KR101166846B1 - A telescopic antenna for telecommunication terminal apparatus - Google Patents

Abstract

PURPOSE: A telescopic antenna for a mobile terminal is provided to keep a cylindrical leaf spring in place by preventing the movement of the cylindrical leaf spring during extension and contraction thereof. CONSTITUTION: An end cap(300) comprises an insertion part and a cylinder head part(320) inserted to the lower side of an antenna pipe(100). The cylinder head part restricts a cylindrical leaf spring(200) from being inserted to the lower side of the antenna pipe. The cylindrical plate spring has upper and lower rims formed at the top and bottom of a leaf spring part(210). Rolling protrusion(430) are formed in the upper and lower rims, respectively, and inserted and fixed into a rolling groove at the lower side of the antenna pipe and an end cap insertion rolling groove formed in the circumferential direction of the antenna pipe.

Description

Multi-stage antenna for mobile terminal {A telescopic Antenna For Telecommunication Terminal Apparatus}

The present invention relates to a multi-stage antenna for a mobile terminal to be used as an external type, and more particularly, to have a structure that can maximize the length of extension compared to the reduced length to have a reliable structure to prevent the separation of the bottom joint. A multi-stage antenna for a mobile terminal.

   In general, the multi-stage antenna 1 shown in FIG. 1 is a general structure for inserting antenna pipes having different diameters into a telescopic structure, and is used in various mobile terminals such as DMB, navigation, smartphones, and pads. Each stage antenna pipe is provided with the same reference numeral 10 for convenience of reference.

Since the multi-stage antenna 1 is a structure that is stretched and contracted, cylindrical plate springs 20 inserted into the respective antenna pipes 10 are inserted to fix the extended state by spring force, and each antenna pipe 10 is reduced when it is reduced. 2A and 2B, the antenna pipe 10 is fitted with a small diameter antenna pipe used as an upper end by forcibly fitting the end cap 30 or forming an expansion part 35 at the lower end of The technique to prevent falling back through the interior of the) has been commonly used.

   However, when the multi-stage antenna is repeatedly stretched and contracted, the multi-stage antenna pipes 10 are sequentially inserted from the top side into the neighboring antenna pipes 10 from the top side and are not reduced. The lower antenna pipe may be inserted first and then contracted. In this case, in the case of the expanded multistage antenna, a defect may occur in which the upper antenna pipe is pulled out. In this case, the cylindrical plate spring 20 is also removed. According to the user's needs, there is a problem that a failure occurs in which the function cannot be exerted as the multi-stage antenna 1 which operates in a stretched manner.

As described above, even when the end cap is pressed against the lower end of the antenna pipe, external physical influences (forces from external factors such as contact force with the surroundings) or chemical influences (oxidation or rigid deformation, etc.) are applied to the area. ), Etc. due to thousands of tens of thousands of stretching operations, the expansion operation that pushes or pulls the antenna with excessive force, or the foreign matter gets caught in the gap between the antenna pipes. There is a problem that the cap is pulled back and thus the failure caused by the antenna pipe of the upper end is pulled back.

Meanwhile, in FIG. 1 (attached to FIG. 3 of the drawings of the present invention) for describing the prior art of the Republic of Korea Patent Publication No. 10-2008-32434 (hereinafter referred to as the cited invention), the end cap is fitted The drawing shows a structure that prevents the end cap (named stopper as reference numeral 130 as cited in the invention) from falling out by providing a groove (quoted as reference numeral 112 in the cited invention). Due to the very thin thickness structure of the antenna pipe and the material structure of the end caps and pipes, which are difficult to form large recesses (reference numeral 112 in the cited invention), the end caps are inevitably pulled out during numerous stretching operations. Elongated length by having a separate fixing part (reference numeral 114 in the cited invention) and partitioned separately from the spring (reference numeral 140 in the cited invention) There is a problem in that the length of the antenna can not be extended as much as possible compared to the length of the antenna pipe at the time of stretching the antenna, and the complex of forming the convex portion (reference numeral 132 in the cited invention) apart from the fixing part and the spring described above. There was a problem in that there is a structure, and as described above, when the end antennas are not shrunk in sequence or the antennas are not inserted due to foreign matters, the user uses excessive force, which causes the end cap to be deformed due to physical deformation. There is a big problem that there is a risk of failure to fall back.

