CN219610981U - Frock structure of quick installation of radio frequency patch cord - Google Patents

Abstract

The utility model discloses a tool structure for rapidly installing a radio frequency patch cord, which comprises the following steps: the device comprises a power input structure, a transmission structure and a power output structure, wherein one end of the power input structure is connected with a power source; the transmission structure is connected with the other end of the power input structure; the power output structure is connected with the transmission structure; wherein, the power take off structure includes: the hollow output shaft and an output shaft connecting block arranged on the output shaft are also of a hollow structure, the output shaft is connected with the transmission structure, the output shaft connecting block is detachably assembled with one end of the sleeve, and the other end of the sleeve is matched with the nut; the line body part of the radio frequency patch cord passes through the output shaft connecting block and the inside of the output shaft. The utility model can lead the wire body part of the integrated radio frequency patch cord to pass through the middle part of the output shaft in the using process and directly contact with the nut on the connector to realize quick installation.

Description

Frock structure of quick installation of radio frequency patch cord

Technical Field

The utility model relates to the technical field of mechanical design, in particular to a tooling structure for quickly installing a radio frequency patch cord.

Background

The radio frequency switching line is a device for converting wired connection into wireless connection, is mainly applied to a device for converting wired audio signals into radio signals for transmission, and can be understood as a conversion device or a conversion interface. Along with the development of science and technology and economy, the application scene of the radio frequency connector is more and more penetrated into the aspects of human life, and the radio frequency connector is widely applied to the fields of communication, medical treatment, aerospace, transportation and the like, and is also commonly used in the fields of safety systems, civil aviation, microwave elements, radio frequency microwave switches, electronic consumer goods and the like.

The radio frequency patch cord mainly has two split and integral structures, the split type is that the line body and the connector part are separated, and the on-site connection is needed; the integral type is the form of line body and connector as an organic whole fixed connection. The split structure has the characteristics of simple structure, convenient installation and the like, but also has the problem of easy loosening; the integral structure has the advantages of stable structure and simple installation.

Therefore, the integrated radio frequency patch cord is more prone to being used at present, however, due to the interference of the cord body, the integrated radio frequency patch cord can only be manually fastened by using a spanner, and cannot be quickly locked by using an electric screwdriver, so that the efficiency is low; meanwhile, the method is not suitable for large-scale and batch production.

There is an urgent need for a rapid tooling structure for an integrated radio frequency patch cord to improve production efficiency.

Disclosure of Invention

Therefore, the utility model aims to provide a tooling structure for rapidly installing a radio frequency patch cord.

In order to achieve the above purpose, the technical scheme adopted by the utility model is as follows:

frock structure of quick installation of radio frequency patch cord, wherein includes:

one end of the power input structure is connected with the power source;

the transmission structure is connected with the other end of the power input structure;

the power output structure is connected with the transmission structure;

wherein, the power take off structure includes: the hollow output shaft and the output shaft connecting block arranged on the output shaft are also of a hollow structure, the output shaft is connected with the transmission structure, the output shaft connecting block is detachably assembled with one end of a sleeve, and the other end of the sleeve is matched with a nut; the wire body part of the radio frequency patch cord passes through the output shaft connecting block and the inside of the output shaft.

The frock structure of foretell radio frequency patch cord quick installation, wherein, transmission structure includes: the turbine is fixedly connected with the power input structure, the turbine is meshed with the worm, and the turbine is fixedly connected with the output shaft.

The tool structure for quickly installing the radio frequency patch cord comprises a turbine, wherein a through hole is formed in the middle of the turbine, an output shaft is arranged in the through hole, and the output shaft is fixedly connected with the turbine through a flat key.

The tool structure for rapidly installing the radio frequency patch cord is characterized in that two ends of the output shaft are respectively connected with the output shaft connecting blocks.

The tool structure for rapidly installing the radio frequency patch cord comprises an output shaft, wherein two annular clamping springs are arranged on the output shaft, the clamping springs are sleeved on the output shaft, a turbine is arranged between the two clamping springs, and the two clamping springs limit the position of the turbine.

The frock structure of foretell radio frequency patch cord quick installation, wherein still includes: and the transmission structure and at least one part of the power output structure are arranged in the outer shell.

