CN115367143B - Technological device for assembling airborne photoelectric pod and use method - Google Patents

Abstract

The invention relates to a product assembly tool, in particular to a process device for assembling an airborne photoelectric pod and a use method thereof, belonging to the technical field of mechanical processes; including machine carries photoelectricity nacelle body, bottom plate, stand supporting component and arc supporting component, machine carries photoelectricity nacelle body includes lower cabin body, well cabin body and goes up the cabin body, pass through screw connection between lower cabin body and the well cabin body, between well cabin body and the upper cabin body, arc supporting component can dismantle and connect on the bottom plate, the adaptation installation between arc supporting component and the lower cabin body, arc supporting component is used for supplementary cabin body assembly down, stand supporting component can dismantle and connect on the bottom plate, the adaptation installation between stand supporting component and the well cabin body, stand supporting component is used for supplementary well cabin body and lower cabin body assembly. The invention provides a process device for assembling an airborne photoelectric pod and a use method thereof, which are used for solving the problem of low assembly efficiency of the existing airborne photoelectric pod.

Description

Technological device for assembling airborne photoelectric pod and use method

Technical Field

The invention relates to a product assembly tool, in particular to a process device for assembling an airborne photoelectric pod and a use method thereof, and belongs to the technical field of mechanical processes.

Background

The machine-mounted photoelectric pod is a photoelectric device which is arranged below the belly of an aircraft and is used for shooting, monitoring, countering striking and the like, and mainly comprises a pod body, a searching module, a tracking module, a laser striking module and a command module. The working flow is as follows: the searching module finds out the target, the tracking and aiming module tracks and aims the target, and the laser striking module emits laser to strike the aiming target according to the instruction of the instruction control module. The machine carried photoelectric pod relates to the technical fields of optics, electronics, control, image, algorithm, software, machinery, communication and the like, and belongs to high-precision tip equipment.

Because the size and the weight of the airborne photoelectric pod are strictly limited, the arrangement in the airborne photoelectric pod basically does not leave a space, which causes great difficulty for the assembly of the airborne photoelectric pod, and the airborne photoelectric pod is generally internally provided with an optical path transmission and electrical connection plug-in unit, so that the assembly quality requirement is high, the assembly efficiency of the airborne photoelectric pod is lower, and the requirement of batch production progress is difficult to meet.

Therefore, a process device for assembling the airborne photoelectric pod and a use method are provided, so that the problem of low assembly efficiency of the existing airborne photoelectric pod is solved.

Disclosure of Invention

The invention aims to provide a process device for assembling an airborne photoelectric pod and a use method thereof, so as to solve the problem of low assembly efficiency of the existing airborne photoelectric pod.

In order to achieve the above object, the technical scheme of the present invention is as follows:

The utility model provides a process units for airborne photoelectric pod assembly, includes airborne photoelectric pod body, bottom plate, stand supporting component and arc supporting component, airborne photoelectric pod body includes lower cabin body, well cabin body and goes up the cabin body, pass through screw connection between lower cabin body and the well cabin body, between well cabin body and the upper cabin body, arc supporting component can dismantle and connect on the bottom plate, the adaptation is installed between arc supporting component and the lower cabin body, arc supporting component is used for supplementary lower cabin body assembly, stand supporting component can dismantle and connect on the bottom plate, the adaptation is installed between stand supporting component and the well cabin body, stand supporting component is used for supplementary well cabin body assembly.

Specifically, the device also comprises a suspension type assembly bracket, wherein the suspension type assembly bracket is detachably connected with the airborne photoelectric pod body and is used for assisting the airborne photoelectric pod body to carry out function debugging.

Specifically, a plurality of fixed threaded holes are formed in the bottom plate.

Specifically, arc supporting component includes two diaphragms, two risers and intermediate junction board, two the middle part position of diaphragm all is equipped with the first rectangular channel that is used for fixing a position the riser, first rectangular channel and riser assorted, set up on the diaphragm with fixed screw hole assorted first bar hole on the bottom plate, through bolted connection between diaphragm and the bottom plate, peg graft in first rectangular channel in the lower extreme of riser, just riser and first rectangular channel weld into an organic whole structure, the arc wall has been seted up to the upper end of riser, arc wall and the cambered surface assorted of lower cabin, two the central axis phase-match of arc wall on the riser, two set up intermediate junction board between the riser, the installation screw hole has been seted up at the both ends of intermediate junction board, the second rectangular channel has been seted up with intermediate junction board assorted second hole on the intermediate junction board in the second rectangular channel, through bolted connection between riser and the intermediate junction board.

Specifically, stand supporting component includes stand subassembly and ear seat, stand subassembly includes backup pad, steel pipe and regulating plate, set up in the backup pad with fixed screw hole assorted third bar hole on the bottom plate, pass through bolted connection between backup pad and the bottom plate, the upper surface middle part position welding steel pipe of backup pad, the one end that the backup pad was kept away from to the steel pipe welds with the regulating plate, set up on the regulating plate and accept the screw hole, the ear seat is L type structure fourth bar hole has all been seted up on the perpendicular of ear seat and the horizontal plane, fourth bar hole on the horizontal plane and accept screw hole assorted, pass through bolted connection between regulating plate and the ear seat, the butt joint screw hole has been seted up to the position that fourth bar hole on the external lateral wall of well cabin corresponds the perpendicular, pass through bolted connection between ear seat and the well cabin body.

Specifically, suspension type assembly stand includes section bar support body, truckle and adjustment callus on the sole, section bar support body is including welding into the last loading board of an organic whole structure, load floor down, four first section bars, two second section bars, third section bar A, third section bar B and two fourth section bars, four first section bars are rectangular array welding in the upper surface of load floor down, the upper end welding of first section bar is in the lower surface of last loading board, the upper surface front and back bilateral symmetry welding second section bar of going up the loading board, just the left end of second section bar extends along last loading board left side outside, two welding third section bar A and third section bar B between the second section bar, welding fourth section bar between the left end downside of second section bar and the first section bar, the bottom surface four corners position of load floor passes through bolted connection down, adjustment threaded connection is on the load floor down, on the third section bar B has the lug through the lug on the lug, but the lug is connected with the lug through the lug.

A method of using a process device for the assembly of an on-board optoelectronic pod, comprising:

S1: adopting an arc-shaped supporting component to assist in assembling the lower cabin, ensuring that central axes of arc-shaped grooves on two vertical plates coincide before assembling, inserting a middle connecting plate into a second rectangular groove, fixedly connecting the vertical plates with the middle connecting plate by using bolts, then placing the lower cabin on the arc-shaped grooves of the vertical plates, and installing a transverse plate on a bottom plate by using bolts;

S2: the method comprises the steps that an upright post supporting component is adopted to assist in assembling a middle cabin body, an ear seat is fixedly connected with the middle cabin body through a bolt, the vertical surface of the ear seat is guaranteed to be parallel to the bottom surface of the middle cabin body during fixed connection, the middle cabin body is fixedly connected with a lower cabin body through a screw, a supporting plate is fixedly connected with a bottom plate through a bolt, the supporting plate is guaranteed to be attached to the connecting surface of the bottom plate during fixed connection, and the upper cabin body is fixedly connected with the middle cabin body through a screw, so that the whole machine of the airborne photoelectric pod body is assembled;

S3: the suspended assembly bracket is adopted to assist the airborne photoelectric pod body to carry out function debugging, the truckles and the adjusting foot pads are fixed on the lower bearing bottom plate, the using height of the adjusting foot pads is adjusted, the profile bracket body is adjusted to be horizontal, the airborne photoelectric pod body is connected to the lifting ring through the lock catch, and then the function debugging of the airborne photoelectric pod body is carried out.

The beneficial effects of the invention are as follows:

(1) According to the invention, the arc-shaped supporting component is arranged for assisting in assembling the lower cabin, the lower cabin is stably arranged on the arc-shaped groove, so that the stability of the lower cabin during assembling is ensured, the stability and the safety of the subsequent operation of assembling parts, optical debugging, laser power calibration and the like in the lower cabin are ensured, and the assembling quality and efficiency are improved; meanwhile, the arc-shaped supporting component also provides protection measures for the assembly and adjustment of the upright post supporting component, and the whole airborne photoelectric pod body is prevented from being inclined and other dangerous conditions;

(2) The invention is used for assisting the assembly of the middle cabin body through the upright post supporting component, and after the upright post supporting component is fixed with the middle cabin body, the installation and the fixation of each component in the subsequent middle cabin body are facilitated, meanwhile, the disassembly, the replacement, the assembly and the adjustment of components such as a photoelectric module, an electric module and the like in the middle cabin body are facilitated at any time, and the assembly quality, the efficiency and the safety of the airborne photoelectric pod body are improved;

(3) The invention is used for assisting the airborne photoelectric pod body to carry out function debugging by arranging the suspension type assembly bracket, and is convenient for carrying out simulated flying and various index detection on the airborne photoelectric pod body after the airborne photoelectric pod body is suspended on the suspension type assembly bracket, and is also convenient for the maintenance of the whole airborne pod system.

Drawings

FIG. 1 is a front view of an arcuate support assembly according to an embodiment of the present invention;

FIG. 2 is a side view of an arcuate support assembly according to an embodiment of the present invention;

FIG. 3 is a front view of a column support assembly according to an embodiment of the present invention;

FIG. 4 is a top view of a column support assembly according to an embodiment of the present invention;

FIG. 5 is a front view of a suspension mount bracket according to an embodiment of the present invention;

FIG. 6 is a side view of a suspension mount bracket according to an embodiment of the present invention;

FIG. 7 is a top view of an embodiment of a suspension mount bracket;

fig. 8 illustrates a flow chart of a method of using a process device for the assembly of an on-board optoelectronic pod in accordance with an embodiment.

Reference numerals: the machine-mounted photoelectric pod comprises an airborne photoelectric pod body 00, a middle pod body 00-2, a bottom plate 1, a supporting plate 2-1, a steel pipe 2-2, an adjusting plate 2-3, an ear seat 2-4, a fourth bar-shaped hole 2-5, a fixing threaded hole 2-6, a transverse plate 3-1, a vertical plate 3-2, a middle connecting plate 3-3, a caster 4-1, an adjusting foot pad 4-2, a lower bearing bottom plate 4-3, a first section bar 4-4, an upper bearing plate 4-5, a second section bar 4-6, a third section bar 4-7, a fourth section bar 4-8, a hanging ring 4-9, a lock catch 4-10 and a lifting lug 5.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and fully with reference to the accompanying drawings, in which it is evident that the embodiments described are only some, but not all embodiments of the invention. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

Example 1

Referring to fig. 1-7, the invention provides a process device for assembling an airborne photoelectric pod, which comprises an airborne photoelectric pod body 00, a bottom plate 1, a stand column support assembly and an arc support assembly, wherein the airborne photoelectric pod body 00 comprises a lower cabin body, a middle cabin body 00-2 and an upper cabin body, the lower cabin body is connected with the middle cabin body 00-2 and the upper cabin body are connected through screws, the arc support assembly is detachably connected to the bottom plate 1, the arc support assembly is adaptively installed between the arc support assembly and the lower cabin body, the arc support assembly is used for assisting in assembling the lower cabin body, the stand column support assembly is detachably connected to the bottom plate 1, the stand column support assembly is adaptively installed between the stand column support assembly and the middle cabin body 00-2, and the stand column support assembly is used for assisting in assembling the middle cabin body 00-2; the device also comprises a suspension type assembly bracket, wherein the suspension type assembly bracket is detachably connected with the airborne photoelectric pod body 00 and is used for assisting the airborne photoelectric pod body 00 in functional debugging.

Furthermore, the airborne photoelectric pod body 00 comprises a lower pod body, a middle pod body 00-2 and an upper pod body, when the airborne photoelectric pod body 00 is assembled, the arc-shaped supporting component is adopted to assist the lower pod body to be assembled, the upright post supporting component is adopted to assist the middle pod body 00-2 to be assembled and the lower pod body is connected with the middle pod body 00-2, and finally the upper pod body is connected to the middle pod body 00-2 through screws, so that the whole machine assembly of the airborne photoelectric pod body 00 can be realized.

Specifically, the bottom plate 1 is provided with a plurality of fixing threaded holes 2-6.

Furthermore, the fixing threaded holes 2-6 are convenient for installing the arc-shaped supporting component and the upright post supporting component on the bottom plate 1, and are convenient to operate.

