CN116014606A - Auxiliary operation support rod of vertical installation equipment - Google Patents

Abstract

The invention discloses an auxiliary operation support rod of vertical installation equipment, which comprises a main support rod module, wherein the main support rod module comprises a support rod assembly, a limiting assembly, a release assembly and a locking assembly, the support rod assembly is limited in one direction through the limiting assembly, the release assembly is extruded through the limiting assembly, and the release assembly is movably connected with the locking assembly; the auxiliary supporting component is movably connected with the supporting rod component. According to the invention, the main ram is arranged to carry out holding operation of electricity testing and power transmission, and the auxiliary lever is arranged to limit the middle section of the main ram, so that inconvenient force generation and deformation caused by overlong length of the main ram in the use process are effectively avoided, after the electricity testing operation is carried out firstly, the handle is rotated and is switched to contact with the knife switch at the power transmission end, and then the power transmission operation is carried out, so that the use is more convenient and safer.

Description

Auxiliary operation support rod of vertical installation equipment

Technical Field

The invention relates to the technical field of distribution network tools, in particular to an auxiliary operation support rod of vertical installation equipment.

Background

The distribution network 10kV line is provided with a plurality of disconnecting switches and drop-out fuse devices with long operational life, and the installation positions are higher and are vertically installed. When the power distribution operation personnel operate, the accuracy is reduced due to the difficulty of force generation, and the isolating disconnecting link is taken as an example:

if the operation is performed under the isolating switch, the operation cannot be completed because the operating rod is parallel to the isolating switch and the stress angle is 0;

if an operator stands far away from the electric pole, the operator holds an operation rod which is too long, the operation rod can bend after being stressed, the top end of the operation rod can shake continuously, and the operator can be inserted into the equipment operation ring only after taking a long time;

and before power transmission, the power transmission needs to be tested, and by means of a single operating rod, time and labor are wasted, and the power transmission are difficult to synchronously finish.

In summary, the above operations are not only time-consuming and laborious, but also easily damage the equipment body and even cause line tripping.

Disclosure of Invention

This section is intended to outline some aspects of embodiments of the invention and to briefly introduce some preferred embodiments. Some simplifications or omissions may be made in this section as well as in the description summary and in the title of the application, to avoid obscuring the purpose of this section, the description summary and the title of the invention, which should not be used to limit the scope of the invention.

The present invention has been made in view of the problems occurring in the prior art.

Therefore, the technical problem to be solved by the invention is that the existing isolating switch and drop-out fuse equipment are higher in installation position and are vertically installed, the power transmission operation is time-consuming and labor-consuming, and before power transmission, the power transmission operation also needs to be performed, and the power transmission operation is time-consuming and labor-consuming by means of a single operating rod, so that the power transmission operation is difficult to be completed synchronously.

In order to solve the technical problems, the invention provides the following technical scheme: the auxiliary operation support rod of the vertical installation equipment comprises a main support rod module, wherein the main support rod module comprises a support rod assembly, a limiting assembly, a release assembly and a locking assembly, the support rod assembly is limited in one direction through the limiting assembly, the release assembly is extruded through the limiting assembly, and the release assembly is movably connected with the locking assembly;

the auxiliary supporting component is movably connected with the supporting rod component;

the linkage operation module comprises a linkage assembly, a transmission assembly and an operation assembly, wherein the linkage assembly is movably connected with the stay bar assembly, and the transmission assembly is movably connected with the linkage assembly and the operation assembly respectively.

As a preferable mode of the vertical installation apparatus auxiliary operation support bar of the present invention, wherein: the support rod assembly comprises a main adjusting rod, a manual control rod and a manual control handle, wherein both ends of the manual control rod penetrate through the main adjusting rod, one end of the manual control rod is connected with the manual control handle, and the outer wall of the manual control rod is connected with a gear.

As a preferable mode of the vertical installation apparatus auxiliary operation support bar of the present invention, wherein: the limiting assembly comprises a limiting bin, a displacement rod and a displacement handle, wherein the limiting bin is arranged on the outer wall of the main adjusting rod, one end of the displacement rod is connected with the displacement handle, one end of the displacement rod penetrates through the limiting bin and is connected with a movable plate, one face of the movable plate is connected with the inner wall of the limiting bin through a first spring, one face of the movable plate is connected with an arc toothed plate, and the arc toothed plate is arranged on one side of the gear.