The present invention for solving the above-mentioned problems is to simplify the components in the coupling structure between the antenna pipe to be multi-stage coupled to reduce the weight due to the components constituting the product compared to the prior art while achieving the cost reduction effect Increases the assembly and productivity, and also improves the coupling force between the end cap and the antenna pipe compared to the conventional multi-stage antenna coupling structure, which causes failure of the lower end of the front antenna pipe to fall behind the rear antenna pipe even by numerous telescopic operation of the multi-stage antenna. The goal is to be able to significantly reduce it.

   The present invention for achieving the above object,

   In a general multi-stage antenna having a structure in which a plurality of antenna pipes are continuously inserted through a cylindrical plate spring and stretched in a telescopic manner,

   An end cap having a cylindrical head portion having an insertion portion inserted into the lower end of the antenna pipe and a stepped portion preventing the retraction of the cylindrical plate spring and restricting insertion into the lower end of the antenna pipe, wherein the insertion portion of the end cap is provided. The end cap insertion part rolling groove and the antenna pipe lower rolling groove are formed by rolling the pressure that is pressed in the circumferential direction of the antenna pipe within the range in which the insertion portion of the end cap is inserted in the state inside the lower end of the antenna pipe. ; The lower end of the cylindrical plate spring provides a multi-stage antenna, characterized in that the rolling projection is inserted into the rolling groove at the lower end of the antenna pipe in the circumferential direction is fixed to perform the coupling between the antenna pipe.

In the above-described configuration, the cylindrical plate spring has a lower edge and an upper edge at upper and lower ends of the leaf spring portion, and the rolling protrusion is formed on the lower edge.

   Alternatively, in the above-described configuration, the cylindrical plate spring has a lower border and an upper border at the upper and lower ends of the leaf spring portion, characterized in that the rolling protrusion is formed on the upper border.

    In addition, in the above-described configuration, the rolling protrusion is formed on both the upper edge and the lower edge and doubled, and correspondingly, the rolling groove is also doubled in two.

On the other hand, the present invention, in the above-described configuration, instead of the end cap insertion portion rolling groove and the antenna pipe lower rolling groove formed in the circumferential direction of the end cap inserting portion and the antenna pipe at least three places in the circumferential direction Composed of a pressurized spot groove, the cylindrical plate spring may be composed of three or more spot projections instead of the rolling projection.

According to the present invention having the above-described configuration, the action of suppressing the end cap coming off even if the previous stage presses the end cap maintains the coupling force between the lower end of the antenna pipe and the rolling groove in which the end cap is rolled together. The force that prevents the antenna pipe rolling groove from expanding by the physical action that the rolling protrusion penetrates, so that the user excessively extends the multi-stage antenna, the other end when the force is driven to the end cap or by foreign matter The end cap does not easily come out of the antenna pipe even when the lower end of the front end of the antenna pipe is pushed down by the insert portion of the end cap with a large force due to the antenna not being easily inserted (reduced). When pressed, the cylindrical plate spring is easily retracted Because of the loss, it is possible to increase the reliability of the stretching action that causes most of the multi-stage antennas and to significantly reduce the occurrence of failures. In addition, compared to the prior art, the length of the stretched antenna can be further increased when each stage antenna pipe is the same size. That is, the length of the antenna can be increased compared to the length when the antenna is reduced in the same antenna stage. In addition, it is possible to prevent the movement of the cylindrical leaf spring during sliding by the expansion and contraction operation to prevent the deviation of the cylindrical leaf spring.