Specifically, arc supporting component includes two diaphragm 3-1, two riser 3-2 and intermediate junction plate 3-3, two the middle part position of diaphragm 3-1 all is equipped with the first rectangular channel that is used for fixing a position riser 3-2, first rectangular channel and riser 3-2 assorted, set up on the diaphragm 3-1 with fixed screw hole 2-6 assorted first bar hole on bottom plate 1, pass through bolted connection between diaphragm 3-1 and the bottom plate 1, peg graft in first rectangular channel in the lower extreme of riser 3-2, just riser 3-2 and first rectangular channel welding structure, the arc wall has been seted up to the upper end of riser 3-2, arc wall and lower cabin's cambered surface assorted, two the central axis phase-match of arc wall on riser 3-2 sets up intermediate junction plate 3-3 between two intermediate junction plate 3-3, the mounting screw hole has been seted up at the both ends of intermediate junction plate 3-3, the intermediate junction plate 3-2 has been seted up through bolted connection in the second rectangular channel 3-2, second rectangular channel and intermediate junction plate 3-3 through the second rectangular channel, intermediate junction plate 3-3.

Furthermore, the arc-shaped supporting component consists of two transverse plates 3-1, two vertical plates 3-2 and a middle connecting plate 3-3, wherein the first rectangular groove is matched with the vertical plates 3-2, so that the vertical plates 3-2 are convenient to weld in a positioning way, and meanwhile, the transverse plates 3-1 and the vertical plates 3-2 are welded into an integrated structure, and the arc-shaped supporting component is used for supporting the weight of a lower cabin in the assembly and adjustment process of the lower cabin and can also be used as a protection means for preventing the airborne photoelectric pod body 00 from falling in the assembly process; the arc-shaped groove is formed in the upper end of the vertical plate 3-2, the arc-shaped groove is matched with the arc-shaped groove of the lower cabin body, the central axes of the arc-shaped grooves on the two vertical plates 3-2 are guaranteed to coincide, the arc-shaped groove and the arc-shaped groove of the lower cabin body are convenient to completely attach, the shake of the lower cabin body in the assembly process is prevented from affecting the optical debugging of the airborne photoelectric pod body 00, the stable debugging environment of the airborne photoelectric pod body 00 in optical, electrical and other systems is improved, and the debugging efficiency of the whole machine is improved.

Specifically, the stand supporting component comprises a stand component and an ear seat 2-4, the stand component comprises a supporting plate 2-1, a steel pipe 2-2 and an adjusting plate 2-3, a third strip-shaped hole matched with a fixing threaded hole 2-6 on a bottom plate 1 is formed in the supporting plate 2-1, the supporting plate 2-1 is connected with the bottom plate 1 through a bolt, the steel pipe 2-2 is welded at the middle position of the upper surface of the supporting plate 2-1, one end, far away from the supporting plate 2-1, of the steel pipe 2-2 is welded with the adjusting plate 2-3, a receiving threaded hole is formed in the adjusting plate 2-3, the ear seat 2-4 is of an L-shaped structure, a fourth strip-shaped hole 2-5 is formed in the vertical surface and the horizontal surface of the ear seat 2-4, the fourth strip-shaped hole 2-5 is matched with the receiving threaded hole on the horizontal surface, the adjusting plate 2-3 is connected with the ear seat 2-4 through a bolt, a butt joint threaded hole is formed in the position of the fourth hole 2-5 on the vertical surface corresponding to the outer side wall of the middle cabin body 00-2, and the ear seat 2-00 is connected with the middle cabin body through the bolt 2-00-2.

Furthermore, the upright post supporting component consists of the upright post component and the ear seat 2-4, wherein the third strip-shaped hole is arranged, so that the supporting plate 2-1 and the bottom plate 1 are fixedly connected through bolts, and meanwhile, the position of the supporting plate 2-1 during installation is conveniently adjusted; through setting up ear mount 2-4 and regulating plate 2-3, be convenient for through the bolt with regulating plate 2-3 with well cabin body 00-2 fixed, each components and parts installation in the follow-up well cabin body 00-2 are fixed, and the component parts such as photoelectric module, electric module in the well cabin body 00-2 are convenient to dismantle, change and the dress is transferred at any time simultaneously, have improved the assembly quality, efficiency and the security of airborne photoelectric pod body 00.

