CN114770089A - Large-scale vertical condensate pump center adjusting device - Google Patents

Abstract

The invention discloses a center adjusting device of a large vertical condensate pump, which comprises a pipeline module; the fixing module is movably connected with the pipeline module and comprises a sleeving assembly and a clamping assembly, and the sleeving assembly is movably connected with the clamping assembly; and the driving module is movably connected with the fixed module. According to the invention, the adjusting device is arranged on the pipeline through the fixing module, the driving module is used for completing the connection and clamping between the adjusting device and the pipeline, the quick connection and connection are realized, and the position of the pipeline is adjusted through the extrusion and pushing between the adjusting components, so that the flange plates on the end surfaces of the pipeline are positioned at the same center to complete the alignment, the adjustment process is prevented from being adjusted by adopting a method of hammering by a sledge hammer, prying a motor by a crowbar or pulling the motor by a chain block, the adjustment efficiency is improved, and meanwhile, the damage of equipment in the adjustment process is avoided.

Description

Large-scale vertical condensate pump center adjusting device

Technical Field

The invention relates to the technical field of large vertical condensate pumps, in particular to a center adjusting device of a large vertical condensate pump.

Background

Because the original design of the large-scale vertical condensate pump in the prior art has no central adjusting device. When the center is adjusted, the center is adjusted by adopting a method of hammering by a sledge hammer, prizing a motor by a crow bar or pulling the motor by a chain block. This not only takes time and labor, increases the labor intensity of the worker, but also easily damages the equipment.

Disclosure of Invention

This section is for the purpose of summarizing some aspects of embodiments of the invention and to briefly introduce some preferred embodiments. In this section, as well as in the abstract and title of the application, simplifications or omissions may be made to avoid obscuring the purpose of the section, the abstract and the title, and such simplifications or omissions are not intended to limit the scope of the invention.

The present invention has been made keeping in mind the above problems occurring in the prior art.

Therefore, the technical problem to be solved by the invention is that when the center of the large vertical condensate pump is adjusted, the adjustment is time-consuming and labor-consuming, more redundant actions are needed, and the flange is directly knocked or extruded, so that the flange is easily damaged.

In order to solve the technical problems, the invention provides the following technical scheme: a large vertical condensate pump center adjusting device comprises a pipeline module; the fixing module is movably connected with the pipeline module and comprises a sleeving assembly and a clamping assembly, and the sleeving assembly is movably connected with the clamping assembly; the driving module is movably connected with the fixing module and comprises a driving assembly, a displacement assembly and a limiting assembly, the driving assembly is movably connected with the displacement assembly, and the displacement assembly is movably connected with the limiting assembly; and the linkage module is movably connected with the driving module and comprises an unlocking component and a releasing component which are movably connected.

As a preferable scheme of the center adjusting device of the large vertical condensate pump of the present invention, wherein: the suit subassembly includes first frame, fixed arc board, second frame and cutting ferrule, the one end of first frame and second frame is connected through the hinge, the one end of cutting ferrule is connected with the outer wall of second frame, the one end of fixed arc board is connected with the inner wall of second frame.

As a preferable scheme of the center adjusting device of the large vertical condensate pump of the present invention, wherein: the clamping assembly comprises a clamping frame, a first threaded sleeve, a first screw and a movable arc plate, one end of the clamping frame is connected with the inner wall of the clamping frame, one end of the first threaded sleeve is movably connected with the inner wall of the clamping frame, one end of the first screw is in threaded connection with the inner wall of the first threaded sleeve, the other end of the first screw penetrates through the clamping frame and is connected with the movable arc plate, and the outer wall of the first threaded sleeve is connected with the inner wall of the clamping frame through a bearing mounting seat.