1 is a view showing a general multi-stage antenna applied state,
Figure 2a and 2b is a cross-sectional view shown for explaining a conventional multi-stage antenna coupling structure,
Figure 3 is a cross-sectional view shown to explain another conventional multi-stage antenna coupling structure,
4A and 4B are perspective views illustrating the coupling structure of the multistage antenna of the present invention, and FIGS. 5A and 5B and 5C are cross-sectional views illustrating the coupling structure of the multistage antenna of the present invention;
Figure 6 is a view for helping to understand the direction of the operating direction and the pressure force during the expansion and contraction in the multi-stage antenna of the present invention,
7 is a perspective view showing another embodiment of the present invention,
8 is a perspective view showing another embodiment of the present invention;
9 is a cross-sectional view showing the circumferential arrangement of the spot projections in the embodiment of FIG.

   Hereinafter, the present invention will be described with reference to the accompanying drawings.

   4A and 4B are perspective views illustrating the coupling structure of the multistage antenna of the present invention, and FIGS. 5A and 5B and 5C are cross-sectional views illustrating the coupling structure of the multistage antenna of the present invention, and FIG. In order to understand the operation direction and the direction of the pressure force in the expansion and contraction in the multi-stage antenna. 7 is a perspective view showing another embodiment of the present invention.

    As shown in Figures 4a to 6, the multi-stage antenna (1) of the present invention is a comprehensive technology that has a structure in which a plurality of antenna pipes 100 are continuously inserted through the cylindrical plate spring (200) telescopically stretched The concept is the same as that of the general multi-stage antenna 1. Each stage antenna pipe 100 is different in diameter and inner diameter, but is provided with the same reference numerals as 100 for convenience.

    In the present invention will be described in detail with respect to the different parts from the prior art. 4A to 6, the multi-stage antenna of the present invention prevents the retraction of the insertion portion 310 and the cylindrical plate spring 200 inserted into the lower end of the antenna pipe 100 and at the same time the antenna pipe ( It has an end cap 300 having a cylindrical head portion 320 having a step 322 to restrict the insertion of the lower end of the 100, the insertion portion 310 of the end cap 300 is the antenna pipe ( 100) the end cap inserting part rolling groove by being pressed by pressing in the circumferential direction of the antenna pipe 100 within a range in which the inserting part 310 of the end cap 300 is located inside the lower end part. 410 and a rolling groove 420 formed below the antenna pipe; At the edge of the cylindrical plate spring 200, a rolling protrusion 430 is inserted into and fixed to the rolling groove 420 at the lower end of the antenna pipe in the circumferential direction to form a coupling between the antenna pipes 100. It is characterized by.

  The cylindrical plate spring 200 is a general having a lower border 230 and the upper border 220 at the upper and lower ends of the leaf spring 210, as shown in Figure 4a, the rolling protrusion 430 is a lower border ( 230, characterized in that formed. Figure 5a shows a state in which it is coupled to the multi-stage antenna.

  In addition, the cylindrical plate spring 200 may be coupled to the rolling protrusion 430 is formed on the upper border 220 as shown in Figure 4b as shown in Figure 5b.

  In addition, as illustrated in FIGS. 4C and 5C, the rolling protrusion 430 may be formed on both the upper border 220 and the lower edge 230 to be dualized, and correspondingly, the two rolling grooves 410 and 420 may be dualized. Of course you can.

   The effect of the present invention configured as described above may refer to FIG. 7 to help explain the effects of the present invention described above.

  In FIG. 7, reference numeral A denotes the multi-stage antenna 1 extending direction, and in this case, a force acting on the end cap 300, more specifically, a force acting on the circumferential step 322 of the cylindrical head part 320. do. Reference numeral B is a direction in which the lower end of the upper antenna is lowered when the multi-stage antenna (1) is reduced, and the pressing force acts in the direction in which the end cap 300 is pulled out. If there is a force applied to the end cap 300 when extending the multi-stage antenna, the end cap 300 may act as a force to fall out, but such force is in close contact with the inner surface of the antenna pipe 100 and acts as a leaf spring 210 It is limited to some extent by the spring elastic pressure of the coupling force for exceeding this limiting force by the coupling structure of the rolling groove (410, 420) formed by pressing together with the lower end of the antenna pipe 100 described above also Coupling structure can be maintained by a double coupling in which the coupling strength can be maintained and the coupling strength is added by the rolling protrusion 430 formed in the cylindrical plate spring 200.