The frock structure of foretell radio frequency patch cord quick installation, wherein, the shell body includes: the upper cover plate and the lower cover plate are oppositely arranged, the upper cover plate and the lower cover plate are respectively provided with a first bearing, and the worm is installed in the first bearings.

The frock structure of foretell radio frequency patch cord quick installation, wherein, the shell body includes: the left cover plate and the right cover plate are oppositely arranged, second bearings are arranged on the left cover plate and the right cover plate, and the output shaft is installed in the second bearings.

The tool structure for rapidly installing the radio frequency patch cord is characterized in that the inner part of the outer shell is connected through bolts.

The tool structure for rapidly installing the radio frequency patch cord comprises a power input structure and a power output structure, wherein the power input structure and the power output structure are provided with included angles.

The utility model adopts the technology, so that compared with the prior art, the utility model has the positive effects that:

(1) The utility model can lead the wire body part of the integrated radio frequency patch cord to pass through the middle part of the output shaft in the using process and directly contact with the nut on the connector to realize quick installation.

(2) The power input structure and the power output structure of the utility model have an included angle, so that the utility model can be suitable for being installed in the environment in a narrow and inconvenient way in a single direction

(3) The nut locking device can solve the problem that the nut of the radio frequency patch cord cannot be locked rapidly in batch and large-scale production, improves the assembly efficiency, and has the advantages of low cost, simple and compact structure, strong practicability and the like.

Drawings

Fig. 1 is a schematic diagram of a tooling structure for rapid installation of a radio frequency patch cord according to the present utility model.

Fig. 2 is an exploded schematic view of a tooling structure for rapid installation of a radio frequency patch cord according to the present utility model.

Fig. 3 is a schematic diagram of a radio frequency patch cord of the tooling structure for rapid installation of the radio frequency patch cord of the present utility model.

In the accompanying drawings: 1. a radio frequency patch cord; 2. a wire body; 3. a connector; 4. a baffle; 5. a nut; 6. a power input structure; 7. a worm; 8. a turbine; 9. a first bearing; 10. a flat key; 11. clamping springs; 12. an upper cover plate; 13. a lower cover plate; 14. an output shaft; 15. an output shaft connecting block; 16. a second bearing; 17. a left cover plate; 18. a right cover plate; 19. and (5) a bolt.

Detailed Description

The utility model is further described below with reference to the drawings and specific examples, which are not intended to be limiting. Fig. 1 is a schematic diagram of a tooling structure for rapid installation of a radio frequency patch cord of the present utility model; fig. 2 is an exploded schematic view of a tooling structure for rapid installation of a radio frequency patch cord of the present utility model; fig. 3 is a schematic diagram of a radio frequency patch cord of the tooling structure for rapid installation of a radio frequency patch cord of the present utility model, and referring to fig. 1 to 3, a tooling structure for rapid installation of a radio frequency patch cord according to a preferred embodiment is shown, including: the power input structure 6, the transmission structure and the power output structure, wherein one end of the power input structure 6 is connected with a power source; the other end of the transmission structure is connected with the other end of the power input structure 6; the power output structure is connected with the transmission structure; wherein, the power take off structure includes: the hollow output shaft 14 and an output shaft connecting block 15 arranged on the output shaft 14, the output shaft connecting block 15 is also of a hollow structure, the output shaft 14 is connected with the transmission structure, the output shaft connecting block 15 is detachably assembled with one end of a sleeve, and the other end of the sleeve is matched with the nut 5; the wire body 2 of the radio frequency patch cord 1 partially penetrates through the output shaft connecting block 15 and the inside of the output shaft 14.

In a preferred embodiment, the power input structure 6 is matched with an electric screwdriver, the electric screwdriver is used as a power source to provide power, the power is sequentially transmitted to the transmission structure and the power output structure from the power input structure 6, a sleeve is arranged on an output shaft connecting block 15 of the power output structure, one end of the sleeve, opposite to the output shaft connecting block 15, is matched with a nut 5 of the radio frequency patch cord 1, and therefore the power is finally transmitted to the nut 5, and further the rotation and installation of the nut 5 are achieved.

