Optical fiber waveguide type fluorescent condenser for wireless optical communication
Technical Field
The utility model relates to a fluorescence spotlight ware technical field specifically is a fiber waveguide type fluorescence spotlight ware for wireless optical communication.
Background
The optical fiber waveguide type fluorescent condenser for wireless optical communication is one of fluorescent condensers, and the fluorescent condenser is a device for converting sunlight into fluorescence and condensing light so as to be convenient to use, but some existing fluorescent condensers in the market are damaged due to the fact that the fluorescent condensers are lack of an anti-vibration mechanism if the fluorescent condensers fall in the moving process.
SUMMERY OF THE UTILITY MODEL
Technical problem to be solved
The utility model provides a not enough to prior art, the utility model provides an optic fibre waveguide type fluorescence spotlight ware for wireless optical communication has solved the problem that the existing some fluorescence spotlight ware lacks the antidetonation mechanism in the market.
(II) technical scheme
In order to achieve the above purpose, the utility model discloses a following technical scheme realizes: an optical fiber waveguide type fluorescence condenser for wireless optical communication comprises a fluorescence condenser body, wherein an adapter plate is fixedly connected to the bottom of the fluorescence condenser body, a main spring is welded on one side of the top of the adapter plate, a adapter block is welded at one end of the main spring, an adapter column is welded on one side of the bottom of the adapter block, one end of the adapter column penetrates through an opening formed in one side of the top of the adapter plate and extends to the other side of the adapter plate, a secondary spring is welded at one end of the adapter column, a support plate is welded at one end of the secondary spring, a adapter shaft is movably sleeved in a movable opening formed in one side of the adapter column, main slide rails are welded on the left side and the right side of one end of the top of the support plate, a main sliding block and a secondary sliding block are respectively sleeved on the left side and the right side in the main slide rails, the top of the main sliding block is hinged with an auxiliary, the one end of assisting the arm is articulated through the adapter shaft with the one end of digging arm, and the welding of top one side of backup pad has the support arm, the slide rail is assisted to fixedly connected with in the cavity that support arm top one side set up, and assists the activity in the slide rail and cup jointed the sliding plate, support spring fixed connection is passed through with the bottom of support arm inner wall in the bottom of sliding plate, and the top fixedly connected with support column of sliding plate, the one end welding of support column is in bottom one side of adapter plate.
Further preferably, the number of the transfer blocks is four, and the four transfer blocks are arranged at the bottom of the transfer plate in a rectangular array.
Further preferably, the number of the support columns is four, and the four support columns are arranged at the bottom of the adapter plate in a rectangular array.
Further preferably, the bottom of the supporting plate is provided with a rubber cushion pad, and the surface of the rubber cushion pad is provided with frosted lines.
Further preferably, the main slider and the sub slider are equal in size, and the front surfaces of the main slider and the sub slider are both U-shaped in cross section.
Preferably, the auxiliary arm is made of metal, and the front section of the auxiliary arm is Y-shaped.
(III) advantageous effects
The utility model provides a fiber waveguide type fluorescence spotlight ware for wireless optical communication possesses following beneficial effect:
(1) when the fluorescent condenser body falls to the ground, the support plate is contacted with the ground, at the moment, the impact on the fluorescent condenser body is transmitted downwards through the adapter plate and moves downwards through the adapter plate, when the adapter plate moves downwards, the support column moves in the same direction in the auxiliary slide rail through the sliding plate and applies pressure to the support spring to enable the support spring to absorb the impact in a compression state and transmit the impact to the support plate, the main spring is pulled to be in a stretching state in the moving process of the adapter plate and transmits the received impact to the adapter plate through the main spring to enable the adapter plate to move in the same direction, the adapter plate moves in the same direction to apply pressure to the secondary spring to enable the secondary spring to be in a stretching state and transmit the received impact to the support plate through the spring, and as the adapter plate pulls away from the support plate in the moving process, the auxiliary arm and the movable arm rotate by taking the adapter shaft as the axis, and the auxiliary arm and the movable arm move towards the opposite side in the main sliding rail through the main sliding block and the secondary sliding block respectively in the rotating process, the supporting plate transmits the impact to the ground after being impacted, the impact is transmitted to the ground, so that the main spring, the secondary spring and the supporting spring lose pressure to rebound and drive other structures to reset, and most of the impact received by the fluorescent condenser main body is transmitted and absorbed by other structures to ensure that the fluorescent condenser main body cannot be easily damaged and prolong the service life of the fluorescent condenser main body.
(2) The auxiliary arm is made of metal materials, so that the auxiliary arm has enough service life, and the front section of the auxiliary arm is Y-shaped, so that enough activity space is provided for the movable arm in the rotating process, and the service life aggravation loss of the auxiliary arm and the movable arm caused by interference is avoided.
Drawings
Fig. 1 is a front view of the structure of the present invention;
FIG. 2 is an enlarged view of the structure A of FIG. 1 according to the present invention;
FIG. 3 is an enlarged view of the structure B of FIG. 1 according to the present invention;
fig. 4 is a sectional view of the front structure of the support arm of the present invention;
fig. 5 is a top view of the support plate structure of the present invention;
fig. 6 is an enlarged view of the structure at C in fig. 1 according to the present invention.