  In addition, when pressing the lower end portion of the front end antenna pipe 100 by pressing the insertion portion 310 of the end cap acts in the direction in which the end cap 300 is pulled out, but in this case as well as the coupling structure by the double coupling force Will be maintained. Therefore, the coupling structure is maintained in a simple component configuration in comparison with the previously described, and compared to the known prior art shown in FIG. You can lengthen your height.

   In addition, this invention is not limited to the structure mentioned above.

As shown in FIG. 7, the end cap inserting portion 310 and the end cap inserting portion rolling grooves 410 formed in the circumferential direction of the lower end of the antenna pipe and the antenna pipe lower rolling grooves 420 instead of the rolling. The grooves 410 and 420 are formed of a spot groove 510 partially pressed to at least three places in the circumferential direction, and the cylindrical plate spring 200 is formed of three or more spot protrusions 520 instead of the rolling protrusion 430. Of course, it can be configured as an embodiment characterized in that. Although the spot protrusion 520 is circumferentially specified, it is referred to as circumferential direction by the edge supporting the leaf spring portion 210 of the cylindrical leaf spring 200, but the upper and lower areas of the edges 220 and 230 of the cylindrical leaf spring 200 are not included. As a matter of course, some small dimensions on the straight line in the circumferential direction may deviate from the straight line in the circumferential direction.

The present invention can be formed as another embodiment as shown in FIGS. 8 and 9.

  In a multi-stage antenna for a general mobile terminal having a structure in which a plurality of antenna pipes 100 are continuously inserted through a cylindrical plate spring 200 and stretched in a telescopic manner,

   Cylindrical head portion having a stepped portion 322 which prevents the retraction of the insertion portion 310 and the cylindrical plate spring 200 inserted into the lower end of the antenna pipe and restricts the insertion to the lower end of the antenna pipe 100 ( An end cap 300 having an end cap 300 is provided, and the insertion portion 310 of the end cap is inserted in the state where the insertion portion 310 of the end cap 300 is inserted into the lower end of the antenna pipe 100. Rolling is pressurized in the circumferential direction of the antenna pipe 100 within the range located in the end cap insertion portion rolling groove 410 and the lower end of the antenna pipe rolling groove 420 is formed; At the lower end of the cylindrical plate spring 200, spot projections 520 inserted into the rolling groove 420 at the lower end of the antenna pipe in the circumferential direction are formed at three or more positions. The spot protrusion 520 may be formed by caulking the leaf spring. In the caulking process, in the process of forming a cylindrical plate spring by a mold in the form of a plate, the coking may be performed simultaneously with the forming of a cylinder or may be performed when the plate has a plate shape before forming into a cylinder. This structure prevents the movement of the cylindrical plate spring 200 and the movement of the antenna pipe 100 when the spot protrusion 520 of the cylindrical plate spring is reinforced in addition to the coupling force between the rolling grooves 410 and 420. It is possible to increase the coupling force of the lower end and the end cap 300. The spot protrusion 520 is a cross-sectional view as shown in FIG. 9, but is shown to be formed at five locations, but the number may vary depending on the size of the cylindrical antenna.

  When the spot protrusion 520 is formed by caulk instead of the rolling protrusion 430, when the thickness of the cylindrical plate spring is large or the strength is large, the spot protrusion 520 may be easily formed as compared with the rolling protrusion 430. If the strength is large, since the shape of the spot protrusion 520 is not easily deformed, the force held while pressing the lower rolling groove 430 described above is strongly maintained, so that the end cap 300 is pulled out by external physical influences. It is advantageous for the escape or cylindrical leaf spring to remain in position.

  8A, 8B, and 8C show examples in which spot protrusions may be formed on both the lower and upper edges of the cylindrical leaf spring. If formed on both, the effect will be greater.