As a preferable scheme of the center adjusting device of the large vertical condensate pump of the present invention, wherein: the pipe module comprises a pipe assembly and an adjusting assembly, the pipe assembly comprises a first pipe and a second pipe, the first pipeline and the second pipeline respectively penetrate through the two sets of the sheathing components, the opposite ends of the first pipeline and the second pipeline are both connected with flanges, the number of the adjusting components is two, the adjusting components are arranged on two sides of the sleeving component and comprise vertical rods, first adjusting bolts, shape adjusting frames, second adjusting bolts and fixing pieces, one ends of the two vertical rods are respectively connected with the outer walls of the first frame and the second frame in the sleeving component at the bottom position, one ends of the two fixing pieces are respectively connected with the outer walls of the first frame and the second frame in the sleeving component at the top position, the one end of shape alignment jig is connected with the montant, first adjusting bolt and second adjusting bolt all with the outer wall threaded connection of shape alignment jig.

As a preferable scheme of the center adjusting device of the large vertical condensate pump of the present invention, wherein: the utility model discloses a drive assembly, including drive casing, driving-disc, actuating lever, drive chain, the one end of drive casing is connected with the outer wall of first frame, the one end of actuating lever runs through the drive casing and is connected with the driving-disc, the inner chamber of actuating lever is provided with first spring, the one end of first spring is connected with the telescopic link, the one end of telescopic link is connected with first gear, the surface of telescopic link is provided with the disc, the outer wall of telescopic link is provided with protruding strip, the inner wall of actuating lever is provided with the spacing guide way of using with protruding strip cooperation.

As a preferable scheme of the center adjusting device of the large vertical condensate pump of the present invention, wherein: the displacement assembly comprises a second gear, a second threaded sleeve, a second screw rod and a traction rod, one end of the second gear is opposite to the first gear, the other end of the second gear is connected with the second threaded sleeve, the outer wall of the second threaded sleeve is connected with the inner wall of the driving shell through a bearing seat, one end of the second screw rod is in threaded connection with the inner wall of the second threaded sleeve, the other end of the second screw rod is connected with the traction rod, the cross section of the traction rod is rectangular, and one end of the traction rod penetrates through the outer side of the driving shell.

As a preferable scheme of the center adjusting device of the large vertical condensate pump of the present invention, wherein: spacing subassembly includes the locating plate, runs through pole, sliding seat and bracing, the one end of traction lever is connected with the locating plate, the one end of locating plate with run through the pole and be connected, the one end that runs through the pole runs through the cutting ferrule and is connected with the limiting plate, the sliding seat sets up in the outer wall of limiting plate, the one end of bracing is connected with the sliding seat, the both sides that run through the pole all are connected with the second spring, one side of second spring is connected with the bracing, the both ends of bracing are connected with first crosspiece and second crosspiece respectively.

As a preferable scheme of the center adjusting device of the large vertical condensate pump of the present invention, wherein: the unblock subassembly includes curb plate, hollow rod and resilience pole, the one end of curb plate is connected with the traction lever, the one end of hollow rod is connected with the curb plate, the inner wall of hollow rod is connected with the third spring, the one end of third spring is connected with spacing cardboard, the one end of spacing cardboard is connected with the resilience pole, the one end of resilience pole runs through hollow rod and is connected with the movable wheel, the one end of movable wheel and the outer wall contact of disc.

As a preferable scheme of the center adjusting device of the large vertical condensate pump of the present invention, wherein: the removing assembly comprises a removing bin, a traction pin, a traction handle and a baffle, one end of the removing bin is connected with the hollow rod, one end of the traction pin penetrates through the removing bin and is connected with the traction handle, the other end of the traction pin is connected with a sliding plate, one end of the sliding plate is connected with the baffle, one end of the baffle penetrates into the hollow rod, the other end of the sliding plate is connected with a fourth spring, and one end of the fourth spring is connected with the inner wall of the removing bin.

As a preferable scheme of the center adjusting device of the large vertical condensate pump of the present invention, wherein: the surface meshing of actuating lever has the driving chain, the one end of driving chain runs through to in the chucking frame and is connected with the outer wall rotation of first swivel nut, the tooth's socket that uses with the driving chain cooperation is seted up to the outer wall of first swivel nut.