Specifically, the suspension assembly bracket comprises a section bracket body, casters 4-1 and an adjusting foot pad 4-2, wherein the section bracket body comprises an upper bearing plate 4-5, a lower bearing bottom plate 4-31, four first section bars 4-4, two second section bars 4-6, a third section bar 4-7A, a third section bar 4-7B and two fourth section bars 4-8 which are welded on the upper surface of the lower bearing bottom plate 4-31 in a rectangular array, the upper end of the first section bar 4-4 is welded on the lower surface of the upper bearing plate 4-5, the front side and the rear side of the upper surface of the upper bearing plate 4-5 are symmetrically welded with second section bars 4-6, the left end of the second section bar 4-6 extends along the outer part of the left side of the upper bearing plate 4-5, the third section bar 4-7A and the third section bar 4-7B are welded between the two second section bars 4-6, the third section bar 4-7B is welded on the upper surface of the second section bar 4-6 along the upper side 4-5, the upper end of the upper bearing bottom plate 4-5 is connected with the lower surface of the lower bearing bottom plate 4-5 through a lifting lug 4-5, the left side of the lifting lug is connected with the upper surface of the upper bearing bottom plate 4-5 by the adjusting foot pad 4-5, the left end of the lifting lug is connected with the upper side 4-5 through the lifting lug 4-5, the hanging ring 4-9 is detachably connected with the lifting lug 5 through a lock catch 4-10.

Furthermore, the suspension type assembly bracket related by the invention consists of a section bracket body, casters 4-1 and an adjusting foot pad 4-2, wherein the section bracket body consists of an upper bearing plate 4-5, a lower bearing bottom plate 4-31, four first section bars 4-4, two second section bars 4-6, a third section bar 4-7A, a third section bar 4-7B and two fourth section bars 4-8, and the upper bearing plate 4-5, the lower bearing bottom plate 4-31, the four first section bars 4-4, the two second section bars 4-6, the third section bar 4-7A, the third section bar 4-7B and the two fourth section bars 4-8 are welded into an integrated structure, so that the working strength and stability of the whole suspension type assembly bracket can be enhanced; the caster 4-1 is arranged, so that the hanging type assembly bracket is convenient to move in the function debugging process, and the use is convenient; the adjusting foot pad 4-2 is arranged, so that the supporting suspension type assembly bracket and the airborne photoelectric pod body 00 are supported in the debugging position, the horizontal adjustment of the whole suspension type assembly bracket is realized through screw thread adjustment, and the shaking and the movement of the caster 4-1 in the debugging process are eliminated while the suspension type assembly bracket is supported and lifted, so that the instability of subsequent function debugging is avoided; through setting up rings 4-9, lug 5 and hasp 4-10, be convenient for improve the height of airborne photoelectric nacelle body 00 in the debugging in-process, be convenient for manual operation, simultaneously also be convenient for follow-up system, search system, hit the joint debugging of system etc. in the remote department of optical axis to improve the inspection and the acceptance efficiency of airborne photoelectric nacelle body 00 finished product, in addition, the structure of hasp 4-10 is prior art, and no more detailed here is provided, as long as can realize fastening rings 4-9 and lug 5.

Example 2

Referring to fig. 8, the present invention provides a method for using a process device for assembling an on-board optoelectronic pod, comprising:

S1: the arc-shaped supporting components are adopted to assist in assembling the lower cabin, before assembling, the central axes of the arc-shaped grooves on the two vertical plates 3-2 are guaranteed to coincide, then the middle connecting plate 3-3 is inserted into the second rectangular groove, the vertical plates 3-2 and the middle connecting plate 3-3 are fixedly connected through bolts, then the lower cabin is placed on the arc-shaped grooves of the vertical plates 3-2, and then the transverse plates 3-1 are installed on the bottom plate 1 through bolts.

Further, the lower cabin body is placed on the arc-shaped groove of the middle plate 3-2 of the arc-shaped supporting component, the arc-shaped groove is attached to the arc-shaped surface of the lower cabin body, the lower cabin body can be prevented from shaking in the debugging process, and further optical debugging of the airborne photoelectric pod body 00 is affected, so that stable debugging environment and tools are improved, and optical debugging efficiency is improved.