In a preferred embodiment, as shown in fig. 3, the present apparatus is directed to an integrated radio frequency patch cord 1, where the radio frequency patch cord 1 includes: the line body 2, connector 3, baffle 4 and nut 5, the line body 2 is connected with connector 3, and nut 5 and connector 5 matched with screw thread are equipped with on the connector 3 to baffle 4 between locating nut 5 and the connector 3, and baffle 4 and nut 5 are used for fixing radio frequency patch cord 1 in the position of predetermineeing, for example: a through hole is formed in one plate, the radio frequency patch cord 1 is installed in the through hole, the cord body 2 needs to penetrate through the through hole, one end of the plate is arranged on one part of the connector 3, the baffle 4 abuts against the end face of one end of the plate, the nut 5 abuts against the other end of the plate, threads on the nut 5 and the connector 3 are matched and locked, and the threads and the baffle 4 abut against two ends of the plate to achieve fixation.

Further, in the prior art, because the wire body 2 exists, an electric screwdriver cannot be used, and only a spanner can be used for screwing, so that time and labor are wasted; the device adopts the hollow output shaft 14, the wire body 2 passes through the inside of the output shaft 14, and the locking of the sleeve connected on the output shaft connecting block 15 to the nut 5 is not affected.

In a preferred embodiment, different nuts 5 can be accommodated using different sized sleeves.

In a preferred embodiment, the transmission structure comprises: the turbine 8 and the worm 7, the worm 7 and the power input structure 6 are fixedly connected, the turbine 8 is meshed with the worm 7, and the turbine 8 is fixedly connected with the output shaft 14.

In a preferred embodiment, a through hole is formed in the middle of the turbine 8, the output shaft 14 is disposed in the through hole, and the output shaft 14 and the turbine 8 are fixedly connected through the flat key 10.

In a preferred embodiment, output shaft connection blocks 15 are connected to both ends of output shaft 14, respectively.

It should be noted that, two ends of the output shaft 14 are connected to two output shaft connecting blocks 15, and when the rotation direction of the output shaft 14 is determined, reversing the two output shaft connecting blocks 15 can realize the rotation in opposite directions, that is, can simultaneously realize the functions of locking the nut 5 and loosening the nut 5.

The foregoing is merely a preferred embodiment of the present utility model, and is not intended to limit the embodiments and the protection scope of the present utility model.

The present utility model has the following embodiments based on the above description:

in a further embodiment of the utility model, two annular clamping springs 11 are arranged on the output shaft 14, the clamping springs 11 are sleeved on the output shaft 14, the turbine 8 is arranged between the two clamping springs 11, and the two clamping springs 11 limit the position of the turbine 8.

In a further embodiment of the present utility model, further comprising: the shell body, at least one part of the transmission structure and the power output structure are all arranged in the shell body.

In a further embodiment of the utility model, the outer housing comprises: the upper cover plate 12 and the lower cover plate 13 are oppositely arranged, the upper cover plate 12 and the lower cover plate 13 are respectively provided with a first bearing 9, and the worm 7 is arranged in the first bearings 9.

As shown in fig. 1, two first bearings 9 are respectively embedded in the upper cover plate 12 and the lower cover plate 13, and the first bearings 9 are installed at two ends of the worm 7 to play a role in positioning and realize the rotation function of the worm 7.

In a further embodiment of the utility model, the outer housing comprises: the left cover plate 17 and the right cover plate 18 are oppositely arranged, the second bearings 16 are arranged on the left cover plate 17 and the right cover plate 18, and the output shaft 14 is arranged in the second bearings 16.

As shown in fig. 2, the two second bearings 16 are respectively embedded in the left cover plate 17 and the right cover plate 18, and the second bearings 16 are mounted at two ends of the output shaft 14 to play a role in positioning and realize the rotation function of the output shaft 14.

In a further embodiment of the utility model the interior of the outer housing is connected by means of bolts 19.

In a further embodiment of the utility model, the power input structure 6 and the power output structure have an included angle.

It should be noted that, the included angle between the power input structure 6 and the power output structure can be adapted to the situation that the power input structure 6 and the power output structure are narrow in a single direction and inconvenient to apply force, for example, the space along the axis direction of the output shaft 14 is limited and inconvenient to apply force, and the included angle between the power input structure 6 and the power output structure can be operated in a direction other than the axis direction of the output shaft 14, and only the sleeve needs to be installed and matched with the nut 5 in the axis direction of the output shaft 14.

