CN112285863A - Automatic bonding equipment for eyepiece objective of monocular - Google Patents

Abstract

The invention discloses automatic bonding equipment for an eyepiece objective of a monocular telescope, which comprises a casing, wherein a driving cavity is arranged above the casing, a driving mechanism is arranged in the driving cavity, a mounting cavity with a forward opening is arranged in the middle of the casing, an embedding pushing cavity communicated with the mounting cavity is arranged above the mounting cavity, and an embedding mechanism is arranged in the embedding pushing cavity.

Description

Automatic bonding equipment for eyepiece objective of monocular

Technical Field

The invention relates to the field of optical instruments, in particular to automatic adhering equipment for an eyepiece objective of a monocular telescope.

Background

The telescope is widely used at present, from toys to military, and has great application at all levels, because the telescope is very helpful for people to overlook due to the long sight function, thereby being an important military article.

However, the process of transferring the binoculars or monocular telescopes is manually performed by workers, which is troublesome, in that the objective lens and the eyepiece are installed, precise calibration is not required, and adjustment of the lens is not required, but the binoculars or monocular telescopes are manually pasted by workers, and the process is troublesome.

Disclosure of Invention

The invention aims to solve the technical problem of providing automatic adhering equipment for an eyepiece objective of a monocular telescope, which overcomes the problems.

The invention is realized by the following technical scheme.

The invention relates to automatic bonding equipment for an eyepiece objective of a monocular telescope, which comprises a casing, wherein a driving cavity is arranged above the casing, a driving mechanism is arranged in the driving cavity, a mounting cavity with a forward opening is arranged in the middle of the casing, an embedding pushing cavity communicated with the mounting cavity is arranged above the mounting cavity, an embedding mechanism is arranged in the embedding pushing cavity, the embedding mechanism comprises an embedding power cavity which is arranged above the embedding pushing cavity and communicated with the embedding pushing cavity, an embedding power push block with the lower end extending into the embedding pushing cavity is arranged in the embedding power cavity, an embedding power spring is fixedly connected to the upper end surface of the embedding power push block, the other end of the embedding power spring is fixed on the upper cavity wall of the embedding power cavity, an embedding power pull rope is also fixedly connected to the upper end surface of the embedding power push block, and an embedding power stop cavity communicated with the embedding power pull rope is arranged in the, the embedded power stop cavity is internally provided with an embedded power stop block with the right end extending out of the cavity, the left end face of the embedded power stop block is fixedly connected with an embedded power stop spring, the other end of the embedded power stop spring is fixed on the left cavity wall of the embedded power stop cavity, the left end face of the embedded power stop block is also fixedly provided with an embedded power control pull rope, the embedded push cavity is internally provided with an embedded reset block with the lower part extending into the installation cavity, the embedded push cavity is internally and slidably connected with a grabbing block with the middle part arranged on the embedded reset block, the left end face of the grabbing block is fixedly connected with a grabbing block spring, the other end of the grabbing block spring is fixed in the embedded push cavity, the right end face of the grabbing block is fixedly connected with an embedded pull rope, the left cavity wall and the right cavity below the embedded push cavity are both provided with embedded power control cavities communicated with the embedded power control block, and, the embedded power control cavity is characterized in that an embedded power control spring is fixedly connected to the right end face of the embedded power control block, the other end of the embedded power control spring is fixed to the right end face of the embedded power control cavity, and the embedded power control pull rope is fixed to the left end face of the embedded power control cavity.

Furthermore, the upper end of the embedded reset block is fixedly connected with an embedded reset spring, the other end of the embedded reset spring is fixed on the upper end surface of the grabbing block, the lower end surfaces of the left side and the right side of the embedded reset block are respectively provided with an air suction channel, a sucking disc is arranged below the air suction channel, the lower side of the left side of the embedded reset block is also rotatably connected with an eyepiece nut sleeve, the left wall of the installation cavity is internally provided with an objective cavity communicated with the outside, the left wall of the installation cavity is also internally provided with an eyepiece cavity communicated with the outside, the lower wall of the installation cavity is internally provided with a gluing control cavity with an upward opening, the gluing control cavity is internally provided with a gluing control block with an upper end extending cavity, the gluing lower end surface of the control block is fixedly connected with a gluing control spring, the other end of the gluing control spring, the gluing control cavity is internally provided with a gluing rack cavity with an upward opening, a gluing rack with an upper end extending out of the cavity is arranged in the gluing control cavity, and a gluing hole is formed in the upper end of the gluing rack.