In the figure: the fluorescent condenser comprises a fluorescent condenser main body 1, an adapter plate 2, a main spring 3, a transfer block 4, a transfer column 5, a secondary spring 6, a support plate 7, a transfer shaft 8, a main slide rail 9, a main slide block 10, a secondary slide block 11, an auxiliary arm 12, a movable arm 13, a support arm 14, an auxiliary slide rail 15, a sliding plate 16, a support spring 17 and a support column 18.
Detailed Description
The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.
Referring to fig. 1-6, the present invention provides a technical solution: an optical fiber waveguide type fluorescence condenser for wireless optical communication comprises a fluorescence condenser main body 1, wherein an adapter plate 2 is fixedly connected to the bottom of the fluorescence condenser main body 1, a main spring 3 is welded on one side of the top of the adapter plate 2, a adapter block 4 is welded on one end of the main spring 3, an adapter column 5 is welded on one side of the bottom of the adapter block 4, one end of the adapter column 5 penetrates through an opening formed in one side of the top of the adapter plate 2 and extends to the other side of the adapter plate, a secondary spring 6 is welded on one end of the adapter column 5, a supporting plate 7 is welded on one end of the secondary spring 6, a rubber buffer cushion is arranged on the bottom of the supporting plate 7, and frosted lines are arranged on the surface of the rubber buffer cushion 7, so that the supporting plate 7 is enabled to have enough supporting force and the frosted lines improve the friction force when the supporting plate 7 is in contact with the ground to prevent equipment from being placed on the ground to cause skidding, a transfer shaft 8 is movably sleeved in a movable opening arranged at one side of the transfer column 5, main slide rails 9 are welded at the left side and the right side of one end of the top of the support plate 7, a main slider 10 and a secondary slider 11 are respectively sleeved at the left side and the right side in the main slide rails 9, the main slider 10 and the secondary slider 11 are equal in size, the front sections of the main slider 10 and the secondary slider 11 are U-shaped, the arrangement ensures that the main slider 10 and the secondary slider 11 have the same moving distance, enough space is reserved for the connection with an auxiliary arm 12 and a movable arm 13 respectively, the top of the main slider 10 is hinged with an auxiliary arm 12 through the auxiliary shaft, the auxiliary arm 12 is made of metal, the front section of the auxiliary arm 12 is Y-shaped, the arrangement ensures that the auxiliary arm has enough service life, and the front section of the auxiliary arm 12 is Y-shaped, so that the auxiliary arm provides enough moving space for the movable arm 13 in the rotating process, the service life aggravation loss of the two sides caused by interference between the secondary sliding block and the movable arm 13 is guaranteed, the top of the secondary sliding block 11 is hinged to the movable arm 13 through the movable shaft, one end of the auxiliary arm 12 is hinged to one end of the movable arm 13 through the adapter shaft, the supporting arm 14 is welded to one side of the top of the supporting plate 7, the auxiliary sliding rail 15 is fixedly connected to the cavity formed in one side of the top of the supporting arm 14, the sliding plate 16 is movably sleeved in the auxiliary sliding rail 15, the bottom of the sliding plate 16 is fixedly connected to the bottom of the inner wall of the supporting arm 14 through the supporting spring 17, the supporting columns 18 are fixedly connected to the top of the sliding plate 16, one ends of the supporting columns 18 are welded to one side of the bottom of the adapter plate 2, the number of the supporting columns 18 is four, the four supporting columns 18 are arranged at the bottom of the adapter plate 2 in a, and four impacts are uniformly absorbed by the four supporting columns 18, so that the service life of each supporting column 18 is prolonged.
The working principle is as follows: when the optical fiber waveguide type fluorescent condenser for wireless optical communication is used, the support plate 7 is in contact with the ground when the fluorescent condenser body 1 falls to the ground through the fluorescent condenser body 1, at the moment, the impact received by the fluorescent condenser body 1 is transmitted downwards through the adapter plate 2 and moves downwards through the adapter plate 2, when the adapter plate 2 moves downwards, the support column 18 moves in the same direction in the auxiliary slide rail 15 through the sliding plate 16 and applies pressure to the support spring 17 to enable the support spring 17 to absorb the impact and be in a compressed state and transmit the impact to the support plate 7, when the adapter plate 2 moves, the main spring 3 is pulled to be in a stretched state and the received impact is transmitted to the adapter plate 4 through the main spring 3 to enable the adapter plate to move in the same direction, when the adapter plate 4 moves in the same direction, the adapter column 5 applies pressure to the secondary spring 6 to change the secondary spring into a stretched state and transmit the received impact to the support plate 7 through the spring 6, because the switching column 5 is pulled far away from the support plate 7 in the moving process, the auxiliary arm 12 and the movable arm 13 rotate in the axial direction by taking the switching shaft 8 as an axis, and the auxiliary arm 12 and the movable arm 13 move towards the opposite side in the main slide rail 9 through the main slide block 10 and the secondary slide block 11 respectively in the rotating process, the support plate 7 is transmitted to the ground after being impacted, so that the ground impacts, at the moment, the main spring 3, the secondary spring 6 and the support spring 17 lose pressure to rebound and drive other structures to reset because the impact is transmitted to the ground, most of the impact on the fluorescent condenser main body 1 is transmitted and absorbed by other structures, so that the fluorescent condenser main body 1 cannot be easily damaged, and the service life of the fluorescent condenser main body is prolonged.
Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that various changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention.