KR100924520B1 - Receiver for shark fin type - Google Patents

Abstract

The present invention relates to a shark fin receiver applied to a vehicle. According to the present invention, a plurality of refracting lines repeatedly formed to form a vertical coil and an angle different from an axial direction of the refracting lines, and both ends of the refracting lines are connected to the same body, respectively, are arranged in a plurality of refracting lines. An antenna having a plurality of connecting wires zigzag-connecting and extending the overall length of the refracting lines; A circuit board on which the antenna is mounted in a vertical state; A case for shielding and protecting the circuit board; A supporter built in the case and supporting the antenna for the vertical state of the antenna; And fixing means integrally fixing the support to the inside of the case. The present invention can ensure excellent reception by a coil-shaped antenna connected in a zigzag manner, and stable reception is possible because the antenna is prevented from flowing by the support.

Vehicle, Antenna, Support, Circuit Board, Case

Description

Shark fin receiver {RECEIVER FOR SHARK FIN TYPE}

The present invention relates to a shark fin receiver installed in a vehicle, and relates to a shark fin receiver configured to be capable of compact configuration while receiving AM and FM as well as DMB.

In general, the vehicle is provided with an antenna for receiving or transmitting radio waves inside or outside. Such antennas are broadly classified into indoor and outdoor applications. In the case of indoor use, there is a sticky film antenna or a glass antenna installed in a window of a vehicle, and in the case of outdoor use, there is a micro antenna or a helical antenna. In this way, the antenna installed in the vehicle mainly receives radio signals or DMB signals.

Recently, a shark fin type receiver, also known as a shark fin antenna, which is formed in the shape of a shark fin and installed outside the vehicle, has been used. Such a shark fin receiver is not only beautiful in appearance but also can reduce the resistance of the air, so it is mainly used in large luxury vehicles.

The shark fin receiver as described above is triangular in shape as shown in FIG. 1. In this shark fin type receiver, a coiled antenna 12 installed inside the case 1 receives radio waves as shown in an enlarged manner. At this time, the coiled antenna 12 is fixed to the circuit board 22 seated on the base 2 as shown. Thus, the coiled antenna 12 is fixed to the vehicle V via the base 2. Of course, the base 2 is fixed to the vehicle V by the bolt pipe 4a and the union nut 4b as shown enlarged.

Alternatively, the shark fin receiver may be composed of a rod antenna 14 as shown in FIG. The rod antenna 14 is a dielectric in which a microfiber-shaped copper wire wound around a ferrite core is wound as shown in an enlarged view. Such a rod antenna 14 is fixed to the case 1 by an adhesive 14a such as epoxy as shown.

However, as described above, the antennas 12 and 14 of the shark-type receiver are formed long as shown, and thus receive radio waves in a linear form along the upper surface of the case 1, thereby having a very low reception rate. In particular, the antennas 12, 14 as described above can actually only receive AM or FM, or AM and FM, or DMB signals due to the low reception rate. That is, the antennas 12 and 14 described above have a problem in that they cannot receive both AM, FM, and DMB signals.

On the other hand, the antenna 12, 14 as described above is excellent in the reception rate as the vertical standing in the reception characteristics of the radio wave. However, the antennas 12 and 14 described above cannot be installed vertically due to structural problems and the size of the space inside the case 1.

The present invention was created in order to solve the above-mentioned conventional problems, and forms a coil form partly in a zigzag form as a whole, thereby ensuring not only a length suitable for receiving various radio waves but also a height lower than the length. It is an object to provide a shark fin type receiver that can form a built-in antenna, which receives radio waves at various positions therein.
In particular, it is an object of the present invention to provide a shark fin receiver with a member for vertically supporting the antenna.