Further, a third step block moving cavity communicated with the gluing rack cavity is arranged in the left cavity wall of the gluing rack cavity, a third step block with the right end extending into the gluing rack cavity is arranged in the third step block moving cavity, a third step block moving block is also connected to the left cavity wall of the third step block moving cavity in a sliding manner, a third step block sliding block is also connected to the lower cavity wall of the third step block moving cavity in a sliding manner, a third step block spring is fixedly connected to the left end face of the third step block, the other end of the third step block spring is fixed to the right end face of the third step block moving block, a third step block pull rope is fixedly connected to the lower end face of the third step block, a third step block lifting spring is fixedly connected to the lower end face of the third step block, the other end of the third step block lifting spring is fixed to the upper end face of the third step block sliding block, and a gluing rack, the other end of the gluing rack spring is fixed on the right end surface of the three-step block, the left end surface of the gluing rack is also fixedly connected with a pull rope of the three-step block, a gluing rack transmission cavity communicated with the gluing rack cavity is arranged in front of the gluing rack cavity, a gluing rack gear shaft with the rear end extending into the gluing rack cavity is arranged in the gluing rack transmission cavity, the rear end of the gluing rack gear shaft is fixed with a gluing rack gear which is meshed with the lower end face of the gluing rack, a gluing rack transmission gear is fixed at the front end of the gluing rack gear shaft, a gluing rack power cavity with a right opening is arranged in front of the right side of the gluing rack transmission cavity, a ratchet shaft with the rear end extending into the gluing rack power cavity is arranged in the gluing rack transmission cavity, the front end of the ratchet shaft is fixedly connected with a gluing rack power gear meshed with the gluing rack transmission gear.

Furthermore, a ratchet wheel is fixed at the rear end of the ratchet wheel shaft, a ratchet wheel power friction wheel which is meshed with the ratchet wheel and rubs with the wall of the gluing control cavity is arranged in the gluing rack power cavity, a switching cavity communicated with the ratchet wheel is arranged in the rear cavity wall of the mounting cavity, a switching clamping shaft with the front end extending into the mounting cavity is arranged in the switching cavity, a clamping pin is fixedly connected at the front end of the switching clamping shaft, a clamping block is rotatably connected to the clamping pin, a clamping torsion spring is fixedly connected in the clamping pin, the other end of the clamping torsion spring is fixed on the clamping block, a switching turbine is fixedly connected at the rear end of the switching clamping shaft, a gluing rope pulley sleeve is rotatably connected at the rear end face of the gluing rope pulley, a gluing control rope is fixedly connected to the gluing rope pulley sleeve, and the driving mechanism comprises a, the utility model discloses a rotary coating machine, including drive chamber, control chamber, drive chamber the place ahead be equipped with the intercommunication with it the conversion chamber, be equipped with the motor in the intracavity of drive chamber, terminal surface power is connected with the lower extreme and passes under the motor the control chamber is established the main shaft in the rubber coating drive intracavity, the main shaft upper end is fixed with nut drive gear, main shaft upper end still fixedly connected with conversion drive bevel gear, the main shaft lower extreme is fixed with control drive gear, the main shaft lower extreme still is fixed with rubber coating drive bevel gear, the drive chamber front end is equipped with the nut power shaft, on the nut power shaft fixedly connected with nut drive gear meshing and with eyepiece nut.

Furthermore, a conversion driving worm shaft with the front end extending into the conversion cavity and engaged with the conversion turbine is also arranged in the driving cavity, a conversion sliding bevel gear engaged with the conversion driving bevel gear is connected to the rear end of the conversion driving worm shaft through a spline, a conversion sliding bevel gear groove with a forward opening is arranged in the front end face of the conversion sliding bevel gear, a conversion sliding bevel gear block is arranged in the conversion sliding bevel gear groove, a conversion sliding bevel gear spring is fixedly connected to the front end face of the conversion sliding bevel gear block, the other end of the conversion sliding bevel gear spring is fixed on the front cavity wall of the driving cavity, a conversion sliding bevel gear electromagnet is fixed on the front end face of the driving cavity, a control shaft groove communicated with the control shaft is arranged in the upper cavity wall behind the control cavity, and a control shaft with the lower part extending into the control cavity is arranged in the control shaft, the upper end of the control shaft is rotatably connected with a control shaft rotating block, the upper end face of the control shaft rotating block is fixedly connected with a control shaft spring, the other end of the control shaft spring is fixed on the upper end face of the control shaft groove, the upper end face of the control shaft groove is also fixedly connected with a control shaft electromagnet, the upper end of the control shaft is fixedly provided with a control shaft stopping wheel, and the upper section of the control shaft is fixedly provided with a control shaft rotating gear meshed with the control driving gear.

Further, the lower end of the control shaft is fixedly connected with a control shaft rope rolling wheel, the control shaft rope rolling wheel is fixedly provided with the embedded pull rope, the lower end of the control shaft is fixedly provided with a control shaft rope pulling wheel, the lower end face of the control shaft rope pulling wheel is rotatably connected with a control shaft rope pulling sleeve, the control shaft rope pulling sleeve is fixedly connected with the embedded power pull rope, a gluing rotating worm meshed with the gluing control worm is arranged at the rear end of the gluing driving cavity, and a gluing rotating bevel gear meshed with the gluing driving bevel gear is fixedly connected to the left end of the gluing rotating worm.

The invention has the beneficial effects that: the device simple structure, the simple operation, when needs work, can put into the lens cone of monocular, the device can give its automatic rubber coating, then with its reversal, inlay the eyepiece again on the lens cone, the lens cone of eyepiece also coats glues simultaneously, after inverting it again, inlay the back with the eyepiece and screw up the nut on it again, the device makes the automation that the assembly of monocular becomes, make the integrative simplification that complicated procedure becomes, convenient and fast effectual beneficial effect has been reached.

Drawings

In order to more clearly illustrate the embodiments of the invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the invention, and it is obvious for those skilled in the art that other drawings can be obtained based on these drawings without creative efforts.

FIG. 1 is a schematic front view of an embodiment of the present invention;

FIG. 2 is an enlarged schematic view of the structure A-A in FIG. 1 according to an embodiment of the present invention;

FIG. 3 is an enlarged schematic view of the structure B-B in FIG. 2 according to an embodiment of the present invention;

FIG. 4 is an enlarged schematic view of the structure of the glue spreading mechanism in the embodiment of the invention;

FIG. 5 is an enlarged view of the structure C-C shown in FIG. 4 according to an embodiment of the present invention.

Detailed Description

The invention will now be described in detail with reference to fig. 1-5, wherein for ease of description the orientations described hereinafter are now defined as follows: the up, down, left, right, and front-back directions described below correspond to the up, down, left, right, and front-back directions in the projection relationship of fig. 1 itself.

Combine the automatic dress equipment that glues of eyepiece objective of monocular telescope of 1-5 of attached drawing, including casing 10, casing 10 top is equipped with drive chamber 52, be equipped with actuating mechanism 95 in the drive chamber 52, casing 10 middle part is equipped with forward open-ended installation cavity 28, installation cavity 28 top is equipped with the promotion chamber 29 of inlaying of intercommunication with it, it is equipped with inlaying mechanism 96 in the promotion chamber 29 to inlay, inlay mechanism 96 including establishing inlay the promotion chamber 29 top and with it inlay power chamber 30 of intercommunication, it stretches into to inlay the lower extreme in the power chamber 30 inlay power ejector pad 33 that promotes the chamber 29, inlay power ejector pad 33 up end fixedly connected with and inlay power spring 31, it fixes to inlay the power spring 31 other end on inlaying power chamber 30 upper chamber wall, it still fixedly connected with inlays power stay cord 32 to inlay power ejector pad 33 up end, the power locking cavity 30 is provided with an embedded power locking cavity 35 communicated with the embedded power locking cavity in the left cavity wall, the embedded power locking block 34 with the right end extending out of the cavity is arranged in the embedded power locking cavity 35, the left end face of the embedded power locking block 34 is fixedly connected with an embedded power locking spring 36, the other end of the embedded power locking spring 36 is fixed on the left cavity wall of the embedded power locking cavity 35, the left end face of the embedded power locking block 34 is further fixed with an embedded power control pull rope 27, the embedded reset block 12 with the lower part extending into the installation cavity 28 is arranged in the embedded push cavity 29, the embedded push cavity 29 is further connected with a grabbing block 98 with the middle part arranged on the embedded reset block 12 in a sliding manner, the grabbing block spring 20 is fixedly connected on the left end face of the grabbing block 98, the other end of the grabbing block spring 20 is fixed on the embedded push cavity 29, the right end face of the grabbing block, inlay and all be equipped with the power control chamber 26 of inlaying with it intercommunication in the chamber wall about promoting chamber 29 below, it stretches out the power control block 25 of inlaying of chamber to be equipped with the left end in the power control chamber 26 of inlaying, fixedly connected with inlays power control spring 24 on the power control block 25 right-hand member face of inlaying, inlay the power control spring 24 other end and fix on the power control chamber 26 right-hand member face of inlaying, be fixed with on the power control chamber 26 left end face of inlaying inlay power control stay cord 27.

