KR101097281B1 - High power rf push connector - Google Patents

Abstract

PURPOSE: A high output RF push connector is provided to improve the shielding performance of an RF push connector by shielding the protruded connection terminal. CONSTITUTION: A female connector(10) includes a first housing(20), a first insulation block, and a first connection terminal(40). One side of the first connection terminal is protruded to the first housing. The other side of the first connection terminal passes through the first insulation block. The other side of the first connection terminal is installed in a first connection hole(24). A male connector(50) includes a second housing(60), a second insulation block(70), and a second connection terminal(80). One side of the second connection terminal is protruded to the outside of the second housing. The second connection terminal is combined with the first connection terminal.

Description

High Power RF Push Connector

The present invention relates to a high power RF push connector (High Power RF Push connector), and more particularly to a process for transmitting a high power RF signal due to the degradation of the shielding performance in the connection area of the female connector and the male connector The present invention relates to a high power RF push connector that can suppress external radiation and inflow of a signal in the present invention.

In general, mobile communication, broadcasting modules, amplifiers, filters, and the like use coaxial cables to connect the components. Such a coaxial cable includes an inner core wire made of a conductor for transmitting RF signals, an insulation and impedance matching dielectric (insulator) surrounding the core wire, and a conductor shielding the outside of the dielectric.

Since such coaxial cables are relatively thick and rigid and are not easy to connect with each other, a dedicated connector (hereinafter referred to as "ALP push connector") is used to maintain fastening and electrical connection. At this time, the RF push connector SMA (Sub Miniature type A) or N connector may be used.

The RF push connector is largely divided into a female connector and a male connector, and the female connector and the male connector are respectively connected to one end of a coaxial cable. The connector of the male connector is inserted into the connector of the female connector, and the connector of the male connector is coupled to the connector of the female connector. Each connector of the female connector and the male connector has a single tube shape and has a structure in which a connection terminal is formed therein. Typically, the RF push connector is designed to have an impedance characteristic of 50Ω and is used at 100W or less.

However, in the recent mobile communication or broadcasting system, as the use of high power of 100W or more becomes more frequent, there is a demand for a high output RF push connector that can stably transmit a high power RF signal.

In addition, since the connector of the male connector is inserted into and coupled to the connector of the female connector, there is a limit in securing a good connection force between the female connector of the single tube type and the male connector.

Accordingly, an object of the present invention to improve the shielding performance of the connection area of the female connector and the male connector to provide a high output RF push connector that can suppress the radiation of the signal and the influx of external signals in the process of delivering a high output RF signal. have.

Another object of the present invention is to provide a high output RF push connector that can be automatically coupled by the contact between the female connector and the male connector without using a separate tightening or tools when coupling between the female connector and the male connector.

In order to achieve the above object, the present invention provides an RF push connector comprising a female connector and a male connector. The female connector may include a first housing having a first connection hole, a first insulating block having a portion inserted into the first connection hole, one side protruding out of the first housing, and the other side passing through the first insulating block. 1st connection hole is provided with the 1st connection terminal provided in the longitudinal direction of the said 1st connection hole. The male connector has a second connection hole is formed and the second housing is inserted into the first connection hole, the second insulating block with a part inserted into the second connection hole, one side protrudes out of the second housing and the other side And a second connection terminal penetrating the second insulating block and installed in the second connection hole in the lengthwise direction of the second connection hole to be coupled to the first connection terminal. In this case, the first housing of the female connector includes a first fastening plate and a double connection tube protruding from one side of the first fastening plate to correspond to the length of the first connection terminal. The second housing of the male connector includes a second fastening plate and a connection pipe protruding in a length direction of the second connection terminal from one side of the second fastening plate and inserted into the double connection pipe.

In the high output RF push connector according to the present invention, the double connecting tube includes an inner connecting tube surrounding the first connecting terminal protruding from the bottom surface of the first insulating block inserted into the first connecting hole, and It is connected to the lower end of the inner connection pipe, and comprises an outer connection pipe surrounding the inner connection pipe spaced apart from the inner connection pipe. At this time, the male connector is inserted and coupled between the inner connector and the outer connector.