The invention has the beneficial effects that: according to the invention, the adjusting device is arranged on the pipeline through the fixing module, the driving module is used for completing the connection and clamping between the adjusting device and the pipeline, the quick connection and connection are realized, and the position of the pipeline is adjusted through the extrusion and pushing between the adjusting components, so that the flange plates on the end surfaces of the pipeline are positioned at the same center to complete the alignment, the adjustment process is prevented from being adjusted by adopting a method of hammering by a sledge hammer, prying a motor by a crowbar or pulling the motor by a chain block, the adjustment efficiency is improved, and meanwhile, the damage of equipment in the adjustment process is avoided.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings required to be used in the description of the embodiments are briefly introduced below, and it is obvious that the drawings in the description below are only some embodiments of the present invention, and it is obvious for those skilled in the art that other drawings can be obtained according to the drawings without inventive labor. Wherein:

fig. 1 is a diagram showing an installation structure of the apparatus in the first and second embodiments.

Fig. 2 is a locking structure diagram of the fixing module in the first, second and third embodiments.

Fig. 3 is a structural view of a chucking assembly in the second and third embodiments.

Fig. 4 is a structural diagram of a driving module in the second and third embodiments.

Fig. 5 is a configuration diagram of a link module in the third embodiment.

Detailed Description

In order to make the aforementioned objects, features and advantages of the present invention more comprehensible, embodiments accompanying figures of the present invention are described in detail below.

In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present invention, however, the present invention may be practiced otherwise than as specifically described herein, and it will be appreciated by those skilled in the art that the present invention may be practiced without departing from the spirit and scope of the present invention and that the present invention is not limited by the specific embodiments disclosed below.

Furthermore, the references herein to "one embodiment" or "an embodiment" refer to a particular feature, structure, or characteristic that may be included in at least one implementation of the present 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 and 2, a first embodiment of the present invention provides a centering device for a large vertical condensate pump, which includes a pipe module 100;

the pipeline module 100 comprises a pipeline assembly 101 and an adjusting assembly 102, the adjusting assembly 102 is connected with a sleeving assembly 201, when the sleeving assembly 201 is clamped with the pipeline assembly 101 to finish installation, the sleeving assembly 201 located at the top is displaced through extrusion of bolts in the adjusting assembly 102, and therefore the position between a first pipeline 101a and a second pipeline 101b in the pipeline assembly 101 is changed, two groups of flanges 101c are aligned, and center position adjustment is achieved.

The fixing module 200 is movably connected with the pipeline module 100, the fixing module 200 comprises a sleeving assembly 201 and a clamping assembly 202, and the sleeving assembly 201 is movably connected with the clamping assembly 202;

make equipment suit on the pipeline surface through the suit subassembly 201, accomplish the chucking to the pipeline through chucking subassembly 202 to realize the quick installation location of equipment, after the installation location of fixed module 200 is accomplished, through the regulation of adjusting part 102, the bolt extrusion force that makes fixed module 200 receive transmits to pipeline department, thereby realizes the regulation of pipeline position.

The driving module 300 is movably connected with the fixed module 200, the driving module 300 comprises a driving component 301, a displacement component 302 and a limiting component 303, the driving component 301 is movably connected with the displacement component 302, and the displacement component 302 is movably connected with the limiting component 303;

through drive assembly 301 and displacement assembly 302 linkage, drive spacing subassembly 303 and link to the realization is to the connection chucking between first frame 201a and the second frame 201c in the suit subassembly 201, accomplishes the installation of equipment.

The linkage module 400 is movably connected with the driving module 300, the linkage module 400 comprises an unlocking component 401 and a releasing component 402, and the unlocking component 401 is movably connected with the releasing component 402.

After the connection clamping is completed between the first frame 201a and the second frame 201c, the unlocking assembly 401 is driven to be linked through the limiting assembly 303, so that the connection relation between the driving assembly 301 and the displacement assembly 302 is released, then the clamping assembly 202 is continuously driven to perform clamping operation through the driving assembly 301, and then the clamping of the pipeline is completed.

Example 2

Referring to fig. 2 to 4, a second embodiment of the present invention is based on the above embodiment.

The pipeline module 100 comprises a pipeline assembly 101 and an adjusting assembly 102, the pipeline assembly 101 comprises a first pipeline 101a and a second pipeline 101b, the first pipeline 101a and the second pipeline 101b respectively penetrate through two sets of the sleeving assemblies 201, and one ends, opposite to the first pipeline 101a and the second pipeline 101b, of the first pipeline 101a are connected with flanges 101 c.

In the accommodation process, the purpose is let two sets of flanges 101c align and realizes the installation of same central point promptly, two sets of suit subassemblies 201 suit respectively on first pipeline 101a and second pipeline 101 b's surface, in the accommodation process, exert the extrusion force through the bolt, with power transmission to suit subassembly 201 department, and suit subassembly 201 again with pipeline fixed connection, thereby make first pipeline 101a and second pipeline 101b take place the skew, then realize the position control to flange 101c, thereby realize the butt joint.

The sheathing assembly 201 comprises a first frame 201a, a fixed arc plate 201b, a second frame 201c and a clamping sleeve 201d, wherein one ends of the first frame 201a and the second frame 201c are connected through a hinge, one end of the clamping sleeve 201d is connected with the outer wall of the second frame 201c, and one end of the fixed arc plate 201b is connected with the inner wall of the second frame 201 c.

During installation, the worker unfolds the first frame 201a and the second frame 201c to fit on the surface of the pipeline, and rotates and aligns the first frame 201a and the second frame 201c, one end of the first frame 201a and the second frame 201c are connected through a hinge, and the other end of the first frame 201a and the second frame 201c are engaged with the ferrule 201d through the limiting component 303, so that the first frame 201a and the second frame 201c are connected in an installation mode.

The clamping assembly 202 comprises a clamping frame 202a, a first threaded sleeve 202b, a first screw 202c and a movable arc plate 202d, one end of the clamping frame 202a is connected with the inner wall of the clamping frame 202a, one end of the first threaded sleeve 202b is movably connected with the inner wall of the clamping frame 202a, one end of the first screw 202c is in threaded connection with the inner wall of the first threaded sleeve 202b, the other end of the first screw 202c penetrates through the clamping frame 202a and is connected with the movable arc plate 202d, and the outer wall of the first threaded sleeve 202b is connected with the inner wall of the clamping frame 202a through a bearing mounting seat.

The first screw 202c is driven to move by the rotation of the first threaded sleeve 202b, the movable arc plate 202d is driven to move by the movement of the first screw 202c, the outer wall of the pipeline is clamped by the movement of the movable arc plate 202d, and the fixed connection between the fixed module 200 and the pipeline is completed.

The number of the adjusting components 102 is two, and the adjusting components 102 are arranged on two sides of the sheathing component 201, each adjusting component 102 comprises a vertical rod 102a, a first adjusting bolt 102b, an L-shaped adjusting bracket 102c, a second adjusting bolt 102d and a fixing piece 102e, one end of each vertical rod 102a is connected with the outer walls of the first frame 201a and the second frame 201c in the sheathing component 201 at the bottom position, one end of each fixing piece 102e is connected with the outer walls of the first frame 201a and the second frame 201c in the sheathing component 201 at the top position, one end of each L-shaped adjusting bracket 102c is connected with the vertical rod 102a, and the first adjusting bolt 102b and the second adjusting bolt 102d are both in threaded connection with the outer walls of the L-shaped adjusting brackets 102 c.

In the accommodation process, rotate first adjusting bolt 102b through the user, through first adjusting bolt 102 b's rotation extrusion, make it carry out the altitude mixture control of direction from top to bottom to stationary blade 102e, rotate second adjusting bolt 102d through the user, make it carry out the altitude mixture control of horizontal direction to stationary blade 102e, before erection equipment, can measure the offset, ensure the mounted position and wait the regulating variable adaptation, the disposable regulation of being convenient for is accomplished.

Example 3

Referring to fig. 2 to 5, a third embodiment of the present invention is based on the above two embodiments.

The driving assembly 301 comprises a driving shell 301a, a driving disk 301b, a driving rod 301c and a transmission chain 301d, one end of the driving shell 301a is connected with the outer wall of the first frame 201a, one end of the driving rod 301c penetrates through the driving shell 301a and is connected with the driving disk 301b, an inner cavity of the driving rod 301c is provided with a first spring 301e, one end of the first spring 301e is connected with a telescopic rod 301f, one end of the telescopic rod 301f is connected with a first gear 301g, a disc 301h is arranged on the surface of the telescopic rod 301f, a protruding strip is arranged on the outer wall of the telescopic rod 301f, a limiting guide groove matched with the protruding strip for use is arranged on the inner wall of the driving rod 301c, and the telescopic rod 301f can move in the driving rod 301c in a telescopic mode while rotating.

The staff rotates driving disc 301b through the instrument, and the rotation through driving disc 301b drives actuating lever 301c to rotate, and the rotation through actuating lever 301c drives telescopic link 301f to rotate, and the rotation through telescopic link 301f drives first gear 301g to rotate.

The displacement assembly 302 comprises a second gear 302a, a second threaded sleeve 302b, a second screw 302c and a traction rod 302d, one end of the second gear 302a is opposite to the first gear 301g, the other end of the second gear 302a is connected with the second threaded sleeve 302b, the outer wall of the second threaded sleeve 302b is connected with the inner wall of the driving shell 301a through a bearing seat, one end of the second screw 302c is in threaded connection with the inner wall of the second threaded sleeve 302b, the other end of the second screw 302c is connected with the traction rod 302d, the section of the traction rod 302d is rectangular, and one end of the traction rod 302d penetrates to the outer side of the driving shell 301 a.

The first gear 301g drives the second gear 302a to rotate, the second threaded sleeve 302b rotates through the rotation of the second gear 302a, the second threaded sleeve 302b rotates to drive the second screw 302c to move, the second screw 302c rotates to drive the traction rod 302d to move, the section of the traction rod 302d is rectangular, and the traction rod can only move and cannot rotate when penetrating through the driving shell 301a, so that the second screw 302c is limited, the follow-up rotation phenomenon is avoided, and the stability of the transmission operation is ensured.

Spacing subassembly 303 includes locating plate 303a, run through pole 303b, sliding seat 303c and bracing 303d, the one end of traction lever 302d is connected with locating plate 303a, the one end of locating plate 303a with run through pole 303b and be connected, the one end that runs through pole 303b runs through cutting ferrule 201d and is connected with limiting plate 303h, sliding seat 303c sets up in limiting plate 303 h's outer wall, bracing 303 d's one end is connected with sliding seat 303c, the both sides that run through pole 303b all are connected with second spring 303g, one side of second spring 303g is connected with bracing 303d, the both ends of bracing 303d are connected with first crosspiece 303d and second crosspiece 303f respectively.

When the first frame 201a is butted with the second frame 201c, the first frame 201a drives the limiting component 303 to move, so that the limiting plate 303h, the penetrating rod 303b, the inclined strut 303d and other components penetrate through the clamping sleeve 201d, the maximum distance between the two clamping sleeves 201d is greater than the inner diameter of the clamping sleeve 201d, the inclined strut 303d is in a compressed state in the clamping sleeve 201d through the second spring 303g arranged between the inclined strut 303d and the penetrating rod 303b, after the inclined strut 303d leaves the inner cavity of the clamping sleeve 201d, the inclined strut 303d is restored to an initial state through the elasticity of the second spring 303g, the clamping limiting between the inclined strut 303d and the clamping sleeve 201d is more stable through the arrangement of the first transverse barrier 303d and the second transverse barrier 303f, the deviation of the inclined strut 303d under the stress is avoided, the limiting stability of the first frame 201a and the second frame 201c is ensured, and the connection between the first frame 201a and the second frame 201c is more stable.

The parts such as the inclined strut 303d can remain residual length after penetrating through the clamping sleeve 201d, the positioning plate 303a is driven to move through the movement of the traction rod 302d, the penetrating rod 303b is driven to move through the movement of the positioning plate 303a, the limiting plate 303h is driven to move through the movement of the penetrating rod 303b, the inclined strut 303d is driven to move through the movement of the limiting plate 303h, the inclined strut is in contact with the outer wall of the clamping sleeve 201d, and the clamping sleeve 201d and the clamping sleeve are locked with each other.