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The shark fin receiver according to the present invention for achieving the above object is repeatedly refracted to form a vertical coil form to ensure a length suitable for reception of a set frequency while reducing the height compared to the actual length due to the structural characteristics. By forming a plurality of refraction lines and an angle different from the axial direction of the refraction lines, and both ends of the plurality of refraction lines are connected to the same body by zigzag connection of the plurality of refraction lines while extending the overall length of the refraction lines An antenna having a plurality of connection lines formed in a line shape such as a wire, the antenna having a length suitable for reception of radio waves together with the refraction lines; A circuit board on which the antenna is mounted in a vertical state; A case for shielding and protecting the circuit board; A supporter built in the case and supporting the antenna for the vertical state of the antenna; And fixing means integrally fixing the support to the inside of the case.
Here, the support is formed in the form of a collapsible cover for supporting the antenna from all sides to accommodate the antenna while folded in a state in which the built-in antenna, built in a pair on the inner side of one side to form a spaced state Protruding striker, and the engaging rod for the striker is provided on the inner side of the other side, and locked in a state in which the antenna is accommodated by the combination of the striker and the engaging rod, the vertical groove and the horizontal line is inserted into the refractive line and connecting line of the antenna It is preferable to configure so that a groove may be formed.
Preferably, the fixing means is configured such that a lead protrusion is formed on the support, a protrusion insertion hole is formed on the circuit board, and the lead protrusion is inserted into the protrusion insertion hole to constrain the support. .

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The shark fin receiver according to the present invention as described above, because it is connected to the same body by a connecting line is built in an antenna made of a plurality of refraction lines to secure the length that can receive a variety of radio waves, not only can receive all the various radio waves In addition, since the plurality of refracting lines form a vertical line as one, the reception rate can be greatly improved, and in addition to providing various radio waves to a vehicle, it is also effective to provide a high quality broadcast signal. Furthermore, since the height of the antenna embedded in the case is formed low, there is an effect that can be manufactured compactly.

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In particular, since the support firmly supports the antenna inside the case, there is an effect that the antenna can be prevented from flowing by driving of the vehicle.

Hereinafter, a shark fin receiver according to the present invention will be described with reference to the accompanying drawings as follows, and FIG. 3 is a perspective view of an antenna applied to a shark fin receiver according to an embodiment of the present invention, and FIG. An exploded perspective view of a shark fin receiver according to an embodiment of the present invention. And, Figure 5 is a side view showing the deployed state of the support shown in Figure 4, Figure 6 is a perspective view showing a state of use of the support shown in Figure 4, Figure 7 is a shark according to an embodiment of the present invention This is a perspective view modeling three-dimensionally the configuration of a pin type receiver.

Referring to FIG. 3, the antenna 50 applied to the shark fin receiver according to an embodiment of the present invention includes a plurality of refractive lines 52 and connecting lines 54, as shown. The antenna 50 is connected to the refractive line 52 and the connecting line 54 in the same body. That is, the antenna 50 is formed in one piece. Here, the components as described above in more detail as follows.

The refracting line 52 is formed in plural as shown, and repeatedly refracted to form a coil shape that is substantially vertical. Therefore, the refractive line 52 is formed at a low height as shown in the drawing due to its structural characteristics, and thus has an overall cylindrical shape.

This line of refraction 52, when unfolded, has a very long length. However, the refractive line 52 has a short length, that is, a low height, as it is formed in a coil shape as shown. Thus, the antenna 50 is compactly formed due to the low height of the refracting line 52.

As described above, since the refracting line 52 is formed in a coil shape and generally has a cylindrical shape, the refractive line 52 may have a sufficiently low length suitable for reception of a set frequency as described above. Of course, the refractive line 52 may be formed in a cylindrical shape of a triangular or square, unlike shown.

The plurality of refracting lines 52 may be formed at the same height as shown in the figure, or may be formed at different heights. In addition, the refractive lines 52 may be configured as four as shown, alternatively two or three or more. The quantity of such refractive lines 52 is determined in proportion to the reception characteristic of the set (designed) frequency. That is, the refractive line 52 is formed to have a length suitable for the reception characteristics in design.