Beneficially, the upper end of the inlaid reset block 12 is fixedly connected with an inlaid reset spring 11, the other end of the inlaid reset spring 11 is fixed on the upper end face of the grabbing block 98, the left and right lower end faces of the inlaid reset block 12 are respectively provided with an air suction channel 23, a suction cup 22 is arranged below the air suction channel 23, the left lower side of the inlaid reset block 12 is also rotatably connected with an eyepiece nut sleeve 13, the left cavity wall of the installation cavity 28 is internally provided with an objective cavity 21 communicated with the outside, the left cavity wall of the installation cavity 28 is also internally provided with an eyepiece cavity 14 communicated with the outside, the lower cavity wall of the installation cavity 28 is internally provided with a gluing control cavity 17 with an upward opening, the gluing control cavity 17 is internally provided with a gluing control block 18 with an upper end extending out of the cavity, the lower end face of the gluing control block 18 is fixedly connected with a gluing control spring 15, the lower end face of the gluing control block 18 is also fixedly connected with a gluing control pull rope 16, a gluing control turbine 19 connected with the gluing control block 18 through a spline is further arranged above the gluing control cavity 17, a gluing rack cavity 83 with an upward opening is formed in the gluing control block 18, a gluing rack 85 with an upper end extending out of the cavity is arranged in the gluing rack cavity 83, and a gluing hole 84 is formed in the upper end of the gluing rack 85.

Advantageously, a third step moving cavity 79 communicated with the left cavity wall of the gluing rack cavity 83 is arranged in the left cavity wall of the gluing rack cavity 83, a third step 80 with the right end extending into the gluing rack cavity 83 is arranged in the third step moving cavity 79, a third step moving block 76 is also connected with the left cavity wall of the third step moving cavity 79 in a sliding manner, a third step sliding block 77 is also connected with the lower cavity wall of the third step moving cavity 79 in a sliding manner, a third step spring 73 is fixedly connected with the left end surface of the third step 80, the other end of the third step spring 73 is fixed on the right end surface of the third step moving block 76, a third step pull rope 74 is fixedly connected with the lower end surface of the third step 80, a third step lifting spring 75 is fixedly connected with the lower end surface of the third step 80, the other end of the third step lifting spring 75 is fixed on the upper end surface of the third step 77, a gluing rack spring 81 is fixedly connected with the left end surface of the gluing rack, the other end of the gluing rack spring 81 is fixed on the right end face of the three-step block 80, the left end face of the gluing rack 85 is fixedly connected with the pull rope 74 of the three-step block, the front of the gluing rack cavity 83 is also provided with a gluing rack transmission cavity 90 communicated with the gluing rack cavity, a gluing rack gear shaft 78 with the rear end extending into the gluing rack cavity 83 is arranged in the gluing rack transmission cavity 90, the rear end of the gluing rack gear shaft 78 is fixed with a gluing rack gear 89, the gluing rack gear 89 is meshed with the lower end face of the gluing rack 85, the front end of the gluing rack gear shaft 78 is fixed with a rack gluing transmission gear 91, the front of the right side of the gluing rack transmission cavity 90 is provided with a gluing rack power cavity 94 with an opening to the right, the rear end of the ratchet shaft 88 extending into the gluing rack power cavity 94 is arranged in the gluing rack transmission cavity 90, and the front end of the ratchet shaft 88 is fixedly connected with a gluing rack power gear 91 meshed 93.

Advantageously, a ratchet wheel 87 is fixed at the rear end of the ratchet shaft 88, a ratchet wheel power friction wheel 86 engaged with the ratchet wheel 87 and rubbing the cavity wall of the gluing control cavity 17 is arranged in the gluing rack power cavity 94, a switching cavity 41 communicated with the cavity wall is arranged in the rear cavity wall of the mounting cavity 28, a switching clamping shaft 45 with the front end extending into the mounting cavity 28 is arranged in the switching cavity 41, a clamping pin 47 is fixedly connected at the front end of the switching clamping shaft 45, a clamping block 48 is rotatably connected to the clamping pin 47, a clamping torsion spring 43 is fixedly connected in the clamping pin 47, the other end of the clamping torsion spring 43 is fixed on the clamping block 48, a switching turbine 46 is fixedly connected at the rear end of the switching clamping shaft 45, a gluing rope pulling wheel 44 is fixedly connected at the rear end of the switching clamping shaft 45, a gluing rope pulling sleeve 42 is rotatably connected at the rear end of the gluing rope pulling wheel 44, and the gluing control rope 16 is, the drive mechanism 95 includes a control chamber 61 disposed below and in communication with the drive chamber 52, the front of the driving cavity 52 is provided with the conversion cavity 41 communicated with the driving cavity, the lower part of the control cavity 61 is provided with a gluing driving cavity 67 communicated with the control cavity, the upper cavity wall of the driving cavity 52 is internally provided with a motor 49, the lower end surface of the motor 49 is in power connection with a main shaft 50, the lower end of the main shaft penetrates through the control cavity 61 and is arranged in the gluing driving cavity 67, a nut driving gear 51 is fixed at the upper end of the main shaft 50, a conversion driving bevel gear 38 is also fixedly connected at the upper end of the main shaft 50, a control driving gear 68 is fixed at the lower end of the main shaft 50, a gluing driving bevel gear 66 is also fixed at the lower end of the main shaft 50, the front end of the driving cavity 52 is provided with a nut power shaft 37, and a nut driven gear 39 which is meshed with the nut driving gear 51 and the eyepiece nut sleeve 13 is fixedly connected to the nut power shaft 37.

Advantageously, a conversion driving worm shaft 40 with a front end extending into the conversion cavity 41 and engaged with the conversion turbine 46 is further arranged in the driving cavity 52, a conversion sliding bevel gear 97 engaged with the conversion driving bevel gear 38 is splined to the rear end of the conversion driving worm shaft 40, a conversion sliding bevel gear groove 71 with a forward opening is arranged in the front end face of the conversion sliding bevel gear 97, a conversion sliding bevel gear block 69 is arranged in the conversion sliding bevel gear groove 71, a conversion sliding bevel gear spring 70 is fixedly connected to the front end face of the conversion sliding bevel gear block 69, the other end of the conversion sliding bevel gear spring 70 is fixed to the front cavity wall of the driving cavity 52, a conversion sliding bevel gear electromagnet 72 is fixed to the front end face of the driving cavity 52, a control shaft groove 53 communicated with the control shaft is arranged in the upper cavity wall at the rear of the control cavity 61, a control shaft 99 extending into the control cavity 61 at the lower part is arranged in the control shaft groove 53, the upper end of the control shaft 99 is rotatably connected with a control shaft rotating block 55, the upper end surface of the control shaft rotating block 55 is fixedly connected with a control shaft spring 54, the other end of the control shaft spring 54 is fixed on the upper end surface of the control shaft groove 53, the upper end surface of the control shaft groove 53 is also fixedly connected with a control shaft electromagnet 56, the upper end of the control shaft 99 is fixedly provided with a control shaft stopping wheel 57, and the upper section of the control shaft 99 is fixedly provided with a control shaft rotating gear 58 meshed with the control driving gear 68.

Beneficially, the lower end of the control shaft 99 is fixedly connected with a control shaft rope winding wheel 59, the embedding pull rope 63 is fixed on the control shaft rope winding wheel 59, the control shaft rope pulling wheel 62 is fixed on the lower end of the control shaft 99, the lower end face of the control shaft rope pulling wheel 62 is rotatably connected with a control shaft rope pulling sleeve 60, the embedding power pull rope 32 is fixedly connected on the control shaft rope pulling sleeve 60, a gluing rotating worm 64 with the rear end meshed with the gluing control turbine 19 is arranged in the gluing driving cavity 67, and the left end of the gluing rotating worm 64 is fixedly connected with a gluing rotating bevel gear 65 meshed with the gluing driving bevel gear 66.

Sequence of mechanical actions of the whole device:

1: in the initial state, the embedded power push block 33 is clamped by the embedded power stop block 34 and is positioned above the embedded power cavity 30, the control shaft electromagnet 56 works to attract the control shaft stop wheel 57 and clamp the control shaft 99 so that the control shaft 99 cannot rotate, the embedded pull rope 63 is in a semi-tensioning state at the moment, the conversion sliding bevel gear electromagnet 72 works to attract the conversion sliding bevel gear 97 so that the conversion sliding bevel gear 97 is disengaged from the conversion driving bevel gear 38, the gluing rack 85 is positioned on the left side of the gluing rack cavity 83, the gluing rack spring 81 is in an extending state, the third step block 80 is clamped in the second step, the lower end face of the gluing rack 85 is engaged with the gluing rack gear 89, the gluing control pull rope 16 is loosened, and the third step block pull rope 74 is tensioned.

2: when the telescope needs to work, the big end of the single-tube telescope is placed downwards into the mounting cavity 28, the clamping block 48 clamps the telescope, then the motor 49 is started, the motor 49 drives the main shaft 50 to rotate, so as to drive the nut driving gear 51, the conversion driving bevel gear 38, the control driving gear 68, the nut driven gear 39, the nut power shaft 37, the gluing driving bevel gear 66, the gluing rotating bevel gear 65, the gluing rotating worm 64 and the gluing control turbine 19 to rotate, so as to drive the gluing control block 18 to rotate for a circle, so that the gluing holes 84 of the gluing rack 85 apply glue to the large circle of the telescope during the rotation process, then the conversion sliding bevel gear electromagnet 72 stops working, so that the conversion sliding bevel gear 97 is meshed with the rotating conversion driving bevel gear 38 under the action of the conversion sliding bevel gear spring 70, so that the conversion driving bevel gear 38 drives the conversion sliding bevel gear 97, the conversion driving worm shaft, The conversion turbine 46 and the conversion clamping shaft 45 rotate to enable the conversion clamping shaft 45 to rotate one hundred eighty degrees, the gluing control pull rope 16 is loosened after being tensioned, the gluing control block 18 moves towards the lower part of the gluing control cavity 17 when the gluing control pull rope 16 is tensioned, the gluing control pull rope 16 is loosened again after the conversion clamping shaft 45 rotates one hundred eighty degrees, the gluing control block 18 moves upwards under the action of the gluing control spring 15, the ratchet power friction wheel 86 and the wall of the gluing control cavity 17 rub to drive the ratchet wheel 87, the ratchet shaft 88, the gluing rack power gear 93, the gluing transmission gear rack 91, the gluing rack gear shaft 78 and the gluing rack gear 89 to rotate, the gluing rack gear 89 drives the gluing rack 85 to move leftwards to the left side of the gluing rack cavity 83, the gluing control block 18 rotates again to glue a small circle, the control shaft electromagnet 56 stops working in the process to enable the control shaft rotating gear 58 to be meshed with the rotating control driving gear 68, so that the control shaft rotating gear 58 rotates to drive the control shaft 99, the control shaft stop gear 57, the control shaft rope pulling wheel 62 and the control shaft rope rolling wheel 59 to rotate to tighten the embedded pull rope 63, thereby the grabbing block 98 and the embedded reset block 12 are pulled to move rightwards, when the grabbing block 98 moves to the right end of the embedded pushing cavity 29, the embedded power control block 25 is pressed to press the embedded power control pull rope 27, so that the embedded reset block 12 is pressed downwards to make the suction cup 22 descend the suction channel 23 to suck in the objective lens cavity 21, then the motor 49 rotates reversely to make the embedded pull rope 63 loosened again, so that the embedded reset block 12 moves leftwards under the action of the grabbing block spring 20, in the process, the control shaft rope pulling wheel 62 tightens and loosens the embedded power pull rope 32 again, the embedded power push block 33 is pulled again to be clamped by the embedded power stop block 34, when the embedded reset block 12 moves to the left end of the embedded pushing cavity 29, the embedded power pull rope 32 is loosened again when the embedded power control block 25 is pulled, when the embedded power control block 25 is pressed into the embedded power control cavity 26, the embedded power stop block 34 releases the embedded power push block 33 again, so that the embedded reset block 12 is pressed downwards by 3 again, the embedded reset block 12 descends in the process to enable the ocular to be embedded in the suction channel 23 on the lens cone to deflate and separate, and at the moment, the embedded reset block 12 sucks up the ocular and an ocular fixing nut in the ocular cavity 14.

3: then the conversion sliding bevel gear electromagnet 72 works again to drive the conversion clamping shaft 45 to rotate reversely by one hundred eighty degrees, in the process, the gluing control pull rope 16 is tensioned and then loosened, so that the gluing control block 18 causes the ratchet power friction wheel 86 to rub with the front wall of the gluing control cavity 17 again in the ascending process, so that the gluing rack 85 continues to move towards the left end of the gluing rack cavity 83, the gluing rack spring 81 is compressed, the three-step block pull rope 74 is loosened, the three-step block 80 is pushed to move towards the left end of the three-step block moving cavity 79, the three-step block 80 moves upwards under the action of the three-step block lifting spring 75, the second step of the three-step block 80 is clamped, at the moment, the three-step block 80 lifts the gluing rack 85, the lower end of the gluing rack 85 is disengaged with the gluing rack gear 89, and moves towards the right cavity wall of the gluing rack 85 to reset under the action of the gluing rack spring 81, in the process, the third step pull rope 74 is tensioned to pull down the third step 80 again, the second step of the third step 80 is clamped and reset again under the action of the third step spring 73, the glue coating rack 85 is meshed with the glue coating rack gear 89 again at the moment, then the conversion sliding bevel gear electromagnet 72 attracts the conversion sliding bevel gear 97 again, the motor 49 rotates forwards again to tension the embedding pull rope 63, the embedding reset block 12 moves towards the right side again to press the embedding power control block 25, the embedding power push block 33 is loosened again to enable the embedding reset block 12 to embed the eyepiece on the lens barrel, at the moment, the eyepiece nut sleeve 13 is meshed with the rotating nut driven gear 39 to tighten the eyepiece fixing nut, and the single-barrel telescope is taken down after being installed to complete the work.