In the high output RF push connector according to the present invention, the inner connecting pipe is divided into a plurality of in the longitudinal direction of the first connecting terminal. The connecting tube has an inner diameter of one end that is larger than an outer diameter of the inner connecting tube and smaller than an inner diameter of the outer connecting tube, and the inner diameter is formed to narrow from one end to a predetermined depth, and the narrowed inner diameter of the inner connecting tube Having a length corresponding to an outer diameter, the connection tube may be elastically coupled to the internal connection tube.

In the high output RF push connector according to the present invention, a support step is formed between the inner connection pipe and the external connection pipe and inside the connection pipe, and one end of the connection pipe is formed on the support jaw of the double connection pipe. One end of the inner connection pipe is in close contact with or in contact with the base jaw of the connection pipe, and an inner surface of the base jaw of the connection pipe and an inner surface of the inner connection pipe may be positioned on substantially the same surface.

In the high output RF push connector according to the present invention, one side of the first insulating block protrudes to the other side of the first fastening plate, and the other side of the first insulating block is inserted into the first connection hole to allow the first insulation. The edge portion of the bottom surface of the block may be fixed in close contact with the lower surface of the base jaw of the double connection pipe. One side of the second insulating block protrudes to the other side of the second fastening plate, and the other side of the second insulating block is inserted into the second connection hole so that an edge portion of the bottom surface of the second insulating block is connected to the connection pipe. It can be fixed in close contact with the lower surface of the base jaw of the.

In the high output RF push connector according to the present invention, the first connection terminal may include an insertion pin protruding from the bottom surface of the first insulating block. The second connection terminal includes a coupling pin protruding from the bottom surface of the second insulating block, the coupling pin is formed with a coupling groove to which the insertion pin is inserted and coupled, divided into a plurality of longitudinally inserted The insertion pin may be elastically coupled.

According to the present invention, since the connector of the male connector is inserted into the double connector of the female connector and shields the connecting connector protruding out of the insulating block of the female connector and the male connector in three times, the shielding performance of the RF push connector is improved. It is possible to suppress the flow and inflow of the signal in the process of delivering the high output RF signal. At this time, since the connecting terminal is surrounded by the connecting tube and the connecting tube as a whole, and substantially the same thickness, the flow of high power RF signal is prevented from flowing in and out of the specific part in the process of transmitting the RF signal. Can be passed.

Also in the double connector of the female connector, the inner connector is formed to be substantially the same length as the connecting terminal exposed to the inner connector, and the outer connector is substantially the same or more than the connecting terminal exposed to the inner connector. Since it is formed long, it can shield and surround the whole connection terminal connected at the time of mating with a male connector, and can suppress the flow and inflow of a signal in the process of transmitting a high output RF signal.

In addition, since a plurality of inner connecting pipes are divided in the longitudinal direction of the female connector among the double connecting pipes of the female connector, the male connector is elastically connected between the double connecting pipes of the female connector. As a result, the coupling force between the female connector and the male connector can be strengthened. In addition, since the connecting terminal of the female connector is elastically inserted and connected to the connecting terminal of the male connector, the coupling force between the female connector and the male connector can be strengthened by improving the coupling force between the connecting terminals. Good contact reliability between the connection terminals can be ensured.

In addition, the inner diameter of one end of the connector of the male connector is larger than the outer diameter of the inner connector of the female connector and smaller than the inner diameter of the outer connector, and the inner tube of the male connector is formed in such a manner that the inner diameter is narrowed from one end to a certain depth. Since the male connector has a length corresponding to the outer diameter of the inner connector of the female connector, the male connector is stably inserted to the female connector to a certain depth, and then moves toward the point where the inner and outer diameters become narrow, resulting in narrowing of the split inner connector. Sexually coupled. This enhances the coupling force between the female connector and the male connector while inducing a stable coupling between the female connector and the male connector.

1 is an exploded perspective view showing an RF push connector according to an embodiment of the present invention.
FIG. 2 is a partial cutaway perspective view showing the female connector of FIG. 1. FIG.
3 is a partially cutaway perspective view showing the male connector of FIG.
4 is a cross-sectional view taken along the line 4-4 of FIG.
5 is a perspective view showing a combined RF push connector according to an embodiment of the present invention.
6 is a cross-sectional view taken along line 6-6 of FIG.