As a preferable mode of the vertical installation apparatus auxiliary operation support bar of the present invention, wherein: the two groups of release components are respectively arranged on two sides of the inner cavity of the main adjusting rod, each release component comprises a sliding arc plate, a traction rod and an arc traction plate, two ends of each traction rod are respectively connected with the corresponding sliding arc plate and the corresponding arc traction plate, the outer wall of each arc traction plate is connected with an extrusion pin, the concave surface of each sliding arc plate is provided with a slide way, each manual control rod is arranged between two groups of sliding arc plates, and the outer wall of each manual control rod is connected with a cam disc.

As a preferable mode of the vertical installation apparatus auxiliary operation support bar of the present invention, wherein: the locking assembly comprises a side plate, a limiting slide plate and a guide rod, wherein two ends of the guide rod are connected with the side plate, one side of the side plate is connected with the inner wall of the main adjusting rod, the limiting slide plate is sleeved on the outer wall of the guide rod, one end of the limiting slide plate is connected with the sliding arc plate, the outer wall of the guide rod is sleeved with a second spring, and two ends of the second spring are respectively connected with two groups of limiting slide plates.

As a preferable mode of the vertical installation apparatus auxiliary operation support bar of the present invention, wherein: the auxiliary supporting component comprises a limit sleeve, a movable seat and a first auxiliary rod, wherein the limit sleeve is sleeved on the outer wall of the main adjusting rod, the movable seat is arranged on the outer wall of the limit sleeve, and one end of the first auxiliary rod is movably connected with the movable seat.

As a preferable mode of the vertical installation apparatus auxiliary operation support bar of the present invention, wherein: the first auxiliary rod outer wall is sleeved with a second auxiliary rod, and the second auxiliary rod outer wall is in threaded connection with a positioning bolt.

As a preferable mode of the vertical installation apparatus auxiliary operation support bar of the present invention, wherein: the linkage assembly comprises a mounting frame, a first wheel disc, a first linkage rod and a driven bevel gear, wherein the mounting frame is arranged at one end of the main adjusting rod, two ends of the first linkage rod are connected with the inner wall of the mounting frame, the first wheel disc and the driven bevel gear are arranged on the outer wall of the first linkage rod, one end of the manual control rod penetrates through the mounting frame and is connected with the driving bevel gear, and teeth on the surface of the driving bevel gear are meshed with the driven bevel gear.

As a preferable mode of the vertical installation apparatus auxiliary operation support bar of the present invention, wherein: the transmission assembly comprises a second linkage rod, a second wheel disc and a transmission chain, wherein the second wheel disc is arranged on the outer wall of the second linkage rod, two ends of the second linkage rod are connected with the inner wall of the mounting frame, and two ends of the transmission chain are respectively connected with the second wheel disc and the first wheel disc in a rotating mode.

As a preferable mode of the vertical installation apparatus auxiliary operation support bar of the present invention, wherein: the operation assembly comprises a mounting ring, a connecting rod, a power transmission clamping block and an electroscope, wherein the mounting ring is arranged on the outer wall of the second linkage rod, and the power transmission clamping block and the electroscope are connected with the mounting ring through the connecting rod.

The invention has the beneficial effects that: according to the invention, the main ram is arranged to carry out holding operation of electricity testing and power transmission, and the auxiliary lever is arranged to limit the middle section of the main ram, so that inconvenient force generation and deformation caused by overlong length of the main ram in the use process are effectively avoided, after the electricity testing operation is carried out firstly, the handle is rotated and is switched to contact with the knife switch at the power transmission end, and then the power transmission operation is carried out, so that the use is more convenient and safer.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings that are needed in the description of the embodiments will be briefly described below, it being obvious that the drawings in the following description are only some embodiments of the present invention, and that other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art. Wherein:

fig. 1 is a schematic diagram of an apparatus structure according to an embodiment of the present invention.

Fig. 2 is a schematic diagram of a partial enlarged structure at Q in fig. 1 according to an embodiment of the present invention.

Fig. 3 is a schematic structural diagram of a limiting component in an embodiment of the invention.

Fig. 4 is a schematic view of the internal structure of the main adjusting lever according to the embodiment of the present invention.

FIG. 5 is a schematic view of the release assembly and locking assembly in an embodiment of the present invention.

Fig. 6 is a block diagram illustrating installation of a linkage operation module in an embodiment of the present invention.

Fig. 7 is a schematic structural diagram of a linkage operation module in an embodiment of the present invention.

Detailed Description

In order that the above-recited objects, features and advantages of the present invention will become more readily apparent, a more particular description of the invention will be rendered by reference to specific embodiments thereof which are illustrated in the appended drawings.

In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present invention, but the present invention may be practiced in other ways other than those described herein, and persons skilled in the art will readily appreciate that the present invention is not limited to the specific embodiments disclosed below.

Further, reference herein to "one embodiment" or "an embodiment" means that a particular feature, structure, or characteristic can be included in at least one implementation of the invention. The appearances of the phrase "in one embodiment" in various places in the specification are not necessarily all referring to the same embodiment, nor are separate or alternative embodiments mutually exclusive of other embodiments.

Example 1

Referring to fig. 1 to 7, in a first embodiment of the present invention, there is provided an auxiliary operation support bar for a vertical installation apparatus, which includes a main brace module 100, wherein the main brace module 100 includes a brace assembly 101, a limiting assembly 102, a release assembly 103 and a locking assembly 104, the brace assembly 101 is limited in one direction by the limiting assembly 102, the release assembly 103 is extruded by the limiting assembly 102, and the release assembly 103 is movably connected with the locking assembly 104.

Before power transmission, the switch blade needs to be subjected to power inspection for ensuring the safety of switching on, and a user drives the linkage operation module 300 to integrally move through the traction of the main support rod module 100, so that the power inspection equipment is in contact with the switch blade to perform power inspection operation, and after the power inspection is completed, the output end of the linkage operation module 300 is switched, so that the power transmission end is in contact with a switch blade, and power transmission operation is performed.

The auxiliary supporting component 200 is movably connected with the supporting rod component 101;

in the process of electricity testing and power transmission operation, another worker holds the auxiliary supporting component 200 by hand to support the middle section of the main supporting rod module 100, so that the problem that the stability and safety of power transmission are affected due to the fact that the whole using length of the main supporting rod module 100 is long and the deformation of the end part of the main supporting rod module is avoided.

The linkage operation module 300, the linkage operation module 300 includes linkage assembly 301, drive assembly 302 and operation assembly 303, and linkage assembly 301 and vaulting pole subassembly 101 swing joint, drive assembly 302 respectively with linkage assembly 301 and operation assembly 303 swing joint.

When switching the output end of the device, the user first adjusts the limiting component 102 to release the limiting of the supporting rod component 101, so that the adjusting component in the supporting rod component 101 can freely rotate.

The rotation power is output through the stay bar assembly 101, so that the release assembly 103 is driven to be linked, and the stay bar assembly 101 and the auxiliary support assembly 200 are fixed, so that the stay bar assembly 101 can slide in the inner cavity of the auxiliary support assembly 200 in the power transmission process, and the stability of equipment operation is prevented from being influenced.

The linkage assembly 301 and the transmission assembly 302 are linked by the output of the rotation power of the stay bar assembly 101, so that the operation assembly 303 is overturned, the state switching is completed, and after the switching is completed, the limiting assembly 102 is reset, so that the state of the equipment is kept stable.

Example 2

Referring to fig. 1 to 5, a second embodiment of the present invention is based on the previous embodiment.

The stay bar assembly 101 comprises a main adjusting rod 101a, a manual control rod 101b and a manual control handle 101c, wherein two ends of the manual control rod 101b penetrate through the main adjusting rod 101a, one end of the manual control rod 101b is connected with the manual control handle 101c, and the outer wall of the manual control rod 101b is connected with a gear 101d.

The inner wall of the main adjusting rod 101a is provided with a bearing matched with the manual control rod 101b, so that the phenomenon that the sliding of the manual control rod 101b in the inner cavity of the main adjusting rod 101a affects the power transmission stability is avoided, and when the output power needs to be adjusted, a user rotates the manual control handle 101c, so that the manual control rod 101b is driven to rotate, and the rotating mechanical transmission force is output.

The limiting assembly 102 comprises a limiting bin 102a, a displacement rod 102b and a displacement handle 102c, wherein the limiting bin 102a is arranged on the outer wall of the main adjusting rod 101a, one end of the displacement rod 102b is connected with the displacement handle 102c, one end of the displacement rod 102b penetrates through the limiting bin 102a and is connected with a movable plate 102e, one surface of the movable plate 102e is connected with the inner wall of the limiting bin 102a through a first spring 102d, one surface of the movable plate 102e is connected with an arc toothed plate 102f, and the arc toothed plate 102f is arranged on one side of the gear 101d.

Before rotational adjustment of the hand lever 101b, the adjustment limit assembly 102 is required to contact its limit of the hand lever 101 b.

Specifically, the user pulls the displacement handle 102c, the displacement handle 102c moves to drive the displacement rod 102b to move, the movable plate 102e is driven to move through the movement of the displacement rod 102b, the first spring 102d is stretched to deform through the movement of the movable plate 102e, and the subsequent reset of the device is facilitated through deformation energy storage of the first spring 102 d.

The arc toothed plate 102f is driven to move through the movement of the movable plate 102e, the meshing locking state of the arc toothed plate 102f and the gear 101d is released through the movement of the arc toothed plate 102f, the gear 101d can rotate freely, namely, the manual control rod 101b can rotate freely for adjustment, when the manual control rod 101b rotates for adjustment, a user releases the displacement handle 102c, the equipment is reset through elastic reset of the first spring 102d, the meshing locking state of the arc toothed plate 102f and the gear 101d is restored, and the equipment is restored to the locking state again.

Two sets of release components 103 divide and establish main regulation pole 101a inner chamber both sides, release components 103 includes slip arc board 103a, traction lever 103b and arc traction plate 103d, traction lever 103b both ends are connected with slip arc board 103a and arc traction plate 103d respectively, extrusion round pin 103e is connected to arc traction plate 103d outer wall, slide 103c is seted up to the concave surface of slip arc board 103a, manual lever 101b sets up between two sets of slip arc boards 103a, cam plate 101e is connected to manual lever 101b outer wall.

Specifically, the cam plate 101e is rotated by the rotation of the manual lever 101b, and the user adjusts the number of rotations of the manual lever 101b to be one-fourth of the number of rotations, so that the number of rotations of the cam plate 101e is also one-fourth of the number of rotations.

In the initial state, the longer two ends of the cam plate 101e are not contacted with the sliding arc plate 103a, and the extrusion pin 103e is positioned in the inner cavity of the main adjusting rod 101 a.

When the cam plate 101e rotates one quarter turn, its longer ends are just against the deepest of the concave surface in the sliding arc plate 103 a. Through the opening of the slide way 103c, the phenomenon of clamping stagnation during sliding connection with the outer wall of the sliding arc plate 103a in the rotation process of the cam disc 101e can be effectively avoided, and stable transmission extrusion of equipment is effectively ensured.

The sliding arc plate 103a is extruded through rotation of the cam disc 101e, so that the sliding arc plate 103a moves, the traction rod 103b and the arc traction plate 103d are driven to move through movement of the sliding arc plate 103a, the extrusion pin 103e is driven to move through movement of the arc traction plate 103d, the extrusion pin penetrates through the main adjusting rod 101a and contacts with the inner wall of the limiting sleeve 201, the main adjusting rod 101a and the limiting sleeve 201 are extruded mutually, and therefore the outer wall of the main adjusting rod 101a and the inner wall of the limiting sleeve 201 are fixedly connected.

After the fixed connection of the main adjusting rod and the main adjusting rod is realized, when a user conducts power transmission operation through the main adjusting rod 101a, the power transmission device on the end face of the main adjusting rod can be contacted with the knife switch, and then one end of the main adjusting rod 101a is directly pressed, so that the main adjusting rod 101a can rotate by taking the movable seat 202 as an axle center to conduct lever rotation, and the power transmission operation is more convenient and safer. The situation that the end face of the main adjusting rod 101a is not limited is avoided, when a worker conducts power transmission operation, the end face of the main adjusting rod shakes, and the power transmission operation is time-consuming and labor-consuming.

The locking assembly 104 comprises a side plate 104a, a limit sliding plate 104b and a guide rod 104d, wherein two ends of the guide rod 104d are connected with the side plate 104a, one side of the side plate 104a is connected with the inner wall of the main adjusting rod 101a, the limit sliding plate 104b is sleeved on the outer wall of the guide rod 104d, one end of the limit sliding plate 104b is connected with the sliding arc plate 103a, a second spring 104c is sleeved on the outer wall of the guide rod 104d, and two ends of the second spring 104c are respectively connected with two groups of limit sliding plates 104 b.

When the sliding arc plate 103a is subjected to force extrusion and force movement, the sliding arc plate 103a drives the limit sliding plate 104b to slide on the surface of the guide rod 104d, in the moving process of the limit sliding plate 104b, the second spring 104c is pulled to deform, the deformation energy storage of the second spring 104c is carried out, when the follow-up cam disc 101e rotates, the extrusion of the cam disc 101e on the sliding arc plate 103a is released, the sliding arc plate 103a is synchronously reset after the second spring 104c is reset, finally, the extrusion pin 103e is retracted into the inner cavity of the main adjusting rod 101a, and the limit between the main adjusting rod 101a and the limit sleeve 201 is released.

The auxiliary supporting assembly 200 comprises a limiting sleeve 201, a movable seat 202 and a first auxiliary rod 203, wherein the limiting sleeve 201 is sleeved on the outer wall of the main adjusting rod 101a, the movable seat 202 is arranged on the outer wall of the limiting sleeve 201, and one end of the first auxiliary rod 203 is movably connected with the movable seat 202.

Through the arrangement of the movable seat 202, the limit sleeve 201 can rotate by taking the movable seat 202 as the axle center in the supporting operation process, so that the power transmission operation of a user is facilitated.

The outer wall of the first auxiliary rod 203 is sleeved with a second auxiliary rod 204, and the outer wall of the second auxiliary rod 204 is connected with a positioning bolt in a threaded manner.

In the field operation process, the user adjusts the length of the first auxiliary rod 203 in the inner cavity of the second auxiliary rod 204, and locks the positioning bolt after the adjustment is completed, so that the overall use length of the auxiliary support assembly 200 is adjusted, and the on-site use of workers is facilitated.

Example 3

Referring to fig. 6 to 7, a third embodiment of the present invention is based on the above two embodiments.

The linkage assembly 301 comprises a mounting frame 301a, a first wheel disc 301b, a first linkage rod 301c and a driven bevel gear 301d, wherein the mounting frame 301a is arranged at one end of the main adjusting rod 101a, two ends of the first linkage rod 301c are connected with the inner wall of the mounting frame 301a, the first wheel disc 301b and the driven bevel gear 301d are arranged on the outer wall of the first linkage rod 301c, one end of the manual control rod 101b penetrates through the mounting frame 301a and is connected with the driving bevel gear 101f, and teeth on the surface of the driving bevel gear 101f are meshed with the driven bevel gear 301 d.

In the adjustment linkage process, specifically, when the manual lever 101b rotates, it drives the drive bevel gear 101f to rotate, drives the driven bevel gear 301d to rotate through the rotation of the drive bevel gear 101f, drives the first linkage lever 301c to rotate through the rotation of the driven bevel gear 301d, and drives the first wheel disc 301b to rotate through the rotation of the first linkage lever 301 c.

The transmission assembly 302 comprises a second linkage rod 302a, a second wheel disc 302b and a transmission chain 302c, wherein the second wheel disc 302b is arranged on the outer wall of the second linkage rod 302a, two ends of the second linkage rod 302a are connected with the inner wall of the mounting frame 301a, and two ends of the transmission chain 302c are respectively connected with the second wheel disc 302b and the first wheel disc 301b in a rotating mode.

The transmission chain 302c is driven to rotate through rotation of the first wheel disc 301b, the second wheel disc 302b is driven to rotate through rotation of the transmission chain 302c, the diameters of the first wheel disc 301b and the second wheel disc 302b are different, through arrangement, after the first wheel disc 301b rotates for one quarter of a circle, the second wheel disc 302b just rotates for half a circle, and the second linkage rod 302a is driven to rotate through rotation of the second wheel disc 302 b.

The operation unit 303 includes a mounting ring 303a, a connecting rod 303b, a power feeding block 303c, and an electroscope 303d, the mounting ring 303a is provided on an outer wall of the second link 302a, and the power feeding block 303c and the electroscope 303d are connected to the mounting ring 303a through the connecting rod 303 b.

The installation ring 303a is driven to rotate through the rotation of the second linkage rod 302a, the two groups of connecting rods 303b are driven to rotate through the rotation of the installation ring 303a, the second linkage rod 302a rotates for half a circle, so that the positions of the power transmission clamping block 303c and the electroscope 303d are opposite to those of the installation frame 301a, one end of the electroscope 303d is in an extending state in the initial state, a user holds the main adjusting rod 101a to conduct electricity testing, after the electricity testing is completed, the user immediately adjusts the limiting assembly 102 to release the limiting state, rotates the manual handle 101c for a quarter circle, and accordingly the outer wall of the main adjusting rod 101a is locked with the limiting sleeve 201, and the positions between the electroscope 303d and the power transmission clamping block 303c are switched.

The surface of the power transmission clamping block 303c is provided with a groove, when power is transmitted, the groove is clamped at the outer side of the knife switch, the groove and the knife switch are embedded, a user presses one end of the main adjusting rod 101a again, and the power transmission clamping block 303c is tilted upwards through the lever principle, so that power transmission closing is realized.

It is important to note that the construction and arrangement of the present application as shown in a variety of different exemplary embodiments is illustrative only. Although only a few embodiments have been described in detail in this disclosure, those skilled in the art who review this disclosure will readily appreciate that many modifications are possible (e.g., variations in sizes, dimensions, structures, shapes and proportions of the various elements, values of parameters (e.g., temperature, pressure, etc.), mounting arrangements, use of materials, colors, orientations, etc.) without materially departing from the novel teachings and advantages of the subject matter described in this application. For example, elements shown as integrally formed may be constructed of multiple parts or elements, the position of elements may be reversed or otherwise varied, and the nature or number of discrete elements or positions may be altered or varied. Accordingly, all such modifications are intended to be included within the scope of present invention. The order or sequence of any process or method steps may be varied or re-sequenced according to alternative embodiments. In the claims, any means-plus-function clause is intended to cover the structures described herein as performing the recited function and not only structural equivalents but also equivalent structures. Other substitutions, modifications, changes and omissions may be made in the design, operating conditions and arrangement of the exemplary embodiments without departing from the scope of the present inventions. Therefore, the invention is not limited to the specific embodiments, but extends to various modifications that nevertheless fall within the scope of the appended claims.

Furthermore, in an effort to provide a concise description of the exemplary embodiments, all features of an actual implementation may not be described (i.e., those not associated with the best mode presently contemplated for carrying out the invention, or those not associated with practicing the invention).

It should be appreciated that in the development of any such actual implementation, as in any engineering or design project, numerous implementation-specific decisions may be made. Such a development effort might be complex and time consuming, but would nevertheless be a routine undertaking of design, fabrication, and manufacture for those of ordinary skill having the benefit of this disclosure.

It should be 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 the technical solution of the present invention may be modified or substituted without departing from the spirit and scope of the technical solution of the present invention, which is intended to be covered in the scope of the claims of the present invention.

Claims (10)

1. The utility model provides a perpendicular erection equipment auxiliary operation bracing piece which characterized in that: comprising the steps of (a) a step of,

the main stay bar module (100), the main stay bar module (100) comprises a stay bar assembly (101), a limiting assembly (102), a release assembly (103) and a locking assembly (104), the stay bar assembly (101) is limited in one direction through the limiting assembly (102), the release assembly (103) is extruded through the limiting assembly (102), and the release assembly (103) is movably connected with the locking assembly (104);

the auxiliary supporting component (200), the auxiliary supporting component (200) is movably connected with the supporting rod component (101);

the linkage operation module (300), linkage operation module (300) include linkage subassembly (301), drive assembly (302) and operation subassembly (303), linkage subassembly (301) and vaulting pole subassembly (101) swing joint, drive assembly (302) respectively with linkage subassembly (301) and operation subassembly (303) swing joint.

2. The vertical installation apparatus auxiliary operation support bar according to claim 1, wherein: the support rod assembly (101) comprises a main adjusting rod (101 a), a manual control rod (101 b) and a manual control handle (101 c), wherein both ends of the manual control rod (101 b) penetrate through the main adjusting rod (101 a), one end of the manual control rod (101 b) is connected with the manual control handle (101 c), and the outer wall of the manual control rod (101 b) is connected with a gear (101 d).

3. The vertical installation apparatus auxiliary operation support bar according to claim 1, wherein: spacing subassembly (102) are including spacing storehouse (102 a), displacement pole (102 b) and displacement handle (102 c), spacing storehouse (102 a) set up in main regulation pole (101 a) outer wall, displacement pole (102 b) one end is connected with displacement handle (102 c), spacing storehouse (102 a) are run through to displacement pole (102 b) one end and link movable plate (102 e), movable plate (102 e) one side is passed through first spring (102 d) and is connected with spacing storehouse (102 a) inner wall, arc pinion rack (102 f) are connected to movable plate (102 e) one side, arc pinion rack (102 f) set up in gear (101 d) one side.

4. A vertical mounting apparatus auxiliary operation support bar according to claim 2 or 3, wherein: two sets of release subassembly (103) divide and establish main regulation pole (101 a) inner chamber both sides, release subassembly (103) are including slip arc board (103 a), traction lever (103 b) and arc traction plate (103 d), traction lever (103 b) both ends are connected with slip arc board (103 a) and arc traction plate (103 d) respectively, arc traction plate (103 d) outer wall connection extrusion round pin (103 e), slide (103 c) are seted up to the concave surface of slip arc board (103 a), hand control pole (101 b) set up in two sets of between slip arc board (103 a), hand control pole (101 b) outer wall connection cam dish (101 e).

5. The vertical installation apparatus auxiliary operation support bar according to claim 4, wherein: the locking assembly (104) comprises a side plate (104 a), a limiting slide plate (104 b) and a guide rod (104 d), wherein two ends of the guide rod (104 d) are connected with the side plate (104 a), one side of the side plate (104 a) is connected with the inner wall of the main adjusting rod (101 a), the limiting slide plate (104 b) is sleeved on the outer wall of the guide rod (104 d), one end of the limiting slide plate (104 b) is connected with the sliding arc plate (103 a), a second spring (104 c) is sleeved on the outer wall of the guide rod (104 d), and two ends of the second spring (104 c) are connected with two groups of limiting slide plates (104 b) respectively.

6. A vertical installation apparatus auxiliary operation support bar according to any one of claims 1 to 3, 5, wherein: the auxiliary support assembly (200) comprises a limit sleeve (201), a movable seat (202) and a first auxiliary rod (203), wherein the limit sleeve (201) is sleeved on the outer wall of the main adjusting rod (101 a), the movable seat (202) is arranged on the outer wall of the limit sleeve (201), and one end of the first auxiliary rod (203) is movably connected with the movable seat (202).

7. The vertical installation apparatus auxiliary operation support bar according to claim 6, wherein: the outer wall of the first auxiliary rod (203) is sleeved with a second auxiliary rod (204), and the outer wall of the second auxiliary rod (204) is connected with a positioning bolt in a threaded manner.

8. The vertical installation apparatus auxiliary operation support bar according to claim 7, wherein: the linkage assembly (301) comprises a mounting frame (301 a), a first wheel disc (301 b), a first linkage rod (301 c) and a driven bevel gear (301 d), wherein the mounting frame (301 a) is arranged at one end of a main adjusting rod (101 a), two ends of the first linkage rod (301 c) are connected with the inner wall of the mounting frame (301 a), the first wheel disc (301 b) and the driven bevel gear (301 d) are arranged on the outer wall of the first linkage rod (301 c), one end of a manual control rod (101 b) penetrates through the mounting frame (301 a) and is connected with a driving bevel gear (101 f), and teeth on the surface of the driving bevel gear (101 f) are meshed with the driven bevel gear (301 d).

9. The vertical installation apparatus auxiliary operation support bar according to claim 8, wherein: the transmission assembly (302) comprises a second linkage rod (302 a), a second wheel disc (302 b) and a transmission chain (302 c), wherein the second wheel disc (302 b) is arranged on the outer wall of the second linkage rod (302 a), two ends of the second linkage rod (302 a) are connected with the inner wall of the mounting rack (301 a), and two ends of the transmission chain (302 c) are respectively connected with the second wheel disc (302 b) and the first wheel disc (301 b) in a rotating mode.

10. The vertical installation apparatus auxiliary operation support bar according to claim 9, wherein: the operation assembly (303) comprises a mounting ring (303 a), a connecting rod (303 b), a power transmission clamping block (303 c) and an electroscope (303 d), wherein the mounting ring (303 a) is arranged on the outer wall of the second linkage rod (302 a), and the power transmission clamping block (303 c) and the electroscope (303 d) are connected with the mounting ring (303 a) through the connecting rod (303 b).

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