secondary coil patterns 430b of the outer substrates 41b connected to the upper and lower sides of the inner substrate 410a, respectively, with each other through respective through holes 440 to form a secondary coil 200. Thus, a two-band antenna 400 is formed.

Figure 7 schematically illustrates the method of manufacturing the dual band antenna in a third embodiment of the present invention.

Several through holes 540 have been formed in each of the raw foils 410 which have been formed by using a ceramic paste so that coils of different pitches and diameters can be formed on each of the raw foils 510.

Primary coil patterns 530a printed on the inner substrates 51a are connected through through holes 540 to secondary coil patterns 530b of outer substrates 51b, thereby forming a helical antenna 500.

Under these conditions, the patterning means forming the primary and secondary coil patterns 530a and 530b merge as follows. More specifically, a conductive paste consisting of Cu, Ni, Ag or Au is pressed to form the patterns and thus when raw foils are stacked, helical coils are formed by being electrically bonded to each other through the through holes 540.

After stacking the inner substrates 51a and the outer substrates 51b with the primary coil patterns 530a and the secondary coil patterns 530b formed thereon, the substrates are compressed under a pressure of from 80 to about 120 kg / cm 2 to form the final structure. This structure is cut into individual antennas and burned at a temperature of from 800 to about 1000 ° C, thereby forming a dual band antenna 500.

If the antennas in the second and third embodiments formed by stacking the ceramic substrates or the raw foils are used in a handset or the like, the antennas do not protrude outside the apparatus and therefore the apparatus can be miniaturized.

Figure 8 schematically illustrates the method of manufacturing the dual band antenna in a fourth embodiment of the present invention.

As shown in this figure, a first conductive pattern 620a has been printed on a first flexible substrate in the diagonal direction, while an interconnecting pattern 640 has been printed on the other side of the substrate so as to connect it to the first conductive pattern 620a.

Thereafter, a number of second conductive patterns 620b have been printed on a second flexible substrate 61b with a certain angle of inclination. Thereafter, the second flexible substrate 61b has been wound around a cylindrical substrate 630 made of a resin, a ceramic or a magnetic material.

The second conductive patterns 620b of the second flexible substrate 61b wound around the cylindrical substrate 630 form a primary coil 100. Thereafter, the first flexible substrate 61a is wound around the second flexible substrate 610b and thus the first conductive pattern 620a to a secondary coil 200.

The interconnecting pattern 640 printed on the other side of the first flexible substrate 61a is connected to the second conductive pattern 620b of the second flexible substrate 610b, and therefore the two sets of conductive patterns 620a and 620b are electrically interconnected to form a dual band antenna. 600.

In addition to the connections between the two sets of conductive patterns 620a and 620b of the first and second flexible substrates 61a and 610b by using the interconnecting pattern 640, the connections can also be made by soldering.

Thus, the antenna 600 can be made in a simple manner by winding the first and second flexible substrates around the cylindrical substrate 630. The cylindrical substrate 630 may have a minimal diameter and therefore the miniaturization of the antenna becomes possible, as well as the improvement of the reception sensitivity.

According to the present invention as described above, the dual band antenna which receives signals through a number of frequency bands is improved with respect to its reception sensitivity, miniaturized, and prevented from being deflated or damaged upon receiving an external shock. Furthermore, the reception bandwidth can be increased.

Furthermore, the desired dielectric constant can be obtained by a free choice of dielectric material and therefore the limitation of the design can be minimized. Furthermore, the conductive leads can be precisely arranged and therefore the occurrence of defects can be minimized.

The present invention has been described above on the basis of the specific preferred embodiments and the accompanying figures, but those skilled in the art will appreciate that various changes and modifications may be made without departing from the spirit and scope of the present invention which will be set forth in the appended claims.

Claims (2)

10 15 20 5.25 8 40 7 Patent claim A method of manufacturing a dual band antenna (600), comprising the steps of: i) preparing a first (610a) and a second (61Ob) flexible substrate; ii) forming a diagonal first conductive pattern (620a) on one major surface of the first flexible substrate (610a); iii) forming a plurality of inclined second conductive patterns (620b) on the second flexible substrate (610b) at predetermined intervals; iv) forming an interconnecting pattern (640) on the second major surface of the first flexible substrate (610a); v) winding the second flexible substrate (610b) around a substantially cylindrical substrate (630); and vi) winding the first flexible substrate (610a) around the substantially cylindrical substrate (630) on top of the second flexible substrate (610b) so that the first conductive pattern (620a) of the first flexible substrate (610a) is electrically connected to the second flexible substrate; (610b) other conductive patterns (620b). in The method of claim 1, wherein the cylindrical substrate (630) having the first (610a) and second (610b) flexible substrates wound thereon is made of any substance selected from the group consisting of a resin, a ceramic and a magnetic material. .