The unlocking assembly 401 comprises a side plate 401a, a hollow rod 401b and a rebound rod 401c, one end of the side plate 401a is connected with the traction rod 302d, one end of the hollow rod 401b is connected with the side plate 401a, the inner wall of the hollow rod 401b is connected with a third spring 401f, one end of the third spring 401f is connected with a limiting clamping plate 401e, one end of the limiting clamping plate 401e is connected with the rebound rod 401c, one end of the rebound rod 401c penetrates through the hollow rod 401b and is connected with a movable wheel 401d, and one end of the movable wheel 401d is in contact with the outer wall of the disc 301 h.

The draw bar 302d drives the positioning plate 303a to move and simultaneously drives the side plate 401a to move, the hollow rod 401b is driven to move by the movement of the side plate 401a, the rebound rod 401c is driven to move by the movement of the hollow rod 401b, the movable wheel 401d is driven to move by the movement of the rebound rod 401c, the movable wheel 401d is contacted with and pushed by the disc 301h by the movement of the movable wheel 401d, the telescopic rod 301f is driven to move by the movement of the disc 301h, the first gear 301g is driven to move by the movement of the telescopic rod 301f, the meshing relation with the second gear 302a is released, the second gear 302a can stop rotating after the transmission and locking of the inclined strut d are completed, the locking operation is continuously maintained, and the continuous transmission operation of the driving assembly 301 is not influenced.

The surface of the driving rod 301c is engaged with a transmission chain 301d, one end of the transmission chain 301d penetrates into the clamping frame 202a and is rotatably connected with the outer wall of the first threaded sleeve 202b, and the outer wall of the first threaded sleeve is provided with a tooth socket matched with the transmission chain 301d for use.

After the clamping between the first frame 201a and the second frame 201c is completed, the first threaded sleeve 202b is driven to rotate through the continuous rotation of the transmission chain 301d, so that the movable arc plate 202d continuously moves to clamp the pipelines, and the clamping adjustment operation of the pipelines with different specifications is facilitated;

the size and the shape of the first frame 201a and the second frame 201c are determined during production, so that the travel of the traction rod 302d moving to drive the inclined strut 303d to clamp cannot conflict with the clamping travel of the movable arc plate 202d, and the application range of the equipment is effectively widened.

The release assembly 402 comprises a release bin 402a, a traction pin 402b, a traction handle 402c and a baffle 402d, one end of the release bin 402a is connected with a hollow rod 401b, one end of the traction pin 402b penetrates through the release bin 402a and is connected with the traction handle 402c, the other end of the traction pin 402b is connected with a sliding plate 402f, one end of the sliding plate 402f is connected with the baffle 402d, one end of the baffle 402d penetrates into the hollow rod 401b, the other end of the sliding plate 402f is connected with a fourth spring 402e, and one end of the fourth spring 402e is connected with the inner wall of the release bin 402 a.

The surface of the driving shell 301a is provided with a detachable cover, after the equipment is adjusted, a user pulls the traction handle 402c, the traction pin 402b is driven to move by the movement of the traction handle 402c, the sliding plate 402f is driven to move by the movement of the traction pin 402b, the sliding plate 402f is driven to compress and deform the fourth spring 402e by the movement of the sliding plate 402f, the baffle 402d is driven to move by the movement of the sliding plate 402f, so that the limit of the limit catch plate 401e is released, the third spring 401f is in a stretching state at the moment, the limit catch plate 401e is driven to move by the return of the third spring 401f, so that the return rod 401c and the movable wheel 401d move, the limit of the disc 301h is released, the first gear 301g returns to the meshing relationship with the second gear 302a by the first spring 301e, and the user can detach the equipment, and finishing the adjustment operation.

It is important to note that the construction and arrangement of the present application as shown in the various 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., temperatures, pressures, etc.), mounting arrangements, use of materials, colors, orientations, etc.) without materially departing from the novel teachings and advantages of the subject matter recited 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 this 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 present invention is not limited to a particular embodiment, but extends to various modifications that nevertheless fall within the scope of the appended claims.

Moreover, 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 unrelated to the presently contemplated best mode of carrying out the invention, or those unrelated to enabling 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, without undue experimentation.

It should be noted that the above-mentioned embodiments are only for illustrating the technical solutions of the present invention and not for limiting, 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 or equivalent substitutions may be made on the technical solutions of the present invention without departing from the spirit and scope of the technical solutions of the present invention, which should be covered by the claims of the present invention.

Claims (10)

1. The utility model provides a large-scale vertical condensate pump center adjusting device which characterized in that: comprises the steps of (a) preparing a mixture of a plurality of raw materials,

a pipe module (100); and (c) a second step of,

the fixing module (200), the fixing module (200) is movably connected with the pipeline module (100), the fixing module (200) comprises a sleeving assembly (201) and a clamping assembly (202), and the sleeving assembly (201) is movably connected with the clamping assembly (202); and (c) a second step of,

the driving module (300) is movably connected with the fixing module (200), the driving module (300) comprises a driving component (301), a displacement component (302) and a limiting component (303), the driving component (301) is movably connected with the displacement component (302), and the displacement component (302) is movably connected with the limiting component (303); and the number of the first and second groups,

the linkage module (400), the linkage module (400) is movably connected with the driving module (300), the linkage module (400) comprises an unlocking component (401) and a removing component (402), and the unlocking component (401) is movably connected with the removing component (402).

2. The center adjusting device of the large vertical condensate pump according to claim 1, wherein: the sleeving assembly (201) comprises a first frame (201a), a fixed arc plate (201b), a second frame (201c) and a clamping sleeve (201d), one ends of the first frame (201a) and the second frame (201c) are connected through a hinge, one end of the clamping sleeve (201d) is connected with the outer wall of the second frame (201c), and one end of the fixed arc plate (201b) is connected with the inner wall of the second frame (201 c).

3. The center adjusting device of a large-sized vertical condensate pump according to claim 2, wherein: the clamping assembly (202) comprises a clamping frame (202a), a first threaded sleeve (202b), a first screw rod (202c) and a movable arc plate (202d), one end of the clamping frame (202a) is connected with the inner wall of the clamping frame (202a), one end of the first threaded sleeve (202b) is movably connected with the inner wall of the clamping frame (202a), one end of the first screw rod (202c) is in threaded connection with the inner wall of the first threaded sleeve (202b), the other end of the first screw rod (202c) penetrates through the clamping frame (202a) and is connected with the movable arc plate (202d), and the outer wall of the first threaded sleeve (202b) is connected with the inner wall of the clamping frame (202a) through a bearing mounting seat.

4. A large vertical condensate pump centering device as claimed in claim 2 or 3, wherein: the pipeline module (100) comprises a pipeline assembly (101) and an adjusting assembly (102), the pipeline assembly (101) comprises a first pipeline (101a) and a second pipeline (101b), the first pipeline (101a) and the second pipeline (101b) respectively penetrate through two sets of sleeving assemblies (201), and one opposite ends of the first pipeline (101a) and the second pipeline (101b) are connected with flanges (101 c);

the number of the adjusting components (102) is two, the two components are arranged on two sides of the sleeving component (201), the adjusting assembly (102) comprises vertical rods (102a), first adjusting bolts (102b), L-shaped adjusting frames (102c), second adjusting bolts (102d) and fixing pieces (102e), one end of each of the two vertical rods (102a) is connected with the outer walls of a first frame (201a) and a second frame (201c) in the sleeving assembly (201) located at the bottom, one end of each of the two fixing pieces (102e) is connected with the outer walls of the first frame (201a) and the second frame (201c) in the sleeving assembly (201) located at the top, one end of the L-shaped adjusting frame (102c) is connected with the vertical rod (102a), and the first adjusting bolt (102b) and the second adjusting bolt (102d) are in threaded connection with the outer wall of the L-shaped adjusting frame (102 c).