It should be noted that in the following description, only parts necessary for understanding the embodiments of the present invention will be described, and descriptions of other parts will be omitted so as not to distract from the gist of the present invention.

The terms or words used in the specification and claims described below should not be construed as being limited to the ordinary or dictionary meanings, and the inventors are appropriate to the concept of terms in order to explain their invention in the best way. It should be interpreted as meanings and concepts in accordance with the technical spirit of the present invention based on the principle that it can be defined. Therefore, the embodiments described in the present specification and the configuration shown in the drawings are only preferred embodiments of the present invention, and do not represent all of the technical idea of the present invention, and various equivalents may be substituted for them at the time of the present application. It should be understood that there may be variations and variations.

Hereinafter, with reference to the accompanying drawings will be described in detail an embodiment of the present invention.

1 is an exploded perspective view showing an RF push connector according to an embodiment of the present invention. FIG. 2 is a partial cutaway perspective view showing the female connector of FIG. 1. FIG. 3 is a partially cutaway perspective view showing the male connector of FIG. 4 is a cross-sectional view taken along the line 4-4 of FIG. 5 is a perspective view showing a combined RF push connector according to an embodiment of the present invention. 6 is a cross-sectional view taken along line 6-6 of FIG.

1 to 6, the RF push connector 100 according to the exemplary embodiment of the present invention includes a female connector 10 and a male connector 50, and is connected to the double connector 23 of the female connector 10. The connector 63 of the male connector 50 has a structure that can be elastically coupled.

The female connector 10 includes a first housing 20, a first insulating block 30, and a first connection terminal 40. The first housing 20 is formed with a first connection hole 24. A part of the first insulating block 30 is inserted into the first connection hole 24. In addition, one side of the first connection terminal 40 protrudes out of the first housing 10, and the other side of the first connection terminal 40 passes through the first insulating block 30 and has a length of the first connection hole 24 in the first connection hole 24. Direction is installed.

The male connector 50 includes a second housing 60, a second insulating block 70, and a second connection terminal 80. The second housing 60 is inserted into the first connecting hole 24 and the second connecting hole 64 is formed. A part of the second insulating block 70 is inserted into the second connection hole 64. In addition, one side of the second connection terminal 80 protrudes out of the second housing 60, and the other side of the second connection terminal 80 passes through the second insulating block 70 and has a length of the second connection hole 64 in the second connection hole 64. Direction and is coupled to the first connection terminal 40.

In addition, the first housing 20 of the female connector 10 has a first connection plate 21 and a double connection tube protruding corresponding to the length of the first connection terminal 40 from one side of the first connection plate 21. And (23). In addition, the second housing 60 of the male connector 50 protrudes in the lengthwise direction of the second connection terminal 80 from one side of the second fastening plate 61 and the second fastening plate 61 and has a double connection pipe ( And a connecting tube 63 inserted into the 23.

The female connector 10 and the male connector 50 according to the present embodiment will be described in detail as follows.

First, the female connector 10 will be described with reference to FIGS. 1 and 2.

The first housing 20 is made of a metal material and shields the first and second connection terminals 40 and 80 to be joined. The first fastening plate 21 has a fastening hole 22 to which bolts can be fastened at four corners in the form of a square plate. The double connecting pipe 23 is formed to protrude from one side of the first fastening plate 21. The 1st connection hole 24 is formed in the center part of the 1st fastening board 21 and the double connection pipe 23. As shown in FIG. The double connection pipe 23 may be bonded to one side of the first fastening plate 21.

A part of the first insulating block 30 protrudes to the other side of the first fastening plate 21, and another part of the first insulating block 30 includes the first connection hole 24 of the double connection pipe 23 including the first fastening plate 21. ) Is inserted. The first insulating block 30 insulates the first connecting terminal 40 from the double connecting pipe 23 and performs an impedance matching function. An insulating plastic material such as Teflon may be used as the material of the first insulating block 30.

The first connection terminal 40 passes through the first insulating block 30 and is installed in the longitudinal direction of the first connection hole 24, and one end thereof protrudes to the other side of the first fastening plate 21. The first insulating block 30 protrudes out of one end surface of the insulating block 30, and the other end is inserted into the other end surface (or bottom surface) of the first insulating block 30, that is, the first connection hole 24. Protruding to a predetermined length with respect to the bottom surface of the). At this time, the first connecting terminal 40 is provided in the axial direction of the first connecting hole 24. A portion of the first connection terminal 40 exposed to the first connection hole 24 may be formed in a pin type.

In this case, the double connector 23 includes an inner connector 25 and an outer connector 27, and the connector 63 of the male connector 50 includes an inner connector 25 and an outer connector 27. It is inserted in between and elastically coupled. The inner connection pipe 25 surrounds the first connection terminal 40 protruding from the bottom surface of the first insulating block 30 inserted into the first connection hole 24. And the outer connection pipe 27 is connected to the lower end of the inner connection pipe 25, spaced apart from the inner connection pipe 25 by a predetermined interval surrounding the inner connection pipe (25). Therefore, an insertion groove 28 through which the connection tube 63 of the male connector 50 can be inserted is formed between the internal connection tube 25 and the external connection tube 27.

The inner connection tube 25 is formed to have substantially the same length as the portion of the first connection terminal 40 protruding from the bottom surface of the first insulation block 30, and the outer connection tube 27 is formed of the first insulation block 30. It may be formed to be the same as or longer than the portion of the first connection terminal 40 protruding from the bottom surface. The reason for this formation is to suppress the occurrence of noise in the process of transmitting the high power RF signal by shielding the entire first and second connection terminals 40 and 80 when they are combined with the male connector 50. .

In addition, the internal connection pipe 25 is divided into a plurality in the longitudinal direction of the first connection terminal 40. The reason for forming in this way is to allow the connection tube 63 of the male connector 50 to be inserted into the internal connection tube 25 to be elastically coupled.

In addition, the outer circumferential surface of the front end of the inner connecting pipe 25 is formed with a fixing jaw 26 that can be fixed after being inserted into the connecting pipe 63 of the male connector 50. As will be described later, a fixing groove (66 in FIG. 3) is formed inward from the inner circumferential surface of the connecting tube 63 to correspond to the fixing jaw 26 in the connecting tube 63 of the male connector 50.

Such a female connector 10 may be assembled as follows. First, the first connection hole 24 of the double connection pipe 23 in a state where the first connection terminal 40 on which the first fastening plate 21, the double connection pipe 23, and the first insulating block 30 are formed is prepared. ) Is inserted into and fixed to the first insulating block 30 including a portion from which the first connecting terminal 40 to be connected to the second connecting terminal 80 protrudes. At this time, the first connection terminal 40, in which the first insulating block 30 is connected to the coaxial cable, protrudes to one side of the double connection pipe 23. The female connector 10 may be manufactured by inserting the first fastening plate 21 into the first insulating block 30 protruding to one side of the double connecting pipe 23, and then attaching the first fastening plate 21 to the double connecting pipe 23. Can be.

Next, the male connector 50 will be described with reference to FIGS. 1 to 3.

The second housing 60 is made of a metal material and is inserted and elastically coupled between the inner connection pipe 25 and the outer connection pipe 27, and the first and second connections together with the first housing 20. Shield the terminals 40, 80. The second fastening plate 61 has a fastening hole 62 to which bolts can be fastened at four corners in the form of a square plate. The connection tube 63 is formed to protrude from one side of the second fastening plate 61. The second connection hole 64 is formed in the center portion of the second fastening plate 61 and the connection pipe 63. The connection tube 63 may be bonded to one side of the second fastening plate 61.

Part of the second insulating block 70 protrudes to the other side of the second fastening plate 61, and the other part of the second connection hole 64 of the connection pipe 63 including the second fastening plate 61. It is inserted in. The second insulating block 70 insulates the second connection terminal 80 from the connection tube 63 and performs an impedance matching function. An insulating plastic material such as Teflon may be used as the material of the second insulating block 70.

The second connection terminal 80 penetrates through the second insulating block 70 and is installed in the longitudinal direction of the second connection hole 64, and one end thereof protrudes to the other side of the second fastening plate 61. The second insulating block 70 protrudes out of one end surface of the insulating block 70, and the other end is inserted into the other end surface (or bottom surface) of the second insulating block 70, that is, the second connection hole 64. Protruding to a predetermined length with respect to the bottom surface of the). At this time, the second connection terminal 80 is provided in the axial direction of the second connection hole 64. The second connection terminal 80 exposed to the second connection hole 64 may be formed as a groove type into which the pin type first connection terminal 40 may be inserted and coupled.

The male connector 50 can be assembled as follows. First, in a state in which the second connection terminal 80 having the second fastening plate 61, the connection tube 63, and the second insulating block 70 is prepared, the second connection hole 64 of the connection tube 63 is formed. The second insulating block 70 including the protruding portion of the second connection terminal 80 to be connected to the first connection terminal 40 is inserted and fixed. At this time, the second connection terminal 80, which is connected to the coaxial cable, with the second insulating block 70 protruded to one side of the connection pipe 63. The male connector 50 may be manufactured by inserting the second fastening plate 61 into the second insulating block 70 protruding to one side of the connecting tube 63 and then attaching the second fastening plate 61 to the connecting tube 63. .

At this time, the connection tube 63 is formed in a form that the inner diameter of one end is larger than the outer diameter of the inner connection pipe 25 and smaller than the inner diameter of the outer connection pipe 27, the inner diameter is narrowed from one end to a certain depth, narrowed inner diameter May have a length corresponding to the outer diameter of the inner connecting pipe 25. As a result, the connection pipe 63 may be elastically coupled to the divided internal connection pipe 25. That is, since the inner diameter of one end of the connecting tube 25 is larger than the outer diameter of the inner connecting tube 25, and the outer diameter of the connecting tube 25 is smaller than the inner diameter of the outer connecting tube 27, the connecting tube 63 is internally connected. The insertion can be stably started between the pipe 25 and the external connection pipe 27. And the connection pipe 25 is formed in the form that the inner diameter is narrowed from one end to a predetermined depth, since the narrow inner diameter has a length corresponding to the outer diameter of the inner connection pipe 25, the internal connection inserted into the connection pipe 63 The pipe 25 is elastically in close contact with the inner circumferential surface of the connection pipe 63 while the interval between the divided internal connection pipes 25 is narrowed while the inclined surface inside the connection pipe 63 is inserted into the connection pipe 63.

In this case, one end of the connection tube 63 may contact or approach the bottom surface between the inner connection tube 25 and the external connection tube 27, that is, the first fixing jaw 29. The connection pipe 63 has a second support jaw 69 formed therein, and one end of the internal connection pipe 25 may contact the second support jaw 69. The inner side surface of the second base jaw 69 and the inner side surface of the inner connection pipe 25 may be positioned on substantially the same surface. At this time, a fixing groove 66 to which the fixing jaw 26 of the inner connection pipe 25 is coupled is formed around the inner surface of the second supporting jaw 69.

One side of the first insulating block 30 protrudes to the other side of the first fastening plate 21, and the other side of the first insulating block 30 is inserted into the first connection hole 24 so that the first insulating block 30 is formed. The edge portion of the bottom surface of the double contact tube 23 is fixed in close contact with the first support jaw (29). In addition, one side of the second insulating block 70 protrudes to the other side of the second fastening plate 61, and the other side of the second insulating block 70 is inserted into the second connection hole 64 to form the second insulating block 70. The edge portion of the bottom surface of the c) is in close contact with and fixed to the lower surface of the second support jaw 69 of the connection pipe 63.

The first connection terminal 40 includes an insertion pin 45 protruding from the bottom surface of the first insulating block 30. In addition, the second connection terminal 70 includes a coupling pin 85 protruding from the bottom surface of the second insulating block 70. At this time, the coupling pin 85 is provided with a coupling groove 85a to which the insertion pin 45 is inserted and coupled, and elastically couples the insertion pin 45 to be inserted into a plurality of inserts in the longitudinal direction.

Here, the first connection terminal 40 is connected to the first connecting portion 41 and the first connecting portion 41 that protrude out of one end surface of the first insulating block 30 and connected to the coaxial cable, and the first insulating block 30. The insertion pin 45 is connected to the first sealing portion 43, the first sealing portion 43 is sealed in the protruding to the bottom surface of the first insulating block 30 is inserted into the second connection terminal (80). Include. In this case, the protrusion 43a may be formed on the outer surface of the first seal 43 so that the first seal 43 may be stably sealed to the first insulating block 30. That is, the first suture portion 43 is basically formed with the same outer diameter as the first connection portion 41, the outer diameter is formed larger than the other portion only the protrusion 43a. Although the protrusion 43a has been disclosed as an example in the form of a continuous pad surrounding the outer surface of the first suture 43, it may be formed in the form of a discontinuous projection. Insertion pin 45 may be formed in a two-stage shape to be stably supported on the bottom surface of the first insulating block (30). The insertion pin 45 may include a support part 45a protruding from the bottom surface 31 of the first insulating block 30 and an insertion part 45b protruding from the support part 45a. Here, the support 45a has an outer diameter larger than that of the first sealing portion 43 so that the support portion 45a can be supported by the bottom surface 31 of the second insulating block 30. Insertion portion (45b) has a smaller outer diameter than the support portion (45a), the end is formed pointed to be stably coupled to the coupling groove 85 of the coupling pin (85).

The second connection terminal 80 protrudes out of one end surface of the second insulating block 70 and is connected to the second connecting portion 81 and the second connecting portion 81 connected to the coaxial cable and sealed to the second insulating block 70. Coupling pin 85 is connected to the second sealing portion 83, the second sealing portion 83 is projected to the bottom surface 71 of the second insulating block 70 to insert the insertion pin 45 is coupled Has In this case, the second sealing unit 83 may have a protrusion 83a formed on an outer surface thereof so that the second sealing unit 83 may be stably sealed to the second insulating block 70. That is, the second suture portion 83 is formed to have the same outer diameter as the second connection portion 81, and the outer diameter is larger than the other portions of the protrusion portion 83a. Although the protrusion 83a has been disclosed as an example in the form of a continuous pad surrounding the outer surface of the second suture portion 83, it may be formed in the form of a discontinuous projection. At this time, the coupling pin 85 is formed to have a larger outer diameter than the second sealing portion 83 so as to be stably supported on the bottom surface 71 of the first insulating block 70. The coupling pin 85 has a coupling groove 85a corresponding to the outer diameter of the insertion portion 45b of the insertion pin 45 at the center portion.

In addition, the coupling pin 85 is provided with a coupling groove 85b to which the insertion pin 45 is inserted and coupled, and elastically couples the insertion pin 45 inserted into the plurality of insertion pins 45 in the longitudinal direction. At this time, the inlet of the coupling groove (85b) is formed larger than the outer diameter of the insertion pin 45, so that the insertion pin 45 can be stably inserted. The depth of the coupling groove 85b is formed at least deeper than the insertion portion 45b of the insertion pin 45. When the male connector 50 is inserted into and coupled to the female connector 10, the upper surface of the support part 45b of the insertion pin 45 may be located close to or in contact with the upper surface of the coupling pin 85.

As described above, the RF push connector 100 according to the present embodiment is inserted with the connector 63 of the male connector 50 inserted into the double connector 23 of the female connector 10 so that the female connector 10 and the male connector ( Since the entire first and second connection terminals 40 and 80 protruding out of the bottom surfaces 31 and 71 of the first and second insulating blocks 30 and 70 of the 50 are triple surrounded and shielded, the RF push is performed. The shielding performance of the connector 100 may be improved to prevent noise from being generated during the transfer of the high output RF signal. In this case, the double connection tube 23 and the connection tube 63 are surrounded by substantially the same thickness while enclosing the first and second connection terminals 40 and 70 as a whole, thereby transmitting a high power RF signal. In order to suppress the generation of noise in a specific part, a uniform signal can be transmitted.

In addition, in the double connector 23 of the female connector 10, the inner connector 25 is formed to have substantially the same length as the portion of the first connector terminal 40 located in the inner connector 25, the outer The connection pipe 27 is formed to be substantially the same as or longer than the portion of the first connection terminal 40 positioned in the internal connection pipe 25 so that the first and second connections connected when the connection pipe 27 is engaged with the male connector 50. Since the entirety of the terminals 40 and 8 can be enclosed and shielded, it is possible to suppress the occurrence of noise in the process of transmitting the high output RF signal.

In addition, since the internal connector 25 is divided into plural in the longitudinal direction of the female connector 10 of the double connector 23 of the female connector 10, the male connector 50 is a double connector of the female connector 10. It may be elastically coupled between the connection pipe (23). For this reason, the coupling force between the female connector 10 and the male connector 50 can be strengthened. In addition, since the first connecting terminal 40 of the female connector 10 is elastically inserted and connected to the second connecting terminal 80 of the male connector 50, the first and second connecting terminals 40 and 80 are connected. The coupling force between the female connector 10 and the male connector 80 can be strengthened by improving the coupling force between the two. Good contact reliability between the first and second connection terminals 40 and 80 can be ensured.

In addition, the inner diameter of one end of the connector 63 of the male connector 50 is larger than the outer diameter of the inner connector 25 of the female connector 10 and smaller than the inner diameter of the outer connector 27, the male connector 50 Male connector 50 is formed in the form that the inner diameter is narrowed from one end to a predetermined depth and the narrow inner diameter has a length corresponding to the outer diameter of the inner connector 25 of the female connector 10, the male connector 50 Is stably inserted into the female connector 10 to a certain depth and then moved toward the point where the inner diameter and the outer diameter is narrowed and the elastic inner coupling 25 is narrowly coupled. As a result, the coupling force between the female connector 10 and the male connector 50 can be strengthened while inducing a stable coupling between the female connector 10 and the male connector 50.

Referring to the coupling method of the RF push connector 100 according to this embodiment as follows. First, as shown in FIGS. 1 to 4, the double connector 23 and the connector 63 align the female connector 10 and the male connector 50 to face each other. In this case, a coaxial cable may be connected to the female connector 10 and the male connector 50, respectively.

Next, the connection pipe 63 of the male connector 50 is inserted between the double connection pipe 23, that is, between the internal connection pipe 25 and the external connection pipe 27. At this time, since the inner diameter of one end of the connecting tube 63 is larger than the outer diameter of the inner connecting tube 25 and smaller than the inner diameter of the outer connecting tube 27, the connecting tube 63 is connected to the inner connecting tube 25 and the outer connecting tube ( 27) can be inserted stably between.

Subsequently, when the connection pipe 63 is pushed further into the double connection pipe 23, the connection pipe 63 is elastically coupled between the internal connection pipe 25 and the external connection pipe 27. That is, the connecting tube 63 is formed in a form in which the inner diameter is narrowed from one end to a predetermined depth, and since the narrowed inner diameter has a length corresponding to the outer diameter of the inner connecting tube 25, an internal connection inserted into the connecting tube 63 is formed. The pipe 25 is elastically coupled to the inner circumferential surface of the connection pipe 63 while the gap between the divided internal connection pipes 25 is narrowed while being inserted into the connection pipe 63 on the inclined surface inside the connection pipe 63. .

At this time, the first connecting terminal 40 positioned in the double connecting tube 23 is inserted into the second connecting terminal 80 positioned in the connecting tube 63 and elastically coupled thereto. That is, since the insertion pin 45 of the first connection terminal 40 is inserted while opening the coupling groove 85a of the coupling pin 85 divided into a plurality, the insertion pin 45 is burnt on the coupling pin 85. Sexually coupled.

Then, when the insertion coupling of the male connector 50 to the female connector 10 is completed, the front end of the inner connection tube 25 is in contact with the second support jaw 69 of the connection tube 63, the inner connection tube 63 The fixing jaw 26 formed on the outer circumferential surface of the tip is inserted into the fixing groove 66 formed on the second supporting jaw 69. The upper surface of the support portion 45a of the insertion pin 45 may be close to the upper surface of the coupling pin 85. The tip of the connection pipe 63 may be located close to the bottom surface between the internal connection pipe 25 and the external connection pipe 27. And both side surfaces of the connection tube 63 may be in close contact with the outer peripheral surface of the inner connection tube 25 and the inner peripheral surface of the outer connection tube 27.