Compared to the prior art Korean Patent Publication No. 10-2008-32434 in all embodiments, the present invention described above has the effect of increasing the elongated length compared to the tightening force of the end cap and the reduced length of the multi-stage antenna. There is. In addition, cost reduction can be achieved due to simplification of parts and assembly, and the simple structure allows the cylindrical leaf spring to be positioned at the bottom of the antenna pipe without departing from its position. In addition, as the end cap does not easily fall off, the coupling force between the antenna pipes is maintained, thereby lowering the failure rate at which the upper antenna pipe falls below the larger diameter antenna pipe.

1- multi-stage antenna
100-antenna pipe 200-cylindrical plate spring
210-Plate spring 220-Top border 230-Bottom border
300-end cap 310-insertion 320-head 322-step
410-end cap insert rolling groove 420-antenna pipe lower rolling groove
430-rolling protrusion
510-spot projection 520-spot groove

Claims (6)

In a multi-stage antenna for a general mobile terminal having a structure in which a plurality of antenna pipes 100 are continuously inserted through a cylindrical plate spring 200 and stretched in a telescopic manner,
End cap having a cylindrical head portion 320 having a step which prevents the retraction of the insertion portion 310 and the cylindrical plate spring 200 inserted into the lower end of the antenna pipe and restricting the insertion into the lower end of the antenna pipe Although the insert portion 310 of the end cap is inserted into the lower portion of the antenna pipe 100, the insert portion 310 of the end cap is pressed in the circumferential direction of the antenna pipe within a range located therein The rolling process is pressurized so that the end cap inserting part rolling groove 410 and the antenna pipe lower rolling groove 420 are formed; The lower end of the cylindrical plate spring 200 is formed with a rolling protrusion 430 is inserted into the antenna groove lower rolling groove 420 fixed in the circumferential direction is characterized in that the structure to couple the antenna pipe 100 Multi-stage antenna for mobile terminal. According to claim 1, wherein the cylindrical plate spring 200 has a lower border and an upper border at the upper and lower ends of the leaf spring 210, respectively, the rolling protrusion 430 is characterized in that formed on the lower border Multi-stage antenna for mobile terminal. According to claim 1, wherein the cylindrical plate spring 200 has a lower border and an upper border on the upper and lower edges of the leaf spring 210, the rolling protrusion 430 is characterized in that formed on the upper border Multi-stage antenna for mobile terminal. According to claim 1, wherein the cylindrical plate spring 200 as having a lower border and the upper border on the upper and lower edge of the leaf spring 210, the rolling projection 430 the upper edge of the cylindrical plate spring (200) And a dual edge antenna formed on both lower edges and correspondingly duplicated to two end cap inserting rolling grooves 410 and an antenna pipe lower rolling groove 420. According to any one of claims 1 to 4, The end cap inserting portion 310 and the end cap insertion portion rolling groove 410 formed in the circumferential direction of the lower end of the antenna pipe and the antenna pipe lower rolling groove ( 420 instead of three or more spot grooves 520 partially pressurized in the circumferential direction, and the cylindrical plate spring 200 has three or more positions corresponding to the spot grooves 520 instead of the rolling protrusion 430. Multi-stage antenna for a mobile terminal, characterized in that consisting of a spot projection (510). In a multi-stage antenna for a general mobile terminal having a structure in which a plurality of antenna pipes 100 are continuously inserted through a cylindrical plate spring 200 and stretched in a telescopic manner,
End cap having a cylindrical head portion 320 having a step which prevents the retraction of the insertion portion 310 and the cylindrical plate spring 200 inserted into the lower end of the antenna pipe and restricting the insertion into the lower end of the antenna pipe Although the insert portion 310 of the end cap is inserted into the lower portion of the antenna pipe 100, the insert portion 310 of the end cap is pressed in the circumferential direction of the antenna pipe within a range located therein The rolling process is pressurized so that the end cap inserting part rolling groove 410 and the antenna pipe lower rolling groove 420 are formed; The lower end of the cylindrical plate spring 200 is formed in three or more spot projections 520 are inserted into the antenna groove lower rolling groove 420 in the circumferential direction is formed so as to couple between the antenna pipe 100 Multi-stage antenna for a mobile terminal, characterized in that the.

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