In a preferred embodiment, the device solves the problem that the nut 5 of the radio frequency patch cord 1 cannot be quickly locked during mass production, improves the assembly efficiency, and has the advantages of low cost, compact structure, high practicability and the like.

In a preferred embodiment, as shown in fig. 1, one end of the power input structure 6 protrudes to form a first bump, one end of the worm 7 is provided with a first groove, a part of the power input structure 6 is installed in the first groove, the first bump is also installed in the groove, and the power input structure 6 and the worm 7 are fixed in an interference fit at the first bump and the first groove.

In a preferred embodiment, as shown in fig. 2, one end of the output shaft connecting block 15 protrudes to form a second bump, a second groove is formed on the inner ring of the output shaft 14, the second bump is installed in the second groove, and the output shaft connecting block 15 and the output shaft 14 are fixed in an interference fit manner at the second bump and the second groove.

In a preferred embodiment, the output connection block, the output shaft 14, the input connection block, the worm 7, the turbine 8, the upper cover plate 12, the lower cover plate 13, the left cover plate 17 and the right cover plate 18 are customized according to requirements, and all materials are alloy steel pieces;

in a preferred embodiment, the bolt 19, the first bearing 9, the second bearing 16, the flat key 10 and the clamp spring 11 are all normalized parts, and the flat key 10 and the clamp spring 11 are made of alloy steel parts

In a preferred embodiment, the outer surface of the output shaft 14 is further provided with an annular groove for fixing the snap spring 11, and the inner ring of the annular snap spring 11 is arranged in the annular groove.

The foregoing is merely illustrative of the preferred embodiments of the present utility model and is not intended to limit the embodiments and scope of the present utility model, and it should be appreciated by those skilled in the art that equivalent substitutions and obvious variations may be made using the description and illustrations of the present utility model, and are intended to be included in the scope of the present utility model.

Claims (10)

1. Frock structure of quick installation of radio frequency patch cord, its characterized in that includes:

one end of the power input structure is connected with the power source;

the transmission structure is connected with the other end of the power input structure;

the power output structure is connected with the transmission structure;

wherein, the power take off structure includes: the hollow output shaft and the output shaft connecting block arranged on the output shaft are also of a hollow structure, the output shaft is connected with the transmission structure, the output shaft connecting block is detachably assembled with one end of a sleeve, and the other end of the sleeve is matched with a nut; the wire body part of the radio frequency patch cord passes through the output shaft connecting block and the inside of the output shaft.

2. The tooling structure for rapid installation of a radio frequency patch cord according to claim 1, wherein the transmission structure comprises: the turbine is fixedly connected with the power input structure, the turbine is meshed with the worm, and the turbine is fixedly connected with the output shaft.

3. The tooling structure for quickly installing the radio frequency patch cord according to claim 2, wherein a through hole is formed in the middle of the turbine, the output shaft is arranged in the through hole, and the output shaft is fixedly connected with the turbine through a flat key.

4. A tooling structure for rapid installation of a radio frequency patch cord according to claim 3, wherein two ends of the output shaft are respectively connected with the output shaft connecting blocks.

5. A tooling structure for rapid installation of a radio frequency patch cord according to claim 3, wherein two annular clamping springs are arranged on the output shaft, the clamping springs are sleeved on the output shaft, the turbine is arranged between the two clamping springs, and the two clamping springs define the position of the turbine.

6. A tooling structure for rapid installation of a radio frequency patch cord as in claim 3, further comprising: and the transmission structure and at least one part of the power output structure are arranged in the outer shell.

7. The tooling structure for rapid installation of a radio frequency patch cord of claim 6, wherein the outer housing comprises: the upper cover plate and the lower cover plate are oppositely arranged, the upper cover plate and the lower cover plate are respectively provided with a first bearing, and the worm is installed in the first bearings.

8. The tooling structure for rapid installation of a radio frequency patch cord of claim 6, wherein the outer housing comprises: the left cover plate and the right cover plate are oppositely arranged, second bearings are arranged on the left cover plate and the right cover plate, and the output shaft is installed in the second bearings.

9. The tooling structure for rapid installation of a radio frequency patch cord of claim 6, wherein the interior of the outer housing is bolted.

10. The tooling structure for rapid installation of a radio frequency patch cord of claim 1, wherein the power input structure and the power output structure have an included angle.