In other words, the refractive line 52 is configured in large quantities when the overall length of the antenna 50 is to be formed long, and is formed in small quantities when the length is short. That is, the refraction lines 52 are composed of three to five when the length of the antenna 50 is to be formed long, and two to three when the length of the antenna 50 is to be formed short. In conclusion, the refraction line 52 is formed to have a length suitable for the design reception characteristic, whereby the quantity is determined.

The connecting line 54 is composed of a plurality as shown, and is a linear member such as a wire. The connecting line 54 may be formed in a straight line as shown, and may be formed in a curved shape or inclined form as shown in the drawing.

The connecting line 54 is connected to the plurality of refracting lines 52 each of which is the same as both ends. That is, one end of the connection line 54 is connected to one of the refractive lines 52 in the same body, and the other end thereof is connected to the other refractive lines 52 in the same body. The connecting line 54 has an angle different from the axial direction of the refracting line 52 as shown, while both ends are connected to the refracting line 52. That is, the connecting line 54 is horizontally different from the refracting line 52 which is vertical.

The connecting line 54 substantially extends the overall length of the refracting lines 52 while connecting the plurality of refracting lines 52 to the same body as shown. Of course, the antenna 50 is extended in length by the connecting line 54.

The connecting line 54 may connect the upper part of the pair of refractive lines 52 as shown, and may also connect the lower part of the pair of refractive lines 52. Therefore, the connecting line 54 connects the plurality of refractive lines 52 in a zigzag manner.

Here, the connecting line 54 is a dielectric wire formed of a single body with the refractive line 52, and is formed by an unshown molding machine for shaping the refractive line 52 in the form of a coil. That is, the antenna 50 is a straight wire and has a refractive line 52 and a connecting line 54 by a molding machine not shown. Thus, the connecting line 54 together with the plurality of refracting lines 52 forms a length L suitable for reception of radio waves.

The length of the connection line 54 is determined in proportion to the reception characteristic of the set frequency. That is, the length of the connecting line 54 is long when the total length of the antenna 50 is to be formed long according to the reception characteristics of the designed frequency, and the length when the total length of the antenna 50 is short (L) is formed short. Of course, the connecting line 54 is formed to have a length L in consideration of the length of the refractive line 52.

The connection line 54 may be provided with a bent portion 54a that is bent at a portion so that the length L extends. This bent portion 54a substantially extends the length of the connecting line 54 due to the bent shape characteristic as shown.

The bent portion 54a is provided at the connecting line 54 when the entire length of the antenna 50 is to be formed long. In particular, the bent portion 54a is formed so that the entire length of the antenna 50 is too long when the above-described refractive line 52 is applied, the entire length of the antenna 50 when the straight line 54 is applied It is suitable to apply when the length is formed too short.

As described above, at least one of the plurality of connecting lines 54 may be formed to have a different length L, and thus, at least one of the plurality of refractive lines 52 may be spaced at different intervals. Can be. That is, in the case of the connecting line 54 formed on the left side, the illustrated antenna 50 has a length L different from the other connecting lines 52 as the bent portion 54a is formed. Therefore, the refractive lines 52 located on the left side of the drawing are spaced at different intervals from the other refractive lines 52 as shown. That is, the refraction lines 52 positioned on the left side of the drawing are spaced apart by a wider distance than the other refraction lines 52 due to the connection line 54 on which the refraction portions 54a formed on the left side are formed.

Of course, the plurality of connecting lines 54 may be formed to have the same length L, as shown, so that the plurality of refracting lines 52 are spaced at the same interval. That is, all of the connection lines 54 may be provided with the above-described bent portion 54a or may be formed without all of the bent portions 54a.