The above embodiments are merely illustrative of the technical ideas and features of the present invention, and the purpose thereof is to enable those skilled in the art to understand the contents of the present invention and implement the present invention, and not to limit the protection scope of the present invention. All equivalent changes and modifications made according to the spirit of the present invention should be covered within the protection scope of the present invention.

Claims (6)

1. The utility model provides an automatic equipment of gluing of eyepiece objective of monocular, includes the casing, its characterized in that: the power transmission mechanism is characterized in that a driving cavity is arranged above the casing, a driving mechanism is arranged in the driving cavity, an installation cavity with a forward opening is arranged in the middle of the casing, an embedding pushing cavity communicated with the installation cavity is arranged above the installation cavity, an embedding mechanism is arranged in the embedding pushing cavity, the embedding mechanism comprises an embedding power cavity arranged above the embedding pushing cavity and communicated with the embedding pushing cavity, an embedding power pushing block with the lower end extending into the embedding pushing cavity is arranged in the embedding power cavity, an embedding power spring is fixedly connected to the upper end face of the embedding power pushing block, the other end of the embedding power spring is fixed on the upper cavity wall of the embedding power cavity, an embedding power pull rope is also fixedly connected to the upper end face of the embedding power pushing block, an embedding power locking cavity communicated with the embedding power locking block is arranged in the left cavity wall of the embedding power cavity, and an embedding power, the left end face of the embedded power stop block is fixedly connected with an embedded power stop spring, the other end of the embedded power stop spring is fixed on the left cavity wall of the embedded power stop cavity, the left end face of the embedded power stop block is also fixed with an embedded power control pull rope, the embedded push cavity is internally provided with an embedded reset block, the lower part of the embedded reset block extends into the installation cavity, the embedded push cavity is internally further connected with a grabbing block, the middle part of the grabbing block is arranged on the embedded reset block, the left end face of the grabbing block is fixedly connected with a grabbing block spring, the other end of the grabbing block spring is fixed in the embedded push cavity, the right end face of the grabbing block is fixedly connected with an embedded pull rope, the left and right cavity walls below the embedded push cavity are both provided with embedded power control cavities communicated with the embedded power control block, the embedded power control cavity is internally provided with an embedded power control block, the left end, the other end of the embedded power control spring is fixed on the right end face of the embedded power control cavity, and the left end face of the embedded power control cavity is fixed with the embedded power control pull rope.

2. The automatic adhering apparatus of an eyepiece objective lens of a monocular telescope according to claim 1, wherein: the upper end of the embedded reset block is fixedly connected with an embedded reset spring, the other end of the embedded reset spring is fixed on the upper end surface of the grabbing block, the left and right lower end surfaces of the embedded reset block are respectively provided with an air suction channel, a sucker is arranged below the air suction channel, the left lower side of the embedded reset block is also rotatably connected with an eyepiece nut sleeve, the left cavity wall of the installation cavity is internally provided with an objective cavity communicated with the outside, the left cavity wall of the installation cavity is also internally provided with an eyepiece cavity communicated with the outside, the lower cavity wall of the installation cavity is internally provided with a gluing control cavity with an upward opening, the gluing control cavity is internally provided with a gluing control block with an upper end extending out of the cavity, the lower end surface of the gluing control block is fixedly connected with a gluing control spring, the other end of the gluing control spring is, the gluing control cavity is internally provided with a gluing rack cavity with an upward opening, a gluing rack with an upper end extending out of the cavity is arranged in the gluing control cavity, and a gluing hole is formed in the upper end of the gluing rack.