S2: the assembly of the middle cabin body 00-2 is assisted by adopting a stand column supporting component, the lug seat 2-4 is fixedly connected with the middle cabin body 00-2 by utilizing a bolt, the vertical surface of the lug seat 2-4 is ensured to be parallel to the bottom surface of the middle cabin body 00-2 during the fixed connection, the middle cabin body 00-2 is fixedly connected with the lower cabin body by utilizing a screw, then the supporting plate 2-1 is fixedly connected with the bottom plate 1 by utilizing the bolt, the joint surface lamination of the supporting plate 2-1 and the bottom plate 1 is ensured during the fixed connection, the upper cabin body is fixedly connected with the middle cabin body 00-2 by utilizing the screw, and the assembly of the whole machine of the airborne photoelectric pod body 00 is completed.

Further, the middle cabin body 00-2 to be assembled is placed on the lower cabin body, the lug seat 2-4 is fixedly connected with the middle cabin body 00-2 through bolts, the middle cabin body 00-2 is fixedly connected with the lower cabin body through screws, the supporting plate 2-1 is fixedly connected with the bottom plate 1 through bolts, the joint surface of the supporting plate 2-1 and the bottom plate 1 is guaranteed to be attached when the supporting plate is fixedly connected, components such as an electric board card and an optical device in the middle cabin body 00-2 are installed and fixed, then the components are subjected to circuit arrangement connection, and the components are subjected to circuit inspection, so that the tool is convenient for installation and circuit arrangement of the components in the middle cabin body 00-2; meanwhile, when the components are required to be replaced, the tool does not influence the installation and debugging of other components, and is convenient for improving the efficiency; and finally, fixedly connecting the upper cabin body with the middle cabin body 00-2 through screws to complete the assembly of the whole machine of the airborne photoelectric pod body 00.

S3: the suspended assembly bracket is adopted to assist the airborne photoelectric pod body 00 in functional debugging, the casters 4-1 and the adjusting foot pads 4-2 are fixed on the lower bearing bottom plate 4-31, the profile bracket body is adjusted to be horizontal by adjusting the use height of the adjusting foot pads 4-2, the airborne photoelectric pod body 00 is connected to the hanging rings 4-9 through the lock catches 4-10, and then the function debugging of the airborne photoelectric pod body 00 is carried out.

Furthermore, after the assembly and debugging of the airborne photoelectric pod body 00 are completed, the airborne photoelectric pod body 00 is suspended on a suspension assembly bracket through the suspension rings 4-9, the lifting lugs 5 and the lock catches 4-10, so that the follow-up joint debugging of a follow-up system, a search system, a striking system and the like at a position far from an optical axis is facilitated.

Finally, it is noted that the above embodiments are only for illustrating the technical solution of the present invention and not for limiting the same, and although the present invention has been described in detail with reference to the preferred embodiments, it should be understood by those skilled in the art that modifications and equivalents may be made thereto without departing from the spirit and scope of the technical solution of the present invention, which is intended to be covered by the scope of the claims of the present invention.

Claims (5)

1. The technological device for assembling the airborne photoelectric pod is characterized by comprising an airborne photoelectric pod body, a suspension type assembling bracket, a bottom plate, a stand column supporting component and an arc supporting component, wherein the suspension type assembling bracket is detachably connected with the airborne photoelectric pod body and is used for assisting the airborne photoelectric pod body to carry out function debugging; the suspended assembly bracket comprises a section bracket body, casters and an adjusting foot pad, wherein the section bracket body comprises an upper bearing plate, a lower bearing bottom plate, four first sections, two second sections, a third section A, a third section B and two fourth sections which are welded into an integral structure, the four first sections are welded on the upper surface of the lower bearing bottom plate in a rectangular array, the upper ends of the first sections are welded on the lower surface of the upper bearing plate, the second sections are symmetrically welded on the front side and the rear side of the upper surface of the upper bearing plate, the left end of the second section extends along the left side outside of the upper bearing plate, a third section A and a third section B are welded between the two second sections, the third section B is welded on one side of the second section extending along the left side outside of the upper bearing plate, the fourth section is welded between the lower side of the left end of the second section and the first section, the four corners of the lower bearing bottom plate are connected with the casters through bolts, the adjusting foot pad is in threaded connection on the lower bearing bottom plate, the third section B is connected with a hanging ring body through a lock catch, and the hanging ring body is connected with the hanging ring body through the hanging ring body and the hanging ring body; the lower cabin body is connected with the middle cabin body and the middle cabin body is connected with the upper cabin body through screws, the arc-shaped supporting component is detachably connected to the bottom plate and is installed in an adaptive mode with the lower cabin body, the arc-shaped supporting component is used for assisting in assembling the lower cabin body and comprises two transverse plates, two vertical plates and a middle connecting plate, and first rectangular grooves used for positioning the vertical plates are formed in the middle positions of the two transverse plates; an arc-shaped groove is formed in the upper end of the vertical plate and is matched with the arc surface of the lower cabin body; a middle connecting plate is arranged between the two vertical plates, a second rectangular groove is formed in the middle of each vertical plate, and the second rectangular grooves are matched with the middle connecting plate; the upright post supporting component is detachably connected to the bottom plate, the upright post supporting component is mounted with the middle cabin body in an adapting mode, the upright post supporting component is used for assisting in assembly of the middle cabin body, the upright post supporting component comprises an upright post component and an ear seat, the upright post component comprises a supporting plate, and the supporting plate is connected with the bottom plate through bolts; the ear seat is of an L-shaped structure, and the ear seat is connected with the middle cabin body through bolts.