On the other hand, the above-described refractive line 52 may be configured such that the upper and lower diameters are the same as shown to form a straight cylindrical shape as a whole. Alternatively, the refractive line 52 may be configured such that the diameters of the upper end and the lower end are different from each other, as shown in the enlarged view "A" in the drawing, so as to form a cylindrical shape in which the diameters of the upper and lower ends are different from each other. Alternatively, the refraction line 52 is formed to have a cylindrical shape in which at least one portion of the diameter is different from the diameter of the other portion as shown in the enlarged view "B" in the drawing, and the diameter of the portion is entirely different from the other portion as a whole. It can also be configured to. Of course, when the diameter of the refractive line 52 is formed to be partially different as described above, the total length of the refractive line 52 is converted. Accordingly, the reception characteristic of the antenna 50 may be changed by the length of the refractive line 52. That is, the reception characteristic of the antenna 50 may be changed by the length of the refractive line 52.

On the other hand, the connection line 54 described above is very easy to manufacture when formed in a straight horizontal state as shown as shown. However, unlike the illustrated figure, the connecting line 54 may be formed in a curved shape, such as "U" or "∩", and may be formed in an inclined state rather than a horizontal state.

In addition, the connecting line 54 may be formed in a straight line as shown, alternatively, the enlarged view may be formed in the form of a refractive line 52 as shown in "C". As such, when the refractive line 52 is formed, the connecting line 54 may have an actual length L longer. The length L of the connection line 54 is determined by the reception characteristic of the set frequency of the antenna 50. That is, the length L of the connecting line 54 is formed to suit the reception characteristic of the set frequency.

4, the antenna 50 is installed in the shark fin receiver according to the embodiment of the present invention in a vertical state as shown. The receiver according to the embodiment of the present invention includes the above-described antenna 50 as shown; A circuit board 60; Case 70 and; Support 80; includes. The antenna 50, the circuit board 60, the case 70 and the support 80 are assembled in an aligned state as shown.

Here, the case 70 includes an upper case 72 that protects the circuit board 60 by shielding an upper portion of the circuit board 60 as shown; A base 74 on which the circuit board 60 is seated; A lower case 76 attached to a vehicle not shown; It can be configured to include. At this time, the lower case 76 is selectively applied as necessary. That is, the lower case 76 can be omitted.

Referring to FIG. 5, the antenna 50 is supported by the support 80 as shown. Thus, the antenna 50 remains vertical. The support 80 includes a vertical groove 84 into which the refracting line 52 of the antenna 50 is inserted in a vertical state so that the antenna 50 is stably supported as shown in the figure; A horizontal groove 86 into which the connecting line 54 of the antenna 50 is inserted in a horizontal state; may be provided. And, the support 80 is preferably configured to be folded to both sides as a center to be folded as shown.

The support 80 is accommodated in a state in which the antenna 50 is folded while the antenna 50 is embedded therein, and is formed in the form of a foldable cover that supports the antenna 50 in all directions. Further, the supporter 80 is provided with a rocker 88 as shown to be folded and locked in a folded state. As shown in the rocker 88, a pair of strikers 88a protruding from one side inner surface of the support 80 in a spaced state; It is formed on the inner side of the other side engaging hook 88b for catching the striker 88a; can be configured to include. At this time, the rocker 88 may be provided with an insertion hole (88c) is inserted into the end of the striker (88a) is caught on the locking rod (88b).

Such a support 80 is fixed integrally on the circuit board 60 by the fixing means protruding at the bottom as shown. For example, the fixing means forms a lead protrusion 82 in the support 80 as shown in an enlarged view, and forms a protrusion insertion hole 60a in the circuit board 60 so that the lead protrusion 82 inserts the protrusion. It is preferable to be configured to fit the ball 60a to restrain the support 80. At this time, the lead protrusion 82 may be configured to be press-fitted into the projection insertion hole (60a) by pressing fit, otherwise forming a hook as shown enlarged at the end to be inserted into the projection insertion hole (60a) to be fixed It can also be configured.

 Alternatively, the above-mentioned fixing means may include, for example, a lead protrusion 82 formed on the support 80 as described above; It may be configured to include; not shown screw is fastened to the lead projection 82 through the circuit board 60. Of course, the screw is not fastened to the lead protrusion 82, it may be fastened directly to the support (80).

Referring to FIG. 6, the support 80 is fixed to the circuit board 60 in a folded state as shown. At this time, the lead protrusion 82 is inserted into the protrusion insertion hole (60a) of the circuit board 60 as shown enlarged and fixed.

This support 80 is kept folded by the above-described rocker 88 as shown when folded. That is, the rocker 88 locks the folded support 80 in a folded state. In this way, the support 80 to maintain the folded state is accommodated in a state surrounding the antenna 50 as shown. Therefore, the support 80 supports the antenna 50 from all directions.

Referring to FIG. 7, the support 80 is embedded in the case 70 together with the circuit board 60 as shown. Of course, the support 80 is embedded in the case 70 in a state in which the antenna 50 is accommodated. At this time, as the antenna 50 is compactly formed, it is easily inserted into the case 70 as shown. The antenna 50 is soldered after being embedded in the circuit board 60, the bottom of the rightmost side as shown.

As shown in the antenna 50, the refracting lines 52 are vertically arranged on the circuit board 60 as shown. That is, the antenna 50 is disposed on the circuit board 60 with most of the body standing vertically. Of course, the antenna 50 is vertically erected at various places inside the case 70 as the refractive lines 52 are formed in plural. Therefore, the higher the reception rate, the better the reception rate due to the characteristics of the antenna 50.

On the other hand, the antenna 50 applied to the receiver according to the embodiment of the present invention was formed such that the entire length is about 780 mm when the wires 52 and the connecting line 54 are unfolded in a straight line. The total length of the antenna 50 is set because the total length of the antenna 50 must be about 780 mm to receive AM and FM signals and DMB signals. Of course, this overall length is set by the formula " λ / 4 = total length " applied to the design of the vehicle antenna. In conclusion, the receiver applied to the receiver according to the embodiment of the present invention can receive both AM and FM signals and DMB signals by the antenna 50.

Herein, the performance of the shark fin receiver as described above will be described with reference to the accompanying drawings. FIG. 8 is a three-dimensional chart showing the directivity of the receiver according to the embodiment of the present invention. 10 is a graph showing a gain of a receiver according to an embodiment of the present invention, FIG. 10 is a graph showing a loss ratio of the receiver according to the embodiment of the present invention, and FIG. 11 is an AM reception of the receiver according to the embodiment of the present invention. It is a graph showing the performance.

Referring to Figure 8, the receiver according to the embodiment of the present invention is formed in a zigzag form due to the antenna is installed vertically as shown in the excellent reception up to the upper end and the lower end. That is, the antenna applied to the receiver according to the embodiment of the present invention has a very good reception rate. Of course, at the top and bottom portions of the upper and lower portions, that is, the reception rate is slightly insufficient. However, the reception rate of this vertex portion is insufficient for most antennas.

Here, (a) on the figure shown is data which measured the reception rate of FM, and (b) on the figure is data which measured the reception rate of DMB.

9, the antenna I of the receiver according to the embodiment of the present invention has the same reception rate as that of the microantenna II as shown in (a) of the figure. In particular, the antenna I of the receiver according to the embodiment of the present invention has a better reception rate at the vertex portion Ia than the vertex portion IIa of the microantenna II.

In addition, the antenna I of the receiver according to the embodiment of the present invention has a reception ratio similar to that of the helical antenna III as shown in (b) of the figure. In particular, the antenna I of the receiver according to the embodiment of the present invention has a better reception rate at the vertex portion a than the vertex portion IIIa of the helical antenna III.

Here, (a) on the figure shown is data which measured the reception rate of FM, and (b) on the figure is data which measured the reception rate of DMB.

Referring to FIG. 10, the microantenna II does not operate in the DMB section as shown. That is, the microantenna II cannot receive the DMB. And, the helical antenna (III) does not work in the FM section. That is, the helical antenna III cannot receive FM. However, the antenna I of the receiver according to the embodiment of the present invention operates in the FM band as shown and also in the DMB band. That is, the antenna I of the receiver according to the embodiment of the present invention may receive both FM and DMB. In conclusion, the receiver according to the embodiment of the present invention has a very good reception rate due to the antenna I as described above. Therefore, when using the receiver according to the embodiment of the present invention, one receiver can receive most broadcasts.

Referring to FIG. 11, a receiver according to an embodiment of the present invention may receive an AM signal as shown. That is, the receiver according to the embodiment of the present invention can receive AM signals as well as FM and DMB signals. Of course, since the receiver according to the embodiment of the present invention includes an analog TV signal in the DMB section, the receiver can naturally receive a general TV signal. Therefore, the receiver according to the embodiment of the present invention receives almost all broadcast signals.

Since the above embodiments are merely illustrative of preferred embodiments of the present invention, the scope of application of the present invention is not limited to the above, and appropriate modifications are possible within the scope of the same idea. Therefore, since the shape and structure of each component shown in the embodiment of the present invention can be carried out by deformation, it is natural that the modification of the shape and structure belong to the appended claims of the present invention.

1 is a perspective view of a typical shark fin receiver;

2 is a longitudinal sectional view of another type of shark fin receiver;

3 is a perspective view of an antenna applied to a shark fin receiver according to an embodiment of the present invention;

4 is an exploded perspective view of a shark fin receiver according to an embodiment of the present invention;

FIG. 5 is a side view showing an expanded state of the support shown in FIG. 4; FIG.

6 is a perspective view showing a state of use of the support shown in FIG.

FIG. 7 is a perspective view modeling perspectively three-dimensionally the configuration of a shark fin receiver according to an embodiment of the present invention; FIG.

8 is a three-dimensional chart showing the directivity of the receiver according to the embodiment of the present invention;

9 is a plane chart showing the gain of the receiver according to the embodiment of the present invention;

10 is a graph showing a loss rate of a receiver according to the embodiment of the present invention; And

11 is a graph illustrating AM reception performance of a receiver according to an embodiment of the present invention.

<Description of Major Symbols in Drawing>

50: antenna

52: refractive line

54: connecting line

60: circuit board

70: case

80: support

Claims (11)

delete delete delete delete delete delete delete delete In the sark pin receiver installed in the vehicle to receive radio waves, Due to the structural characteristics, the plurality of refracting lines 52 and the refracting lines 52 which are repeatedly refracted to form vertical coils are formed so as to secure a length suitable for reception of a set frequency while reducing the height relative to the actual length. It forms an angle different from the axial direction, and both ends of the plurality of refracting lines 52 are connected to the same body so as to zigzag connect the plurality of refracting lines 52 and extend the overall length of the refracting lines 52. Thereby, together with the refracting lines 52 to form a length (L) suitable for reception of radio waves, having an antenna (50) having a plurality of connecting lines 54 in the form of a wire; A circuit board 60 on which the antenna 50 is mounted in a vertical state; A case 70 shielding and protecting the circuit board 60; A support (80) embedded in the case (70) for supporting the antenna (50) for the vertical state of the antenna (50); And Shark pin receiver comprising a; fixing means for integrally fixing the support (80) to the inside of the case (70). The method of claim 9, wherein the support 80, It is formed in the form of a collapsible cover for supporting the antenna 50 in all directions by receiving the antenna 50 in a state of folding the antenna 50 in a built-in state, spaced in pairs on the inner side of one side Protruding striker 88a and a catching rod 88b for catching the striker 88a are provided on the inner side of the other side, and the antenna 50 is coupled by the striker 88a and the catching rod 88b. And a vertical groove (54) and a horizontal groove (86) into which the refraction line (52) and the connecting line (54) of the antenna (50) are inserted in a state of being accommodated. The method of claim 9, wherein the fixing means, A lead protrusion 82 is formed in the support 80, and a protrusion insertion hole 60a is formed in the circuit board 60, so that the lead protrusion 82 is inserted into the protrusion insertion hole 60a. Shark-pin receiver, characterized in that configured to restrain the support (80).

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