3. The automatic adhering apparatus of an eyepiece objective lens of a monocular telescope according to claim 1, wherein: a third step block moving cavity communicated with the gluing rack cavity is arranged in the left cavity wall of the gluing rack cavity, a third step block with the right end extending into the gluing rack cavity is arranged in the third step block moving cavity, a third step block moving block is also connected on the left cavity wall of the third step block moving cavity in a sliding manner, a third step block sliding block is also connected on the lower cavity wall of the third step block moving cavity in a sliding manner, a third step block spring is fixedly connected on the left end surface of the third step block, the other end of the third step block spring is fixed on the right end surface of the third step block moving block, a third step block pull rope is fixedly connected on the lower end surface of the third step block, a third step block lifting spring is fixedly connected on the lower end surface of the third step block, the other end of the third step block lifting spring is fixed on the upper end surface of the third step block, a gluing rack spring is fixedly connected on the left end surface of the gluing rack, and, the gluing rack is characterized in that the left end face of the gluing rack is fixedly connected with the three-step block pull rope, a gluing rack transmission cavity communicated with the gluing rack transmission cavity is arranged in front of the gluing rack cavity, a gluing rack gear shaft with the rear end extending into the gluing rack cavity is arranged in the gluing rack transmission cavity, a gluing rack gear is fixed at the rear end of the gluing rack gear shaft and meshed with the lower end face of the gluing rack, a gluing rack transmission gear is fixed at the front end of the gluing rack gear shaft, a gluing rack power cavity with a right opening is arranged in front of the right side of the gluing rack transmission cavity, a ratchet shaft with the rear end extending into the gluing rack power cavity is arranged in the gluing rack transmission cavity, and the front end of the ratchet shaft is fixedly connected with the gluing rack power gear meshed with the gluing rack transmission.

4. The automatic adhering apparatus of an eyepiece objective lens of a monocular telescope according to claim 1, wherein: the rear end of the ratchet shaft is fixedly provided with a ratchet wheel, the power cavity of the gluing rack is internally provided with a ratchet wheel power friction wheel which is meshed with the ratchet wheel and rubs with the wall of the gluing control cavity, the rear cavity wall of the mounting cavity is internally provided with a switching cavity communicated with the switching cavity, the switching cavity is internally provided with a switching clamping shaft the front end of which extends into the mounting cavity, the front end of the switching clamping shaft is fixedly connected with a clamping pin, the clamping pin is rotatably connected with a clamping block, the clamping pin is internally and fixedly connected with a clamping torsion spring, the other end of the clamping torsion spring is fixed on the clamping block, the rear end of the switching clamping shaft is fixedly connected with a switching turbine, the rear end of the switching clamping shaft is fixedly connected with a gluing rope-pulling wheel, the rear end face of the gluing rope pulling wheel is rotatably connected with a gluing rope pulling sleeve, the gluing rope pulling sleeve is fixedly, the utility model discloses a rotary coating machine, including drive chamber, control chamber, drive chamber the place ahead be equipped with the intercommunication with it the conversion chamber, be equipped with the motor in the intracavity of drive chamber, terminal surface power is connected with the lower extreme and passes under the motor the control chamber is established the main shaft in the rubber coating drive intracavity, the main shaft upper end is fixed with nut drive gear, main shaft upper end still fixedly connected with conversion drive bevel gear, the main shaft lower extreme is fixed with control drive gear, the main shaft lower extreme still is fixed with rubber coating drive bevel gear, the drive chamber front end is equipped with the nut power shaft, on the nut power shaft fixedly connected with nut drive gear meshing and with eyepiece nut.

5. The automatic adhering apparatus of an eyepiece objective lens of a monocular telescope according to claim 1, wherein: a conversion driving worm shaft with the front end extending into the conversion cavity and engaged with the conversion turbine is further arranged in the driving cavity, a conversion sliding bevel gear engaged with the conversion driving bevel gear is connected to the rear end of the conversion driving worm shaft through a spline, a conversion sliding bevel gear groove with a forward opening is arranged in the front end face of the conversion sliding bevel gear, a conversion sliding bevel gear block is arranged in the conversion sliding bevel gear groove, a conversion sliding bevel gear spring is fixedly connected to the front end face of the conversion sliding bevel gear block, the other end of the conversion sliding bevel gear spring is fixed on the front cavity wall of the driving cavity, a conversion sliding bevel gear electromagnet is fixed on the front end face of the driving cavity, a control shaft groove communicated with the conversion sliding bevel gear block is arranged in the upper cavity wall behind the control cavity, a control shaft with the lower end extending into the control cavity is arranged in the control shaft groove, and a control shaft rotating block, the upper end face of the control shaft rotating block is fixedly connected with a control shaft spring, the other end of the control shaft spring is fixed on the upper end face of the control shaft groove, the upper end face of the control shaft groove is also fixedly connected with a control shaft electromagnet, the upper end of the control shaft is fixedly provided with a control shaft stop wheel, and the upper section of the control shaft is fixedly provided with a control shaft rotating gear meshed with the control driving gear.

6. The automatic adhering apparatus of an eyepiece objective lens of a monocular telescope according to claim 1, wherein: the utility model discloses a power transmission device, including control shaft, power stay cord, control shaft stay cord sleeve, rubber coating drive intracavity be equipped with the rear end with rubber coating control turbine meshing's rubber coating rotates the worm, rubber coating rotate worm left end fixedly connected with rubber coating drive bevel gear meshing's rubber coating rotates bevel gear.

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