2. The process device for assembling an airborne optoelectronic pod of claim 1 wherein the base plate is formed with a plurality of threaded fastener holes.

3. The process device for assembling the airborne optoelectronic pod according to claim 2, wherein the first rectangular slot is matched with the vertical plate, the transverse plate is provided with a first strip-shaped hole matched with the fixing threaded hole on the bottom plate, the transverse plate is connected with the bottom plate through a bolt, the lower end of the vertical plate is inserted into the first rectangular slot, the vertical plate and the first rectangular slot are welded into an integrated structure, the central axes of the arc-shaped slots on the two vertical plates coincide, the two ends of the middle connecting plate are provided with mounting threaded holes, the second rectangular slot is provided with a second strip-shaped hole matched with the mounting threaded hole on the middle connecting plate, and the vertical plate is connected with the middle connecting plate through a bolt.

4. The process device for assembling the airborne optoelectronic pod according to claim 1, wherein the upright post assembly further comprises a steel pipe and an adjusting plate, a third strip-shaped hole matched with the fixing threaded hole on the bottom plate is formed in the supporting plate, the steel pipe is welded in the middle of the upper surface of the supporting plate, one end, far away from the supporting plate, of the steel pipe is welded with the adjusting plate, a receiving threaded hole is formed in the adjusting plate, fourth strip-shaped holes are formed in the vertical surface and the horizontal surface of the ear seat, the fourth strip-shaped holes are matched with the receiving threaded holes in the horizontal surface, the adjusting plate is connected with the ear seat through bolts, and a butt threaded hole is formed in the position, corresponding to the fourth strip-shaped hole in the vertical surface, of the outer side wall of the middle pod.

5. A method of using a process unit for the assembly of an on-board optoelectronic pod according to any one of claims 1 to 4, comprising:

S1: adopting an arc-shaped supporting component to assist in assembling the lower cabin, ensuring that central axes of arc-shaped grooves on two vertical plates coincide before assembling, inserting a middle connecting plate into a second rectangular groove, fixedly connecting the vertical plates with the middle connecting plate by using bolts, then placing the lower cabin on the arc-shaped grooves of the vertical plates, and installing a transverse plate on a bottom plate by using bolts;

S2: the method comprises the steps that an upright post supporting component is adopted to assist in assembling a middle cabin body, an ear seat is fixedly connected with the middle cabin body through a bolt, the vertical surface of the ear seat is guaranteed to be parallel to the bottom surface of the middle cabin body during fixed connection, the middle cabin body is fixedly connected with a lower cabin body through a screw, a supporting plate is fixedly connected with a bottom plate through a bolt, the supporting plate is guaranteed to be attached to the connecting surface of the bottom plate during fixed connection, and the upper cabin body is fixedly connected with the middle cabin body through a screw, so that the whole machine of the airborne photoelectric pod body is assembled;

S3: the suspended assembly bracket is adopted to assist the airborne photoelectric pod body to carry out function debugging, the truckles and the adjusting foot pads are fixed on the lower bearing bottom plate, the using height of the adjusting foot pads is adjusted, the profile bracket body is adjusted to be horizontal, the airborne photoelectric pod body is connected to the lifting ring through the lock catch, and then the function debugging of the airborne photoelectric pod body is carried out.