On the other hand, the embodiments of the present invention disclosed in the specification and drawings are merely presented specific examples to aid understanding, and are not intended to limit the scope of the present invention. In addition to the embodiments disclosed herein, it is apparent to those skilled in the art that other modifications based on the technical idea of the present invention may be implemented.

10: female connector 20: first housing
21: first fastening plate 23: double connector
24: first connection hole 25: internal connection pipe
26: fixed jaw 27: external connection pipe
29: first base step 30: first insulating block
40: first connection terminal 45: insertion pin
50: male connector 60: second housing
61: second fastening plate 63: connection tube
64: second connection hole 66: fixing groove
69: second stand 70: second insulating block
80: second connection terminal 85: coupling pin
100: RF Push Connector

Claims (6)

A first housing in which a first connection hole is formed, a first insulating block having a portion inserted into the first connection hole, one side protruding out of the first housing, and the other side penetrating the first insulating block into the first connection hole A female connector having a first connecting terminal provided in a longitudinal direction of the first connecting hole;
A second housing formed with a second connection hole and inserted into the first connection hole, a second insulating block having a portion inserted into the second connection hole, one side of which protrudes out of the second housing, and the other side of the second insulation; And a male connector provided in the second connecting hole in the lengthwise direction of the second connecting hole and passing through the block, the male connector having a second connecting terminal coupled to the first connecting terminal.
The first housing of the female connector,
First fastening plate;
And a double connector pipe protruding from one side of the first fastening plate to correspond to the length of the first connection terminal.
The second housing of the male connector,
Second fastening plate;
A connection tube protruding in a length direction of the second connection terminal from one side of the second fastening plate and inserted into the double connection pipe;
RF push connector comprising a. The method of claim 1, wherein the double connection pipe,
An inner connecting tube surrounding the first connecting terminal protruding from the bottom surface of the first insulating block inserted into the first connecting hole;
It is connected to the lower end of the inner tube, the outer tube is spaced apart from the inner tube and the outer tube surrounding the inner tube;
The RF push connector, characterized in that the connection pipe of the male connector is inserted and coupled between the inner connection pipe and the external connection pipe. The method of claim 2,
The inner connecting pipe is divided into a plurality in the longitudinal direction of the first connecting terminal,
The connection tube has an inner diameter of one end is larger than the outer diameter of the inner connection tube is smaller than the inner diameter of the outer connection tube, the inner diameter is formed in a narrow shape from the one end to a predetermined depth, the narrowed inner diameter of the inner connection tube It has a length corresponding to the outer diameter, the RF push connector, characterized in that the connection pipe is elastically coupled to the inner connection pipe. The method of claim 3,
A support jaw is formed between the inner connection pipe and the external connection pipe and inside the connection pipe, respectively, and one end of the connection pipe is close to or contacts the support jaw of the double connection pipe, and the support jaw of the connection pipe. And one end of the inner connection tube contacts the inner side surface of the base jaw of the connection tube and the inner side surface of the inner connection tube is an RF push connector. The method of claim 4, wherein
One side of the first insulating block protrudes to the other side of the first fastening plate, and the other side of the first insulating block is inserted into the first connection hole so that the edge portion of the bottom surface of the first insulating block is double connected. Is fixed in close contact with the lower surface of the base of the pipe,
One side of the second insulating block protrudes to the other side of the second fastening plate, and the other side of the second insulating block is inserted into the second connection hole so that an edge portion of the bottom surface of the second insulating block is connected to the connection pipe. The RF push connector, characterized in that is fixed in close contact with the lower surface of the support jaw. The method of claim 1,
The first connection terminal includes an insertion pin protruding from the bottom surface of the first insulating block,
The second connection terminal includes a coupling pin protruding from the bottom surface of the second insulating block, the coupling pin is formed with a coupling groove to which the insertion pin is inserted and coupled, divided into a plurality of longitudinally inserted RF push connector, characterized in that the elastically coupled to the insertion pin.

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