5. The large vertical condensate pump centering device of claim 3, wherein: drive assembly (301) are including drive casing (301a), driving-disc (301b), actuating lever (301c) and driving chain (301d), the one end of drive casing (301a) is connected with the outer wall of first frame (201a), the one end of actuating lever (301c) is run through drive casing (301a) and is connected with driving-disc (301b), the inner chamber of actuating lever (301c) is provided with first spring (301e), the one end of first spring (301e) is connected with telescopic link (301f), the one end of telescopic link (301f) is connected with first gear (301g), the surface of telescopic link (301f) is provided with disc (301h), the outer wall of telescopic link (301f) is provided with protruding strip, the inner wall of actuating lever (301c) is provided with the spacing guide way of using with protruding strip cooperation.

6. The large-scale vertical condensate pump centering device of claim 5, wherein: the displacement assembly (302) comprises a second gear (302a), a second threaded sleeve (302b), a second screw rod (302c) and a traction rod (302d), one end of the second gear (302a) is opposite to the first gear (301g), the other end of the second gear (302a) is connected with the second threaded sleeve (302b), the outer wall of the second threaded sleeve (302b) is connected with the inner wall of the driving shell (301a) through a bearing seat, one end of the second screw rod (302c) is in threaded connection with the inner wall of the second threaded sleeve (302b), the other end of the second screw rod (302c) is connected with the traction rod (302d), the section of the traction rod (302d) is rectangular, and one end of the traction rod (302d) penetrates to the outer side of the driving shell (301 a).

7. The large-scale vertical condensate pump centering device of claim 6, wherein: spacing subassembly (303) include locating plate (303a), run through pole (303b), sliding seat (303c) and bracing (303d), the one end of traction lever (302d) is connected with locating plate (303a), the one end of locating plate (303a) with run through pole (303b) and be connected, the one end that runs through pole (303b) runs through cutting ferrule (201d) and is connected with limiting plate (303h), sliding seat (303c) set up in the outer wall of limiting plate (303h), the one end of bracing (303d) is connected with sliding seat (303c), the both sides that run through pole (303b) all are connected with second spring (303g), one side of second spring (303g) is connected with bracing (303d), the both ends of bracing (303d) are connected with first crosspiece (303d) and second crosspiece (303f) respectively.

8. The large vertical condensate pump centering device of claim 7, wherein: the unlocking assembly (401) comprises a side plate (401a), a hollow rod (401b) and a rebound rod (401c), one end of the side plate (401a) is connected with a traction rod (302d), one end of the hollow rod (401b) is connected with the side plate (401a), the inner wall of the hollow rod (401b) is connected with a third spring (401f), one end of the third spring (401f) is connected with a limiting clamping plate (401e), one end of the limiting clamping plate (401e) is connected with the rebound rod (401c), one end of the rebound rod (401c) penetrates through the hollow rod (401b) and is connected with a movable wheel (401d), and one end of the movable wheel (401d) is in contact with the outer wall of a disc (301 h).

9. The large-scale vertical condensate pump centering device of claim 8, wherein: the release assembly (402) comprises a release bin (402a), a traction pin (402b), a traction handle (402c) and a baffle (402d), one end of the release bin (402a) is connected with a hollow rod (401b), one end of the traction pin (402b) penetrates through the release bin (402a) and is connected with the traction handle (402c), the other end of the traction pin (402b) is connected with a sliding plate (402f), one end of the sliding plate (402f) is connected with the baffle (402d), one end of the baffle (402d) penetrates into the hollow rod (401b), the other end of the sliding plate (402f) is connected with a fourth spring (402e), and one end of the fourth spring (402e) is connected with the inner wall of the release bin (402 a).

10. The large vertical condensate pump centering device of claim 5, wherein: the surface of the driving rod (301c) is engaged with a transmission chain (301d), one end of the transmission chain (301d) penetrates into the clamping frame (202a) and is rotationally connected with the outer wall of the first threaded sleeve (202b), and a tooth groove matched with the transmission chain (301d) is formed in the outer wall of the first threaded sleeve.

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